docThe Ambystoma laterale-jeffersonianum Complex
download 
Report Transcription
The Ambystoma laterale-jeffersonianum Complex
The Ambystoma laterale-jeffersonianum Complex in Central Ontario: Ploidy Structure, Sex Ratio, and Breeding Dynamics in a Bisexual-Unisexual Community Author(s): Leslie A. Lowcock, Hugh Griffith, Robert W. Murphy Source: Copeia, Vol. 1991, No. 1 (Feb. 7, 1991), pp. 87-105 Published by: American Society of Ichthyologists and Herpetologists Stable URL: http://www.jstor.org/stable/1446251 . Accessed: 04/02/2011 09:20 Your use of the JSTOR archive indicates your acceptance of JSTOR's Terms and Conditions of Use, available at . http://www.jstor.org/page/info/about/policies/terms.jsp. JSTOR's Terms and Conditions of Use provides, in part, that unless you have obtained prior permission, you may not download an entire issue of a journal or multiple copies of articles, and you may use content in the JSTOR archive only for your personal, non-commercial use. Please contact the publisher regarding any further use of this work. Publisher contact information may be obtained at . http://www.jstor.org/action/showPublisher?publisherCode=asih. . Each copy of any part of a JSTOR transmission must contain the same copyright notice that appears on the screen or printed page of such transmission. JSTOR is a not-for-profit service that helps scholars, researchers, and students discover, use, and build upon a wide range of content in a trusted digital archive. We use information technology and tools to increase productivity and facilitate new forms of scholarship. For more information about JSTOR, please contact support@jstor.org. American Society of Ichthyologists and Herpetologists is collaborating with JSTOR to digitize, preserve and extend access to Copeia. http://www.jstor.org Copeia,1991(1),pp. 87-105 The Ambystomalaterale-jeffersonianumComplex in Central Ontario: Ploidy Structure, Sex Ratio, and Breeding Dynamics in a Bisexual-unisexual Community LESLIEA. LOWCOCK,HUGH GRIFFITH AND ROBERT W. MURPHY Ploidy ratio was investigated in six Ontario populations of the Ambystoma complex by collecting blood from individual salamanders laterale-jeffersonianum during spring migrations, and analyzing the nuclear DNA content of erythrocytes by flow cytometry. All populations contained diploid male and female A. laterale as well as a potential mixture of diploid, triploid, and tetraploid female hybrids, which occurred at variable frequencies. Triploid males, pentaploid females and possible polyploid A. laterale (3n and 4n) were found in one extensively sampled population. Initial separation of A. laterale from hybrids based on morphological criteria was tested for accuracy by comparison with the cytometric results and found to be exceptionally high (99.6%). Sex ratios in all populations were biased overwhelmingly towards females, primarily because female hybrids accounted for up to 84%of a breeding aggregate;however, diploid female A. laterale outnumbered males in several populations and in two instances, near the northern limit of hybrid biotypes, these account for much of the biased sex ratio. Timing of breeding, always triggered by precipitation (rain or snow), varied between sites and was correlated with altitude/latitude. Initial immigrations at all sites contained biotypes indicative of local primary composition with respect to both ploidy and hybridity. The breeding dynamics of one population were investigated by daily sampling throughout the breeding period. Migration occurred in distinct waves. In A. laterale, frequency of immigrating males declined over the breeding period while frequency of females increased, a pattern conforming to the typical Ambystomabreeding dynamic. Within hybrids, the percentage of tetraploids increased over the breeding period. Within waves, there was a general increase in hybrids over time. T HE evolution and ecology of unisexual vertebrates is an emerging area of concern in organismal biology. Reasons for this include: 1) occurrences of complexes containing unisexual and bisexual biotypes in fishes, amphibians and reptiles are more widespread than previously thought (Dawley and Bogart, 1989); 2) reproductive modes employed by these forms can be varied and confounding, even within a population (Bogart et al., 1987, 1989); 3) unisexuals in a given association seldom form a homogeneous group (Bogart et al., 1987; Bogart, 1989; Lowcock, 1989); 4) interspecific hybrid origin of most unisexual forms appears to confer a high degree of tolerance for aberrant meiotic processes and elevated levels of ploidy (Dawley and Bogart, 1989); and 5) an evolutionary role exists for some of these forms which may involve direct speciation, or an effect on incipient speciation in associated bisexuals (Bogart, 1989; Lowcock, 1989). One of the most interesting and least studied of these features is the lack of homogeneity within the unisexual segment of a population, and the relative proportions of different unisexual forms with respect to each other and their bisexual cohorts. Variability in genome constitution and ploidy among unisexuals has been carried to an extreme in hybrid complexes of the North American salamander genus Ambystoma,in which male and female diploid bisexuals breed in aggregations which can also contain diploid (2n), triploid (3n), tetraploid (4n) and pentaploid (5n) unisexual di- or trihybrids. In genetic and ecological studies of such populations, it is desirable to be able to obtain unambiguous baseline data on ploidy composition and sex-ratio without creating sampling artifact in the population. Numerous studies have established that unisexuals in Ambystomatypically outnumber bisexuals in these populations, but these were unable ? 1991 by the American Society of Ichthyologists and Herpetologists 88 COPEIA, 1991, NO. 1 to distinguish between ploidy classes in unisexual hybrids (Clanton, 1934; Uzzell, 1964; Wilbur, 1971). Genetic studies carried out on randomly collected samples (up to 149 individuals from the same locality; Bogart and Licht, 1986) have demonstrated that variable ploidy and genomic compositions characterize most unisexual populations. At best, however, these studies have been only suggestive of ploidy and sex ratios (Bogart, 1989; Bogart et al., 1985, 1987). Populations of Ambystomacan be very large, and reliable methods for elucidating ploidy composition in samples of several hundred individuals can be prohibitively time consuming and necessitate sacrificing of the animals. Methods of ploidy evaluation that do not require sacrificing, such as erythrocyte area measurements (Uzzell, 1964; Wilbur, 1971; Austin and Bogart, 1982; Bogart et al., 1985) and ectodermal cell or nuclei area measurements (Morris and Brandon, 1984; Licht and Bogart, 1987) can also be slow, labor intensive and lack the precision of other methods at higher levels of ploidy. Additionally, random sampling of breeding populations may yield biased results due to ecological and behavioral partitioning of males, bisexual females and genomically variable polyploid biotypes (Bogart et al., 1987). Flow cytometry (FCM), a rapid and highly sensitive method for measuring the nuclear DNA content of cells, has been used in the investigation of a unisexual complex of hybrid fishes. Dawley and Goddard (1988) employed FCM in their analysis of diploid, triploid and diploid-triploid mosaic biotypes of Phoxinus eosneogaeus. The ability to use FCM for non-destructive gathering of ecological data based on ploidy comparisons among large numbers of individuals is of great benefit to the study of bisexual-unisexual associations. The accuracy of this method precludes the necessity of chromosome confirmation of ploidy when samples are run against standards of known ploidy (Tank et al., 1987). Where hybrids involve two species of differing DNA content, FCM may also indicate genomic composition (Dawley and Goddard, 1988) although the higher the ploidy, the less informative this becomes. Unequivocal genotypic classification of polyploids in hybrid complexes remains most reliably accomplished through allozyme electrophoresis. Where hybrids involve species of similar DNA content (such as in Ambystoma),genotypic inferences can be made only with reference to information gleaned from molecular investigations and a priori knowledge of biogeographic distributions of particular bisexual and unisexual biotypes (Lowcock, 1989). In the present investigation, the template genomic composition of polyploid biotypes associated with populations of the bisexual diploid A. laterale are known from genetic and/or biogeographic data (Lowcock, 1989), and FCM is used solely to compare relative amounts of DNA among individuals. In this paper, we describe the first application of FCM to large numbers of unisexuals (> 100), and obtain the first comprehensive data on ploidy and sex-ratios in breeding aggregations of the A. laterale-jeffersonianumcomplex (nomenclature of Lowcock et al. [1987]). These data contain a number of unique and unexpected results with regard to ploidy levels and ratios within hybrids. Mechanisms are considered to account for each ploidy level. Sex-ratios within syntopic A. laterale failed to conform with theoretical expectations; females outnumbered males, and we discuss possible reasons for this. For one population, sampled comprehensively over the breeding period, we compared arrival time of individuals of different sex or ploidy, because timing has been reported to vary along these parameters (Uzzell, 1964; Panek, 1978; Weller, 1980). At this locality, we also tested to see if ploidy composition remained relatively constant among peak immigration events throughout the breeding period; this provided a measure of the validity of ploidyratio data generated by one-time samples from other areas. Local influences of latitude, physiography and climate on timing of breeding were compared among samples and evaluated. METHODS AND MATERIALS Sampling.-Adult salamanders were collected by various methods during breeding migrations to five ponds and one series of marshes in central Ontario (Fig. 1). The most successful and reliable method was a drift-fence/pitfall trap system (Gibbons and Semlitsch, 1982) at Haliburton Beaver Pond (HBP), Oro Pond (OP), and Algonquin Highlands Pond (AHP). Other immigrants were collected as they crossed asphalt barriers (analagous to a fence; manned and patrolled for the entire evening) separating overwintering habitat from breeding sites: Coboconk Pond (CP) and Algonquin Lowlands (AL). Salamanders from Fort Irwin Pond (FIP) were collected by seining and dipnetting. Ponds were checked frequently before the breeding season LOWCOCK ET AL.-PLOIDY IN HYBRID AMBYSTOMA 89 AlgonquinHighland * Algonquin Lowland Fort L.Huron Irwin Haliburton Oro Coboconk L.Ontario 100 km LErie Fig. 1. Southern and central Ontario, showing location of the six sites from which migratingsalamanders were sampled.The dashed line at the top indicatesthe approximatenorthern limit of hybridbiotypes,beyond laterale.Inset shows area of Ontario enlarged. which all populationsare pure Ambystoma to ensure that immigration had not been initiated prior to sampling. Samples were collected during the first waves of breeding migrations at all localities except HBP, where samples were collected daily throughout the immigration period. pond. Handling time was minimized; the average time from capture to release was less than 24 h. To test the influence of processing on breeding behavior, several recently revived salamanders were paired and placed in 5 litre buckets filled with pond water and detritus. Processing.--Blood preparations for FCM were obtained in the following manner: animals were anesthetized in a weak solution of tricaine methanosulfate (MS-222), examined for sex and/or hybridity, subjected to three measurements with vernier calipers (snout-vent length [SVL], head width [HW] and internarial distance [IND]; see Zeyl and Lowcock [1989] for measurement parameters), and 1-2 drops of blood extracted from an interphalangeal toe-clip. For each sample, whole blood was mixed in a pyrex depression-plate well, with enough freezing solution (2-3 drops, Dawley and Goddard, 1988) to effect a pink color. This suspension was transferred by 0.1 ml pipettor or hematocrit tube to 1.8 ml screw-top cryotubes and frozen immediately in liquid nitrogen (-196 C). Salamanders were revived by washing in pond water, and recuperated briefly in a pan lined with wet paper towelling prior to transport back to the Ploidy analysis.-In order to determine the ratios of: 1) A. laterale: hybrids; 2) male: female A. laterale; 3) males: total females (hybrids + A. laterale) and; 4) 2n:3n:4n hybrids, we initially separated A. laterale from putative hybrids based on visually evaluated morphological criteria, so FCM would also test the reliability of subjective field distinctions. When absolute size could not be used (A. laterale <80.0 mm SVL; Appendix 2, Lowcock, 1986), separation was primarily based on: 1) dorsal and ventral background color (lighter in hybrids; Clanton, 1934); 2) head shape and width at the angle of the jaw (wider in hybrids relative to SVL; Lowcock, 1986); and 3) IND (A. laterale, 2.5-3.9 mm, : = 3.25; syntopic hybrids, 3.3-4.7 mm, R = 4.10; Appendix 2, Lowcock, 1986). Ploidy classes within the unisexual segment of other hybrid complexes of Ambystoma cannot be reliably determined through morphological inspection (Zeyl and 90 COPEIA, 1991, NO. 1 1. TABLE RESULTS OF TEST CROSSES BETWEEN cipitation type) were recorded during sample collection. These were coupled with regional data obtained from Atmospheric Environment Services (Environment Canada) weather monitoring stations at closest proximity to each site. FEMALES AND MALE Ambystomalaterale FROM HBP WHICH WERE PROCESSED FOR BLOOD. VARIOUS Female Eggs laid Fertilized Viable to hatching % Successa A. laterale A. laterale 153 212 134 189 116 154 87.5/86.6 89.2/81.4 LLJb 167 130 102c LLJ LLLJ 143 84 140 47 98c 17c 77.8/78.5 97.9/70.0 56.0/36.2 SFertilization/hatching; survival unknown. b i.e., A. (2)laterale-jeffersonianum; nomenclature of Lowcock et al. (1987). c Many abnormal larvae, survival rates likely low. Lowcock, 1989), so this was not attempted. Males were readily identified by a laterally compressed tail, squarish snout and conspicuously swollen cloacal area. To determine nuclear DNA content of erythrocytes, we followed the FCM staining procedures of Dawley and Goddard (1988), substituting propidium iodide (PI; fluoresces over a broad spectrum, but not UV) for diamidino-2phenylindole (DAPI; fluoresces in the UV) as the nuclear stain. We used an argon-laser EPICS V Flow Cytometer (Coulter Electronics, Hialeah, FL) to excite PI at 488 nm with 500 mw of power, and collected red fluorescent wavelengths above the limit established by a 595 X interference filter. For each sample, 100020,000 nuclei were examined and histograms were accumulated by the MDADS computer system (Coulter Electronics). Nuclear DNA content of samples in each FCM run were determined based on comparisons to a known diploid sample of A. laterale. Environmentalparameters.--Air and water temperatures, as well as other general and local conditions (ice cover, elevation, latitude, preTABLE 2. COMPARISONS OF DATE Site Coboconk (CP) Oro Pond (OP) Haliburton(HBP) Fort Irwin (FIP) Algonquin Lowlands(AL) Algonquin Highlands (AHP) Statistics.-To test for independence of breeding waves to relative frequencies of sexes and ploidies, chi-square (x2) and G-tests (Sokal and Rohlf, 1981) were conducted on the daily data from HBP. In these tests, we include only data from the 8 d on which significant migration occurred individuals) and for which we (>-40 ploidy ratios by FCM (4-8, 12had determined 14 April). RESULTS Salamanders recovered from anesthesia within one-half h and did not appear to suffer illeffects from toe-clips; post-breeding individuals with toe-clips were captured leaving HBP and were frequently encountered in the area in summer and autumn of 1988. Test matings involving male A. laterale and female A. laterale or hybrids demonstrated that processing was not traumatic to breeding behavior or ability. All test matings produced viable (fertilized) eggs within 24 h. Hatching success of eggs laid by female A. laterale or hybrids were concordant with expectations based on previous reports (Uzzell, 1964; Weller, 1980) and our own field observations (Table 1). Breeding timing.-Date of first breeding varied between sites and was positively correlated with both latitude and altitude (Table 2). Most breeding migrations coincided with significant daytime or overnight rainfall. Although evening migrations continued when rain turned to snow after nightfall (HBP, AHP, AL, FIP), large OF FIRST SIGNIFICANT BREEDING, TIONS AT SIX CENTRAL ONTARIO Altitude (m) Lat(N)/Long(W) Date 274.3 283.5 335.3 365.8 396.2 472.4 44.39/78.48 44.44/78.56 45.00/78.30 45.15/78.20 45.45/78.20 45.35/78.40 3 April 3 April 3 April 14 April 23 April 28 April In 24 h period prior to evening migration. PHYSICAL AND ENVIRONMENTAL CONDI- SITES. Snow cover 90% 75% 80% Ice cover 10% 95% 5% 95% Precipitation" (mm) Temperaturea (min/max C) 8.4 8.4 11.0 12.4 24.8 9.6 6/12 6/12 -2/12 4/8 -6/7 3/9 LOWCOCK ET AL.-PLOIDY migrations were not initiated when daytime precipitation was snow; diurnal snow is typically associated with unfavorable temperatures. At HBP, immigration began on the evening of 3 April and continued until the morning of 28 April. Peak immigrations occurred in distinct waves coinciding with optimal conditions of temperature and moisture (4, 7, 13-14, 18, 24 April), and were typically followed by "stragglers" (frequently abundant) that arrived during non-optimal conditions (5-6, 8-9, 15, 21, 25-28 April) (Fig. 2). On 11-12 April, immigration initiated under apparently non-optimal parameters was correlated with other factors. Immigration was halted by inclement weather on four occasions, and did not resume until weather patterns had meliorated. Both sexes and the locally commonest hybrid ploidy levels were represented during the first wave of immigration at all sites. Thus, first immigrations may be reliable indicators of local primary composition of biotypes. This was true at HBP where ploidy ratios on day 1 were concordant with overall primary composition, but not exact frequencies; there are generally more male A. laterale in early migrations, and proportions of unisexuals can increase through time within waves. Because ploidy ratio within hybrids on day 1 (and wave 1 in general) varied significantly from that of subsequent waves (Table 3), hybrid ploidy ratios could only be roughly estimated for the latest immigration dates at HBP, in which hybrids were counted but not differentiated with respect to ploidy. Ploidy structure.--A total of 1119 salamanders were collected and examined. Of these, 1025 individuals were screened for ploidy; the remaining 94 were late immigrants at HBP (1527 April) and could be classified unambiguously only with respect to sex and hybridity. Hybrid ploidy ratios were roughly estimated in HBP samples collected after 14 April (Fig. 2) based on results from the 710 individuals collected prior to this date; we observed that the percentage of tetraploids remained identical through waves 2-3, which accounted for 65% of the population (migrations after 14 April accounted for only 8.6%). These estimates are for comparative purposes only and are not necessarily reliable extrapolations of trajectories in late-immigrant ploidy ratios, which may have increased or decreased. Results of FCM were unambiguous, demonstrating that all populations contained diploid IN HYBRID AMBYSTOMA TABLE 3. 91 PLOIDY RATIOS OF HYBRIDS IN FIRST THREE IMMIGRATION Migration day (n > 20) WAVES AT HBP. % 4n Approximate ratio 3n:4n 1 (4 April) 2 (5 April) 3 (6 April) Wave 1 total 8.8 8.0 2.1 6.7 10:1 12:1 47:1 14:1 4 (7 April) 5 (8 April) Wave 2 total 12.7 15.7 13.4 7:1 5:1 6:1 6 (12 April) 7 (13 April) 8 (14 April) 9 (15 April)a Wave 3 total 14.7 13.4 12.7 13.4 13.2 6:1 6:1 7:1 8:1 7:1 Overall total, waves 1-3 12.3 8:1 * Estimated based on within-wave data previous to this date. A. laterale as well as a variable potential mixture of; 1) 2n, 3n, 4n, and 5n female hybrids; and 2) rare male hybrids and/or polyploid A. laterale (Fig. 3). Successive ploidy levels above 2n showed characteristic increases of DNA corresponding to the addition of a full haploid set of chromosomes: erythrocyte nuclei contained exactly 1.5 x the DNA content of a diploid, 4n nuclei contained 2 x the diploid amount and 5n nuclei 2.5 x (Fig. 4). The distribution of ploidy classes in our samples are compared in Figure 3 and detailed in Table 4 (AHP, AL, CP, OP, FIP) and Table 5 (HBP). Aneuploidy was not indicated and ploidy mosaics were not encountered. A priori assignment of individuals to either A. laterale or the A. laterale-jeffersonianumhybrid category was compared with FCM results (Table 6) and found to be exceptionally accurate. Unless specifically noted, hybrids were initially assumed to be of 3n or higher ploidy. Based on this, overall prediction accuracy with respect to hybridity was 99.98% (range 99.6-100%). An individual from OP classified a priori as hybrid, but which had a ploidy determination of 2n (therefore "misclassified" under our assumption), was reevaluated on morphological grounds. This animal was clearly a hybrid based on size alone (>85.0 mm SVL). A second individual from OP was originally classified as a diploid hybrid, the sole exception to our ploidy assumption for hybrids, and was confirmed by FCM. Three polyploid females originally classed COPEIA, 1991, NO. 1 92 20- A HM precipitation 15- RS ERS E10-H RS S 5 L MMIL L S B - RS R IRS R S S S R R R R 1 O 0.1 water -- temp..,--•./.- 04 0 20C air temp. O15- max 010 a min(HBP) 5 ,--"min 0- 250 D-8 S5n 200 a ploidy a composition other -34n S150 E -2n S2n 100 male S3n E _ 509 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 April days Fig. 2. A comparisonof environmental parameters,numbers of migrants and daily ploidy composition during the breeding regime at HBP. All X-axes are April days. From the top of the figure: A) precipitation amount and type (AES data, Environment Canada plus our own local observations),R = rain, H = heavy rain, L = light rain, M = mist, S = snow. B) Comparisonof water temperature (left Y-axis)to percent ice cover (right Y-axis).C) Maximumand minimum daily air temperaturesderived by averaging temperatures from three AES monitoring stations within 10 km of the site. Minimumlocal temperature, as measured at the site (1 m above ground) is comparedto the area minimumin order to show meliorations.D) Comparison of daily ploidy composition and numbersof immigrantsduring the breeding regime. as A. laterale may be 3n or 4n forms of this species. Measurements of these specimens do not unambiguously support this conclusion, as they fall within the range of overlap between this species and co-occurring unisexuals (Lowcock, 1986). A single 3n male hybrid from HBP was correctly classified on initial examination in the field. LOWCOCK ET AL.-PLOIDY COB and altitude Increasing HBP ORO 93 latitude FI 5n 2n Hybrid IN HYBRID AMBYSTOMA AL AH 9 3ncid / / Other 4n 3n 2nY LLi Day 14 Cumulative Fig. 3. Relative sex and ploidy composition of Day 1 breeding cohorts examined in central Ontario. Site abbreviationsas in text. At HBP, the Day 1 (4 April) total is compared to the cumulativetotal (4-28 April). Absolute values are listed in Tables 4-5. BREEDING DYNAMICS AT HBP Ambystoma laterale (diploids) vs polyploid hybrids.--Significant differences in the ratios of diploid to polyploid individuals were observed among the four waves (x2, 3 df = 16.65, P = 0.001; G, 3 df = 7.81). This is attributable to a very high percentage of polyploid individuals in the second wave (91.3%). The remaining waves had percentages close to 80 (Table 7). Male A. laterale vs female A. laterale.-No dependence was observed between waves and sex ratios for diploid individuals (x2, 3 df = 2.12, P = 0.549; G, 3 df = 1.60). Male A. laterale vsfemales (all ploidies).-No dependence between sex and wave was observed for the population as a whole (x2, 3 df = 3.96, P = 0.266; G, 3 df = 5.8). Triploidvs tetraploidfemales.-Only the first three waves were included in this test because hybrid ploidies were not determined for the final wave. Slight significance was observed (x2, 2 df = 5.684, P = 0.058; G, 2 df = 6.20). This is attributable to the higher proportion of triploids in the first wave (93.3%). Second and third wave polyploids were 86.5% and 86.1% triploid, respectively. Comparisons among individual days within waves (waves 1-3) indicated some intra-wave heterogeneity of sex and ploidy composition. Percentages of sexes and ploidies, and relevent G-scores are provided in Table 7. Ambystoma laterale (diploids) vs polyploid hybrids.-Although significant variation in the ratios of diploids to polyploid hybrids was observed among waves, within waves the ratios did not not vary significantly. 94 COPEIA, 1991, NO. 1 20k 2n () o "- 4n 10k 5n E D 0 76 149 114 188 250 of fluorescence Intensity lateraleand 3n, of nuclear DNA content for 2n Ambystoma 4. measurements Separateflow-cytometric Fig. 4n and 5n hybrid biotypes of A. laterale-jeffersonianum depicted by an overlay of single parameterhistograms representingthe integral of red fluorescence. Channel numbers on the X-axis correspondto the position of the peak for each histogram. Male A. laterale vsfemale A. laterale.-Significant differences in diploid male:female ratios did not occur among days of the first wave, but within the second and third waves the percentage of diploid females increased significantly with passing days, reaching 100% in the final day of each wave. Male A. laterale vs females (all ploidies).-No significant variation was found in the overall male : female ratio among days of the first wave. However, within the second and third waves a significant increase in the numbers of females across days was observed. there Triploid vs tetraploidfemales.-Although was significant variation in the relative numbers of triploid and tetraploid females across waves, TABLE 4. DISTRIBUTION within waves significant changes in the composition of polyploids did not occur. DISCUSSION Ploidy levels and ratios.-The ratio of A. laterale to hybrids varied between samples but was consistent with the range of variation previously reported for the A. laterale-jeffersonianumcomplex (Clanton, 1934; Uzzell, 1964; Lowcock, 1989). Unisexual hybrids, dominated by triploids (LLJ; where L = one genome of A. laterale and J = one genome of A. jeffersonianum), greatly outnumber diploid bisexuals, except in the periphery of the complex, where the extent of unisexuality fluctuates widely between populations. Diploid bisexuals eventually predominate near the distributional limits of hybrid biotypes OF SEX AND PLOIDY CLASSES IN FIRST IMMIGRATIONS SITES AS DETERMINED A. laterale Site n CP OP FIP AL AHP 95 74 50 54 42 a m" 11.6/61.1 12.2/45.0 14.0/70.0 18.5/27.7 14.2/25.0 ONTARIO Hybridsc f 7.4/38.9/8.3 14.9/55.0/16.9 6.0/30.0/6.9 48.1/72.3/59.1 42.9/75.0/50.0 Percent of sample/% of A. laterale. b Percent of sample/% of A. laterale/% of females. c Percent of sample/% of hybrids/% of females. AT FIVE CENTRAL BY FLOW CYTOMETRY. 2n 2.7/3.7/3.1 - - 3n 78.9/97.4/89.2 70.0/96.3/80.0 80.0/100/93.1 29.6/88.9/36.4 42.9/100/50.0 4n 2.1/2.6/2.4 - 3.8/11.1/4.5 LOWCOCKET AL.-PLOIDY IN HYBRID AMBYSTOMA TABLE 5. DISTRIBUTION OF SEX AND PLOIDY CLASSESIN DAILY IMMIGRATIONSAT HBP IN 1988 As DETERMINED BY FLOW CYTOMETRY(4-14 APRIL) AND A PRIORI ASSIGNMENT (15-28 APRIL). A. laterale Date n 4* 96 5* 62 6* 55 7* 225 8* 61 Hybrids" ma fa 6.3/37.5 10.4/62.5/11.1b 76.00/91.3/81.1 12.9/66.7/13.8b 74.2/92.0/79.3 (n = 6) (n = 10) 6.5/33.3 (n = 4) 3n (n = 73) 4n (n = 7) 6.5/8.0/6.9 (n = 8) (n = 46) (n = 4) 9.1/71.4 3.6/28.6/4.0 85.5/97.9/94.0 1.8/2.1/2.0 (n = 5) 4.0/42.9 (n = 9) (n = 2) 5.3/57.1/5.6 (n = 12) (n = 47) 78.7/86.8/81.9 (n = 177) (n = 1) 11.6/12.7/12.0 (n = 26) - 6.6/100/6.6 77.0/82.5/77.0 14.8/15.7/14.8 (n = 4) - (n = 47) 100 (n = 9) - 1 - 11 6 50.0/75.0 16.7/25.0/33.3 16.7/50.0/33.3 (n = 3) 16.6/50.0/33.3 (n = 1) (n = 1) (n = 1) 65.9/85.3/76.3 11.4/14.7/13.2 44 13.6/60.0 13* 85 14* 75 4-14 710 9.1/40.0/10.5 (n = 4) (n = 6) 7.1/33.3 14.1/66.7/15.2 (n = 29) (n = 5) 68.2/86.6/73.4 10.6/13.4/11.4 (n = 6) (n = 12) (n = 58) (n = 9) 1.3/8.3 14.7/96.7/15.1 72.0/85.7/74.0 10.7/12.7/10.9 (n = 1) (n = 11) (n = 54) (n = 8) 9.0/61.5/9.6 (n = 64) 75.1/88.0/79.7 (n = 533) 9.9/11.6/10.5 (n = 70) 5.6/38.5 (n = 40) Other 7.3/8.8/7.7 9 12* 95 0.44/0.49/0.46c (n = 1) 1.6/1.8/1.6c (n = 1) - 1.3/1.6/NAd (n = 1) 0.28/0.33/0.30c (n = 2) 0.14/0.16/NAd (n = 1) 14.6 (n = 104) % of population by category m 15* 18* 25 45 21 5 24 12 25 26 27 28 2 1 1 3 4-28 f 804 % of population by category 6.7/30.0 Undifferentiated hybrids' 47.1/100/47.1 52.9/52.9 (n = 8) (n = 17;2D 15.5/70.0/16.7 77.8/83.3 (n = 3) (n = 7) (n = 35;4) - 20.0/100/20.0 (n = 1) 25.0/100/25.0 80.0/80.0 (n = 4) 75.0/75.0 (n = 3) 100 - (n = 9;19 100 100 - - 5.3/33.9 (n = 43) 10.4/66.1/11.1 (n = 84) 15.7 (n = 127) * Significant migrations (n > 20). Percentages arranged as in Table 4. b Includes one polyploid female (LLL or LLLL). c 5n female. d 3n male. e Percent of sample/% of females. I Estimated number of 4n females in sample. a 85.4 (n = 606) 100 84.3/100/88.9 (n = 677) 84.3 (n = 677) 96 TABLE COPEIA, 1991, NO. 1 6. PERCENT ACCURACY PREDICTION OF A PRIORI ASSIGNMENTS ON RESULTS n Site Initial WITH RESPECT TO HYBRIDITY CP OP 74 98.6 50 54 42 710 100 100 100 99.6 3 2n laterale/2 x 3n; 1 x 4n 98.6-100 ( = 99.7) 1 polyploid hybrid and 2n hybrid 3 2n laterale unknown FIP AL AHP HBP Overall (n = 1025) Final Reevaluated Misclassified/determineda - 95 100 BASED OF FLOW CYTOMETRY. 100 1 polyploid hybrid/2n 2n hybridb 100 3n/4n laterale?c 100 100 100 99.6 99.6-100 ( = 99.98) a Our classification/ploidy determination by flow cytometry. b Hybrid by morphology, misclassified because all hybrids were assumed to be polyploid. c Could not be classified unambiguously as A. laterale. (Lowcock, 1989). This is exemplified in our study by the two most northern samples (AL, AHP), which are close to these limits, and show a significantly higher proportion of diploid bisexuals in initial breeding waves (Fig. 3). Based on data from HBP, we would expect these ratios to hold over the course of the breeding season. To what extent distributional limits of hybrid biotypes are governed by geological, ecological, historical or physiological factors is unknown. Although cytogenetic tendencies within populations may play a limited role, it has been arTABLE 7. PERCENT COMPOSITION gued that several of the former variables, and their inherent interactions, form the major components of limitation (Lowcock, 1989). First immigration results for AL and AHP could be interpreted as artifactual if diploid bisexuals breed much earlier than unisexuals in northern areas. However, such a regimen would serve only to lower the likelihood of a unisexual being mated, ultimately providing another mechanism by which increases in the unisexual component of a population could be intrinsically controlled, resulting in the same relative OF DIPLOID AND POLYPLOID FEMALES AT HBP, BY DAY AND BY MIGRATION WAVE.Numbers in parentheses indicate sample sizes. Day Percent polyploid of population Wave G-score/df 1 1 2 0.96/2 0.52/1 83.3 (96) 90.7 (225) 80.7 (62) 93.4 (61) 87.3 (55) - 3 2.92/3 77.3 (25) 78.8 (44) 84.0 (85) 4 Percent female of diploids Percent female of population Percent triploid of polyploids - 1 2 3 4 12.82/3b - 1 2 3 4 1 2 3 2 77.8 (45) 62.5 (16) 57.1 (21) 40.0(10) 66.7 (9) 66.7 (12) 100.0 (4) 66.7 (18) - 4.40/1b 8.38/3b - 93.8 96.0 86.4 93.2 (96) (225) (25) (43) 93.6 (62) 100.0 (61) 92.9 (44) 2.84/2 0.40/1 0.10/2 91.3 (80) 87.2 (203) 85.3 (34) 92.0 (50) 83.9 (56) 86.5 (67) 3.04/2 3.98/1b 0.48/2 2 Significant differences in percent among waves. b Significant differences in percent within waves. - 3 -28.6 (7) - 4 - 68.0 (75) - Total for wave 83.6 (213)a 91.3 (286) 79.0 (229) 77.8 (45) 91.7(12) - 100.0 (8) - 57.1 64.0 72.9 66.7 (35) (25) (48) (9) 90.0 (55) 97.3 (85) - 100.0 (75) - 93.0 96.9 93.9 93.2 (213) (286) (229) (43) 97.9 (48) 87.1 (62) - 93.0 (213)a 86.5 (259) 86.1 (163) LOWCOCK ET AL.-PLOIDY counterbalance of diploid bisexuals that were observed. Variable ploidy in unisexual A. laterale-jeffersonianum has only been considered recently (Sessions, 1982; Bogart, 1982, 1989) and its extent has not been quantified. Our results show that the most common deviation from triploidy in central Ontario hybrids is an elevation to the tetraploid state (LLLJ). Tetraploids were found at three of six sites, and probably occur at lower frequencies in the others. The typical route to tetraploidy in hybrid Ambystomais fertilization of an unreduced triploid egg (Bogart and Licht, 1986; Bogart et al., 1987). Thus, when hybrids enter a population, the initial preponderance of tetraploidy likely reflects the interaction of: 1) the frequency at which unreduced eggs are produced by triploids; and 2) the probability of fertilization. Once the breeding aggregation includes tetraploid females, the recruitment dynamic of these forms will change depending on what type of eggs/offspring they produce. Because the known progeny of allotetraploid females of the analagous A. laterale-texanumcomplex are triploid and tetraploid (Bogart and Licht, 1986; Bogart et al., 1987), this is likely also true of the A. laterale-jeffersonianumcomplex. Thus, under certain circumstances, tetraploid genotypes may accumulate in a population. Bogart et al. (1989) recently found that the temperature at which eggs are exposed to sperm dictates the relative frequency of gynogenetic, hybridogenetic and ploidy-elevated offspring produced by a particular female. This seriously confounds the issue, e.g., conditions favorable to the de novo synthesis of tetraploids from triploid eggs may not be the same as those conducive to gynogenetic activation of unreduced tetraploid eggs. The situation begs greater scrutiny, because other important considerations, such as reproductive viability of females and tetraploid potential ecological role for tetraploid biotypes, are not understood. Tetraploids produce at least some viable unreduced ova, as evidenced by the low frequency of pentaploid female hybrids (LLLLJ) at HBP. Pentaploidy was not anticipated because: 1) it has not been revealed in previous genetic studies of hybrid complexes of Ambystoma;2) mortality of 3n and 4n eggs and larvae is exceedingly high (Bogart et al., 1987; Licht and Bogart, 1987; Licht, 1989); 3) in autopolyploid Ambystoma, fecundity decreases as ploidy increases (Humphrey and Fankhauser, 1956); and 4) potential tetraploid progenitors typically repre- IN HYBRID AMBYSTOMA 97 sent a low percentage of hybrids (Bogart, 1989; Bogart et al., 1985, 1987). This first recorded instance of naturally occurring pentaploid vertebrates is important from two standpoints. First, all experimentally induced and lab-raised pentaploid urodeles have been autopolyploids of greatly reduced viability, suffering severe developmental, physiological and behavioral debilities that precluded the attainment of sexual maturity (Fankhauser, 1945; Fankhauser and Humphrey, 1950). Haliburton Beaver Pond pentaploids were clearly hybrids, visibly swollen with eggs, some of which were ovulated, had no noticeable deformities, and possessed body sizes indicating ages of 3 yr or more. Thus, compared to autopentaploids, these allopentaploid salamanders demonstrate an enhanced tolerance of multiple chromosome sets. Secondly, autopentaploids were commonly generated by fertilization of a tetraploid egg produced by a diploid parent (suppression of both meiotic divisions; Fankhauser, 1945). Our pentaploids could not have been produced via this route; HBP pentaploids are hybrids, and potential progenitors (diploid hybrid genotypes) do not occur here. Pentaploid A. lateralejeffersonianum at HBP are presumably generated by the fertilization of an unreduced tetraploid ovum produced by a hybrid tetraploid female, in analogy to the production of tetraploids by triploids. Test matings between HBP tetraploids and male A. texanum yielded numerous pentaploids, confirming the scenario of origin for pentaploid biotypes at HBP (J. P. Bogart, pers. comm.). It may be assumed, as with triploids and tetraploids, that there is a greatly reduced viability of pentaploid embryos and larvae, and that those surviving to adulthood are a highly selected fraction of those produced. Thus, the rarity of pentaploids at HBP is in accordance with the proportion of available tetraploid progenitors. Based on this, the apparent scarcity of tetraploid biotypes in other populations lessens the probability of pentaploids occurring there. Potential production of pentaploids by the union of polyploid sperm with polyploid eggs cannot be ruled out. The most likely source of such sperm, however, is triploid males, which are rare and of unknown viability. Diploid hybrids (LJ) are perhaps our most perplexing finding with regards to hybridity. These biotypes were recorded only at OP, where they have been reported previously (Lowcock, 1989). If present at other sites, the frequency 98 COPEIA, 1991, NO. 1 must be extremely low. The large sample from HBP indicates diploid hybrids do not occur there at all. Diploid hybrid A. laterale-jeffersonianum are known from active zones of hybridization in Ontario and New England (Bogart, 1989; Lowcock, 1989), where the opportunity for de novo synthesis exists because of the presence of both parental bisexuals. The origin and status of diploid hybrids outside hybrid zones is currently unknown. It is typically assumed that diploid hybrid female Ambystomaproduce unreduced diploid eggs, giving rise to triploids through backcrosses to males of either parental species. Under this assumption, diploid hybrids are not self-perpetuating unless their unreduced eggs are activated gynogenetically, a possibility that is unresolved. If LJ hybrids at OP produce some meiotically reduced eggs, in addition to unreduced hybrid ova, then they could give rise to three types of progeny through syngamy with L sperm: LL, LJ and LLJ. It is also possible to generate a diploid hybrid from a triploid, either by syngamy of L sperm with a rare haploid J egg, or the gynogenetic activation of a diploid hybrid meiotic product. Reduction mechanisms for producing diploids from triploids have been speculated elsewhere (Sessions, 1982; Bogart, 1989; Lowcock, 1989) but remain unsubstantiated. If J eggs are occasionally produced by triploids, and assuming equal frequency and viability of the reciprocal meiotic product (i.e., LL), we would also expect to find some incidence of triploid A. laterale (LLL) in the population. These biotypes did not occur at OP, but may have been present at HBP, along with autotetraploids (LLLL); three females classified originally as diploid A. laterale on morphological grounds were shown to be polyploid by FCM (Table 6). This is not unusual, as triploid A. texanum and A. laterale have been encountered in A. laterale-texanum complex populations on Pelee Island (Bogart and Licht, 1986; Licht, 1989; Sever et al., 1989). Despite this potential connection, mutual exclusion of LJ and LLL biotypes at OP and HBP suggests that these forms may also be generated autonomously. Erroneous a priori classification of the individuals at HBP is possible, but seems unlikely given prediction accuracies (Table 6). Triploid males have been reported on several occasions, and appear to be a cosmopolitan, but rare, feature of hybrid complexes of Ambystoma (Clanton, 1934; Servage, 1979; Morris and Brandon, 1984). Clanton (1934) reported three out of 1300 individuals examined (0.23%), and the single individual in our study represented 0.14% of the population and 0.16% of hybrids at HBP (Table 5). Morris and Brandon (1984) reported an individual that was sterile, but it may have been a trihybrid (A. laterale-jeffersonianum-texanum)and/or a tetraploid. It is unlikely that complete sterility is universal in these forms (Fankhauser, 1945). Sperm smears from testes of A. laterale-jeffersonianum complex triploid males showed active, though occasionally deformed sperm (pers. obs. with J. P. Bogart). Potential partial viability notwithstanding, the rarity of triploid males precludes any meaningful contribution to the population, although test matings should be conducted to evaluate reproductive capacities. Sex ratio.-Overall sex ratios show males to be a predictably limited resource (Tables 4-5, 8). Males in first day immigrations comprised an average of 12.8% of migrants, and were most plentiful in populations with high ratios of diploids (AL, AHP). At HBP, where males were most scarce, the figure fell from an initial 6.3% to 5.3% over the entire breeding period (Table 5). This is expected given the breeding dynamic of Ambystoma(see below). Corresponding total (A. laterale plus polyploid) female: male sex ratios were congruent with previous reports obtained under controlled (i.e., fenced) conditions (Table 8). Estimates prior to Uzzell (1964) are difficult to reconcile with these observations, and are suspect in that they represent variable samples combined over periods of up to 5 yr, some of which: 1) contain numerous newly transformed individuals (in which sex determination is tenuous); 2) were generated from unfenced or inadequately fenced ponds; or 3) were not inventoried daily from the first day of immigration. In general, our figures, and those reported by Uzzell (1964), Wilbur (1971) and Weller (1980), show the male component of A. lateralejeffersonianum complex populations in Ontario and southern Michigan to be greater than that in the A. laterale-texanum complex. Bogart and Licht (1986) and Licht (1989) found 5.6% males in their randomly collected cumulative samples from Pelee Island. Aside from potential collection artifact, the situation is confounded on Pelee (an active hybrid zone) by the presence of A. laterale, A. texanum and diploid male A. laterale-texanum, in addition to a large component of diploid hybrid females. Diploid male A. laterale-jeffersonianumare known from in and around LOWCOCK ET AL.-PLOIDY TABLE 8. IN HYBRID AMBYSTOMA 99 COMPARISON BETWEENSEX AND PLOIDY RATIOS IN THE Ambystomalaterale-jeffersonianumCOMPLEX AS REPORTED Ploidy ratioa 3.75 1.56 3.21/6.07 18.00 11.00 4.90 13.33 0.69 1.00 8.06 4.69 IN THE LITERATURE AND AS DETERMINED Sex ratiob Mean ratio (Weller) Actual ratioe Reference Population is LL/LLJ based 3.28 6.71/14.16 8.40 7.63 7.22 6.14 4.40 6.00 17.69 6.23 7.00 3.59 13.00 2.14 51.25 52.00 Population is JJ/JJL based 8.00 73.00 76.80/100 16.33 17.00 11.37 9.06* 7.66* 23.00 15.03 13.62 13.67 12.66 BY THIS STUDY. Uzzell (1964) Wilbur (1971) Wilbur (1971)c Wilbur (1971) this study (CP) this study (OP) this study (FIP) this study (AL) this study (AHP) this study (HBP) Wilbur (1971) Uzzell (1964) Uzzell (1964) Uzzell (1964) Clanton (1934) Clanton (1934) Clanton (1934) Bishop (1941) Peckhamand Dineen (1955) Wacasey(1961)c Weller (1980) Weller (1980) Weller (1980)d 1973; Weller (1980) 1974; Weller (1980) 1975; Weller (1980) 1976; Weller (1980) 1977; Weller (1980) 1973-77 females: non-hybrid females. bSHybrid Total females: males. c One population in two separate years. d Cumulative data in a 5 yr study; the ploidy ratio is from a sample collected randomly over this period. A breakdown of Weller's data (below solid line) yields slightly different figures than his own total. Weller suggests that the data from 1973-74 (*) may not be reliable due to sampling problems (e.g., dipnetting, partial fencing, mistiming). LOur calculation using total number of individuals in Weller (1980). active hybrid zones of that complex in southern Ontario and New England (Bogart, 1989), but reproductive capacities and contributions of these biotypes to their respective local populations have not been studied. Whether a lower percentage of males on Pelee Island is an artifact of random collection in and around breeding ponds, or is directly related to the inherent genotypic structure and reproductive dynamics of the A. laterale-texanumcomplex, is unknown. Cryptic behavior by breeding A. laterale-texanum complex males, and difficult collecting con- ditions in breeding ponds, have been cited as factors in biased samples (Bogart and Licht, 1986; Bogart et al., 1987). Uncontrolled sampling (in or outside of the breeding season) in these complexes can result in samples which are biased in favor of unisexuals (e.g., Uzzell, 1964; Downs, 1978; Kraus, 1985a, 1985b; and pers. obs. of collections at the University of Guelph [Guelph, Ontario], Royal Ontario Museum [Toronto, Ontario], and National Museum of Natural Sciences [Ottawa, Ontario]). Considering bisexual-unisexual population structure, and if 100 COPEIA, 1991, NO. 1 all parameters of ecological distribution are equal, the probability of encountering unisexuals in the field can be an order of magnitude higher than that for diploid bisexuals. However, ecological partitioning of biotypes is apparently operative in some hybrid complexes (Bogart et al., 1987), and this could greatly affect encounter probabilities. The geographically variable male component will influence local evolutionary trajectories within hybrid complexes via reproductive output, especially if fluctuating ecological factors affect male recruitment temporally. In this context of intrinsic determinism, no perspective can be gained unless sex ratios within A. laterale are examined as a subset of the total female: male sex ratio in populations. Our results unexpectedly show that this relationship may also vary geographically (Table 4; Fig. 3). In three populations (AL, AHP, HBP), ratios differ significantly from the expected 1:1 (P < 0.001; X2 goodness of fit tests). In each case, this is due to a much higher proportion of female A. laterale. This is confounding from several standpoints. First, although they may fluctuate from year to year, sex ratios in other pond-breeding species of Ambystomatypically show an overwhelming bias in favor of males (Shoop, 1960; Semlitsch, 1983; Sexton et al., 1986). This is also true for populations of A. laterale (Cook, 1967; Gilhen, 1984; Lowcock, 1986) and A. jeffersonianum (Uzzell, 1964; Douglas, 1979; Weller, 1980) that occur outside of the range of hybrid biotypes. Skewed breeding sex ratios in favor of male Ambystomahave been attributed to: 1) differential mortality between sexes (higher male survival; Husting, 1965; Whitford and Vinegar, 1966); 2) failure of females to breed in consecutive years (Husting, 1965); or 3) delayed maturation of females (Wacasey, 1961; Weller, 1980; Philips and Sexton, 1989). It seems reasonable that the latter point may also be considered in the context of selection for precocious maturation of males. Skewed diploid sex ratios favoring females within hybrid complex populations could be related to forces other than those outlined. Given their early breeding habits, higher male mortality is possible, but seems unlikely and has not been observed in the field. A higher proportion of diploid females breeding annually is possible, especially if many go unmated because of the large number of unisexuals; unmated diploid females would presumably resorb their eggs, not suffer the energetic costs of egg-laying, and be more likely to breed in consecutive years. In this case, we would expect populations containing low percentages of hybrids to show diploid sex ratios in breeding aggregations closer to equity or even biased towards males in early immigrations. We did not observe this, although it was reported by Clanton (1934) and fits with ratios reported by Cook and Gorham (1979), Gilhen (1984) and Lowcock (1986) for east-coast populations with few unisexuals. Lower proportions of males breeding in every year seems unlikely given the energy budget difference between sexes, i.e., there would certainly be no advantage to this. Indeed, despite the complex and irregular breeding schedule of individuals, Weller (1980) found that a greater proportion of male A. jeffersonianumbred annually over a 5 yr period in a hybrid complex population involving that species. Accelerated maturation of females and/or delayed maturation of males is the final possibility based on previous conjectures. There are no data available to support such a conclusion, and in fact, body size data of breeding adults at HBP argue for the opposite tenet, i.e., precocoius maturation of males. Cytogenetic factors contributing to higher proportions of diploid females may be more convincing. The most obvious is a higher overall production of female offspring by female A. laterale. Clanton (1934) states that although both sexes in adult A. laterale were "equally represented" in populations containing hybrids, 60% of progeny of diploid females were female. Uzzell (1964) presents similar data for juvenile A. jeffersonianum (53.6-66.7% female; 9 = 61.6%). If this varies among populations, it could explain our observation of higher numbers of females. A mechanism of meiotic drive involving sex chromosomes need be invoked to consider this possibility, and substantiation would require investigation at the cellular level. One can envision selection favoring enhanced production of diploid females in populations with hybrid biotypes. Because they are the only route to the production of males, these females serve to maintain the "precious" diploid component, which is the lynch-pin of bisexual-unisexual communities. The possibility that some diploid females are produced by unisexual hybrids has been alluded to (Bogart, 1980; Lowcock, 1989; Lowcock and Bogart, 1989), but appears to be an event of extremely low frequency. Such a conclusion, however, may be an artifact of those methods used to determine its occurrence; allo- LOWCOCKET AL.-PLOIDY IN HYBRID AMBYSTOMA zyme electrophoresis cannot demonstrate the production of diploids from unisexuals unless there has been introgression at marker loci from other species involved in the complex under consideration (Lowcock, 1989). It is apparent from other data presented here that such a mechanism would be variable in occurrence, frequency and success. The cytogenetic tendencies which have contributed to variable ploidy composition between populations may also be operative in this case. Because sex ratios in first day immigrants vary among populations, and are biased overwhelmingly towards females in only a few, such a mechanism seems likely. It is of interest to note that Bogart et al. (1987) reported a perfect 1:1 sex ratio for non-hybrids in the A. laterale-texanum-tigrinumcomplex on Kelleys Id., although the number of A. texanum examined was small. Finally, Beneski et al. (1986) counted up to seven times as many male emigrants as immigrants in their study of A. macrodactylum, concluding that they had missed a component of initial migration, despite fencing the pond before ice-off. It is unlikely that this occurred at HBP, where the male component was lowest; our fence was erected while the pond was frozen to the margins, with an average ice depth of 20 cm, snow cover of equal depth in the bush at 100%, and 80% on south-facing slopes. Males would have had to overwinter in the pond in order not to be inventoried. final considerBreeding dynamics at HBP.-A ation, which also bears on proportions of females in first day immigrations, is breeding dynamics. Onset and duration of migrations were directly related to environmental factors. Migratory movement was nocturnal and typically limited to periods preceded by (rain) or during (rain or snow) precipitation (Fig. 2). Wave 3 began on the evening of 11 April and built through the 12th, despite no precipitation on either day. These movements were triggered by a high humidity gradient near the ground surface at night, the result of localized evaporation/condensation caused by an ice-free pond and strong sunlight during the day. Migrations were often initiated despite partial snow cover in an area, indicating some animals were in a position to respond to environmental cues despite ground frost. It has been speculated (Weller, 1980) that the ground must be thawed before initiation of migration. Observations of syntopic A. maculatum and Notophthalmus viridescens showed they followed this pattern, 101 reaching peak immigration several days later than A. laterale-jeffersonianumcomplex individuals at northern sites, where ground frost and snow cover were extensive. Individuals of the A. laterale-jeffersonianum complex are extremely cold tolerant. They frequently migrated across large expanses of snow and ice and/or moved in great numbers at nearfreezing air temperatures into 1-3 C water. Individuals frozen in drop buckets with excess moisture could thaw and walk away. Those frozen in dry conditions dessicated rapidly and died, or suffered debilitating nerve damage, becoming partially incapacitated upon thawing. Ambystomalaterale, especially males, were more tolerant than hybrids. That immigration is readily initiated under such conditions, coupled with the subarctic range limits of this species, argues convincingly for an evolutionary history tied to a boreal or sub-boreal climatic regimen, possibly in association with the proglacial environments of an ice age. Pleistocene events have often been evoked for the splitting of A. laterale from its sister species A. jeffersonianum (Uzzell, 1964); however, Lowcock (1989) has presented genetic data that argues for a more distant split, perhaps associated with pre-Pleistocene ice ages. Greater tolerance of harsh conditions by male Ambystomaappears to be a general attribute of the genus. Males typically enter ponds earlier and leave later than females, remaining in the area up to twice as long as their female counterparts (Shoop, 1960; Weller, 1980; Sexton et al., 1986). This has been variously attributed to: 1) differential rate and/or distance of travel; 2) differential response to environmental cues; and 3) differential orientation ability. Philips and Sexton (1989) discounted the latter in their study of A. maculatum, but were unable to substantiate whether the first two were operative. Douglas (1979) maintained that the selective advantage of females lagging behind males is reduction of risk of environmental danger, particularly low temperatures, a selective force which would be exacerbated in the case at hand. Based on this, one can construct an idealized schemata for immigration/emigration in pondbreeding Ambystoma,altering it to reflect the observations made in those studies, i.e., that females are represented in early samples but that males, typically more abundant, reach peak proportion in the breeding population earlier than females (Fig. 5). Assuming this dynamic to be operative among diploid bisexuals within hybrid complex popu- COPEIA, 1991, NO. 1 102 100 A A Immigration 3n .. Emigration B 75 "C, 100 C t- 50-0 D o female 5n 3n male 50 25- 9 50-~ 4n , - 1 2 3 4 Diploid 5 6 7 8 immigration 9101112131415 days Fig. 5. Breeding dynamicsin pond-breedingAmbystoma.In each case, the X-axis is a time function. From the top of the figure: A) idealized breeding regimen for males and females based on the assumptions that 1) malesoutnumberfemales, 2) malesenter the pond earlier, stay longer and depart later than females,and 3) there are no extenuatingcircumstances that would meliorate the selective forces driving this system. B) Likely shape of immigrationcurves in reality. Curvesare normalizedto show relative numbers of each sex for ease of direct comparison.Males and females begin migrating at the same time, but more males immigrate early so that this sex reaches its peak first. Stars indicate expected onset of emigration for females (black)and males (white).C) Trajectories for cumulativetotals over time based on the curves in (B). Stars as in (B). D) Trajectories for cumulative totals of immigrants as measured at HBP showing conformity to model in (C). In this case the starsshow actual dates of commencementof emigration for each sex. 1 2345 00 6 7 8 9 10 a Days Fig. 6. Relative percentages of polyploid hybrids during significant migration-days(n > 20) at HBP (daysas in Table 3; Day 10 = 18 April). lations (Uzzell, 1964; Weller, 1980), we compared the data from HBP to such a regimen (Fig. 5). No clear linear relationships existed between proportions of sexes and breeding times; however, differential achievement of peak proportions by male and female A. laterale occurred; approx. 25% of females immigrated after the peak proportion of males (April 14). Major waves (2-3) appeared to comprise separate episodic breeding events; within a wave over time, generally showing a: 1) slow increase and rapid decrease of males; 2) rapid increase then rapid decrease in females; and 3) corresponding increase in proportions of polyploids (Fig. 2; Table 5). Hybrids may be slower to respond to environmental cues, though the increase in relative proportions of these forms is LOWCOCK ET AL.-PLOIDY most readily explained by the decrease in diploids. Assuming no mate discrimination by males, polyploids will theoretically do well in the competition for sperm due to sheer numbers, despite the fact that they reach peak proportions after all diploids within waves. For selection to favor hybrid biotypes, the majority would have to arrive within the period at which the male proportion of the population peaked. The two initial waves were characterized by higher proportions of hybrids, representing up to 96% of the female component on a given day (Table 5). Overall, ploidy ratios of hybrids did not vary significantly during the immigration period, showing only a modest increase in the tetraploid component over day 1 (Table 3; Fig. 3). During wave 2, however, a significant increase in the proportion of tetraploids occurred. The capture of pentaploid females was coincident with the increase in hybrid biotypes of elevated ploidy. This observation is problematic: are higher polyploids harder to stimulate into migration than triploids, or are they behaving like diploid females, to which they are more similar by virtue of extra genomes from A. laterale? From the onset of wave 2, polyploid ratios remained relatively constant (Fig. 6). The issue of whether hybrid biotypes arrive at ponds ahead of diploid females has not been studied.The possibility has been raised (Panek, 1978; Weller, 1980; Lowcock, 1986), and the available data are suggestive. The time necessary for the proportion of males and females arriving at the pond to approach equity is greater in pure populations (Douglas, 1979) than in mixed diploid/triploid aggregations (Weller, 1980). Thus, the abrogation in lag time may be caused by an influx of hybrid females. Unfortunately, previous data suffer from a lack of differentiation between ploidy levels (and hybridity) of females, and as such, are inconclusive. Results of this study, however, in which all females were distinguished with respect to hybridity, lends support to this interpretation. Conclusions.-Understanding of the evolution and ecology of bisexual-unisexual communities of vertebrates is greatly aided by non-destructive large-scale studies of composition and interaction. Such investigations can ultimately inform and be informed by the vast repository of genetic information available from these populations. Our several unexpected findings with regard to ploidy structure, sex ratio and breeding dynamics, suggest that in addition to pop- IN HYBRID AMBYSTOMA 103 ulation differences, these parameters may all vary temporally, and that long-term studies of breeding and transforming cohorts would be productive means of evaluation. What emerges from our study is clear evidence that unisexuals affect population structure and breeding dynamics in syntopic bisexuals. We would expect that this would obtain for other ecological considerations in these associations. ACKNOWLEDGMENTS We are grateful for the extensive field and laboratory assistance of C. Garland and M. Mosquito. A great debt of gratitude is extended to C. Smith, who operated the University of Toronto Department of Immunology flow cytometer for incalculable periods and at odd hours. We are indebted to R. M. Dawley for his help with FCM technique. R. Elinson and J. P. Bogart carried out the tetraploid-A. texanum cross. C. Rutland compiled the bibliography. The study was supported by Natural Sciences and Engineering Research Council of Canada grant A3148 to RWM, and some field work was supported by a Friends of Algonquin Park Research grant to LAL. LITERATURE CITED AUSTIN, N., AND J. P. BOGART. 1982. Erythrocyte area and ploidy determination in the salamanders of the Ambystoma jeffersonianumcomplex. Copeia 1982:485-488. BENESKI, J. T., JR., E.J. ZALISKOANDJ. H. LARSEN, JR. 1986. Demographyand migratorypatterns of the eastern long-toed salamander, Ambystomamacro- Ibid. 1986:398-408. dactylumcolumbianum. BOGART, J. P. 1980. Evolutionary implications of polyploidyin amphibiansand reptiles, p. 341-378. In: Polyploidy:biological relevance. W. H. Lewis (ed.). Plenum Publ. Corp., New York, New York. . 1982. Ploidyand genetic diversityin Ontario salamandersof the Ambystoma comjeffersonianum plex revealed through an electrophoretic examination of larvae. Can.J. Zool. 60:848-855. . 1989. A mechanism for interspecific gene -exchangevia all-femalesalamanderhybrids,p. 170179. In: The evolution and ecology of unisexual vertebrates.R. DawleyandJ. P. Bogart (eds.). New York State Museum Bulletin, 466 Albany, New York. --, R. P. ELINSON AND L. E. LICHT. 1989. Tem- peratureand sperm incorporationin polyploidsalamanders.Science 246:1032-1034. -, AND L. E. LICHT. 1986. Reproduction and the origin of polyploids in hybrid salamandersof 104 COPEIA, 1991, NO. 1 the genus Ambystoma.Can. J. Genet. Cytol. 28:605northwestern Ohio and southeastern Michigan: a 617. study of the consequences of hybridization. Copeia S , M. J. OLDHAMANDS.J. DARBYSHIRE. 1985:309-324. 1985. Electrophoretic identification of Ambystoma LICHT, L. E. 1989. Reproductive parameters of unilaterale and Ambystomatexanum as well as their dipsexual Ambystomaon Pelee Island, Ontario, p. 209loid and triploid interspecific hybrids (Amphibia: 217. In: The evolution and ecology of unisexual vertebrates. R. Dawley and J. P. Bogart (eds.). New Caudata) on Pelee Island, Ontario. Can.J. Zool. 63: 340-347. York State Museum Bulletin, 466, Albany, New L. A. LoWCOCK, C. W. ZEYLANDB. K. MABLE. York. -~, 1987. Genome constitution and reproductive bi, AND J. P. BOGART. 1987. Ploidy and develology of hybrid salamanders, genus Ambystoma,on opmental rate in a salamander hybrid complex (genus Ambystoma).Evolution 41:918-920. Kelleys Island in Lake Erie. Ibid. 65:2188-2201. W. 1934. An unusual situation in the sal- LOwcocK, L. A. 1986. Genetics, zoogeography, and CLANTON, amander Ambystomajeffersonianum (Green). Occ. Pap. morphological aspects of peripheral populations of Mus. Zoo. Univ. Michigan 290:1-14. the Ambystoma jeffersonianumcomplex. Unpubl. M.S. COOK,F. R. 1967. An analysis of the herpetofauna thesis, University of Guelph, Guelph, Ontario. of Prince Edward Island. Nat. Mus. Can. Bull. 212: . 1989. Recent and palaeobiogeography in hy1-60. brid complexes of Ambystoma:interpreting unisex, AND S. W. GORHAM.1979. The occurrence ual-bisexual data through time and space, p. 180of the triploid form in populations of the Blue209. In: The evolution and ecology of unisexual vertebrates. R. Dawley and J. P. Bogart (eds.). New spotted Salamander, Ambystoma laterale, in New Brunswick. J. New Brunswick Mus. 1979:154-161. York State Museum Bulletin, 466, Albany, New DAWLEY, R. M., ANDJ. P. BOGART (Eds.). 1989. EvoYork. lution and ecology of unisexual vertebrates. New , ANDJ. P. BOGART. 1989. Electrophoretic evYork State Museum Bulletin, 466, Albany, New idence for the multiple origins of triploidy in the York. Ambystomajeffersonianumcomplex. Can. J. Zool. 67: 1988. Diploid-triploid , AND K. GODDARD. 350-356. mosaics among unisexual hybrids of the minnows -, L. E. LICHTANDJ. P. BOGART. 1987. NoPhoxinus eos and Phoxinus neogaeus. Evolution 42: menclature in hybrid complexes of Ambystoma:no 649-659. case for the erection of hybrid "species." Syst. Zool. DOUGLAS,M. E. 1979. Migration and sexual selection 36:328-336. in Ambystomajeffersonianum.Can. J. Zool. 57:2303MORRIS,M. A., AND R. A. BRANDON. 1984. Gyno2310. genesis and hybridization between Ambystomaplatineum and Ambystomatexanum in Illinois. Copeia DowNs, F. L. 1978. Unisexual Ambystomafrom the Bass Islands of Lake Erie. Occ. Pap. Mus. Zoo. Univ. 1984:324-337. Michigan 685:1-36. PANEK,F. M. 1978. A developmental study of AmG. 1945. The effects of changes in FANKHAUSER, bystomajeffersonianum and A. platineum (Amphibia, chromosome number on amphibian development. Urodela, Ambystomatidae). J. Herp. 12:265-266. Quart. Rev. Biol. 20:20-78. PHILIPS, C. A., AND O.J. SEXTON. 1989. Orientation FANKHAUSER, G., AND R. R. HUMPHREY.1950. Chroand sexual differences during breeding migrations mosome number and development of progeny of of the spotted salamander Ambystomamaculatum. triploid axolotl females mated with diploid males. Copeia 1989:17-22. J. Exp. Zool. 115:207-250. SEMLITSCH, R. D. 1983. Structure and dynamics of GIBBONS, J. W., AND R. D. SEMLITSCH. 1982. Tertwo breeding populations of the eastern tiger salrestrial drift fences with pitfall traps: an effective amander, Ambystomatigrinum. Ibid. 1983:608-616. technique for quantitative sampling of animal popSERVAGE,D. L. 1979. Biosystematics of the Ambysulations. Brimleyana 7:1-16. toma jeffersonianum complex in Ontario. Unpubl. GILHEN, J. 1984. Amphibiansand reptiles of Nova M.S. thesis, Univ. Guelph. Guelph, Ontario, CanScotia. Nova Scotia Museum Publ., Halifax, Nova ada. Scotia. S. K. 1982. Cytogenetics of diploid and SESSIONS, HUMPHREY, R. R., AND G. FANKHAUSER. 1956. Structriploid salamanders of the Ambystomajeffersonianum ture and functional capacity of the ovaries of higher complex. Chromosoma 84:599-621. polyploids (4N, 5N) in the Mexican axolotl (Siredon SEVER, D. M., L. E. LICHT AND J. P. BOGART. 1989. or Ambystomamexicanum).J. Morph. 98:161-197. Male cloacal anatomy in a hybrid population of AmHUSTING, E. L. 1965. Survival and breeding strucbystoma (Amphibia: Caudata). Herpetologica 45: ture in a population of Ambystomamaculatum. Cope161-167. ia 1965:352-362. SEXTON, O. J., J. BIZER, D. C. GAYOU, P. FREILING KRAUS, F. 1985a. A new unisexual salamander from ANDM. MOUTSEOUS.1986. Field studies of breedOhio. Occ. Pap. Mus. Zoo. Univ. Michigan 709:1ing spotted salamanders, Ambystomamaculatum, in 24. eastern Missouri, USA. Milwaukee Public Museum S1985b. Unisexual salamander lineages in Contrib. Biol. Geol. 67:1-19. LOWCOCK ET AL.-PLOIDY SHOOP,C. R. 1960. The breeding habits of the mole salamanders, Ambystomatalpoideum (Holbrook), in southeastern Louisiana. Tulane Stud. Zool. 8:6582. SOKAL, R. R., AND F.J. ROHLF. 1981. Biometry.2nd ed. W. H. Freeman & Company, San Francisco, California. TANK, P. W., R. K. CHARLTON AND E. R. BURNS. 1987. Flow cytometry analysis of ploidy in the axolotl, Ambystomamexicanum.J. Exp. Zool. 243:423433. UZZELL, T. M. 1964. Relations of the diploid and comtriploid species of the Ambystomajeffersonianum plex (Amphibia, Caudata). Copeia 1964:257-300. WACASEY, J. W. 1961. An ecological study of two sympatric species of salamanders, Ambystomamaculatum and Ambystomajeffersonianum, in Southern Michigan. Unpubl. Ph.D. dissert., Michigan State University. WELLER, W. F. 1980. Migration of the salamanders Ambystomajeffersonianum (Green) and A. platineum Cope to and from a spring breeding pond, and the growth, development and metamorphosis of their IN HYBRID AMBYSTOMA 105 young. Unpubl. M.S. thesis, University of Toronto, Toronto, Ontario, Canada. WHITFORD, W. G., AND A. VINEGAR. 1966. Homing, survivorship, and overwintering of larvae in spotted salamanders (Ambystomamaculatum). Copeia 1966: 515-519. WILBUR,H. M. 1971. The ecological relationship of the salamander Ambystomalaterale to its all-female, gynogenetic associate. Evolution 25:168-179. ZEYL,C. W., AND L. A. LOWCOCK.1989. A morphometric analysis of hybrid salamanders (genus Ambystoma)and their progenitors on Kelleys Island in Lake Erie. Can. J. Zool. 67:2376-2383. DEPARTMENT OFICHTHYOLOGY ANDHERPETOLOGY,ROYALONTARIOMUSEUM,100 QUEEN'S PARK,TORONTO,ONTARIO M5S 2C6, CANADAAND RAMSAYWRIGHTZOOLOGICAL LAUNIVERSITYOF TORONTO 25 BORATORIES, HARBORDST., TORONTO,ONTARIO,CANADA. Accepted 22 April 1990. Copeia, 1991(1), pp. 105-110 The Influence of Photoperiod and Position of a Light Source on Behavioral Thermoregulation in Crotaphytuscollaris (Squamata: Iguanidae) LYNNETTE M. SIEVERTAND VICTOR H. HUTCHISON Temperature selection of male Crotaphytus collaris acclimated to 25 ? 1 C was measured over a 24 h period in a thermal gradient with either uniform light over the entire gradient, a point source of light over the hot end of the gradient, or a point source of light over the cold end of the gradient and an 16L/8D, 12L/ 12D or 8L/16D photoperiod. Both photoperiod and the position of the light source over the gradient significantly influenced the diel cycle of thermal selection. The position of the light also significantly affected mean selected body temperatures. Photoperiod and light position were important both as separate and conjunctional factors influencing behavioral thermoregulation. We concluded that light position, heat, and photoperiod are used as separate cues in behavioral thermoregulation. changes throughout a repPHOTOPERIOD tile's activity season provide reliable seasonal cues. Reptiles often thermoregulate within narrow limits when provided the opportunity, and some show seasonal differences in temperature preference (Patterson and Davies, 1978; Sievert and Hutchison, 1989a; Van Damme et al., 1986). Photoperiod affects many behavioral and physiological responses including repro- duction (Licht, 1971a, 1971b), DNA synthesis in the testis (Noeske and Meier, 1983), temperature selection (Graham and Hutchison, 1979; Rismiller and Heldmaier, 1982, 1988), diel patterns of temperature selection (Rismiller and Heldmaier, 1982; Spellerberg, 1974), and thermal tolerance (Hutchison and Kosh, 1964; Licht, 1968). Photoperiods with a longer photophase (16L/ ? 1991 by the American Society of Ichthyologists and Herpetologists
