XXII October 12-16, 2014 Copenhagen, Denmark Pathways to Therapy and Prevention
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XXII October 12-16, 2014 Copenhagen, Denmark Pathways to Therapy and Prevention
XXII ND World Congress of Psychiatric Genetics October 12-16, 2014 Copenhagen, Denmark ORAL PRESENTATION ABSTRACTS Pathways to Therapy and Prevention Monday, October 13, 2014 11:00 AM - 12:00 PM Concurrent Oral Sessions OVERALL SESSION: THE GENOMICS OF AFFECTIVE DISORDERS & ADHD THE RELATIONSHIP BETWEEN COMMON AND RARE GENETIC VARIANTS IN ATTENTION DEFICIT HYPERACTIVITY DISORDER Joanna Martin1, Michael C. O'Donovan1, Anita Thapar1, Kate Langley1, Nigel Williams1 1 MRC Centre for Neuropsychiatric Genetics and Genomics, Cardiff University Background Attention deficit hyperactivity disorder (ADHD) is highly heritable. Genome-wide molecular studies show an increased burden of large, rare copy number variants (CNVs) in children with ADHD compared with controls. Recent polygenic score analyses have also shown that common variants can be used in mass to differentiate ADHD cases from controls. The relationship between these common and rare variants has yet to be explored. Methods In this study, we tested whether children with ADHD with a large (>500kb), rare (<1% frequency) CNV (N=60) differ from children with ADHD without such CNVs (N=421) by polygenic risk scores for ADHD. We also compared ADHD polygenic scores in ADHD children with and without CNVs to a group of population controls (N=4,670; of whom N=397 with CNVs). Results The results show that children with ADHD with large, rare CNVs have lower polygenic scores than children without such CNVs (OR=0.72, p=0.020). Although ADHD children without CNVs had higher scores than controls (OR=1.19, p=0.0013), this difference was not observed for ADHD children with CNVs (OR=0.86, p=0.26). Discussion These results are consistent with a polygenic liability threshold model of ADHD with both common and rare variants involved. ADHD POLYGENIC RISK SCORES PREDICT ADHD AND AGGRESSION IN CHILDHOOD AND ADOLESCENCE, BUT NOT ANXIETY AND DEPRESSION Christel M Middeldorp1, Maria M. Groen-Blokhuis1, Kees-Jan Kan1, Eveline L. de Zeeuw1, Abdel Abdellaoui1, Catharina E.M. van Beijsterveldt1, Meike Bartels1, Eric A. Ehli2, Gareth E. Davies2, Paul A. Scheet3, James J. Hudziak4, Jouke-Jan Hottenga1, Psychiatric Genomics Consortium Subgroup ADHD, Benjamin M. Neale5, Dorret I. Boomsma1 1 VU University Amsterdam, Biological Psychology, 2Avera Institute for Human Genetics, 3University of Texas, MD Anderson Cancer Center, 4University of Vermont, department of Psychiatry, 5Broad Institute Background With polygenic score analyses we recently demonstrated that genetic risk factors associated with an ADHD diagnosis predict continuous ADHD scores in the general population in preschool and school-aged children. ADHD symptoms can persist in adolescence and adulthood and are frequently co- morbid to aggression, anxiety and depression in childhood and adolescence. We present the results of polygenic risk scores analyses for these phenotypes. Methods In participants from the Netherlands Twin Register, polygenic risk scores were calculated based on the latest results from the childhood ADHD mega-analysis performed in PGC. In a linear mixed model, taking into account the relatedness between twins, the prediction of the polygenic risk scores was tested for maternal ratings at age 3, 7, 10 and 12 for the Child Behavior Checklist Scales (www.aseba.org) of aggression, anxious depression and withdrawn depressed. In adolescence, the prediction was tested for the self-reports for these scales and attention problems. For each age, data were available for between 1,000 and 2,000 individuals. We also analyzed the largest childhood and largest adolescent dataset including 2263 and 3424 individuals respectively. Results Significant prediction was found for the aggression and for attention problem scores throughout childhood and adolescence, for maternal ratings as well as self-reports and for each age. There were no significant predictions from ADHD polygenic scores towards anxious depression and withdrawn depressed behavior, not even in the largest samples. Discussion There is consistent overlap in genetic risk factors for a diagnosis of ADHD and continuous ADHD and aggression scores in childhood. Moreover, this prediction extends into adolescence. Although the phenotypic correlation between ADHD scores and anxious depression is as high as for ADHD scores and aggression, no significant predictions were detected from genetic risk scores to a diagnosis to anxious depression. Modeling of twin data and bivariate genome-wide association or GCTA analyses need to shed light on the different mechanisms that underlie the phenotypic associations of childhood ADHD and other behavioral and emotional problems. SHARED GENETIC INFLUENCES BETWEEN ATTENTION-DEFICIT HYPERACTIVITY DISORDER TRAITS IN THE GENERAL POPULATION AND CLINICAL DIAGNOSIS IN AN INDEPENDENT SAMPLE Evie Stergiakouli1, Joanna Martin2, Marian Hamshere2, Anita Thapar2, David Evans3, Beate St. Pourcain4, Nicholas Timpson3, George Davey Smith3 1 MRC Integrative Epidemiology Unit at the University of Bristol, 2Institute of Psychological Medicine and Clinical Neurosciences, MRC Centre for Neuropsychiatric Genetics and Genomics, Cardiff University School of Medicine, 3MRC Integrative Epidemiology Unit at the University of Bristol, 4MRC Integrative Epidemiology Unit at the University of Bristol, School of Oral and Dental Sciences, University of Bristol Background Many psychiatric disorders can be viewed as extremes of dimensional attributes present in the general population. Polygenic risk scores based on additive effects of common gene variants have been shown to contribute to psychiatric disorders considered either categorically or as a continuum (Lee et al. 2012). However, for behavioral traits in the general population genome-wide complex trait analysis (GCTA) did not show a significant genetic influence despite twin heritability being substantial in the same sample, suggesting that perhaps the genetic architecture of behavioral traits is different to disorder (Trzaskowski et al. 2013). For ADHD at least, common genetic risk scores associated with categorical diagnosis contribute to population trait variation (Martin et al. 2014). We performed a genomewide association study of ADHD symptoms in a general population sample and tested whether polygenic risk scores for ADHD traits predict diagnostic status and the severity of disorder. Methods Polygenic risk scores were calculated according to the method described by the International Schizophrenia Consortium (ISC) (Purcell et al. 2009) for 508 children aged 4-18 years with a confirmed research diagnosis of ADHD (Cardiff University) and 5,081 comparison subjects from the Wellcome Trust Case Control Consortium (target sample). The QC procedures, ascertainment of the target sample and GWAS results have been described in detail previously (Stergiakouli et al. 2012). The discovery sample consisted of a genome-wide study of ADHD symptoms measured by the Development and WellBeing Assessment (DAWBA) completed by a parent in 5,690 ALSPAC children (mean age 7.7 years (SD 0.14) (Boyd et al. 2013). SNPs with p<0.5 (after LD pruning) were selected from the discovery sample to calculate polygenic scores weighted for beta coefficient in the target sample. Results Polygenic risk scores calculated on 508 children with an ADHD diagnosis and 5,081 controls were associated with the number of total ADHD symptoms (beta coefficient=0.29 (0.04-0.54), p=0.024) within cases. ADHD polygenic scores could also distinguish cases from controls (OR=1.15 (1.05-1.26), p=0.001). Discussion Our results suggest that the same genetic variants that are relevant for the number of ADHD symptoms in a general population sample without clinical ADHD are also implicated in clinical ADHD predicting both severity and ADHD diagnostic status. This provides evidence that common genetic factors contribute to both behavioral traits in the general population and psychiatric disorder at least in the case of ADHD. Future studies of other behavioral traits will show if this is the case for other behavioral traits or it is limited only on ADHD symptoms. OF SEQUENCING AND COMPLEX TRAITS: GENE DISCOVERIES FOR DEPRESSION IN A LARGE FAMILY Najaf Amin1, Cornelia van Duijn2 1 Erasmus University Medical Center, 2Department of Epidemiology, Erasmus MC, Rotterdam, the Netherlands Background Depression is a common psychiatric disorder with a lifetime prevalence estimated to be 14.6%. Its obscure etiology hinders effective treatment, which at present is based on trial and error and hampered by the lack of biomarkers. Despite a strong genetic component (40-50%), there is no single unequivocally identified common variant for major depressive disorder or related phenotypes. This has raised the question whether relatively rare variants that segregate in families determine the disease in part. These variants may be identified using exome-sequencing in families. Methods We sequenced exomes of 1,300 individuals at an average depth of 74x and exome-array genotyped another 1,500 individuals from a uniquely large Dutch family (Erasmus Rucphen Family; ERF) that spans 23 generations. All individuals are assessed for depressive symptoms (Hospital anxiety and depression scale (HADS) and Center for epidemiologic studies depression scale (CESD)) and 369 patients diagnosed with depression. We used several approaches including linkage, haplotyping, filtering, genome-wide single-variant and gene-based association analyses to identify rare genetic variation that confer large effects on depression/depressive symptoms in this family. Results Genome-wide single-variant association analysis identified a significant, although intronic, rare variant G>A (p-value=9.2*10-08; MAF=1.7%, effect=3.36) in the gene TMEM151A on chromosome 11q13 associated with the HADS scale. The variant also appeared to segregate in the family, connecting all carriers (N=43) in six generations. Using linkage, haplotyping and filtering approach we identified a missense variant T>C on chromosome 9p24 (p-value=9*10-04, MAF=1%, effect=2.47) in the gene RCL1 associated with the HADS scale. All carriers (N=34) connected within 6 generations. This variant is highly conserved (phastcons = 1) and predicted to be damaging (polyphen=0.68). A rare T>G damaging (polyPhen=1) missense variant in the gene BTNL9 on chromosome 5q35 was suggestively associated (pvalue=1.5*10-05, MAF=1%, effect=3.44) with the HADS depression scale. All carriers (N=35) were connected to each other in four generations of which, 15 were treated for either major or mild depression. Discussion Using exome-sequencing and various gene-mapping techniques in a large family from a genetically isolated population, we have identified several rare genetic variants that segregate and confer large effects on depression/depressive symptoms. While RCL1 is a novel candidate, TMEM151A lies in the candidate region discovered in the major depression genome-wide association study by the psychiatric genetics consortium. Further, TMEM151A is predominantly expressed in brain (primarily subthalamicnucleus: AUC = 1.00, p-value=3*10-09) and predicted to be involved in dopamine and serotonin release cycle (p-value=2.7*10-11). BTNL9 is expressed in brain and fat tissues and known to be involved in triglyceride homeostasis. All discovered variants are relatively rare in 1000 genomes and other populations and usually not well-imputed thus limiting the scope for replication. Most variants are also not present on the Illumina exome array. We, therefore, plan to perform functional analyses. PATHWAY-BASED ENRICHMENT ANALYSIS (INRICH) IN 9,474 PATIENTS WITH BIPOLAR DISORDER AND 14,278 CONTROLS SUGGESTS AN INVOLVEMENT OF NCAM SIGNALING IN DISEASE ETIOLOGY Sven Cichon1, Thomas W. Mühleisen2, Andreas Forstner3, Markus Leber4, Thomas G. Schulze5, Jana Strohmaier6, Franziska Degenhardt3, Stefan Herms1, Manuel Mattheisen7, Per Hoffmann1, Additional Members of the MooDS Bipolar Disorder Working Group MooDS BD, Peter Propping8, Tim Becker4, Marcella Rietschel6, Markus M. Nöthen3 1 University of Basel, 2Institute of Human Genetics, Life & Brain Center, University of Bonn, Germany; Institute of Neuroscience and Medicine (INM-1), Research Center Juelich, 3Institute of Human Genetics, Life & Brain Center, University of Bonn, Germany, 4DZNE Bonn, Germany; Institute of Medical Biometry, Informatics and Epidemiology (IMBIE), University of Bonn, 5University of Göttingen, 6 Central Institute of Mental Health, Medical Faculty Mannheim, University of Heidelberg, 7Aarhus University, 8Institute of Human Genetics, University of Bonn Background Genome-wide association studies (GWAS) have identified the first common risk variants for bipolar disorder (BD), in particular ANK3, CACNA1C, NCAN, ODZ4, ADCY2, MIR2113-POU3F2. The majority of genetic variants influencing BD, however, remains unknown. These variants are expected to have small effect-sizes and are difficult to detect individually at high statistical stringency by GWAS using the currently available sample sizes. Pathway-based approaches have been developed, which use prior biological knowledge on gene function to facilitate a more powerful analysis of GWAS data sets and get more comprehensive insights into the biology of complex diseases. We employed this strategy in a large GWAS data set of BD. Methods For the pathway-based analysis, we used a sample of 9,747 patients with BD and 14,278 controls, comprised of a large cohort of European/Australian descent and the samples of the published BD-GWAS by the Psychiatric Genomics Consortium. Analysis was performed with INRICH, a software that tests if association signals in predefined gene sets (pathways) are enriched across independent gene loci (non-overlapping intervals). Results Test intervals were constructed in two steps. First, GWAS results on 2.3 million autosomal SNPs were filtered for strong to moderate signals (P<5E-4), resulting in 5,312 SNPs. Mapping of these SNPs to the largest gene isoform yielded a basic set of 386 genomic intervals. Secondly, overlapping intervals were merged to avoid multi-counting of clustered genes. Finally, 359 intervals covering 496 genes were tested for enrichment in 430 sets with 3,881 genes (Reactome pathway map). We found that a subset of 10 intervals, each covering a single gene, was significantly enriched in a set of 67 genes that form a pathway for NCAM signaling (P=3.4E-5). The result withstood correction for the total number of sets tested. Of note, among the 10 interval genes were the voltage-dependent calcium channel gene CACNA1C, the sulfate proteoglycan gene NCAN, and the transcription factor gene CREB1. Discussion The present study is an example for the increased power to detect potentially disease-relevant biological processes by applying pathway-based approaches. The results were generated in the largest GWAS data set of BD published to date. Our INRICH analysis provides correction-stable evidence that genetic variation in the NCAM pathway is of likely relevance for the development of BD. Some of the genes involved in this pathway (CACNA1C, NCAN) had previously been identified at genome-wide significance in single-marker level GWAS. The INRICH analysis puts these two genes in a broader biological context now by highlighting an enrichment of association signals in additional genes of that particular pathway. The NCAM pathway plays an important role in defined cellular processes in the brain, such as axonal growth and synaptic plasticity. THE NEGATIVE PHENOTYPIC CORRELATION BETWEEN DEPRESSION AND EDUCATIONAL ATTAINMENT IS NOT EXPLAINED BY PLEIOTROPIC GENETIC EFFECTS: RESULTS IN ~25,000 SUBJECTS Wouter J. Peyrot1, Sang H. Lee2, Yuri Milaneschi1, Tonu Esko3, Douglas F. Levinson4, Nicholas G. Martin5, Dorret I. Boomsma6, Naomi R. Wray2, Brenda WJH Penninx1, PGC-MDD Consortium 1 VU University Medical Center & GGZ inGeest, Amsterdam, 2The University of Queensland, Queensland Brain Institute, 3Estonian Genome Center, University of Tartu, Estonia, 4Department of Psychiatry and Behavioral Sciences, Stanford University, 5QIMR Berghofer Medical Research Institute, Brisbane, QLD 6Department of Biological Psychology, VU University Amsterdam, Amsterdam, The Netherlands, Background An association of lower educational attainment (EA) and increased risk for depression (MDD) has been confirmed in various western countries. This negative phenotypic correlation can result from multiple, not necessarily independent, effects; including causal, environmental or pleiotropic genetic effects. This study aims to estimate the contribution of pleotropic genetic effects on the phenotypic correlation between EA and MDD (genetic correlation). Methods Data were analyzed from a total of 9,662 MDD cases (with a DSM-IV based diagnoses) and 14,949 controls (with no diagnosis of MDD in lifetime) from the Psychiatric Genomics Consortium with additional Dutch and Estonian data. Information on EA (years of education) was available for 15,138 of these individuals. The association of MDD and EA was assessed with logistic regression. With genomewide data on 884,105 common autosomal SNPs, four methods were applied to test for genetic pleiotropy: (i) bivariate Genomic-Relationship-Matrix Restricted Maximum Likelihood (GREML), polygenic risk score analyses with (ii) EA as discovery and MDD as target and with (iii) MDD as discovery and EA as target, and (iv) SNP effect concordance analysis (SECA; Nyholt Bioinformatics 2014). The discovery sample for (ii) consisted of independent meta-analyses results of Rietveld et al (Science 2013), and the discovery sample for (iii) was constructed in the current sample with a ten-fold leave-one-out procedure. Results On the phenotypic level, EA was associated to MDD as expected with an odds ratio of 0.85 per standard deviation increase in years of education (95%CI 0.82-0.88). A similar association was found when only cases with an age at onset older than 30 were taken into account. A weak negative genetic correlation between MDD and EA was suggested by bivariate GREML analyses (i), but this correlation was not significant. The polygenic risk score analyses showed no evidence for genetic correlation, because the risk scores of discovery EA did not predict MDD (ii), and the risk scores of discovery MDD did not predict EA (iii). The SECA analyses (iv) yielded no evidence for negative genetic correlation. Discussion An association between low EA and MDD was confirmed within this sample from western countries comprising approximately 25,000 individuals. No consistent evidence was found for pleotropic genetic effects of genome-wide common SNPs. Hypothetically, pleiotropic genetic effects could exist amongst genetic variation not taken into account in this study, but more plausible is that environmental effects are causing the phenotypic correlation between EA and MDD. OVERALL SESSION: GENOMIC APPROACHES IN SCHIZOPHRENIA, SUBSTANCE ABUSE, AND PTSD GWAS OF POSTTRAUMATIC STRESS DISORDER: FIRST REPORT OF THE PSYCHIATIC GENOMICS CONSORTIUM - PTSD GROUP Laramie Duncan1, Caroline Nievergelt2, Stephan Ripke1, Jackie Goldstein1, Lynn Almli3, Laura Bierut4, Louis Fox4, Joel Gerlernter5, Guia Guffanti6, Israel Liberzon7, Mark Logue8, Adam Maihoffer2, Monica Uddin9, Mark Daly1, Kerry Ressler3, Karestan Koenen6 1 Broad Institute of MIT and Harvard, 2University of California San Diego, 3Emory University, 4 Washington University, 5Yale University, 6Columbia University, 7University of Michigan, 8Boston University, 9Wayne State University School of Medicine Background Post-traumatic stress disorder (PTSD) is a common psychiatric disorder with substantial unmet treatment need. Though neural circuitry is thought to be well understood in PTSD, the specific genetic variants contributing to the moderate heritability of PTSD (estimates 30%-72%) are largely or completely unknown, with few and somewhat inconsistent loci reported to date. To address the challenge of underpowered individual studies, the PGC-PTSD group was formed, with over 20 groups contributing data and analysis complete for 19,029 samples. Methods Standard GWAS quality control procedures were performed on each dataset individually, accounting for substantial diversity of genetic ancestry by identifying African American, European American, and other mixed ancestry subsets of each dataset. GWAS was first conducted within each ancestral group, and then fixed effect, inverse-variance weighted meta-analysis was conducted across groups. Results One novel locus reached genome-wide significance in the overall meta-analysis (3.76e-8). This SNP is genic and has the same direction of effect in the current PGC schizophrenia mega-analysis (p=0.01). The possibility of shared risk loci with schizophrenia is also indicated by an excess of samedirection, nominally associated (p<.05) loci observed when examining 111 SNPs robustly associated with schizophrenia in these PTSD meta-analytic results (15 same-direction, nominally associated loci observed and only 6 expected). Discussion In this collaborative study with sample size larger than any PTSD GWAS published to date, we identified a novel genic locus associated with PTSD across African American and European American samples. Preliminary evidence also suggests shared risk loci with schizophrenia. Notably, the diversity of ancestry in these PTSD samples is substantially greater than all other PGC datasets, with 52% African Americans and only 37% European Americans. This represents an important resource for the PGC community as we seek to ensure that results from large-scale genomic studies are equally applicable across diverse populations. THE INFLUENCE OF POLYGENIC RISK SCORES ON THE ASSOCIATION BETWEEN INFECTIONS AND SCHIZOPHRENIA – A NATIONWIDE DANISH STUDY Michael Benros1, Betina Trabjerg2, Sandra Meier2, Preben Mortensen2, Merete Nordentoft3, Esben Agerbo2 1 Mental Health Centre Copenhagen, Copenhagen University, 2National Centre for Register-based Research, Aarhus University, 3Mental Health Centre Copenhagen, University of Copenhagen Background Several studies have suggested an important role of infections and immune responses in the etiology of schizophrenia. However, the causal pathway underlying the enhanced risk for schizophrenia in individuals with infections is still unknown. Genetic studies of individuals with schizophrenia have shown associations with genes involved in immune processes, suggesting a shared genetic liability towards infections and schizophrenia. We therefore investigated the effect of the polygenic risk scores for schizophrenia on the association between infections and the risk of schizophrenia. Methods We made use of a nested case-control design and analysed a Danish population-based sample comprising of 823 cases with schizophrenia and 832 controls matched on sex, age and birth year. The (post-imputed) genomic data was obtained from the Psychiatric Genomics Consortium (PGC) after samples have been processed from the Danish Neonatal Screening Biobank. Polygenic risk scores based on the local cases-control sample were calculated using discovery effect size estimates weights from the latest PGC-GWAS mega-analysis for schizophrenia (excluding the Danish replication sample). All individuals were linked with nationwide population-based registers with virtually complete registration of all hospital contacts for infections. Out of the 823 individuals diagnosed with schizophrenia, a total of 332 individuals had a hospital contact with infection prior to the schizophrenia diagnosis (40%). Results After mutual adjustments for family history of infections and psychiatric disorders, a prior hospital contact with infection was associated with an increased relative risk of schizophrenia by 1.47 (95%CI=1.16-1.84). Adding the polygenic risk score, which was robustly associated with schizophrenia in this sample (RR=1.18; 95%CI=1.13-1.23), did not significantly alter the observed association of hospital contacts with infections and increased risk of schizophrenia (RR=1.53; 95%CI=1.20-1.94). No significant interaction between the polygenic risk score and infections were observed on the risk of developing schizophrenia (p=0.938). Neither did we observe any significant effect of the polygenic risk score on the risk of acquiring infections prior to being diagnosed with schizophrenia in analysis of cases only (RR=1.01; 95%CI=0.96-1.07). After mutual adjustments for the above variables, a maternal history of hospitalization for infection increased the risk of schizophrenia (RR=1.34; 95%CI=1.0 Discussion The polygenic risk score and a history of infections have strong independent effects on the schizophrenia risk. Although we adjusted for an important source of common genetic risk using the polygenic score, the effect of infections on the risk of schizophrenia remained. The common genetic risk measured by the polygenic risk score seems not to account for the association with infection. However the polygenic risk is lacking information on variation in the MHC region and rare variants, which might have affected the results. Results will additionally be presented from updated analysis on a larger dataset, including the associations with immune related genes, dose-response associations between the number of infections, time since the last infection, the severity of the infection, type and localization of the infection and associations with the polygenic risk score. TRANSLATING HUMAN GENETICS INTO NOVEL TARGET HYPOTHESES FOR SCHIZOPHRENIA H. Simon Xi2, Eric B. Fauman2, Shaoxian Sun3, Sara A. Paciga3, Schizophrenia Working Group, Patricio O'Donnell4, Jens R. Wendland3 1 Pfizer, 2Computational Sciences CoE, Pfizer Worldwide Research and Development, 3 PharmaTherapeutics Clinical Research, Pfizer Worldwide Research and Development, 4Neuroscience Research Unit, Pfizer Worldwide Research and Development Background Human genetics is a rational starting point for evidence-based drug discovery. Due to a paucity of robust genetic findings for brain disorders such as schizophrenia, this approach has found little application in CNS drug discovery to date. However, recent large-scale analyses have begun to identify a number of robust genetic loci for schizophrenia and now pose a fundamentally new opportunity and challenge to derive truly novel drug targets. In this work, we summarize current strategies for applying human genetics and related ‘omics data to drug discovery and outline the path from genetic locus to testable therapeutic mechanism for schizophrenia. Methods Starting from a list of genome-wide significant GWAS loci identified by the schizophrenia working group of the Psychiatric Genomics Consortium (PGC), we identified putatively causal genes in LD-independent loci using linkage disequilibrium and/or distance mapping. Once identified, we contextualize each causal gene with additional annotation on function and pathway, tissue expression, pharmacological, and literature knowledge to a) assess the potential causal relationship to schizophrenia, directionality of effect, cellular context, and potential safety liability, and b) identify a putative hypothesis for therapeutic intervention. These putative hypotheses were then further prioritized based on confidence in disease mechanisms, chemical doability, and availability of reagents and tools. Results Starting from a list of 125 LD-independent loci, we were able to map 107 putatively causal genes (85.6%). After gene triage and prioritization as outlined above, we were able to select 10-12 high priority genes within well-defined biological pathways relevant to schizophrenia, including calcium signaling and homeostasis, synaptic transmission, solute carrier transporters and inflammatory processes. Several of the identified high priority targets are currently being followed up in exploratory studies to address key gaps in validating them individually as a truly novel target for schizophrenia. Discussion Neuropsychiatric disorders, such as schizophrenia, remain one of the defining biomedical challenges in the 21st century, but are poorly served with new therapeutics. While recent advances in human genetics, from GWAS studies to rare variants, hold great promise for defining the pathogenesis of these brain disorders, the path from genetics to new medicines is far from clear. In this work, we have identified an efficient strategy to generate testable hypotheses to facilitate the translation from human genetics into new therapeutics for schizophrenia. This strategy is generalizable and applicable to not only other brain disorders, but furthermore other therapeutic areas where rich genetic substrate is or will be available. A BIOINFORMATICS PIPELINE FOR FUNCTIONAL ANNOTATION OF COMMON VARIANTS IDENTIFIED IN SCHIZOPHRENIA GWAS META-ANALYSIS Younes Mokrab1, James Scherschel1, Lewis Vidler1, Cara Ruble1, Brian Eastwood1, Suzanne Brewerton1, David Collier1, Schizophrenia Working Group Psychiatric Genomics Consortium 1 Eli Lilly Background Genome-wide association studies (GWAS) have been successful in identifying common variants associated with complex disorders such as schizophrenia, type 2 diabetes, and Alzheimer’s disease. However, most of the associated variants are non-coding (intra- or intergenic), and each index variant (i.e. showing the strongest statistical significance) is in linkage disequilibrium (LD) with other variants in the same locus, often spanning multiple genes. This makes it difficult to identify the variants that are likely to have a causal biological effect on disease, thus hampering the identification of the causative gene(s) within most loci. In the present study, we used summary data from the Schizophrenia Working Group of the Psychiatric Genomics Consortium (PGC2-SCZ) study which recently identified 108 genome-wide significant loci associated with schizophrenia (Ripke et al. 2014, submitted), to develop a pipeline for functional annotation of associated variants for further biological analysis. Methods GWAS meta-analysis was performed as described in the PGC2-SCZ study. Briefly, the dataset contained 51 ancestry matched non-overlapping case-control samples (48 European, 3 East Asian, 36,989 cases and 113,075 controls). In each sample, association was tested using imputed marker dosages and principal components to control for population stratification. Results were combined using an inverse- weighted fixed effects model. Next, the tested genetic variants were processed in two stages: First, QC was performed involving filtering by imputation INFO score ≥ 0.6, MAF ≥ 0.01, and successfully imputation in ≥ 20 samples producing 9.5 million variants. Second, variants were processed using an internal pipeline based on Variant Effect Predictor (VEP) (ensembl.org) to annotate the variants and their associated genes together with publically available data on gene function, regulation, conservation, expression, disease associations, pathways, known ligands, drug ability and protein structure. Results LD-independent index variants were defined as those with low LD (r2 < 0.1) to a more significantly associated variant within a 500 kb window. 128 index variants were found to surpass genome-wide significance (P ≤ 5x10-8) and are in turn correlated with 3,801 significant variants at r2 <0.6. Chromosomal loci were defined as the physical region containing each index variant and the associated variants at r2 > 0.6. Associated loci within 250 kb of each other were merged. Thus 108 distinct loci were found, 84 of which have not been previously implicated in schizophrenia. Together these loci contain 588 genes. 75% of the loci include protein-coding genes (40% a single gene) and a further 8% are within 20 kb of a gene. In principle, any of the index or close LD friends can constitute the causal variants affecting specific gene function. Therefore, systematic analysis for all the significant 3,929 variants was performed using VEP in order to assess the potential impact on gene function. Discussion Analysis of VEP results showed that 304 genes are found within 5kb distance from any given significant variant. These comprise 268 genes in which variants fall outside gene boundaries and 36 genes for which variants fall inside a gene (exons, introns, 5’-UTR or 3’-UTR). Of the latter a number of genes were affected by missense variants including SLC39A8, APOPT1, ITIH3 and FES. Currently, further analysis is being performed to categorize the variants into functional classes and add further regulatory data to help build specific hypotheses about gene function alterations as disease aetiology in schizophrenia. GENOME-WIDE META-ANALYSES OF FTND SCORE AND THE TIME TO SMOKE FIRST CIGARETTE IN THE MORNING Xiangning Chen1, Jingchun Chen1, FTND Meta-analysis Consortium 1 Virginia Commonwealth University Background The Fagerstrom test for nicotine dependence (FTND) is commonly used in the study of smoking addiction and nicotine dependence. One of the items, the time to smoke first cigarette in the morning, or TFC, could be considered a nicotine withdrawal measure. We used these phenotypes to identify risk genes for nicotine dependence. Those genes identified by TFC analyses may be used for translational studies using animal models where withdrawal measures are robust. Methods We organized a consortium and conducted genome-wide association analyses of FTND sum scores (0-10) and TFC (0-3) phenotypes. The consortium yielded 15 independent datasets with more than 19,000 subjects of European ancestry. Each site conducted genotype imputation and association analyses separately, and meta-analyses were used to combine data from individual datasets. Results We found that the CHRNA5-A3-B4 gene cluster on 15q25 was associated with FTND scores (minimal p at rs14714468, 6.9x10-18). 4 other loci (rs76000782 located between TRIM42 and SCL25A36, p 1.7x10-8; rs148155309 in PIK3AP1, p 3.0x10-8; rs117029742, p 4.7x10-9; and rs78824641 in HS3ST4, p 1.1x10-8) reached genome-wide significance. The analyses of the TFC phenotype identified the CHRNA5-A3-B4 locus (minimal p at rs17487223, 1.1x10-9) and 3 other loci (rs184042824, p 4.4x10-8, rs117029742, p 1.0x10-8 and rs10133756, p 3.9x10-9). Other candidates identified by the analyses of both FTND and TFC included CHRNB3 (rs57308096, FTND p 4.8x10-5 and TFC p 4.1x10-7), KIF2B (rs2877510, FTND p 2.5x10-5, TFC p 1.67x10-5), CDH12 (rs4266369, FTND p 9.6x10-6, TFC p 6.6x10-6), ZNF804A (rs80078811, FTND p 2.2x10-5, TFC p 3.1x10-5), and MFSD2A (rs34022242, FTND p 2.2x10-5, TFC p 1.3x10-6). Discussion In addition to the CHRNA5-A3-B4 locus, other significant loci discovered by FTND and TFC are mutually supportive. The same marker identified in PI3KAP1 by FTND analyses, rs148155309, is close to genome-wide significance (p = 6.0x10-8) in TFC analyses. rs117029742 is significant in both FTND and TFC analyses. rs10133756, identified by TFC analyses, has a p value of 2.6x10-6 in FTND analyses. And rs78824641 identified by FTND has a p value of 3.6x10-5 in TFC analyses. PIK3AP1 encodes a protein involved in the Toll like receptor signaling pathway that plays an important function in inflammatory responses and other immune functions. There is no known gene near rs117029742, but an EST, BG182718, with no known function, is nearby. Other top candidate genes supported by both FTND and TFC analyses have been reported to be associated with smoking behaviors (CHRNB3), obesity (KIF2B and CDH12), psychiatric disorders (CDH12 and ZNF804A) and cancers (CDH12, HS3ST4, and MFSD2A). THE GENETIC LANDSCAPE OF CANNABIS USE: A META-ANALYSIS INCLUDING 27,000 SUBJECTS SHOWS ENRICHMENT OF NOMINALLY SIGNIFICANT ASSOCIATIONS Sven Stringer1, Camelia Minica2, Karin J.H. Verweij3, Hamdi Mbarek2, International Cannabis Consortium International Cannabis Consortium, Eske M. Derks1, Nathan A. Gillespie4, Jacqueline M. Vink2 1 Academic Medical Center Amsterdam, 2Department of Biological Psychology / Netherlands Twin Register, VU University Amsterdam, The Netherlands, 3Department of Developmental Psychology and EMGO Institute for Health and Care Research, VU University, Amsterdam, the Netherlands, 4Virginia Commonwealth University Background Cannabis is the most widely produced and consumed illicit drug worldwide. Previous research has demonstrated the adverse effects of cannabis use. Cannabis use may lead to abuse or dependence; subsequently causing physical, psychological and social problems. The International Cannabis Consortium (ICC) was created to combine results of multiple GWA studies in order to identify genetic variants underlying individual differences in cannabis use phenotypes. Methods We performed a meta-analysis of 27,788 GWA samples from 12 samples collected in Europe, the US and Australia. Lifetime cannabis use (i.e., never/ever used cannabis) ranged from 1.26% to 91.6% with a median of 46.0%. Participating groups performed their own quality control. Imputation and GWA analysis were performed according to a standardized protocol. All imputations were based on the same reference panel (1000 genomes phase 1 European (EUR)). All GWA analyses were based on dosage data and corrected for age, sex, and birth cohort effects and population stratification by controlling for ancestry PCs. Additionally, we performed gene-based tests of association. Results Although the QQ-plot clearly indicated enrichment of nominally significant findings, no genome- wide significant hits were identified. The statistically most significant marker was located on chromosome 12 (12:30479358) with a p-value=8.6*10-8. This polymorphism is located in an intergenic region about 30kb from transmembrane and tetratricopeptide repeat containing 1 (TMTC1) and 30kb from Importin 8 (IPO8). Among the 23,523 genes tested, none reached genome-wide significance following FDR correction. The lowest p-value from the gene-based test was found for GammaAminobutyric Acid (GABA) A Receptor, Rho 3 (GABRR3) (p=9.46*10-5). We have access to two independent replication samples, including another ~3500 subjects in which we aim to test for replication of the top 10 SNPs. Discussion We present preliminary results of the world’s largest meta-analysis of cannabis use to date. The QQ-plot of this meta-analysis indicated significant enrichment of nominally significant findings. One polymorphism nearly reached genome-wide significance and this may be an interesting candidate for future replication studies. The SNP of interest is located near the gene TMTC1, which has previously been found to be associated with weight-related phenotypes. The reward system in the brain plays a role both in eating behaviors and substance use and this gene is therefore an interesting candidate for future studies. In this regard, it is interesting that the top-result in the gene-based tests was found for GABBR3. Previous research has suggested that GABA plays a role in addictive behaviors through its involvement in the reward pathway and even though no significant association was detected, the role of this gene in cannabis use should be further investigated. OVERALL SESSION: NOVEL “OMICS” INSIGHTS INTO SCHIZOPHRENIA AND BIPOLAR DISORDER LARGE-SCALE RNA-SEQUENCING OF SCHIZOPHRENIA BRAINS BY THE COMMONMIND CONSORTIUM Pamela Sklar1, CommonMind Consortium 1 Icahn School of Medicine at Mount Sinai Background Advances in human genetics are reshaping the way we understand schizophrenia (SCZ). We know infinitely more about disorder-associated DNA changes, specifically, that there are many variants, rare and common, that are contributors. Using information from gene expression microarrays and protein interactions databases we have basic outlines of genesets enriched for importance, but none of this information has led to the identification of specific targets for drug development. The CommonMind Consortium (CMC, http://commonmind.org) is a public-private pre-competitive consortium that brings together disease area expertise, large and well-curated brain sample collections, and data management and analysis expertise. CMC is generating and analyzing large scale data from human subjects with neuropsychiatric and neurodevelopmental disorders. The consortium consists of five academic groups, two pharmaceutical companies, and one non-profit group. Methods RNA sequencing was performed in 554 human post-mortem samples (265 schizophrenia samples and 289 controls) from the DLPFC (BA9, BA46) as part of the CommonMind Consortium efforts. Ribozero libraries were constructed to enable detection of non-coding RNAs. Genotype data from Illumina human core and exome were available on all samples. Covariates were controlled using surrogate variable analysis. Differential expression analysis was performed using linear models implemented in a voom/limma analysis pipeline. Gene coexpression networks were constructed using WGCNA and high-density eQTL analyses were conducted. A variety of publicly available CRE annotations for promoters, enhancers or open chromatin (DNase hypersensitivity regions) were used. Furthermore, we used in-house generated CRE (promoter) annotations for neuronal cells sorted from the DLPFC of controls and cases with schizophrenia. Common and rare variant data from multiple GWAS and exome sequencing were also used. Results Differential expression was detected for 15.6% of transcripts in the DLPFC at an FDR of 5%. Differentially expressed genes were enriched for several categories of DNA variants implicated in risk for SCZ including rare nonsynonymous DNA mutations previously reported in a Swedish case-control exome sequencing study and common variants associated with SCZ. WGCNA gene coexpression analysis identified 37 modules of which 11 are dysregulated in SCZ at FDR 5%. Among those, 3 modules are upregulated (primarily related to neuronal function) and 8 are down regulated (primarily related to neuronal function, synaptic function, glutamate transmission, PSD and mitochondria/energy production). Discussion In this study, we applied a stepwise approach to identify a subset of putative causal SNPs and genes and then examined their distribution in gene coexpression networks. Overall, the results support the existence of convergent genetic abnormalities in schizophrenia that could potentially drive the disease leading to molecular and cellular alterations. GENIC COPY NUMBER VARIANTS IN AN EXOME-SEQUENCING STUDY OF 4,978 SCHIZOPHRENIA CASES AND 6,256 CONTROLS Douglas Ruderfer1, Menachem Fromer1, Giulio Genevese2, Peter Holmans3, Patrick Sullivan4, Steven McCarroll2, Christina Hultman5, Pamela Sklar1, Shaun Purcell1 1 MSSM, 2Broad, 3Cardiff, 4UNC, 5Karolinska Background Large, rare copy number variants (CNV) are associated to schizophrenia (SCZ) risk, in terms of genome-wide burden as well as at specific loci (e.g. 22q11.2). We have previously documented the role of rare CNVs in a large Swedish sample, based on single nucleotide polymorphism microarray data (Szatkiewicz et al., 2014). Here we use next generation exome-sequencing on over 10,000 individuals to study rare CNVs in the same sample, by analysis of sequence read-depth. Compared to microarrays, CNV detection through sequencing likely has complementary properties, including, in some cases, greater sensitivity for smaller deletions and duplications that impact single genes. Methods The Swedish sample compromised 4,978 individuals with SCZ and 6,256 controls; deepcoverage exome-sequence and SNP microarray data were available on all individuals. We used a method we previously developed (XHMM, Fromer et al., 2012) to detect and genotype CNVs from exomesequencing read-depth; PLINK was used to perform the primary QC, burden and pathway analyses. Results Using XHMM we detected 6,426 high-confidence rare (<1%) deletions and 9,270 duplications (~1.3 per person). Of prior microarray-based CNVs that spanned genes, ~80% (4,649/5,929) were also detected by XHMM, consistent with previous reports of sensitivity. We were able to demonstrate a significant enrichment of genic deletions in cases compared to controls, especially pronounced for large (>500kb) deletions (p=1.4x10-5). Of particular note here, however, is the large number of smaller, genic CNVs (N=3,379 CNV spanning no more than 3 targets, mean size 11kb), most of which were not in the prior microarray dataset. In the set of CNVs new to this analysis we see significant enrichment in both deletions (p=0.008) and duplications (p=0.001). We are currently in the process of further geneset and network analyses of these novel sequence-based CNVs. Discussion Our results demonstrate that CNVs can be robustly detected by exome-sequencing and we replicate the previously reported burden of CNVs in schizophrenia cases. XHMM also detects a large number of novel CNVs that typically impact single genes: although a proportion of these calls are likely to be false positives, they could also provide a basis to implicate individual risk genes. The next step, which we will also discuss here, is to test single genes and pathways for association combining all classes of rare variation obtained from exome-sequencing, including point mutations, short insertion/deletions and de novo mutations from family-based studies. RARE, PROTEIN-ALTERING VARIATION IN A SWEDISH SCHIZOPHRENIA CASECONTROL COHORT OF MORE THAN 11,000 INDIVIDUALS Giulio Genovese1, Shaun Purcell2, Jennifer Moran3, Menachem Fromer2, Kimberly Chambert3, Patrick Sullivan4, Pamela Sklar2, Christina Hultman5, Steven McCarroll3 1 Broad Institute, 2Mount Sinai, 3Stanley Center, 4University of North Carolina at Chapel Hill, 5Karolinska Institutet Background Because individuals affected with schizophrenia have substantially fewer offspring than unaffected individuals do, variants of large effect may be rare in populations. While common variant association studies based on tens of thousands of individuals have implicated many individual genes, rare variant association studies are at an earlier stage. Methods We sequenced the exomes of more than 11,000 individuals – 4,954 schizophrenia cases and 6,239 controls – doubling the size of our recent collaborative study (Purcell et al., Nature 506, 185–190 (2014)). We developed a framework for effectively correcting for ancestry effects. We applied burden tests to find enrichments of mutations in cases. We also describe methods for ascertaining somatic mutations in exome sequence data. Results We first show that singleton (observed exactly once in the cohort of 11,200) loss of function mutations in any gene are enriched in schizophrenia cases relative to controls (p=0.0009, OR=1.055). We show a clear polygenic signal which is a) concentrated in brain-expressed genes, b) concentrated in ultrarare alleles, and c) more pronounced in disruptive loss of function and damaging missense variants. We also show how results from population-based studies are converging with trio studies of de novo mutation. Our results greatly expand the implication of genes whose mRNA transcripts are bound by FMRP, which in our data show definitive enrichment for loss of function ultra-rare alleles in schizophrenia cases (p=3.1e-7, OR=1.39). Discussion Rare variation points to a highly polygenic architecture for schizophrenia. Though this is the largest exome sequencing study in schizophrenia to date, more than doubling the size of our recent collaborative study, definitive implication of specific genes will require still-larger sample sizes. POLYGENIC RISK SCORES FOR SCHIZOPHRENIA AND BIPOLAR DISORDER PREDICT CREATIVITY Robert Power1, Stacy Steinberg2, Gyda Bjornsdottir2, G. Bragi Walters2, Engilbert Sigurdsson3, Augustine Kong2, Daniel Gudbjartsson2, Hreinn Stefansson2, Kari Stefansson2 1 Institute of Psychiatry, London, 2deCODE genetics, 3University of Iceland Background Great thinkers of the past, from Aristotle to Shakespeare, have remarked that the same unleashing of thoughts and imagination characterize the creative genius and insanity. Such views run the risk of romanticizing psychiatric disorders that present misery to individuals and huge healthcare costs to society. However, evidence in support of the notion that creativity and psychotic disorders truly overlap could shed light on the nature of creativity and on psychiatric pathogenic processes that hitherto have remained elusive. Several attempts have been made at quantifying the overlap between psychiatric disorders and creativity by studying both patients and their close relatives, for the most part these studies have documented the existence of the overlap though concerns exist over reporting and ascertainment of cases within families defined as ‘creative’. Hence we sought to answer this question using genetic markers to establish a more objective measure of overlapping heritability. Methods To do so we made use of the Psychiatric Genomics Consortium’s available data on common sequence variants that predispose to psychosis, and tested whether they are more commonly found in creative Icelanders than in population controls and in several carefully selected and matched control groups (N=92,647). Creative individuals were defined from member lists of organizations and unions in various fields of arts, including writers, musicians, painters, dancers, and accomplished chess players. Results We showed that polygenic risk scores for psychotic disorders are significantly greater in unaffected creative individuals than in population controls (P = 2.6 x 10-9 and 2.7 x 10-7 for schizophrenia and bipolar risk scores, respectively), but not for 20 diseases chosen as negative controls or in random individuals matched to creative individuals on age, sex and ancestry. Further it appeared that the polygenic risk score for bipolar disorder was associated with educational attainment while the schizophrenia score was not, potentially suggesting different mechanisms by which they affect cognitive traits such as creativity. Discussion Our results suggest that creativity that is conferred on individuals by common variants in their genomes that are also known to increase risk of psychiatric disorders. Hence, the ability to think and feel differently, a prerequisite for being creative, may come with a compulsion to think and feel differently, a prerequisite for psychiatric diagnoses. Determining what features set an individual down one of these paths and not, be it environment or deleterious rare variants, is a crucial next step in understanding the causes of psychiatric disorders. POLYGENIC PROFILE RISK SCORES, PSYCHIATRIC FAMILY HISTORY AND THE RISK OF SCHIZOPHRENIA Esben Agerbo1, Carsten Pedersen2, Manuel Mattheisen3, Ole Mors4, Sandra Meier5, Anna Kähler6, Preben Bo Mortensen7 1 CIRRAU - Centre for Integrated Register-based Research, National Centre for Register-based Research, Aarhus University, 2CIRRAU - Centre for Integrated Register-based Research, National Centre for Register-based Research, Aarhus University, 3Department of Biomedicine and Centre for Integrative Sequencing (iSEQ), Aarhus University, 8000 Aarhus C, Denmark. The Lundbeck Foundation Initiative for Integrative Psychiatric Research, iPSYCH, Aarhus and Copenhagen, Denmark, 4Centre for Psychiatric Research, Aarhus University Hospital, Psychiatric Hospital, Denmark, 5National Centre for Register- Based Research, Aarhus University, Aarhus, Denmark, 6Department of Medical Epidemiology and Biostatistics, Karolinska Institutet, Stockholm, Sweden, 7Lundbeck Foundation Initiative for Integrative Psychiatric Research, iPSYCH; Aarhus University, Denmark Background Genome-based profile risk scores and family history of severe psychiatric illnesses are strongly associated with the risk of schizophrenia. Few studies, however, have had the opportunity to evaluate the combined impact of a polygenic risk score and a family history of severe psychiatric illness simultaneously on the risk of schizophrenia in a nationwide and population-based sample. The aim of this study is 1) to assess the marginal impacts of polygenic risk scores and family history of severe psychiatric illness on the risk of schizophrenia in a population-based sample, 2) to quantify the fraction of subjects with schizophrenia that would not have occurred if the effects associated with the polygenic risk score and the family history of severe psychiatric illness were absent, 3) to determine the proportion of the risk associated with family history that is mediated through the polygenic risk score. Methods We made use of a nested case-control design and analysed a Danish population-based sample comprising of 866 cases with schizophrenia, 871 controls and their first-degree relatives. Information on family history was extracted from the National Health Registers and the (post-imputed) genomic data was obtained from the Psychiatric Genomics Consortium (PGC) after samples have been processed from the Danish Neonatal Screening Biobank. Risk scores based on the local cases-control sample were calculated using discovery effect size estimates weights from the latest PGC-GWAS mega-analysis for schizophrenia (excluding the Danish replication sample). Family history was categorized to indicate whether the subject's parents or siblings previously had been diagnosed with: schizophrenia or related psychosis, bipolar affective disorder or any other psychiatric disorder. Results The risk of schizophrenia was elevated in those with relatives with a schizophrenia-like psychoses (OR:4.2 [2.6-6.8]), bipolar affective disorder(2.8 [1.9-4.3]) or 3) other psychiatric disorder(2.6 [2.0-3.4]). Based on 24755 markers (p-value threshold of 0.05) in the PGC discovery sample, there was a dose-response relationship with the risk score and the risk of schizophrenia with an OR of 8.0 (4.5-14.1) in the upper decile vs the lowest decile. The attributable risks associated with family history and the risk score were 26% (23%-28%) and 52% (50%-53%). The interaction p-value was 0.03. To assess the part of family history that was mediated through the polygenic risk score, we calculated the mediating proportion under interaction, which suggested that 64% (26%-103%) of the effect of a family history with psychosis among subjects with a family history of psychosis was mediated through the risk score while 24% (14%-34%) was mediated in subjects without a family history of psychosis. Discussion The polygenic risk score as well as a family history of severe psychiatric illness represent strong valid measures to which a sizeable proportion of the excess schizophrenia risk can be attributed. The effects of the polygenic risk score and family history are dependent. Furthermore, a particular large proportion of the effect associated with a family history of psychosis is mediated through the polygenic risk score for subjects with a family history of psychosis leaving some room open for the influence of environmental factors. BIOLOGICAL INSIGHTS FROM 108 SCHIZOPHRENIA-ASSOCIATED GENETIC LOCI Stephan Ripke1, PGC Schizophrenia Group 1 Massachusetts General Hospital Background The PGC (Psychiatric Genomics Consortium) is an international group of researchers whose major aim is to maximize the utility of extant psychiatric GWAS through mega-analysis. In a previous study, our first wave of genome-wide schizophrenia association analysis identified multiple loci involved in this genetically complex and clinically heterogeneous disorder (Nature Genetics, 2011). The first results from our most recent endeavor were presented at World Congress of Psychiatric Genetics 2013. Methods Here we present an update of the biological insights gained analyzing the results. This international endeavor, which now comprises 35,476 schizophrenia cases and 46,839 controls coming from 52 substudies. The presented data is imputed into 1000 Genomes (Aug, 2012) and analyzed using standard logistic regression with ancestry components as covariates. All index SNPs with a p-value smaller than 1x10-6 were used for replication lookup in an independent GWAS analysis with 1,500 cases and 66,000 controls. There will be an estimated additional lookup of approximately 4,000 cases and 10,000 controls genotyped on PsychChip. Results There are numerous follow up analysis being performed with the more than 100 reliably associated regions from this newest round of meta-analysis. The loci implicated include prior findings (MIR137, CACNA1C, ZNF804A) along with a host of new targets. Associations at DRD2 and multiple genes involved in glutamatergic neurotransmission highlight molecules of known and potential therapeutic relevance to schizophrenia. Additionally the hypothesized link between the immune system and schizophrenia is supported by these associations. Discussion These results are in line with prior predictions and developments in other complex disease GWAS with sufficiently large samples like Crohn's disease. They continue to provide new insights into the biology of schizophrenia. OVERALL SESSION: EPIGENETIC APPROACHES ALLELE-SPECIFIC DNA METHYLATION ACROSS BRAIN AND BLOOD IDENTIFICATION OF TISSUE-SPECIFIC DIFFERENTIALLY METHYLATED REGIONS Sarah Marzi1, Emma Meaburn2, Manuela Volta3, Matthew Davies4, Claire Troakes3, Simon Lovestone3, Leonard Schalkwyk3, Jonathan Mill5 1 MRC SGDP Research Centre, Institute of Psychiatry, King’s College London, 2Department of Psychological Sciences, Birkbeck, University of London, 3MRC SGDP Research Centre, Institute of Psychiatry, King’s College London, 4Department of Twin Research and Genetic Epidemiology, St Thomas’ Hospital, King’s College London, 5Exeter University Medical School Background While most DNA methylation is thought to be symmetrical across both alleles throughout the genome, there are some notable exceptions. Genomic imprinting and X chromosome inactivation are two well-studied sources of allele-specific (or allelically-skewed) methylation (ASM), but recent research has indicated a more complex pattern in which genotypic variation can be associated with DNA methylation in cis. Methods Given the known heterogeneity of methylation across tissues and cell types we explored inter and intra-individual variation in ASM across multiple human brain tissues and whole blood from multiple individuals. We used SNP microarrays to quantitatively assess ASM in amplicons covering ~8% of the human genome following cleavage with a cocktail of methylation-sensitive restriction enzymes (MSREs). Results Consistent with previous studies, we find widespread ASM with >4% of the ~220,000 loci interrogated showing evidence of allelic skewing. A large proportion of ASM appears to be tissuespecific, with ~50% of ASM loci identified within an individual being specific to one tissue, with higher levels observed in blood compared to brain. Interestingly, cross-tissue ASM is enriched in regions of the genome associated with lincRNAs. Discussion These findings contribute to our understanding about the nature of differential DNA methylation across tissues and have important implications for genetic studies of psychiatric disease. AN EPIGENOME-WIDE SCAN FOR AUTISM SUSCEPTIBILITY LOCI ACROSS MULTIPLE BRAIN REGIONS Chloe Chung Yi Wong1, Neelroop Parikshak2, Laura Lysenko3, Elham Assary3, Claire Troakes3, Joana Viana4, Daniel Condliffe3, T. Grant Belgard2, Vivek Swarup2, Eilis Hannon4, Leonard Schalkwyk3, Daniel Geschwind2, Jonathan Mill5 1 Institute of Psychiatry, King's College London, 2University of California, Los Angeles, 3King's College London, 4Exeter University, 5King's College London, Exeter University Background Autism Spectrum disorders (ASD) are a range of complex neurodevelopmental disorders with heterogeneous aetiological origins. There is now emerging evidence to suggest that in addition to genetic factors, environmental and epigenetic factors also play a significant role in the aetiology of ASD. We had previously defined shared RNA co-expression changes in ASD post mortem brain, but aetiology of many of these changes was undefined. Methods With the aim to explore the contribution of epigenetic variation to ASD, we have profiled DNA methylation in a unique and sizeable collection of post-mortem brain tissues (n=202) among three brain regions including dorsolateral prefrontal cortex, primary auditory cortex and cerebellum. DNA methylation at over 485,000 CpG sites was quantified using the Illumina Infinium HumanMethylation450 array. Quality control and data pre-processing was undertaken using the WateRmelon R package in conjunction with an analysis pipeline developed by our group. Results Our analyses reveal a number of significant ASD-assoicated DNA methylation differences CpG sites, located in both novel genomic region as well as in the vicinity of several known ASD genes. In addition to identifying region- specific differentially methylated sites, we have identified regions that are consistently altered across the two cortical regions using a novel meta- analysis method. Discussion This study, to our knowledge, represents the most comprehensive epigenomic analysis of ASD using post-mortem tissues to date. Our epigenome-wide scan identifies several new candidate genes for ASD and provide further evidence for a role of altered DNA methylation in ASD. EXPOSURE TO GLUCOCORTICOIDS DURING HIPPOCAMPAL NEUROGENESIS AND CHILDHOOD MALTREATMENT: MECHANISMS OF SYSTEM WIDE EPIGENETIC EFFECTS Nadine Provençal1, Tania Carrillo-Roa2, Torsten Klengel3, Christoph Anacker4, Carmine M Pariante5, Kerry J. Ressler6, Elisabeth Binder7 1 Max Planck Institute for Psychiatry, 2Dept. Translational Research in Psychiatry Max Planck Institute for Psychiatry, 3YRK: Behav Neuro & Psych Dis, Emory University, 4Dept. Neurosciences, Columbia University, 5Psychological Medicine, King's College London, 6Dept. Psychiatry and Behavioral Sciences, Emory University, 7Dept. Translational Research in Psychiatry, Max Planck Institute for Psychiatry and Emory University Background Excessive glucocorticoids (GC) release after early life stress exposure is thought to result in a long-lasting disruption of the stress hormone system and ultimately to an increase risk for psychiatric disorders later in life. Stress and GCs are known to regulate hippocampal neurogenesis and to induce long- lasting changes in DNA methylation in specific loci such as the glucocorticoid receptor (NR3C1) and FK506 binding protein 5 (FKBP5) in hippocampal and in peripheral blood cells DNAs. Here we aim to expend these results to multiple loci using whole genomic comprehensive analysis of the epigenetic effects of GC activation during hippocampal neurogenesis. Specifically, we aim to identify stable epigenetic modifications induced by GC activation during early neurogenesis stages that are maintained through cell maturation. Moreover, we hypothesised that part of these epigenetic alterations will be seen in peripheral blood cells DNA of adults expose to severe child abuse. Methods We used Illumina arrays to analyse gene expression, CpG methylation and hydroxymethylation levels of immortalised human hippocampal progenitor cells (HPC) treated with dexamethasone (Dex) or vehicle at different stages during neurogenesis. Cells were either treated in the proliferation phase, after the proliferation and differentiation phases (acute), followed by 20 days of washout after the acute treatment (sustained) or followed by 20 days of washout after a treatment in postdifferentiation (post- diff). We also quantify global changes in DNA methylation and hydroxymethylation levels using ELISA. CpG methylation profiles from adults exposed or not to severe child abuse (n=496) were analysed by Illumina 450K arrays. All the analysis where done correcting for estimated cells counts (neuron/glia or PBMC ratios). Results Global methylation and hydroxymethylation analysis revealed a significant effect of Dex treatment on hippocampal neurogenesis that could possibly be explained by differential expression of DNMT3b and TET1. Overall, the methylation analysis revealed a large number of Dex-induced differentially methylated CpG sites (Pvalue < 0.05 and FDR < 0.05) following the acute (7222 CpGs), the sustained (6207 CpGs) and the post-differentiation (14383 CpGs) treatments but not after proliferation. Interestingly, 136 CpG sites showed differential methylation followed Dex treatment in the acute phase and maintained this difference after 20 days of washout, identifying sustained effect of Dex in various loci including FKBP5. Most of these CpGs sites were not affected by Dex treatment in postdifferentiation. In addition, over 11% of the differentially methylated CpGs in the HPCs following Dex treatment were also differentially methylated in blood cells of adult exposed to child abuse. Discussion Preliminary analysis provides evidence of clustered and genome-wide epigenetic effects of GC activation during hippocampal neurogenesis where the timing of the exposure seems to be critical to induce long-lasting changes. CROSS-TISSUE METHYLOMIC PROFILING STRONGLY IMPLICATES A ROLE FOR CORTEX-SPECIFIC DEREGULATION OF ANK1 IN ALZHEIMER’S DISEASE NEUROPATHOLOGY Jonathan Mill1, Katie Lunnon1, Rebecca Smith2, Eilis Hannon1, Claire Troakes2, Joe Burrage1, Ruby Macdonald1, Pavel Katsel3, Vahram Haroutunian3, Zachary Kaminsky4, Catharine Joachim5, John Powell2, Simon Lovestone5, Leonard Schalkwyk2 1 University of Exeter, 2King's College London, 3The Icahn School of Medicine at Mount Sinai, 4Johns Hopkins University School of Medicine, 5University of Oxford Background Alzheimer’s disease (AD) is a chronic neurodegenerative disorder characterized by progressive neuropathology and cognitive decline. Although the neuropathological manifestation of AD is well characterized in post-mortem brain, little is known about the underlying risk factors or mechanism(s) involved in disease progression. Increasing knowledge about the biology of the genome implicates an important role for epigenetic variation in human health and disease, and recent methodological advances mean that epigenome-wide association studies (EWAS) are now feasible for complex disease phenotypes. We have undertaken the first systematic cross-tissue EWAS analysis of DNA methylation in AD using a powerful sequential replication design, with the goal of identifying disease-associated methylomic variation across pathologically-relevant regions of the brain. Methods The first (‘discovery’) stage of our analysis utilized multiple tissues from donors (N = 117) archived in the MRC London Brainbank for Neurodegenerative Disease. From each donor, genomic DNA was isolated from four brain regions (entorhinal cortex, superior temporal gyrus, frontal cortex and cerebellum) and, where available, whole blood obtained pre-mortem. A cortical 'replication' dataset was generated using DNA isolated from two regions (STG and PFC) obtained from a cohort of brains archived in the Mount Sinai Alzheimer's Disease and Schizophrenia Brain Bank (N = 144). A third replication sample was obtained from the Thomas Willis Oxford Brain Collection. DNA methylation was quantified using the Illumina 450K HumanMethylation array with differentially methylated positions (DMPs) confirmed using bisulfite-pyrosequencing. Results We identify a highly significant AD-associated differentially methylated region (DMR) in the ankrin 1 (ANK1) gene that is strongly associated with neuropathology in the entorhinal cortex, a primary site of AD manifestation in the brain. This region was confirmed as significantly hypermethylated in two other cortical regions (superior temporal gyrus and prefrontal cortex) but not in the cerebellum, a region largely protected from neurodegeneration in AD, or whole blood obtained premortem, from the same individuals. These CpG sites were subsequently found to be significantly hypermethylated in cortical samples from two independent brain cohorts, providing compelling evidence for an association between cortex-specific ANK1 hypermethylation and AD-related neuropathology. Discussion Our study represents the first EWAS of AD employing a sequential replication design across multiple tissues, and highlights the power of this approach more broadly for the identification of disease- associated DMRs. DYNAMIC AND SEX-SPECIFIC CHANGES IN DNA METHYLATION DURING HUMAN FETAL BRAIN DEVELOPMENT Helen Spiers1, Eilis Hannon2, Leonard Schalkwyk1, Chloe Wong1, Rebecca Smith1, Nick Bray1, Jonathan Mill3 1 King's College London, 2University of Exeter, 3University of Exeter, King's College London Background Brain development involves the alteration of cellular phenotype in response to genetically pre-programmed, environmental and stochastic events. The emergence of epigenome-wide profiling technologies has facilitated the study of epigenetic processes, such as DNA methylation at CpG dinucleotides, in neurodevelopment. Here we report data from a genome-wide interrogation of methylomic trajectories across human fetal brain development. Methods Genome-wide DNA methylation was quantified in a unique cohort of human fetal brain samples (n=100 male, n=79 female, age range = 23 to 184 days post-conception) using the Illumina HumanMethylation450 BeadChip. This technology provides a quantitative measure of DNA methylation level at 485,577 CpG sites, covering 99% of RefSeq genes with an average of 17 CpG sites per gene region. Results After adjusting for sex, linear regression identified 28,718 autosomal age-associated differentially methylated probes (aDMPs) passing genome-wide significance testing (P<1.25E-7), 16,190 of these showed age-associated hypomethylation, whereas 12,528 became hypermethylated. Weighted gene co-methylation network analysis identified several modules of co-methylated loci enriched for functional pathways associated with brain development. We also identified considerable sex differences in DNA methylation during brain development; of note, 521 autosomal probes displayed significant (P<1.22E-7) sex-specific levels of DNA methylation across brain development and sex-age interactions were observed at 59 autosomal probes. Discussion This study provides increased knowledge about the molecular mechanisms that regulate dynamic gene expression across human brain development, and identifies pathways contributing to sexual differentiation of the brain. This work has the potential to enhance understanding of the pathogenesis of neurodevelopmental brain disorders, such as autism and schizophrenia, and may provide a route to understanding the sexual dimorphism observed in such conditions. A LARGE-SCALE DNA METHYLATION ANALYSIS OF SLC6A4 USING PERIPHERAL BLOOD SAMPLES OF PATIENTS WITH BIPOLAR DISORDER Tempei Ikegame1, Miki Bundo1, Yui Murata1, Hiroko Sugawara1, Harumi Saida1, Fumiko Sunaga1, Jun Ishigooka1, Tsukasa Sasaki1, Kenji Kondo1, Masashi Ikeda1, Nakao Iwata1, Tadafumi Kato2, Kiyoto Kasai1, Kazuya Iwamoto1 1 The University of Tokyo, 2Laboratory for Molecular Dynamics of Mental Disorders, RIKEN Brain Science Institute Background To date, a large number of studies have focused on serotonin transporter (5-HTT) as a key molecule to elucidate the mechanism of mental disorders because aberrant release and reuptake of serotonin in the brain of patients with mood and anxiety disorders were reported. In a previous study, we have shown the promoter hypermethylation of SLC6A4 gene, which encodes 5-HTT in monozygotic twins discordant for bipolar disorder (BD). Furthermore, we have confirmed SLC6A4 promoter hypermethylation in lymphoblastoid cell lines and postmortem brain tissues of patients with BD. Here we examined DNA methylation level of SLC6A4 promoter using genomic DNA derived from a relatively large-scale peripheral blood cell (PBC) samples of healthy controls and patients with BD. In addition, we analyzed the relationship between DNA methylation level and the short (S) or long (L) allele of serotonin transporter-linked polymorphic region (5-HTTLPR) of SLC6A4 promoter. Methods Two micrograms of genomic DNA extracted from PBC samples of patients with BD (n = 449) and age- and sex-matched healthy controls (n = 456) were treated with sodium bisulfite modification using an EpiTect 96 Bisulfite Kit (QIAGEN). All subjects were from the Japanese population. A regionspecific PCR with a biotinylated primer was performed for SLC6A4 promoter. The examined CpG sites were chosen based on the our previous epigenetic studies that reported DNA methylation alterations in BD. DNA methylation level was measured with the PSQ 96MA instrument (QIAGEN) according to the manufacturer’s protocol. The 5-HTTLPR was genotyped by using standard PCR and direct amplicon sequencing. Results We found a significantly higher methylation level at one of the two validated CpG sites in patients with BD compared to controls (p < .001). Subsequent analysis revealed significant effect of sex on DNA methylation level in controls. Data analysis considering sex difference revealed that hypermethylation was prominent in male patients with BD compared to male controls (p < .01). Significant hypermethylation in male patients was also observed even when they were classified into bipolar I and II disorders (p < .05). Finally, subgroup analysis considering 5-HTTLPR revealed a significant hypermethylation in male patients with BD harboring a particular L allele. Discussion Hypermethylation of SLC6A4 promoter in patients with BD is consistent with most of the previous studies on mood disorders and other psychiatric disorders. Hypermethylation in BD was associated with sex and 5-HTTLPR, suggesting the complex interactions between genetic and environmental factors contribute to the epigenetic change in patients with BD. 2:30 PM - 4:30 PM Symposia Sessions NEW DATA ABOUT THE GENETICS OF ATTENTION DEFICIT HYPERACTIVITY DISORDER Chair: Stephen Faraone, SUNY Upstate Medical University Overall Abstract Details This symposium presents new data about the genetics of ADHD. The first two talks focus on variant discovery; the second two address the biological significance of implicated variants. Anders Borglum will present a genome-wide association study of a Danish birth-cohort of ADHD cases and controls based on the Danish Newborn Screening Biobank (DNSB). The Danish Psychiatric Central Research Register has identified all children born since 1981 diagnosed with ADHD (~18,000) and selected a large random population based control group (~28,000) that can be individually matched to the cases. The samples of the identified individuals have been retrieved from the DNSB for DNA extraction and genotyping on the PsychChip. The register provides access to a broad range of phenotypic information (e.g. on sub-phenotypes and comorbidities) and environmental risk factors/exposures, allowing for comprehensive genetic, environmental and GxE analyses. Dr. Borglum will present the results from the first data freeze consisting of a large subset of the Danish iPSYCH sample of ADHD cases and controls (in total >45,000 individuals). Ben Neale will present result from the PsychChip analyses from the ADHD subgroup of the Psychiatric Genomics Consortium (PGC). The PsychChip incorporates exome chip content, a common variant GWAS backbone for imputation, and a set of ~50,000 markers selected based on previous evidence in psychiatry. Using the PsychChip, the current number of ADHD cases with genome-wide association data increases from the approximately 5,000 samples currently to ~15,000. Dr. Neale will also integrate analysis of 23&Me self-report of ADHD into the meta-analysis to evaluate the effectiveness of their self-report phenotyping. Beth Wilmot will present the results of a pathway analysis of ADHD that uses individual genotype data from multiple variants to model a pathway-level effect, thus allowing different underlying models of disease risk to be tested. This approach is in contrast to those that test for enrichment of individual SNP-level effects. She will discuss the differences in performance across these methods and their impact on the resulting determination of significant pathways in relation to the ADHD cohorts within the PGC. Jan Haavik will review some approaches to investigating the biological functions of ADHD variants, particularly missense variants in genes found by GWAS and sequencing. This work focusses on regulatory protein complexes involved in serotonin and catecholamine signaling, including the family of 14-3-3 proteins that are highly expressed in the nervous system and interact with hundreds of target proteins, implicating them in a range of different cellular pathways. The functional analysis pipeline includes biochemical studies, in silico modeling and molecular systems biology approaches. Many computational tools have been proposed to predict the effects of SNPs and prioritize variants for further studies. While homology modeling GENOME-WIDE ASSOCIATION STUDY OF A DANISH BIRTH-COHORT OF ADHD CASES AND CONTROLS Anders Børglum1 1 Aarhus University Individual Abstract Attention deficit hyperactivity disorder (ADHD) is a common childhood behavioral disorder affecting 3-6% of school-age children around the world. The disorder is highly heritable and several moderately sized genome-wide association studies have been performed, the largest by the Psychiatrics Genomics Consortium including 2,064 trios, 896 cases, and 2,455 controls. None of these studies have identified single SNPs reaching genome-wide significance. However, the SNP heritability of ADHD has been estimated to 0.28, which is similar to what is reported for schizophrenia (0.23), indicating that common SNPs contribute substantially to ADHD susceptibility and that increasing GWAS sample sizes is likely to produce significant results. In Denmark, nationwide screening of new-borns for phenylketonuria (PKU) and other metabolic diseases has been carried out since 1975 and since 1981 surplus of the samples have been stored in the Danish Newborn Screening Biobank (DNSB). DNSB presently contains dry blood spot samples from more than 2 million individuals, and it continuously increases with annual screening of around 65,000 new-borns. Thus, the Biobank constitutes a unique resource of biological material from nationwide birth-cohorts. Moreover, using the unique personal identification number assigned to all live-born children it is possible to crosslink the DNSB samples to the comprehensive Danish register system containing detailed longitudinal information on multiple health and social outcomes. As part of the Danish iPSYCH (Lundbeck Foundation Initiative for Integrative Psychiatric Research) program and in collaboration with the Broad Institute and the Psychiatric Genomics Consortium, we have initiated a large-scale study of ADHD based on the samples available in the DNSB. Coupling the samples with information from the Danish Psychiatric Central Research Register we have identified all children born in Denmark since 1981 that have been diagnosed with ADHD (?18,000) and selected a large random population based control group (?28,000) that can be individually matched to the cases. The samples of the identified individuals have been retrieved from the DNSB for DNA extraction and genotyping on the PsychChip. Through the register system we have access to a broad range of phenotypic information (e.g. on sub-phenotypes and comorbidities) and environmental risk factors/exposures, allowing for comprehensive genetic, environmental and GxE analyses. Here we will present the results from the first data freeze consisting of a large subset of the Danish iPSYCH sample of ADHD cases and controls (in total >45,000 individuals). GENOME-WIDE ASSOCIATION META-ANALYSIS OF ADHD Benjamin Neale1, PGC-ADHD Group 1 Massachusetts General Hospital Individual Abstract Genome-wide association studies for psychiatric illnesses are beginning to yield robust replicable results, as led by the current efforts in schizophrenia. For Attention Deficit/Hyperactivity Disorder (ADHD), such associations have yet to be found. However, GCTA heritability analysis and polygenic scoring results suggest that the search for common variants may not be in vain. As part of the current Psychiatric Genomics Consortium efforts, we have designed the PsychChip, a custom genotyping array that incorporates the exome chip content, a common variant GWAS backbone for imputation, and a set of ~50,000 markers selected based on previous genome-wide association evidence in psychiatry or on emerging rare variant analysis. Using the PsychChip, we are expanding the current number of cases with genome-wide association data from the approximately 5,000 samples currently to ~15,000. We will also integrate analysis of 23&Me self-report of ADHD into the meta-analysis to evaluate the effectiveness of such self-report phenotyping. Primary association results from the meta-analysis of ADHD will be presented, as will polygenic prediction from the self-report phenotypes into the clinically ascertained samples. We will also evaluate the extent to which rare standing coding variation, as assayed by the exome chip content, will inform on risk to ADHD in the population. Genome-wide association analysis of ADHD holds the potential to reveal robust replicable results that can inform the biological basis of disease as well as provide insight into the nature of overlap between ADHD and other psychiatric and developmental phenotypes. Large sample sizes are an essential component of this landscape and these results will shed further light on how many cases for ADHD will be necessary to gain a more comprehensive view on the genetic basis of this disease. UTILIZING GENETIC ARCHITECTURE TO MODEL PATHWAY LEVEL EFFECTS IN ATTENTION DEFICIT HYPERACTIVITY DISORDER Beth Wilmot1, Michael Mooney1, Shannon McWeeney1, Joel Nigg1 1 Oregon Health & Science University Individual Abstract Pathway representation can provide a biological context for the interpretation of genomic variants associated with complex disease. Within Pathway analyses, multiple approaches for calculating pathway-level association measures exist. A critical aspect of some newer methods is to utilize individual genotype data from multiple variants to model a pathway-level effect, thus allowing different underlying models of disease risk to be tested. These methods are in contrast to those that test for enrichment of individual SNP-level effects. The interpretation of results from pathway analyses is dependent on the underlying assumptions of the pathway methods and the parameters used for each algorithm. Factors influencing the analysis include choices for SNP to gene assignment, pathway definition, summarization across genes and pathways and the model assumptions of the statistical methods. The challenge in finding the most informative model is how to adequately capture the complexity of the underlying genomic architecture when calculating pathway-level effects. The widely used enrichment-type methods are dependent on individual SNPs having independent main effects, because they first calculate individual SNP association measures and then combine these individual effects to calculate a pathway-level association measure. Our hypothesis is that methods utilizing multi- variant models to calculate gene- or pathway-level effects better represent the underlying genetic complexity. Such methods are underutilized in psychiatric genetics to date. Therefore, we investigated approaches that utilize the original genotype data as input, rather than individual SNP p-values, to test for association between pathways and a trait of interest. We will discuss the differences in performance across these methods and their impact on the resulting determination of significant pathways in relation to the ADHD cohorts within the Psychiatric Genetics Consortium. FUNCTIONAL STUDIES OF ADHD CANDIDATE GENES Jan Haavik1 1 University of Bergen Individual Abstract Genome wide association studies and DNA sequencing are gradually revealing genetic markers that are associated with psychiatric disorders. Reported relative risks have been small and the strongest associations have been reported for large copy number variants spanning many genes and intergenic or intronic SNPs variants. As each variant contributes small effects across many different phenotypes, it is unclear how they relate a particular symptom or diagnosis, e.g. if there are any “true” schizophrenia or ADHD genes. It is often unclear which genes or biological systems that are affected, if the variants represent gain or loss of function, altered temporal or spatial expression patterns and how they interact with other genetic or environmental factors. Moreover, given the large number of variants in the human genome, it is difficult to distinguish relatively “silent” versus pathogenic variants. All these questions need to be addressed to understand how particular DNA variants trigger events at the molecular, cellular and organism level that ultimately lead to observable phenotypes and clinical syndromes. Together, this indicates that elucidation of disease mechanisms constitutes an even larger challenge than finding the genetic markers. It also implies that a variety of different experimental and statistical tools are needed, depending on the nature of the variations and which aspects of function that are addressed. In my talk I will briefly review some of these approaches and show recent examples from our group where we have investigated the effects of missense variants in ADHD candidate genes found by GWAS and sequencing. At the molecular level, communication in the nervous system is mainly performed by proteins and through complex regulation of protein-protein interactions. We have been studying regulatory protein complexes involved in serotonin and catecholamine signaling, including the family of 14-3-3 proteins that are highly expressed in the nervous system and interact with hundreds of target proteins, implicating them in many different cellular pathways. We have established a pipeline of methodology for analyzing the effects of multiple nonsynonymous variants in these proteins. This includes biochemical studies, in silico modeling and molecular systems biology approaches. Many computational tools have been proposed to predict the effects of SNPs and prioritize variants for further studies. While homology modeling using high resolution NMR- or X-ray structures sometimes can be used to predict functional outcomes, we have shown that commonly used “mutation prediction” softwares such as PolyPhen or SIFT etc. are of limited value and may produce misleading results. This is an area where improved methods are needed to assess the role of genetic variants. As many disease associated variants act in concert with other macromolecules, particular attention should be on developing tools to predict effects on molecular interactions. TELOMERES AND TELOMERASE IN MOOD DISORDER: MARKERS FOR RISK AND TREATMENT? Chair: Catharina Lavebratt, Karolinska Institutet Overall Abstract Details Recent findings propose that telomeres are altered in psychiatric disorders. Telomeres are protective DNA-protein complexes that form the chromosome ends, which shorten progressively during each cell division. Telomere shortening is a hallmark of aging and has been associated with oxidative stress, inflammation, and recently, psychological stress and psychiatric disorders. In psychiatry, telomeres have so far primarily been studied in blood leukocytes and with regard to length of the telomeres. Shorter blood leukocyte telomere length (LTL) has been reported in internalizing disorders including depression, anxiety and PTSD. Altered LTL has been reported also in schizophrenia. This symposium will focus on data from leukocytes and from the hippocampus, a region with active telomerase which counteracts the telomere shortening by adding oligonucleotides to the chromosome ends. A recent study revealed that disruption of hippocampal telomerase activity led to depressive behavior in mice, while the antidepressant fluoxetine unregulated telomerase activity. Also, elevation of telomerase activity has been reported to correlate with treatment response to SSRI in depressed patients. Further, a recent study implicated long-term lithium treatment to protect against telomere shortening in blood leukocytes. Mammalian telomeres are coated by capping proteins, known as shelterin. Shelterin is a six-protein complex with compelling evidence for involvement in telomere protection and regulation of telomerase activity. Dysfunctional telomeres may result from either removal of shelterin components or excessive attrition due to telomerase deficiency. We will present telomere length studies in large cohorts, but also findings regarding mechanisms regulating telomerase. TELOMERES AND PSYCHIATRIC DISORDERS: AN OVERVIEW Catharina Lavebratt1 1 Karolinska Institutet Individual Abstract This talk will review telomere biology in relation to already published findings in psychiatry as well as to somatic disorders. Studies have during the last 7 years generated compelling findings proposing telomere dysfunction in mood disorders and schizophrenia. Telomeres are DNA nucleoprotein complexes capping the ends of linear eukaryotic chromosomes, which protect the latter from cellular erosion and fusion with each other. However, telomeres erode progressively with each cell division, partly because of the end replication problem and also because of oxidative stress, finally signaling cellular senescence and apoptosis. Key factors in the protection against telomere shortening include the enzyme telomerase which elongates the telomere, and the shelterin protein complex which 'caps' and stabilizes the telomere ends, and regulates telomerase activity. Telomerase activity has been positively linked to antidepressant effects and hippocampal neurogenesis. Critically short telomeres cannot recruit their associated proteins, leaving the chromosome ends ‘uncapped’. Short telomere length has been associated with mood disorders, increased all-cause mortality and somatic disorders including diabetes mellitus, cardiovascular diseases, dementia and osteoporosis, whereas lithium treatment of bipolar patients was proposed to associate with longer leukocyte telomeres. The pathophysiological role, and mechanisms, of telomere dysregulation in mood disorders and their treatment are yet to be explored. TELOMERE LENGTH AND DEPRESSIVE AND ANXIETY DISORDERS Brenda Penninx1, Josine Verhoeven1 1 VU University Medical Center Individual Abstract Introduction: Patients with Major Depressive and Anxiety disorders have an increased onset risk of aging-related somatic diseases such as heart disease, diabetes, obesity and dementia. This might be the consequence of accelerated cellular aging, which can be indexed by a shorter length of leukocyte telomeres. We determined whether these psychiatric disorders are associated with shorter telomeres and whether specific disease characteristics influence this association. Methods: Data are from a total of 2981 subjects (mean age 41.6 years, 66.8% female) from the Netherlands Study of Depression and Anxiety. The sample consisted of 1881 current MDD and/or anxiety patients, 518 remitted MDD and/or anxiety patients and 582 control subjects without any lifetime psychiatric disorder based on the Composite International Diagnostic Interview. Telomere length (TL) was assessed as the telomere sequence copy number (T) compared to a single-copy gene copy number (S) using quantitative polymerase chain reaction (qPCR). This resulted in a T/S ratio and was converted to base pairs (bp). Results: Compared to control subjects (mean bp=5506), adjusted TL was shorter among current MDD patients (p=.03), remitted MDD patients (p=.04) and current anxiety patients (p=.003). Adjustment for sociodemographics, health and lifestyle variables did not reduce associations. Higher depression severity (p<.01), longer symptom duration in the past 4 years (p=.01) and higher anxiety severity (p<.01) were associated with shorter TL. Conclusions: Our results demonstrate that depressed and anxious patients show accelerated cellular aging according to a “dose-response” gradient: those with the most severe and chronic symptoms of depression or anxiety showed the shortest telomere length, representing 7-10 years of advanced cellular aging compared to controls. We also confirmed the imprint of past exposure to depression as those with remitted MDD had shorter telomere length than controls. DEPRESSION AND SHORT TELOMERES: ASSOCIATION TO ALTERATION IN SHELTERIN AND TELOMERASE Yabin Wei1, Lina Martinsson1, Yvonne Forsell2, Martin Schalling2, Lena Backlund2, Catharina Lavebratt2 1 Karolinska University Hospital, 2Karolinska Institutet Individual Abstract Mammalian telomeres are protective DNA-protein complexes that form the chromosome ends, which shorten progressively during each cell division. A number of studies reported shorter blood leukocyte telomere length (LTL) to be associated with major depression, but whether telomere length (TL) is shorter in brain and whether levels of telomere protective proteins, known as shelterin, are associated with depression have never been investigated. Further, long-term lithium treatment was previously reported to protect against LTL shortening, but how remains elusive. In the hippocampus region, TL, shelterin expression, and telomerase expression and activity were compared between: 1) a genetic rat model of depression-like behavior (the Flinders Sensitive Line; FSL) and its controls (the Flinders Resistant Line; FRL), and between 2) naïve FSL and lithium-treated FSL. In addition, we assessed if rs2736100 in hTERT associated with depression and number of depressive episodes in cohorts of unipolar depression and bipolar disorder (BP), respectively. Finally, by using human whole saliva DNA we compared the TL between unipolar depression patients and healthy controls, and tested the TL correlation between whole saliva DNA and blood leukocyte DNA. The naïve FSL, compared to FRL, exhibited shorter hippocampal TL, which associated with down regulation of Terf2, Rap1 and Tert expression and reduced telomerase activity. Lithium treatment rescued the Tert expression and telomerase activity in the FSL. Rs2736100 associated with a unipolar depression diagnosis and with number of depressive episodes in BP. Saliva TL was decreased in depression patients compared to the healthy controls, and it correlated positively with TL in blood leukocytes. This is the first report on shelterin in psychiatric disorder and on lithium’s mechanism in protection against telomere shortening. We also provide the first finding of hTERT variation associated with depression. VARIABLE TELOMERE LENGTH ACROSS POST-MORTEM HUMAN BRAIN REGIONS AND SPECIFIC REDUCTION IN THE HIPPOCAMPUS OF MAJOR DEPRESSION Adolfo Sequeira1, Firoza Mamdani1, Marquis Vawter1, William Bunney1 1 University of California Irvine Individual Abstract Stress and depression have been associated reduced neurogenesis and hippocampal volume in animal and in human studies. Telomere shortening has been observed in blood lymphocytes in depressed patients in some but not all studies while a post-mortem brain study using occipital cortex tissue did not observe any reduction of telomere length in depression. We hypothesized that because telomere length is the result of the balance between dividing and non-dividing cell telomere degradation, variable telomere length might be observed across brain regions and that telomere length might be reduced in psychiatric disorders as a consequence of stress mediated accelerated cellular aging. Postmortem human brains (N=40; 10 per diagnosis) obtained through the UCI brain bank were dissected and used to extract DNA. Telomere length was quantified using Q-PCR and compared to a single copy gene (t/s) in several brain regions (dorsolateral prefrontal cortex (DLPFC), hippocampus, amygdala, nucleus accumbens and substantia nigra (SN)) in major depressive disorder (MDD), bipolar disorder (BP), schizophrenia (SZ) and control subjects. We observed significant differences in telomere length across brains regions, suggesting variable levels of cell aging, with SN and hippocampus having the longest telomeres and the DLPFC the shortest. Also, a significant decrease in telomere length was observed specifically in the hippocampus of MDD subjects even after controlling for age. Our results suggest accelerated cellular aging in depression specifically in the hippocampus. BEYOND BONFERRONI: LARGE SCALE INFERENCE FOR COMPLEX DISORDERS Chair: Peter Visscher, University Of Queensland Overall Abstract Details Complex traits and disorders such as schizophrenia are associated with the effects of multiple genes. These disorders often cluster in families, have no clear-cut pattern of inheritance, and have a high fraction of phenotypic variance attributable to genetic variance (high heritability). It is becoming clear that many genes influence most complex traits and disorders. In such a scenario with a very high number of risk genes, each gene has a tiny effect. This makes it difficult to determine an individual’s risk, and to identify disease mechanisms that can be used for development of new effective treatments. Genome-wide association studies (GWAS) have identified many traitassociated single nucleotide polymorphisms (SNPs), but so far these explain only small portions of the heritability of complex disorders. This “missing heritability” has been attributed to a number of potential causes. However, it has been shown that a large proportion of the missing heritability exists GWAS data when associations of SNPs are examined in aggregate. This implies that there are very many common variants each with small genetic effects. These effects cannot be reliably detected with traditional GWAS statistical methods given realistic sample sizes. Thus, there is a need for innovative statistical approaches to identify polygenetic effects and to reduce the proportion of ‘missing heritability’. We describe recent GWAS results and novel statistical tools that are designed for polygenic traits. These methods enhance gene discovery, improve replication rates of discovered risk variants, and improve estimates of polygenic risk. The basic framework relies on a simple model that assumes a large proportion of loci are either null (unassociated with the phenotype of interest) or have negligible effects, but that a small proportion have larger (though still small) effect sizes. The first talk (A. Schork) outlines relevant statistical aspects of this model as applied to PGC schizophrenia (SCZ) GWAS data. The second talk (O. Andreassen) presents a genetic pleiotropy-informed method to improve power to identify new loci associated with SCZ. The third talk (S.H. Lee) presents an extension of a recent two-trait approach to a multiple trait model and applies multi-trait genomic best linear unbiased prediction (MTGBLUP) for individual risk prediction. The fourth talk (M. Reimers) describes an empirical Bayes algorithm to integrate various kinds of genomic data, and selects one or a few specific SNPs within wide loci implicated by GWAS, and further identifies many more loci than GWAS alone. The Discussant (N. Wray) will provide an overview of how these statistical methods and results reflect current understanding of complex diseases and potential future directions of statistical methodological research. MIXTURE MODELS AND REPLICATION EFFECT SIZES Andrew Schork1, Wesley Thompson1, Yunpeng Wang1, Anders Dale1 1 University of California, San Diego Individual Abstract This talk outlines the relevant statistical aspects of our mixed model approach to statistical inference as applied to GWAS data. This talk also describes a novel resampling algorithm for estimating posterior effect sizes directly. Model parameters estimated from this resampling algorithm can also be used to estimate the posterior probability that a given locus is null given its observed test statistic, termed the local false discovery rate (fdr). Applying this methodology to the Psychiatric Genetics Consortium SCZ GWAS data demonstrates that a simple scale mixture of normal model fits replication effect sizes very closely, with strong implications for tagged heritability, power for gene discovery, and power for estimation of polygenic risk. LEVERAGING PLEIOTROPY TO IMPROVE GENE DISCOVERY AND EFFECT SIZE ESTIMATION Ole Andreassen1 1 University of Oslo Individual Abstract We have developed a new statistical framework leveraging genetic pleiotropy to improve discovery and effect size estimation. This is based on a genetic pleiotropy-informed method to improve gene discovery using genome-wise association study (GWAS) summary statistics data (Andreassen et al, 2014). This methodology was used to identify new loci associated with psychiatric disorders, which are highly heritable disorders with significant missing heritability. Bipolar disorder and schizophrenia have overlapping clinical characteristics, and are both regarded as polygenic complex disorders. We applied the new statistical framework to boost the discovery of new genes, using nonoverlapping summary stats results. The new tools provided 3-4 times increased discovery rate of common gene variants in schizophrenia and bipolar disorders. These discoveries also have a high replication rate. The new statistical tools can also be used to investigate polygenic overlap between neurological disorders and psychiatric phenotypes. We leveraged the pleiotropy between multiple sclerosis and schizophrenia and bipolar disorders, and discovered a strong genetic overlap between multiple sclerosis and schizophrenia but not bipolar disorders. Follow up analyses revealed that most of the overlap was located in HLA alleles, possibly distinguishing between bipolar disorder and schizophrenia. Further, the effect of five overlapping HLA variants were opposite in multiple sclerosis and schizophrenia. Epidemiological and clinical studies suggest co-morbidity between schizophrenia and cardiovascular disease (CVD) risk factors, including systolic blood pressure, triglycerides, low and high-density lipoprotein cholesterol, body mass index, waist-hip-ratio, and type 2 diabetes. Applying a novel conditional false discovery rate method, we identified more than 25 loci associated with schizophrenia at a conditional fdr level of 0.01. Of these, 10 loci were associated with both schizophrenia and CVD risk factors, mainly triglycerides, low and high-density lipoproteins cholesterol, but also waist hip ratio, systolic blood pressure, and body mass index. Recently, we have applied the new tools to investigate the pleiotropy between immune-mediated diseases and schizophrenia, providing strong evidence for overlapping genes and thus strengthening the immune component of schizophrenia pathophysiology. We have also recent results providing strong evidence for overlapping common variants in schizophrenia and prefrontal cortex area obtained from MRI GWAS. Together these findings demonstrate an important role of pleiotropy in psychiatric disorders, and show how we can leverage polygenic pleiiotropy to provide better understanding of the polygenic architecture of psychiatric disorders. Andreassen OA, Thompson WK, Dale AM. Boosting the Power of Schizophrenia Genetics by Leveraging New Statistical Tools. Schizophr Bull. 2014 Jan;40(1):13-7. JOINT ANALYSIS OF PSYCHIATRIC DISORDERS INCREASES ACCURACY OF RISK PREDICTION FOR SCHIZOPHRENIA Sang Hong Lee1, Gerhard Moser1, Guo-Bo Chen1, PGC-CDG NA, Naomi Wray1 1 The University of QueenslandIndividual Abstract Most common diseases are highly polygenic and each variant explains only a small proportion of the genetic variation. Therefore, the accuracy of risk prediction is low even when using a polygenic approach. A major factor determining how well a polygenic model can predict a trait value in an independent sample is the sample size of the training data. Using more individuals will provide more information about the effect of a specific SNP. Another way to increase information about SNP effects is to incorporate information from correlated traits. Using a bivariate linear mixed model, we recently demonstrated significant shared genetic factors across five psychiatric disorders (schizophrenia, bipolar disorder, major depression, autism and ADHD) from the Psychiatric Genomics Consortium (PGC). Here we extend our two-trait approach to a multiple trait model and apply multi-trait genomic best linear unbiased prediction (MTGBLUP) for individual risk prediction. MTGBLUP is expected to be more powerful as it uses pleiotropy between disorders and simultaneously evaluates individual risk across disorders. We apply our model to the cross-disorders?) PGC GWAS data and show a significant increase of prediction accuracy of schizophrenia risk using MTGBLUP. We further demonstrate a relationship between functional annotated SNPs and increased prediction accuracy of SCZ. LEVERAGING GENOMIC INFORMATION TO INFORM GENETIC ANALYSIS Mark Reimers1, Kenneth Kendler2, Aaron Wolen2 1 Virginia Institute for Psychiatric & Behavioral Genetics, 2Virginia Commonwealth University Individual Abstract Risk SNPs for psychiatric disorders are likely to lie in DNA regions with large effects on gene regulation in the brain, which are a relatively small fraction of the genome. Several studies have shown that the majority of genetic variants currently implicated by GWAS for many diseases lie in open chromatin regions in the specific tissue relevant to the disease, or have other epigenetic marks indicative of function. We describe an empirical Bayes algorithm to integrate various kinds of genomic data with genetic data that selects one or a few specific SNPs within wide loci implicated by GWAS, and further identifies many more loci than GWAS alone. This approach makes use of information about regulatory regions of the genome obtained from the recently released ENCODE epigenetic data as well as using evolutionary conservation. We adopt an empirical Bayes formalism to accomplish the integration; the talk will discuss how to estimate the prior and conditional probabilities essential to make the method work. We illustrate the method on two notoriously difficult psychiatric disorders: schizophrenia and bipolar disorder, and identify hundreds of specific variants with high probability of association with each. We validate the predictions of the method on data from independent genetic studies. Follow-up studies confirm that the Bayesian posterior probabilities of risk for SNPs are indeed accurate; and confidence intervals are available. We show how to combine GWAS results with several different types of genomic information in an extensible and flexible manner to obtain much greater power in psychiatric genetic studies. INDUCED PLURIPOTENT STEM CELL MODELLING IN AFFECTIVE DISORDERS AND PSYCHOSIS Chair: Melvin McInnis, University of Michigan Overall Abstract Details Neurons and glial cells derived from induced pluripotent stem cells (iPSC) provide an opportunity to study functional cellular models from individuals affected with neuropsychiatric disorders. One of the major limitations in the study of these conditions is limited access to the primary organ (brain) tissue, which may be at least partially overcome by iPSC technology. These models will provide new information on gene expression patterns at sequential stages of differentiation; developmental patterns and predictors of functional capacity may be identified by studying expression profiles at specific culture times. Electrophysiological analyses of the cell and cell networks can be studied and compared; the cellular microenvironment perturbed and analyzed, and the metabolite profile of the cell culture supernatants examined. The coordinated study of the genetics, biochemistry, and physiology of iPSC derived neural cells thus provides a window on brain organization. This symposium will present and discuss the current status of induced pluripotent stem cell modeling in the affective disorders and psychosis. The genetic basis of such disorders is clearly established; however there is considerable heterogeneity in the genetic findings. There are no established pathogenesis, etiology, or anatomical substrates, and there is a critical unmet need for informative models that will lead to more efficacious treatments. Data and analyses will include expression patterns from iPSC cells and derived neurons at sequential stages of development, the undifferentiated iPSC and neurons and glial cells derived from the iPSC. Gene expression between control and affected neurons are remarkably similar, but neurons differentiated from them are different in their transcription factor expression pattern, in their expression of membrane receptors and ion channels. Interestingly, TF consistent with ventral neuronal cell fate (MGE) are increased in BP, and TF that control or maintain dorsal fate increased in neurons differentiated from control iPSC. Independent electrophysiological studies are emerging that suggest differences in action potentials in bipolar derived neurons vs controls. Methods and results to be presented include voltage clamp and calcium transient studies that are suggest altered excitability of the bipolar derived neuron, and co-culture with lithium affects BP and C neurons differently. Analysis of the supernatants from BP and C neuronal cultures also consistent identify fundamental biological differences in the cells. The plasticity of bipolar derived neurons appears to be less compared to control neurons. We will present data from large scale screening of small molecules in iPSC cells to demonstrate the feasibility of a large scaled approach to identify patterns of responses that may suggest novel treatment modalities.This approach will lead to prioritization of small molecules for testing on specific signaling pathways. LABEL-FREE OPTICAL IMAGING OF REPROGRAMMED BIPOLAR DISORDER PATIENTDERIVED CELLS TO INVESTIGATE LITHIUM RESPONSIVENESS Roy Perlis1, Jennifer Wang1, Steven Shamah2, Alfred Sun3, Stephen Haggarty1 1 Massachusetts General Hospital, 2X-Body, Inc., 3Stanford University Individual Abstract Cellular reprogramming may allow the disease biology of psychiatric disorders to be investigated using patient skin cells transdifferentiated to neurons. A major challenge in such efforts is the efficient identification and characterization of relevant cellular or molecular phenotypes. This presentation will describe the generation and investigation of induced neuron models of lithium response in bipolar disorder, based on fibroblasts from individuals with bipolar disorder as well as healthy control. We utilized a high-throughput, label-free imaging assay based on a nanostructured photonic crystal biosensor to characterize induced neurons from these three groups. In this assay, the signal generated is a measure of adhesion of the cell to the underlying surface, allowing quantification of changes in cell count, morphology, and adhesion over time. Cells drawn from lithium-responsive individuals differed significantly from those drawn from lithium-nonresponsive individuals. In addition to discussing these results, more general methodologic challenges - including substantial effects of age and sex, as well as inter individual variability - will be discussed, and their implication for future cellular modeling efforts. Our results suggest the possibility that this platform may be useful in development of high-throughput approaches to drug discovery, but also highlight the major methodologic challenges in applying cellular reprogramming to understand psychiatric illness. REGULATION OF NEURONAL DEVELOPMENT BY RISK GENES FOR MENTAL DISORDERS Guo-Li Ming1 1 Johns Hopkins University Individual Abstract Schizophrenia and affective disorders are chronic and generally disabling brain disorders with a prominent genetic basis and with neurodevelopmental origin. A number of susceptibility genes have been identified, including DISC1, neuregulin, COMT, FEZ1. How dysfunction of these genes leads to aberrant neural development and contribute to the pathology of the disorder is largely unknown. DISC1 is by far the best-characterized risk genes for schizophrenia and other major mental disorders, and almost nothing is known about its function in human neural development. To understand how mutation of DISC1 gene in patients impacts the development of human neurons, we generated iPSC lines from multiple patients from one family with a DISC1 mutation and we are able to differentiate these iPSCs into forebrain neurons in high efficiency. I will discuss our recent findings on the roles of DISC1 in morphological developmental and synaptic development of human neurons derived from patient specific iPSCs. HIGH THROUGHPUT SMALL MOLECULE SCREENS ON IPSC-DERIVED CELLS Sevilla Detera-Wadleigh1, Liping Hou2, Xueying Jiang2, Nirmala Akula2, David Chen2, Barbara Mallon3, Nahid Tayebi4, Winston Corona2, Layla Kassem2, Ellen Sidransky5, Marc Ferrer6, Francis McMahon2 1 National Institute of Mental Health, NIH, 2Human Genetics Branch, NIMH/NIH, 3NIH Stem Cell Unit, NINDS/NIH, 4Neurogenetics Section, NHGRI/NIH, 5Molecular Neurogenetics Section, NHGRI/NIH, 6 Division of Preclinical Innovation, NCATS/NIH Individual Abstract Bipolar disorder (BD) is a complex neuropsychiatric disease marked by debilitating episodes of mania and depression afflicting approximately 1% of studied populations. Recent genomewide association studies on large samples have identified BD-associated genetic variants, potentially representing risk loci. Two major challenges in understanding the biological underpinnings of BD include: a) determining how risk loci function to confer aberrations in mood, and b) developing novel, effective, fast-acting, and better-tolerated therapeutic agents. Recent advances in cell biology offer a unique and unprecedented opportunity to conduct functional studies on a patient’s own neural cells generated through induced pluripotent stem cell (iPSC) technology. These new templates permit discovery of distinct cellular phenotypes that would facilitate the search for novel, fast-acting and bettertolerated therapeutic agents. Novel agents could benefit patients, particularly those unresponsive to the existing mood stabilizers, such as lithium and valproate (VPA). We have developed an assay system based on viability of human iPSC-derived neural stem cells after challenge with a drug known to induce neuropsychiatric disturbances in humans. Unlike terminally-differentiated neurons, neural stem cells are renewable and expandable. Drug challenge is performed using mefloquine, an anti-malarial drug widely reported to cause psychiatric disturbances, including mania and psychosis, particularly in individuals with a preexisting psychiatric condition. In preliminary studies, we found that mefloquine destroys the viability of iPSC-derived neural stem cells, and that lithium and VPA, at therapeutic levels, exert a neuroprotective effect on cell viability. To our knowledge, this is the first study of neuroprotection by mood stabilizers in human iPSC-derived neural stem cells after challenge by a psychiatric symptominducing drug. The assay is amenable to a high throughput format and in collaboration with the National Center for Advancing Translational Sciences (NCATS) at NIH, we are poised to screen three large collections of small molecules to identify compounds that mimic the neuroprotective effect of lithium and VPA in our model system. Gene expression profiles reveal the molecular repertoire related to various drug treatments in neural stem cells. Compounds that mimic the neuroprotective effects of lithium and/or VPA will be strong candidates for further evaluation as novel mood stabilizing treatments for patients with bipolar disorder. INTERNEURON DYSFUNCTION IN IPSC MODELS OF BIPOLAR DISORDER Melvin McInnis1, Sue Oshea1, Monica Bame1, Cindy Delong1, Aislin Williams1 1 University of Michigan Individual Abstract Bipolar disorder (BP) affects millions of individuals worldwide, yet progress in understanding its genesis and improving treatments has been hampered by the lack of viable cell models. Patient-derived induced pluripotent stem cells (iPSC) now offer the opportunity to study the development of neural tissues and the prospect of identifying novel disease mechanisms in BP. We have derived iPSC from three individuals with BP and three healthy controls and differentiated them into telencephalic neurons. RNAs were extracted from undifferentiated iPSC and neurons derived from them and microarray analysis carried out. Expression of transcription factors that convey regional neuronal cell fate was significantly different between the two groups. Neurons derived from control iPSC expressed transcripts that confer dorsal telencephalic fate, while neurons derived from BP iPSC expressed genes involved in the differentiation of ventral (MGE) brain regions. During development, the majority of cortical interneurons originate in the MGE, undergo tangential migrations to their adult cortical locations where they form a variety of inhibitory GABAergic interneurons. Although only 20% of the total number of cortical neurons, interneurons play a critical role in maintaining the normal balance in cortical activity by making local synapses on long-projecting excitatory (glutamatergic) pyramidal neurons. Consistent with the increase in transcripts involved in interneuron cell fate, GABA expression by BP vs C neurons was elevated throughout the culture period. To determine if the phenotype could be altered, cells have been exposed to ventralizing agents (purmorphamine) or dorsalizing agents (lithium) and are being evaluated using PCR, western blot and immunohistochemistry. We have found that iPSC from both BP and controls are responsive to patterning cues, increasing expression of NKX2-1 (ventral identity) or EMX2 (dorsal). Since interneuron dysfunction has been suggested to underlie a number of neurodevelopmental and neuropsychiatric conditions, alterations in the specification or function of GABAergic interneurons would be expected to permanently disrupt the excitatory-inhibitory balance in the cortex, contributing to BP. 6:00 PM - 8:00 PM Symposia Sessions SHARED GENETICS BETWEEN DEPRESSION AND COMORBID PHYSICAL CONDITIONS Chair: Margarita Rivera, Institute of Psychiatry, King's College London Overall Abstract Details Major depressive disorder (MDD) or depression is a highly prevalent and heterogeneous mental disorder. It is a major public health problem and one of the leading causes of disease burden and disability in adults worldwide. There is growing evidence suggesting that rates of physical conditions, such as obesity, diabetes, migraine and cardiovascular disorder are increased among people with depression. Mortality rates are elevated in people with depression, mainly due to comorbid physical conditions. These people are also less likely to receive standard levels of health care for most of the comorbid physical conditions. Besides, both depression and physical conditions are associated with substantial individual and societal economic costs. Shared genetic effects (genetic pleiotropy) may contribute to the link between depression and comorbid physical conditions. Phenotypic heterogeneity of MDD may play a role in this relationship, as different clinical subtypes may be characterized by a partially distinct genetic liability. The relationship between depression and comorbid physical conditions may therefore differ when considering the specific clinical subtypes as compared to the overall MDD diagnosis. To further explore the contribution of shared genetic factors to the association between depression and certain physical conditions (BMI, migraine, inflammation and autoimmune disorders), we performed several strategies based on genome-wide data including Genome Polygenic Risk Scoring (GPRS), Genomic-Relatedness-Matrix Restricted Maximum Likelihood (GREML) and SNP Effect Concordance Analysis (SECA). Our findings have important implications for studies investigating shared genetic effects of depression and physical conditions, and highlight the importance of using novel statistical genetic strategies in order to disentangle the observed comorbidity. ESTIMATION OF THE GENETIC CORRELATION BETWEEN MAJOR DEPRESSIVE DISORDER AND BODY MASS INDEX USING COMMON GENETIC VARIANTS Margarita Rivera1, Chi-Fa Hung2, Nick Craddock 3, Michael J. Owen3, Martin Preisig4, Stefan Kloiber5, Bertram Müller-Myhsok 5, Susanne Lucae5, Florian Holsboer5, Oliver S.P. Davis 6, Gerome Breen7, Ian W. Craig7, Cathryn M. Lewis 7, Anne E. Farmer 7, Peter McGuffin7 1 King's College London, 2Kaohsiung Chang Gung Memorial Hospital and Chang Gung University College of Medicine, 3Cardiff University, 4Lausanne University Hospital, 5Max-Planck-Institute of Psychiatry, 6UCL Genetics Institute, University College London, 7MRC Social Genetic and Developmental Psychiatry Centre, Institute of Psychiatry, King's College London Individual Abstract Background: Both obesity and major depressive disorder (MDD) are prevalent in developed countries and cause huge disease burden. Previous studies have shown strong association between obesity and MDD but why they cluster together remains unclear. Given the high heritability of both disorders it is worth considering that the clustering of MDD and obesity might be partly mediated by common genetic factors. We aimed to investigate the phenotypic variance of body mass index (BMI) and MDD explained by genetic variance captured by genome-wide association studies (GWAS) data and genetic correlation between BMI and MDD using GREML (Genomic-Relatedness-Matrix Restricted Maximum Likelihood) analysis. Methods: The sample consists of 3,872 unrelated individuals from the RADIANT study, and another 1,645 individuals from the Munich depression study. DSM-IV or ICD-10 diagnosis of MDD was ascertained using the Schedules for Clinical Assessment in Neuropsychiatry (SCAN) interview. The controls were screened for lifetime absence of any psychiatric disorder using a modified version of the Past History Schedule and the Composite International Diagnostic Screener, respectively. All the individuals were genotyped using the Illumina HumanHap610-Quad BeadChip (Illumina, Inc., San Diego, CA, USA). BMI was defined as weight in kilograms divided by height in meters squared (kg/m2). We performed univariate and bivariate GREML analysis using the GCTA (Genome-wide Complex Trait Analysis) software package. Results & Conclusions: We found in the combined Radiant and Munich sample that the phenotypic variance accounted for by common SNPs was 15% for BMI (s.e=0.09, p=0.04) and 33% for MDD (s.e=0.08, p=5x10-6). There was also evidence of genetic correlation between BMI and MDD (rG=0.40, s.e=0.23, p=0.08) suggesting that a genetic overlap may contribute to the association between MDD and high BMI. The results confirm that both BMI and MDD are heritable with a significant proportion of phenotypic variance explained by the additive genetic effects of common SNPs. PHENOTYPIC HETEROGENEITY OF MDD: DISTINCT GENETIC LIABILITY FOR MDD SUBTYPES? Yuri Milaneschi1, Femke Lamers1, Dorret Boomsma2, Brenda Penninx1 1 VU University Medical Center/GGZ inGeest, 2VU University Individual Abstract Introduction Phenotypic heterogeneity of Major Depressive Disorder (MDD) may contribute to discrepant or blurred effect sizes in large collaborative genetic studies. Studies based on data- driven techniques have confirmed that depressed populations can generally be divided into a ‘typical’ (a.k.a. ‘melancholic’) and an ‘atypical’ subtype, differentiated mainly by the direction of change in vegetative symptoms and associated with distinct biological correlates and specific genetic variants. We hypothesized that MDD subtypes may be characterized by a partially distinct genetic liability. We preliminary tested this hypothesis by comparing genomic profile risk scores (GPRS), derived from large discovery cohorts, for psychiatric (MDD, schizophrenia, bipolar) and somatic (CRP-inflammation, BMI) disorders across MDD subtypes in a Dutch target sample. Methods: The target sample is represented by 1649 MDD patients from the Netherlands Study of Depression and Anxiety (NESDA) and 1810 screened controls mainly from the Netherlands Twin Registry (NTR). Autosomal SNPs were genotyped on the Affymetrix 6.0 Human Genome-Wide SNP Array. Depression diagnoses are based on DSM-IV criteria and MDD subtypes (severe melancholic and severe atypical) are derived from latent class analyses applied to MDD endorsed symptoms. GPRS were generated based on meta-analyses results from the Psychiatric Genomics Consortium (PGC) for MDD, schizophrenia (SCZ) and bipolar disorder (BIP), from the Cohorts for Heart and Aging Research in Genomic Epidemiology (CHARGE) Consortium for CRP, and from the Genetic Investigation of Anthropometric Traits (GIANT) consortium for BMI. Results: Overall MDD diagnostic status was significantly predicted by the GPRS for psychiatric disorders but not for CRP and BMI. Results suggested differential patterns of association between specific GPRS and MDD sub-phenotypes, with SCZ being most strongly associated with the melancholic subtype and BMI with the atypical subtype. Conclusions Preliminary evidence suggests differential polygenic signature across MDD clinical sub-phenotypes. We planned to confirm these findings by using complementary techniques (SNP Effect Concordance Analysis, SECA) and by including additional cohorts in order to achieve the adequate statistical power to compare single genetic variants across MDD subtypes and to estimate their (co)heritability via genomic-relationship-matrix restricted maximum likelihood (GREML) methods. The possibility to identify a more homogenous MDD phenotype may help future research on the genetic determinants of depression. INVESTIGATING THE ROLE OF PAIN IN DEPRESSION WITH GENETIC DATA Lannie Ligthart1, Dale Nyholt2, Brenda Penninx3, Cathryn Lewis4, Dorret Boomsma1 1 VU University, 2QIMR Berghofer Medical Research Institute, Brisbane, 3VU Medical Center, Amsterdam, 4King's College London Individual Abstract Patients with major depressive disorder (MDD) are known to have high rates of migraine and other pain symptoms. The mechanisms underlying this comorbidity have been debated for decades. Twin and family studies have shown there is a genetic correlation between migraine and depression, which may reflect a variety of underlying mechanisms, including pleiotropy, uni- or bidirectional causation, or a syndromic relationship. To further investigate these mechanisms, we applied several strategies based on genetically informative data, including a co-twin control design and crossdisorder prediction using polygenic scores and SNP effect concordance analysis (SECA). Questionnaire data on migraine, pain symptoms, anxiety and depression, and genotype data were collected in participants of the Netherlands Twin Registry and the Netherlands Study of Depression and Anxiety (NESDA). Cross-disorder genetic risk prediction was performed using GWA summary statistics from the UK RADIANT study on major depressive disorder (MDD) and the Australian Twin Migraine study (migraine). Our research showed that the presence of pleiotropic genetic effects alone is unlikely to explain the comorbidity of depression and migraine. The results suggest that the observed comorbidity is explained by a subset of individuals with both MDD and migraine, in whom the migraine may be a symptom or consequence of MDD. We speculate that in these patients, migraine might be viewed as a symptom of MDD, rather than a separate comorbid condition. Furthermore, our observation of a highly consistent pattern of comorbidity between depression and pain symptoms, regardless of anatomical site, is consistent with the hypothesis that not only migraine, but pain in general can arise as a symptom of MDD. Further analysis should elucidate whether our findings with respect to the genetic overlap of MDD and migraine can be generalized to MDD and pain in general. These findings have important implications for genetic studies of depression and comorbid pain conditions, and are particularly relevant to studies investigating cross-disorder genetic effects. UNRAVELING THE COMORBIDITY BETWEEN MAJOR DEPRESSIVE DISORDER AND THE AUTOIMMUNE DISORDERS – SHARED RISK ALLELES? Jack Euesden1, Andrea Danese1, Ian Scott1, Cathryn Lewis1 1 King's College London Individual Abstract BACKGROUND Comorbidity, the co-existence of two or more diseases in an individual, can provide an insight into the aetiology of many common disorders. Major Depressive Disorder (MDD) shows an unusual pattern of comorbidities; although no risk alleles have been identified for MDD via genome-wide association studies (GWAS), comorbidity can be a sign of genetic overlap – pleiotropy – between disorders. MDD is more common in autoimmune disorders such as Rheumatoid Arthritis (RA), Crohn’s Disease (CD) and Ulcerative Colitis (UC), than would be predicted by chance. Many theories for the aetiology of MDD have focused on the ability of abnormal inflammatory protein levels in the blood to influence mood – the ‘Cytokine Hypothesis’ - and so investigating the genetic overlap between MDD and autoimmune disorders may illuminate biological pathways underlying MDD. Furthermore, depression in RA patients is associated with worse pain, more functional disability and higher rates of healthcare utilization; establishing its cause in RA is therefore an important research goal. METHODS In order to investigate the genetic overlap between MDD and autoimmune disorders, we used a number of statistical genetics techniques, including Genome Profile Risk Scoring (GPRS) and bivariate Genome-Relatedness-Matrix Restricted Maximum Likelihood (GREML). We focused on MDD and RA, and expanded this to UC and CD, both of which include arthritis in their extra-intestinal symptoms. We performed GPRS, using GWAS results to construct polygenic risk scores in an independent test dataset. The RADIANT dataset contains GWAS data on 1,624 MDD cases and 1,588 screened controls. We can therefore test the predictive value of a genetic risk profile for an autoimmune disorder on MDD status. We calculated risk profiles for RA using GWAS results from the BIRAC and YEAR consortia, testing their prediction of MDD status using Nagelkerke’s Pseudo R2. We repeated this calculating risk profiles for Crohn’s Disease and Ulcerative Colitis using results from the Inflammatory Bowel Disorder Consortium. Finally, we used bivariate GREML to investigate the genetic correlation between MDD and RA. We used the WTCCC RA dataset in addition to the RADIANT MDD dataset, and implemented bivariate GREML in the GCTA software package. RESULTS & CONCLUSIONS In GPRS, there was no evidence for prediction of MDD status from RA polygenic risk scores (minimum pvalue 0.42). The GREML estimate for the genetic correlation between MDD and RA was non-significant (rG = 0.29, p = 0.094). We find no evidence for shared genetic risk between RA and MDD. This is supported by both GREML and GPRS, methods, whose assumptions we review. Our results have implications for the Inflammatory Cytokine hypothesis of MDD and indicate the extent to which GWAS datasets can be leveraged using newer statistical genetics techniques in order to dissect observed phenotypic correlations. A SMALL WINDOW TO PSYCHIATRIC GENETICS IN CHINA Chair: Chunyu Liu, University of Illinois at Chicago Overall Abstract Details This symposium selected four studies, including imaging genetics of schizophrenia, candidate gene study of schizophrenia, brain regulatory network study and gene- and pathway-based secondary analysis of large genome-wide association study (GWAS) data. Dr. Xue has worked on study of GABRB2 in Chinese schizophrenia for a decade, representing a focused research of candidate genes. Results of extensive molecular genetics, population genetics, evolutionary genetics, and epigenetics will be presented about GABRB2's role in schizophrenia and relevant intermediate phenotypes. Dr. Yao and her collaborators studied the global brain connectivity variations in healthy siblings, comparing with that of schizophrenia patients and healthy controls, looking into the plasticity mechanism of those healthy siblings although they may share common genetic risks and environmental factors with patients. Connectivity variations and alternations in patients and their siblings will be presented. Dr. Chen and his collaborators used postmortem brain samples to study miRNA-mRNA regulatory network, and further identified novel regulatory pathway related to psychiatric diseases. Dr. Li and his collaborators developed gene and pathway-based methods to re-analyze GWAS data of psychiatric diseases. This study demonstrates that integrative analysis is important to characterizing genetic risk genes of complex diseases. Besides these studies presented in the Symposium, several posters about Autism and Schizophrenia studies in China will be presented in the conference. Altogether, they showcase the current psychiatric genetics researches in China. Chinese investigators welcome more collaborative researches, contributing not only samples and data but also original, innovative ideas on studies of psychiatric disorders in Chinese. GABRB2 IN SCHIZOPHRENIA AND BEYOND Hannah Hong Xue1 1 Hong Kong University of Science and Technology Individual Abstract Deciphering the molecular basis of schizophrenia is essential to effective management of this devastating mental disorder. Over the past decade, my research group has focused on the basic research on schizophrenia etiology through the discovery and characterization of a schizophrenia-associated gene – GABRB2, coding for GABAA receptor? 2 subunit. The association between schizophrenia and single nucleotide polymorphisms (SNPs) in introns 9 and 10 of GABRB2, first reported by my group (1), has been cross-validated for multiple ethnic groups (2, 3). Functional impacts of the schizophrenia associated non-coding SNPs in GABRB2 have been demonstrated at both mRNA and protein levels, viz. genotype-dependent alterations in mRNA expression and splicing, and effects of genotypes on isoform ratios and electrophysiological attenuation of GABAA receptors (4, 5). Through extensive molecular genetics, population genetics and evolutionary genetics characterizations, GABRB2 has been shown by us to be under strong positive selection (6), active recombination (7) as well as genomic imprinting (8), likely contributed to by a human lineage-specific insertion of an AluY transposable element. Our work on epigenetic regulation of GABRB2 revealed its developmental control and disruption in schizophrenia (9). Most recently, we have also extended GABRB2 association from psychotic disorders to social cognitions (10). Our work has thus improved current understanding of schizophrenia at molecular level centered at GABRB2, which represents at present one of the best characterized schizophrenia candidate genes. References: 1. Wing-Sze Lo, Ching-Fun Lau, Zhenyu Xuan, Anthony Chun-Fung Chan, Guo-Yin Feng, Lin He, Zhong-Chang Cao, Hua Liu, Qing-Ming Luan, and Hong Xue (2004) Association of SNPs and haplotypes in GABAA receptor ?2 gene with schizophrenia. Molecular Psychiatry 9(6): 603-608 2. TL Petryshen, et al. (2005) Genetic investigation of chromosome 5q GABAA receptor subunit genes in schizophrenia. Molecular Psychiatry 10:10741088 3. Wing-Sze Lo, Mutsuo Harano, Micha Gawlik, Zhiliang Yu, Jianhuan Chen, Frank Wing Pun, Ka-Lok Tong, Cunyou Zhao, Siu-Kin Ng, Shui-Ying Tsang, Naohisa Uchimura, Gerald Stoeber and Hong Xue (2007) GABRB2 association with schizophrenia: commonalities and differences between ethnic groups and clinical subtypes. Biological Psychiatry 61:653-660 4. Cunyou Zhao, Zhiwen Xu, Jianhuan Chen, Zhiliang Yu, Ka-Lok Tong, Wing Sze, Cario Lo, Frank Wing Pun, Siu-Kin Ng, ShuiYing Tsang, and Hong Xue (2006) Two isoforms of GABAA receptor β2 subunit with different electrophysiological properties: differential expression and genotypical correlations in schizophrenia. Molecular Psychiatry 11:1092-1105 5. Zhao, CY, Zhiwen Xu, Feng Wang, Jianhuan Chen, Siu-Kin Ng, Pak-Wing Wong, Zhiliang Yu, Frank W. Pun, Lihuan Ren, Wing-Sze Lo, Shui-Ying Tsang and Hong Xue (2009) Alternative-splicing in the Exon-10 region of GABAA receptor β2 subunit gene: relationships WHOLE BRAIN CONNECTIVITY STUDY IN SCHIZOPHRENIA PATIENTS AND THEIR HEALTHY SIBLINGS Yin Yao1, HongBao Cao2, Jinsong Tang3, Xiaogang Chen3 1 National Institutes of Health, 2NIMH, 3Xiangya Second Hospital Individual Abstract Background: Schizophrenia (SCZ) is a complex disease that has been hypothesized to arise from functional dysconnectivity of the brain. However, study results discovered various inconsistent abnormal connectivity alterations in SCZ patients. Recent work used both SCZ patients and their nonpsychotic siblings in SCZ studies to seek common abnormalities as biomarkers of this disease. To date, no researchers have compared the global alterations amongst SCZ patients, their healthy siblings and healthy controls. In this study, we investigate the global brain connectivity variations in healthy siblings, compare with that of SCZ patients and healthy controls, re-examining the compensative plasticity mechanism in healthy siblings Methods: Resting state functional magnetic resonance imaging (fMRI) data were collected from 107 study subjects, including 44 healthy controls, and 32 schizophrenia patients that are treatment-resistant, and 31 of their healthy siblings with no SCZ history. The whole brain was parcellated into 1000 brain networks using a fix point clustering (FPC) algorithm proposed by us. Connectivity features in the number of 500500 were analyzed, including both intra- and internetwork/region connectivity. Then the ANOVA analysis was independently conducted for each connectivity feature with 4 contrasts: C1, Cases, siblings and healthy controls; C2, Case vs. sibling; C3, Case vs. control; and C4, Sibling vs. control. Results: This work indicates that healthy siblings, while compared with the SCZ patients, presented connectivity variations involving greater than 60% of the whole brain regions. At the same level of significance, the healthy siblings exhibited little connectivity alteration in small brain regions in contrast with healthy controls. On the other hand, SCZ patients have great than 40% comparable brain regions that demonstrate connectivity variations in contrast with healthy controls; And those brain regions are partially overlapped with that of siblings/cases study. In addition, the changes observed between cases and controls in altered connectivity feature numbers are smaller than that of cases and siblings (less than a half). When evaluated using the multivariate classification approach, selected connectivity features provided the highest identification accuracies of 84.1%, 92.1% and 81.3% for C2, C3 and C4 respectively. Conclusion: Healthy siblings of individuals with SCZ demonstrate functional regulations within large area of brain regions. Although most of those changes are moderate in comparison with healthy controls, the majority of them show significance in sibling/case study, indicating that connectivity variations in SCZ patients and their healthy siblings are in different scales or even opposite directions. We thus postulate that those alterations in healthy siblings may be a form of virtuous compensative regulations preventing them from becoming ill. INTEGRATION OF MIRNA-MRNA NETWORKS TO ELUCIDATE THE COMPLEX OF PSYCHIATRIC DISORDERS Chao Chen1, Lijun Cheng2, Chunling Zhang3, Judith Badner3, Elliot Gershon3, Chunyu Liu3 1 Central South University, 2Northwestern University, 3The University of Chicago Individual Abstract MicroRNAs (miRNAs) are small, non-coding, endogenous RNAs involved in regulating gene expression and protein translation. One single miRNA can target multiple mRNAs and a single mRNA can be targeted by multiple miRNAs. We consider that miRNA-mRNA clusters with statistically significant associations can explore potentially regulatory mechanism and, therefore, of biological interest. In this study, we collected 89 parietal cortex samples from Stanley Medical Research Institute (SMRI). After quality control, each sample has 420 miRNA, 19,984 mRNA and more than 1,000,000 SNPs screened. We first constructed scale-free networks including both miRNA and mRNA, and found one module exhibited differential expression between controls and psychotic patients. In this module, mir-320e acted as one of the hub nodes. Quantitative Trait Locus (QTL) result also indicated mir-320e was regulated by genetic variants. Another hub gene, PDLIM5, was validated by five miRNA binding prediction software. To further investigate the causal relationship between PDLIM5 and mir-320e, we applied Network Edge Orienting (NEO) and found mir-320e regulates PDLIM5. In summary, we detected one classic regulation pathway: Genotype ->mir.320e -> PDLIM5 -> gene module -> psychosis, which can be partially explain the etiology of psychiatric disease. GENE- AND PATHWAY-BASED ASSOCIATION ANALYSES OF SHARED PSYCHIATRIC GENOMICS CONSORTIUM DATA Miaoxin Li1, Shu-Jui Hsu1, Pak Chung Sham1 1 The University of Hong Kong Individual Abstract Characterizing genetic risk factors of common psychiatric diseases is far from complete. Using gene and pathway as analysis units, i.e., the gene- and pathway-based association approaches, is potentially more powerful than the use of individual Single-nucleotide polymorphisms (SNPs) to identify weak genetic factors of complex diseases. In the present study, we applied the gene and pathway-based methods we developed (http://statgenpro.psychiatry.hku.hk/limx/kgg/) to re-analyze association p-values of SNPs from meta-analysis studies on multiple psychiatric diseases (including autism spectrum disorder, attention deficit-hyperactivity disorder, bipolar disorder, major depressive disorder, and schizophrenia) released by Psychiatric Genomics Consortium (PGC). This knowledgebased secondary analysis revealed a number of additional interesting genes and pathways significantly associated with psychiatric disorders. We also found that these genes show interesting co-expression patterns in brain-tissues and protein-protein interaction networks. While supporting the polygenic model of common psychiatric diseases, this study demonstrates that introducing genomic knowledge into conventional statistical genetic analysis is a powerful strategy to characterizing genetic risk genes of complex diseases. FOLLOWING A STRONG LEAD: FUNCTIONAL INVESTIGATION OF GWAS SIGNALS FOR SCHIZOPHRENIA Chair: Gary Donohoe, NUI Galway Overall Abstract Details Large-scale genome-wide association studies (GWAS) have been successful in identifying high confidence genetic susceptibility loci for schizophrenia, with more than 100 genomewide significant signals yielded to date. GWAS have additionally provided evidence for numerous other schizophrenia susceptibility loci that fall short of this significance threshold, which can be captured collectively though methods such as polygenic risk scoring. This symposium will feature four talks that span the gap between risk genotype and the clinical phenotype of schizophrenia. These will cover molecular, cellular, neuroimaging and neuropsychological investigations of GWAS signals for schizophrenia at both the individual variant and polygenic level. The first talk, given by Dr Nick Bray (Institute of Psychiatry, King’s College London), is entitled ‘Proximal genetic risk mechanisms for schizophrenia: effects of genome-wide significant risk variants on gene expression in the human brain.’ This talk will introduce fundamental ways in which genetic risk variants can impact on gene function, before describing largely unpublished work investigating the effects of several GWS schizophrenia risk variants (e.g. at AS3MT-CNNM2-NT5C2, TSNARE1, VRK2, CACNA1C and CACNB2) on the expression of these candidate genes in human brain. The second talk, given by Dr Colm O’Dushlaine (Broad Institute of Harvard and MIT), is entitled ‘Functional annotation and cellular phenotyping of disease-implicated variants’. This presentation will describe computational approaches (e.g. functional annotation and pathway analyses) and cellular approaches (e.g. assay of isogenic cell lines by multielectrode arrays) to elucidate molecular and cellular mechanisms underlying GWS associations with schizophrenia. The third talk will be given by Prof. Andreas Meyer-Lindenberg (Heidelberg University) and is entitled 'Neural mechanisms underlying genome wide significant associations with schizophrenia'. This will describe the application of imaging genetics to delineate neural correlates of both genome-wide significant common (ZNF804A, CACNA1C, MHC) and rare variants (with an emphasis on CNV). This work begins to define convergent mechanisms of risk for psychotic disorders, with an emphasis on medial prefrontal-limbic interactions. The final talk of the symposium will be given by Prof. Andrew McIntosh (Edinburgh University) and is titled ‘Cross-disorder and condition–specific cognitive effects of polygenic risk for psychosis’. This presentation will describe the effects of GWAS identified schizophrenia risk variants on cognition and cognitive ageing, and how these compare with the cognitive effects observed in other psychoses, major depression, ADHD and autism. PROXIMAL GENETIC RISK MECHANISMS FOR SCHIZOPHRENIA: EFFECTS OF GENOME-WIDE SIGNIFICANT RISK VARIANTS ON GENE EXPRESSION IN THE HUMAN BRAIN Nick Bray1 1 Institute of Psychiatry, King's College London Individual Abstract Large-scale genome-wide association studies (GWAS) have identified more than 100 high confidence risk loci for schizophrenia, but the molecular mechanisms that mediate these associations are largely unknown. In the absence of obvious effects on protein structure, many of these loci are likely to impact on schizophrenia risk by altering the expression of nearby genes. However, extensive linkage disequilibrium at many of the risk loci and long-range effects of regulatory elements make it difficult to confidently determine the genes that are affected. This talk will introduce fundamental ways in which genetic risk variants can impact on gene function and methods for testing association between risk genotype and gene expression. It will explain how the effects of genetic risk variants on gene expression can be specific to brain region and developmental stage, before describing largely unpublished work investigating the effects of several genome-wide significant schizophrenia risk variants (e.g. at ZNF804A, AS3MT-CNNM2-NT5C2, TSNARE1, VRK2, CACNA1C and CACNB2) on the expression of these candidate genes in the human brain. FUNCTIONAL ANNOTATION AND CELLULAR PHENOTYPING OF DISEASEIMPLICATED VARIANTS Colm O'Dushlaine1, Jen Pan1, Ralda Nehme1, Sulagna Ghosh1 1 Broad Institute Individual Abstract Technology advances and sample size increases over recent years have given rise to a large number of genome-wide significant associations to psychiatric disorders. These range from common (SNP) associations, to rare structural or rare single nucleotide variants. We describe computational and physical experiments that strive to elucidate causative functional mechanisms underlying regional associations to schizophrenia. Computational experiments extend from detailed functional annotation and constraint scoring (for example using scoring metrics such as Polyphen and CADD) to testing for enrichment of association by gene-based or pathway analyses. We summarize preliminary experiments extending from this, from applying genome editing technologies such CRISPR to establish isogenic stem cell lines carrying the identified variants, to developing cellular assays for phenotypic analysis of the derived neurons, such as using multi-electrode arrays for electrophysiological profiling. NEURAL MECHANISMS UNDERLYING GENOME WIDE SIGNIFICANT ASSOCIATIONS WITH SCHIZOPHRENIA Andreas Meyer-Lindenberg1 1 Central Institute of Mental Health Individual Abstract Recent advances in psychiatric genetics have provided an unprecedented amount of Information on Genome-wide significant both common and rare variants associated with schizophrenia, but the understanding of the neural mechanisms through which these genetic risk factors act is incompletely understood. In this contribution, we review recent work from our laboratory and collaborators to delineate neural correlates of both genome-wide significant common (ZNF804A, CACNA1C, MHC) and rare variants (with an emphasis on CNV). This work begins to define convergent mechanisms of risk for psychotic disorders, with an emphasis on medial prefrontal-limbic interactions. Interestingly, this circuit is also impacted by environmental risk factors associated with schizophrenia, such as urban upbringing and migration, suggesting that this circuit may also support, besides convergence of risk, gene-environment interactions. In initial support of this hypothesis, we report unpublished work that indicates that methylation in candidate genes associated with early social adversity further modulate both activation and connectivity in this circuit. POLYGENIC RISK OF MAJOR PSYCHIATRIC DISORDER, COGNITION AND COGNITIVE AGING Andrew McIntosh1, Toni Clarke1, Michelle Lupton2, Ian Deary1, David Porteous1, Lynsey Hall1, Caroline Hayward1 1 University of Edinburgh, 2 QIMR Berghofer Medical Research Institute Individual Abstract Introduction: Polygenic risk of schizophrenia is associated with reduced general cognitive ability and with a greater relative decline between age 11 and 73. The specificity of these findings to risk variants affecting schizophrenia is now known however. We sought to test whether risk variants influencing vulnerability to other forms of major psychiatric disorders (depression, bipolar disorder, major depression, ADHD and Autism) had convergent effects on cognition and cognitive ageing. Methods: We used data from a newly-available cohort, Generation Scotland (N=21516), the Lothian Birth Cohorts of 1921 and 1936 (N=1522) and the Brisbane Adolescent Twins Sample (N=902). Individuals were profiled using the latest public release from the Psychiatric Genomics Consortium Cross- Disorder GWAS. Polygenic risk profile scores were then tested for their association with cognition and cognitive ageing. Results: We found specific effects of polygenic risk for schizophrenia on cognition and cognitive ageing. In contrast, however, we found either no association for other mental disorders – or effects in the opposing direction (evidence of a positive association between polygenic risk an cognitive ability). Conclusions: Polygenic risk for major mental disorder influences cognition, general cognitive ability (IQ) and cognitive ageing. These effects are not uniform across all mental disorders. This suggests important differences between factors influencing vulnerability for major mental disorder and differing effects on brain function. NEW FINDINGS FROM THE ENHANCING NEURO IMAGING GENETICS THROUGH META-ANALYSIS (ENIGMA) CONSORTIUM Chair: Sarah Medland, Queensland Institute of Medical Research Overall Abstract Details In this session, we will provide an overview of recent findings from the ENIGMA consortium (http://enigma.ini.usc.edu) examining the genetic determinants of subcortical brain structure (MRI) and white matter (DTI). The ENIGMA Consortium first presented results to the WCPG last year in Boston and this year we will present the significant progress we have made since. Sarah Medland will chair the session and will give an overview of the underlying philosophy and long-term goals of the consortium. The second major phase of the ENIGMA Consortium meta-analysed GWAS of subcortical brain structures (nucleus accumbens, amygdala, caudate, hippocampus, pallidum, putamen, thalamus) and intracranial volume. This study of 29,037 participants, in partnership with the CHARGE consortium, is now complete, yielding some very exciting results. Derrek Hibar will present these findings including linking significant genetic variants to functional and behavioural changes. Recently, there has been intense interest in the ENIGMA Consortium specifically with the intent of expanding the focus of the consortium to include specific psychiatric and neurological diseases as well as working groups on imaging modalities. Working groups on schizophrenia, bipolar disorder, major depressive disorder, and ADHD were formed in order to identify the most robust brain-derived endophenotypes with the largest possible power. Ole Andreassen will present findings from two of the working groups each of which is the largest ever study of schizophrenia and bipolar disorder. In addition, will provide updates on new projects examining disease specific effects in the human cortex. Some major projects in the consortium have focused on imaging modalities. One such effort is the DTI Working Group, which was formed with the goal of identifying the most heritable and reliably segmented regions of white matter in the brain. They have produced a standardized protocol for harmonizing the analysis of white matter (DTI) across sites around the world. The results of this work and the first GWAS findings will be presented by Dr. Neda Jahanshad. In order to advance one of the long-term goals of the ENIGMA Consortium and of particular interest to the WCPG audience, we have established a collaboration with the Psychiatric Genomics Consortium with the goal of identifying common genetic overlap between the genetic determinants of brain-derived endophenotypes and risk factors for psychiatric disorders. Our efforts and initial results examining the genetic overlap between the largest-ever GWAS of subcortical structures from the ENIGMA Consortium and the 2nd round of results from the PGC Schizophrenia group will be presented by Barbara Franke (Moderator). The implications of these findings for psychiatric research using imaging endophenotypes will be discussed by Nick Martin (Discussant). COMMON GENETIC VARIANTS INFLUENCE HUMAN SUBCORTICAL BRAIN STRUCTURES IN 29,000 PEOPLE Derrek Hibar1, Sarah Medland2, Paul Thompson1, ENIGMA Consortium 1 University of Southern California, 2 QIMR Berghofer Medical Research Institute Individual Abstract Subcortical brain structures are considered the gateway to the human cortex, linking neuronal interactions to form complex human behaviors. The human subcortex has diverse functions, but can largely be split into two major systems: the basal ganglia and limbic system. The basal ganglia is comprised of the putamen, pallidum, accumbens, and caudate nuclei which play a role in voluntary movement and procedural memory. The limbic system is comprised of the amygdala, hippocampus, and thalamus which play a role in memory formation and emotional response. A number of highly heritable psychiatric and neurological disorders are characterized by disrupted connections in subcortical regions of the brain. In order to identify genetic variants related to structural changes in seven subcortical brain regions we examined genome-wide genotyping data and related it to structural MRI brain changes in 29,037 subjects, the largest-ever study of neuroimaging genetics. Here we report six novel genetic variants, influencing the volumes of the putamen (14q22.3, P = 1.35 x10-32; 8q21.2, P = 5.61x10-14; 20q11.21, P = 1.62x10-12), caudate nucleus (11q14.1, P = 5.15x10-9), and global head size (7p11.2, P = 4.41x10-10), and replicated two associations previously found to influence hippocampal volume (12q24.22, P = 5.51 x10-16 and 12q14.3, P = 3.70 x10-10). One of the novel intergenic loci with highly replicable influence on putamen volume (14q22.3, an eQTL for KTN1) showed evidence of altering functional activation of the brain’s reward circuitry, neuronal cell shape and dendritic complexity. Variants influencing the putamen across cohorts clustered near developmental genes known to regulate apoptosis, axon guidance, and vesicle transport. Identification of these genetic variants enables us to begin mapping the genetic architecture of brain development and function, a process that will help elucidate the dysfunctions that lie at the core of neuropsychiatric and neurological disorders. ENIGMA BIPOLAR DISORDER AND SCHIZOPHRENIA: CLEAR PATTERNS OF BRAIN STRUCTURE ABNORMALITIES Ole Andreassen1 1 University of Oslo Individual Abstract As part of the disease specific working groups of the ENIGMA Consortium we have joined forces with researchers around the world in order to search for the best brain-derived endophenotypes for the study of bipolar disorder and schizophrenia. Our worldwide effort analyzed brain MRI scans from 1,745 bipolar patients and 2,613 healthy controls (the largest neuroimaging study of bipolar disorder to date). We found consistent disease effects on subcortical brain volumes (nucleus accumbens, amygdala, caudate, hippocampus, pallidum, putamen, thalamus, lateral ventricles), and intracranial volumes (ICV). Many limbic structures were smaller in bipolar patients compared to controls: mean (of left + right) hippocampus (Cohen’s d = -0.221 ± 0.049; P = 6.62x10-6), thalamus (d = -0.150 ± 0.051; P = 3.21x10-3), and amygdala (d = -0.143 ± 0.043; P = 9.44x10-4). Bipolar patients had larger lateral ventricles (d = 0.289 ± 0.066; P = 1.29x10-5) than healthy controls. This profile of limbic deficits suggests that key subcortical structures are subtly but consistently altered in bipolar cohorts worldwide. Similarly, we analyzed brain MRI scans from 2,028 schizophrenia patients and 2,540 healthy controls, assessed with standardized methods at 15 centers worldwide. The profile of brain structural abnormalities in schizophrenia is still not fully understood, despite decades of research using brain scans. We identified subcortical brain volumes that differentiated patients from controls, and ranked them according to their effect sizes. Compared to healthy controls, patients with schizophrenia had smaller hippocampus (Cohen’s d=-0.46), amygdala (Cohen’s d=-0.31), thalamus (Cohen’s d=-0.31), accumbens (Cohen’s d=-0.25), and intracranial volumes (Cohen’s d=-0.12) and larger pallidum (Cohen’s d=0.21) and lateral ventricle volumes (Cohen’s d=0.37). Putamen and pallidum volume exacerbations were positively associated with duration of illness and hippocampal deficits scaled with the proportion of not-medicated patients. Cooperative analyses of brain imaging data support a consistent profile of subcortical abnormalities in schizophrenia. These findings provide the foundation for future work using brain-derived measures as endophenotypes for genetics analysis as well as understanding the differences and common factors underlying psychiatric disorders. MULTI-SITE GENETIC ANALYSIS OF DIFFUSION WEIGHTED MAGNETIC RESONANCE SCANS FROM THE ENIGMA–DTI WORKING GROUP Neda Jahanshad1, Peter Kochunov2, Paul Thompson3, David Glahn4, DTI Working Group ENIGMA 1 Imaging Genetics Center, Institute of Neuroimaging and Informatics, Keck School of Medicine of USC, 2 University of Maryland, 3University of Southern California, 4Yale University Individual Abstract Introduction: White matter pathways in the human neural network relay information to and from the functioning gray matter cortex and the subcortical control centers of the brain. Diffusion tensor imaging (DTI) allows for insight into the microstructural organization and makeup of these white matter pathways. The DTI working group within the Enhancing Neuro Imaging Genetics through Meta-Analysis (ENIGMA) Consortium has actively worked on establishing efficient methods for delineating reliable and heritable phenotypes of interest from fractional anisotropy (FA) images; these methods have been shown to be efficient and reliable in over 10 cohorts of different ethnicities, ages, and familial relatedness. Now that heritable phenotypes have been established and prioritized, the working group is initializing a worldwide, genome-wide association meta-analysis. An initial mega- and metaanalytical investigation into candidate white matter pathway genes reveals the urgent need for such systematic discovery procedures. Methods: Over 2,200 healthy subjects from five different family-based cohorts were used to calculate estimate the heritability of phenotypes extracted using the ENIGMA-DTI protocols. Heritability estimates were jointly analyzed using two different meta-analytical approaches as well as combining all data into one large family and performing a mega-analysis of heritability. Specific genetic variants were then tested for reproducibility and replication across populations. Nearly 2900 subjects from 3 overlapping and two additional cohorts were then combined in the largest DTI-imaging genetics study to date. 16 candidate SNPs previously associated with FA in a single cohort were examined across all groups in all 15 prioritized regions (phenotypes). Candidates evaluated include psychosis variants in DISC1, BDNF, COMT, NRG1, NTKR3, ErbB4, and dementia-risk variants in APOE, HFE, CLU, as well as other variants found to be “top hits” associated with FA through previously published single-site genome-wide analyses. Genome-wide association results are Results – Children and adults of different ethnicities show similar patterns of FA heritability in regions extracted using standardized protocols. Meta-analysis of candidate genes shows inconsistencies in SNP-FA associations across cohorts. Meta-analyzed GWAS results show SNPs that associate to brain microstructure. Conclusion: By harmonizing protocols and initially estimating heritability of the FA across the entire scan, we are able to prioritize the regions on the FA map that show consistent heritability across multiple cohorts of children and adults from multiple ethnicities. Many SNPs previously found to associate with FA may not be generalizable across populations using meta-analysis and genome-wide discovery methods are essential to find pathway associated genetic markers. A rolling GWAS-meta analysis is now underway with over 10,000 scans. Tuesday, October 14, 2014 2:15 PM - 4:15 PM Concurrent Symposia Sessions THE APPLICATION OF ISOLATED POPULATIONS IN THE IDENTIFICATION OF RARE RISK VARIANTS FOR PSYCHIATRIC DISORDERS Chair: Anders Børglum, Aarhus University Overall Abstract Details The allelic architecture of complex traits is likely to be underlined by a combination of multiple common and rare variants. Genome-wide association studies (GWAS) and largescale consortia meta-analysis of GWAS have successfully been applied in the search for common variants affecting the risk of developing psychiatric disorders. However, these studies are designed to examining only “the common variant” proportion of the genomic landscape of psychiatric disorders. Due to increased genetic drift during founding and potential bottlenecks, followed by population expansion, isolated populations may be particularly useful in identifying rare disease variants, that may appear at higher frequencies and/or within a more clearly distinct haplotype structure compared to outbred populations. Small isolated populations also typically show reduced phenotypic, genetic and environmental heterogeneity, thus making them advantageous in studies aiming to map risk variants involved in complex traits. These characteristics are complemented by elevated levels of linkage disequilibrium, which facilitates long-range haplotype-phasing and accurate imputation using population specific reference data. The extended levels of LD may, however, hamper the ability to discover the specific variants involved. A unique pattern of LD and haplotype frequencies may also obstruct the use of imputation algorithms based on HapMap CEU samples, and thus require the development of a population specific reference sample for imputation. Other potential concerns involve whether findings using isolated populations will generalize to other populations, when the identified risk alleles are private to the isolated population. Isolated populations have been applied in psychiatric genetics for decades, but they are, however, often small and the number of available cases are therefore often substantially lower than what can be obtained in outbred populations. One unresolved question is thus whether the increase in power due to genetic and environmental homogeneity is large enough to fully compensate for the limited number of available cases? The recent developments in the application of ‘next-generation sequencing’ (NGS) are particularly useful for identifying rare variants, especially when applied in samples from genetically isolated populations. NGS allows the direct examination of both common and rare alleles and the characteristics of isolated populations may facilitate the identification of rare variants. The speakers for this session will discuss approaches to using NGS and GWAS data for identification of risk variants for psychiatric disorders in isolated populations, presenting specific methodological approaches and illustrating their use in samples from such populations. They will present their latest research on psychiatric disorders using isolated populations of varying age, ranging from the relatively old isolated populations of the Ashkenazi Jews and Finland to the more recently PSYCHIATRIC DISORDERS AND ISOLATED POPULATIONS Hreinn Stefansson1 1 deCODE genetics Individual Abstract In a small fraction of patients with schizophrenia or autism, alleles of recurrent copy-number variants (CNVs) in their genomes are probably the strongest factors contributing to the pathogenesis of the disease. Some of the CNVs clearly alter fecundity and also cognitive function in control carriers. The high mutation rate of these CNVs compensates for the reduced fecundity and the CNV alleles are found in comparable frequencies worldwide. Single nucleotide polymorphisms (SNPs), conferring high-risk of severe psychiatric disorders, are also likely to be under negative selection pressure explaining why few founder mutations have been uncovered for psychiatric disorders. Genotyped samples from isolated populations can be long-range-phased which allows for imputations of low frequency sequence variants. Using this approach in Iceland variants conferring high-risk and protective for Alzheimer’s disease have been uncovered. THE FINNISH POPULATION ISOLATE AS AN EXAMPLE IN PSYCHIATRIC GENETICS Aarno Palotie1 1 SISu Project Individual Abstract Population isolates provide potential short cuts to identify disease associated low frequency and rare variants. Finland is the largest population isolate in Europe with its current 5.4 million inhabitants. It was founded thousands of years ago by a small number of settlers and has until recently had very little immigration. In the 17th century the Swedish King demanded a major internal migration to populate the Eastern and Northern parts of the country. This resulted in a second bottle neck effect and a large number of small communities that remained isolated for centuries. For unknown reasons the prevalence of schizophrenia and cognitive impairment follows the internal migration pattern, both traits being more frequent in the rural, late settlement regions in the North East of the Country. In a North Eastern Finnish schizophrenia high risk isolate we recently identified a rare 250kb deletion that deletes the TOP3B gene and found the deletion to be associated with an increased risk to schizophrenia and cognitive impairment. Characteristic for a large isolate, we also could identify four cases who were homozygotes for the TOP3B deletion; all of them had schizophrenia and/or cognitive impairment. The topoisomerase TOP3B forms a complex with the FMRP protein and thus connects the finding to the FragileX pathway (Stoll et al 2013). This work demonstrated the potential to identify disease associated low frequency variants enriched in an isolate. To use the potential of the Finnish isolate to identify low frequency coding SNPs, relevant for disease traits, the collaborative SISu Project (Sequencing Initiative Suomi (Suomi is Finland in Finnish) integrates all large scale sequence data produces from Finnish samples. To understand the overall landscape of coding variants we compared 3000 Finnish exomes from the SISu project with variants from 3000 non-Finnish European exomes. We could demonstrate that the genetic bottleneck has resulted depletion of private variants and in a shift of an increased proportion of population specific variants with a frequency of 0.5-5%, specifically with an increased proportion of loss of function variants (Lim et al submitted). Large, existing epidemiological cohorts that can be linked to nationwide health registers enable phenome mining strategies to study potential gene variant associations to a large number of phenotypes, including longitudinal health data. To test such strategies we analyze 80 loss of function (LoF) variants enriched in Finland in 35 000 Finns and linked these variants to a number of biochemical parameters and disease endpoints using the National Health Registers. Among these LoF variants we identified several associations to medically relevant, mostly cardiometabolic, traits. These findings suggest that similar strategies could be used to study neuropsychatric traits. IDENTIFICATION OF RARE VARIANTS IN AN ASHKENAZI JEWISH CASE-CONTROL SCHIZOPHRENIA COHORT Todd Lencz1, Semanti Mukherjee1, Shai Carmi2, Anil Malhotra1, Itsik Pe'er2, Ariel Darvasi3 1 The Zucker Hillside Hospital, 2Columbia University, 3Hebrew University Individual Abstract Increasing attention in psychiatric genetics has been paid to the identification of rare (<1%) variants with relatively high penetrance. Microarrays have provided support for the rare variant hypothesis, with the identification and replication of several high penetrance copy number variants associated with schizophrenia, autism, and other neuropsychiatric disorders. The recent advent of affordable next-generation sequencing provides the opportunity to identify a broader range of rare variants, but interpretation is hindered by locus and allelic heterogeneity in disease susceptibility, as well as the large number of mutations observed in healthy genomes. To reduce the “needle-in-the-haystack” problem, we examined cases and controls in a homogeneous founder cohort: the Ashkenazi Jewish (AJ) population. Using genomewide SNP data, we applied an identity-by-descent (IBD) approach for disease mapping in a genetically homogenous cohort of 904 cases and 1640 controls from the Ashkenazi Jewish population. Shared chromosomal segments (IBD segments) with length greater than 10KB were identified using the GERMLINE algorithm and clustered using the DASH algorithm. Consistent with our hypothesis, we observed a greater degree of IBD sharing of rare haplotypes in cases compared to controls; under a “clan genomics” model, these rare haplotypes are likely to harbor disease susceptibility variant(s). Whole genome sequencing is currently being performed in n=240 cases of this cohort, compared with n=300 sequenced AJ controls. Candidate mutations emerging from the sequencing analysis will then genotyped in additional subjects from the full cohort. Analyses are ongoing, and detailed results will be presented at the meeting. Because the range of rare of variation in the human genome is immense, strategies for increasing signal-to-noise are required to more rapidly identify functional variants associated with psychiatric disease. COMBINATION OF WHOLE-GENOME AND WHOLE-EXOME SEQUENCING, TO IDENTIFY RARE AND DE-NOVO VARIATION IN CASES OF SCHIZOPHRENIA AND BIPOLAR DISORDER FROM THE FAROE ISLANDS Francesco Lescai1, Thomas D. Als1, Mette Nyegaard1, Andrew McQuillin2, Ditte Demontis1, Alessia Fiorentino2, Niamh O’Brien2, Alexandra Jarra2, Jakob Grove1, Manuel Mattheisen1, Gudrid Andorsdottir3, Marjun Biskopstø3, August G. Wang4, Ole Mors5, Jun Wang6, Anders Børglum1 1 Aarhus University, 2University College London, 3Genetic Biobank of the Faroes, Faroe Islands, 4Mental Health Centre Amager, Denmark, 5Aarhus University Hospital, 6BGI - Beijing Genomics Institute, China Individual Abstract Isolated populations represent an advantage to identify rare disease variants that may appear at higher frequencies compared to outbred populations. In this work, we use the Faroese population to test this hypothesis, and combine low-depth (6X) whole-genome (WGS) and high-depth (35X) whole exome (WES) sequencing approaches to describe genomic variation, de-novo mutations and perform association mapping in patients with schizophrenia (SZ) and bipolar disorder (BP). Our sample consists of 106 SZ cases, 28 BP and 214 controls (344 total): together with unrelated individuals, it includes 54 complete trios. A total of 17,345,307 and 259,904 variants have been called in WGS and WES respectively. We discovered 9,130 de-novo mutations in WGS and 417 in WES. Clear differences emerge between WGS and WES in identifying different types of variants. A specificity of this work is the combination of WGS and WES in the discovery of de-novo mutations: both approaches discover the same number of de-novo loss-of-function mutations but high-depth WES is clearly more powerful in calling coding variants, mostly because of depth filtering criteria. In the association mapping we analysed variants with increased frequency in the Faroese population and identified a number of significant loci, which are currently being replicated in 3,300 BP and controls from UCL. The results of this analysis, the concordance between WES and WGS, and their perspectives will be presented and discussed. Whole Exome (35X) Whole Genome (6X) count percent count percent All Variants Loss of Function 3,140 1.21% 5,753 0.03% Missense 65,785 25.31% 80,087 0.46% Synonymous 41,904 16.12% 42,989 0.25% Non coding 149,075 57.36% 17,216,478 99.26% Total 259,904 17,345,307 De Novo Variants Loss of Function 6 1.44% 6 0.07% Missense 89 21.34% 12 0.13% Synonymous 32 7.67% 6 0.07% Non-coding 290 69.54% 9,106 99.74% Total 417 9,130. EATING DISORDERS: BREAKTHROUGHS AND NEW DIRECTIONS IN GENOMICS AND EPIGENOMICS Chair: Cynthia Bulik, University of California at Chapel Hill Overall Abstract Details Eating disorders (ED), including anorexia nervosa, bulimia nervosa, and binge eating disorder are associated with high morbidity and mortality. Anorexia nervosa is an enigmatic illness marked by extreme negative energy balance and maintenance of biologically implausible low body weights. Only 50% of patients with ED improve with treatment, highlighting the need for new discoveries and treatment targets. Genetic research into all eating disorders is progressing, with new consortia and novel large studies yielding insights into the pathogenesis of ED. This symposium will focus on new findings from varied methodological approaches aimed at identifying genetic factors in ED. We will present and discuss emerging evidence from across Europe and the US on how the genome, the epigenome, and the co-action of genes and environment can elucidate risk ED, course, and outcome. The first presentation (Prof C. Bulik) will focus on a mega-analysis performed as part of the Psychiatric Genomics Consortium, combining samples from: the Genetic Consortium for Anorexia Nervosa and the Wellcome Trust Case Control Consortium 3, and the Children’s Hospital of Philadelphia and Price Foundation samples. The second presentation (Dr Nadia Micali) will focus on the role of geneenvironment interactions (focusing on serotonin, dopamine genes and obesity-related genes and their interaction with life events and other relevant environmental factors) in increasing the risk for bulimic behaviours (binge eating and purging) and anorexic behaviours (food restriction and excessive exercise in the context of low weight) in a large UK population-based cohort of 8,000 adolescents and young adults. The third presentation (Dr Y Guo) will focus on applying machine learning risk prediction to anorexia nervosa using genome-wide genotyping data from 3940 cases and 4179 controls of European ancestry. The fourth presentation (Prof H. Frieling) will highlight findings from a large genome-wide methylation study and a candidate gene methylation study in German participants with eating disorders. Dr G Breen will moderate the symposium, discuss the findings presented, and contextualize them relative to other psychiatric disorders. He will also discuss translational implications of the findings highlighting next steps in animal models and how and whether the findings are currently relevant to clinicians, families, and patients in understanding these pernicious illnesses. A MEGA-ANALYSIS OF GENOME WIDE ASSOCIATION IN ANOREXIA NERVOSA Cynthia Bulik1, Genetic Consortium for Anorexia Nervosa, Wellcome Trust Case Control Consortium, Anorexia Nervosa Working Group of the Psychiatric Genomics Consortium 1 University of California at Chapel Hill Individual Abstract Anorexia nervosa (AN) is a complex and heritable eating disorder characterized by the maintenance of dangerously low body weight. Two subtypes, restricting—marked by decreased energy consumption and increased energy expenditure—and binge-eating/purging—marked by the presence of both low weight and binge eating or purging exist. Both represent extremes of dysregulated appetite and weight. Two small genome-wide association studies (GWAS) of AN have been conducted, neither of which has yielded genome-wide significant findings, as would be expected by sample size. A mega analysis is underway to combine these two studies to be followed by cross-disorder analyses with other phenotypes present in the Psychiatric Genomics Consortium (i.e., obsessive-compulsive disorder, major depression, alcohol and drug dependence, major depression, autism, attention-deficit hyperactivity disorder, schizophrenia, bipolar disorder, and post-traumatic stress disorder). With the increasing availability of large GWAS genotyped samples of many psychiatric disorders, we are well positioned to apply molecular genetic approaches to explain clinical comorbidity. Such analyses, including genome- wide complex trait analysis (GCTA) enable the calculation of bivariate SNP heritabilities and determination of genetic correlations between disorders. This talk will set the stage for the symposium and present up-to-date findings and analyses relevant to the genetics of eating disorders. GENE ENVIRONMENT INTERACTIONS AND ADOLESCENT EATING DISORDER BEHAVIORS: A POPULATION-BASED STUDY Nadia Micali1, Marta Cros Bou2, Janet Treasure3, Emily Simonoff3 1 UCL Institute of Child Health, 2Harvard School of Public Health, 3Institute of Psychiatry Individual Abstract Eating disorders have a peak of onset in adolescence. Evidence suggests that eating disorders result from an interplay between genes and environment. The majority of studies so far, however, have focused on anorexia nervosa and bulimia nervosa. Moreover, few studies have investigated Gene x environment (GxE) interactions in population-based studies, and fewer have focused on specific eating disorder behaviours (possible better phenotypes than syndromes). Case control studies have highlighted an association between genes in the serotonin and dopamine system, as well as other genes in the appetitive and weight system and eating disorders. G x E interactions have mainly been studied in relation to bulimia nervosa. The aim of this study was to investigate previously identified GxE interactions for anorexia nervosa and bulimia nervosa such as: childhood abuse and life events in interaction with a polymorphism of the serotonin transporter (5-HTTLPR) for bulimia nervosa behaviours (bingeing and purging); parenting style in interaction with 5-HTTLPR polymorphisms for anorexia nervosa behaviours (drive for thinness, food restriction in the presence of low weight); life events and stress in interaction with a SNP in Brain-derived neurotrophic factor (BDNF) for anorexia nervosa behaviours. We prospectively collected data at three timepoints in adolescence (14, 16, 18 years) on 7,000 adolescents from the Avon Longitudinal Study of parents and Children (ALSPAC), a population-based study based in the UK to derive eating disorder behaviours. Genotype data was obtained using the Illumina Hapmap 550 quad chip on 6,500 adolescents. Population stratification will be assessed and hidden population stratification will be controlled for. Data will be analysed using logistic and linear regression models. We will present data on the full sample and stratified analyses by gender. All analyses will be adjusted for age at assessment and Body Mass index (for analyses relating to bulimia nervosa behaviours). MACHINE LEARNING BASED DISEASE RISK PREDICTION FOR ANOREXIA NERVOSA Yiran Guo1, Zhi Wei2, Brendan Keating1, GCAN, WTCCC, Hakon Hakonarson1 1 Children's Hospital of Philadelphia, 2New Jersey Institute of Technology Individual Abstract Machine learning disease risk prediction is measured by area under ROC (receiver operating characteristic) curve (AUC), a value between 0.5 and 1 for assessing how well the model can distinguish cases versus controls, with the higher number indicating better discriminative power. This method has been used to predict risk for complex human diseases in which genetics plays a part of the etiology like type 1 diabetes (T1D) and inflammatory bowel disease (IBD), with AUC of around 0.85. We applied the method to evaluate the risk for Anorexia nervosa, a psychiatric and eating disorder to which genetics also contribute susceptibility, using genome-wide genotyping data from 3940 cases and 4179 controls of European ancestry. The resulting AUC is 84.7% which indicates comparable ability to predict disease risk using the genetics data and machine learning method. EATING DISORDERS AND THE EPIGENOME - HOW (MAL) NUTRITION CHANGES THE CHROMATINE CODE Helge Frieling1, Vanessa Buchholz2, Martina de Zwaan2, Stefan Ehrlich3 1 University of Erlangen-Nurenberg, 2Hannover Medical School, 3Gustav Carus University Dresden Individual Abstract Eating disorders and especially anorexia nervosa are believed to be highly heritable with heritability estimates ranging up to 70%. Molecular genetic studies so far have failed to find convincing risk genes. Twin studies have revealed high concordance rates between persons sharing the same genotype, still many monozygotic twin pairs discordant for anorexia nervosa exist. This discordance together with the high heritability estimates poses the question, why some persons with a genetic risk profile are able to stay healthy. The study of epigenetics, investigating those mechanisms that control the activity of certain genes by turning them on or off, may help to understand this paradox. Environmental influences change the epigenetic code of gene regulation throughout the life-span of the organism, starting even before the implantation of the fertilized egg. Pre-, peri and postnatal adversities have been shown to program certain vulnerabilites towards an eating disorder and life-style factors later in life can function as initiating and maintaining factors of the actual disease. Epigenetic mechanism like DNA methylation and histone modifications can be regarded as the molecular biological foundation of these processes. In contrast to genetics risk factors, epigenetics are dynamic and prone to modification by all kind of interventions including changes in life-style and psychotherapy. The talk will focus on how epigenetic mechanisms are involved in the etiology of eating disorders and show, how these mechanisms contribute to successful remission of the disorder, thereby showing that genes are not fate. REPORT OF THE ISPG GENETIC TESTING TASKFORCE Chair: Francis McMahon, NIH/NIMH Overall Abstract Details Genetic testing was once a distant prospect in clinical psychiatry, but is now increasingly regarded by clinicians and the public as a potential source of information that could help guide diagnosis, treatment, and family counselling. However, research on the clinical use of genetic testing in psychiatry is still quite limited, and the issue remains clouded in misinformation, regulatory flux, and ethical concerns. Recently, the International Society of Psychiatric Genetics (ISPG) released a consensus statement on the clinical use of genetic testing in psychiatry aimed at providing guidance for clinicians and the general public. To accomplish this, the ISPG charged a taskforce with the goal of updating and expanding the Society's previous statement. The taskforce considered a broad range of scientific, clinical, and ethical issues. In this workshop, members of the taskforce will review and discuss the evidence and considerations that were used in formulating the latest consensus statement. Several controversial topics will be highlighted and discussed. Audience participation is highly encouraged in what promises to be a lively and informative discussion of one of the big issues facing our field today. COPY NUMBER VARIATIONS -- ROLE IN COUNSELING Elliot Gershon1, Ney Alliey-Rodriguez1 1 University of Chicago Individual Abstract Copy Number Variants (CNVs; chromosomal microdeletions and microduplications) are the most potent known individual risk factors for Schizophrenia, Autism Spectrum Disorder, Bipolar disorder, and Intellectual Disability. Rare CNVs at specific locations greatly increase the likelihood that an individual will have one of these disorders. Another risk is presented by de novo CNVs, which are mutations found in an individual but not the parents. In the aggregate, these are common events, occurring in 1% of normals and in 4% to 7% of patients with BD, SZ, or ASD. De novo CNVs are independent of family history. These findings have profound implications for genetic counseling, although for some of these findings further replication will be needed before introduction into clinical counseling practice. The broad spectrum of phenotypes of CNV associations leads to relatively large cumulative risks of any illness. The risk of BD, SZ, or ASD is 14% in the case of a de novo CNV. The risk of any of these disorders for a carrier of the rare 22q11 microdeletion CNV is 82%. Traditionally, people who ask for risk counseling are concerned about a particular illness because of a family history. As genome-wide scans become more widely used, people will ask for counseling on any possible illness based on unanticipated genetic test results. With such potent and pluripotent risk factors, counseling issues can arise: a) abortion or non-implantation of embryos, b) stigmatization of carriers, of their families, and of their communities, c) family members’ rights to genetic information, d) population screening, and e) psychological and interpersonal problems arising from results of counseling, which include an individual’s coming to terms with undesired test results, and conflict within families over communication of results and over blame for genetic risk. GENETIC TESTS TO GUIDE OPTIMAL TREATMENT Daniel Mueller1 1 University of Toronto Individual Abstract While few studies have investigated the association between non-pharmacological treatment forms in psychiatry (e.g., ECT, CBT), there is a growing list of genetic markers associated with effectiveness and adverse events of various drugs. In some situations, pharmacogenetic markers can supplement clinical information to help guide treatment decisions for psychiatric disorders, reducing the risk of treatment failure and serious adverse events. Notably, some pharmacogenetic markers were shown to have substantial effects sizes and clinically relevant odd ratios, and in particular for drug induced side effects. For example, in patients of Asian ancestry who receive carbamazepine, the HLA-B*1502 marker substantially increases risk of serious skin disorders (Stevens Johnson Syndrome and toxic epidermal necrolysis). Another example would be antipsychotic-induced weight gain, where one marker near the MC4R gene has shown to account for approximately half of the variance of weight gain. As for serum drug levels, a similar relationship can be seen for some CYP450 enzymes (e.g., CYP2D6, CYP2C19). These enzymes are highly involved in metabolism of drugs, including antidepressants and antipsychotics. Variation in the genes that encode these enzymes can lead to differences in drug metabolism that can be predicted by genetic markers. Individuals with genetic markers of poor or rapid metabolism may be at higher risk for non-response, adverse events, or drug-drug interactions. A third pharmacogenetic phenotype could be delineated which would include gene products targeted specifically for symptoms reduction, such as the serotonin transporter through antidepressants. Although most studies have consistently shown an association between the short allele of the serotonin transporter and antidepressant response, the relationship is less clear and effects are typically smaller in this category. Other gene-drug pairings are under active investigation. In view of these findings, expert panels have started to publish guidelines such as for use of CYP450 testing in psychiatry. In a recent statement, the ISPG board declared to generally concur with some of these guidelines, which do not recommend genetic testing on a global level, but provide guidance if genotype data are already available. As with most complex phenotypes, other factors also influence drug outcome (such as diet, use of other medications, or treatment resistance) which need to be taken into account and studied further. Randomized, double-blind clinical trials are needed to establish the clinical utility of genetic testing in psychiatric drug treatment. ISPG recommends clinicians follow good medical practice and stay current on changes to drug labeling and adverse event reports. One useful (but not necessarily exhaustive) list of pharmacogenetic tests is maintained by the US Food and Drug Administration. REPORTING OF INCIDENTAL OR SECONDARY FINDINGS Marcella Rietschel1 1 Central Institute of Mental Health Individual Abstract Incidental findings have been defined as unexpected observations of potential clinical significance. Genetic technologies permitting genome-wide screens may generate incidental findings of potential importance for medical conditions unrelated to the clinical complaint for which these tests were originally performed. Given that some of these events occur with a substantial frequency in the general population, it may be more appropriate to describe them as secondary rather than incidental. Irrespective of the terminology applied, such secondary findings may highlight a preventable illness or one that could benefit from early intervention. Some authorities, such as the American College of Medical Genetics (ACMG) recommend that clinicians report some secondary findings back to the individual patients. This recommendation is not generally accepted and while the ISPG in its statement “Genetic Testing and Psychiatric Disorders” concurs with the ACMG recommendation regarding reporting of actionable secondary findings to the referring clinician, it also states that a decision to inform a patient about such finding(s) must weigh the seriousness of the implicated disease, the potential medical consequences of nondisclosure, the patient’s stated wish to be informed about secondary/incidental findings (ideally established during pre-test counselling), the patient’s ability to rationally appreciate the prognostic implications of such finding(s) and participate in any preventive or therapeutic interventions that might be recommended, and the potential negative impact of disclosure on the patient’s psychological condition and quality of life. To fulfill these recommendations adequate expertise in counseling and time resources are needed. This text is largely based on the wording of the ISPG Statement “Genetic Testing and Psychiatric Disorders” PSYCHOLOGICAL, ETHICAL AND CLINICAL IMPLICATIONS IN GENETIC TESTING Jehannine Austin1 1 University of British Columbia Individual Abstract We now have a substantial and growing list of genetic variations - including both single nucleotide polymorphisms and copy number variations - that we can confidently identify as contributing to the etiology of conditions like schizophrenia, bipolar disorder and depression. This progress is accompanied by a need for urgent attention to the question of how to apply this knowledge clinically in such a way as to promote the best possible outcomes for those who live with psychiatric disorders and their families. In this presentation, the ethical and psychological implications of applying our developing knowledge of the etiology of psychiatric disorders in the clinical setting will be discussed. For example, we will explore the psychological importance for people with psychiatric illness and their families of understanding cause of illness, and in particular, the psychological ramifications of understanding that there is a genetic contribution to these conditions. The process of risk communication in relation to psychiatric disorders and its attendant ethical issues will be discussed, and the influence that applying new genetic knowledge clinically may have on various facets of psychiatric illness-related stigma. The aim is to open discussion of questions of exactly *how* to apply our developing knowledge clinically, in order to promote the best possible outcomes for patients and families. FAMILY GENOME SEQUENCING IN BIPOLAR DISORDER Chair: John Kelsoe, University of California San Diego Overall Abstract Details Genome sequencing in families is a powerful strategy for gene identification. Genome sequencing generates a large number of variants that must be filtered on a variety of criteria in order to identify those most likely associated with disease. Family segregation is a powerful filter in identifying variants most related to disease. Early work in this area has revealed some intriguing results. Most families segregate for multiple likely functional susceptibility variants, and many of these variants are regulatory in nature. Seth Ament will present results from the sequencing of 36 families that supports these two ideas. Maja Bucan will discuss their efforts in genome sequencing portions of very large Amish pedigrees. These data suggest that even such large pedigrees from population isolates may still harbor many susceptibility variants. Bill Byerley will present mutations found in genome sequencing of extended pedigrees from isolates in Palau and Costa Rica. Lastly, Tadafumi Kato will discuss their work in exome sequencing of Japanese trios with bipolar disorder. RARE, NON-CODING VARIANTS IN CALCIUM SIGNALING GENES INFLUENCE RISK FOR BIPOLAR DISORDER Seth Ament1, Gustavo Glusman1, Szabolcs Szelinger2, Katherine Rouleau1, Denise Mauldin1, Tatyana Shekhtman3, Richard Gelinas1, Nathan Price1, Howard Edenberg4, Francis McMahon5, David Craig3, Leroy Hood1, John Kelsoe4, Jared Roach1 1 Institute for Systems Biology, 2Translational Genomics Institute, 3University of California at San Diego, 4 Indiana University School of Medicine, 5National Institute of Mental Health Individual Abstract We sequenced the genomes of 200 individuals from 40 multiply-affected pedigrees with bipolar disorder to identify its genetic causes. We show that a minority of these pedigrees can be explained by kilobase-scale deletions that segregate perfectly with disease and which are predicted to have large effects on disease risk. Bipolar disorder in the remaining pedigrees is better explained by the combined effects of multiple small- to moderate-effect risk variants. Intriguingly, both the large-effect and small-effect risk variants were enriched in the regulatory (non-coding) regions around genes with neuronal functions. In contrast to recent findings in schizophrenia and autism, we did not find an enrichment of exonic (coding) variants in these neuronal genes. Based on these results, we selected 30 genes for targeted sequencing in an additional 4000 bipolar disorder cases and 2000 controls. We confirmed an association in both European Americans and African Americans between bipolar disorder and rare, non-coding variants near several voltage-gated calcium channels. In addition, we confirmed an association in European Americans between bipolar disorder and rare variants in MTRNR2L2, which encodes the neuropeptide humanin. We demonstrate a novel effect of humanin on calcium flux in neuronal cell culture. Our results support the idea that risk variants for bipolar disorder perturb the regulatory sequences of genes involved in neuronal excitability. WHOLE GENOME SEQUENCING IN A GENETIC ISOLATE Maja Bucan1, Benjamin Georgi2, Rachel Kember2, David Craig3, Christopher Brown2, Janice A. Egeland4, Steven M. Paul5, Maja Bucan2 1 University of Pennsylvania , 2Department of Genetics, Perelman School of Medicine, University of Pennsylvania, 3The Translational Genomics Research Institute, 4Department of Psychiatry and Behavioral Sciences, University of Miami Miller School of Medicine, 5Departments of Neuroscience, Pharmacology and Psychiatry, Weill Cornell Medical College Individual Abstract We conducted a comprehensive genomic analysis of bipolar disorder in a large Old Order Amish pedigree. High-density SNP-array genotypes of 388 subjects were combined with whole genome sequence data for 80 family members, comprising 30 parent-child trios. This study design permitted evaluation of candidate variants within the context of haplotype structure by a) resolving the phase in sequenced parent-child trios and b) by imputation of variants into multiple unsequenced siblings. Non-parametric and parametric linkage analysis of the entire pedigree as well as on smaller clusters of families identified nominally significant linkage peaks. We report dozens of predicted deleterious genetic variants under each linkage peak, in addition to moderately frequent (in the Amish, but rare in 1000 Genomes) variants at the published bipolar and schizophrenia GWAS loci. In addition, we used high density SNP-array data to address the role of copy-number variation (CNV). Although we find no evidence for an increased burden of CNVs in BP individuals, we report a trend towards a higher burden of CNVs in known Mendelian disease loci in bipolar individuals (p=0.06). Dissection of exonic and regulatory variants in genes identified additional credible candidate genes for functional studies and replication in population-based cohorts. The striking haplotype and locus heterogeneity we observed suggest that mechanistic studies on a large number of genes will be necessary to increase our knowledge about the etiology of bipolar illness and its relationship to other disorders. EXOME ANALYSIS IN TRIO FAMILIES OF BIPOLAR DISORDER Tadafumi Kato1, Nana Matoba2, Muneko Kataoka3, Kumiko Fujii4, Tadafumi Kato2 1 RIKEN Brain Science Institute , 2Lab for Molecular Dynamics of Mental Disorders, RIKEN Brain Science Institute, 3Lab for Molecular Dynamics of Mental Disorders, RIKEN Brain Science Institute; Department of Child Neuropsychiatry, Graduate School of Medicine, The University of Tokyo, 4 Department of Psychiatry, Dokkyo University School of Medicine Individual Abstract Bipolar disorder is one of major mental disorders characterized by recurrent manic and depressive episodes. Twin studies showed that heritability of bipolar disorder is around 85%. GWAS identified a number of common SNPs associated with bipolar disorder, but the effect of each SNP is weak. We hypothesize that combination of multiple rare damaging variants contribute to bipolar disorder and the variants detected in patients are enriched in genes within specific functional categories. To test this hypothesis, we performed exome sequencing in 36 parents-proband trio families of bipolar disorder. No significant difference in the number of damaging mutations was found between the variants transmitted from the parents to the proband and those not transmitted to the proband. When gene ontology enrichment analysis was applied, several functional categories were found to be enriched in transmitted rare damaging variants than in the un-transmitted variants. We are analyzing independent bipolar trios as well as control trios to test the reproducibility and specificity of this finding. ENDOPHENOTYPES FOR GENE DISCOVERY IN MAJOR MENTAL DISORDER Chair: Andrew McIntosh, University of Edinburgh Overall Abstract Details Endophenotypes are quantitative traits associated with mental disorders that show co-segregation with clinical disorder within multiply affected families and demonstrate a high genetic correlation with the target condition irrespective of clinical state. To date, many candidate endophenotypes have been proposed and in many cases these traits have a polygenic architecture similar to the clinical disorders with which they are associated. In this symposium we will review the value of endophenotypes for psychosis, bipolar disorder and depression and present methods for adjudicating their value. We will also present data that allows endophenotypes to be assessed on the basis of epistasis as well as an additive genetic component. We will also present evidence demonstrating their value for gene finding studies using linkage and family-based association studies. ENDOPHENOTYPES FOR DEPRESSION AND HEIR VALUE IN GENE DISOCVERY Andrew McIntosh1, David Porteous1, Ian Deary1, Toni Clarke1, Lynsey Hall1, Pippa Thomson1, Caroline Hayward1, Maria Fernandez1, Chris Haley1, Donald MacIntyre2 1 University of Edinburgh, 2NHS Lothian Individual Abstract Introduction Major Depression (MDD) is clinically and causally heterogeneous and has so far resisted attempts to reveal its underling genetic architecture through genome wide association studies (GWAS). The use of genetically-correlated quantitative traits represents an alternative means of identifying risk variants for the condition. Methods We genotyped a large, recently available population based family cohort 'Generation Scotland' (N=21516). Fourteen thousand individuals were genotypes using the Human OmniExpress SNP Array with exome variants. Individuals completed a cognitive test battery, the General Health Questionnaire (GHQ), the Eysenck Personality Questionnaire (EPQ) and measures of schizotypy and bipolar spectrum disorders. Ranking on the basis of genetic correlation with MDD, we prioritized variables and used them for GWAS. Results Three of our quantitative traits had genetic correlations with MDD of >0.3. We performed multivariate GWAS (mvGWAS) using the vector of these traits. In addition, we performed a principal components analysis of the genetic and phenotypic correlations between these traits and used the first unrotated principal component for univariate GWAS. Whereas we found little evidence for significant genome-wide association with the binary clinical trait, we found a novel association with our derived quantitative traits. A common locus was revealed by both methodological approaches (mvGWAS and 1st-PCA analysis). Conclusions Our findings demonstrate that quantification of MDD coupled to studies which prioritize candidate endophenotypes may hold promise as a means of identifying risk variants. DISCOVERING SCHIZOPHRENIA ENDOPHENOTYPES IN RANDOMLY ASCERTAINED PEDIGREES David Glahn1 1 Yale & Institute of Living Individual Abstract The genetic architecture of schizophrenia is complex, involving multiple common and rare mutations within specific gene pathways. To make progress, it is necessary to determine how risk variants impact the multifaceted behavioral symptoms that define the illness. Yet, traversing between genotype and phenotype is difficult, even for simple Mendelian disorders. Endophenotypes can help to characterize disruptions in gene networks on quantitative traits closely aligned to schizophrenia. Unfortunately, relatively few schizophrenia endophenotypes are genetically correlated with disease liability. We present a novel method for discovering endophenotypes in unselected extended pedigrees. Specifically, we search for neurocognitive and neuroanatomic endophenotypes for schizophrenia in large unselected multigenerational pedigrees using a novel approach to the estimation of the endophenotypic ranking value that is closely related to the genetic correlation between endophenotype and disease. Using a coefficient of relationship approach, a fixed effect test within a variance component analysis was performed on neurocognitive and cortical surface area traits in 1,606 Mexican-American individuals from large, randomly ascertained extended pedigrees who participate in the “Genetics of Brain Structure and Function” study. Despite having sampled just 6 individuals with schizophrenia, our sample provided 233 individuals at various levels of genetic risk for the disorder. We identified three neurocognitive measures (digit-symbol substitution, facial memory, and emotion recognition) and six medial temporal and prefrontal cortical surfaces associated with liability for schizophrenia. With our novel analytic approach one can discover and rank endophenotypes for schizophrenia, or any heritable disease, in randomly ascertained pedigrees. EPISTASIS INCREASES VARIATION EXPLAINED IN ENDOPHENOTYPES ABOVE THE CONTRIBUTION OF THE POLYGENIC SCORE Kristin Nicodemus1 1 The University of Edinburgh Individual Abstract Although several studies have successfully shown a polygenic component explains a small but significant amount of variation in endophenotypes for psychiatric disorders such as cognition and clinical symptomology, epistasis may also play an important role in the underlying genomic architecture of these complex traits. Recent work1 that has examined variation in cognitive endophenotypes in psychosis cases explained by the schizophrenia candidate gene ZNF804A and its putative pathway (defined as differentially expressed genes after ZNF804A knockdown). Of particular importance was assessing the relative contribution of the polygenic score versus epistasis in explaining variation in these cognitve endophenotypes. Psychosis patients (N = 424) were assessed in cognitive function impaired in schizophrenia (e.g., IQ, memory, attention). The polygenic score was created Using the Psychiatric GWAS Consortium schizophrenia case-control study results within the genes in the ZNF804A pathway. Increased polygenic scores were associated with poorer performance in psychosis patients on IQ, memory and social cognition, and the amount of variation explained (R2) by the polygenic score on these endophenotypes ranged between 1-3%, which is similar to that observed in other studies. Using a newly-developed statistical model that simultaneously models both polygenic and epistatic components, epistasis in the ZNF804A pathway was found to explain 2-3 times more variability in working memory in psychosis cases than the polygenic score, even after controlling for the contribution of the polygenic score in the model. This increase was able to be replicated in two independent samples, including a “narrow psychosis” (p = 0.016) and “broad psychosis” set (p = 0.036) as well as combined psychosis (p = 0.0012). This method is currently being applied to variation in cognitive endophenotypes explained by the Fragile X Mental Retardation Protein (FMRP) pathway, which has been associated with several psychiatric disorders including schizophrenia, major depressive disorder, bipolar disorder and autism. 1. Nicodemus KK, et al. Epistasis increases the amount of variability in working memory performance explained by polygenic scores in the ZNF804A pathway. JAMA Psychiatry [in press] ADOLESCENT NEURODEVELOPMENTAL PHENOTYPES OF BIPOLAR DISORDER IN A GENETICALLY ISOLATED POPULATION Carrie Bearden1, Nelson Freimer 1, Scott Fears 1, Susan Service 1, Chiara Sabatti 2, Rita Cantor1, Carlos Lopez-Jaramillo3, Gabriel Macaya3, Victor Reus3, David Glahn4, Julio Molina , Javier Escobar, Juan David Palacio 1 University of California, Los Angeles, 2Standford University, 3Universidad de Antioquia, 4Yale & Institute of Living Individual Abstract Although genome-wide association studies have now identified the first replicated loci contributing to risk for bipolar disorder (BP), the small relative risk attributed to these loci may reflect the significant heterogeneity of the disorder, at both the genetic and phenotypic level. We have now collected the most extensive set of putative BP component phenotypes yet assessed within any study sample, in multi-generational pedigrees enriched for severe BP-I disorder. Based on strong heritability and association with disease in adult members of these pedigrees, we have been able to prioritize a set of candidate quantitative traits for genetic mapping and further investigation. In particular, neuroimaging phenotypes [i.e., prefrontal and temporal cortical thickness, volume of medial temporal structures, and microstructural integrity of the corpus callosum, as measured with diffusion tensor imaging (DTI)], as well as circadian and sleep phenotypes, were prioritized for further analysis based on these criteria. We have now extended our investigation to adolescent offspring of the adult members of the pedigrees, in order to examine developmental expression of these phenotypes. Preliminary findings reveal high rates of anxiety and inattentive disorders, and impairments in recognition of facial emotional expression and in frontally- mediated cognitive processes (i.e. inhibitory control) in youth at genetic risk for BP. Greater stability of daily rhythms, as measured with actigraphy, was associated with lower self-reported daily stress. Additionally, given significant linkage findings (LOD =5.1) for amygdala volume in adult pedigree members, we are now investigating structural integrity and functional connectivity of the amygdala as a candidate biomarker for bipolar risk in adolescents. Longitudinal investigation of a genetically informative cohort, in which verified risk loci for both the clinical diagnosis of BP and BPassociated endophenotypes have been identified, offers an unprecedented opportunity for connecting risk genes to brain development and emergent psychopathology in adolescence. 4:30 PM - 6:00 PM Concurrent Oral Sessions OVERALL SESSION: NOVEL APPROACHES AND TOOLS FOR BENCH AND BEDSIDE DEVELOPMENT OF A NEW TECHNOLOGY FOR SINGLE-CELL MRNA-SEQ ANALYSIS, ON THE SCALE REQUIRED TO ANALYZE THE CELLULAR COMPLEXITY OF THE BRAIN Steven McCarroll1, Evan Macosko2, Anindita Basu3, James Nemesh4, Melissa Goldman5, Alex Shalek6, David Weitz7, Aviv Regev6 1 Stanley Center for Psychiatric Research, Broad Institute of MIT and Harvard, 2Harvard Medical School; Stanley Center for Psychiatric Research, Broad Institute, 3Harvard University; Broad Institute, 4Stanley Center for Psychiatric Research, Broad Institute, 5Harvard Medical School, 6Broad Institute, 7Harvard University Background An increasingly critical research direction is to leverage genetic leads to reach insights about the pathophysiology involved in brain disorders. To do this, we need methods to systematically relate genes to the specific cell populations in which they are expressed, and to identify altered cellular states in those cells. The brain’s enormous cellular complexity, which has yet even to be satisfactorily catalogued, poses immense challenges to this goal. Methods To address this need, we have been developing a technology called DropSeq, enabling simultaneous analysis of thousands of single-cell transcriptomes. DropSeq starts with suspended cells, isolates individual cells in nanoliter-sized aqueous compartments within oil-aqueous reverse emulsions, massively barcodes these tiny compartments, and generates high-quality 3'-end single-cell cDNA libraries from thousands of cells, in a process that takes about 12 hours. Library preparation and sequencing occur in a single bulk reaction. We use “cellular barcodes” to track the cell-of-origin of each transcript; “molecular barcodes” to distinguish the distinct mRNA molecules from the same cell; and the rest of a sequence read to identify the gene from which each mRNA transcript arose. This allows expression profiling of each individual cell from a mixture of thousands of cells. Results In validation experiments, we have found that DropSeq can detect tens of thousands of unique mRNA molecules per cell, while accurately tracking the cell-of-origin of each transcript. Because of the tiny reaction volumes used, we estimate DropSeq library preparation costs to be 3 cents per cell, and throughput to be 10,000 single-cell libraries per day. We will present single-cell mRNA-seq data from tens of thousands of cells, including human primary neurons and glia, demonstrating DropSeq's ability to classify cellular types and subtypes. Discussion We believe DropSeq has the potential to accelerate progress from psychiatric genetics to biological insights by enabling the comprehensive cellular-level characterization of complex tissues throughout the brain. We will describe research strategies for systematically relating findings from psychiatric genetics to specific neuronal and glial populations. INTERNATIONAL BREAKPOINT MAPPING CONSORTIUM - IDENTIFYING NEURODEVELOPMENTAL AND NEUROPSYCHIATRIC GENES BY SATURATION OF THE HUMAN GENOME WITH CHROMOSOMAL BREAKPOINTS Christina Halgren1, Niels Tommerup2, Peter Jacky3, Iben Bache4, Allan Lind-Thomsen2, Malene Boegehus Rasmussen2, Mana Mehrjouy2, Claus Hansen2, Ana Carolina dos Santos Fonseca5, Angela Vianna Morgante6, Kikue Terada Abe7, Mads Bak2, The International Breakpoint Mapping Consortium 1 Wilhelm Johannsen Center for Functional Genome Research, Department of Cellular and Molecular Medicine, University of Copenhagen, 2Wilhelm Johannsen Center for Functional Genome Research, Department of Cellular and Molecular Medicine, University of Copenhagen, Denmark, 3Kaiser Permanente Emeritus, 4Wilhelm Johannsen Center for Functional Genome Research, Department of Cellular and Molecular Medicine, University of Copenhagen, Denmark and Department of Clinical Genetics, Rigshospitalet, Copenhagen, Denmark, 5Wilhelm Johannsen Center for Functional Genome Research, Department of Cellular and Molecular Medicine, University of Copenhagen, Denmark and Departamento de Genetica e Biologia Evolutiva, Universidade de Sao Paulo, Brazil, 6Departamento de Genetica e Biologia Evolutiva, Universidade de Sao Paulo, Brazil, 7Sarah Network of Rehabilitation Hospitals Background Despite the availability of the draft human genome for a decade, we still lack genotypephenotype-information for ~80-90% of our ~22,000 protein-coding genes, and for almost all of the rapidly growing number of non-coding RNA (ncRNA) genes and regulatory elements. Even with the prospects of exome and full genome sequencing, it will take decades and tremendous resources to saturate the exome, transcriptome and regulome with mutations that can be linked to normal and abnormal phenotypes including neurodevelopmental and neuropsychiatric disorders. Methods As a supplement to exome and full genome sequencing strategies, we will use already identified balanced chromosomal rearrangements (BCR) to establish a first, detailed map of mutations covering a significant fraction of the human genome. In the first clinical and molecular re-examination of unselected carriers of de novo balanced chromosomal rearrangements (BCRdn) detected by 40 years of prenatal diagnosis in Denmark, we used high throughput mate-pair sequencing to rapidly map the chromosomal breakpoints to sequence level. Results We showed that BCRdn truncate protein coding genes, ncRNA genes, unannotated transcripts detected by deep sequencing, as well as developmental regulatory genomic landscapes, mimicking random mutagenesis. Phenotype-genotype associations were guided by information obtained in nationwide Danish medical registries including the Danish Psychiatric Central Research Register. With a mean follow-up period of 17 years (range 4-34 years), we identified a ~20% morbidity-risk exclusively involving neurodevelopmental and neuropsychiatric disorders, e.g. intellectual disability, behavioural disorders, autism spectrum disorders, depression and anxiety. This is likely to represent a conservative morbidity-risk since many neuropsychiatric disorders manifest in adolescence and adulthood. Discussion We have initiated clinical re-examination and mapping of all known BCRs in Denmark. Based on a population of just 5.5 million, this will provide data on >1,200 breakpoints. By international expansion we will extend this at least 10-fold to reach a proposed first goal of ~10,000 breakpoints. Unlike other large scale genomic efforts, all countries including undeveloped and developing countries can participate. We expect that the breakpoint-map will identify and confirm numerous genotypephenotype associations, a majority of which will involve disorders of the brain. PSYCHCHIP: DESIGN, QUALITY CONTROL AND PERFORMANCE Stephan Ripke1, PGC PsychChip Group 1 Massachusetts General Hospital Background The Psychiatric Genomics Consortium (PGC) is an international group of researchers whose major aim is to maximize the utility of psychiatric genome-wide association studies (GWAS) through mega-analysis. In recent years, these studies have successfully identified many novel genetic associations for psychiatric disorders by integrating data from >170,000 subjects. To continue these efforts, the PGC has developed a custom genotyping array, the PsychChip, and is coordinating genotyping of over 100,000 samples at the Stanley Center of the Broad Institute and the Mount Sinai School of Medicine. Methods The PsychChip consists of three components: a GWAS backbone of ~256k SNPs, ~236k rare and low-frequency exome variants, and ~50k custom markers tailored to psychiatric disorders. We used previous psychiatric genetic studies to select markers with the following goals in mind. First, we ensured any variants showing modest association (P<0.01) were represented on the chip either directly or indirectly. Second, for all highly associated loci (P<0.00001), we selected a dense set of markers in the region that can be used for fine-mapping studies. Third, we added extra markers to regions with copy number variants (CNV) associated with psychiatric disorders. Fourth, we added rare variants discovered from whole-exome sequencing studies. Finally, we predicted where functional variants were likely to occur for genes that have been shown to be strongly associated with psychiatric disorders (e.g., CHD8 and autism). Results As of May 2014, we have genotyped 11,811 samples on the PsychChip array at the Broad Institute and 2,666 samples at Mount Sinai. For genotype calling, we tested GenCall and Birdseed for common variants to assess which algorithm generates the most robust data. We found that a consensus calling approach maximizes the number of SNPs that pass QC and minimizes the number of Mendel errors and violations of Hardy-Weinberg Equilibrium. We used zCall to recover rare genotypes missed by GenCall and Birdseed. Preliminary analysis of ~2,000 schizophrenia cases, ~2,000 controls and ~1,100 trios with schizophrenic probands showed that 85% of the previously reported schizophrenia associations are in a consistent direction (P=2.1x10-14). Discussion A major limitation in psychiatric genomics has been inadequate sample size. We believe that the PsychChip will be an important tool due to its low cost and targeted content for psychiatric disorders. The PsychChip can be purchased by anyone directly from Illumina. By the end of 2014, we project to have genotyped >100,000 samples, including substantial numbers of new cases for schizophrenia, bipolar disorder, ADHD, autism, PTSD, OCD, and anorexia nervosa. The PsychChip pilot data demonstrate that this genotyping platform will be a useful for interrogating the role of common variation in psychiatric illnesses while also enabling the assessment of rare coding and copy number variation. Substantial data generation is in progress, and we will present an update at WCPG in 10/2014. GENOME-WIDE ANALYSIS IDENTIFIES COMMON VARIANTS ASSOCIATED WITH NEONATAL BRAIN VOLUMES Rebecca Knickmeyer1, Kai Xia1, Shaili Jha1, Fei Zou1, Hongtu Zhu1, Martin Styner1, Pat Sullivan1, John Gilmore1 1 University of North Carolina Chapel Hill Background Brain development in the prenatal and perinatal periods is extremely dynamic and may be critical in the etiology of psychiatric illness. Previous research revealed high heritability of gray and white matter volumes in neonates, but the specific genetic variants which contribute to this variation remain unknown. The primary aim of this study was to identify single nucleotide polymorphisms (SNPs) associated with intracranial and global tissue volumes in neonates. Methods Buccal cells from a large and well-characterized population sample of infants assessed with high-resolution MRI of the brain at 2 weeks of age were genotyped with Affymetrix Axiom GenomeWide LAT and Exome arrays. Following rigorous quality control, SNP imputation was performed using data from the 1000 Genomes project. An automatic, atlas-moderated expectation maximization segmentation tool was used to classify brain tissue as gray matter (GM), white matter (WM), or cerebral spinal fluid (CSF). In addition to total tissue volumes, intracranial volume (ICV) and cortical GM and WM were also calculated. 594 subjects (278 singletons and 316 twins/siblings) with high quality genetic and neuroimaging data are included in this analysis. To account for the correlation structure between twins/siblings, linear mixed effect models were used to test a total of 9.5 million SNPs against each MRI variable. Results An intergenic SNP in 15q13.3 between KLF13 and OTUD7A was significantly associated with ICV (rs8030297; p=2.98 x 10-8) and total WM (rs6493639, p=4.24 x 10-8), and marginally associated with total GM (rs8030297; p=5.25 x 10-7) and cortical WM (rs6493639, p=1.17 x 10-7). Additional marginally significant SNPs in/near biologically plausible genes were also identified. Discussion 15q13.3 microdeletion increases the risk of intellectual disability, seizures, behavioral problems, and psychiatric disorders including schizophrenia. The current results suggest that common genetic variants in this region are associated with brain volumes in neonates and thus may play a role in cognitive development and psychiatric risk. We are also actively testing whether the combined effects of many common variants each with a small effect size predict variation in neonatal brain structure using pathway analysis and exploring the impact of copy number variants (CNVs) on neonatal brain structure. Ultimately, identifying genetic variations impacting brain development will significantly improve diagnosis, guide research efforts into environmental risk factors, and generate new therapeutic possibilities for individuals with psychiatric conditions. LINKAGE OF SCHIZOPHRENIA-RELATED GREY MATTER COMPONENT TO 12Q24 Emma Sprooten1, Navin Cota2, Emma Knowles1, D. Reese McKay1, Joanne E Curran3, Jack W. Kent 3, Melanie A. Carless3, Marcio Almeida3, Thomas Dyer3, Rene L. Olvera4, Peter Kochunov5, Laura Almasy3, Vince D Calhoun6, John Blangero3, Jessica A Turner7, David C Glahn1 1 Yale University, 2The Mind Research Network, 3Texas Biomedical Institute, 4University of Texas Health Science Center, 5University of Maryland, 6University of New Mexico, 7Georgia State University Background Meta-analysis (Glahn et al. 2009; Bora et al., 2011) and multivariate mega-analysis (Turner et al., 2012) indicate that grey matter density in the insula and the medial prefrontal cortex (mPFC) are the most consistent and pronounced imaging-based grey matter abnormalities in association with schizophrenia. Moreover, this grey matter component is also altered in unaffected siblings of patients (Turner et al., 2012), indicating that it may be a mediating some of the effects of genetic risk for the disorder. We applied source-based morphometry (SBM) to a large sample of randomly ascertained extended pedigrees to extract the same insula-mPFC grey matter component, estimate its heritability, and identify quantitative trait loci (QTL) that influence it in the general population. Methods As part of the GOBS study, T1-weighted MR images were acquired for 887 individuals from extended pedigrees of Mexican-American ancestry (532 female; 18-85 years; pedigree size: 1-258 individuals). After normalisation and grey mater segmentation, SBM was applied to extract 21 spatially independent components. The insula-mPFC component was identified by visual inspection and its overlap with the schizophrenia-associated component (Cota et al., In Review) was verified using the Dice coefficient and cross-voxel correlations. To estimate the heritability, the weights on the component, reflecting the overall grey matter density in the contributing voxels for each individual, were entered into polygenic analyses in SOLAR (Almasy & Blangero, 1998). Linkage analysis was performed by extending the polygenic model with location-specific identiy-by-descent information for ~15,000 points across the genome. Linkage peaks (LOD>2.9) were further examined by performing associations of SNPs underneath. Results The insula-mPFC grey matter SBM component derived from GOBS was very similar to the one derived from the case-control sample (Cota et al., In Review): Dice coefficient: 0.42, Pearson r = 0.58. The overall grey matter density across this component was highly heritable, as indicated by the polygenic model of the weights (h2 = 0.59; p = 1.78*10-15). A QTL was identified on chromosome 12 at 12q24.22-12q24.23, with a highly significant LOD = 3.76. There were 397 common SNPs under the linkage peak, the strongest association of which was for rs7133582 (p = 7.71*10-4) in a transcription factor binding site of KSR2, at the 12q24.23 end of the peak, which is in agreement with the maximum LOD score in this locus. Discussion There is compelling evidence that gray matter density in the insula and mPFC is reduced in patients with schizophrenia, and their unaffected relatives. Our findings indicate that genetic variation in 12q24 influences grey matter density in these brain regions. Our QTL has previously been linked to schizophrenia (Bulayeva at al., 2007) and bipolar disorder (Berettini et al., 2001). Our top SNP under the peak is located <200kb away from the schizophrenia candidate gene NOS1, and near the single top SNP in the ENIGMA genome-wide association analysis with hippocampal volume (Stein et al., 2012). In conclusion, mPFC and insula morphology are likely brain morphological endophenotypes that are coinherited with schizophrenia susceptibility variants at 12q24, and are thus vulnerability markers that can give further insights into the bioligical mechanisms of the development of schizophrenia and related disorders. COMBINATORIAL PHARMACOGENOMICS FOR TREATMENT-RESISTANT DEPRESSION: CLINICAL VALIDITY, CLINICAL UTILITY, AND HEALTH ECONOMICS Bryan Dechairo1, Josiah Allen1, Joseph Carhart1, Andrew Marshak1, Joel Winner1, Tony Altar1 1 AssureRx Health Background Less than half of patients experience complete remission when initially treated with antidepressants. These medications show comparable efficacy across drug classes, with limited improvement relative to placebo. By optimizing therapeutic selection for patients, pharmacogenomics can increase treatment response and decrease healthcare costs. GeneSight Psychotropic is a combinatorial pharmacogenomic test designed to bridge the translational gap from the bench to the point of care. GeneSight integrates variations in 8 genes (CYP2D6, CYP2C19, CYP2C9, CYP2B6, CYP1A2, CYP3A4, SLC6A4, HTR2A) to stratify 38 psychotropic medications into one of three cautionary categories, based on each medication’s metabolic pathways and mechanisms of action. Methods In three clinical outcome studies, 258 depressed subjects who had failed at least one antidepressant medication were enrolled into one of two treatment arms: GeneSight-guided treatment (results were available to clinicians at the beginning of the trial), or treatment as usual (TAU; results were withheld until the end of the trial). Study visits occurred at baseline and weeks 2, 4, and 8. In a retrospective healthcare utilization study, the medical charts of 96 psychiatric patients were reviewed for healthcare utilization (e.g., outpatient visits, medical absence days, disability claims) and analyzed according to the GeneSight cautionary category of their medications. In a prospective pharmacy claims pilot, 2,176 patients who received GeneSight testing were propensity matched to 10,880 non-tested, TAU patients. Pharmacy data were tracked for 180 days prior to and 365 days following project entry. Medication costs were compared between the two groups and between cautionary categories. Results Each prospective study showed improved clinical outcomes for subjects in the GeneSight arm relative to the TAU arm. In a meta-analysis, a 3.9 additional HAM-D17 point reduction was obtained from baseline to week 8 for subjects in the GeneSight versus TAU arm, representing a 71% greater treatment response. Stratification by GeneSight cautionary category within the blinded, TAU arm showed almost no improvement for subjects on genetically discordant medications, while subjects on genetically concordant medications showed the most improvement (p = 0.003). In the GeneSight arm, >90% of subjects were switched from genetically discordant to genetically concordant medications and showed improved clinical outcomes relative to their blinded, TAU counterparts (p = 0.005). Discussion Continued from results: In the retrospective healthcare utilization study, subjects on discordant medications had 69% more total healthcare visits (p = 0.01), 3-fold more medical absence days (p = 0.04), 4-fold more disability claims (p = 0.003), resulting in an estimated $5,188 higher medical costs relative to subjects on genetically concordant medications. In the prospective pharmacy claims pilot, GeneSight-guided patients saved a mean $1,035.60 in annual medication costs compared to unguided TAU patients (p < 0.0001). Within the GeneSight arm, patients who remained on genetically concordant medications saved $587.77 more annually relative to patients who remained on genetically discordant medications (p = 0.007). Conclusions - GeneSight has shown clinical validity by predicting patient treatment responses. - GeneSight clinical utility is evidenced by a 2.3-fold greater odds of response. GeneSight is estimated to reduce healthcare costs by over $3,000 annually. OVERALL SESSION: FUNCTIONAL GENOMICS & ENDOPHENOTYPES THE ANTIPSYCHOTIC OLANZAPINE INTERACTS WITH THE GUT MICROBIOME TO CAUSE WEIGHT GAIN IN MOUSE James Crowley1, Andrew Morgan1, Randal Nonneman1, Corey Quackenbush1, Cheryl Miller1, Allison Ryan1, Molly Bogue2, Sur Paredes1, Scott Yourstone1, Ian Carroll1, Thomas Kawula1, Maureen Bower1, Balfour Sartor1, Patrick Sullivan1 1 University of North Carolina at Chapel Hill, 2Jackson Laboratory Background The second-generation antipsychotic olanzapine is effective in reducing psychotic symptoms but is associated with considerable weight gain. Given the known involvement of the gut microbiome in obesity, we used a mouse model to evaluate the role of the gut microbiome in olanzapineinduced weight gain. Methods C57BL/6J mice were randomized to receive either olanzapine (50 mg/kg diet) or placebo while consuming a high-fat diet ad libitum beginning at 8 weeks of age and body weight was measured weekly. Results First, we established that oral delivery of olanzapine to C57BL6/J mice on a high fat diet resulted in considerable weight gain compared to placebo (p = 1.1 × 10-5). Second, we found that mice raised in germ-free conditions had no significant weight gain while consuming olanzapine (p = 0.48) but that the same mice had significant weight gain following introduction of gut flora (p = 4.9 × 10-3). Third, we used a randomized controlled crossover design to survey the fecal microbiome before, during, and after olanzapine treatment by sequencing bacterial 16S ribosomal DNA. Olanzapine potentiated a shift towards an “obesogenic” microbiota and this shift was correlated with weight gain. Finally, we demonstrated that olanzapine has antimicrobial activity in vitro against two commensal enteric bacterial strains. Discussion Taken together, these results provide strong evidence for a mechanism underlying olanzapine- induced weight gain in mouse. Olanzapine is a subtle antimicrobial, and shifts the gut microbiome to an obesogenic pattern. This work suggests a hypothesis for clinical translation in human patients. We note that the effects of olanzapine are analogous to low-dose antibiotic regimens used to promote growth in livestock. CARRIERS OF A GENOME-WIDE SIGNIFICANT BIPOLAR DISORDER RISK ALLELE SHOW DECREASED TRANK1 EXPRESSION IN NEURAL PROGENITOR CELLS THAT IS RESCUED BY SODIUM VALPROATE Xueying Jiang1, Sevilla Detera-Wadleigh 1, Nirmala Akula1, Francis McMahon1 1 National Institute of Mental Health Background Genome-wide association studies (GWAS) have identified several risk variants for bipolar disorder (BD), but the functional consequences of most variants remain undefined. A common variant (rs9834970) located ~15 kb 3’ of the gene TRANK1 on chromosome 3p22 has shown genome-wide significant association with BD in several studies [1-4] and nearby markers have been associated with schizophrenia [5]. Previously, we showed that valproic acid (VPA), an effective treatment for BD, increased TRANK1 expression in commercial cell lines [1]. In this study, we aimed to confirm the effect of VPA treatment on TRANK1 expression in induced pluripotent stem cells (iPSc) and in iPSC-derived neural progenitor cells (NPCs), and to test the effect of the rs9834970 risk allele (G) on TRANK1 expression in both iPSc and NPC cultures. Methods iPSC lines were generated by lentiviral reprogramming of adult human fibroblast cells from 7 individuals with known genotypes at rs9834970. All 7 iPSC lines were further differentiated into NPCs with Gibco PSC neural induction medium (Life technology, CA). iPScs and NPCs were validated by standard immunochemical analysis. RNA was extracted at baseline and after 72h of treatment with VPA (0.5mM or 1mM) from 4 iPSC and 7 NPC lines. TRANK1 gene expression levels were measured by quantitative real-time polymerase chain reaction (qRT-PCR), with 3 technical replicates for each treatment condition. All samples were genotyped on the Illumina Infinium Human OmniExpress Exome bead array. Statistical significance of gene expression differences was determined by two-way ANOVA. Results VPA treatment substantially increased TRANK1 expression in both iPSc and NPC lines. Foldchange vs. baseline ranged from 2.76 (0.5mM VPA) to 6.18 (1mM VPA) in iPSc (P<0.01), and from 2.76 (0.5 mM VPA) to 4.06 (1mM VPA) in NPC (p<0.01). Carriers of the risk allele of rs9834970 had lower baseline TRANK1 expression in NPC lines (fold-change vs non-carriers, 4.98, p<0.05). The decreased TRANK1 expression in risk allele carriers was normalized by VPA (Number of risk alleles x VPA, F(2,17)=4.48, p<0.03). Discussion These results confirm and extend our previous findings, demonstrate that VPA increases TRANK1 expression in both iPSc and NPC lines, and reveal a previously unknown cis-effect of rs9834970 on TRANK1 expression that is antagonized by VPA. These findings suggest that VPA normalizes reduced TRANK1 expression in carriers of the BP risk allele at rs9834970, implying a novel therapeutic mechanism for VPA in BD. Gene expression studies in iPSc-derived NPCs of risk allele carriers may prove to be a useful strategy to characterize the tissue-specific functional impact of risk alleles implicated by GWAS, ultimately enhancing our understanding of etiological mechanisms and pointing the way toward improved pharmacologic therapies. MOLECULAR MECHANISMS OF D-CYCLOSERINE IN FEAR EXTINCTION: INSIGHTS FROM RNA AND MICRORNA SEQUENCING Stefanie Malan-Müller1, Lorren Fairbairn 2, Mahjoubeh Jalali 3, Edward Oakeley 4, Junaid Gamieldien 3, Martin Kidd 5, Soraya Seedat 2, Sian Hemmings 2 1 Stellenbosch University, 2Stellenbosch University, Department of Psychiatry, 3University of the Western Cape, South African National Bioinformatics Institute, 4Novartis Institutes for BioMedical Research, Biomarker Development - Human Genetics and Genomics, Genome Technologies, 5Stellenbosch University, Centre for Statistical Consultation Background Posttraumatic stress disorder (PTSD) is a severe, chronic and debilitating psychiatric disorder that can occur after a traumatic event. D-cycloserine (DCS), a partial N-methyl-D-aspartate (NMDA) receptor agonist, has been found to be effective in facilitating fear extinction in both animal and human studies of anxiety. However, the precise mechanism whereby DCS facilitates fear extinction is unknown. The aim of this study was to elucidate the molecular mechanism of action of DCS in facilitating fear extinction in a rat model of PTSD. Methods The PTSD animal model described by Siegmund and Wotjak (2007) was followed. Rats were grouped into four groups, Fear + saline (FS), Fear + DCS (FD), Control + Saline (CS) and Control + DCS (CD). Animal behavioural tests were conducted to determine which rats displayed anxiety-like behaviour. Next-generation RNA-seq and microRNA (miRNA)-seq and subsequent bioinformatics analyses were performed on RNA extracted from left dorsal hippocampi (LDH) to identify differentially expressed genes and miRNAs between the groups which might provide information on how DCS facilitates fear extinction. Target enrichment analysis was performed to determine whether the differentially expressed miRNAs targeted any of the differentially expressed genes identified in the RNAseq analysis. A luciferase assay was performed to functionally verify if the upregulation of rno-miR-31a-5p may have facilitated the downregulation of its predicted target gene, interleukin-1 receptor antagonist (IL1RN). Results A total of 424 genes were significantly down-regulated in the FD Well-adapted (FDW) group compared to the FS maladapted (FSM) group, of which 121 genes were predicted to be biologically significant to PTSD. Twenty seven genes were significantly upregulated in the FDW group compared to the FSM group, of which nine genes were predicted to be biologically relevant to PTSD. Genes transcribing components within the immune, proinflammatory and oxidative stress systems were downregulated in fear conditioned rats that received DCS. These factors mediate neuroinflammation and cause neuronal damage. DCS also regulated genes involved in learning and memory processes, genes that were previously associated with PTSD and disorders that commonly co-occur with PTSD. In addition, 32 miRNAs were differentially expressed between FDW and FSM groups. Functional luciferase analysis indicated that the upregulation of rno-mi31a-5p could have facilitated the downregulation of IL1RN as detected in RNAseq. Discussion Differential gene and miRNA expression analyses in this PTSD animal model enabled us to identify genes, miRNAs, and networks that might explain how DCS facilitates fear extinction. It is hypothesised that DCS attenuates neuroinflammation and subsequent neuronal damage, and also regulates genes involved in learning and memory processes. Gene and miRNA expression alterations may have mediated optimal neuronal functioning, plasticity, learning and memory which contributed to the fear extinction process. Furthermore, differentially expressed genes that were associated with other chronic medical conditions, such as cardiovascular disease and metabolic diseases, might help to explain the co- occurrence of these disorders with PTSD.Identifying the molecular underpinnings of fear extinction might bring us closer to understanding and effectively treating PTSD. BEHAVIORAL AND TRANSCRIPTOMIC ALTERATIONS IN 15Q13.3 HOMOZYGOUS KNOCKOUT MICE Annika Forsingdal1, Jacob Nielsen1, Marcelo Bertalan2, Thomas Werge2 1 H. Lundbeck A/S, 2Mental Health Center Sct Hans Background Genome wide association studies have revealed that certain copy number variants (CNVs) strongly increase the risk of schizophrenia and other psychiatric diseases. One such CNV is a 1.5 MB long hemizygous deletion located in the 15q13.3 region that covers 6 genes (FAN1, MTMR10, TRPM1, KLF13, OTUD7A, and CHRNA7). The 15q13.3 microdeletion increases the risk of schizophrenia, epilepsy and autism (Malhotra and Sebat, 2012). Human cases of homozygous microdeletion carriers have also been reported, all with severe impairments (Hoppman-Chaney et al., 2013). However, the mechanisms underlying increased disease risk in the 15q13.3 microdeletion syndromes are unknown. A mouse model of the human 15q13.3 hemizygous microdeletion syndrome, Df(h15q13)+/-, has been generated, and characterization of the model identified disease-related phenotypes (Fejgin et al., 2013). However, those phenotypes were relatively subtle, which complicates mechanistic exploration. Methods Homozygous 15q13 knockout mice, Df(h15q13)-/-, were bred from Df(h15q13)+/-. Df(h15q13)-/- mice were characterized by basic physiological and behavioral tests as well as disease related behavioral tests. Transcriptional changes were assessed by whole transcriptome RNAsequencing of brain and body samples from Df(h15q13)-/- and wildtype mice. Results Df(h15q13)-/- display physiological and behavioral impairments compared to wildtype mice. A number of genes are differentially expressed in Df(h15q13)-/- compared to wildtype. Differential expression is seen both in the central nervous system and in the periphery. Bioinformatic analysis of RNA sequencing data is ongoing. Discussion As expected, a number of genes are differentially expressed in the Df(h15q13)-/- mice. The expression profile of these mice will provide cues to which biological mechanisms that predispose 15q13 deletion carriers to psychiatric diseases and guide future mechanistic exploration. PHARMACOGENOMIC ENDOPHENOTYPES: WHAT CAN THE SUBJECTIVE RESPONSE TO D-AMPHETAMINE TELL US ABOUT RISK FOR PSYCHIATRIC DISORDERS? Abraham Palmer1 1 University of Chicago Background The subjective response to d-amphetamine is heritable and may serve as an endophenotype for a variety of psychiatric disorders, especially those related to dopaminergic signaling. Methods We performed a Genome Wide Association Study (GWAS) for the subjective responses to amphetamine using data from 398 non-drug abusing healthy volunteers. Response to amphetamine were measured using a double-blind, placebo-controlled, within-subjects design. We used sparse factor analysis to reduce the dimensionality of the data and then performed GWAS using genotypes from Affy 6.0 imputed to 1000 Genomes. Results We identified several putative associations; the strongest was between a factor reflecting the positive subjective effects of amphetamine and a SNP (rs3784943) in the 8th intron of cadherin 13 (CDH13; P?=?4.58×10-8), a gene previously associated with a number of psychiatric traits, including methamphetamine dependence. We have examined both CDH13 knockout rats and adiponectin knock out mice and observed differences in conditioned place preference, which offers additional support for the role of CDH13 in modulating the sensitivity to the subjectively positive effects of amphetamine. Additionally, we observed a putative association between a factor representing the degree of positive affect at baseline and a SNP (rs472402) in the 1st intron of steroid-5-alpha-reductase-?-polypeptide-1 (SRD5A1; P?=?2.53×10-7), a gene whose protein product catalyzes the rate-limiting step in synthesis of the neurosteroid allopregnanolone. This SNP belongs to an LD-block that has been previously associate Discussion None of the data from CDH13 KO rats or adiponectin knock out mice have been published. Some ongoing analyses of the human GWAS data will also be discussed. IDENTIFYING ENDOPHENOTYPES FOR DEPRESSION - A COMPOSITE TRAIT ANALYSIS Lynsey Hall1, Toni-Kim Clarke1, Ana-Maria Fernandez-Pujals1, Pippa Thomson1, Caroline Hayward1, Donald MacIntyre1, Chris Haley1, David Porteous1, Ian Deary2, Andrew McIntosh1 1 University of Edinburgh Background Despite heritability estimates of 31-42% genetic studies of major depressive disorder (MDD) have failed to identify any robust, replicable genetic risk loci. One method which may aid genetic discovery is to identify quantitative endophenotypes for depression. The aim of this study was to assess whether cognitive, mood and personality traits genetically correlated with depression could be used to generate a quantitative endophenotype for MDD where genetic correlation and heritability were jointly maximized. We further hypothesized this composite trait would have greater power to identify genetic risk variants for depression than the binary classification of case/control. Methods Generation Scotland: A Scottish Family Health Study (GS:SFHS) is a large family and population-based study with genotypic and extensive phenotypic information, including detailed data on mental health and ten measures of cognitive function, mood and personality. Bivariate heritability analysis of 21,340 individuals from GS:SFHS, conducted using social pedigree data, revealed five traits with a genetic correlation (rg) with depression of > 0.2. The three most highly correlated traits (General Health Questionnaire (rg=0.69), Mood Disorder Questionnaire (rg=0.62) and Eysenck Personality Questionnaire for Neuroticism (rg=0.58)) were used to create a composite trait. These were subjected to principal components analysis and the first unrotated principal component used as a quantitative measure of depression (h2=0.38, rg=0.79). Results Genome-wide association analyses of the composite trait (n=9,863; nSNPs=609,002), depression as a binary variable (n=1,700 cases, 7,634 controls) and recurrent depression (n= 1,147 cases, 7,634 controls) identified no genome-wide significant SNPs (p < 5x10-8). The top GWAS hit for the composite trait was rs4661250 (p = 1.1x10-7), located in the 3' intron of sushi domain-containing protein 4 (SUSD4) gene, which is highly expressed in the white matter of oligodendrocytes. White matter integrity is reduced in MDD suggesting a plausible role for SUSD4 in the aetiology of depression. Using summary data from the PGC GWAS of MDD, polygenic risk score profiles for MDD were generated in GS:SFHS. These scores were tested for their association with MDD and the newly derived composite trait. Polygenic score had a stronger association with and explained more of the variance of the composite trait (p=8.4x10-7, 0.4%) than depression (p=0.001, 0.1%) or recurrent depression (p=7.2x10-4, 0.1%). Discussion Given that the composite trait is more strongly associated with polygenic risk for MDD, using summary data from a completely independent sample, it suggests that the trait is successfully capturing a greater proportion of the heritable component of depression. However, this study is still underpowered to detect causal variants for depression whether analyzed as a binary or quantitative trait. The remainder of the GS:SFHS cohort (currently being genotyped), will afford a much larger GWAS sample (n= ~21,000; ~2750 cases, ~17,400 controls). Replicating these analyses in the larger cohort, in conjunction with larger collaborative efforts, may yield robust results which will aid the discovery of genetic variants associated with depression. OVERALL SESSION: AFFECTIVE DISORDERS: GENOMICS & MORE BIPOLAR DISORDER AND ITS RELATION TO MAJOR PSYCHIATRIC DISORDERS: A FAMILY- BASED STUDY IN THE SWEDISH POPULATION Jie Song1, Sarah E. Bergen 2, Ralf Kuja-Halkola 2, Henrik Larsson 2, Mikael Landén 3, Paul Lichtenstein 2 1 Department of Medical Epidemiology and Biostatistics, Karolinska Institutet, 2Department of Medical Epidemiology and Biostatistics, Karolinska Institutet, 3Institute of Neuroscience and Physiology, The Sahlgrenska Academy at Gothenburg University; Department of Medical Epidemiology and Biostatistics, Karolinska Institutet Background Bipolar disorder (BPD) shares genetic components with other psychiatric disorders; however, uncertainty remains about where in the psychiatric spectra BPD falls. To understand the etiology of BPD, we studied the familial aggregation of BPD and co-aggregation between BPD and schizophrenia, depression, anxiety disorders, attention deficit/hyperactivity disorder (ADHD), drug abuse, personality disorders and autism spectrum disorders (ASD). Methods A population-based cohort was created by linking several Swedish national registers. 54,723 BPD individuals were identified among 8,141,033 offspring from 4,149,748 nuclear families. The relative risk of BPD in relatives and co-occurrence of other psychiatric disorders in BPD patients and their relatives were compared to those of matched population controls. Structural equation modeling was used to estimate the heritability and tetrachoric correlation. Results The familial risks for relatives of BPD probands were 5.8-7.9 in first degree relatives, and decreased with genetic distance. Co-occurrence risks for other psychiatric disorders were 9.7-22.9 in BPD individuals and 1.7-2.8 in full siblings of BPD probands. Heritability for BPD was estimated at 58%. The correlations between BPD and other psychiatric disorders were considerable (0.37-0.62) and primarily due to genetic effects. The correlation with depression was the highest (0.62), and was 0.44 for schizophrenia. Discussion The high familial risks provides evidence that genetic factors play an important role in the etiology of BPD, and the shared genetic determinants suggest pleiotropic effects across different psychiatric disorders. Results also indicate BPD is in both the mood and psychotic spectra, but possibly more closely related to mood disorders. PSYCHIATRIC GENOMICS CONSORTIUM (PGC) BIPOLAR DISORDER GWAS OF 50,000 SAMPLES Eli Stahl1, PGC Bipolar Working Group 1 Icahn School of Medicine at Mount Sinai Background The purpose of the Psychiatric Genomics Consortium (PGC) is to conduct meta-analyses of genome-wide genetic data for psychiatric disease. Recognizing that individual GWAS studies are too small to have adequate power for gene discovery, an international PGC Working Group has focused on extending their meta-analysis of bipolar disorder (BD). Recently, we reported a combined GWAS of bipolar disorder in a sample of 16,731 individuals that identified two genome wide-significant loci (Nature Genetics, 2011). Here we present the results of PGC2 Bipolar Disorder GWAS, including data from 21,035 cases and 28,758 controls. Methods Data for 13,200 new case samples and 19,508 new controls of European decent were received from Germany, Bulgaria, Romania, Sweden, Norway, the UK, the US and Mexico. Subphenotype data acquisition is ongoing, with at least 11,888 cases of bipolar disorder 1 (BD1), 2,359 bipolar disorder 2 (BD2) and 938 schizoaffective bipolar subtype (SAB). Data were prepared by the PGC central analytic pipeline as described previously. The data were imputed with 1000 Genomes Project data and analyzed using standard logistic regression with MDS components as covariates. SNP-heritability analyses were conducted using GCTA, and polygenic scoring analyses using all SNPs were conducted as previously reported. Results Initial analyses of the entire dataset yield at least eleven genome-wide significant, and at least three new, bipolar risk loci. We continue to investigate substantial heterogeneity among the sample cohorts, revealed by leave-on-out BD polygenic risk score profiling. Bivariate analysis of a subset of the new data reveals that SNP-heritability of BD1 (0.35) is greater than that of BD2 (0.23, P=4x10-3 for difference from BD1), and greater than BD1-BD2 coheritability (0.23, P=4x10-4 for difference from BD1), consistent with an incomplete genetic correlation (rG=0.84) between BD1 and BD2 diagnoses. Polygenic risk scores based on other psychiatric disease GWAS differentiate between BD subphenotypes; for example, schizophrenia polygenic scores are higher in BD1 than BD2 (P=0.002). We also report initial lookups of suggestively associated SNPs in preliminary psychChip data, and pathway analyses of the primary GWAS results. Discussion In conclusion, we provide support for the importance and utility of continued GWAS exploration in bipolar disorder in efforts to increase the number of genetic loci with compelling association to bipolar disorder. INTERACTION BETWEEN GENETIC VARIANTS AND ENVIRONMENTAL ADVERSITY IN THE ETIOLOGY OF MAJOR DEPRESSIVE DISORDER Niamh Mullins1, Robert Power1, Ken Hanscombe1, Helen Fisher1, RADIANT, BACCs and GENDEP Investigators1, Rudolf Uher2, Anne Farmer1, Peter McGuffin1, Gerome Breen1, Cathryn Lewis1 1 King's College London, 2King's College London, Dalhousie University Background Depression is a common and disabling condition which results from a complex interaction between genetics and environmental factors. The genetic diathesis for major depressive disorder (MDD) is highly polygenic, resulting from the additive and multiplicative interaction of many genetic variants with small effect sizes. Adverse experiences such as childhood trauma and stressful life events (SLEs) are also risk factors. Gene-by-environment interaction studies in depression have typically investigated candidate genes, but polygenic scores that incorporate thousands of genetic variants simultaneously, better capture the genetic liability to a complex trait. Here, for the first time we test for an interaction between polygenic scores and environmental adversity in the etiology of major depressive disorder. Methods The RADIANT UK sample consists of patients with recurrent MDD and controls screened for the absence of psychiatric illness. Blood samples were genotyped genome-wide. The List of Threatening Experiences Questionnaire was used to assess the numbers of SLEs in the 6 months prior to worst episode of depression (cases) or interview (controls). The number of SLEs was adjusted for age and sex. The Childhood Trauma Questionnaire was also used to assess exposure to sexual, physical and emotional abuse, physical and emotional neglect in childhood. Discovery results from a mega-analysis on MDD by the Psychiatric Genomics Consortium (with the RADIANT UK sample removed) were used to construct MDD polygenic scores for each individual in the RADIANT UK validation dataset. Ability to predict case/control status was tested using logistic regression with an interaction between polygenic score and environmental adversity and principal components as covariates to adjust for population stratification. Results In 1605 MDD cases and 1064 controls, cases reported a significantly greater number of SLEs than controls (mean cases= 1.57, mean controls= 0.68, P < 0.001). Polygenic scores for depression showed significant predictive ability for depression in the RADIANT UK sample (P = 1.8x10-6, Nagelkerke’s pseudo-R2 = 0.011). Polygenic score-by-SLE interaction showed no predictive ability for case/control status. Genetic liability to bipolar disorder and schizophrenia will also be examined using results from the Psychiatric Genomics Consortium as well as testing for interactions between polygenic scores and childhood trauma. Discussion Polygenic scoring is an appropriate approach to investigating the genetics of a complex trait. Including environmental risk along with genetics is important in studying the etiology of major depressive disorder and using polygenic scores rather than candidate genes may increase statistical power to detect gene-by-environment interactions. SHARED GENETIC EFFECTS CONTRIBUTING TO RISK OF MAJOR DEPRESSIVE DISORDER ACROSS EUROPEAN AND HAN CHINESE POPULATIONS T. Bernard Bigdeli1, Stephan Ripke2, Silviu-Alin Bacanu3, Roseann E. Peterson3, Ayman H. Fanous4, Li Qibin5, Yu Xin6, Jonathan Flint7, Kenneth S. Kendler3, Patrick F. Sullivan8, PGC MDD Workgroup9, CONVERGE 1 VIPBG, 2Analytic and Translational Genetics Unit, Massachusetts General Hospital, 3 Virginia Institute for Psychiatric and Behavioral Genetics, Department of Psychiatry, Virginia Commonwealth University School of Medicine, 4Mental Health Service Line, Washington VA Medical Center, 5Beijing Genomic Institute, 6 Institute of Mental Health, Peking University, Beijing, CN, 7 Wellcome Trust Centre for Human Genetics, 8Departments of Genetics and Psychiatry, Center for Psychiatric Genomics, University of North Carolina at Chapel Hill Background Major depressive disorder (MDD) is a common, complex psychiatric disorder and a leading cause of disability worldwide. Although modestly heritable (~30-40%), a complex genetic architecture has hindered efforts to detect robustly associated genetic risk variants. Furthermore, the extent to which liability to MDD is shared across ancestrally divergent populations is unknown. Methods We combined single nucleotide polymorphism (SNP) summary statistics from CONVERGE (China, Oxford and VCU Experimental Research on Genetic Epidemiology) and the Psychiatric Genomics Consortium (PGC) studies of MDD, representing 11139 Han Chinese (5647 cases, 5492 controls) and 18663 European (9447 cases, 9215 controls) subjects, respectively. We performed genomewide association study (GWAS) meta-analysis, consisting of 15094 cases and 14707 controls. Secondary GWAS used phenotypes consisting of recurrent MDD (>2 episodes), only females, and only females with recurrent MDD. For varying P-value thresholds (PT), we determined the fraction of CONVERGE SNPs that had the same direction of effect as those in the PGC study and assessed the predictive accuracy of polygene scores constructed from each study’s results. Results Of the observed associations not previously reported in GWAS of either dataset individually, the strongest evidence was for females-only recurrent MDD at SNPs immediately upstream of SLC29A4 (7p22.1; P=6.2x10-8). This locus encodes a transmembrane protein known to facilitate reuptake of serotonin and dopamine into presynaptic neurons. A binomial sign test of the fraction of CONVERGE SNPs demonstrating a direction of effect consistent with the PGC results was most significant at a PT [for consistency with above] threshold of .05 (P=2.4x10-5). A PGC-trained polygene score explained less than 0.3% of the variance in MDD risk in CONVERGE (P=1.65x10-5; recurrent MDD; PT>0.4); a CONVERGE-trained score explained slightly more than a tenth of a percent of the variance in the PGC (P=8.82x10-3; females-only MDD; PT>0.5). Discussion We have conducted a large, cross-population meta-analysis of MDD, and the first such study to combine European and Han Chinese samples. After multiple-testing correction for the number of GWAS performed, no single variant remained significant at genome-wide levels, though replication efforts are ongoing. However, the observation that a significant fraction of SNPs exhibit a consistent direction of effect across European and Chinese studies, taken together with the significant, bidirectional predictive values of polygene scores, suggests a shared polygenic risk of MDD across these populations. These findings support a complex etiology for MDD and possible population differences in predisposing genetic factors, with important implications for future genetic studies. THE EFFECT OF THE FTO GENE ON BODY-MASS INDEX IS INCREASED BY THE PRESENCE OF DEPRESSIVE DISORDER: A META-ANALYSIS OF 13,701 INDIVIDUALS Margarita Rivera 1, Adam E Locke2, Tanguy Corre3, Darina Czamara4, Christiane Wolf4, Ana ChingLopez5, Yuri Milaneschi6, Dorret I Boomsma7, Stefan Kloiber4, Bertram Müller-Myhsok4, Brenda WJH Penninx6, Martin Preisig8, Anne E Farmer9, Cathryn M Lewis9, Gerome Breen9, Peter McGuffin9 1 Institute of Psychiatry, King's College London, 2Department of Biostatistics and Center for Statistical Genetics, University of Michigan, 3Department of Medical Genetics, University of Lausanne and Swiss Institute of Bioinformatics, 4Max-Planck-Institute of Psychiatry, 5Department of Psychiatry, School of Medicine, University of Granada, 6Department of Psychiatry and EMGO Institute for Health and Care Research, VU University Medical Center/GGZ inGeest, 7Department of Biological Psychology, VU University Amsterdam, 8Department of Psychiatry, Lausanne University Hospital, 9MRC SGDP Centre, Institute of Psychiatry, King’s College London Background Depression and obesity are highly prevalent major public health problems that frequently co-occur. Both conditions are major risk factors for chronic (physical) diseases such as type 2 diabetes, cardiovascular disease and hypertension among others. Shared aetiological factors have been found between depressive disorder and obesity, although the nature of this association remains unclear. Recently, we reported the first study implicating FTO in the association between depression and obesity. We aimed to confirm these findings by investigating the FTO rs9939609 polymorphism in a metaanalysis of 13,701 individuals. Methods The sample consists of 6,902 depressed patients and 6,799 controls from five independent studies (Radiant, PsyCoLaus, GSK, MARS and NESDA/NTR). As common inclusion criteria we looked for the studies with information available on a lifetime DSM-IV diagnosis of depressive disorder, body mass index (BMI) and genotype data for the rs9939609 FTO polymorphism. Homogeneous ethnicity (Caucasian) was also required for each study to reduce the risk of population stratification. In each individual study, linear regression models for quantitative traits assuming an additive genetic model were performed to test for association between the rs9939609 and BMI. We also tested for the interaction between rs9939609 variant and depression status for an effect on BMI. Age, sex and principal components were controlled for including them as covariates in the models. Fixed-effects and randomeffects meta-analyses based on inverse-variance-weighted effect size were performed using METASOFT. Results Fixed-effects meta-analyses support a significant association between rs9939609 polymorphism and BMI in the whole sample (ß=0.07, p=1.29x10-12) and in depressive cases (ß=0.12, p=6.92x10-12). No association was found in the control group (ß=0.02, p=0.15). Fixed and random-effects metaanalyses further support a significant interaction between FTO, BMI and depressive disorder (fixedeffects: ß=0.13, p=3.087x10-7; random-effects: ß=0.12, p=0.027), wherein depressed carriers of the risk allele have increased BMI risk. Subjects with depression have an additional increase of 2.2% in BMI for each risk allele, over and above the main effect of FTO and disease status. Discussion This meta-analysis demonstrates a significant interaction between FTO, depression and BMI, indicating that depression increases the effect of FTO on BMI. Depression-related alterations in key biological processes may interact with the rs9939609 FTO risk allele to increase obesity. These findings will have potential implications for predicting which patients with depression are at risk of high-BMI related disorders, but could also have more general relevance to the population as a whole. The identification of common causes for its comorbidity can help better clinical awareness and ascertainment of such comorbid states. FAMILIALITY AND SNP HERITABILITY OF AGE AT ONSET AND EPISODICITY IN MAJOR DEPRESSIVE DISORDER Panagiotis Ferentinos1, Artemis Koukounari 2, Robert Power 3, Margarita Rivera3, RADIANT Study Investigators, Rudolf Uher 4, Gerome Breen 3, Ian W. Craig3, Anne E. Farmer 3, Peter McGuffin 3, Cathryn M. Lewis 3 1 University of Athens, 2nd Department of Psychiatry, 2Department of Biostatistics, Institute of Psychiatry, King’s College London, London, United Kingdom, 3MRC Social Genetic and Developmental Psychiatry Centre, Institute of Psychiatry, King’s College London, London, United Kingdom, 4Dalhousie University Background Despite extensive research in the field, the genetic architecture of major depressive disorder (MDD) remains highly elusive. Phenotypic and genetic heterogeneity have been pinpointed as mainly responsible for as yet unfruitful investigations. Promising strategies to dissect MDD heterogeneity have mainly relied on subphenotypes, such as age at onset (AAO) and recurrence/ episodicity. Recurrent and early-onset forms are most consistently associated with higher familiality and heritability of MDD. Yet, to date evidence on whether these subphenotypes are per se familial or heritable is scarce in MDD. The aims of this study are, therefore: first, to investigate the familiality of AAO and episode frequency of MDD; second, to assess the SNP heritability of AAO and episode frequency in unrelated subjects with MDD. Methods For investigating familiality, we used 1498 subjects with recurrent depression from the DeNt (Depression Network) affected siblings study (691 families with 2-5 affected full siblings). Square root AAO (sqrtAAO) was fitted into a linear mixed model (LMM) with center and family as nested random effects. SqrtAAO familiality was measured by the family-level intraclass correlation coefficient (ICC). Depressive episode count was fitted into a negative binomial generalized linear mixed model with center as fixed and family as random effects. An ICC was calculated with a recently described formula. For estimating SNP heritabilities, we used 2695 unrelated MDD cases from the RADIANT studies. SqrtAAO was adjusted for gender, study and center in a LMM and standardized residuals were saved. Episode count was similarly adjusted for gender, age, study and center in a negative binomial model and deviance residuals were saved. Derived residuals were then used with the GREML method in GCTA software. Results In the DeNt dataset, the ICC for sqrtAAO was estimated at 0.28 (SE 0.054, p<0.001) and ICC for episode frequency was 0.071 (SE 0.011, p<0.001). Analyses were underpowered for estimating SNP heritability of AAO and episodicity in the RADIANT dataset (power 0.66 and 0.07, respectively; Visscher et al 2014 PLOS Genetics). The SNP-heritability estimates obtained were 0.16 (SE 0.13, p=0.1) for AAO and 0.095 (SE 0.18, p=0.29) for episodicity. Discussion Significant familiality of both AAO and episodicity were obtained in the DeNt sibling sample; a moderate and small proportion, respectively, of their variance could be attributed to family membership. However, GREML analyses of SNP heritability were underpowered and we were unable to confirm that common SNPs capture this information; larger samples are required to estimate the SNP heritability of AAO and episodicity in MDD. OVERALL SESSION: SCHIZOPHRENIA: GENOMICS & MORE THE IMPACT OF CNVS ON CNS FUNCTION IN SCHIZOPHRENIA Andrew Pocklington1, Elliott Rees2, David H. Kavanagh2, Jun Han2, Jennifer L. Moran3, George Kirov2, Steven A. McCarroll3, James T.R. Walters2, Michael J. Owen2, Michael C. O'Donovan2 1 Cardiff University, 2MRC Centre for Neuropsychiatric Genetics & Genomics, Cardiff University, UK, 3 Stanley Centre for Psychiatric Research, Broad Institute of MIT and Harvard Background Individuals with schizophrenia have been found to possess an increased burden of large, rare CNVs compared to matched controls in most studies. Set based analyses applied to case-control data indicate enrichment of schizophrenia CNVs for synaptic and developmental gene sets, while de novo case CNVs have been found to be enriched for members of postsynaptic N-methyl-D-aspartate receptor (NMDAR) and neuronal activity-regulated cytoskeleton-associated (ARC) protein complexes (Kirov et al., 2012). Further supporting a role for these complexes in schizophrenia, exome sequencing has uncovered enrichment of both ARC and NMDAR gene sets for rare de novo point mutations (Fromer et al, 2014). Here we present a detailed functional analysis of CNVs called in 12,492 schizophrenia cases and 16,996 controls, drawn from three separate studies (ISC, 2008; Levinson et al., 2011; Hamshere et al., 2013). Methods Starting from the primary hypothesis that schizophrenia reflects perturbation of brain function and development, we analyzed the enrichment of a circumscribed set of annotations based on proteomic, RNA sequencing and functional genetic data. As a secondary, hypothesis-generating analysis, we then searched for any additional gene-set enrichment in the more comprehensive range of annotations available from large, freely accessible databases. Gene set enrichment analysis of large, rare CNVs (>100kb, frequency < 1%) was performed using a logistic regression model with covariates to correct for CNV size, number of genes hit and the inclusion of multiple studies and genotyping chips. Results When compared to permuted data a consistent excess of associated CNS gene sets was observed across multiple significance thresholds. Gene sets linked to learning and memory, synaptic physiology and postsynaptic protein complexes were all highly associated. In particular, there was strong, independent evidence of enrichment in glutamatergic PSD-95 and NMDAR complexes. There was no evidence of any additional enrichment in non-CNS gene sets. Discussion There is good evidence that the disruption of specific elements of nervous system function is associated with schizophrenia. Evidence is strongest for behavioral and physiological correlates of learning and closely related postsynaptic complexes. These associations support the disease relevance of functional processes previously implicated through the study of de novo CNVs and rare variants. FUNCTIONAL ANALYSIS OF THE SCHIZOPHRENIA AND AUTISM-ASSOCIATED GENE, TRANSCRIPTION FACTOR 4 (TCF4), DURING CORTICAL DEVELOPMENT Brady Maher1, Matthew Rannals1, Stephanie Cerceo-Page1, Morganne Campbell1, Aaron Briley1, Andrew Jaffe1, Ran Tao1, Thomas Hyde1, Joel Kleinman1, Daniel Weinberger1 1 Lieber Institute for Brain Development Background Schizophrenia is a neurodevelopmental disorder with unknown pathophysiology. Genome- wide association studies (GWAS) have identified a number of loci associated with increased risk for SZ and several of these risk variants are located within introns of Transcription Factor 4 (TCF4; E2-2, ITF2). In addition, autosomal dominant mutations in TCF4 result in Pitt Hopkins Syndrome (PTHS), a rare neurodevelopmental disorder characterized by a spectrum of symptoms including hyperventilation, seizures, autistic behaviors, intellectual disability, and brain malformations. Currently, the molecular mechanisms and underlying pathophysiology responsible for these two disorders are not understood. Our goal is to determine the function of TCF4 during cortical development and to understand the molecular mechanism of risk that is associated with genetic variants of TCF4. Methods To test the function of TCF4 in the developing neocortex we altered its expression by transfecting layer 2/3 pyramidal cells in the rat medial prefrontal cortex by in utero electroporation. We knockdown TCF4 expression using two shRNA constructs that target independent sequences within the TCF4 transcript and over-expressed human TCF4 with recombinant TCF4 constructs. Functional analysis was performed using whole-cell electrophysiology and confocal imaging in acute brain slices. To gain insights into the molecular mechanisms responsible for increased risk associated with genetic variants of TCF4, we analyzed RNA sequencing data obtained from the dorsal lateral prefrontal cortex of postmortem brains from schizophrenia patients (n=107) and controls (n=107). Results Embryonic knockdown of TCF4 in layer 2/3 pyramidal cells resulted in decreased intrinsic excitability and the ectopic appearance of spike-frequency adaptation. These phenotypes were associated with an increase in the afterhyperpolarization (AHP) amplitude and were rescued by manipulating intraand extracellular Ca2+ levels. Embyronic over-expression of the full-length human isoform TCF4B significantly accelerated neuronal differentiation and migration. In addition, expression of either TCF4B or a shorter isoform TCF4A, which lacks a nuclear localization sequence, resulted in the abnormal distribution of cortical columns. Lastly, analysis of human RNA sequencing data from postmortem dorsal lateral prefrontal cortex (DLPFC) identified a single TCF4 5’ exon that showed significantly decreased expression in schizophrenia patients compared to controls. This differentially expressed exon is unique to TCF4H and in utero transfection of this isoform did not produce abnormal cortical columns. Discussion Our results suggest the dosage of TCF4 is critical to cortical development and neuronal physiology. Knockdown of TCF4 produces defects in neuronal excitability and over-expression results in abnormal cortical columns, the presumed microprocessing unit of the cortex. By analyzing RNA sequencing data in human brain, we have now identified a specific isoform of TCF4 that infers schizophrenia risk, suggesting that this may be the molecular mechanism of the clinical association with schizophrenia. We believe these novel data will allow us to model schizophrenia in our rat model with high fidelity. Future experiments will be designed to specifically knockdown this risk associated TCF4 isoform and determine its effects on cortical development and neuronal physiology. ADVANCED PATERNAL AGE, DE NOVO MUTATIONS, GENETIC LIABILITY AND THE RISK OF PSYCHIATRIC ILLNESS Peter Visscher1, Jacob Gratten1, Naomi Wray1, Wouter Peyrot2, John McGrath1, Michael Goddard3 1 The University of Queensland, 2VU University Medical Center, 3University of Melbourne Background There is evidence that the offspring of older fathers are at increased risk of psychiatric disorders such as schizophrenia and autism, and it is well established that the de novo point mutation rate increases with paternal age, and that gene-disrupting de novo mutations confer risk for psychiatric illness. A widespread assumption in the field is that a causal relationship exists between these observations - i.e. that paternal age-related mutations are sufficient to explain the epidemiological findings. However, not all the evidence is consistent with this conclusion and an alternative explanation is that elevated genetic liability to psychiatric illness may lead to delayed fatherhood. Methods We used population genetic models to explore whether recent empirical estimates of the de novo mutation rate can explain increased rates of psychiatric disorders in those with older fathers (defined as fathers 10 years older than average), or if other mechanisms (e.g. delayed fatherhood in men with a high liability to psychiatric disease) are more plausible. We considered four models: (1) a model in which new mutations are assumed to act independently to cause psychiatric illness, (2) an equivalent model in which the rate of causal mutations is also influenced by age-related selfish spermatogonial selection in the testis ("selfish selection"), (3) a model in which new and existing mutations combine additively in their effect on liability to psychiatric illness, (4) a model in which paternal age-at-first-child is correlated with liability for psychiatric illness, and/or in which mating is assortative with respect to disease liability. Results In models considering age-related de novo mutations (1,3), the relative risk (RR) to children of older fathers was low (e.g. <1.05) for all parameter combinations consistent with empirical observations on the RR to siblings. Thus if a disease is heritable, in the sense of a high RR to siblings, few of the cases are due to de novo mutations and only some of these are due to mutations in older fathers. Similarly the RR to offspring due to age-related selfish selection was trivial (e.g. ~1.01) for most plausible combinations of model parameters. Conversely, a modest correlation (e.g. <0.2) between paternal age-at- first-child and liability to psychiatric illness recapitulated published estimates (i.e. ~1.5) of the RR to children of older fathers. Discussion Our models suggest that shared genetic factors, rather than age-related de novo mutations, are the primary genetic mechanism underlying the relationship between advanced paternal age and risk of psychiatric disorders in offspring. However, our simple models do not represent the true complexity of the aetiology of common psychiatric disorders and it is possible that a more complex and nuanced combination of factors underlie the epidemiological observations. There is a compelling need for more primary data to investigate this question and to enable well-powered assessments of model predictions. CHROMATIN IMMUNOPRECIPITATION AND NEXT-GENERATION SEQUENCING ANALYSIS IMPLICATES TRANSCRIPTION FACTOR 4 (TCF4) IN THE REGULATION OF NEURONAL DEVELOPMENT AND CELL ADHESION PATHWAYS Joseph McClay1, Hanzhang Xia1, Lin Ying Xie1, Gaurav Kumar1, Douglas Sweet1, Robin Chan1, Srilaxmi Nerella1, Karolina Aberg1, Patrick Sullivan2, Edwin van den Oord1 1 Virginia Commonwealth University, 2University of North Carolina at Chapel Hill Background The TCF4 locus on chromosome 18 has been consistently associated with schizophrenia (SZ) in meta-analyses of genome-wide studies. The strength of current evidence suggests that functional characterization of this gene would be timely. TCF4 encodes a basic helix-loop-helix transcription factor that recognizes an Ebox motif ('CANNTG'). However, this motif is too small and non-specific to predict TCF4 binding computationally and no study has yet mapped genome-wide TCF4 binding empirically. Knowledge of TCF4 binding sites would enable us to build TCF4 regulatory networks and could provide clues to SZ pathogenic processes. Here, we use chromatin-immunoprecipitation coupled with nextgeneration sequencing (ChIP-seq) to systematically map genome-wide binding of TCF4 in CNS cell lines. Methods Antibody screening followed ENCODE guidelines, with three antibodies exhibiting clean Western blots, immunoprecipitate (IP) cross-reactivity and presence of TCF4 in IP as confirmed by mass spectrometry. All three antibodies were used to perform ChIP in SH-SY5Y cells, a commonly used CNS model. Each ChIP-seq experiment used 12 million cells, with two duplicate assays per antibody. Mock IP (IgG) and input DNA controls were used. ChIP DNA was sequenced on a SOLiD 5500xl Wildfire (Life Technologies) using single-end 50 bp reads. Alignment to hg19, followed by stringent quality control, yielded on average 36 million uniquely aligned reads per duplicate, or 73 million per antibody. This greatly exceeded the ENCODE standard 20 million minimum. ChIP-seq analysis was performed using SPP, while pathway analysis used ConsensusPathDB. Genome-wide gene expression array data (n=72 subjects) was from the Stanley Medical Research Institute post-mortem brain collection. Results Best Minimal Saturated Enrichment Ratios (MSERs) were with antibody ITF-2 (N-16) (Santa Cruz Biotech) using mock IP control. MSERs for each duplicate were 2.1 and 3.2, indicating good saturation, with 781 sites implicated at FDR<0.05. DNA input control comparisons also worked well, with 80-85% of the top 100 sites typically overlapping between duplicates. The top site detected by all antibodies was chr15: 51922178-89, located < 10 bp from a known Ebox ('CATGTG') and 7.5 kb upstream from DMXL2. Other robust findings included binding sites at ZEB2 and NRCAM. Pathway analysis of genes implicated (±10 kb) by the top 250 binding sites yielded significant results for monoamine neurotransmitter degradation (p=4.85x10-5, q=0.013), focal adhesion (p=0.002, q=0.08) and axon guidance (p=0.003, q=0.08). Finally, genes harboring TCF4 binding sites showed significant expression differences in brain tissue of subjects with psychosis versus controls (p < 0.01, 10,000 permutations). Discussion DMXL2 is involved in regulating Notch signaling, ZEB2 directs migration of cortical neurons and NRCAM encodes the neuronal cell adhesion molecule. These top genes, plus our pathway analysis, indicate that TCF4 regulates several genes involved in neuronal development and cell adhesion. Biologically, this suggests a plausible role for TCF4 in SZ etiology. This role is further supported by our observation that TCF4-regulated genes show altered expression in patients with psychosis. We plan to extend our ChIP-seq methods to study TCF4 in other CNS cell types. SHANK3 VARIANTS CONFER RISK FOR SCHIZOPHRENIA AND INDICATE A GENETIC OVERLAP WITH AUTISM SPECTRUM DISORDERS Simone Berkel1, Ana deSena2, Franziska Degenhardt3, Birgit Weiss2, Ralph Roeth2, Marcella Rietschel4, Markus Noethen3, Gudrun Rappold2 1 Institute of Human Genetics Heidelberg, 2Heidelberg, 3Bonn, 4Mannheim Background The SHANKs are postsynaptic scaffolding proteins at glutamatergic synapses in the brain that are essential for proper synapse formation and maintenance. The SHANK gene family (comprising SHANK1, SHANK2 and SHANK3) is linked to a spectrum of neurodevelopmental disorders, including intellectual disability and autism spectrum disorders (ASD). Schizophrenia (SCZ) is a neuropsychiatric disease with high variability in the clinical phenotype, characterized by major impairments in perception of reality and disorganized thought or behavior. Different studies have already pointed to an impairment of glutamatergic synaptic plasticity as an underlying cause of SCZ pathology. Methods To elucidate a putative contribution of genetic SHANK3 variants to the etiology of SCZ, we sequenced the gene in 500 affected individuals and compared the sequencing results to ancestrally matched controls. Results Novel SHANK3 missense variants were identified in 1.6 % of the screened individuals, three of which were predicted as deleterious by different algorithms. We identified disease risk alleles of 3 uncommon variants, with study-wide (c.4947C>T, P=7xE-06) and genome-wide significance (c.2997C>T, P=1.4xE-08). Combined with previous studies a rare amino acid exchange G>V was found in 2 out of 685 SCZ patients and in 4 out of 1972 individuals with autism spectrum disorders (ASD), but not in 9082 controls. Discussion We conclude that the SHANK3 gene harbors different genetic variations predisposing to SCZ, ranging from common and uncommon variants to rare deleterious missense mutations. The SHANK3-G>V variant found in both ASD and SCZ patients, points to an overlapping genetic contribution of SHANK3 to both neuropsychiatric disorders. METHYLOMIC PROFILING OF HUMAN BRAIN TISSUE SUPPORTS A NEURODEVELOPMENTAL ORIGIN FOR SCHIZOPHRENIA Jonathan Mill1, Ruth Pidsley2, Joana Viana1, Eilis Hannon1, Helen Spiers2, Claire Troakes2, Safa Al-Saraj2, Naguib Mechawar3, Gustavo Turecki3, Leonard Schalkwyk2, Nicholas Bray2 1 University of Exeter, 2King's College London, 3McGill University Background Schizophrenia is a severe neuropsychiatric disorder that is hypothesized to involve disturbances in early brain development. The neurobiological mechanisms underlying the disorder remain largely undefined, and molecular evidence for in utero disturbances in schizophrenia is currently lacking. Here, we describe a systematic study of schizophrenia-associated methylomic variation in the adult brain and its relationship to changes in DNA methylation during human fetal brain development. Methods Our ‘discovery’ cohort comprised prefrontal cortex (PFC) and cerebellum samples from schizophrenia patients and matched (for sex, age and sample quality markers (e.g. pH)) control donors archived in the MRC London Brain Bank for Neurodegenerative Disease. We quantified genome-wide patterns of DNA methylation using Illumina Infinium HumanMethylation450 BeadChip (450K array). Bisulfite-pyrosequencing was used to validate the 450K array data for three schizophrenia-associated differentially methylated positions (DMPs). We subsequently generated a 'replication' 450K array PFC dataset using schizophrenia and control brains archived at the Douglas Bell-Canada Brain Bank, Montreal, Canada. Finally, schizophrenia-associated DMPs were tested for an association with brain development using a unique 450K DNA methylation dataset generated by our lab using human fetal brain tissue (n=179, range 23-184 days post-conception. Results We identify significant disease-associated differential DNA methylation at multiple loci, particularly in the prefrontal cortex (PFC), and confirm these differences in an independent set of adult brain samples. Our data reveal discrete modules of co-methylated loci associated with schizophrenia that are highly significantly enriched for genes involved in neurodevelopmental processes. Methylomic profiling in human fetal cortex samples (spanning 23 to 184 days post-conception) showed that schizophrenia-associated differentially methylated positions (DMPs) are significantly enriched for loci at which DNA methylation is dynamically altered during human fetal brain development. Discussion Our data strongly support the hypothesis that the etiology of schizophrenia has an important early neurodevelopmental component, with epigenetic mechanisms likely contributing to these disturbances. Wednesday, October 15, 2014 1:00 PM - 2:30 PM Concurrent Oral Sessions OVERALL SESSION: TRANSDIAGNOSTIC APPROACHES, OCD, AND EATIND DISORDERS DIFFERENTIAL GENIC BURDEN OF CODING AND REGULATORY VARIANTS IN HUMAN OBSESSIVE-COMPULSIVE DISORDER: GUIDED BY NATURAL CANINE MODEL AND INDUCED MOUSE MODEL Hyun Ji Noh1, Hyun Ji Noh1, Ruqi Tang2, Jason Flannick1, Colm O'Dushlaine1, Ingegerd Elvers1, Ross Swofford1, Michele Perloski1, Jeremy Johnson1, S. Evelyn Stewart3, James K. Knowles4, Carol Mathews5, Guoping Feng2, Jeremiah M. Scharf6, Elinor K. Karlsson7, Kerstin Lindblad-Toh8 1 Broad Institute of MIT and Harvard, 2McGovern Institute , 3British Columbia Mental Health and Addictions Research Institute, University of British Columbia, 4Department of Psychiatry and The Behavioral Sciences, Zilkha Neurogenetic Institute, Keck School of Medicine, University of Southern California, 5University of California San Francisco, 6Massachusetts General Hospital, 7FAS Center for Systems Biology, Harvard University, 8Science for Life Laboratory, Uppsala University Background Obsessive-compulsive disorder (OCD) is a common, complex genetic disorder. A prior genome-wide association study (GWAS) on 1865 cases and 6357 controls implicated glutamate signaling, but no SNPs were associated at genome-wide significance. In a natural model (dog), we found four genes (CDH2, CTNNA2, PGCP, ATXN1), all involved in synapse function and maintenance, through GWAS and targeted re-sequencing of predisposed dog breeds. Notably, many of the top human and canine SNPs fall in non-coding regions, and in dogs, we have shown that two such SNPs have regulatory function in a human neural cell line. In an artificial model, mouse, optogenetic control of the orbitofronto-striatal pathway governs compulsive behavior, implicating this specific neural circuit in OCD. Methods We aimed to identify genes and networks that harbor risk alleles by re-sequencing 592 DSMIV OCD cases and 560 matched controls. We targeted the coding and non-coding, evolutionarily constrained sequence for 608 genes, selected from genetic studies of OCD and related disorders, including genes found in the canine OCD GWAS and the orbitofronto-striatal pathway implicated in mouse. In order to increase power and to account for potential different architecture between coding and regulatory variants, we evaluated the genic burden of all, coding and regulatory variants separately. We also evaluated a polygenic burden of variants using 989 gene ontology (GO) sets representing our target set, covering diverse brain-related functions from synaptic transmission and cytoskeleton to receptors and ion channels. Results Five genes had excess variant burdens significantly associated with OCD after multiple testing procedures (MTP). Two had excess coding variants in cases, two had excess regulatory variants, and one had excess both variant types. Literature suggests that genes with coding variants involve synaptic composition while genes with regulatory variants involve synaptic maintenance. The gene with both variant types involves signaling molecules for cell migration and maturation. Considering rare variants only (allele frequency<0.01), no significant burden was found, suggesting a major role for common risk alleles. Among the 989 GO sets analyzed for polygenic burden, neuronal migration and developmental signaling were nominally associated with OCD (MTP in progress). We also identified a number of candidate rare variants from the top genes that we are currently validating by genotyping. Discussion This is the first study to report robust genetic associations to OCD (strict MTP). We were able to achieve this through small-scale sequencing due to several factors: 1) Our target space included regulatory regions where many risk alleles reside, capturing many causal variants; 2) Association signals mainly emerged from common alleles, making the burden test sensitive. Our results are consistent with recent genome complex trait analysis showing OCD heritability largely arises from common alleles (although for rare variants our sample size may be underpowered); 3) Separate analyses of coding and regulatory variants revealed 80% of our genes, implying stratification improved power. In short, our study shows that regulatory and coding variants are both critical in OCD but may affect different types of genes. Our approach, which combined insights offered by natural and artificial models of OCD with targeted human genome sequencing, is yielding new insights into the genetic etiology of OCD. CORE-EXOME CHIP STUDY OF LOW-FREQUENCY VARIANTS IDENTIFIES GENOMEWIDE SIGNIFICANT HITS ASSOCIATED WITH ANOREXIA NERVOSA Laura Huckins1, Konstantinos Hatzikotoulas1, Laura Thornton2, Lorraine Southam1, GCAN GCAN, David Collier3, Patrick Sullivan2, Cynthia Bulik2, Eleftheria Zeggini1 1 Wellcome Trust Sanger Institute, 2University of North Carolina at Chapel Hill, 3King's College London Background Anorexia nervosa (AN) is a neuropsychiatric disorder presenting with extremely low body weight, and a marked fear of gaining weight. AN has the highest mortality of any psychiatric disorder, and affects roughly 0.9% of women. Very little is known about the biological mechanisms which underlie AN; two small GWAS have been completed and have yet to identify genome-wide significant hits. No effective medications are available, and treatment outcome for AN remains unacceptably poor. Methods Our study comprises 2,376 female AN cases and >22,000 controls, genotyped on the CoreExome Chip. Samples derive from eight different populations; care has been taken to ensure that cases and controls are ancestrally matched. The CoreExome Chip enables us to study both common and lowfrequency variants simultaneously; our study is the first to examine the role played by low-frequency and rare variants in AN. Results Analysis is currently complete across three of the eight contributing populations: Norway, with 87 cases and 100 controls; Finland, 163 cases, 5,300 controls; and the UK, 181 cases and 10,034 controls. We have performed a meta-analysis across these three populations and thus far have identified four genome-wide significant signals: exm370124, exm462797, exm464785, exm2116552. These four variants are all low frequency, mis-sense variants. We looked at the frequency of these SNPs in both cases and controls. All SNPs were extremely low frequency in the control populations, with highest MAF between 0.005 and 0.01. SNPs were also low frequency in the cases, with highest MAF between 0.01 and 0.10. Effect sizes for each SNP were high, and the same direction of effect was noted for every SNP in at least 2/3 populations. Maximum effect sizes for each SNP were between 6.6 and 74.5. Discussion One of these associated variants (exm464785) lies in RASGRF2, a gene that has previously been associated with eating disorders (Wade et al 2013), albeit not at a genome-wide significant level. This is the first genome-wide significant variant that has been associated with AN. We hope that this will enable further studies into the functional mechanisms underlying AN, and perhaps be a first step towards establishing effective medications and treatment. Further, all four hits that have been identified are very low frequency and could not possibly have been identified in previous GWAS studies. This may be a good indication that low-frequency, Core-Exome chip type studies have potential to reveal new associated variants across a range of psychiatric disorders. MEGA-ANALYSIS OF AGE AT ONSET OF BIPOLAR DISORDER, MAJOR DEPRESSIVE DISORDER AND SCHIZOPHRENIA IN THE PSYCHIATRIC GENOMICS CONSORTIUM T. Bernard Bigdeli1, Stephan Ripke2, Silviu-Alin Bacanu3, Richard L. Amdur4, Aiden Corvin5, Cathryn M. Lewis6, Robert A. Power7, Andrew McQuillin8, S. Hong Lee9, Naomi R. Wray9, Kenneth S. Kendler3, PGC Cross-disorder Group, PGC MDD Workgroup, PGC Bipolar Disorder Workgroup, PGC Schizophrenia Workgroup, Ayman H. Fanous4 1 VIPBG, 2Analytic and Translational Genetics Unit, Massachusetts General Hospital, 3Virginia Institute for Psychiatric and Behavioral Genetics, Department of Psychiatry, Virginia Commonwealth University School of Medicine, 4Mental Health Service Line, Washington VA Medical Center, 5Neuropsychiatric Genetics Research Group, Department of Psychiatry, Trinity College Dublin, 6Medical Research Council's Social, Genetic, and Developmental Psychiatry Centre, Institute of Psychiatry, King's College London, 7 MRC Social Genetic & Developmental Psychiatry Centre, Institute of Psychiatry, King's College London, 8 Molecular Psychiatry Laboratory, Windeyer Institute of Medical Sciences, Research Department of Mental Health Sciences, University College London, 9The Queensland Brain Institute, The University of Queensland Background Age at onset (AAO) of adult psychiatric disorders is an important clinical indicator of illness course and outcome, with earlier AAO often associated with disease severity and response to treatment. Whether onset at very early or relatively advanced ages suggests distinct disease entities remains unclear, as does the relative importance of familial and environmental factors. Methods Single-nucleotide polymorphism (SNP) and AAO data were available for 8803 bipolar disorder (BIP), 9380 major depressive disorder (MDD), and 9354 schizophrenia (SCZ) cases from respective workgroups of the Psychiatric Genomics Consortium. We performed genome-wide association studies (GWAS) of AAO within each disorder (case-only), combining these results in cross-disorder meta- analyses of BIP and MDD (N=18183) and BIP and SCZ (N=18157), and culminating in a metaanalysis of all three disorders (N=27537). We obtained estimates of the proportion of variability in AAO explained by genome-wide SNPs using the Genome-wide Complex Traits Analysis (GCTA) tool. Results While no single SNP attained genome-wide significance (P<5×10-8) in the all-disorder or BIP/MDD meta-analyses, combining results for SCZ and BIP yielded several SNPs in vicinity of TGFB1 (19q13.2) that exceeded this criterion (P=1.45×10-9). That TGFB1 failed to demonstrate meaningful association with disease risk in either primary analysis is an important observation, as this suggests a “modifier” effect. Polygenic scores based on AAO in any one disorder did not significantly predict AAO in either of the other disorders. We estimated for each disorder the variability in AAO attributable to common SNPs, revealing that genetic factors explain a significant fraction of the heritability of AAO among BIP and SCZ (16.17% and 9.39%, respectively) but not MDD cases. Discussion Our mega-analysis of AAO in BIP, MDD, and SCZ represents the largest case-only GWAS to date to our knowledge. Our efforts have thus far yielded a single robustly associated candidate locus— albeit one of particular biological relevance, given an established role for TGFB1 in neurodevelopment. Using molecular methods, we provide additional support for a genetic basis of AAO in BIP and SCZ but, notably, not MDD. Taken together, these findings have important implications for the study of psychiatric genetics, suggesting that case only designs based on careful phenotyping can provide insight into important genetic mechanisms of disease not assessed by standard case-control studies. GENOME-WIDE SEARCH IMPLICATES A POTASSIUM CHANNEL GENE IN COGNITIVE PERFORMANCE IN THE ELDERLY Thomas Muehleisen1, Silke Lux2, Stefan Lenzen2, Tatsiana Vaitsiakhovich3, Svenja Caspers2, Per Hoffmann4, Stefan Herms4, 1000BRAINS Study Group, Tim Becker5, Katrin Amunts2, Sven Cichon2 1 Genomic Imaging Group, 2Institute of Neuroscience and Medicine (INM-1), 3Institute for Medical Biometry, Informatics, and Epidemiology, University of Bonn, 4Division of Medical Genetics, Department of Biomedicine, University of Basel, 5German Center for Neurodegenerative Diseases (DZNE), Background Normal aging of the brain is characterized by changes of its structure and function resulting in decreasing cognitive abilities. However, the age-dependent decline of the cognitive performance (CP) can vary greatly in elderly subjects of the same age range and in both sexes. Formal genetic data from family and twin studies provide accumulating evidence that the variability of cognitive endophenotypes is also influenced by a strong genetic component. So far, there are only a few systematic genetic studies of cognitive aging and therefore little is known about the underlying genetic factors in the general population. Here we performed a genome-wide association study (GWAS), in which elderly subjects showing 'good' CP-profiles were compared with elderly subjects showing 'poor' CP-profiles to detect variants that contribute to these differences. The profiles comprehensively covered four major cognitive domains: attention, executive functions, language, and memory. Methods Subjects represent the first release of a new population-based cohort from Germany with a research focus on the aging brain, the 1000BRAINS-Study. CP was assessed using 13 neuropsychological tests. Test profiles were analyzed by a cluster analysis and a subsequent discrimant analysis. DNA was genotyped for single-nucleotide polymorphisms (SNPs) using Illumina microarrays. SNPs were tested for association using a logistic regression model. SNPs were annotated for regulatory features of the noncoding genome using HaploReg. Expressed quantiative trait (eQTL) analysis in blood and 12 brain regions was performed using a linear regression model and RNA sequencing data from the GTEx Consortium. Results CP-profile analysis of the total sample revealed a group of 323 'high-performers' (HPs) that cognitively performed better than a group of 159 'low-performers' (LPs). Of 574K SNPs, none reached genome-wide significance (P<5E-8). However, 28 SNPs showed strong to moderate evidence for association with CP-differences (P<5E-5). Overall, the most significant association was observed for a SNP (P=1.94E-6) that is located between the genes SATB1 and KCNH8. The minor allele (MA) of this SNP is significantly over-represented in the LPs compared to the HPs (frequency: 38% vs. 26%, odds ratio: 1.77). In a first follow-up investigation, we found evidence that the SNP overlaps with a regulatory motiv for a transcription factor (TF). In addition, we found that the MA showed a nominally significant association with lower expression levels of KCNH8 in the amygdala. On the neuropsychological level, the MA was associated with a reduction of CP in all four domains with a minimum in the memory domain. Discussion The main finding of our GWAS suggests that a common variant on chromosome 3p24.3 contributes to CP in the elderly. The protein-encoding gene, which is located closest to the SNP, is KCNH8. It is primarily expressed in the nervous system and belongs to a family of voltage-gated potassium channels that likely are involved in modulating the overall excitability of neurons. Evidences for a TF binding site and an eQTL support a potentially functional role of the SNP. Our study proposes a promising new candidate gene for CP. Replication in independent samples is necessary to confirm our GWAS finding. GENES INVOLVED IN LEFT/RIGHT STRUCTURAL ASYMMETRY ARE ASSOCIATED WITH HANDEDNESS AND APPEAR TO CONTRIBUTE NEURODEVELOPMENTAL DISORDERS Silvia Paracchini1, William Brandler2, Susan Ring3, John Stein2, Joel Talcott4, Simon Fisher5, Caleb Webber2 1 University of St Andrews, 2University of Oxford, 3University of Bristol, 4University of Aston, 5Max Planck Institute, Nijmegen Background Humans display structural and functional asymmetries in brain organization, strikingly manifested through language and handedness. Atypical laterality patterns have been associated with neurodevelopmental disorders, such as dyslexia and schizophrenia. While we understand the biology of body asymmetries, the molecular basis of behavioural laterality and brain asymmetries remains mainly unknown. Understanding the biology of laterality and the link between asymmetries and psychiatric disorders have been two important research questions investigated for over a century. Methods We conducted a genome-wide association study (GWAS) for a quantitative measure of handedness and dexterity (pegboard) in individuals with dyslexia (n = 728) and the general population (N =2666). The pegboard task involves one individual moving pegs from one row of holes to another. The time difference (PegQ) between completing the task with the right versus the left hand provides a measure of relative hand skills. PegQ is normally distributed with a positive mean, indicating most people are more skilled with their right hand. PegQ strongly correlates with hand preference. Results The most strongly associated variant, rs7182874 (P = 8.68×10-9), is located in PCSK6, a gene known to activate NODAL, which is required to regulate left/right body axis determination. The association is specific in the dyslexia cohort. A novel approach for GWAS pathway analysis, based on gene-set enrichment strategies, showed that left/right asymmetry pathways are associated with handedness in both the dyslexia and a general population cohorts. In particular, genes involved in corpus callosum development were enriched among the GWAS top hits. Furthermore, different markers at the PCSK6 locus were found to be associated with a measure of handiness in a completely independent study. The dyslexia-specific marker-trait association could be the result of an epistatic effect. Discussion We report the first gene to be associated with handedness at genome-wide significant level. PCSk6 has an established role in controlling left/right structural asymmetries suggesting that share biological pathways are implicated in different aspects of laterality. Furthermore, the dyslexia-specific association has opened the way to novel hypotheses in studying the link between laterality and neurodevelopmental disorders at molecular level. Recent findings show that dyslexia candidate genes play a role in ciliogenesis, an important developmental process at the basis of left/right structural asymmetries determination. We propose cilia function might have an important role in contributing to disorders by controlling laterality processes important for brain development. We are now investigating the molecular mechanisms underlying these observations using neuronal stem cell and zebrafish models. A GENOME-WIDE ASSOCIATION STUDY OF QUANTITATIVE OBSESSIVE-COMPULSIVE TRAITS IN A COMMUNITY-BASED SAMPLE OF CHILDREN AND ADOLESCENTS Christie Burton1, Jennifer Crosbie1, Lauren Erdman1, Annie Dupuis1, Laura Park1, Vanessa Sinopoli1, Andrew Paterson1, Russell Schachar1, Paul Arnold1 1 Hospital for Sick Children Background Obsessive-Compulsive disorder (OCD) is a common (1-2% lifetime prevalence), debilitating and phenotypically heterogeneous disorder which is highly heritable, particularly when symptoms begin in childhood or adolescence. Obsessive-compulsive (OC) behaviors are quantitative traits, continuously distributed in the general population and thus ignoring the quantitative nature of OCD may reduce power of genome wide association studies (GWAS) comparing OCD patients to controls. The goal of our study was to conduct a GWAS on a quantitative distribution of OC behaviors measured in children and adolescents in a community-based sample. Methods The sample consisted of 17,263 children and adolescents recruited from the community. Selfand/or parent-report data on obsessive-compulsive (OC) behaviors using the Toronto OC scale (TOCS) was collected from all participants. From 7662 unrelated individuals of Caucasian descent, the individuals with TOCS total scores in the bottom 10% (N=766) and top 10% (N=766) of the distribution were genotyped first for the GWAS. The remaining samples are currently being genotyped. Genotyping was conducted using Illumina HumanCoreExome beadchips. Standard quality control analyses were conducted using PLINK. Logistic regression analyses using principal components to control for population structure were conducted. The current results are based a subset of the unimputed data (High TOCS N= 718 and low TOCS N = 720). Results Ninety-seven percent of the sample passed QC. Although no genome-wide significant hits were identified in this preliminary analysis, we identified SNPs with P values as low as 5.0 x 10-7. Discussion This research shows the feasibility and potential power of using quantitative OC traits rather than a case control strategy for gene discovery. This will be the first report of a genome-wide study of quantitative OC traits. On-going analyses include genotyping the entire Caucasian sample and analysis of the imputed data. OVERALL SESSION: NOVEL BIOSTATISTICS AND BIOINFORMATICS GENETIC PREDISPOSITION TO SCHIZOPHRENIA ASSOCIATED WITH INCREASED USE OF CANNABIS Robert Power1, Karin J.H. Verweij2, Mohamed Zuhair3, Grant W. Montgomery4, Anjali K. Henders4, Andrew C. Heath5, Pamela A.F. Madden5, Sarah E. Medland4, Naomi R. Wray6, Nicholas G. Martin4 1 Institute of Psychiatry, London, 2Department of Developmental Psychology and EMGO Institute for Health and Care Research, VU University, 3MRC Social, Genetic & Developmental Psychiatry Centre, Institute of Psychiatry, King’s College London, 4Queensland Institute of Medical Research, , 5 Department of Psychiatry, Washington University School of Medicine, 6Queensland Brain Institute, The University of Queensland Background Cannabis is the most commonly used illicit drug worldwide. With debate surrounding the legalization and control of use, investigating its health risks has become a pressing area of research. One established association is that between cannabis use and schizophrenia, a key consideration in the debate about legislating its use. Although considerable evidence implicates cannabis use as a component cause of schizophrenia, it remains unclear whether this is entirely due to cannabis directly raising risk of psychosis, or whether the same genes that increase psychosis risk may also increase risk of cannabis use. Methods In 2,082 healthy individuals from the Queensland Institute of Medical Research sample of twins, we show an association between an individual’s burden of schizophrenia risk alleles and use of cannabis. Polygenic risk scores were derived using the Psychiatric Genomics Consortium’s analysis of schizophrenia in 9,394 cases and 12,462 controls. Results A significant association was found with schizophrenia polygenic risk scores when comparing those who have ever vs. never used cannabis (p=2.6x10-4) and for quantity of use within users (p=3.0x10-3). Discussion While directly predicting only a small amount of the variance in cannabis use, these findings suggest that part of the association between schizophrenia and cannabis is due to a shared genetic aetiology. This is an important consideration when calculating the impact of cannabis use and its health risks. MODELING LINKAGE DISEQUILIBRIUM INCREASES ACCURACY OF POLYGENIC RISK SCORES FOR SCHIZOPHRENIA AND OTHER DISEASES Bjarni Vilhjalmsson1, Jian Yang2, Hilary Finucane3, Alexander Gusev4, Sara Lindström4, Stephan Ripke5, Giulio Genovese6, Nikolaos Patsopoulos7, Po-Ru Loh8, Schizophrenia Working Group of the Psychiatric Genomics Consortium, Shaun Purcell9, Michael Goddard10, Peter Visscher2, Peter Kraft4, Nicholas Patterson6, Alkes Price4 1 Harvard School of Public Health, 2The University of Queensland, Brisbane, Queensland, Australia, 3 Massachusetts Institute of Technology, 4Harvard School of Public Health, 5Massachusetts General Hospital, 6Broad Institute, Cambridge, 7Brigham & Women's Hospital, 8Harvard School of Public Health, 9Mount Sinai School of Medicine, 10The University of Melbourne Background In recent years, polygenic risk scores have become an important technique for detecting a genetic signal, understanding the genetic architecture of common diseases, and predicting disease risk. As training sample sizes increase their accuracy is expected to approach the limit set by the heritability (Chatterjee et al., Nat Genet 2013; Dudbridge et al., PLoS Genet 2013). However, linkage disequilibrium (LD) between causal markers biases the marginally estimated effect estimates from genome-wide association studies (GWAS. The standard approach of applying a P-value threshold to association statistics followed by LD-pruning (LD-clumping) does account for this bias, and yields suboptimal predictions. This negative impact of LD on the prediction accuracy is expected to increase as GWAS sample sizes continue to grow. Methods To address this problem, we propose a Bayesian polygenic risk score that estimates LD from a reference panel and re-weights the effect estimates obtained from GWAS summary statistics. The new effect estimates are the posterior mean effects sizes, which give optimal (best linear unbiased prediction) polygenic risk scores when model assumptions hold. These estimates have a closed-form solution under the prior where every marker is causal and effect sizes are drawn from a mean-zero normal distribution. Under a prior where a fraction of the markers are causal, the posterior mean effect sizes do not have a closed form, and we approximate them with a Markov chain Monte Carlo (MCMC) approach, which we call LDpred. LDpred requires a small independent validation sample to optimize the fraction of causal markers. Importantly, LDpred is computationally efficient and yields well-calibrated predictions when model assumptions hold. Results We compared LDpred to previously proposed approaches that represent the state of the art in polygenic risk prediction with GWAS summary statistics as training data. We found LDpred to outperform other methods in simulations with real and simulated genotypes. The relative improvement over the commonly used LD-pruning/thresholding approach increased with larger GWAS sample sizes. We applied LDpred to WTCCC diseases and observed improved prediction R2 for all but one disease, and for autoimmune diseases that improvement was substantial (e.g. the R2 on the observed scale improved from 28.3% to 35.5% for T1D). Consistent with our simulations, when applied to Schizophrenia PGC2 GWAS summary statistics, we observe a significant improvement in prediction R2 (Nagelkerke) from 15.7% to 18.3% using ISC as an independent validation sample. The relative improvement was even larger when predicting in samples of non-European descent: the R2 (Nagelkerke) went from 2.0% to 2.6%. Discussion As sample sizes continue grow, the prediction accuracy of polygenic risk scores are expected to improve. However, unless the LD between causal markers is appropriately accounted for, the prediction accuracy will fall short of the upper limit determined by the heritability. LDpred addresses this problem, resulting in improved prediction accuracies for most diseases that we applied it to. Intuitively, since nonEuropean samples have a different LD pattern than European samples, we expect greater relative improvement in prediction accuracies for non-European validation samples. However, since it relies on LD estimates from a reference panel LDpred is not a panacea for polygenic prediction. Although an improvement, it is inherently limited by how well that reference sample reflects the LD structure in the GWAS sample. If instead LD information from individual cohorts is available, the prediction accuracy of LDpred could improve even further. DISCOVERY OF AN INVERSE AXIS OF RISK FOR POLYGENIC AND RARE VARIANT BURDENS REVEALS A SHARED RISK ARCHITECTURE AMONG PSYCHIATRIC TRAITS Lea Davis1, Hae-Kyung Im2, Eric Gamazon2, Emily Kistner-Griffith3, Jim Sutcliffe4, Ed Cook 5, Lauren McGrath6, International OCD Foundation Genetics Consortium, Tourette Syndrome International Association Consortium for Genetics, Nancy Cox2 1 The University of Chicago, 2University of Chicago, 3University of South Carolina, 4Vanderbilt University, 5University of Illinois, 6American University Background There has been significant debate over the relative contributions of rare variants and common polygenic risk to the etiology of psychiatric disorders. We hypothesize that if a liability threshold can be crossed by either polygenic risk or rare variant risk, we should detect an inverse correlation between polygenic liability to phenotype and rare variant burden among cases. We use the estimated breeding value (EBV), which has been in use in animal breeding and plant genetics with multiple applications for many years, as a quantitative measure of aggregate polygenic liability to phenotype (Yang et al., 2010; de los Campos et al., 2013). Additionally, we use rare variant burden data on the same samples, taken from previously published studies of copy number variation and exome sequencing (Sanders et al., 2011; Sanders et al., 2012; McGrath et al., in press). Methods In order to test our hypothesis, we calculated EBVs from a matrix that defines genetic relationships between unrelated cases and controls based on risk allele sharing. Using the same genetic relationship matrices that yielded trait heritability estimates, we calculated EBVs for Tourette Syndrome (TS), obsessive-compulsive disorder (OCD), and autism spectrum disorder (ASD) and use these EBVs in multiple analyses with rare variants available from previous analyses on each phenotype (Sanders et al., 2011; Sanders et al., 2012, Davis et al., 2013, McGrath et al., in press). Results In ASD, we show that there is a significant negative correlation between EBV and burden of novel heterozygous variants (i.e., rare inherited or de novo variants never seen in dbSNP or 1,289 control whole-exome samples) from exome sequencing (Sanders et al., 2012), r(151) = -.16, p = 0. 05, that appears to be driven by individuals with below average IQ (<100), r(105) = -.27, p=0.004. Additionally, we found that ASD probands harboring de novo sequence variants had significantly lower polygenic scores than those without de novo variants (p=0.05). Moreover, we found an inverse correlation between EBV and rare (<1%) CNV burden (Sanders et al., 2011) in ASD probands, r(769) = -.07; p=0.05, that was not detected in unaffected siblings. Similarly, in TS, we find that probands who harbor large CNVs (> 500 Kb) have significantly lower polygenic load than those who do not carry large CNV events (p=0.02). We find no such significant differences between OCD probands with and without large CNVs. Discussion The latter finding is consistent with previous work suggesting a limited role for rare variation in OCD compared to TS (Davis et al., 2013). Taken together, our data suggests that both sources of genomic risk are critically important and inversely related. The use of EBVs and the characterization of an “inverse axis of risk” should facilitate novel strategies for the identification of both genetic and nongenetic risk factors related to disease and disease severity. DEVELOPMENTAL REGULATION OF HUMAN CORTEX TRANSCRIPTION AT BASEPAIR RESOLUTION Andrew Jaffe1 1 Lieber Institute for Brain Development Background The transcriptome of the human brain changes dramatically across development and aging, with the largest gene expression changes occurring during fetal life, tapering into infancy (Colantuoni 2011, Kang 2011). Previous transcriptome characterizations used primarily microarray technologies based on pre-defined probe sequences that capture only a limited proportion of transcriptome diversity. The technological advances of RNA sequencing (RNAseq) now permit a flexible and potentially unbiased characterization of the transcriptome at high resolution and coverage (Trapnell 2010). Methods We have implemented a method for RNAseq analysis at single base resolution to more fully characterize transcription dynamics. We performed deep coverage sequencing of the transcriptomes of 72 human dorsolateral prefrontal cortex (DLPFC) samples across 6 important life stages – fetal (2nd trimester), infant, child, teen, adult and elderly (n=6 per group) – and implemented an annotationagnostic differential expression analysis called "derfinder" to leverage the power of RNAseq without the difficulties of transcript assembly. Results We identified 50,650 differentially expression regions (DERs) agnostic of annotation, with significant and replicated expression changes across fetal and postnatal development. While many DERs annotated to non-exonic sequence, they were validated in cytosolic mRNA, suggesting that they are not nuclear pre-mRNAs. We found similar expression profiles of these DERs across 16 diverse human brain regions and within the developing mouse cortex, and observed expression among subsets of non-exonic DERs in diverse cell and tissue types. Lastly, we demonstrate that many expression changes are driven by changing neuronal phenotype related to differentiation and maturation. Discussion These data highlight conserved molecular signatures of transcriptional dynamics across brain development, as well as the incomplete annotation of the human brain transcriptome. GENE-BASED PLEIOTROPY ACROSS FIVE MAJOR PSYCHIATRIC DISORDERS Dale Nyholt1, Huiying Zhao1 1 Queensland Institute of Medical Research Background Studies have indicated genetic overlap between the five disorders in the Psychiatric Genomics Consortium (PGC): autism spectrum disorder (ASD), attention deficit-hyperactivity disorder (ADHD), bipolar disorder (BPD), major depressive disorder (MDD), and schizophrenia (SCZ). In this study, we aimed to identify specific genes overlapping the five psychiatric disorders utilizing a novel gene-based approach. Methods Optimized gene-based tests were performed utilizing genome-wide association (GWA) results from the PGC analysis of single-nucleotide polymorphism (SNP) data for the five disorders in 33332 cases and 27888 controls of European ancestry. After accounting for correlation (i.e., non-independence) of gene-based test results due to linkage disequilibrium we examined the significance of the proportion of genes nominally associated across the five disorders. Pathway and network based analyses were performed on the sets of genes significantly overlapping the disorders. Results We found highly significant overlapping genes between SCZ and BPD, moderate overlap between SCZ and MDD, SCZ and ASD, MDD and ASD, and ADHD and BPD. After combining disorders as discovery sets, we found significant overlap across SCZ, BPD and MDD, across SCZ, BPD, MDD and ASD, and across BPD, MDD and ASD/ADHD. No significant overlap was observed between the individual adult-onset disorders and ADHD. Pathways implicated by the genes overlapping the adultonset disorders include MAPK signalling, calcium signalling, dorso ventral axis formation, chemokine signaling, and melanogenesis. Pathways for BPD and ASD include glycosphingolipd biosynthesis globo series, and pathogenic Escherichia coli infection. Pathways implicated by genes overlapping BPD and ADHD include glutathione metabolism, and arachidonic acid metabolism. Additionally, combining genebased association results across disorders identified numerous genes surpassing our cutoff for genomewide significance. Discussion Utilizing a novel approach, we identified numerous genes associated across multiple psychiatric disorders. Our results extend previous findings from single SNP-based genetic overlap analyses by providing important insight into the likely genes and biological mechanisms underlying the observed genetic correlation and co-morbidity between these major psychiatric disorders. COMPARISON OF MODEL-BASED ESTIMATORS OF POPULATION STRUCTURE IN A GWAS FRAMEWORK Antonio Pardiñas1, Peter Holmans1, Marian Hamshere1, James Walters1 1 Cardiff University Background The genome-wide association study approach (GWAS) is now standard practice in researching complex psychiatric disorders. One of its key quality control procedures involves the assessment of population stratification, an important potential confounder of true association signals. While this is straightforward to perform with Principal Component Analysis (PCA), routinely used in psychiatric genetics, other alternatives for the inference of population structure exist. Some of these are explicitly based on different postulates of population genetic theory, claiming to achieve higher accuracy than PCA. Applied to a case-control GWAS framework, outputs from these techniques could be used to successfully control for stratification. Furthermore, as these techniques reduce the structure patterns into one or two variables, there could be an increase in power when using them as the covariates of a logistic regression, as the number of significant PCs is higher than two in most genotype datasets. Methods To test these premises, we have used several model-based estimators of population structure, such as SPA (Yang et al. 2012), SNPWEIGHTS (Chen et al. 2013) or GAGA (Lao et al. 2014), to correct two case-control association studies of schizophrenia. The first sample contains 3322 cases and 3587 controls from six different ancestries within Europe (ISC; International Schizophrenia Consortium 2009), and thus contains a great deal of population stratification. The second sample consists of 5616 cases and 6380 controls sampled within the United Kingdom (CLOZUK; Rees et al. 2013), and thus would be expected to show much less stratification. In both datasets, we have assessed the results of these methods against other commonly used correction procedures (Stram 2014), which involve PCA using EIGENSTRAT, Cochran–Mantel–Haenszel stratified analysis and two mixed linear models computed with GCTA (Yang et al. 2011). Results After using all the tested methods to correct for stratification, inflation of the regression statistic was assessed by computing the lambda parameter (Devlin and Roeder 1999). In this assessment, linear mixed models achieved the lowest inflation values, followed by PCA and the model-based methods. However, regression results were very similar for all the procedures after using them to correct for stratification in each of the datasets, with only SPA showing a marked increase on the significance of the top association signals for the case of the most stratified sample. Discussion The results of these analyses indicate that the probabilistic model included in SPA might be useful in a GWAS framework, leading to increased power to detect true associations in some scenarios. Nevertheless, as this model is best suited to detect gradients in allele frequency, it does not account for all the possible sources of stratification in a sample. However, this concern is shared with non-model-based alternatives, and in fact imposes a limit on how much any of them can improve association analyses. While mixed models could overcome these limitations, the most stringent procedures available also seem to suffer from overcorrection and power loss, as is consistent with recent discussions on their statistical properties (Yang et al. 2014). OVERALL SESSION: SCHIZOPHRENIA: GENOMICS & MORE EMERGING PATTERNS OF SCHIZOPHRENIA RISK CONFERRED BY DE NOVO MUTATION Daniel Howrigan1, Benjamin Neale1, Kaitlin Samocha1, Jennifer Moran2, Kimberly Chambert2, Sam Rose2, Menachem Fromer3, Sharon Chandler4, Nan Laird5, Hai-Gwo Hwu6, Wei J. Chen6, Stephen V. Faraone7, Stephen J. Glatt7, Ming Tsuang5, Steven McCarroll8 1 Massachusetts General Hospital, 2Broad Institute, 3Mount Sinai School of Medicine, 4University of California, San Diego, 5Harvard School of Public Health, 6National Taiwan University, 7SUNY Upstate Medical University, 8Harvard University Background Increased rates of deleterious de-novo mutations, both across the genome and within specific genes, have emerged as significant genetic risk factors among developmental disorders such as autism, intellectual disability, and epilepsy. In contrast, only modest effects of de novo mutation have been discovered so far among schizophrenia cohorts. Despite the weaker effect size, patterns of observed de novo mutations are converging on gene networks highly expressed in the brain, and larger samples will uncover specific genes as putative de novo risk factors for schizophrenia. Methods Whole-exome sequencing has been performed on 1,141 complete trios from a Taiwanese cohort, with 1,110 trios having high quality sequence reads sufficient for de novo analysis, thus making it the largest cohort to date among schizophrenia de novo analyses. Exome sequencing data were generated using the Illumina HiSeq sequencing with the Agilent SureSelect exome capture platform, achieving an average coverage of 87% at 20X coverage. Validation of candidate de novo signals was analyzed using targeted high-throughput genotyping on Illumina HiSeq and Illumina MiSeq platforms with a downsampled mean coverage of 373X. Confirmed de novo mutations were annotated using the NCBI RefSeq database. Results Among the Taiwanese cohort, de novo mutation rates per trio and across the exome fall in line with the expected mutation rate. Using models that incorporate gene size and site-specific mutation rates into expectations of de novo mutation rates, we do not observe any single gene that surpasses exomewide correction for multiple testing (set at p = 1e-6). We do, however, see a significant enrichment of genes with multiple non-synonymous de novo mutations (empirical p = 7e-4). When we combine our results with published de novo studies of schizophrenia, we observe nine genes with multiple loss-offunction events (empirical p < 1e-4), and 87 genes with multiple missense events (empirical p = 0.01). Gene set analyses also indicate that both loss-of-function and missense de novo mutations are enriched among targets of the Fragile X mental retardation protein (p = 0.004 and p = 6e-5, respectively) and among genes under evolutionary constraint (p = 0.001 and p = 2e-5, respectively). Discussion The current findings do not identify any single gene as an unequivocal risk factor for schizophrenia when disrupted by de novo mutation; however, aggregate analyses of genes hit with multiple damaging mutations and among well characterized gene sets in the literature indicate that significant patterns of de novo risk for schizophrenia are clearly emerging. While we firmly believe larger cohorts and the accumulation of de novo mutations in the literature will soon lead to specific genes being unequivocal risk factors, we are well aware that the increased liability toward schizophrenia due to de novo mutations comprises only a modest fraction of the overall genetic liability to the disorder, and stress this limitation throughout the presentation. THE GENOMICS OF TREATMENT RESISTANT SCHIZOPHRENIA James Walters1, Stephan Ripke2, Elliot Rees3, George Kirov3, Peter Holmans3, Jennifer Moran2, Kimberley Chambert2, Ben Neale2, Giulio Genovese4, Steven McCarroll2, Michael Owen3, Michael O'Donovan3 1 Cardiff University, 2Stanley Center for Psychiatric Research, Broad Institute of MIT and Harvard, Analytical and Translational Genetics Unit, Massachusetts General Hospital, Analytical and Translational Genetics Unit, Massachusetts General Hospital, 3MRC Centre for Neuropsychiatric Genetics and Genomics, Cardiff University, Background A third of those with schizophrenia (Sz) fail to respond to antipsychotic medication and are termed 'treatment-resistant'. These are the most severely unwell patients and experience marked impairments in functioning. It is unclear whether treatment-resistance represents a distinct biological subtype of those with Sz or a more severe form of the condition. Similarly little is known about the genetic architecture underpinning treatment resistant schizophrenia (TRS). In this study we use large-scale GWAS and CNV data to answer questions relating to the genetic nature of TRS: 1. Are Sz polygenic scores higher in TRS than in generic Sz (suggesting a more severe form of the condition). 2. Does GWAS identify risk loci that are specific to TRS (i.e. not seen in generic Sz, suggesting unique biological pathways to TRS). 3. Do the rates of schizophrenia-associated CNVs differ between TRS and generic Sz (suggesting an alternative mechanism associated with TRS). Methods Polygenic risk prediction scores were generated from PGC2 Sz samples excluding our TRS samples. The TRS sample used for the primary GWAS and as the target set for the polygenic analysis was the CLOZUK sample of 5600 cases with a clinical diagnosis of TRS and 6300 controls. The polygenic overlap with CLOZUK was compared to results from generic schizophrenia samples within PGC. The CLOZUK GWAS was performed as part of the PGC2 Sz GWAS analysis through the same QC, imputation and analysis pipelines. For the GWAS we then sought replication of the initial CLOZUK GWAS signals in 2500 independent samples of those taking clozapine. In order to identify genetic variants specific to TRS we compared the SNPs to emerge from the CLOZUK GWAS in the replication samples using clozapine users as cases and non-clozapine users as ‘controls’. CNV analysis was performed according to standard calling and QC procedures. Rates of CNVs were compared with available generic schizophrenia samples (ISC, MGS). Results There was no evidence from the polygenic analysis that the TRS sample is associated with a stronger polygenic signal than generic Sz samples. In the initial CLOZUK GWAS we identified three genome-wide significant SNPs (p<5x10-8). Several of these SNPs replicated in the independent samples of 2500 of those with Sz who have ever taken clozapine. In combining these with the CLOZUK samples we identified eight genome-wide significant SNPs, three of which appear to be specific to TRS (i.e. no association in generic schizophrenia samples). The specificity of these signals to TRS will be confirmed by completion of the clozapine case versus non-clozapine schizophrenia case analysis. Rates of CNVs are broadly equivalent in the TRS and generic schizophrenia samples, although at present these results are preliminary given different genotyping platforms and SNP/CNV coverage between samples. Discussion Our results suggest that there maybe specific polymorphic associations to TRS not seen in generic schizophrenia and thus point toward the involvement of distinct molecular pathways for TRS. In contrast there is little support from a polygenic or CNV analyses that TRS represents simply a more severe form of schizophrenia in that polygenic risk scores and CNV frequencies are broadly equivalent between TRS and generic schizophrenia samples. A HYPOTHESIS-DRIVEN ANALYSIS OF GENOME-WIDE ASSOCIATION SUMMARY RESULTS FROM THE PSYCHIATRIC GENOMICS CONSORTIUM IDENTIFIES NOVEL NUCLEAR-ENCODED MITOCHONDRIA SUSCEPTIBILITY LOCI FOR SCHIZOPHRENIA Vanessa Gonçalves1, Andriy Derkach2, Stephanie Willians3, Jennie Peuget4, Andrew D. Paterson5, Christina Hultman6, Pamela Sklar6, Patrick Sullivan3, Jo Knight4, James Kennedy4, Lei Sun7 1 CAMH, 2University of Toronto, 3University of North Carolina, 4Neuroscience Section, Centre for Addiction and Mental Health, 5Program in Genetics and Genomic Biology, Hospital for Sick Children, 6 Department of Medical Epidemiology and Biostatistics, Karolinska Institutet, 7Biostatistics Division, Dalla Lana School of Public Health, University of Toronto Background Schizophrenia (SCZ) is a severe psychiatric disorder with a strong genetic component and high heritability. Mitochondria are the main sources of aerobic energy for neuronal functioning, and are involved in many cellular activities disturbed in SCZ such as neurotransmission, synaptic plasticity, and oxidative stress. We hypothesized that variants in nuclear-encoded mitochondrial genes may influence SCZ risk. We further hypothesized that variants in the nuclear-encoded oxidative phosphorylation (OXPHOS) genes could be characteristically different from the other nuclear-encoded mitochondrial variants due to the direct interaction of their protein products with mitochondrial DNA proteins. We applied hypothesis-driven analysis in genome-wide association summary results to identify novel nuclear- encoded mitochondria susceptibility loci for SCZ. Methods SCZ GWAS results were obtained as summary statistics from the Psychiatric Genomics Consortium (PGC, Nature Genetics 2011) for a total of 1,252,901 SNPs in 9,394 cases and 12,462 controls of European ancestry. All variants were analyzed using stratified false discovery rate (sFDR). Stratum 1 contained 1,744 OXPHOS SNPs, stratum 2 contained 20,414 other nuclear-encoded mitochondrial SNPs, and stratum 3 contained the remaining 1,230,743 GWAS SNPs. Replication of our association results was performed through meta-analysis with an independent sample (N=11,244). Results Using a q-value criterion of 0.05, all loci previously reported by PGC remain significant, and 17 novel variants from 6 nuclear-encoded mitochondrial genes: C6orf136, VARS2, FTSJ2, AK3, C10orf32 and AS3MT were identified. We then replicated the association at C6orf136, VARS2 and FTSJ2 through meta-analysis. All replication results are based on the same reference allele used in PGC GWAS and the direction of effect was always consistent. Discussion Our study showed that novel loci could be discovered from existing GWAS summary data by performing a hypothesis-driven analysis of the genome, provided a sound biological hypothesis being conceived for the complex trait of interest. Identification of genetic predisposition to SCZ in the mitochondrial system may help to reveal other circuits possibly disturbed in major psychosis disorders and offer new research directions. PARSING GENETIC ASSOCIATIONS IN THE MHC IN SCHIZOPHRENIA Semanti Mukherjee1, Stephan Ripke2, Ole Andreassen3, Aiden Corvin4, Paul deBakker5, Jo Knight6, Yunpeng Wang3, Steve McCarroll2, Ben Neale2, Vishwajit Nimgaonkar7, Roel Ophoff8, PGC SCZ Working Group, Jennie Pouget6, Patrick Sullivan9, Todd Lencz10 1 The Feinstein Institute for Medical Research, 2Broad Institute, 3Oslo University Hospital, 4Trinity College, 5UMC Utrecht, 6CAMH, University of Toronto, 7University of Pittsburgh, 8UCLA, 9University of North Carolina, 10Zucker Hillside Hospital Background The major histocompatibility complex (MHC) has emerged as a region of major interest in schizophrenia genetics. Large-scale genome-wide association studies (GWAS) in schizophrenia have converged to demonstrate that the MHC contains the strongest association signal for illness susceptibility. However, prior GWAS have been unable to precisely localize the source of this signal, due to the extensive long-range linkage disequilibrium throughout the MHC; different studies have identified top SNPs ranging across a nearly 10Mb extent (coordinates ranging from 25-35Mb on Chromosome 6). A subcommittee within the PGC SCZ working group has been formed to parse the signal within the MHC using HLA imputation and conditional analysis. Methods Of the 52 PGC-SCZ cohorts, raw genotype data were available for 38 cohorts of European ancestry, with a total n = 64,631 (29,148 cases and 35,483 controls). Imputation of classical HLA alleles was performed using SNP2HLA (Jia et al. 2013) applied to raw genotype data from each cohort. A total of 267 HLA alleles and 5698 SNP markers were successfully imputed. Regression and conditional regression analyses, covarying for top 10 PCAs and study site, were performed in PLINK and metaanalysis was performed in METAL. Results Six HLA alleles attained genomewide significance (10-15 < all p-values <10-9): HLA_B_0801, HLA_DRB1_0301, HLA_DQB1_0201, HLA_A_0101, HLA_DQA1_0501, HLA_C_0701. In each instance, these alleles were protective, with higher frequencies amongst controls relative to cases (frequencies in cases ~10.5-11% vs ~12-12.5% for controls; OR~0.87). Frequencies for these alleles, which form the so-called 8.1 ancestral haplotype (AH8.1) were strongly correlated across cohorts. Notably, these associations were much less strong than those observed for individual SNPs across the extended MHC, and conditional analyses covarying for AH8.1 components revealed genomewide significant SNPs remaining throughout the region, with top signals at rs34661691 (an eQTL for BTN3A2) and rs2523721 (an eQTL for HLA-A and VARS2). Additional conditional analyses, covarying for top individual SNPs rather than HLA alleles, are ongoing and results will be presented at the meeting. Discussion Initial results demonstrate a pattern that is markedly different from that observed for autoimmune disorders. In most autoimmune disorders, AH8.1 is associated with risk; whereas in schizophrenia, the opposite relationship is observed. Moreover, in autoimmune disorders, SNP effects in the MHC are entirely accounted for by HLA alleles and corresponding amino acid changes. By contrast, SNP effects in schizophrenia are likely to play a significant independent role, probably regulatory in nature, and potentially implicating non-HLA genes. THE GENETIC AND EPIDEMIOLOGICAL RELATIONSHIP BETWEEN RHEUMATOID ARTHRITIS AND SCHIZOPHRENIA Jack Euesden1, Gerome Breen1, Anne Farmer1, Peter McGuffin1, Cathryn Lewis1 1 King's College London Background Unusual epidemiological patterns have historically provided a route towards understanding disease aetiology. Rheumatoid arthritis (RA) is an autoimmune disorder characterized by inflamed, swollen and ultimately fused joints. Schizophrenia (SCZ) is a psychiatric disorder characterized by auditory hallucinations, disorganized thought and delusions. Both are highly heritable and both have been targets of active research within the field of complex disease genetics. Furthermore, both disorders show an involvement with autoimmune-related alleles leading to models for disease aetiology. A number of authors have reported an unusual epidemiological relationship between the two disorders, with studies dating back to 1936 reporting that RA is rarer in SCZ patients than would be expected by chance. Despite this, many of these studies have been underpowered, lacked appropriate control populations, or found conflicting results. Methods We performed a systematic review of studies investigating the prevalence of RA amongst SCZ patients with reference to an appropriate control population, a meta-analysis of RA prevalence in SCZ patients versus controls, and used polygenic risk scoring (PRS) to investigate the presence of non-shared genetic risk between RA and SCZ. We used the most recently publicly available SCZ Genome-Wide Association Study provided by the Psychiatric Genomics Consortium. This used genotype data on 13,833 SCZ patients and 18,310 controls to report association between SCZ and 9,989,079 single nucleotide polymorphisms. We calculated polygenic risk scores for SCZ – a measure of an individual’s genetic risk of disease – in an independent RA case-control dataset. Our RA cases were taken from the WTCCC, and our RA controls were taken from the RADIANT study. We tested the fit of models regressing RA status on SCZ genetic risk after accounting for ancestry using principal components. Results Our systematic review identified 10 studies reported in 9 papers meeting inclusion criteria. There was heterogeneity amongst studies (p < 0.005), therefore we performed a random effects metaanalysis. After meta-analysis, we found substantial evidence supporting an unusual epidemiological relationship between RA and SCZ - unadjusted odds ratio for RA in SCZ patients versus controls = 0.48 (95% CI: 0.34 – 0.67). Polygenic risk scoring, however, revealed that genetic risk for SCZ had no predictive value on RA status; the most predictive polygenic risk score explained under 0.1% of the variance in RA status – calculated using Nagelkerke’s Pseudo R2 – and was non-significant (p = 0.085). Discussion Despite finding robust evidence for a protective effect of SCZ on RA in previous literature, we did not find evidence for a genetic component to this relationship. We suggest that the observed relationship may be due to an environmental factor, such as an anti-inflammatory effect of antipsychotic medication, for which there is substantial evidence. Furthermore, epidemiological studies may be confounded by the effect of SCZ on life expectancy and the relatively late age at onset of RA. Although we did not find evidence for a shared genetic architecture, studies utilizing polygenic risk scoring have begun to stratify the genome based on functional properties of alleles – therefore this may be the next step in exploring the genetic relationship between these two complex disorders. METHYLOME-WIDE INVESTIGATION OF CPGS THAT ARE CREATED OR DESTROYED BY SNPS IMPLICATES SITES ASSOCIATED WITH SCHIZOPHRENIA IN BOTH BLOOD AND BRAIN Karolina Aberg1, Shaunna L. Clark1, Joseph L. McClay1, Linying Xie1, Gaurav Kumar1, Andrey Shabalin1, Daniel E. Adkins1, Swedish Schizophrenia Consortium2, Vladimir Vladimirov2, Patrik KE. Magnusson3, Edwin JCG. van den Oord1 1 Center for Biomarker Research and Personalized Medicine, School of Pharmacy, Virginia Commonwealth University, 2Center for Biomarker Research and Personalized Medicine, School of Pharmacy, and Virginia Institute for Psychiatric and Behavioral Genetics, Virginia Commonwealth University, 3Department of Medical Epidemiology and Biostatistics, Karolinska Institutet, Background The methylation of DNA cytosine residues at the carbon-5 position is a common epigenetic modification that is most often, although not exclusively, found in the sequence context CpG. There are approximately 1.4 million CpGs that are created or destroyed by common SNPs (SNP-CpGs). Investigations of SNP-CpGs provide a promising complement to schizophrenia studies of DNA sequence as these sites involves variation in both sequence and methylation status. Methods We applied methyl-binding domain 2 protein enrichment to extract the methylated fraction of the genome followed by sequencing (MBD-seq). Using GWAS genotyping in combination with 1000-genomes imputation we then investigated the methylation status of SNP-CpGs (MAF > 5%) in DNA extracted from blood in 1408 schizophrenia cases and controls. Next, we performed the same investigations in post-mortem brain tissue from individuals diagnosed with schizophrenia (N=26), bipolar disorder (N=22) and controls (N=27). Our main outcome for the post-mortem samples was the presence of psychotic feature, which allowed us to include all schizophrenia cases and also a subset (N=15) of the bipolar cases. Findings from the methylome wide SNP-CpG analysis in blood and brain tissue were further replicated using highly quantitative targeted bisulfite pyrosequencing, in blood and post-mortem brain tissue from independent schizophrenia case-control samples. Results We found that 68.3% and 67.7% of SNP-CpGs where likely methylated in blood and brain, respectively. The overlap of methylated sites was high (94%). Using a false discovery rate (FDR) of 0.1, the combined analysis of the datasets identified four methylome-wide significant sites (one-sided p ranging 6.5E-09 to 1.5E-06 with q ranging from 0.002 to 0.08). Thus, sites that were associated with schizophrenia in blood were also associated with the presence of psychotic feature in brain. Furthermore, two of the top findings remained significant (one-sided p: 7.8E-09 and 5.9E-07; q: 0.002 and 0.07) when the brain data was limited to include only schizophrenia cases but not when limited to include bipolar cases. One of our top findings was located upstream of ENC1, which is of critical importance for regulation of neuronal processes. This site has been further replicated with pyrosequencing in independent samples (p-value = 1.6E-04, N=368). Replication of the other three SNP-CpGs is on going. Discussion This study represent one of the first genome-wide analysis of SNP-CpGs that identifies associated sites that are consistent between blood and brain and therefore may improve our understanding of disease etiology and may play a role as biomarkers to improve treatment, diagnosis and prognosis for schizophrenia patients. OVERALL SESSION: AUTISIM: GENOMICS & MORE INTEGRATIVE FUNCTIONAL GENOMIC STUDIES IDENTIFY DIFFERENTIAL ACTIVATING AND REPRESSIVE FUNCTIONS OF CHD8 IN NEURODEVELOPMENTAL PATHWAYS ASSOCIATED WITH AUTISM IN NEURAL PRECURSOR CELLS Michael Talkowski1, Marta Biagioli1, Christelle Golzio2, Ian Blumenthal1, Serkan Erdin1, Poornima Manavalan1, Ashok Ragavendran1, Diane Lucente1, Judith Miles3, Steven Sheridan1, Stephen Haggarty1, Nicholas Katsanis2, James Gusella1, Michael Talkowski1 1 Massachusetts General Hospital, 2Duke University, 3University of Missouri Background Inactivating mutations of the chromodomain helicase CHD8, and many other genes with diverse functions, act as strong-effect risk factors for autism spectrum disorder (ASD), suggesting multiple mechanisms of pathogenesis. Methods We perturbed the transcriptional networks that CHD8 regulates early in neurodevelopment by suppressing its expression in neural precursors using 5 independent shRNA hairpins, and performing the experiments in duplicate. We integrated transcriptome sequencing with genome-wide sites of CHD8 binding to chromatin from three independent antibodies. Results Suppressing CHD8 altered expression of 1,756 genes, most of which were up-regulated (~65%), consistent with its putative function as a transcriptional repressor. Chromatin immunoprecipitationsequencing (ChIP-seq) revealed widespread pervasive binding of CHD8 throughout the genome, with as 7,324 replicated sites from all three antibodies markinged 5,658 genes, yet just 9.2% of these genes were differentially expressed. These data suggest that a limited array of direct regulatory effects of CHD8 produces a much larger network of expression changes through secondary indirect regulatory mechanisms. Interestingly, the networks associated with direction of CHD8 regulation are functionally distinct. Genes indirectly down-regulated (i.e., without CHD8 binding sites) are strongly enriched for genes associated with ASD (p = 1.01x10-9) and reflect pathways involved in brain development, including synapse formation, neuron differentiation, cell adhesion, and axon guidance. In striking contrast, g Discussion These data indicate that heterozygous disruption of CHD8 precipitates a network of gene expression changes that include indirect down-regulation of many other ASD risk genes, and that some genes associated with ASD and neurodevelopmental disorders may converge on shared mechanism of pathogenesis. WHAT CAN GENETIC RESEARCH TELL US ABOUT CURRENT PSYCHIATRIC NOSOLOGY? LESSONS FROM AUTISM Susan Santangelo1, Richard Anney 2, Dan Arking3, Joseph Buxbaum4, Ed Cook5, Nick Craddock6, Mark Daly7, Ken Kendler8, Phil H Lee7, Ben Neale7, John Nurnberger9, Stephan Ripke7, Jordan Smoller7, Pat Sullivan10, Jim Sutcliffe11 1 Maine Medical Center, 2Trinity College, 3The Johns Hopkins University, 4Mount Sinai, Icahn School of Medicine, 5University of Illinois, 6Cardiff University, 7Harvard Medical School, 8 Virginia Commonwealth University, 9Washington University, 10University of North Carolina, 11Vanderbilt University Background In 2013, the cross-disorder group (CDG) of the PGC published the largest genetic study of mental illness ever done, finding substantial evidence for common variants and shared genetic etiology among all five disorders studied, including SNPs in two calcium channel genes. We also identified some variants shared by some but not all of the disorders, such as those shared by autism spectrum disorder (ASD) and schizophrenia. Findings from this and other studies raise questions about how unique and separable the five psychiatric disorders studied by the PGC are and what the relative strengths of unique and shared pathophysiologies might be across the disorders. Methods This presentation will describe how the results of large-scale genomic studies can be used to inform psychiatric nosology, with particular attention to the diagnosis of DSM-V autism spectrum disorder. Evidence will be reviewed from genome-wide association studies of psychiatric diagnostic categories (e.g. ASD, schizophrenia and others) and quantitative phenotypes, using various molecular and statistical methods, investigations of common variants (SNPs), rare variants (CNVs, SNVs, LOF mutations, etc.), regulatory elements (i.e., CHD8, miRNAs) and their targets, various pathway analyses and emerging data from epigenetic studies in animal models and humans. Results From studies such as the (as yet unpublished) PGC Autism Meta-Analysis, the recent Autism Genome Project investigation of structural variants, the 2012 exome sequencing efforts, and the current Autism Sequencing Consortium project, we now know that there are many hundreds, if not more, genes involved in ASD, that both rare and common variation are important, and that little overlap is seen between the rare and common variants. However, the hundreds of genes identified so far appear to converge on a few common biological pathways involved in brain development, synapse function and chromatin regulation. Discussion The studies reviewed provide empirical evidence that genetics/genomics can help us move beyond the design of psychiatric nosological systems based on purely descriptive clinical categories to those informed by biological factors in disease causation. Further, genetic and genomic studies can contribute to the prediction, prevention and treatment of psychiatric disorders, such as autism, and to the identification of molecular targets for new generations of psychotropic drugs, some of which are likely to cross arbitrarily assigned disease classification boundaries. Discussion will include how best to exploit the fact that the many hundreds of genes identified for ASD and other psychiatric disorders appear to converge on a few common biological pathways, and whether the pathways themselves might be treated as drugable targets. EXOME SEQUENCING OF AUTISM PATIENTS REVEALS A MIX OF GENES WITH LARGE AND MODEST EFFECTS ON LIABILITY Kaitlin Samocha1, Silvia De Rubeis2, Xin He3, Arthur Goldberg2, Christopher Poultney2, Lambertus Klei4, Benjamin Neale1, Stephen Scherer5, Jeffrey Barrett6, David Cutler7, Kathryn Roeder3, Bernie Devlin4, Mark Daly1, Joseph Buxbaum2 1 Massachusetts General Hospital, 2Icahn School of Medicine at Mount Sinai, 3Carnegie Mellon University, 4University of Pittsburgh School of Medicine, 5The Hospital for Sick Children, 6The Wellcome Trust Sanger Institute, 7Emory University School of Medicine Background The autism spectrum disorders (ASDs) are characterized by impaired speech and social interactions. Both common and rare genetic variation contribute significantly to ASD risk. The Autism Sequencing Consortium has been pursuing trio exome sequencing and using de novo point variants as anchor for gene discovery. The ASDs also show a notable gender bias with four times as many male cases as female. It is thought that there is a higher liability threshold for females to be considered autistic, and that females require a greater genetic burden to be diagnosed with ASD (also known as the female protective effect). A consequence of this model is that events with the same effect on liability – the same odds ratio – in males and females will be seen at a higher frequency in female cases. We can therefore use the frequency difference between male and female cases to estimate the odds ratio of a variant or set of variants. Methods Exome sequencing was performed on 3,781 autism cases – 2,297 of which were part of sequenced trios – and 9,937 ancestry-matched or parent controls. In order to identify sets of genes with strong associations to ASD risk, de novo variation was combined with transmission and case-control information in a weighted, Bayesian model named TADA (“Transmission and De Novo Association”; He et al. 2013). Results The TADA model identified a set of 33 genes with a false discovery rate (FDR) of < 0.1 and 107 genes with FDR < 0.3. All de novo and transmitted loss-of-function variants in these gene sets were then separated by the sex of the individual carrying the event. The set of genes with the greatest evidence for association with ASD (FDR < 0.1) had a significant enrichment of de novo loss-of-function variants within female cases (p = 0.005). Importantly, the ratio of female to male de novo loss-of-function events was 2, which indicates an odds ratio of 20 or greater for such events in this set of 33 genes. By contrast, the set of genes with FDR between 0.1 and 0.3 (n = 74) had much less of an enrichment of de novo lossof-function variants in female cases (ratio of ~1.3), indicating an odds ratio between 2-4 for these events. The rate of transmitted loss-of-function variants showed no significant difference between sexes for either gene set. Discussion These two sets of genes, while both significantly associated with ASD in this large cohort, appear to function in different ways. The set of genes with FDR < 0.1 represents a small group of genes in which damaging events, specifically de novo loss-of-function variants, have a high odds ratio. These genes likely represent key neurodevelopmental processes. This conclusion is supported by the observed overlap between this set of genes and established risk factors for epilepsy and intellectual disability. The genes with a smaller odds ratio, on the other hand, have less of an effect on phenotype and may contribute more to the heritability of ASD. USING GENOME-WIDE GXE ANALYSIS TO SEARCH FOR POTENTIAL MODIFIERS OF THE RISK EFFECT OF MATERNAL SMOKING ON THE EXPRESSION OF AUTISTIC TRAITS Beate St. Pourcain1, Dheeraj Raj2, Skuse David3, William Mandy3, Angelica Ronald4, Robert Plomin5, Jean Golding6, Sue Ring2, Wendy McArdle6, Nicholas Timpson2, John Kemp2, David Evans2, George Davey Smith2 1 University of Bristol, 2MRC Integrative Epidemiology Unit, University of Bristol, 3Institute of Child Health, University College London, , 4Department of Psychological Sciences, Birkbeck, University of London, 5Social, Genetic & Developmental Psychiatry Centre, Institute of Psychiatry, King’s College London, 6School of Social and Community Medicine, University of Bristol Background Maternal smoking during pregnancy has been discussed as a potential risk factor for the increase of autistic symptoms and autism though findings have been inconsistent. It is possible that maternal smoking might only elevate the expression of autistic symptoms in genetically susceptible individuals. Thus, GxE may conceal the true underlying relationship, and explain the inconsistencies in the literature. Using a genome-wide gene-environment analysis approach, we aimed to identify evidence for non-additive genetic influences in the architecture of social communication traits during childhood and adolescence as well as single genetic variant effects, which are specifically involved in a GxE interaction with respect to maternal smoking during pregnancy. Methods We studied up to 5628 children (ALSPAC) with information on maternal tobacco use during the first trimester of the pregnancy, data on social communication problems (Social Communication Disorders Checklist: 8, 11, 14 and 17 years) and imputed genome-wide genotype information. Follow-up analyses were performed in 1330 independent children (TEDS, 8 years) with information on maternal smoking during pregnancy, autism-like traits (total Childhood Asperger Syndrome Test scores) and imputed genotype information. Statistical analysis included a genome-wide screen for differences in phenotypic variance per genotype (Levene’s test) to identify a set of variants, which are likely to be involved in interactions. We then investigated all identified independent signals with respect to maternal smoking during the first trimester. For comparison, we also carried out a genome-wide screen for logadditive effects at each age using Quasi-Poisson regression. Results Levene-test screens in ALSPAC showed deviations from the expected distribution under the null hypothesis for social-communication difficulties at 8 and 11 years of age, compared to QuasiPoisson regression screens, but not later during development. 182 independent SNPs at 8 and 11 years (SNPs with Levene-P<10-5, and SNPs near ASD susceptibility loci with Levene-P<10-4) were investigated for interactions with maternal smoking during pregnancy. The strongest interaction effect (P(E)= 4.4x10-7, P(G)= 0.96, P(GxE)= 0.00016, P(E+GxE)=1.7x10-9) was found at a SNP within the RBFOX1 gene on 16p13.2 at 8 years of age, though this effect was attenuated during later development. Risk effects were only present in carriers of the homozygous common allele. There was no evidence for a main genetic effect. So, far we observed no evidence for replication within a smaller sized follow-up sample (TEDS) using similar measures (P(GxE)=0.34). Discussion Our findings suggest that non-additive effects contribute to the genetic architecture of social communication problems, especially during puberty, although the identification of single genetic variants might be affected by limited power, temporal variation and the search for the correct interaction partner. A FUNCTIONAL GENOMICS APPROACH TO UNDERSTAND GENETIC VARIATION IN (NON)NEURONAL CELL TYPES UNDERLYING AUTISM SPECTRUM DISORDERS Danielle Posthuma1, Gwen Dieleman2, Christiaan de Leeuw3, Andrea Goudriaan4, Tinca Polderman5, Matthijs Verhage5, Guus Smit4, Mark Verheijen4, Frank Verhulst6 1 VU University, 2Department of Child and Adolescent Psychiatry and Psychology, Erasmus University Medical Center-Sophia Children’s Hospital, 3Department of Complex Trait Genetics, VU University Medical Centre, Neuroscience Campus Amsterdam, the Netherlands. Institute for Computing and Information Sciences, Radboud University, 4Department of Molecular and Cellular Neurobiology, Centre for Neurogenomics and Cognitive Research, Neuroscience Campus Amsterdam, VU University, 5 Department of Complex Trait Genetics, VU University Medical Centre, Neuroscience Campus Amsterdam, 6Department of Child and Adolescent Psychiatry and Psychology, Erasmus University Medical Center-Sophia Children’s Hospital Background Autism spectrum disorders (ASD) are a highly heritable and heterogeneous group of disorders characterized by problems with communication, social interaction and repetitive and restricted behavior. Despite its high heritability, little is known about the genetic pathways underlying ASD and the contribution of common genetic variants. In this study we systematically investigated the contribution of common genetic variation in expert-curated sets of genes expressed in the brain to the risk for ASD. Methods We conducted gene-set analyses using data from healthy parents and their affected probands (trios) from the Autism Genome Project and Autism Genetic Resource Exchange, and gene-sets that were informative for specific synaptic and glial (oligodendrocyte, astrocyte, microglia) cell-type functions. Trio data were available from 3989 ASD patients and their parents and expression data were available for 193 healthy individuals. For secondary functional interpretation, we applied a joint association test to gene-expression data of cortical structures in healthy controls. Results We found three significantly associated gene-sets consisting of microglial genes related to cell proliferation, cell locomotion and taxis, and DNA metabolism. Genetic variation in a subset of microglial genes from the three significant gene-sets significantly predicted expression levels of microglial genes in post-mortem cortical samples of healthy subjects. Discussion Our results indicate that genetic variation in genes related to specific microglial function contribute to the pathophysiology in ASD. Given earlier observations of head overgrowth and hyperconnectivity in the brains of autism patients, and recent evidence that microglia cells might influence synaptic pruning and the number of neural cells in the developing brain, our findings suggest that genetic variation in microglia partially underlie neural overgrowth. INCREASED FEMALE BURDEN OF AUTOSOMAL CNVS IN CONTROL POPULATIONS Lauren Weiss1, Guillaume Desachy2, Anthony Torres3, Martin Kharrazi4, Gerald Delorenze5, Gayle Windham4, Cathleen Yoshida5, Lisa Croen5 1 University of California San Francisco, 2UCSF, 3Utah State University, 4California Department of Health Services, 5Kaiser Permanente Northern California Background Recently, increased copy number variant (CNV) burden in mothers compared with fathers of children with autism spectrum disorders (ASDs) and other neurodevelopmental disorders (NDDs) has been observed. We thus set out to explore this phenomenon, and surprisingly, we observed a higher autosomal burden of large, rare CNVs in females in the general population, reflected in, but not unique to, autism families. Methods We analyzed rare (<1%), large (>30kb) autosomal CNVs from published datasets including three autism family datasets (Autism Genetic Resource Exchange, Autism Genome Project, Simons Simplex Collection) and two large control datasets (HapMap, 1000 Genomes) to perform sex comparisons. We additionally utilized the Early Markers for Autism (EMA) study to compare the CNV profile between mothers of children with autism and mothers of controls to assess for the first time a sexmatched parental genetic contribution. Results In autism family genetic datasets, we observed maternal compared with paternal CNV enrichment. Similarly, in control datasets, we observed female compared with male enrichment for autosomal large, rare CNVs. Meta-analysis across datasets confirms consistent female excess in CNV number (P = 2.1 x 10-5) and deletion number (P = 1.1 x 10-3), as well as gene content within all CNVs (P = 4.1 x 10-3) and duplications (P = 3.2 x 10-3). Further, the increased burden was primarily in females with a high individual-level burden, e.g. multiple large, rare CNVs. To exclude a parent-ascertainment effect (e.g. fertility) from using primarily family-based datasets, we show an increased burden in the young female compared with male unaffected siblings of autism probands (P = 6.2 x 10-4). In a sexmatched maternal comparison, Wwe observed CNV enrichment in mothers of children with autism compared to control mothers (P = 0.03), but not in autism probands compared to controls. Discussion Overall, we found that non-psychiatric samples showed increased female CNV burden. Thus, we speculate that our data reflect an early developmental decreased male tolerance for high CNV burden, which might be consistent with increased male fetal loss in the population. Our sex-matched maternal analysis suggests that autism-specific maternal CNV burden may contribute to high sibling recurrence in autism. Our results emphasize the importance of sex-matched controls in all genetic studies and open a novel avenue for studying sexual-dimorphism in the population 2:45 PM - 4:45 PM Concurrent Symposia Sessions COPY NUMBER VARIATIONS IN ADULTS WITH NEURODEVELOPMENTAL DISORDERS Chair: Annick Vogels, University Hospitals Leuven, Department of Human Genetics, KU Leuven, Belgium Overall Abstract Details The development of microarray based technologies for comparative genomic hybridisation (array-CGH) analysis has enabled the detection of submicroscopic microdeletions or microduplications also referred as copy number variations (CNVs). Over the past 5 years a number of papers have reported an enrichment of CNVs in neurodevelopmental disorders such as intellectual disability, autism, attention deficit disorders and schizophrenia. The first speaker will present data of an international collaborative effort to provide an estimate of the frequency of CNV’s in 600 adults with a dual diagnosis of intellectual disability and one or more additional psychiatric disorder. Neuropsychiatric phenotypes including DSM-IV based diagnoses and cognitive functioning were investigated. Microarray analysis was performed in all adults to uncover the genetic risk factors that may contribute to the neurodevelopmental phenotypes. A diagnostic yield of 30 % was obtained. Some CNV’s such as Neurexin1 (NRXN1) are large and have multiple functions in both foetal and adult brain. The fourth speaker will present data on three unrelated patients affected by dysmorphy, mild intellectual disability and psychiatric disorder with a 2p16.3 deletion including NRXN1. We suggest that NRXN1 deletion is not only a risk factor for intellectual disability but is responsible of psychiatric disease with a variable expressivity. There was a particular high prevalence of 16p11.2 duplications in the group of mildly retarded adults while 22q11 deletions were relatively common in those with moderate to severe intellectual disability. The psychiatric phenotype of these CNVs are variable and will be discussed in the third and fourth presentations respectively. COPY NUMBER VARIATIONS IN A LARGE COHORT OF ADULTS WITH A DUAL DIAGNOSIS OF INTELLECTUAL DISABILITY AND NEUROPSYCHIATRIC DISORDERS Griet Van Buggenhout1, Miriam Guitart2, Nick Bass3, Annick Vogels4, Ramon Novell5, Andrew McQuillin3, Eddy Weyts6, Richard Cayenberghs6, Marina Viñas7, Kate Wolfe3, Joris Vermeesch4, Susanna Esteba-Castillo8, André Strydom3 1 University Hospital Leuven, 2Genetic Laboratory UDIAT-CD, Corporació Sanitària Universitària Parc Taulí, Sabadell, 3University College London4 University Hospitals of Leuven, KU Leuven - University of Leuven Department of Human Genetics, 5Mental Health & Intellectual Disability Specialized Service, 6 Psychiatric Hospital Sint-Kamillus, 7Genetic Laboratory, UDIAT-CD, Corporació Sanitària Universitària Parc Taulí, Sabadell, Universitat Autònoma de Barcelona, 8Neuropsychology, Mental Health & Intellectual Disability Specialized Service. IAS, Girona Individual Abstract The development of microarray based technologies for comparative genomic hybridisation (array-CGH) analysis has enabled the detection of submicroscopic microdeletions or microduplications referred to as copy number variations (CNVs). Over the past 5 years a number of papers have reported an enrichment of CNVs in neurodevelopmental disorders such as intellectual disability, autism, attention deficit disorders and schizophrenia. The goal of this study is to provide an estimate of the frequency of CNV’s in adults with a dual diagnosis of intellectual disability and one or more additional psychiatric diagnosis. This study is the result of an international collaborative effort of three institutions and combines genomic with phenotypic data to advance the understanding of the pathogenesis of neurodevelopmental disorders particularly intellectual disability, autism and psychosis. The consortium provides the largest available sample to date (n = 600) of genetic and phenotypically characteristics of adults with a dual diagnosis of intellectual disability and psychiatric disorders. Neuropsychiatric phenotypes including DSM-IV based diagnoses and cognitive functioning were investigated. Microarray analysis was performed in all 600 adults to uncover the genetic risk factors that may contribute to the neurodevelopmental phenotypes. A diagnostic yield of 30% was obtained. The CNV’s at loci 7q11.23, 15q11.2, 15q13, 16p11.2, 16p13.1, 22q11.21, 17p11.2, 3q29 were associated most frequently with the dual diagnosis of intellectual disability and neuropsychiatric disorders. We will present an overview of cognitive functioning, the neuropsychiatric phenotypes and CNV’s found in these 600 adults. COGNITIVE, PSYCHIATRIC AND DYSMORPHIC PHENOTYPE IN THREE FAMILIES WITH DELETION OF NRXN1 GENE Ramon Novell1, Marina Viñas3, Susanna Esteba-Castillo2, Elisabet Gabau4, Neus Baena4, Núria Ribas2, Miriam Gitart4 1 Institut Assistencia Sanitaria, 2Ps Mental Health & Intellectual Disability Specialized Service. IAS, Girona, 3Universitat Autònoma de Barcelona, 4Corporació Sanitària Universitària Parc Taulí, Sabadell Individual Abstract Deletions in 2p16.3 region including the neurexin (NRXN1) gene are involved with intellectual disability and different psychiatric disorders, in particular autism and schizophrenia. We present three unrelated patients, two adults and one child, affected with dual diagnoses of mild intellectual disability and psychiatric disorder in whom we identify an intragenic 2p16.3 deletion within NRXN1 gene using an oligonucleotide array CGH. All three patients had common cognitive features and a dysmorphic phenotype characterized by long face, deep set eyes and premaxilary prominence. Genetic analysis of family members showed one de novo and two inherited deletions. An exhaustive neuropshycological examination of the 2p16.3 deletion carriers revealed borderline intelligence, anxiety disorder and dysexecutive syndrome. The cognitive profile of dysexecutive syndrome that includes difficulties in working memory, switch attention, mental flexibility and verbal fluency was the same than the one observed in the adult probands. We propose that NRXN1 deletion is not only a risk factor for intellectual disability but is also responsible for the psychiatric disease. The phenotype found in the 2p16.3 deletion carriers suggests the notion that a 2p16.3 deletion has a variable expressivity instead of an incomplete penetrance. COGNITIVE AND BEHAVIORAL EFFECTS OF COPY NUMBER VARIATION AT THE 16P11.2 BP4-5 LOCUS Sébastien Jacquemont1, Anne Maillard2, Loyse Hippolyte2, Sébastien Lebon3, Aurélien Macé4, Sandra Martin2, Aurélie Pain2, Katrin Mannik5, Carina Ferrari6, Eugenia Migliavacca5, Zoltan Kutalik4, Philippe Conus6, Jacques S Beckmann7, Alexandre Reymond5, Sébastien Jacquemont2 1 CHUV, University of Lausanne, 2University Hospital of Lausanne, CHUV, 3Department of Pediatrics, CHUV, Lausanne, 4 University of Lausanne, and Swiss Institute of Bioinformatics Lausanne, 5Center for Integrative Genomics, University of Lausanne, Lausanne, Switzerland, 6Department of Psychiatry, CHUV, Lausanne, Switzerland, 7Swiss Institute of Bioinformatics Individual Abstract The 16p11.2 BP4-BP5 deletion (29.5-30.1), one of the most frequent known genetic etiologies of autism spectrum disorder (ASD), is associated with increased head circumference, body mass index and language impairment, while the reciprocal duplication is related to schizophrenia (SZ), decrease in head circumference, and underweight. As observed with other genomic disorders, the 16p11.2 Copy number variants (CNVs) show remarkably variable expressivity, which has hampered genetic counseling and patient management. The objective of the study is to i) define the medical, cognitive, and behavioral phenotypes in carriers of the BP4-5 deletion and reciprocal duplication and ii) characterize clinical manifestations and traits correlated to gene dosage at the 16p11.2 locus. Clinical data was collected on 310 deletion and 232 duplication carriers and performed detailed neuropsychological and psychiatric evaluations on 50 deletion and 41 duplication carriers as well as 38 intrafamilial controls. Effects of the CNVs were estimated using mixed models to account for the effect of kinship. The deletion demonstrates a consistent impact on neurodevelopment regardless of ascertainment. It lowers full scale IQ (FSIQ) by two standard deviation, verbal IQ being lower than non-verbal IQ, with a majority of carriers requiring speech therapy. Epileptic seizures are present in 24% of them. We also identified increased growth velocity of head circumference during infancy, which recapitulates the welldocumented pattern seen in ASD. The duplication shows a complex effect influenced by ascertainment methods. It is significantly associated with higher rates of both high- (FSIQ>100) and low-functioning (FSIQ<50) carriers when compared with deletion carriers (OR=4 and OR=8 respectively, p< 0.01). This may suggests that the extreme clinical spectrum is the consequence of an interaction between the duplication and other genetic or environmental factors. The frequency of a psychiatric diagnosis is high (approximately 80%) in both groups but psychosis was lower than expected in duplication carriers, possibly due our ascertainment methods. In the deletion and the duplication group, a second copy number variant was identified in a subset of carriers and the clinical presentation of these individuals sheds light on the interaction between the 16p11.2 locus and additional CNVs. Reciprocal rearrangements at the 16p11.2 locus represent powerful paradigms to investigate how genetic variants lead to complex neuropsychiatric phenotypes. DIAGNOSING 22Q11 DELETION SYNDROME IN ADULTS WITH NEURODEVELOPMENTAL DISORDERS Annick Vogels1, Ann Swillen2, Eddy Weyts3, Richard Cayenberghs3, Griet Van Buggenhout2 1 University Hospitals Leuven, Department of Human Genetics, KU Leuven, Belgium, 2University Hospitals of Leuven, Kuleuven-University of Leuven Department of Human Genetics, Leuven, Belgium Individual Abstract The study described in the first presentation of this symposium tried to estimate the frequency of copy number variations in adults with neurodevelopmental disorder. Out of a group of 600 adults with intellectual disability and one or more psychiatric disorders, 250 were recruited through a psychiatric inpatient unit for moderate to severely intellectually disabled. In this population, seven adults were found to have a previously undiagnosed 22q11deletion. Apart from the intellectual disability, none of them showed any of the clinical screening criteria for 22q11 Deletion Syndrome (22q11DS). They showed a wide variety of psychiatric diagnoses including psychotic disorders, mood disorders and severe aggression. The psychiatric phenotype will be described in the presentation. The average at diagnosis was high (51 years) and it is unlikely that they would have been diagnosed outside this screening program. These results raised the possibility that 22q11DS in adults without physical symptoms is more common than previously reported and easily missed. We therefore performed a retrospective study with the aim to describe presenting symptoms and age at diagnosis in a large 22q11DS population. A retrospective study was performed on 65 individuals diagnosed with 22q11DS at adult age. Data were collected on patients referred to the genetic clinic or actively recruited through systematic diagnostic examination in both institutions and a psychiatric unit for intellectually disabled. Presenting symptoms were categorized into seven groups: familial occurrence, intellectual disability, cardiac anomalies, palatal anomalies, facial dysmorphic features, psychiatric problems and 'other' (comprising all other features associated with 22q11DS). Age at diagnosis was defined as the age at which the 22q11.2 deletion was detected by fluorescence in situ hybridization or comparative genomic hybridization. Ascertainment subgroups were different in presenting symptoms and age at diagnosis. Adults were referred to the genetic clinic mainly because of familial occurrence, cardiac defects and psychiatric disorders whereas adults diagnosed in institutions for intellectually disabled presented mainly with moderate to severe intellectual disability and psychotic disorders. Adults diagnosed at the psychiatric unit for intellectually disabled had a variety of psychiatric disorders but none of them had additional physical features. This emphasizes the need to stay alert for presenting symptoms such as conotruncal heart defects or moderate to severe intellectual disability in combination with a history of psychiatric disorders, even in the absence of obvious physical features. IMMUNOMICS: EXPLORING NEW TERRITORY IN SCHIZOPHRENIA Chair: Jennie Pouget, Centre for Addiction and Mental Health Overall Abstract Details Interest in an immunological cause of schizophrenia has been renewed in recent years due to accumulating evidence from epidemiological, clinical, and genetic studies suggesting that the immune system is involved in the pathogenesis of schizophrenia. Most notable are the robust observations that early life infections, autoimmune diseases, antibodies against neuronal proteins, increased levels of circulating inflammatory cytokine, and genetic variation in the major histocompatibility complex (MHC) region are associated with schizophrenia. Taken together with recent neurobiological studies illustrating the important role of immune components (such as MHC class I, IL-6, and complement) in brain development, the immune disturbances observed in schizophrenia suggest an underlying immunological cause of the disease in some subset of patients. The immune hypothesis of schizophrenia is exciting clinically because it may provide an opportunity to leverage biologic therapeutics currently being developed to treat autoimmune diseases for use in schizophrenia. Previously it has been difficult to test this hypothesis rigorously, and the majority of evidence has relied on epidemiological data. The generation of large-scale genome-wide association study (GWAS) and sequencing data has provided an opportunity to begin testing the immune hypothesis of schizophrenia rigorously using genetic approaches. This session is designed to illustrate the genetic approaches that can be used to further our understanding of the role of the immune system in schizophrenia. It will give a first glimpse of the results of such investigations, and highlight the need for future research in this area. HYPOTHESIS-DRIVEN GENOME-WIDE ASSOCIATION STUDY HIGHLIGHTS THE ROLE OF IMMUNE GENES IN THE EXTENDED MAJOR HISTOCOMPATIBILITY COMPLEX IN SCHIZOPHRENIA Jennie Pouget1, Vanessa Gonçalves1, Lei Sun2, James Kennedy1 1 Centre for Addiction and Mental Health, 2Dalla Individual Abstract Background: Converging evidence from epidemiological and animal studies suggests that early-life infections increase the risk of schizophrenia. Genetic susceptibility modulates the risk of developing schizophrenia following exposure to early-life infection, leading us to hypothesize that risk variants in immune genes may constitute a necessary "first hit" in order for a "second hit", such as infection, to cause schizophrenia. To evaluate this hypothesis, we investigated the contribution of 953 known immune genes to schizophrenia using a hypothesis-driven genome-wide association study (GWAS) approach. Methods: The Psychiatric Genomics Consortium schizophrenia GWAS (N=9,394 cases and 12,462 controls) was analyzed using a univariate approach with all single-nucleotide polymorphisms (SNPs) weighted equally. Hypothesis-driven analysis of the GWAS data was then performed using the stratified false-discovery rate (sFDR) method to upweight 15,070 SNPs in 953 genes with a demonstrated function in immune response based on public annotation databases. Results: None of the immune SNPs achieved genome-wide significance in the univariate analysis (p>5x10-8). After upweighting immune gene SNPs using the sFDR method, SNPs in UBD (rs404240, p=1.1x10-6, qSFDR=0.02), CFB (rs1270942, p=5.7x10-6, qSFDR=0.02), HLA-DQA1 (rs2187668, p=4.4x10-6, qSFDR=0.02), and HLA-DQB1 (rs2854275, p=4.8x10-6, qSFDR=0.02) were significantly associated with schizophrenia. Discussion: Incorporating prior biological evidence improved the ability to identify immune genes important in schizophrenia, with four SNPs in the extended major histocompatibility complex (xMHC) identified in the immune hypothesis-driven analysis. The xMHC is an 8Mb region of chromosome 6p previously associated with schizophrenia. Our results highlight the potential importance of ubiquitin D (UBD) and complement factor B (CFB), which are involved in innate immunity and complement system activation, respectively. Interestingly, HLA-DQA1 and -DQB1 have previously been associated with autoimmune diseases. All four of these genes are expressed by microglia, the resident immune cells of the central nervous system. Our results further highlight the importance of the xMHC in schizophrenia, and point to microglia as a cell type of particular interest in future functional genetic studies. NEW DATA TO INVESTIGATE AN OLD EPIDEMIOLOGICAL PUZZLE: THE NEGATIVE ASSOCIATION BETWEEN SCHIZOPHRENIA AND RHEUMATOID ARTHRITIS Naomi Wray1, S. Hong Lee 2, Enda M. Byrne2, Stephan Ripke 3, Xinli Hu 4, Yukinori Okada5, Eli A. Stahl 6, Thomas Frissell 7, PGC-SCZ Consortium, RACI Consortium, Swedish SCZ Consortium, Bryan F. Mowry 2, Soumya Raychaudhuri4 1 The University Of Queensland, 2Queensland Brain Institute, The University of Queensland, 3Analytic and Translational Genetics Unit, Massachusetts General Hospital, 4Brigham and Women's Hospital, Harvard Medical School, 5Graduate School of Medical and Dental Sciences, Tokyo Medical and Dental University, Tokyo, Japan & Laboratory for Statistical Analysis, RIKEN Center for Integrative Medical Sciences, Yokohama, Japan, 6 The Department of Psychiatry at Mount Sinai School of Medicine, 7 Karolinska Institutet Individual Abstract Background: A long-standing epidemiological puzzle is the reduced rate of rheumatoid arthritis (RA) in those with schizophrenia (SCZ) and vice versa, made even more puzzling because smoking is a major risk factor for RA and smoking rates are high in those with SCZ. Traditional epidemiological approaches to determine if this negative association is underpinned by genetic factors would test for reduced rates of one disorder in relatives of the other. However, since both disorders affect only ~1% of the population very large samples of families with multiple family members measured for both disorders are needed, which are difficult to achieve. The genomics era presents an alternative paradigm for investigating the genetic relationship between two uncommon disorders using samples of cases and controls that are unrelated in the classical sense. Methods: We use data from genome-wide association studies comprising 8064 seropositive cases and 26737 controls for RA and 12,793 cases and 15,912 controls for SCZ. We used the single nucleotide polymorphism (SNP) genotypes to estimate the genetic similarity between all pairs of individuals, both across the whole genome and for regions annotated by function. We tested the hypothesis that SCZ cases are genetically different to RA cases. Results: We estimated a small but significant negative genetic correlation between RA and SCZ of -0.05 (s.e. 0.03, p=0.04) across the whole genome. The negative correlation increased to -0.17 (s.e.0.071, p=0.007) when only coding and regulatory regions were considered. Previous analyses of RA have highlighted the importance of genes expressed in CD4+ effector memory T cells. The correlations were more negative and more significant when the MHC region was excluded. Discussion: We provide evidence that some genetic risk factors for RA are protective for SCZ and vice versa and that these risk factors are clustered according to functional annotation. We hypothesize that these pathways are of particular relevance in the context of environmental immunological challenges. The existence of antagonistically pleiotropic alleles may explain why common risk variants are maintained in the population. AN EXTREME FORM OF STRUCTURAL VARIATION IN THE HUMAN HLA LOCUS Steven McCarroll1 1 Stanley Center for Psychiatric Research, Broad Institute of MIT and Harvard Individual Abstract We describe an extreme form of structural variation that is present in the human genome’s HLA locus. We show that parts of the HLA locus segregate in dozens of different structural forms in human populations, appearing in widely different copy numbers and larger-scale structures. This form of genetic variation has not been previously ascertained in genome data resources (such as HapMap), in imputation resources (such as 1000 Genomes), in genome-wide association studies, or in exome sequencing. We show that this series of structural alleles consists of common, low-frequency, and rare alleles. These structures have complex linkage disequilibrium relationships with other markers in the HLA. Of course an exciting possibility is that such variation might be contributing to schizophrenia's complex and historically confusing pattern of association to markers across the HLA locus. To analyze the relationship of this novel form of genome variation to human phenotypes, we developed a way to infer these complex genome structures by imputation from dense SNP data. This has allowed us to test long allelic series of functional alleles for relationships to both gene expression and clinical phenotypes. We will describe the results of analyses relating these genome structures to schizophrenia, autoimmune, and auto inflammatory diseases. THE MICROBIOME: THE MISSING LINK IN THE PATHOGENESIS OF SCHIZOPHRENIA Robert Yolken1, Faith Dickerson2 1 Johns Hopkins, 2Sheppard Pratt Hospital Individual Abstract Recent studies indicate that individuals with schizophrenia have evidence of immune activation that may contribute to disease pathogenesis. The source of this immune activation has not been identified but is likely to be related to both genetic and environmental components. Recently it has become apparent that the composition of microbes on mucosal surfaces, termed the microbiome, represents an important modulator of the immune response in humans and in experimental animals. The microbiome has been linked to the generation of an aberrant immune response and also been shown to modulate brain development and behaviour in animal model systems. We employed high throughput sequencing to characterize the complete oro-pharyngeal microbiome of 41 individuals with schizophrenia and 32 controls without a psychiatric disorder. We also examined the role of probiotics in modulating the microbiome. Interim analysis indicates that there are large differences between case and control individuals in terms of bacterial, viral, and fungal composition. Individuals with schizophrenia had increased levels of lactic acid bacteria including Lactobacillus casei, Lactobacillus salivarias, Lactobacillus lactis, and Streptococcus thermophilius as well as several other species of streptococci including S mitis and S mutans. Several of these bacteria have been associated with altered Th2 immune responses, an immunological change also noted in schizophrenia. On the other hand, individuals with schizophrenia had decreased levels of many non-pathogenic bacteria such as strains of Neisseria, Haemophilus, Prochlorococcus, and Shwanella. Within the group of individuals with schizophrenia, altered levels of microorganisms were associated with an increased prevalence of the deficit syndrome as well as increased levels of intestinal immune activation as indicated by antibodies to food and intestinal antigens. In terms of fungi, individuals with schizophrenia had higher levels of pathogenic yeasts such as Candida glabrata and Candida tropicalis, but lower levels of the relatively less pathogenic Candida albicans. We also characterized a number of known human viruses such as Herpesviruses and Papillomaviruses, as well as bacteriophages and novel viruses. The microbiome was significantly altered by probiotic therapy, with a tendency towards normalization following treatment. Furthermore, many of the species which are increased in the oral microbiome of individuals with schizophrenia, such as streptococci, are modifiable by the administration of antibiotic medications. These studies indicate that the oral microbiome is altered in individuals with schizophrenia and that the microbiome is a potential target for novel therapies. SYSTEMS BIOLOGY APPROACHES IN PSYCHIATRIC DISORDERS Chair: Kasper Lage, Harvard Medical School, Massachusetts General Hospital, Broad Institute Overall Abstract Details The recent explosion in genome-wide association studies, exome-sequencing projects, and epigenetic data sets, have revealed many genetic variants likely to be involved in psychiatric disease processes, but the composition and function of the molecular systems they affect remain largely obscure. This limits our progress towards biological understanding and therapeutic intervention. To deduce function from genetic variation there is a need for systematic approaches that can harness the power of model systems, functional genomics, medical records, biological networks, patterns of comorbidity and computation to identify unknown or unexpected pathways perturbed in disease. This session will highlight methods and experiments being developed in this area and broadly exemplify how systems biology has been used to analyze and inform genetic variation and phenotype-genotype relationships. We will introduce specific algorithms, portals, and experimental techniques being applied in the field, which will enable the audience to apply systems-based approaches and mentality to their work on psychiatric disorders moving forward. FUNCTIONAL INTERPRETATION OF GENOMES USING BIOLOGICAL NETWORKS Kasper Lage1 1 Harvard Medical School, Massachusetts General Hospital, Broad Institute Individual Abstract Computational analyses that integrate biological networks (e.g., based on proteinprotein interaction data, gene expression correlations, synthetic lethality relationships, or text mining) with genetic data have emerged as a powerful approach to functionally interpret large genomic data sets scalable to the rapid production of data. With a particular focus on psychiatric disorders, this talk will highlight algorithms, statistics, and web portals being developed in this area and will exemplify how draft molecular systems involved in many different diseases have been reverse engineered from genomic data. Moreover, the talk will illustrate how network-based analyses of genetic variants associated with psychiatric disorders could be used as the starting point for targeted and cost-efficient experiments to deduce high-resolution networks involved brain signaling. NETWORK-BASED ASSOCIATION MODELS FOR EXOME-SEQUENCING DATA Shaun Purcell1 1 Icahn School of Medicine at Mount Sinai Individual Abstract Large-scale whole-exome sequencing studies of common, complex disease, now an achievable reality for many groups, hold great promise for connecting genetic risk to the specific, molecular mechanisms of disease. However, as we will discuss, it is becoming increasingly clear that such studies will often be unlikely to succeed if each gene is analyzed individually and independently of its broader genetic and biological context. To address this, network-based representations of exome data provide a means to capture the dependencies between genes and to test jointly multiple genes for increased rare variant burden. Applied to a large (N>5000) exome-sequencing study of schizophrenia, in contrast to geneset-enrichment approaches, we evaluate the performance of several network-based association methods (using protein-protein interaction data) to a) test for increased connectivity of topranked genes, b) test dynamically-generated sets of neighboring genes jointly, and c) combine genetic data from different assays (CNV, GWAS and exome data) within this context. We will also present software that implements the analyses discussed. DATA INTEGRATION FOR THE UNDERSTANDING OF COMORBIDITIES BETWEEN PSYCHIATRIC DISORDERS AND OTHER DISEASES Søren Brunak1 1 Technical University of Denmark Individual Abstract Electronic patient records remain a rather unexplored, but potentially rich data source for discovering correlations between diseases, drugs and genetic information in individual patients – correlations which may point at the underlying network biology. Such data makes it possible to compute fine-grained disease co-occurrence statistics, and to link the comorbidities to the treatment history of the patients. A fundamental issue is to resolve whether specific adverse drug reaction stem from variation in the individual genome of a patient, from drug/environment cocktail effects, or both. Temporal analysis of the records can be used to identify ADRs directly from the free text narratives describing patient disease trajectories over time. ADR profiles of approved drugs can then be constructed using drug-ADR networks, or alternatively patients can be stratified from their ADR profiles and compared. Given the availability of longitudinal data covering long periods of time we can extend the temporal analysis to become more life-course oriented. We also describe how the use of an unbiased, national registry covering 6.2 million people from Denmark can be used to construct disease trajectories which describe the relative risk of diseases following one another over time. We show how one can “condense” millions of trajectories into a smaller set which reflect the most frequent and most populated ones. References Using electronic patient records to discover disease correlations and stratify patient cohorts. Roque FS et al., PLoS Comput Biol. 2011 Aug;7(8):e1002141. Mining electronic health records: towards better research applications and clinical care. Jensen PB, Jensen LJ, and Brunak S, Nature Reviews Genetics, 13, 395-405, 2012. A nondegenerate code of deleterious variants in mendelian Loci contributes to complex disease risk. Blair DR, Lyttle CS, Mortensen JM, Bearden CF, Jensen AB, Khiabanian H, Melamed R, Rabadan R, Bernstam EV, Brunak S, Jensen LJ, Nicolae D, Shah NH, Grossman RL, Cox NJ, White KP, Rzhetsky A. Cell. 155, 70-80, 2013. Dose-specific adverse drug reaction identification in electronic patient records, Robert Eriksson R, Werge T, Jensen LJ, Brunak S. Drug Safety, 37, 237-247, 2014. Temporal disease trajectories condensed from population-wide registry data covering 6.2 million patients Jensen AB, Moseley PL, Oprea TI, Ellesøe SG, Eriksson R, Schmock H, Jensen PB, Jensen LJ, Brunak S. Nature Comm, to appear 2014. A CROSS-SPECIES NEUROGENOMICS APPROACH TO GENETIC BASIS OF ANXIETY DISORDERS Iiris Hovatta1 1 University of Helsinki Individual Abstract Anxiety and fear are normal emotional responses to threatening situations. However, these responses are excessive and prolonged in anxiety disorders, which include panic disorder, obsessive-compulsive disorder, post-traumatic stress disorder, social and specific phobias, and generalized anxiety disorder. Anxiety disorders were the most common mental disorders in the EU in 2010. The major challenges in the field are to identify the molecular events that initiate and maintain pathological anxiety, and determine how to normalize this pathology. Accordingly, there is a need to find novel, well-defined and clinically relevant drug targets. We have used mouse and human genetic approaches to identify genes that regulate anxiety. The use of mouse models is supported by two strong lines of evidence. First, neuroevolutionary studies show that anxiety is an adaptive response conserved in evolution. Second, several well-validated mouse models are considered appropriate for human anxiety. We have used RNAseq and miRNAseq of known brain anxiety circuits, followed by bioinformatic analysis to identify gene pathways involved in anxiety-like behavior. We are using two different mouse models. The first is a well-established model of innate anxiety, consisting of 6 inbred strains. The second, called social defeat, is widely used in psychosocial stress studies because such stress is the major environmental risk factor for anxiety disorders. This model increases anxiety-like behavior, causing long- term molecular changes in brain. By applying this model to four different genetic backgrounds allows us to investigate gene-environment interactions behind psychosocial stress-induced anxiety. To translate results from the mouse models to human anxiety disorders, we rely on DNA-based methods because of the impracticalities of studying human brain tissue, even post-mortem, from wellcharacterized anxiety disorder patients. We use publicly available mouse genome sequence data to select preferentially cis- regulated differentially expressed genes from our mouse models to be investigated for association to anxiety disorders and anxiety symptoms in Finnish epidemiological cohorts. THE EFFECT OF PSYCHOSIS RISK GENES ACROSS THE PHENOTYPIC SPECTRUM Chair: Anil Malhotra, The Zucker Hillside Hospital Overall Abstract Details The proposed symposium will focus on large scale efforts targeted toward understanding the effects of psychosis risk genes using phenotypes of gene expression (from postmortem brain), structural and functional neuroimaging, and cognitive performance. Dr. Thomas Hyde will use a lifespan developmental approach focused upon the identification of abnormalities in the transcriptome by studying full length and alternative transcripts in large postmortem brain datasets in a host of genes identified through clinical genome-wide association studies. Such an approach is particularly important since many risk variants may exert their deleterious effects long before the range of ages typically associated with the onset of illness. Dr. Ole Andreassen will describe transcriptomic approaches in blood, and enriched polygenic approaches, which have recently been developed using a Bayesian statistical framework. He will present findings showing a polygenic pleiotropy between recent schizophrenia GWAS hits from the PGC, and prefrontal cortical GWAS, strongly indicating a common genetic mechanisms between schizophrenia disease development and prefrontal cortical abnormalities, the brain region most often implicated in schizophrenia. Dr. Anil Malhotra will then address the relationship between genes implicated in schizophrenia by large scale GWAS and normal human cognitive ability. Moreover, in the context of a large collaborative enterprise, he will discuss the overlap between genes that influence cognitive ability, as well as specific domains of cognitive function, and genes that influence schizophrenia risk. Finally, Dr. Aristotle Voineskos will discuss the use of additive genetic approaches in a study examining relationships among several schizophrenia risk genes, brain structural connectivity, and cognitive performance. He will show that an additive genetic risk model can predict a substantial percentage of the variance in brain structural connectivity and cognitive performance among people with schizophrenia, and will discuss how such an approach is relevant in the clinical domain, namely via heterogeneity dissection and biological subtyping of disease. Overall, this collection of presentations brings together the effects of psychosis risk genes on gene expression, neuroimaging, and cognitive data, which when taken together outline schizophrenia risk pathways. In addition, when these approaches are applied in patients with schizophrenia, they can be used to predict disease severity. In turn, these pathways provide converging evidence for specific targets for therapeutic development. GENETIC RISK, NEURODEVELOPMENT, AND THE MOLECULAR PATHOLOGY OF SCHIZOPHRENIA Thomas Hyde1, Joel Kleinman1, Daniel Weinberger1, Andrew Jaffe1, Ran Tao1, Joo Heon Shin1, Gianluca Ursini1, Paul Harrison2, Helena Cousijns2, Brady Maher1, Sharon Eastwood2, Michelle Mighdoll1 1 Lieber Institute for Brain Development, 2Oxford University Individual Abstract The neurodevelopmental hypothesis of schizophrenia posits that the pathological basis of this disorder originates from anomalies in the normal trajectory of brain maturation. Recent large- scale genome-wide association studies have identified multiple sites of allelic variation associated with increased risk for schizophrenia. Reconciling the neurodevelopmental hypothesis with recently identified genetic variations requires a careful molecular interrogation of the developing nervous system. Many of these genetic variations may exert their deleterious effect on the brain decades before the onset of illness. For a number of genes, the risk allele for schizophrenia does not appear to alter the expression of the full- length transcript, either in the fetus or in the adult. The key to understanding the molecular mechanisms of genetic risk relies upon defining the family of transcripts derived from each risk gene. High throughput analyses of gene expression using RNAseq and related technologies have identified transcripts that are preferentially expressed in fetal development. Moreover, risk alleles in multiple genes are associated with alterations in the expression pattern of these fetal-predominant alternative transcripts. Schizophrenia- associated alleles in ZNF804a and GAD1 are examples of genetic variations that are associated with changes in transcripts highly expressed early in brain development. For both genes, studying the expression of the full-length transcript does not fully explain how the risk allele might alter gene expression. Instead, the risk allele is associated with significant alterations in the expression of a truncated transcript that is expressed at high levels early in brain development. The molecular mechanism of genetic risk only can be explained by defining the library of transcripts derived from each risk gene, delineating the pattern of the expression of each transcript across the lifespan in non-neurologic nonpsychiatric controls, and then looking for a relationship between genetic variation and transcript expression. RELATIONSHIP BETWEEN SCHIZOPHRENIA GENES AND NEUROIMAGING PHENOTYPES IN SEVERE MENTAL DISORDERS Ole Andreassen1 1 University of Oslo Individual Abstract The functional consequences of newly discovered schizophrenia risk genes can be investigated in vivo in patients, using brain imaging technology and deep phenotyping (cognition, symptom characteristics). This approach has been fruitful for some individual risk variants, providing insight of gene effects in clinical samples. Variants in the Major Histocompatibility Complex (MHC) are associated with larger ventricle size - a MRI characteristic found in many schizophrenia studies. CACNA1C risk variants have repeatedly been found associated with functional brain abnormalities, using fMRI technique. The phenotypic picture associated with other variants, such as ZNF804A and DISC1 seem to be less clear, while TCF4 is associated with a more neurodevelopmental deficit pattern, associated with earlier age at onset, negative symptoms as well as cognitive dysfunction in schizophrenia. From a clinical perspective, blood mRNA levels could be a fruitful avenue for biomarker identification, and recent evidence suggest a series of expression changes related to risk variants of TCF4, ANK3 and NOTCH4 in severe mental disorders. However, all these variants each confer a small increase in disease risk. Thus, maybe the most interesting line of results come from enriched polygenic approaches, investigating the complex effect of a series of risk variants for schizophrenia. We have recently developed novel Bayesian statistical framework leveraging the polygenic architecture of schizophrenia and other complex disorders. We will present recent findings showing a polygenic pleiotropy between recent schizophrenia GWAS hits from the Psychiatric Genomics Consortium, and prefrontal cortical brain MRI GWAS. These results strongly indicate a common genetic mechanisms between schizophrenia disease development and prefrontal cortical abnormalities, the brain region most often implicated in schizophrenia development. GWAS OF GENERAL COGNITIVE ABILITY AND OVERLAP WITH SCHIZOPHRENIA Anil Malhotra1, COGENT Consortium 1 The Zucker Hillside Hospital, Individual Abstract It has long been recognized that generalized deficits in cognitive ability represent a core component of schizophrenia (SCZ), evident before full illness onset and independent of medication. The possibility of genetic overlap between risk for SCZ and cognitive phenotypes has been suggested by the presence of cognitive deficits in first-degree relatives of patients with SCZ; however, until recently, molecular genetic approaches to test this overlap have been lacking. Within the last few years, large-scale genome-wide association studies (GWAS) of SCZ have demonstrated that a substantial proportion of the heritability of the disorder is explained by a polygenic component consisting of many common singlenucleotide polymorphisms (SNPs) of extremely small effect. Similar results have been reported in GWAS of general cognitive ability. The primary aim of the present study is to provide the first molecular genetic test of the classic endophenotype hypothesis, which states that alleles associated with reduced cognitive ability should also serve to increase risk for SCZ. We tested the endophenotype hypothesis by applying polygenic SNP scores derived from a large-scale cognitive GWAS meta-analysis (~5000 individuals from nine nonclinical cohorts comprising the Cognitive Genomics Consortium (COGENT)) to four SCZ case- control cohorts. As predicted, cases had significantly lower cognitive polygenic scores compared to controls. In parallel, polygenic risk scores for SCZ were associated with lower general cognitive ability. In addition, using our large cognitive meta-analytic data set, we identified nominally significant cognitive associations for several SNPs that have previously been robustly associated with SCZ susceptibility. Moreover, we also tested SNPS linked to schizophrenia risk in the COGENT data set, and found modest evidence that that schizophrenia risk alleles predicted lower performance on tests of generalized cognitive ability. Additional, domain-based analyses are now being conducted in a new significantly larger data set and should provide more specific data on the genetic overlap between SCZ and general cognitive ability, and may provide additional insight into pathophysiology of the disorder. ADDITIVE GENETIC RISK MODELLING PREDICTS PHENOTYPIC HETEROGENEITY IN BRAIN STRUCTURE AND COGNITIVE PERFORMANCE IN PEOPLE WITH SCHIZOPHRENIA Aristotle Voineskos1, Tristram Lett2, James Kennedy2, Daniel Felsky2, Benoit Mulsant2, Tarek Rajji2, Mallar Chakravarty2, Jo Knight2 1 University of Toronto, 2Centre for Addiction and Mental Health, University of Toronto Individual Abstract There is growing theoretical and empirical evidence that additive genetic variation accounts for a considerable percentage of the variance in complex traits. The emerging results of the PGC coupled with known effects of other genetic variants on brain structure and function provides an opportunity to use additive risk modeling to obtain a more comprehensive neurobiological understanding of phenotypic variability among people with schizophrenia. In healthy controls and schizophrenia patients (N=198), we examined the association between an additive genetic model and brain structure via brain- wide analysis of cortical thickness (vertex-wise analysis), and white matter FA (tract-based spatial statistics), as well as cognitive performance. Our additive model included risk alleles with genome-wide association evidence, namely MIR137 (rs1622579), CACNA1C (rs1006737), ZNF804A (rs1344706); and risk alleles from genes with well-established effects on brain structure and function, namely GAD1 (rs3749034), and BDNF (rs6265). Voxel-wise white matter FA mediation analysis was performed on cognitive domains significant associated with additive genetic risk. We found that additive schizophrenia risk score predicted white matter integrity throughout the brain (pcorrected<0.001), and there was a significant model-by-diagnosis interaction predominately in the corpus callosum. There was also a significant vertex-wise interaction between our additive risk score and diagnosis in cortical thickness. High genetic risk loading predicted poor cognitive performance and the effect was greater among schizophrenia patients for verbal fluency (F1,64=9.8, p=0.003; interaction, F1,64=4.7, p=0.031) and motor functioning (F1,64=5.4, p=0.020; interaction, F1,64=10.1, p=0.002)). Voxel-wise FA mediation analyses showed that genetic risk loading on verbal fluency was caused by white matter changes predominately in the corpus callosum (Pcorrected[Sobel] < 0.001). Our findings suggest that the additive genetic risk model that we tested predicts changes in brain structure and cognitive function, and provides a direct link from genetic variation to white matter FA to cognitive performance. 7:00 PM - 9:00 PM Concurrent Symposia Sessions THE INTERPLAY BETWEEN GENETICS AND EARLY TRAUMA IN SEVERE MENTAL DISORDERS Chair: Ingrid Melle, Division of Mental Health and Addiction, Institute of Clinical Medicine, University of Oslo Overall Abstract Details Early stressful life events increase the risk of developing severe mental disorders and influence post-onset severity indicators, course and outcome. The biological mechanisms behind these effects including when- and how- the effects of early trauma interact with genetic risk factors are not fully known. The current symposium focuses on the effect of early trauma spanning the range from animal studies to clinical studies. The first presentation describes the use of a rat prenatal stress (PNS) model to investigate molecular and functional changes that could contribute to development or maintenance of a phenotype based in early life adversity, comprising changes in the expression of neurotrohpins and epigenetic regulators, changes in prefrontal methylation of gene promotors relevant for neuronal function and psychiatric disorders including schizophrenia, in addition to a cross-species approach, as this may allow us to prioritize the list of relevant genes affected by early life adversities. The second presentation focus on blood transcriptomics; studying mRNA levels of inflammatory biomarkers and cytokine related pathways in groups exposed to versus not exposed to childhood trauma across healthy control subjects and patients with depressive disorders; to capture gene expression changes related to both genetic variation and environmental effects. The third presentation investigates how different types of childhood trauma influence the clinical expression and severity indicators in 308 patients with bipolar disorders; in particular the interaction between early trauma and known variants of the serotonin transporter gene. Emotional and sexual abuse was associated with a more severe expression of the disorder such as an earlier age at onset, increase in suicide attempts, more rapid cycling and greater proneness to depression. There was an additional effect of 5HTTLPR genotype on time to onset of BD. The fourth presentation looks at how childhood trauma and a known variant in the gene for the neurotrophin BDNF (val66met) influence the volume of hippocampal subfields in psychotic disorders. It has previously been shown changes in hippocampal subfields in patients with schizophrenia and bipolar disorder relative to controls and that early trauma and BDNF genetic variation influence hippocampal volume. The study indicates an additive effect of trauma and the BDNF(val66met) on blood BDNF RNA levels and on hippocampal subfield volume. Taken together; the presentations imply that early adversity have long term effects on gene expression, affecting neurotrophins, stress response systems and inflammatory biomarkers with potential influence on brain morphology and severity indicators in severe mental disorders (bipolar disorder and schizophrenia). EARLY LIFE STRESS AND LONG-TERM PSYCHOPATHOLOGY: THE ROLE OF EPIGENETICS Marco Riva1 1 University of Milan Individual Abstract Perinatal life is a period of high plasticity and vulnerability to adverse life conditions, which may enhance the susceptibility to chronic diseases, including psychiatric disorders. In particular, exposure to stress during gestation produces complex alterations, including depressive-like behavior and cognitive defects. With this respect, the use of animal models is instrumental for the identification of the systems that may be responsible for the occurrence of a pathologic phenotype. On these bases, we used the rat prenatal stress (PNS) model to investigate molecular and functional alterations that may contribute to the development or maintenance of the phenotype that originate from the exposure to early life adversity. At molecular level, PNS rats show a region- and time-specific reduction in the expression of the neurotrophin BDNF, a marker of neuronal plasticity that has an important role in mood and cognitive function. BDNF changes are sustained by the modulation of specific neurotrophin transcripts with the contribution of epigenetic mechanism. We also found that exposure to PNS produces significant changes in the expression of several epigenetic regulators, including DNMT1, Gadd45ß as well as HDACs. In order to characterize in more details the epigenetic changes produced in response to PNS, we performed an epigenome-wide analysis in the prefrontal cortex and hippocampus of male and female rats using a 400K promoter tiling array. A high number of gene promoters were differentially methylated in PNS rats when compared to control animals, with a highly significant association for neuronal functions and psychiatric disorders, in particular schizophrenia. We next employed a convergent cross-species approach to compare the list of genes differentially methylated in PNS rats with methylation changes identified in a cohort of monkeys exposed to maternal separation as well as with changes found in CD34+ stem cells derived from cord blood in human neonates whose mother were grouped on the basis of early life stress exposure. Such analyses allowed us to prioritize the list of genes that are affected by early life adversities and that may therefore play a relevant role for psychopathology and disease susceptibility. Our data provide further support to the notion that early life stress leads to permanent functional and molecular changes in the offspring and highlight the importance of the identification of methylation signatures that could serve as predictive and diagnostic markers. This will eventually lead to the identification of novel genes and pathways that contribute to long-term susceptibility for mental illness and may be a suitable target for pharmacological intervention. BLOOD TRANSCRIPTOMICS AS TOOL TO IDENTIFY THE LONG LASTING EFFECTS OF CHILDHOOD TRAUMA ON PSYCHOPATHOLOGIES DEVELOPMENT Annamaria Cattaneo1, Alessia Luoni2, Giona Plazzotta2, Marco A. Riva2, Valeria Mondelli3, Patricia Zunszain3, Carmine M. Pariante3 1 King's College London, Institute of Psychiatry; IRCCS Fatebenefratelli Brescia; Department of Pharmacological and Biomolecular Sciences., 2Department of Pharmacological and Biomolecular Sciences, University of Milan, 3King's College London, Institute of Psychiatry Individual Abstract It is well known that a history of early life stressful events increases the vulnerability in the adulthood to develop psychiatric disorders; however, the biological mechanisms underlying this association require further investigation. This talk will focus on the role of childhood trauma in causing changes in specific molecular pathways, which persist over time, and thus, are responsible of increasing the vulnerability to develop depression or other psychopathologies in the adulthood. Blood transcriptomics captures not only gene expression changes due to genetic variability, but also those related to the effect of the environment. Thus, it closer reflects the individual phenotype, and may better represent a promising approach to identify biomarkers associated with increased vulnerability for psychiatric disorders, and novel targets for pharmacological interventions. By using a transcriptomic approach we found that control subjects, which were exposed to childhood trauma events, have higher blood mRNA levels of several inflammatory biomarkers, including: pro-inflammatory cytokines IL-6, MIF and TNF-a, as well as alterations in cytokines-related pathways. Moreover, we have found alterations in the mRNA levels of genes involved in the stress response, and in particular of the mineralcorticoid receptor, of the glucocorticoid receptor and of the serum glucocorticoid kinase (SGK1), a kinase specifically activated by glucocorticoids. SGK1 mRNA levels are higher in control subjects with a history of childhood trauma events as compared with subjects without such experiences; higher SGK1 mRNA levels are also observed in depressed patients without early life stressful events and a further increase can be observed in depressed patients with childhood trauma. This suggests an additive effect of the two components, illness and trauma, in the modulation of SGK1 mRNA levels. Similarly, SGK1 mRNA levels are increased also in the hippocampus of adult rats, which have been exposed to prenatal stress, whereas no alterations can be observed during the previous ages. This supports a long lasting effect of the prenatal stress on SGK1 levels. In order to explain the effect of an early stress on molecular alterations observed later in life, putative mechanisms involving miRNAs and methylation changes will therefore be discussed. CHILDHOOD TRAUMA AND BIPOLAR DISORDERS: SEVERE CLINICAL EXPRESSION AND MODERATION BY GENETIC FACTORS Bruno Etain1, Monica Aas2, Frank Bellivier3, Ingrid Melle2, Chantal Henry4, Ole Andreassen5, Marion Leboyer4 1 INSERM U955, 2Institute of Clinical Medicine, University of Oslo, 3Service de Psychiatrie et d'addictologie, APHP - Hopital Fernand Widal - Lariboisière, 4Pole de Psychiatrie and Inserm U955, APHP, Groupe Hospitalier Henri Mondor, 5 Institute of Clinical Medicine, University of Oslo; Division of Mental Health and Addiction, Oslo University Hospital Individual Abstract The pathophysiology of bipolar disorders (BD) is likely to be partly determined by environmental susceptibility factors that interact with genetic risk variants. Among them, childhood trauma has been proposed a relevant environmental factor for BD. However, case-controls studies are lacking and most studies focused only on physical and sexual abuse (thus neglecting emotional abuse). Furthermore, the influence of trauma on the clinical expression of the disorder remains to be clarified in terms of severity of the course, psychopathological dimensions and interaction with genetic moderators. To investigate these issues, we used a four steps approach. First, we have assessed 206 patients with BD and 94 controls with the Childhood Trauma Questionnaire to perform a case/control study. Second, 587 patients with BD were consecutively recruited from France and Norway, assessed using the Childhood Trauma Questionnaire, and characterized for various clinical features. Third, we studied the interaction between childhood trauma and serotonin transporter gene on the age at onset of BD in 308 patients. Finally, we used the Affective Lability Scale and the Affect Intensity Measure to correlate childhood trauma and adulthood affective instability. Multiple trauma were frequent in patients as compared to controls (63% versus 33%) and among trauma subtypes only emotional abuse was associated with BD with a suggestive dose-effect. We then found that emotional and sexual abuses were associated with a more severe expression of the disorder, as characterized by an earlier age at onset, increased suicide attempts, more rapid cycling and greater proneness to depression. Emotional and sexual abuses were the strongest predictors of increased suicide attempts (OR=1.60[1.07-2.39] and OR=1.80[1.14-2.86] respectively), whilst sexual abuse was the strongest predictor for rapid cycling (OR=1.92[1.14-3.24]). We then used Cox regression analysis to model the effects of emotional trauma and 5HTTLPR (serotonin transporter-linked polymorphism) genotypes on time to onset of BD. This model showed that there was a significant difference in the probability of developing BD between the patients with no emotional neglect and ll/ls genotype and those with emotional neglect and ss genotype (p=0.003). Finally, we demonstrated that the higher the exposure to trauma was, the higher the level of affective instability as measured using the Affective Lability Scale and the Affect Intensity Measure. Our results demonstrate the importance of childhood trauma, not only as a risk factor for bipolar disorders per se, but also for a more severe clinical and dimensional profile of expression of the disorder. We also demonstrated for the first time that an effect of childhood trauma on AAO of BD was observed only in patients who carry a specific stress responsiveness-related 5HTTLPR genotype. ADDITIVE ASSOCIATION BETWEEN CHILDHOOD TRAUMA AND BDNF VAL66MET ON VOLUME OF HIPPOCAMPAL SUBFIELDS- EXPLORING THE ROLE OF BDNF RNA Monica Aas1, Unn K Haukvik 2, Srdjan Djurovic3, Martin S. Tesli4, Lavinia Athanasiu5, Thomas Bjella5, Annamaria Cattaeno6, Ole A. Andreassen7, Ingrid Agartz2, Ingrid Melle4 1 NORMENT, KG Jebsen Centre for Psychosis Research, Division of Mental Health and Addiction, Oslo University Hospital and Institute of Clinical Medicine, University of Oslo, 2NORMENT, Institute of Clinical Medicine, University of Oslo, Norway; Department of Psychiatric Research, Diakonhjemmet Hospital, Oslo, Norway, 3NORMENT, Institute of Clinical Medicine, University of Oslo, Norway; Department of Medical Genetics, Oslo University Hospital, Oslo, Norway, 4NORMENT, Institute of Clinical Medicine, University of Oslo, Norway; NORMENT, Psychosis Research Unit, Division of Mental Health and Addiction, Oslo, 5NORMENT, Psychosis Research Unit, Division of Mental Health and Addiction, Oslo, 6Institute of Psychiatry, Kings College London, UK; University of Milan, Italy, 7 NORMENT, Institute of Clinical Medicine, University of Oslo, Norway; NORMENT, Psychosis Research Unit, Division of Mental Health and Addiction, Oslo University Hospital, Oslo, Norway Individual Abstract Objective: Both childhood trauma and BDNF val66met have been linked to changes in volume of the hippocampus. Here we investigated additive effects of BDNF val66met-met and childhood trauma and volume of hippocampal subfields in patients with psychoses. The role of BDNF RNA on this the association was also investigated. Method: 323 patients with a broad DSM-IV schizophrenia spectrum disorder or bipolar disorder (mean±age: 30.40±10.76; gender: 54% males; diagnosis: 56% schizophrenia spectrum were consecutively recruited to the NORMENT, TOP research study. History of childhood trauma was obtained using the Childhood Trauma Questionnaire. BDNF RNA was analyzed using standardized procedures. A subsample of n=99, all Caucasians with a broad DSM-IV schizophrenia spectrum disorder and bipolar disorder (mean±age: 32.10±11.46; gender: 49% males; diagnosis: 49% schizophrenia spectrum) had data on sMRI. 1.5 T T1-weighted MRI scans were acquired, and the FreeSurfer software (v 5.2.0) was used to automatically obtain measures of interest (hippocampal subfields). All sMRI data were corrected for age and gender. BDNF val66met was genotyped using standardized procedures. Correction of multiple testing was performed. Results: Reports of childhood trauma, as well as being a carrier of the met variant of the BDNF val66met was independently, as well as additively, significantly associated with reduced BDNF RNA levels. Moreover, BDNF val66met- met carriers reporting high levels of childhood trauma demonstrated reduced volume of the hippocampal subfields CA1, CA2-3 and CA4 DG, which was most prominent in females. Lastly, BDNF RNA levels were positively associated with hippocampal volume; however statistical predictor values were low, and only significant in females. Conclusion: Reduced BDNF RNA levels as a result of both childhood trauma and genetic factors may be part of the complex pathophysiological mechanisms behind reduced hippocampal subfields in severe mental disorders. This should be investigated further in larger independent samples. NEURO-PSYCHIATRIC GENETIC RESEARCH IN LATIN AMERICA Chair: Carlos Lopez, University of Antioquia Overall Abstract Details Endophenotypes in bipolar disorder type I, in a genetically isolated population There are still doubts about the genetic bases of BDI; one of the ways that can guide the genetic studies is the distinction between clinical heritable phenotype characteristics and those that are associated with a disease, as in this way it is possible to propose possible endophenotypes and guide further genetic studies. This presentation intends to show the results of a study (Fears SC, Service SK, Kremeyer B, et al. Multisystem Component Phenotypes of Bipolar Disorder for Genetic Investigations of Extended Pedigrees. JAMA Psychiatry. 2014;():. doi:10.1001/jamapsychiatry.2013.4100.) made in collaboration by our group (Psychiatry Investigation group, University of Antioquia), UCLA and Costa Rica university done in two genetically isolated populations(Medellin, Antioquia-Colombia and Central Valley of Costa Rica) with high prevalence of BDI, with 738 subjects (181 BDI patients), were assessed for neurocognitive characteristics related with temperament and neuroanatomical changes measured with neuroimages. This presentation will review the main phenotypes identified and will make a difference between those who were heritable and those that were associated with the disorder. The results that will be discussed will provide in the close future the identification of specific clusters for genetic sampling in BDI NEURO-PSYCHIATRIC GENETIC RESEARCH IN COSTA RICA Henriette Raventós1 1 Universidad de Costa Rica Individual Abstract Genetic research in Costa Rica has a long history, starting in the 70s, mostly on Mendelian inheritance disorders. For the last 25 years, we have been working on complex inheritance neuropsychiatric disorders such as schizophrenia, bipolar disorder, Alzheimer disease, migraine, and alcohol abuse, in collaboration with international partners. We have recruited over 5000 subjects, used different diagnostic instruments and assessments, conducted whole genome scans on these subjects and identified genetic variants associated to some of these disorders, some of which are now being further characterized at a functional level. In this presentation, I will review some of these findings, starting with the mapping and identification of a gene for a dominant form of deafness and moving to our studies on schizophrenia, bipolar disorders and psychosis. I will describe the population genetic structure studies, assessment of the phenotype, some of the positive genotype findings and further characterization of the polymorphisms on candidate positional genes found on schizophrenia, and functional analysis of NRG1 as an example of one of the genes studied, using bioinformatics tools, genome, transcriptome and proteome analysis, and animal models. Ongoing studies on an extended multigenerational family with psychosis will also be described. AN OVERVIEW OF PSYCHIATRIC GENETIC STUDIES IN BRAZIL Homero Vallada1 1 University of Sao Paulo Medical School Individual Abstract Brazil is one of the most heterogeneous populations in the world, formed mainly by the admixture between European, African and Native American populations, and Brazilian studies on psychiatric genetics has been observed since in the 1970's. A review of the literature, including the advantages and difficulties of psychiatric genetic studies in the Brazilian population will be presented. IMMUNOGENETIC SCREENING IN BIPOLAR PATIENTS FROM MEXICO CITY Humberto Nicolini1, Nuria Lanzagorta2, Alma Genis3, Ricardo Aguilar4, Jose Moreno5, Mirna Morales6, Humberto García6, Lorena Orozco6, Michael Escamilla7 1 National Institute of Genomic Medicine INMEGEN, 2Carracci Medical Group, 3SAP, INMEGEN, UACM, 4UACM, 5La Salle University, 6 INMEGEN, 7Center of Excellence for Neurosciences TTUHSC Paul L. Foster School of Medicine Individual Abstract Bipolar disorder (BP) has been estimated between 0.8 % to 1% by several studies (Angst et al., 2004, Simon et al., 2004, Tukel R et al., 2007). Furthermore, comorbid patients have greater suicidal attempts, substance abuse and lower lithium treatment responses. We now realize that a large number of genes, each with a small contribution, explain the heritability of most psychiatric disorders, including BP. In addition, several genes of the immune system have consistently been associated with mental disorders (MHC, TNF, IL4, IL6). Genome profiling using specific tools directed to the immune system may provide some additional inside into the common genetic pathways of patients with comorbid diagnosis. In this study, we will use a genotype array (Golden Gate Custom Array from Illumina) that covers 484 genes, which participate in the immune system, genotyping 1440 polymorphisms along with 96 ancestry makers. We will genotype 92 patients with BP disorder from Mexico City along with 250 controls from the blood bank in Mexico City with no medical disease. Statistical Analysis will be performed by the Immunogenetics department in the National Institute of Genomic Medicine (HG and LO) comparing allele frequencies between cases and controls. MULTISYSTEM PHENOTYPES IN PATIENTS WITH BIPOLAR DISORDER Carlos Lopez1 1 University of Antioquia Individual Abstract There is still doubts about the genetics of BDI. A way in which we can guide future studies (genetic ones) is the finding of special phenotypical characteristics that not only are heritable but that are associated with BDI, as this can be used to create the so called endophenotypes the ones that can guide future studies to identify precise genetic abnormalities. The goal of this presentation is to show and explain the results of a study (Fears SC, Service SK, Kremeyer B, et al. Multisystem Component Phenotypes of Bipolar Disorder for Genetic Investigations of Extended Pedigrees. JAMA Psychiatry.2014;71(4):375-387. doi:10.1001/jamapsychiatry.2013.4100.) that analyzed two genetically secluded subject populations (Costa Rica central Valley and Antioquia-Colombia), with 738 subjects (151 BDI), in which neurocognitive characteristics related to temperament, and neuroanatomical changes measured with MRI were assessed. I will present the main findings, and will make emphasis between the ones that were only heritable and those that were heritable and associated with BDI. These results will allow us to guide further studies for early diagnosis on certain populations with high risk. GENETICS AND AGGRESSION: THE AGGRESSOTYPE PROJECT Chair: Bru Cormand, University of Barcelona Overall Abstract Details Aggression is a basic physiological trait with important roles throughout evolution, both in defense and predation. However, when expressed in humans in the wrong context, aggression leads to maladjustment, social impairment and crime. Despite this, knowledge about aggression aetiology is limited and current treatment strategies are insufficient. The aim of the "Aggressotype" project, recently funded as part of the EU FP7 Program, is to investigate the biological basis of both the reactive (emotional, impulsive) aggression and the proactive (instrumental, predator) presentations of aggression, working in human subjects and in animal models. This involves different levels of scrutiny, including genetics, brain imaging, epigenetics, work on neuron cell lines derived from stem cells or cognitive and behavioral assessments. But most important, we are committed to translate our preclinical findings into predictive, preventive and eventually therapeutic strategies, e.g. by using animal (mice, zebrafish) and cellular models to identify novel leads for treatment. The Symposia speakers are members of the Aggressotype consortium, and their presentations will focus on different aspects of this collaborative effort. Barbara Franke will provide an overview of the aims of the project, with emphasis on characterizing the differences and communalities of reactive impulsive and low emotional, instrumental subtypes of aggression. The possible role of specific genes, such as NOS1 and MAOA, in brain structure and function will be discussed. William Norton will present the zebrafish as a model organism for studying the aetiology of aggression. Aggression can be reliably measured by recording stereotypic agonistic postures elicited when the animal is shown its own mirror image. A mediumthroughput screening of more than one hundred compounds will be performed by administering the drugs by immersion in the tank water, and their effects on fish behavior will be examined. Promising drugs will be validated in mouse aggression paradigms. Jeffrey Glennon will present work on mouse models of aggression, including the TPH2 -/- knockout and the BALB/Cj inbred strain. The resident intruder task, a well-established aggression paradigm, will be used. The aim is to identify neural markers and also epigenetic moderators of impulsive aggressive behavior, which have remained elusive so far. State-ofthe- art MRI acquisition and analysis methods and microRNA sequencing will be applied. Finally, Tetyana Zayats will focus on parent of origin effects (POE), an expression of genomic imprinting that is a source of genetic complexity in common neuropsychiatric conditions. Application of multinomial modelling may serve to better understand POE -and to establish a distinction from maternal effects- and will be used to examine over 3,000 trios with ADHD-affected offspring, where aggression can be a particular problem. AGGRESSION IN ADHD AND CONDUCT DISORDER: IMPULSIVE AND INSTRUMENTAL SUBTYPES Barbara Franke1 1 Departments of Human Genetics and Psychiatry, Donder’s Institute for Brain, Cognition and Behaviour, Radboud University Medical Center Individual Abstract Aggression, overt and covert behavior with the intention of inflicting physical and psychological damage, is a physiological trait with important roles throughout evolution, both in defense and predation. When expressed in humans in the wrong context, however, aggression leads to social maladjustment and crime. Maladaptive aggression is commonly observed across childhood disruptive behavioral disorders, in particular in attention-deficit/hyperactivity disorder (ADHD) and conduct disorder (CD). The aetiology and mechanisms underlying juvenile aggression are still largely elusive. Clearly, genetic factors in interaction with the environment are at play, but how those change cell function, neural organization and brain function leading to aggressive behavioral outcomes needs to be investigated before more effective treatment strategies can be developed. As part of the EU FP7 Program, the international consortium Aggressotype was funded in 2013 to study the mechanisms underlying pathological aggression. With its 21 partners, the consortium focuses on characterizing the differences and communalities of labile, reactive impulsive and low emotional, instrumental subtypes of aggression in ADHD and CD as a route towards facilitating and improving treatment. The neural substrates of impulsive and instrumental aggression have been suggested to involve different parts of the prefrontal cortex and several limbic structures like the striatum and the amygdala. In impulsive aggression the activation of the amygdala seems to be increased, whereas in instrumental aggression the activity of the reward system including the striatum is larger than expected. In this presentation, we present work showing the role of aggression genes in regulating brain structure and activity. We show that NOS1 increases striatal activity during reward anticipation and present data on the role of MAOA in the connectivity between the amygdala and prefrontal cortex. Data from Aggressotype partners suggest that both genes are related to impulsive rather than instrumental aggression. SCREENING FOR NOVEL AGGRESSION THERAPEUTICS IN ZEBRAFISH William Norton1, Lauren Jones1 1 University of Leicester Individual Abstract Aggression is common side effect of psychiatric disorders including attentiondeficit/hyperactivity disorder (ADHD) and conduct disorder. However, our knowledge about aggression aetiology is limited and current treatment strategies are insufficient. The zebrafish is an ideal model organism to address this issue by developing high-throughput drug screens. Aggression can be reliably measured by recording the stereotypic agonistic postures elicited when a fish is shown its own mirror image. Fish display aggression from around one month of age onwards allowing large numbers of animals to be generated in a relatively short time period. Aggression appears to be controlled by similar genes and neurotransmitters in zebrafish and other vertebrates allowing the translation of data to other species. Finally, drugs can be administered by immersion (dissolving the drug in the tank water) thus speeding up application. As part of the Aggressotype project we are undertaking a medium-throughput screen to identify novel drugs that can modulate aggression levels. We will start by investigating the ability of existing aggression therapeutics (methylphenidate, risperidone, valproate and lithium) to reduce aggression levels in fish. We will then choose novel drugs with similar chemical properties and examine their behavioural function. Our screen will screen a minimum of one hundred novel drugs in the first year, and will test further compounds time permitting. Promising drugs will be validated in mouse aggression paradigms, in order to demonstrate a conserved behavioral function across species. This approach represents an excellent opportunity to identify novel aggression therapeutics, with the global aim of improving treatments options for patients suffering from psychiatric disorders. STRUCTURAL AND FUNCTIONAL MRI CHANGES IN ANIMAL MODELS OF AGGRESSION ARE ASSOCIATED WITH ALTERATIONS IN FRONTOSTRIATAL MICRORNA EXPRESSION Jeffrey Glennon1, Amanda Jager1, Houshang Amiri1, Armaz Aschrafi2, Arend Heerschap1, Jan Buitelaar1 1 Radboud University Medical Center, 2Radboud University Individual Abstract The neural correlates of impulsive aggressive behavior and their epigenetic moderators have to date remained elusive. Mechanisms such as the neuron specific tyrosine hydroxylase TPH2 isoform and its yin haplotype have been implicated in the inefficient functional engagement of cortical areas involved in impulsive control and alterations in the mode of functional connectivity of dorsal anterior cingulate cortex pathways (Kennedy et al. 2012). Equally, inbred mouse strains such as the BALB/Cj mouse which display aggressive behavior and reduced sociability have been suggested to express 20% less TPH2 mRNA and possess 28% fewer TPH2 immunolabeled neurons particularly in the raphe nuclei and cerebral cortex than control C57Bl/6J mice (Bach et al. 2011). Taken together, this suggests altered serotonergic transmission may play an important role in impulsive aggression. Our current work applies state-of-the-art MRI acquisition and analysis methods that enable serial assessment of whole-brain structural and functional neuronal networks; beginning with the TPH2 -/- and BALB/Cj mouse models following sub-chronic exposure to the resident intruder task (a well-established aggression paradigm). Current MR data acquisition of diffusion tensor imaging (DTI) and diffusional kurtosis imaging (DKI) as well as resting state functional MRI (rs-fMRI) is ongoing to establish neural markers of impulsive aggression in frontostriatal circuits in both BALB/Cj and TPH2 -/- mice. Others have demonstrated significant positive regression (p?<?0.001) between social behavior in the BALB/Cj mouse and fractional anisotropy in the thalamic nuclei, zona incerta/substantia nigra, visual/orbital/somatosensory cortices and entorhinal cortex (Kim et al., 2011). Furthermore, the same group reported a significant negative regression (p?<?0.001) between social behavior and mean diffusivity in the sensory cortex, motor cortex, external capsule and amygdala. Whether aggressive behavior in the resident intruder task is correlated with the same regions is under investigation. MicroRNA sequencing of the same frontostriatal pathways which may underlie aggressive behavioral changes in both models is underway. Preliminary evidence suggests that alterations in microRNAs are correlated with alterations in frontostriatal connectivity. Whether alteration of the expression of these microRNAs using RNAi technology results in functional changes in resident intruder task performance is a topic of active research and will be discussed. EPIGENETICS IN MENTAL DISORDERS: MATERNAL AND PARENT OF ORIGIN EFFECTS Tetyana Zayats1, Tor-Arne Hegvik1, Johansson Stefan1, Haavik Jan1 1 University of Bergen Individual Abstract Epigenetics is an increasingly expanding field, examining alterations in gene expression caused by mechanisms other than changes in DNA sequence. One of important derivations of such epigenetic influences are parent of origin effects (POE), that are a recognized source of genetic ramification in a number of common complex disorders, including those of neurodevelopmental origin. There is strong evidence for POE in rare genetic syndromes, such as Prader-Willi and Angelman syndromes, where imprinting is known to occur. However, POE has also been noted in bipolar disorder, schizophrenia, autism, Alzheimer’s and attention deficit hyperactivity disorder (ADHD). Several of these neuropsychiatric conditions share an element of dysregulated mood and maladaptive aggression. Aggression can be a particular problem in ADHD that often coexists with conduct disorder. The fundament behind POE - genomic imprinting - has generally been examined by? 2 interrogation of paternal versus maternal transmissions to an affected offspring. However, such approach has been shown to be insufficient in certain combinations of parental genotypes as well as in detection of maternal effects (impact of a genetic locus expressed by mothers, but not their offspring), often confound with POE. Application of multinomial modeling serves further understanding of POE and aids its distinction from maternal effects that refer to entirely different patterns of gene expression than POE. We will discuss multinomial modeling of POE and its application to examination of POE in over 3,000 trios with ADHD- affected offspring. TOWARDS TRANSLATIONAL PSYCHIATRY: FROM GENOMIC DISCOVERIES TO PREDICTION OF TREATMENT RESPONSE Chair: Po-Hsiu Kuo, Institute of Epidemiology and Preventive Medicine, NTU Overall Abstract Details The process of translational sciences involves many steps. One of the major early steps is to foster discovery, including basic research and proof-of-principle human studies, and then to pave the way from new discoveries to clinical applications. In the field of psychiatry, the progress of translational research has been limited so far, hindered by lacking in reproducibly findings of biomarkers to point a way for improving the accuracy of diagnosis and providing new therapeutic targets. With the joint efforts from several large consortia in a variety of psychiatric disorders in the past few years, few common genetic variants are reliably identified for major psychiatric disorders. However, the effect size of these genetic variants is small, and phenotypic variation explained by these findings is not substantial. The search for the causes of complex traits, historically has mainly focused on coding genes that are mutated or genetically altered. Due to recent progress in advanced technologies and detailed characterization of functional genomic elements, there is a paradigm shift to study transcriptome, which is in response to both the inheriting genetic sequence and environmental stimuli, as well as to study the regulation mechanisms for the gene expression levels that are associated with disease status. Additionally, adoption of novel statistical methods to utilize genomic findings for accurate prediction of treatment response is desired, which can bridge the gap between knowledge discovery phase and clinically application phase. This symposium attempts to address a series of topics in relation to different stages of translational psychiatry, covering a wide range of areas of medical research in humans as well as using mouse models, including molecular biology, gene expression, epigenetics (in particular microRNAs mechanism), imaging, and prediction model. More specifically, microRNAs expression and regulation are studied for psychotic symptoms and schizophrenia. Knock-in and knock-down experiments are conducted in mouse hippocampus to explore molecular mechanism underlying the therapeutic effects of electroconvulsive therapy for psychoses. Specific microRNAs expressions are found to correlate with gray matters structures in schizophrenia. In addition, expression levels of genes and transcripts, and microRNAs are examined for the acute and remission status of schizophrenia and bipolar disorder. Finally, artificial neural network model is applied to identify predictors of antidepressant treatment response in patients with major depressive disorder. INVERSELY REGULATED MICRORNAS IN MOUSE HIPPOCAMPUS AFTER METHAMPHETAMINE AND ELECTROCONVULSIVE SHOCK Yu-Lin Chao1, Chia-Hsiang Chen2, Hwei-Hsien Chen3 1 Tzu Chi General Hospital, 2Department of Psychiatry, Chang-gung Memorial Hospital, 3Center for Neuropsychiatric Research, National Health Research Institutes, Taiwan Individual Abstract Micro-RNAs (miRNAs) are small regulatory RNAs that individually regulate hundreds of genes. Recent evidence supports a role for miRNA dysregulation in psychiatric disorders, including schizophrenia, bipolar disorder and autism. MiRNAs may also mediate some of the effects of psychiatric drug therapies. Methamphetamine (MAP) is a psychotomimetic drug, which can induce abnormal behaviors in mice. On the other hand, to treat major psychoses, electroconvulsive therapy (ECT) has been proved to be a highly effective and safe treatment option. However, the underlying mechanism of ECT action remains largely unknown, and there is no research directly addressing the molecular mechanisms of miRNAs with the adverse behavioral effects causing by MAP and the therapeutic effects of ECT. We hypothesize that there are specific miRNAs in brain mediating the changes of behaviors and brain functions after chronic MAP administration and/or repeated electroconvulsive shock (ECS). The main goal of this study was to uncover the miRNA-mediated molecular mechanisms underlying psychotic symptoms. The differentially expressed miRNAs in the hippocampus of mice pre-treated with MAP and/or ECS were identified via the genome-wide mature miRNA PCR array quantification. Our results showed that miR-138, miR-328, miR-339-5p and miR-652 were up-regulated by chronic use of MAP and down-regulated after ECS, while the changes of direction of miR-126-5p and miR-203 were the opposite. These six miRNAs in mouse hippocampus were significantly correlated with the changes of animal behaviors, such as prepulse inhibition during ECS interventions. Using in silico prediction for the target genes of the six differentially expressed miRNAs and pathway analysis, we found several significantly enriched biological pathways that involve with neuronal synapse and axonal guidance. Moreover, we applied the lenti-viral expression vectors to perform the transduction in the mouse hippocampus. Preliminary results demonstrated that overexpression of miR-328 in bilateral hippocampi of mouse could further impair the deficit of prepulse inhibition and behavioral sensitization caused by pre-treated MAP. On the contrary, knocking-down of miR-328 could partially rescue the PPI deficit and decrease the behavioral sensitization. We also identified that both?secretase coding gene BACE1 and post-density 95 protein coding gene DLG4 were targets of miR-328. They were reported to be associated with the regulation of expression of AMPA receptors in postsynaptic neurons. Further studies addressing on the underlying molecular mechanisms of behavioral effects and neuronal function mediated by miR-328 are on-going. Elucidation of the roles of miRNA in the therapeutic mechanism of ECT would bring new insights into the pathogenesis of psychotic disorders, and shed some light on the development of new therapeutic agents. BLOOD-BASED MICRORNA EXPRESSION ABERRATION IN SCHIZOPHRENIA: TREND FROM ACUTE ADMISSION TO PARTIAL REMISSION AND RELATIONS TO CORTICAL GRAY MATTERS STRUCTURES Wei J. Chen1, Chi-Yu Lai2, Su-Yin Lee3, Chun-Chieh Fan4, Ya-Hui Yu5, Chih-Min Liu6, Wen-Yih Tseng7, Hai-Gwo Hwu6 1 College of Public Health, National Taiwan University, 2Institute of Epidemiology and Preventive Medicine, National Taiwan University,; Molecular Psychiatry Laboratory, Florey Institute of Neuroscience and Mental Health, Parkville, 3Institute of Epidemiology and Preventive Medicine, National Taiwan University, 4University of California, San Diego, 5Genetic Epidemiology Core, Center for Genomic Medicine, National Taiwan University, 6College of Medicine and National Taiwan University Hospital, National Taiwan University; and Graduate Institute of Brain and Mind Sciences, College of Medicine, National Taiwan University, 7Center for Optoelectronic Medicine, College of Medicine, National Taiwan University; and Graduate Institute of Brain and Mind Sciences, College of Medicine, National Taiwan University Individual Abstract Background: Previously we have identified a seven-miRNA signature (hsamiR-34a, miR-449a, miR-564, miR-432, miR-548d, miR-572 and miR-652) that could discriminate patients with schizophrenia from healthy controls. This study aimed to investigate whether the expression levels of the seven miRNAs: (1) changed from acute admission to partial remission in inpatients with schizophrenia; and (2) were associated with gray matter volume, thickness, surface area, as well as subcortical volume in schizophrenia patients. Methods: Two independent samples were recruited for this study. For aim 1, a total of 48 patients with schizophrenia were recruited and their peripheral blood mononuclear cells (PBMC) were collected both at acute admission and at discharge with partial remission at least two months later. Age- and gender-matched healthy controls (n = 37) were recruited from university staff and students and similar blood sample collections were performed at two time points with two months apart. For aim 2, 35 patients with schizophrenia and 12 healthy controls were recruited. Quantitative real-time PCR was used to quantify the expression level of each miRNAs. T1 weighted images were obtained through 3T magnetic resonance imaging, while imaging processing was done via Freesurfer. The Pearson correlation coefficient (with Benjamini and Hochberg false discovery rate correction at 0.1 level) of each miRNA and gray matter structure in each brain region were calculated for cases and controls, respectively, as well as the pooled sample of both groups. Results: There were no significant changes in the peripheral blood levels of the seven miRNAs from baseline to 2-month followup for both schizophrenia inpatients and healthy controls, except miR-548d in healthy controls. Four miRNAs (miR-34a, miR-449a, miR-548d and miR-572) out of the original 7-miRNA signature were replicated in showing up-regulation in schizophrenia inpatients in comparison with healthy controls. On the relationship between cortical gray matter structures, hsa-miR-449a showed moderate positive association with the volume of right posterior cingulate cortex in cases. Hsa-miR-572 and hsa-miR-652 showed moderate negative association with the thickness of left caudal middle frontal gyrus and left cuneus cortex. Whereas in healthy controls, only hsa-miR-34a was negatively associated with left parahimppocamal gyrus and right pars orbitalis in volume/surface area structures. The reduction of most regions of thickness structures as well as PBMC-miRNA expressions were correlated with increasing duration of illness in schizophrenia patients. Conclusions: These findings indicate that the aberrant expressions of the seven miRNAs in PBMC of patients with schizophrenia persist from acute admission to partial remission, and the miRNA expression alteration in PBMC may be related to the cortical structural changes that occur with disease progression in patients with schizophrenia. IDENTIFICATION OF NOVEL BIOMARKERS FOR MANIC EPISODE USING WHOLEGENOME TRANSCRIPTOME ANALYSIS Ya-Chin Lee1, Ming-Chyi Huang3, Chung-Feng Kao2, Hsi-Chung Chen4, Po-Hsiu Kuo2 1 Institute of Epidemiology and Preventive Medicine, College of Public Health, National Taiwan University, 2Institute of Epidemiology and Preventive Medicine, College of Public Health, National Taiwan University, 3Taipei City Psychiatric Center, Taipei City Hospital, 4Department of Psychiatry & Center of Sleep Disorders, National Taiwan University Hospital Individual Abstract More than three-thirds of patients with bipolar disorder (BPD) have recurrent episodes throughout lifetime, which demonstrating a chronic course with poor prognosis. To explore the underlying biological mechanisms of bipolar disorder, investigation of the genomic influences for its episodic features is critical. RNA transcriptome is influenced by both the inheriting genetic sequence and environmental stimuli, and it has been found that many non-coding RNAs play important roles in the regulation of human genes and transcripts. We aim to study the change of transcriptome in response to mania episodic status (acute vs. remission) at the genome-wide level to identify potential biomarkers for BPD. A discovery sample consists of six BPD patients who have repeatedly measures in symptom severity and RNA transcriptome at acute manic episode (Young Mania Rating Scale, YMRS score> 20) and remission at two-month time (YMRS score< 12). We used Affymetrix Human Gene 2.0 ST array to obtain transcriptome expressions at each time point. This array includes more than 1.35 million probes to discover about 30,000 transcripts and 11,000 long intergenic non-coding transcripts. We perform quality control processes, quantile normalization and Lowess normalization on expression data, and build volcano plot to select candidate genes and transcripts. Potentially differentially expressed genes/transcripts are validated by quantitative real-time PCR and replicated in an independent set of BPD patients. We apply hierarchical clustering method to show the patterns of gene expressions in corresponding to episodic status. Pathway analysis is performed to construct pathway cross-talk for differentially expressed candidates. Currently, data analysis is still ongoing, and results in this study are anticipated to shedding light on our understanding about the possible mechanisms underlying episodic feature of bipolar disorder and providing novel targets for future therapeutic research. A NEURAL NETWORK MODEL FOR PREDICTING TREATMENT RESPONSE OF ANTIDEPRESSANTS IN PATIENTS WITH MAJOR DEPRESSIVE DISORDER Po-See Chen1 1 National Cheng Kung University Medical College Individual Abstract Background: Predicting the treatment response of antidepressants by pre-treatment features would be of great usefulness for clinical practice since up to 50% of the patients with major depressive disorder (MDD) do not have response as expected. Here, we demonstrated artificial neural network (ANN) and linear regression models to identify predictors of antidepressant treatment response in patients with MDD. Methods: The sample consisted of a reanalysis of 149 MDD outpatients. The use of back-propagation network (BPN) of ANN was investigated. Randomly, 80% of the subjects were used to train the ANN model, 20% of whom were used to validate the algorism model. In the structure of the ANN, inputs contain the information about genetic factors (GNB3 rs5443, BDNF rs6265, 2C19*3 rs4986893, and C2677A rs2032582), biomarker (hs-CRP), and environmental factors (social support scales: available number of social support in crisis status, and perceived number of social supports in routine status), and output contains the information of the percentage reduction in 21-item Hamilton Rating Scale for Depression (HAM-D) scores at week 2. Results: The regression for treatment response in the training and testing groups were 0.94 and 0.86, respectively. From the sensitivity analysis, BDNF rs6265, hs-CRP, and available social support in crisis status were three influences on antidepressant treatment response in chief. However, none of these factors were significantly correlated with treatment response by linear regression. Conclusions: The complex interactions modeled through ANN may be more useful to investigate this complexity than linear regression techniques at the clinical level for predicting individualized response of antidepressants. In addition, further clinical studies will be needed to validate the accuracy of prediction. Thursday, October 16, 2014 8:30 AM - 10:30 AM Concurrent Symposia Sessions EXPLORING THE EVIDENCE THAT POSTPARTUM DEPRESSION IS A MORE HOMOGENEOUS BIOLOGICAL SUBTYPE OF MAJOR DEPRESSION (MDD) Chair: Naomi Wray, The University Of Queensland Overall Abstract Details One of the most vexing questions in psychiatric genetics is elucidating the pathogenesis and genetic architecture of major depression (MDD). In contrast to schizophrenia and bipolar disorder, efforts to identify the genetic basis of MDD have been complicated by etiological heterogeneity. A focus on genetic studies of postpartum depression (PPD), a potentially more homogenous MDD subtype involving exposure to a similar biopsychosocial stressor, may offer significant advantages. PPD is common, affecting at least 1 in 8 women, and is associated with serious adverse consequences for the mother, child and family. This symposium will evaluate the validity of focusing on PPD as a genetically more homogenous MDD subtype by discussing novel research approaches being applied to this type of investigation. It will also discuss how the genetic findings in PPD can provide valuable insight for future genetic and biomarker studies of MDD. Speaker 1, Alexander Viktorin will describe new evidence from the Swedish Twin Study and Swedish National Patient Registers to analyze the heritability of PPD as compared to MDD outside of the perinatal period. The heritability of PPD was first estimated in 2321 parous twins using the classical twin-model, and then was followed by an extended multivariate sibling design including over 1 million parous female siblings: PPD is more heritable than MDD. Speaker 2, Samantha Meltzer-Brody will discuss the application of latent class analysis (LCA) to assess the empirical validity of heterogeneity and subtypes of PPD using data aggregated from a large-scale international perinatal psychiatry consortium (PACT, Postpartum Depression: Action Towards Causes & Treatment). Using phenotypic data, a 3 class solution yielded the best fit and the most striking characteristics were severity, timing of onset, comorbid anxiety, and suicidal ideation in women with PPD. The importance of precise phenotypes as a critical first step toward future large-scale biological and genetic investigations of PPD will be explored. Speaker 3, Naomi Wray will describe the use of risk profile scores (RPS), as the best measure of genetic liability as applied to MDD GWAS datasets with well phenotyped cases of PPD. Using results for MDD and bipolar disorder from the Psychiatric Genomics Consortium, RPS were created for all individuals and results suggest that focusing on PPD as a more homogeneous subset of MDD may be an effective strategy for genetic studies. Finally, the search for a prospective biomarker that predicts PPD will be discussed as well as the clinical/translational application and impact of this type of finding. Speaker 4, Divya Mehta will discuss a study of the predictive value of gene expression profiles from peripheral blood samples collected from women in the third trimester of pregnancy to uncover robust and reproducible biomarkers for PPD. Trine Munk-Olsen will moderate and Patrick Sullivan will serve as discussant for the symposium. HERITABILITY OF PERINATAL DEPRESSION AND GENETIC OVERLAP WITH MAJOR DEPRESSIVE DISORDER Alexander Viktorin1, Samantha Meltzer-Brody2, Ralf Kuja-Halkola3, Mikael Landen3, Paul Lichtenstein3, Patrik Magnusson3 1 Karolinska Institutet, 2Department of Psychiatry University of North Carolina School of Medicine, 3 Department of Medical Epidemiology and Biostatistics, Karolinska Institutet Individual Abstract Perinatal depression (PND) is defined as a major depressive episode that takes place either during pregnancy or within the first 6 months postpartum. Estimated prevalence is in the order of 10-15% and the disorder can have devastating effects both for the mother and the child. Although some research has challenged the view that PND is a separate clinical diagnosis from major depressive disorder (MDD), there may be a distinct biological basis to PND that may be due to any of the major changes in hormonal levels associated with pregnancy and parturition. In the current study, heritability of PND was first estimated in 2321 parous twin women utilizing the classical twin-model, where PND was defined using a lifetime version of the 10-item Edinburgh Postnatal Depression Scale. The narrow sense heritability of PND was estimated to be 54% (95% CI, 35-70%), with the remaining variance attributable to unique environment. This was followed by an extended multivariate sibling design including over 1 million parous female siblings. Here, hospital discharge diagnoses in the Swedish National Patient Register were used to define depression, and the timing of the start of the depression (defined as a) within pregnancy or 6 months postpartum, or b) any other time) was used to separate the two disorders. The heritability of PND was estimated to be 49% (95% CI, 39-60%), with the remaining variance attributable to unique environment. The heritability of MDD was estimated to 28% (95% CI, 1838%), with the remaining variance attributable to shared environment (7%; 95% CI 2-11%) and unique environment (65%; 95% CI, 59-71%). Further, bivariate analysis revealed that the variance in PND was explained by 14% common genetic factors with MDD and 27% unique genetic factors for PND, lending evidence to a partially different genetic etiology of PND and MDD. APPLICATION OF LATENT CLASS ANALYSIS TO UNDERSTAND THE HETEROGENEITY OF POSTPARTUM DEPRESSION IN AN INTERNATIONAL PERINATAL PSYCHIATRY CONSORTIUM Samantha Meltzer-Brody1, the PACT Consortium, 1 University of North Carolina at Chapel Hill Individual Abstract Background/Objective: Postpartum Depression (PPD) confers substantial morbidity and mortality but the definition of PPD is a matter of some controversy. PPD is categorized as a subtype of major depression (MDD) in DSM-5, and, as such, a diagnosis of PPD requires that DSM criteria are fulfilled during the specified perinatal period. Additionally, the phenotypic presentation of PPD may have distinguishing characteristics compared to an episode of MDD occurring outside of the perinatal period. Therefore, this study is an empirical investigation of PPD heterogeneity to identify clinical subtypes. Data were aggregated from the international perinatal psychiatry consortium, PACT (Postpartum Depression: Action Towards Causes and Treatment). PACT members are from 24 institutions in 7 countries, and had 27,776 subject records submitted with phenotypic data. Methods: We applied latent class analyses (LCA) in a 2-tiered approach to assess the empirical validity of heterogeneity and subtypes of PPD. Tier 1 examined PPD heterogeneity in subjects with complete data on the Edinburgh Postnatal Depression Scale (EPDS) (N=6556), including PPD cases and controls. Tier 2 subjects included only PPD cases (N=4245). In the Tier 2 analyses, indicator variables were hypothesized based on distinguishing clinical features of PPD having commonality among sites. These indicator variables included depression severity, EPDS total, EPDS anxiety subscale, timing of onset, pregnancy complications, obstetric complications, suicidality, and psychiatric history/comorbidity of anxiety and depression. Results: A 3 class solution yielded the best fit in both Tier 1 and Tier 2. In both Tiers, the most striking characteristics were severity, timing of onset, comorbid anxiety, and suicidal ideation. The class with the most severe PPD symptoms had significantly worse mood (mean EPDS=20.3), greater anxiety, symptom onset that began during pregnancy, more obstetrical complications and endorsed suicidal ideation. The other PPD class (mean EPDS=12.3) had less severe symptoms; the majority (54%) endorsed symptom onset in the first month postpartum and had more pregnancy complications. Conclusion: PACT represents an important next step toward large scale collaborative research efforts needed to disentangle the pathophysiology of PPD. Examination of PPD heterogeneity to identify more precise phenotypes is a critical first step toward future biological and genetic investigations. EVIDENCE FOR A GENETIC OVERLAP BETWEEN POSTPARTUM DEPRESSION AND BIPOLAR DISORDER Naomi Wray1, Enda Byrne1, Tania Carrillo-Roa2, Samantha Meltzer-Brody3, Brenda Penninx4, Hannah Sallis5, Alexander Viktorin6, Psychiatric Genomic Consortium Major Depressive Disorder, Patrick Sullivan4, Paul Lichtenstein6, Patrik Magnusson8, David Evans3, Grant Montgomery3, Dorret Boomsma7, Nicholas Martin3 1 The University Of Queensland, 2Queensland Institute of Medical Research, 3University of North Carolina at Chapel Hill, 4VU University Medical Center, 5School of Social and Community Medicine, University of Bristol, 6Karolinska Institute, 7Vrije Universiteit Individual Abstract The etiology of major depressive disorder (MDD) is likely to be heterogeneous and researchers are faced with the dilemma of balancing power through increased sample size or sacrificing sample size to achieve greater homogeneity of the case sample. Which strategy is optimal depends on the underlying genetic architecture, which is unknown. Here, using currently available GWAS data for MDD, we explore the validity of focusing on postpartum depression (PPD) as a genetically more homogeneous MDD subtype. We used MDD GWAS data sets from Australia (1450 MDD cases, 1703 controls) and the Netherlands (1699 cases, 1765 controls). From these we identified PPD cases (484 Australian cases and 208 Dutch cases). We used SNP association results from the Psychiatric Genomics Consortia (PGC) of Bipolar Disorder (BPD) and MDD to create polygenic scores for all individuals. The R2 from a logistic regression of PPD case-control status on a SNP profile score weighted by PGC-BPD association results was highly significant for both Australian and Dutch cohorts (R2 > 1.1%, p < 0.008). Interestingly, the BPD profile score explained less variance in the much larger samples of MDD cases and controls (R2 =0.06%, p= 0.08) in both data sets. Our results provide empirical genetic evidence for a more important shared genetic etiology between BPD and PPD than between BPD and MDD. Further, they suggest that focusing on PPD as a defined and more homogeneous subset of MDD may be a fruitful strategy for genetic studies. THE SEARCH FOR ROBUST AND REPRODUCIBLE BIOMARKERS FOR POSTPARTUM DEPRESSION: NEW INSIGHTS AND STRATEGIES Divya Mehta1 1 University of Queensland Individual Abstract Postpartum depression (PPD) is a significant public health problem with approximately 13% incidence affecting not only women and their partners but has widespread cascading consequences on the infant, family and friends and subsequently on the community (Meltzer-Brody & Stuebe 2014). Despite harmful outcomes of PPD such as maternal suicide and infanticide, up to 80% of PPD cases remain undetected (Yonkers 2003). Given the potentially serious consequences of PPD on maternal and infant health and wellbeing, identification of reliable biological tests for early detection is imperative. In a recent study (Mehta et al. 2014) we aimed to identify biomarkers for PPD by global assessment of peripheral blood gene expression (N = 225 samples from 86 women at different timepoints including 29 PPD cases and 40 controls, recruited in Emory University, Atlanta, USA). Using gene expression profiles in the third trimester where all women had no significant depressive symptoms, 116 transcripts were significantly differentially expressed (corrected p-value <0.01) between PPD cases and controls, with functional annotation indicating a role of estrogen signaling. These transcripts differentiated cases and controls with 88% accuracy in the discovery and replication sample. To the best of our knowledge this is the earliest prospective gene expression predictor for PPD. The robustness of these predictors needs to be tested in larger, independent and ethnically diverse cohorts. Also, due to the overlapping etiology of depression and other mood disorders, these results might also be relevant to other mood disorders. Power calculations depicting the number of samples required to test the predictive biomarkers with adequate sensitivity and specificity at a 95% Confidence interval will be described (unpublished). These calculations show that large numbers of samples are required to be able to detect the small and subtle biological changes observed in postpartum depression. For instance, assuming the average postpartum depression disease prevalence rate of 13%, we calculate that even for a predictor with specificity and sensitivity as high as 93%, a total of over 2300 samples will be required. Given the prospective nature of the studies and accounting for variation in rates of women who go on to develop PPD, it is clear that a large international interface is required to pool biological resources to reach these sample sizes. We will discuss the importance of a current initiative associated with PACT to establish a PPD biological repository for gene expression profiling to identify robust early predictive biomarkers for PPD. This talk will demonstrate the scale of data required to uncover robust and reproducible biomarkers for postpartum depression and these results will provide a valuable insight for future ongoing biomarker studies in Major depressive disorders. GENETICS OF LITHIUM RESPONSE IN BIPOLAR DISORDER Chair: John Kelsoe, University of California San Diego Overall Abstract Details Lithium is the oldest and still the best mood stabilizing medication for bipolar disorder. There is a wide range in response to lithium, and a subset of patients have a very robust response with almost complete elimination of symptoms. Lithium response has been shown to be familial, and it has been argued that lithium responsive bipolar disorder may constitute a mechanistically distinct form of illness. If this is true, it suggests that genetic variants associated with good lithium response, may also be susceptibility genes and predispose to a form of illness that involves pathways that are responsive to lithium. The identification of genes for lithium response may therefore have a double yield of a possible clinically useful predictor, and a way to dissect bipolar disorder into less heterogeneous parts. Urs Heilbronner will present the latest results of the ConLiGen consortium GWAS in 2500 subjects. Martin Alda will present genome sequencing results from lithium responsive bipolar patients. Sarah Bergen will describe GWAS results from a large sample of subjects treated with lithium. Lastly, John Kelsoe will describe cellular models in lymphoblasts and iPS derived neurons that may help guide the search for genomic variants by identifying physiologically meaning full targets. These studies suggest a dramatic difference in induction of gene expression in lithium responders as compared to non-responders, as well as, differences in electrophysiological and calcium signaling. AN UPDATE FROM THE CONSORTIUM ON LITHIUM GENETICS (CONLIGEN): PHENOMIC AND GENOMIC STUDIES Urs Heilbronner1, Liping Hou2, Marcella Rietschel3, Francis McMahon2, Thomas Schulze4, The ConLiGen Consortium 1 University Medical Center Goettingen, 2Human Genetics Branch, NIMH, NIH, 3 Department of Genetic Epidemiology in Psychiatry, Central Institute of Mental Health, Mannheim, Germany, 4Section on Psychiatric Genetics, Department of Psychiatry and Psychotherapy, University Medical Center, Georg-August-University, Göttingen, Germany Individual Abstract Background: Lithium remains a mainstay in the long-term treatment of bipolar disorder (BD). The individual response to lithium is variable. About 30% of patients treated with lithium have fewer illness episodes over time, while about 20% have no response. Data from pharmacogenetic studies of lithium are comparatively sparse, and these studies have generally employed small sample sizes and varying definitions of response. Genetic markers of lithium response would be valuable for treatment planning and could provide insights into the biological mechanism of lithium action. To put that idea into practice, the international Consortium on Lithium Genetics (www.ConLiGen.org) was established. Methods In a first GWAS, ConLiGen studied 1080 European and European American lithium-treated BD patients. All patients were characterized for lithium response with an 11-point treatment response scale (“Alda Scale”, Grof et al. 2002). The Alda Scale assesses clinical improvement attributable to lithium, taking into account various confounding variables. Phenotype definitions were developed by consensus within ConLiGen. The whole sample was genotyped using Illumina arrays to perform a genome-wide association study (GWAS) of lithium response. Results: Inter-rater reliability of lithium response assessment was good, with kappa values >0.7. GWAS genotyping was completed at excellent call rates (>99% of samples had a call rate >98%). While no genome-wide significant finding at the p<5*10-8 level was observed, the top hit SNP rs17728078 in the gene SLC4A10 (solute carrier family 4, sodium bicarbonate transporter, member 10; p=9.59*10-6) yielded an odds ratio of 1.58, which is quite uncommon for complex phenotypes, and represents a common allele at a minor allele frequency of ~0.4, increasing the chances of replication in an independent sample. Discussion: Our finding in the SLC4A10 gene is promising as this gene belongs to a small family of sodium-coupled bicarbonate transporters (NCBTs) that regulate the intracellular pH of neurons and the pH of the brain extracellular fluid. However, replication of this finding in additional samples will be crucial to establish it as true susceptibility factor for lithium response. Within the framework of ConLiGen, 1571 new samples from Europe, North America and Australia are currently being analyzed for that purpose. Results of this replication GWAS will be presented at the meeting. Additionally, ConLiGen has access to 222 lithiumtreated BD patients from East Asia. Reference Grof P, Duffy A, Cavazzoni P, Grof E, Garnham J, MacDougall M, O’Donovan C, Alda M: Is response to prophylactic lithium a familial trait? J Clin Psychiatry 2002; 63:942–947. INVESTIGATING RESPONDERS TO LITHIUM AS A DISTINCT SUBGROUP OF BIPOLAR DISORDER Martin Alda1, Cristiana Cruceanu2, Gustavo Turecki2, Guy A. Rouleau2 1 Dalhousie University, 2McGill University Individual Abstract Phenotypic and genetic heterogeneity complicates the genetic and neurobiological research in psychiatry. A promising strategy to reduce heterogeneity is a study of validated subtypes of illness. Robins and Guze (Am J Psychiatry, 1970) proposed five criteria of diagnostic validity: (1) clinical description, (2) follow-up study, (3) delimitation from other disorders, (4) family study, and (5) laboratory studies. We applied these criteria to bipolar disorder responsive to long-term lithium treatment. In a series of investigations we examined characteristics of patients with bipolar disorder responsive to lithium and compared them with lithium non-responders as well as responders to other mood stabilizers. Patients responsive to lithium showed (1) a typical clinical picture with euphoric manias, melancholic depressions, low rates of co-morbid conditions, and recurrent episodic clinical course. The response to lithium was (2) longitudinally stable even after 20 years of follow-up. In comparison, (3) responders to lamotrigine or carbamazepine showed more often atypical features such mood liability, comorbid anxiety, or mood-incongruent psychosis. In family studies (4) lithium responders had higher prevalence of bipolar disorder and lower rates of schizophrenia among their relatives and the relatives suffering from bipolar disorder were about 3.7 times more likely to respond to lithium compared to patients unselected for family history. Finally, several neurobiological studies (5) supported the view of lithium responders as a distinct group. For instance in a positron emission tomography study lithium responders showed a distinct pattern of regional cerebral blood flow changes in response to induced sadness – similar to their unaffected relatives, but significantly different from responders to valproate – with main differences in the rostral anterior cingulate and dorsolateral prefrontal cortex. These results support the view of lithium responsive bipolar disorder as a distinct subtype of bipolar disorder. They also make lithium responders a promising group for genetic and neurobiological studies. In the last 15 years, we established a large sample of patients and relatives characterized for their response to long term treatment. The samples is the basis for a whole exome sequencing study in a combined sample of moderately-sized families (41 families, 234 exomes) and unrelated probands (117 subjects). The results of the study will be presented at the symposium. Preliminary analyses indicate a higher rate of damaging mutations in genes that have been previously proposed as related to pharmacological effects of lithium. GENOME-WIDE ASSOCIATION STUDY OF LITHIUM RESPONSE IN A SWEDISH POPULATION Sarah Bergen1, Jie Song2, Christina Hultman2, Paul Lichtenstein2, Mikael Landen3 1 Karolinska Institute, 2Medical Epidemiology and Biostatistics, Karolinska Institutet, 3Institute of Neuroscience and Physiology, The Sahlgrenska Academy at Gothenburg University; Medical Epidemiology and Biostatistics, Karolinska Institutet Individual Abstract Background: Lithium is one of the oldest and most common treatments for bipolar disorder, but it is only effective in a subgroup of patients. Currently, the effectiveness of lithium is assessed through trial and error, but understanding the factors predicting lithium response could help to prevent wasted time and needless suffering faced by non-responders. This genome-wide association study sought to identify common genetic variation influencing response to lithium. Methods: In a sample of 940 Swedish patients with bipolar disorder, a self-reported measure of lithium response was tested for association against genome-wide genotype data. The 64% of patients reporting full response were contrasted with the 36% with partial response or no benefit. Additionally, the lithium responsive subgroup of patients was tested against 1215 healthy controls, predicated on the idea that they may define a more etiologically homogeneous patient population. Logistic regression was performed in PLINK incorporating four MDS covariates to account for population substructure. Results: For the lithium responder versus non-responder analyses, there were no genome-wide significant results. The top hit was a marker in the zinc-finger gene ZNF83 (p = 7.45 x 10-6). The analyses of lithium responders versus controls, however, yielded one marker approaching genome-wide significance in the DLGAP1 gene (p = 9.26 x 10-8). Discussion: No single common genetic variant with a strong effect on lithium response was detected, but analyses to detect risk markers for bipolar disorder in the subgroup of lithium responsive cases tentatively implicate DLGAP1, a postsynaptic scaffolding protein with several binding partners previously associated with other neuropsychiatric disorders. Additionally, genotyping for 1600 more Swedish subjects with lithium response information is in progress, and collaborations to incorporate 2600 cases from the UK will substantially enhance power to detect associations. DISTINCT CELLULAR PHENOTYPES ASSOCIATED WITH GOOD AND POOR RESPONSE TO LITHIUM IN BIPOLAR DISORDER 4 Kangguang Lin1, Jun Yao2, Kristen Brennand3, John Kelsoe , Michael McCarthy4, Abesh Bhattacharjee4, Susan Leckband5, Cory White4, Wei-Wei Matsuda4, Christopher Woelk4, Fred Gage6, Pharmacogenomics of Bipolar Disorder Study Investigators 1 University of Hong Kong, 2University of Wisconsin, 3Mt. Sinai School of Medicine, 4University of California San Diego, 5VA San Diego Healthcare System, 6Salk Institute Individual Abstract Pharmacogenetics has great potential to both guide clinical treatment and to help unravel the genetic and etiological heterogeneity of bipolar disorder. However, attempts to identify genes associated with response are hampered by the difficulty, as well as, labor and expense of determining drug response in psychiatric subjects. Whereas, GWAS is successfully identifying small effect variants using very large sample sizes, it is likely cost prohibitive at this time to phenotype very large samples for drug response. For this reason, an efficient strategy may be to employ biological information to identify a set of candidate genes that are more likely to be involved in drug response. In this way, a much smaller set of hypotheses can be tested with resulting substantial gain in statistical power. Here, we describe two cellular phenotypes that distinguish bipolar lithium responders from non-responders. Blood for immortalized lymphoblasts and skin biopsies for iPS cells were obtained from bipolar I subjects participating in a multi-site prospective lithium trial, the Pharmacogenomics of Bipolar Disorder Study, or a similar study of veterans. In each of these studies, bipolar I subjects were stabilized on lithium monotherapy over a 16 week period, then those that reached remission were followed for up to 2 years in order to determine time to relapse as a measure of response. Lymphoblasts from 8 prospectively documented lithium responders and 8 non-responders were treated with 1mM lithium for one week at which time RNA was harvested and gene expression determined by RNAseq. Analysis was conducted using BioconductoR and R routines, and gene expression was compared within each subject with and without lithium. While 1557 genes underwent a statistically significant change in expression in the responder group, only 75 were significantly changed in the non-responder group. This suggests, simply, that the responders had a clinical response to lithium because their cells underwent a much greater change in physiological state as compared to non-responders. Most notable was the gene CRIP2 which underwent an 18 fold increase in expression in responder and only a 3 fold increase in non-responders. Induced pluripotent stem (iPS) cells offer a route to model response in derived neurons. Skin biopsies were obtained from 3 responders, 3 matched non-responders and 4 matched controls. These were reprogrammed to iPS cells using Sendai virus and pluripotency validated. They were then differentiated into Prox1 positive hippocampal dentate gyrus/glutamatergic neurons. Patch clamp studies revealed extended trains of action potentials in 2 of 3 responder lines, that were not observed in any of the control lines. The non-responders displayed similar electrophysiology as the responders. A corresponding alteration in calcium flux was also observed, and both phenotypes were rescued by lithium treatment. RNAseq studies in these samples are in progress. (EPI)GENETICS AND (EPI)GENOMICS OF PSYCHOLOGICAL TREATMENT RESPONSE Chair: Thalia Eley, Institute of Psychiatry, Kings College London Overall Abstract Details Background: Anxiety and depressive disorders are highly prevalent and debilitating conditions. Psychological interventions are commonly the treatment of choice for anxiety disorders, and are also widely used in depression. However, as with pharmacological treatments, not all individuals respond to psychological interventions. The small but growing field of therapy genomics, parallel to pharmacogenomics, explores genetic, genomic and epigenetic factors as both predictors of treatment response and as potential mechanisms. Our first speaker will present a GWAS of response to cognitive-behavior therapy (CBT) in child anxiety disorders. Although none of the individual SNPs reached genome-wide significance, there were several at a suggestive level, and a polygenic risk index created from the top ~20 hits, showed a strong and significant association with treatment response. Our second speaker will look at change in (a) genome-wide gene expression and (b) DNA methylation in selected candidate genes, across exposure-based therapy for individuals with panic disorder or specific phobias. RNA and DNA methylation levels are analyzed at three time-points from pre-treatment to posttreatment and follow-up allowing the exploration of both gene expression DNA methylation as potential mechanisms of change. Our third speaker will present a study examining the role of epigenetics in response to psychotherapy for Post-Traumatic Stress Disorder (PTSD). Analyses explore the role of pretreatment methylation levels as a predictor of outcome, and increase/decrease in methylation levels as a potential mechanism of change. The session will close with findings from a study in which adults with depressive disorders have been randomized to CBT versus medication. Analyses include imaging data as well as genotype, gene expression and DNA methylation. Preliminary data of a GWAS for PET imaging predictors of CBT vs MED response in a subsample will be shown, with the top hit being replicated in an independent sample. Conclusion: Genetic factors are likely to become a useful predictor of psychological treatment response. Whilst GWAS analyses are likely to be underpowered, a combination of using polygenic risk scores and working towards multiple datasets on which meta-analyses can be conducted may prove fruitful. It is particularly interesting that genetic findings to date appear to be independent of clinical and demographic predictors of psychological treatment response. However, in order to understand mechanisms of change we need to look beyond genotype alone. Findings relating to gene expression and DNA methylation changes during psychological interventions may provide useful indicators of potential underlying mechanisms and thus new treatment development. A GENOMEWIDE ASSOCIATION STUDY OF RESPONSE TO COGNITIVE BEHAVIORAL THERAPY IN A GLOBALLY-ASCERTAINED COHORT OF CHILDREN WITH ANXIETY DISORDERS Jonathan Coleman1, Kathryn Lester2, Susanna Roberts2, Robert Keers2, Chloe Wong2, Jennifer Hudson3, Gerome Breen2, Thalia Eley2, Team GxT 1 Institute of Psychiatry, King's College London, 2King’s College London, MRC Social, Genetic and Developmental Psychiatry Centre, Institute of Psychiatry, 3Centre for Emotional Health, Department of Psychology, Macquarie University, Sydney Individual Abstract Background: Anxiety disorders are common, with lifetime prevalence in adults of approximately 30%. Psychosocial treatments, including cognitive behavioral therapy (CBT), are the primary treatment modality for anxiety disorders in the United Kingdom. Remission of the disorder following CBT is estimated at approximately 60% post-treatment, and is likely to increase in the period after treatment. A modest candidate gene literature suggests individual differences in treatment response may have a genetic basis; however, such studies are limited by methodological issues. Early successes and failures from the candidate gene literature motivated the presented genome-wide association study (GWAS), examining the association of common single nucleotide polymorphisms (SNPs) with differential response to CBT. Methods: Genetic samples were gathered from 1596 children (aged 5-18) diagnosed with anxiety disorders, undergoing CBT. The cohort originated from eleven different sites in the UK, USA, Australia, and Western Europe. The Anxiety Disorder Interview Schedule was used to provide diagnoses and clinical severity ratings at baseline, upon completion of treatment, and at followup. Buccal swabs were used to obtain DNA, which was extracted using a standard protocol, concentrated by filtration and resuspension, and genotyped using the Illumina HumanCoreExome array. SNPs were then imputed to the latest release from the 1000 Genomes project, providing data on more than 6 x 106 variants for analysis. The worldwide ascertainment of this sample confounds the ability of PCA to control for population stratification, and so mixed linear model association analyses were performed in EMMAX. In addition, an estimate of SNP-chip pseudoheritability was calculated by EMMAX and this is compared to that found using GCTA. Results: The initial outcome variable was change in clinical severity rating across treatment. Findings above suggestive significance (p < 5 x 10-6) were tested against other phenotypes, including change in clinical severity ratings between baseline and follow-up. Pseudoheritabilty and predictions of polygenic effect were calculated. The results and implications of these analyses are discussed. Discussion: We present a GWAS of response to CBT in a cohort of children with anxiety disorder ascertained at sites across the globe. This is, to our knowledge, the first GWAS of response to psychosocial treatment, and the first treatment response GWAS to be performed in anxiety disorder. Although the sample size is relatively large for a study of response to therapy, it is small compared to successful psychiatric GWAS, and is likely underpowered to detect the small effect sizes expected. Power analyses estimate that the sample has 80% power to detect variants at a genotypic relative risk of 1.36 and frequency of 0.4. However, estimates of pseudoheritability suggest common SNPs can explain a portion of the variance in treatment response. EPIGENETIC FACTORS AND RESPONSE TO PSYCHOLOGICAL THERAPY Susanna Roberts1, Kathryn J. Lester1, Jürgen Margraf2, Silvia Schneider2, Tobias Teismann2, Jonathan Coleman1, Gerome Breen1, Chloe C.Y. Wong1, Thalia C. Eley1 1 King's College London, 2Ruhr University Bochumm, Germany Individual Abstract Exposure-based CBT is a psychological therapy which involves exposing the individual to the anxiety-provoking stimuli, and is an effective treatment option in anxiety disorders such as phobias, panic disorder and agoraphobia. However, there is still substantial variability in response; around 30% of adults are not diagnosis-free following treatment, and many retain a high level of fear. Recent research suggests that response to psychological therapies such as manualised CBT and exposure therapy are associated with differences in DNA methylation change across the course of treatment. Furthermore, investigation of gene expression levels across the course of treatment may provide insight into the potential molecular mechanisms involved in response to therapy, as they can be influenced by both genetic and environmental factors and are useful indicators of gene function and activity. Participants consisted of 100 adults receiving exposure-based CBT for a primary diagnosis of panic disorder, agoraphobia or specific phobia. Anxiety disorder diagnoses were made by trained clinicians according to DSM criteria. DNA and RNA were extracted from whole blood samples collected at pretreatment, post-treatment and follow-up time points. DNA methylation at 4 candidate genes (SERT, FKBP5, NR3C1 and CRHR1) was quantitatively measured using the Sequenom EpiTYPER. Genomewide expression was assessed using the Illumina HumanHT-12 v4 Expression BeadChip. Methylation status and expression levels at all three time-points were investigated for association with both dichotomous clinical outcome and changes in symptom severity. The findings of these studies will be reported, and their relevance and implications within clinical and biological frameworks will be discussed. CHANGES IN GR AND FKBP5 METHYLATION IN RESPONSE TO PTSD TREATMENT Rachel Yehuda1, Linda Bierer1, Amy Lehrner1, Nikos Daskalakis1, Iouri Makotkine1, Frank Desarnaud1, Janine Flory1 1 Mount Sinai School of Medicine, James J. Peters VA Medical Center Individual Abstract Epigenetic alterations offer promise as prognostic or diagnostic markers, but it is not known whether these measures associate with or predict clinical state. These questions were addressed in a pilot study with combat veterans with PTSD to determine whether cytosine methylation in promoter regions of the glucocorticoid-related NR3C1 and FKBP51 genes would predict or associate with treatment outcome. Veterans with PTSD were treated with prolonged exposure (PE) psychotherapy, yielding responders, defined by no longer meeting diagnostic criteria for PTSD, and non-responders. Blood samples were obtained at pre-treatment, after 12 weeks of psychotherapy (post-treatment), and after a 3 month follow-up. Methylation was examined in DNA extracted from lymphocytes. Measures reflecting glucocorticoid receptor (GR) activity were also obtained from lymphocytes; plasma and 24-hr urine cortisol and plasma neuropetide-Y levels were also measured. Methylation of the GR gene (NR3C1) promoter assessed at pre-treatment predicted treatment outcome, but was not significantly altered in responders or non-responders at post-treatment or follow-up. In contrast, methylation of the FKBP5 gene (FKBP51) promoter region did not predict treatment response, but decreased in association with recovery. In a smaller subset, a corresponding group difference in FKBP5 gene expression was observed, with responders showing higher gene expression at post-treatment than non-responders. Endocrine markers also changed in association with symptom change. These preliminary observations require replication and validation. However, the results support research indicating that some glucocorticoid related genes are subject to environmental regulation throughout life. Moreover, psychotherapy resulting in substantial symptom change constitutes a form of ‘environmental regulation’ that may alter epigenetic state. Finally, the results further suggest that different genes may be associated with prognosis and symptom state, respectively. GENOMIC AND EPIGENOMIC PREDICTORS OF DIFFERENTIAL RESPONSE TO COGNITIVE BEHAVIORAL THERAPY VS. ANTIDEPRESSANT DRUG TREATMENT IN MAJOR DEPRESSION Elisabeth Binder1, Tania Carrillo-Roa1, Caleb A. Lareau 2, Callie L. McGrath3, Boadie W. Dunlop3, Mary E. Kelley3, Helen S. Mayberg3 1 Max-Planck Institute of Psychiatry, 2University of Tulsa, 3Emory University Individual Abstract Currently the choice of antidepressant treatment strategy is not based on the underlying pathophysiology. Neuroimaging results suggest that patients preferentially responding to either psychotherapy or antidepressant drugs have different resting state neural activation pattern (McGrath et al. 2013). These different activations on the neural circuit level maybe related to different genomic risk factors, both on the DNA sequence and the epigenetic level. This presentation will highlight approaches combining imaging and genetic and epigenetic data to predict differential response to cognitive behavioral therapy (CBT) or antidepressant drugs in patients with major depression. Patients were recruited at Emory University and randomized at baseline to 12 weeks sCIT, or 16 sessions of CBT. Genome-wide genotypes (Illumina OmniExpress) and DNA methylation (Illumina HM-450K) were measured in peripheral blood DNA drawn at baseline. Genome-wide SNPs and CpGs methylation univariate and multivariate association analyses were initially conducted in 76 patients with major depression to test for association with activation pattern in brain regions predicting differential response to CBT vs. drug assessed by Brain glucose metabolism with positron emission tomography prior to treatment randomization. We observed genome-wide significant association of rs34383296 (p = 9.4x10-9) in a multivariate analysis that included three of the 6 tested brain regions. The associated variant lies in a gene dense region on chromosome 9 within the NDOR1 gene and it is an eQTL for ARRDC1, a gene ~400kb downstream, related to arrestin-mediated internalization of cell surface receptors. This SNP was genotyped in an independent larger sample (N = 260) with major depression and predicted differential response to CBT vs. drug in the expected direction. New data of on-going analyses of DNA methylation pattern and GWAS in a larger sample of 310 patients treated with either CBT or escitalopram or duloxetine will be reported. Genetic and genomic biomarkers allowing a prediction of preferential treatment response to psychotherapy vs. antidepressant drugs could optimize the treatment for the individual patient and decrease time to clinical response. McGrath CL, Kelley ME, Holtzheimer PE, Dunlop BW, Craighead WE, Franco AR, Craddock RC, Mayberg HS. Toward a neuroimaging treatment selection biomarker for major depressive disorder. JAMA Psychiatry. 2013 Aug;70(8):821-9. UTILISING FAMILY-BASED INFORMATION IN GENETIC RESEARCH Chair: Pippa Thomson, Institute of Genetics and Molecular Medicine Overall Abstract Details Low frequency, high penetrance alleles in a background of high locus and/or allelic heterogeneity are immune to discovery by genome-wide association study (GWAS) analysis in a conventional case-control or cross-sectional study design. In this situation next generation sequencing is an alternative approach to the identification of causative variants. The high frequency of rare variants in the human genome makes it difficult to identify causative variants from the background level of variation. In this context, utilizing samples for which additional family members are available both increases the filtering power to identify variants shared by cases and provides an in-built quality control for these relatively new sequencing technologies. The increasing move to rare variation, estimation of heritability and the search for endophenotypes has seen a return to the analyses of familial information. We will describe the recent results including exome sequencing data joint analyses of quantitative and binary traits, and aggregate gene- and pathway-centric testing. Using examples from schizophrenia, bipolar disorder and depression, this symposia will highlight the value of such studies and the progress made. ADVANTAGES OF USING FAMILY COHORTS TO STUDY NEUROPSYCHIATRIC DISORDERS Lan Xiong1, Cristiana Cruceanu2, Pingxing Xie2, Qin He1, Mina Ohadi3, Narge Moghimi4, John Vincent4, Martin Alda5, Gustavo Turecki2, Guy Rouleau2 1 University of Montreal, 2McGill University, 3Genetics Research Center, University of Social Welfare and Rehabilitation Services, 4Centre for Addiction and Mental Health, 5Department of Psychiatry, Dalhousie University Individual Abstract In the past decade the main study design for genetic studies of complex traits has addressed the common disease/common variant hypothesis using case-control cohorts. This was possible because of the availability of cheap high-throughput DNA chip technology and the recruitment of large numbers of unrelated cases and controls. However, the development of NGS technologies has led to a refocus onto the contribution of rare variants to disease risk. Most existing case-control cohorts do not have the power to define the role of such rare variants in disease susceptibility. However, familial cohorts provide significant advantages in genetic studies for studying the role of rare variants in complex traits. We are recruiting families to participate in various genetic studies, at first for gene identification of different Mendelian disorders; now to study more complex diseases, such as bipolar disorder, schizophrenia, restless legs syndrome, essential tremor etc., in which familial cases have significantly reduced the clinical and genetic heterogeneity and have led to successful gene discoveries. We have also used a family study design to investigate the role of de novo high-penetrant variants in autism and schizophrenia. We will give examples of how we are using special family cohorts for genetic discovery in psychiatric disorders: (1) Large extended consanguineous pedigrees from Pakistan with schizophrenia, in which we have performed high density SNP genome scan and exome sequencing on all affected individuals in each pedigree; (2) Inbred pedigrees from Iran with bipolar disorders, in which we have performed exome sequencing of all affected individuals; (3) Large pedigrees from Canada with bipolar disorder responsive to lithium treatment, in which we have focused on a more homogenous subphenotype of bipolar disorder and its related candidate genes and pathways. In each of these projects/families we are currently generating whole exome data on every affected individual with reliable diagnosis, then prioritizing on highly penetrant (e.g. protein-truncating, missense, or frameshift) or functionally relevant variants (e.g. 3’UTR, 5’UTR, splicing) shared among all or most affected individuals within the family. We are also testing alternative hypotheses (e.g. different diagnostic schemes and modes of inheritance) and further validating the potential candidate variants through additional genetic testing and functional assays. Family studies may provide answers for more profound genetic questions, such as origin of mutations, heritability of diseases, complex mode of inheritance (such as digenic, oligogenic or multigenic inheritance, or epigenetic inheritance), modifier genes and gene-gene interactions. Family studies are also by default longitudinal and prospective studies, providing significant biological insights into the contribution of genetic/genomic variants to human disease phenotypes. LINKAGE AND SEQUENCING IN A BRAZILIAN BIPOLAR FAMILY WITH 111 MOOD DISORDER CASES Simone de Jong1, Mateus Diniz2, Shaza Alsabban3, Gadelha Ary2, Andiara Rodrigues2, de Jong Simone3, McGuffin Peter3, Bressan Rodrigo2 1 MRC SGDP Centre, Institute of Psychiatry, King's College London, 2Federal University of Sao Paulo, 3 King's College London Individual Abstract We present a phenotypic and molecular study of one of the largest families ever found with multiple cases of bipolar disorder (BP, n=39) and major depressive disorder (MDD, n=59). The family come from a rural area of Brazil and also contains many mood disorder cases with comorbid autoimmune thyroid disease (n=24) and type 1 diabetes (n=31) as well as Parkinson's disease (n=8), selfreported as mature onset insulin dependence, with 7 cases reporting both autoimmune comorbidities. There are multiple child/teenage family members who exhibit some form of mood or psychiatric disturbance with anticipation in age of onset indicated. We have conducted an initial ascertainment of the family in 2009/10 with basic psychiatric phenotyping and self-report of physical comorbidities. In all, 333 of the family members consented and gave blood in the first wave of the study. We performed a whole genome linkage scan of the BBF-A family to find regions of chromosomes that are segregating with mood disorders in the family (Diniz/Al-Sabban et al., in prep). Our data analysis so far has primarily used the 269 family members representing the most densely affected part of the pedigree, using autosomal single nucleotide polymorphisms (SNPs) genotyped using the Affymetrix 10K genotyping array, with approximately 67% of information content genome wide. Multipoint parametric (HLOD) and non- parametric linkage (NPL) analyses were performed using MERLIN splitting BBF-A into twelve subfamilies and breaking loops (9 from 267 meioses in the first wave of data). In addition, Multipoint parametric linkage analyses were performed using MCLINKAGE, where the family could be analyzed with their structure and loops intact. Parametric Linkage analyses were conducted under dominant and recessive modes of disease transmission and non-parametric linkage (NPL) analyses was performed. Genomewide significant linkage, allowing for multiple phenotype definitions, was identified for 2p23.1-p22.3 (LOD=3.83) for all mood disorders, 3p23-p24.1 (LOD=4.18) for narrow bipolar 1, and both 11p14 (LOD=4.49) and 12q24.22-q24.32 (LOD=4.74) for depression. In addition, 22q11.21-q12.1 had a suggestive/trend lod score of 3.76 for a broad Bipolar disorder definition. Exome sequencing has been carried out on a limited number of cases and will be presented. UTILIZATION OF LARGE RANDOMLY ASCERTAINED HUMAN PEDIGREES TO IDENTIFY RARE FUNCTIONAL VARIANTS INFLUENCING RISK OF PSYCHIATRIC DISORDERS John Blangero1, Laura Almasy1, David Glahn2 1 Texas Biomedical Research Institute, 2Yale University Individual Abstract Although the number of psychiatric disease-related QTL localizations has risen rapidly during the GWA era, causal gene discoveries have been few. The accumulating data now suggest that common variants (such as those found in traditional GWA studies) have small biological effects that are extremely difficult to assess functionally and, hence, are unlikely to be easily associated with the underlying causal genes. The advent of economically reasonable whole genome sequencing (WGS) now allows us to turn attention to rare sequence variants that overwhelmingly comprise the majority of human genetic variation. Rare functional variants tend to have substantially larger biological effect sizes that should be much easier to molecularly characterize. However, the rarity of these variants requires a different study design than that of unrelated cases and controls. Pedigree-based studies are optimal for testing the rarest of genetic variants (specifically private variants). In this paper, I will show how large pedigrees can be assessed for their power to detect and test private functional variants using WGS data from the Genetics of Brain Structure and Function Study. A vast amount of private non-synonymous variation is observable for major biological pathways of psychiatric relevance. Many of these private variants are captured in sufficient numbers due to Mendelian transmission to allow direct statistical testing while those that are observed in too few copies can still be utilized for aggregate gene- and pathway-centric testing. Combining the analysis of WGS data with new statistical methods for detecting disease-related endophenotypes in randomly ascertained pedigrees, we identify rare functional variants that implicate several novel likely genes relevant for schizophrenia and mood disorders. IDENTIFYING GENETIC INFLUENCES IN FAMILIAL RECURRENT MAJOR DEPRESSION BY EXOME SEQUENCING Pippa Thomson1, Jennifer E. Huffman1, James Prendergast3, Victoria Svinti1, Generation Scotland1, Caroline Hayward1, Martin Taylor1, Malcolm Dunlop1, David Porteous1, Andrew McIntosh1, Alan Wright1, Nick Hastie1 1 Institute of Genetics and Molecular Medicine, 2Roslin Institute Individual Abstract The high frequency of rare variants in the human genome makes it difficult to identify causative variants from the background level of variation. In order to identify rare variants influencing recurrent major depressive disorder, we have generated whole exome sequence data from 277 members of 44 families and 148 unrelated individuals with familial early onset, drawn from the Generation Scotland: Scottish Family Health Study. Exome variants, that are enriched within affected individuals relative to almost a thousand control exomes have been analyzed for predicted functionality, co-segregation within families, association with endophenotypes of depression, and clustering within genes or pathways. Linkage analyses identify two genome-wide significant regions: a peak at the tip of chromosome 12 under a recessive model (12p13.33, hLOD 6.4, mLOD 3.7) within a micro-deletion region associated with neurodevelopmental delay, and a peak overlapping the centromere at chromosome 18 under an additive model (18p11.2-18q11.2, hLOD 4.12, mLOD 2.5). Quantitative linkage analyses of depression endophenotypes support the involvement of the chromosome 18pq region in age of onset and cognitive phenotypes including logical memory (LOD > 1). Multiple loss-of-function variants have been identified in these regions and burden analyses are underway to identify the gene/genes underlying the linkage peak