The immunopathogenesis of multiple sclerosis

The immunopathogenesis of
multiple sclerosis
Olaf Stüve, M.D., Ph.D.
Neurology Section
VA North Texas Health Care System
Dallas VA Medical Center
Departments of Neurology and Neurotherapeutics
University of Texas
Southwestern Medical Center at Dallas
Disclosures
• Dr. Stüve has received research funding from
Teva Pharmaceuticals
• Dr. Stüve is on the editorial boards of Clinical
and Experimental Immunology, JAMA
Neurology, Multiple Sclerosis, and
Therapeutic Advances in Neurological
Disorders
Learning objectives
A. To understand the role of the adaptive
immune system in the initiation of
relapsing-remitting MS
B. To learn about factors that cause relapses
in relapsing-remitting MS
C. To comprehend events that lead to
remission in relapsing-remitting MS
Multiple Sclerosis
• Inflammatory, demyelinating,
neurodegenerative disease of
the central nervous system
• Unknown etiology
• Presumed autoimmune
pathogenesis
Multiple Sclerosis
Stüve O, Zamvil SS. In: Lange: Medical Immunology (tenth edition). 2001.
http://www.mmorris.com/ms/MRI/multiple_sclerosis_news%20MRI%20Images.htm
Multiple Sclerosis
What starts the disease?
Stüve O, Zamvil SS. In: Lange: Medical Immunology (tenth edition). 2001.
Underlying Factors of MS
Infectious agent
Genetic predisposition
Environmental factors
Abnormal immunologic response
MS
DeLorenze et al. Arch Neurol. 2006.
Multiple Sclerosis
• Peak age of onset: Between 20
and 40 years of age
• Female preponderance
Canada
Denmark
North-East
Ireland
Saskatoon
Oslo
Cardiff
UAA
Iran
Isfahan
Japan
French West Indies
Greater Hobart
Sellner et al. Autoimmunity Reviews. 2011.
Underlying Factors of MS
Infectious agent
Genetic predisposition
Environmental factors
Abnormal immunologic response
MS
Complex genetic diseases
• Unknown genetic parameters
and mode of inheritance
• Substantial role of non-genomic
factors
Selected familial risks for MS
Regions of overlap between whole genome scans in multiple sclerosis
US
2p23
UK
Canada
1p36-p33
1p36-p33
2p23-p21
2p23-21
3p14-p13
3p14-p13
3q22-q24
4q31-qter
*
3q22-q24
3q22-q24
5p14-p12
5p14-22
4q31-qter
5q13-q23
5q12-q13
5q12-q13
6p21
6p21
6p21 (LD)
6q27
6q22-27
7q11-q22
6p21
7q21-q22
17q22
18p11
19q13
Finland
17q22-24
18p11
19q12-13
19q13
19q13
Multiple Sclerosis
What causes a relapse?
Stüve O, Zamvil SS. In: Lange: Medical Immunology (tenth edition). 2001.
Neuropathol-web.org
Circulation
Central Nervous System
T cell
T-cell extravasation
B cell
T cell
T cell
T cell
B-cell – T-cell cross-activation
Chemoattraction
T cell
Plasma cell
CNS
APC
T cell
Antibodies
&
Complement
T-cell adhesion
T-cell reactivation
T cell
Memory
B cell
Inflammatory
mediators
T-cell rolling
T cell
K+ Na+
Inflammation
APC
T cell
T-cell activation
Hypoxia,
ischemia
Activation of
Na+ channels
Oligodendrocyte
NA+
Energy
depletion
Ca2+ Na+
Reverse Na+ Ca2+
exchange
Etiology of Multiple Sclerosis
• Two particular circumstances
have been associated with
clinical MS exacerbations:
Etiology of Multiple Sclerosis
• Two particular circumstances
have been associated with
clinical MS exacerbations:
– Postpartum period
Etiology of Multiple Sclerosis
• Two particular circumstances
have been associated with
clinical MS exacerbations:
– Postpartum period
– Febrile infections
Experimental Autoimmune
Encephalomyelitis (EAE)
myelin Ag./CFA s/c
+myelin Ag.
CD4+
Th1
Nitin Karandikar, UTSW.
VLA-4
α4
1
Natalizumab
Circulation
T cell
Central Nervous System
B cell
T cell
T cell
T cell
B cell – T cell cross-activation
T cell adhesion
Chemoattraction
T cell
Plasma cell
CNS
APC
T cell
Antibodies
&
Complement
T cell re-activation
T cell
Memory
B cell
Inflammatory
mediators
T cell rolling
T cell
K+ Na+
Inflammation
APC
T cell
T cell activation
NA+
Energy
depletion
Hypoxia,
ischemia
Activation of
Na+ channels
Ca2+ Na+
Reverse Na+ Ca2+
exchange
Oligodendendrocyte
Stüve et al. Ann Neurol. 2006.
Fingolimod
– Believed to modulate
sphingosine 1-phosphate
(S1P) receptors on
lymphocytes and other
tissues1,2
Presumed MOA/CNS impact
• S1P receptors are widely
expressed, including in cardiac
tissue, vascular endothelium,
and pulmonary endothelium2,3
– Prevents lymphocytes from
leaving the lymph nodes
and entering the
bloodstream
and CNS compartment1,4,5
Proinflammatory Th1 cells (MS-specific)
Naïve T cells
Anti-inflammatory Th2 cells
(MS-specific)
– The mechanism by which
fingolimod exerts
therapeutic effects in MS is
unknown1
1. Gilenya™ (fingolimod) prescribing information. Novartis Pharmaceuticals Corporation. 2. Chun J, et al. Clin Neuropharm. 2010;33(2):91-101.
3. Szczepaniak WS, et al. Am J Physiol Lung Cell Mol Physiol. 2010;299(1):L137-L145. 4. Lopez-Diego RS, et al. Nat Rev Drug Discovery. 2008;7(11):909-920. 5. Kappos L, et
35al. N
Engl J Med. 2010;362(5):387-401.
Kowarik et al. Neurology. 2011.
Circulation
Central Nervous System
T cell
T-cell extravasation
B cell
T cell
T cell
T cell
B-cell – T-cell cross-activation
Chemoattraction
T cell
Plasma cell
CNS
APC
T cell
Antibodies
&
Complement
T-cell adhesion
T-cell reactivation
T cell
Memory
B cell
Inflammatory
mediators
T-cell rolling
T cell
K+ Na+
Inflammation
APC
T cell
T-cell activation
Hypoxia,
ischemia
Activation of
Na+ channels
Oligodendrocyte
NA+
Energy
depletion
Ca2+ Na+
Reverse Na+ Ca2+
exchange
Hauser et al. NEJM. 2008.
VLA-4
α4
1
Natalizumab
Stüve et al. Ann Neurol. 2006.
Stüve et al. Ann Neurol. 2006.
Circulation
Central Nervous System
T cell
T-cell extravasation
B cell
T cell
T cell
T cell
B-cell – T-cell cross-activation
Chemoattraction
T cell
Plasma cell
CNS
APC
T cell
Antibodies
&
Complement
T-cell adhesion
T-cell reactivation
T cell
Memory
B cell
Inflammatory
mediators
T-cell rolling
T cell
K+ Na+
Inflammation
APC
T cell
T-cell activation
Hypoxia,
ischemia
Activation of
Na+ channels
Oligodendrocyte
NA+
Energy
depletion
Ca2+ Na+
Reverse Na+ Ca2+
exchange
Multiple Sclerosis
What causes remission?
Stüve O, Zamvil SS. In: Lange: Medical Immunology (tenth edition). 2001.
VLA-4
α4
1
Natalizumab
O’Connor et al. Neurology. 2010.
Stüve et al. Neurol. 2009.
Conclusion
• During relapsing-remitting MS, clinical
attacks are likely caused by lymphocytes
Conclusion
• During relapsing-remitting MS, clinical
attacks are likely caused by lymphocytes
• Much of our knowledge on the
immunology in relapsing-remitting MS
stems from observations made with
specific pharmacotherapies
Conclusion
• During relapsing-remitting MS, clinical
attacks are likely caused by lymphocytes
• Much of our knowledge on the
immunology in relapsing-remitting MS
stems from observations made with
specific pharmacotherapies
• There is an intricate interplay between
many cellular subsets
Conclusion
• CD4+ T cells and B cells are thought to be
key players in MS pathogenesis
Conclusion
• CD4+ T cells and B cells are thought to be
key players in MS pathogenesis
• Some T cells and B cells also have
regulatory function
Conclusion
• CD4+ T cells and B cells are thought to be
key players in MS pathogenesis
• Some T cells and B cells also have
regulatory function
• Regulatory cells may be used
therapeutically
The End