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                          MULTIPLE SCLEROSIS
 

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       Multiple sclerosis (MS) is a chronic, demyelinating disease of the central nervous system (Bebo et al., 1999), which usually strikes between the ages of 20 and 40. Symptoms of this disorder include impairment of vision, sensation, muscle strength and coordination, and cognitive processes. Each patient is affected differently by the disorder (Wells, 1997), and the physical and emotional progression of MS are unpredictable (National, 2000).
    The different types of MS have recently been classified into four major categories. Relapsing-remitting (RR) MS is characterized by clearly defined ‘flare-ups,’ followed by either complete recovery or recovery accompanied by slight loss of function. Primary-progressive (PP) MS involves a slow, continuous progession of the disease with only brief episodes of improvement. Secondary-progressive (SP) MS commences as relapsing-remitting MS and eventually converts to primary-progressive MS. Finally, progressive-relapsing (PR) MS is associated with a continuous decline from onset, yet has acute relapses, either with or without recovery back to the level of disease which existed prior to the relapse (Wells, 1997).


The Central Nervous System and the Role of Myelin

    The nervous system is a complex of two major subdivisions, the central nervous system (CNS) and the peripheral nervous system (PNS) (Waxman, 2000). The former, which is the target of demyelination in multiple sclerosis, comprises the brain and spinal cord, and depends upon the rapid and efficient transfer of nerve impulses, primarily through action potentials, in order to properly control body function (Wells, 1997) (Figure One).


                                Figure One. The central nervous system
                                         comprises the brain and the spinal cord.
                                         (Permission for use of image has been
                                         requested.) Please visit the Neuroscience for
                                         Kids webpage at:
                                http://faculty.washington.edu/chudler/neurok.html


    The axons of many nerves in the CNS are covered by a myelin sheath, which consists of multiple layers of lipid-rich membrane, produced by oligodendrocytes (Waxman, 2000). This sheath is divided into segments by short, unmyelinated sections known as the nodes of Ranvier, and action potentials are able to jump from node to node, dramatically increasing the speed of conduction of a nerve impulse along the axon (Figure Two). This process, known as saltatory conduction, results from the abundance of sodium channels at the nodes, and the insulating properties of myelin. Multiple sclerosis is characterized by the destruction of myelin sheaths in the CNS, thus slowing down or stopping action potentials all together (Kalat, 1998).


                           Figure Two. Depiction of a neuron. The axon, myelin
                                     and nodes of Ranvier are indicated. (Permission to use
                                     this image has been requested.) Please visit the
                                     Neuroscience for Kids webpage at:
                                 http://faculty.washington.edu/chudler/neurok.html


Etiology
 

    Although the precise etiology of MS is unknown, there are several major scientific theories concerning the source of the disease (Wells, 1997). It is now generally accepted that MS results from an autoimmune process, in which the immune system mounts an abnormal response against self antigens in the central nervous system (International, 1999). An MS exacerbation begins with the inflammation and swelling of the myelin, producing an area referred to as a lesion (Figure Three).



 
 


      Figure Three. The large round white spot in the

                                                           right frontal region is a lesion resulting from
                                                           myelin inflammation and swelling in an individual
                                                           with Multiple sclerosis.(Permission to use image
                                                           has been requested.) Please visit the Whole Brain
                                                           Atlas website at:
                                                       http://www.med.harvard.edu/AANLIB/home.html


    Blood leaks through dilated vessels into the tissue of the inflammed area and inflammatory white blood cells are released from the blood. White blood cells in a normal individual, are utilized by the immune system to fight foreign substances that may cause disease or infection. However, in MS, these cells are directed to attack myelin, a self-tissue (National, 2000) (Figure Four).


Figure Four- Damage to the myelin sheath
surrounding the axon of a nerve cell, in MS.
(Permission to use image has been requested).
   Please visit the ABCNews website at:
http://abcnews.go.com/sections/living/DailyNews/msherpes.html


    Astrocytes, a type of glial cell (non-nerve brain cells), regulate the blood-brain barrier, which controls the passage of soluble molecules between the CNS cells and the blood vessels. Normally, the blood-brain barrier prevents the passage of many types of cells, including those of the immune system, into the CNS (Figure Five). However, in MS, white blood cells are able to cross the blood-brain barrier and target myelin on nerve cell axons for destruction (Wells, 1997).


                                                      Figure Five. Animation of the blood-brain
                                                        barrier in a normal individual. (Permission
                                                        to use image has been requested). Please
                                                        visit the University of Iowa webpage at:
                                                      http://galileo.physiology.uiowa.edu.
 


     Though the exact cause of the autoimmune response is unknown, research indicates that a combination of several factors (International, 1999)- genetic, viral, and environmental- may be responsible (National, 2000). While MS is not a hereditary disease, having a first degree relative such as a parent or sibling, increases an individual's risk of developing MS. It is theorized that in these individuals, a genetic predisposition to react to environmental factors may exist. Upon exposure to the environmental agent, an autoimmune response can be triggered. A recent study by Bergsteinsdottir et al. (2000) suggests that certain genes may be shared by different autoimmune diseases, thus lending support to the theory of a genetic basis for MS (Bergsteinsdottir et al., 2000).  It is also possible that a virus is the triggering factor in MS. Viruses are well-known causes of demyelination and inflammatory reactions (National, 2000) and may lie dormant in the body where they can eventually be activated and induce autoimmunity. It is likely that there is no single virus for MS, but that a common virus, such as measles, may trigger the disease (International, 1999). Patterns of migration and studies of epidemiology have shown that individuals who move from a high risk area of the world to a low risk area of the world before the age of fifteen, acquire the risk level associated with their new location. Thus, it appears that exposure to some  environmental agent before puberty may predispose an individual to develop MS later in life (National, 2000).

B cells and autoantibodies
 

    Colombo, et al. (2000) discuss two major etiological theories concerning MS. The first proposes that a viral or pathogenic infection precipitates the recruitment of inflammatory cells in the CNS, which may eventually lead to the onset of an autoimmune response. The second theory proposes that MS is triggered by a direct autoimmune response, which targets myelin antigen. Although research implicates T cells, one of the major infiltrates of MS, in the formation of inflammatory lesions, the production of autoantibodies has been shown to be an important factor in the demyelination of nerve cell axons. The involvement of B cells in MS has been investigated, and examinations of the cerebrospinal fluid (CSF) of MS patients reveals the presence of anti-myelin antibodies (Colombo et al., 2000). More specifically, these antibodies are often directed against myelin basic protein (MBP), although detection of anti-MBP antibodies is often regarded as a marker of neurological disease rather than its cause. A variety of other auto-antibodies have been identified in MS patients including anti-myelin-oligodendrocyte glycoprotein, anti-transaldolase, which binds to an enzyme expressed within oligodendrocytes, and antibodies to neoantigens. Neoantigens are expressed following infection of a cell by a virus, and are typically nonsense regions of normal DNA (Vincent et al., 1999). Using polymerase chain reaction (PCR) techniques, Colombo et al. (2000) were able to reveal an ongoing B cell response in MS patients to a relatively limited number of stimulating antigens, as there was an accumulation of clonally related B cells in the CSF of these patients.

T-cell mediated, Fas-dependent mechanisms

    Sabelko-Downes et al. (1999) investigated another possible mechanism of myelin degeneration known as T-cell mediated, Fas-dependent death. This mechanism is an appealing one to consider, as it is not necessarily MHC-restricted (major histocompatibility complex-restricted) and the targets of CNS disruption do not express MHC. They propose that following initial stimulation, T cells which have been activated and have differentiated infiltrate the CNS. T cells specific for neuroantigen then encounter resident antigen-presenting cells (APC), which present antigen, and stimulate the T cells to secrete cytokines such as TNF-alpha and IFN-gamma. These cytokines initiate an inflammatory response, and CNS-specific, FasL+ T cells (stimulated by APCs expressing B7) begin to damage Fas+ targets such as oligodendrocytes. The damage produced in this early stage may perpetuate the inflammatory response and recruit additional T cells, B cells, and macrophages into the lesion, causing further damage. In addition to Fas-FasL dependent mechanisms, non-fasL-mediated factors such as the release of cytotoxic molecules may also damage oligodendrocytes and myelin (Sabelko-Downes et al, 1999).

Chemokines

    Chemokines have also been implicated in the pathogenesis of MS during the progression of lesions. Staining for chemokines in the CNS of MS patients revealed low RANTES and MCP-1 expression associated with the endothelium in inflammation, which attract mononuclear cells from the blood across the blood-brain barrier and into the CNS. The local inflammatory response is maintained through the activation of resident glial cells and the expression of MCP-1, RANTES, and MIP-1alpha by astrocytes and MIP-1alpha, MIP-1beta, and MCP-1 by macrophages. Thus, inhibitory agents that block chemokine receptors may, in the future, provide treatment for MS (Woodroofe et al., 1999).

Experimental autoimmune encephalomyelitis (EAE) and the Beta7 Integrins

    Although no single animal model currently exists, which imitates all of the features of MS, the prototypic model often utilized is experimental autoimmune encephalomyelitis (EAE). This disease can be induced in a number of species by immunization with components of CNS myelin, such as myelin basic protein, or CNS tissue (‘actively-induced EAE’). In vitro, sensitized T cell lines can also be injected intravenously (‘adoptive- transfer EAE’) (Gold et al., 2000). Kanwar et al. (2000) recently studied the involvement of beta7 integrins in the pathogenesis of EAE. These integrins are a subfamily of cell adhesion molecules, consisting of two members, alpha4beta7 and alphaEbeta7. By binding their ligands, MAdCAM-1, VCAM-1 and E-cadherin on the endothelial cells in the brain or on microvessels in the inflamed CNS, the beta7 integrins may be required to mediate the migration of leukocytes across the blood-brain barrier, producing chronic, non-remitting forms of EAE and, perhaps, MS. Thus, another source of treatment for MS may be the inhibition of certain adhesion pathways, particularly those involving the beta7 integrins (Kanwar et al., 2000).


Treatment

    There is presently no cure for MS, but a variety of treatments have been developed and are currently being researched, which effectively act upon various facets of the disease (International, 1999).
    Transforming growth factor- beta2 (TGF-beta2) has recently been shown to reduce demyelination, the expression of viral antigen, and the recruitment of macrophages in mice with Theiler’s murine encephalomyelitis virus (TMEV), a demyelinating disease with pathology similar to that observed in multiple sclerosis. TGF-beta2 is considered to be an immunosuppressive cytokine based upon its ability to decrease the proliferation of B and T cells and to suppress cytokine production. In addition, studies have revealed that TGF-beta2 may also reduce NK cell activity and the generation of cytotoxic T cells. Treatment with TGF-beta2 , three times weekly for thirty-five days following infection, resulted in significantly smaller lesions and a decline in the number of antigen-positive cells in the spinal cords of infected mice. Presumably, TGF-beta2 works by decreasing the function of macrophages and their infiltration into the CNS, thereby reducing the chronic demyelination characteristic of both TMEV and MS (Drescher et al., 2000).
    Interferon-beta (IFN-beta) has been shown to be effective against relapsing-remitting MS and clinical trials are currently underway to determine its effectiveness in progressive MS (International, 1999). A recent study by Khademi et al. (2000) revealed that IFN-beta, a cytokine itself, inhibits the effects of proinflammatory cytokines such as interferon (IFN) gamma and tumor necrosis factor (TNF) alpha. The reduction of IFN-gamma through upregulation of IFN-beta in the CNS is potentially beneficial, as IFN-gamma is responsible for the activation of macrophages and the promotion of TH1 immune responses (Khademi et al., 2000). A number of types of IFN-beta are currently available. The trade names for IFN-beta 1b are Betaseron and Betaferon and for IFN-beta 1a, are Avonex and Rebif. The latter of these pharmaceutical drugs is still undergoing clinical trials in the United States and Betaseron has been available as a prescribed drug in the United States for 2 years. Around 20,000 people diagnosed with MS are currently taking Betaseron in the United States (International, 1999).
    Intravenous immunoglobulin (IVIg) therapy is also showing promise in the treatment of MS. This form of treatment involves the injection of antibodies derived from the blood of healthy individuals into MS patients. (Wells, 1997). A recent study by Stangel et al. (2000) indicates that IVIg may protect oligodendrocytes from damage by antibody-mediated complement through antibody-binding and may also promote myelin repair in damaged areas. Inhibition of inflammatory mechanisms, rather than a direct effect on remyelinating cells as was previously thought, may promote myelin repair (Stangel, 2000).
    Treatment with 1,2-Dihydroxyvitamin D3 may also be effective in resolving acute MS attacks in patients with relapsing-remitting MS. Research reveals that 1,2-Dihydroxyvitamin D3, a hormonally active vitamin D metabolite, significantly reduces the number of macrophages accumulating in the inflamed CNS of mice with EAE (Nashold, 2000). In addition, in vitro, 1,25-Dihydroxyvitamin D3, inhibits the proliferation of T cells and decreases the production of the cytokines, IL-2, IFN-gamma, TNF-alpha (Cantorna, 2000).
    Numerous other treatments are currently available or being researched. To view a complete list please visit: http://www.msaa.com/msaa/litpro.htm.



The Future of MS

    A great deal of research is currently underway to identify the exact mechanisms associated with the pathogenesis of MS. While it may not be possible to improve all function lost to the disorder, victims of MS should maintain their physical and mental condition through rehabilitation and counselling programs. Research is not limited to slowing or halting the progression of MS, as numerous studies are currently investigating the possibility of repairing myelin, which could restore lost function to victims of the disease (Wells, 1997). Early diagnosis and commencement of treatment are also important and, thus, individuals should discover, early on, the occurrence of MS within their own family.



                              Works Cited
 

    Bebo, B., Adlard, K., Schuster, J., Unsicker, L., Vandenbark, A., & Offner, H. (1999). Gender Differences in Protection from EAE Induced by Oral Tolerance With a Peptide Analogue of MBP-Ac1-11. Journal of Neuroscience Research, 55, 432-440.

     Bergsteinsdottir, K., Yang, H., Pettersson, U., & Holmdahl, R. (2000). Evidence for Common Autoimmune Disease Genes Controlling Onset, Severity, and Chronicity Based on Experimental Models for Multiple Sclerosis and Rheumatoid Arthritis. Journal of Immunology, 164, 1564-1568.

     Cantorna, M. (2000). Vitamin D and Autoimmunity: Is Vitamin D Status an Environmental Factor Affecting Autoimmune Disease Prevalence? Proceedings of the Society for Experimental Biology and Medicine, 223, 230-233.

    Colombo, M., Dono, M., Gazzola, P., Roncella, S., Valetto, A., Chiorazzi, N., Mancardi, G., & Ferrarini, M.  (2000). Accumulation of Clonally Related B Lymphocytes in the Cerebrospinal Fluid of Multiple Sclerosis Patients. Journal of Immunology, 164, 5, 2782-2789.

    Drescher, K., Murray, P., Lin, X., Carlino, J., & Rodriguez, M. (2000). TGF-Beta2 Reduces Demyelination, Virus Antigen Expression, and Macrophage Recruitment in a Viral Model of Multiple Sclerosis. Journal of Immunology, 164, 6, 3207-3213.

    Gold, R., Hartung, H., Toyka, K. (2000). Animal models for autoimmune demyelinating disorders of the nervous system. Molecular Medicine Today, 6, 88-91.

    International Federation of Multiple Sclerosis Societies (1999). The World of Multiple Sclerosis. Available: http://www.ifmss.org.uk/

    Kalat, J. (1998). Biological Psychology, 6th ed. New York: Brooks/Cole Publishing Co.

    Kanwar, J., Harrison, J., Wang, D., Leung, E., Mueller, W., Wagner, N., & Krissansen, G. (2000). Beta7 integrins contribute to demyelinating disease of the central nervous system. Journal of Neuroimmunology, 103, 146-152.

    Khademi, M., Wallstrom, E., Andersson, M., Piehl, F., Di Marco, R., & Olsson, T. (2000). Reduction of both pro- and anti-inflammatory cytokines after 6 months of interferon beta-1a treatment of multiple sclerosis. Journal of Neuroimmunology, 103, 202-210.

    Nashold, F., Miller, D., & Hayes, C. (2000). 1,25-Dihydroxyvitamin D3 treatment decreases macrophage accumulation in the CNS of mice with experimental autoimmune encephalomyelitis. Journal of Neuroimmunology, 103, 171-179.

    National Multiple Sclerosis Society (2000) . MS Information. Available: http://www.nmss.org/

    Sabelko-Downes, K., Russell, J., & Cross, A. (1999). Role of Fas-FasL interactions in the pathogenesis and regulation of autoimmune demyelinating disease. Journal of Neuroimmunology, 100, 42-52.

    Stangel, M., Compston, A., & Scolding, N. (2000). Oligodendroglia are protected from antibody-mediated complement injury by normal immunoglobulins. Journal of Neuroimmunology, 103, 195-201.

    Vincent, A., Lily, O., & Palace, J. Pathogenic autoantibodies to neuronal proteins in neurological disorders. Journal of Neuroimmunology, 100, 169-180.

    Waxman, S. (2000). Correlative Neuroanatomy, 24th ed. New York: McGraw-Hill.

    Wells, S. (1997). The Process and Medical Treatments. Multiple Sclerosis Association of America Online. Available: http://www.msaa.com/msaa/litpro.htm

    Woodroofe, N., Cross, A., Harkness, K., Simpson, J. (1999). The Role of Chemokines in the Pathogenesis of Multiple Sclerosis. Advances in Experimental Medicine and Biology, 468, 135-150.



 
 


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