Dorian B. McGavern

Absence of neurological deficits following extensive demyelination in a class I-deficient murine model of multiple sclerosis

Demyelination alone has been considered sufficient for development of neurological deficits following central nervous system (CNS) disease. However, extensive demyelination is not always associated with clinical deficits in patients with multiple sclerosis (MS), the most common primary demyelinating disease in humans. We used the Theilers murine encephalomyelitis virus model of demyelination to investigate the role of major histocompatibility complex (MHC) class I and class II gene products In the development of functional and neurophysiological deficits following demyelination. We measured spontaneous clinical activity by two independent assays and recorded hind-limb motor-evoked potentials in infected class I-deficient and class 11-deficient mice of an identical genetic background as well as in highly susceptible SJL/J mice. The results show that despite a similar distribution and extent of demyelinated lesions in all mice, only class I-deficient mice were functionally normal. We propose that the mechanism by which demyelinated class I-deficient mice maintain neurologic function results from increased sodium channel densities and the relative preservation of axons. These findings are the first to implicate a role for MHC class I in the development of neurological deficits following demyelination.

Primary demyelination in transgenic mice expressing interferon-γ

Ever since the use of interferon-γ to treat patients with multiple sclerosis resulted in enhanced disease, the role of IFN-γ in demyelination has been under question. To address this issue directly, transgenic mice were generated that expressed the cDNA of murine IFN-γ in the central nervous system by using an oligodendrocyte-specific promoter. Expression of the transgene occurred after 8 weeks of age, at which time the murine immune and central nervous systems are both fully developed. Directly associated with transgene expression, primary demyelination occurred and was accompanied by clinical abnormalities consistent with CNS disorders. Additionally, multiple hallmarks of immune-mediated CNS disease were observed including upregulation of MHC molecules, gliosis and lymphocytic Infiltration. These results demonstrate a direct role for IFN-γ as an inducer of CNS demyelination leading to disease and provide new opportunities for dissecting the mechanism of demyelination.

Quantitative assessment of neurologic deficits in a chronic progressive murine model of CNS demyelination

The precise factors involved in the development of a progressive motor dysfunction, a hallmark of immune-mediated demyelinating diseases such as multiple sclerosis, are not well defined. The ability to identify neurologic deficits that result in impaired motor performance early in disease may allow for the identification of therapeutic interventions that slow or eliminate the progression toward a permanent dysfunction. Here we describe the use of three objective, quantitative functional assays (spontaneous activity box, rotarod, and footprint analysis) to detect early neurologic deficits following the initiation of a demyelinating disease with Theilers murine encephalomyelitis virus (TMEV). The results show that the assays are capable of revealing neurologic deficits at the early stages of the demyelinating disease process. These findings are the first to objectively characterize neurologic function in an animal model of progressive CNS demyelination.

Quantitation of spinal cord demyelination, remyelination, atrophy, and axonal loss in a model of progressive neurologic injury.

Spinal cord pathology, such as demyelination and axonal loss, is a common feature in multiple models of central nervous system (CNS) injury and disease. Development of methods to quantify spinal cord pathology objectively would aid studies designed to establish mechanisms of damage, correlate pathology with neurologic function, and assess therapeutic interventions. In this study, we describe sensitive methods to objectively quantify spinal cord demyelination, remyelination, atrophy, and axonal loss following the initiation of a progressive inflammatory demyelinating disease with Theilers murine encephalomyelitis virus (TMEV). Spinal cord demyelination, remyelination, and atrophy were quantified from representative 1‐μm‐thick cross sections embedded in Araldite plastic using interactive image analysis. In addition, this study demonstrates novel, automated methodology to quantify axonal loss from areas of normal‐appearing white matter, as a measure of secondary axonal injury following demyelination. These morphologic methods, which are applicable to various models of CNS injury, provide an innovative way to assess the benefits of therapeutic agents, to determine mechanisms of spinal cord damage, or to establish a correlation with sensitive measures of neurologic function. J. Neurosci Res 58:492–504.

Quantitative Ultrastructural Analysis of a Single Spinal Cord Demyelinated Lesion Predicts Total Lesion Load, Axonal Loss, and Neurological Dysfunction in a Murine Model of Multiple Sclerosis

Infection of susceptible mice with Theilers murine encephalomyelitis virus results in neurological dysfunction from progressive central nervous system demyelination that is pathologically similar to the human disease, multiple sclerosis. We hypothesized that the development of neuropathology proceeds down a final common pathway that can be accurately quantified within a single spinal cord lesion. To test this hypothesis, we conducted quantitative ultrastructural analyses of individual demyelinated spinal cord lesions from chronically infected mice to determine whether pathological variables assessed within a single lesion accurately predicted global assessments of morphological and functional disease course. Within lesions we assessed by electron microscopy the frequencies of normally myelinated, remyelinated, and demyelinated axons, as well as degenerating axons and intra-axonal mitochondria. The frequency of medium and large remyelinated fibers within a single lesion served as a powerful indicator of axonal preservation and correlated with preserved neurological function. The number of degenerating axons and increased intra-axonal mitochondria also correlated strongly with global measures of disease course, such as total lesion load, spinal cord atrophy, and neurological function. This is the first study to demonstrate that functional severity of disease course is evident within a single demyelinated lesion analyzed morphometrically at the ultrastructural level.

Absence of Spontaneous Central Nervous System Remyelination in Class II-deficient Mice Infected with Theiler's Virus

We previously showed that Theilers murine encephalomyelitis virus (TMEV)-infected major histocompatibility complex (MHC) class II-deficient mice develop both demyelination and neurologic deficits, whereas MHC class I-deficient mice develop demyelination but no neurologic deficits. The absence of neurologic deficits in the class I-deficient mice was associated with preserved sodium channel densities in demyelinated lesions, a relative preservation of axons, and extensive spontaneous remyelination. In this study, we investigated whether TMEV-infected class II-deficient mice, which have an identical genetic background (C57BL/6 x 129) as the class I-deficient mice, have preserved axons and spontaneous myelin repair following chronic TMEV-infection. Both class I- and class II-deficient mice showed similar extents of demyelination of the spinal cord white matter 4 months after TMEV infection. However, the class I-deficient mice demonstrated remyelination by oligodendrocytes, whereas class II-deficient mice showed minimal if any myelin repair. Demyelinated lesions, characterized by inflammatory infiltrates in both mutants, revealed disruption of axons in class II- but not class I-deficient mice. Further characterization revealed that even though class II-deficient mice lacked TMEV-specific IgG, they had virus-specific IgM, which, however, did not neutralize TMEV in vitro. In addition, class II-deficient mice developed TMEV-specific cytotoxic T-lymphocytes in the CNS during the acute (7 days) disease, but these cytotoxic lymphocytes were not present in the chronic stage of disease, despite a high titer of infectious virus throughout the disease. We envision that the presence of demyelination, high virus titer, absence of remyelination, and axonal disruption in chronically infected class II-deficient mice contributes to the development of paralytic disease.

Cellular sources and targets of IFN‐γ‐mediated protection against viral demyelination and neurological deficits

IFN‐γ is an anti‐viral and immunomodulatory cytokine critical for resistance to multiple pathogens. Using mice with targeted disruption of the gene for IFN‐γ, we previously demonstrated that this cytokine is critical for resistance to viral persistence and demyelination in the Theilers virus model of multiple sclerosis. During viral infections, IFN‐γ is produced by natural killer (NK) cells, CD4+ and CD8+ T cells; however, the proportions of lymphocyte subsets responding to virus infection influences the contributions to IFN‐γ‐mediated protection. To determine the lymphocyte subsets that produce IFN‐γ to maintain resistance, we used adoptive transfer strategies to generate mice with lymphocyte‐specific deficiencies in IFN‐γ‐production. We demonstrate that IFN‐γ production by both CD4+ and CD8+ T cell subsets is critical for resistance to Theilers murine encephalomyelitis virus (TMEV)‐induced demyelination and neurological disease, and that CD4+ T cells make a greater contribution to IFN‐γ‐mediated protection. To determine the cellular targets of IFN‐γ‐mediated responses, we used adoptive transfer studies and bone marrow chimerism to generate mice in which either hematopoietic or somatic cells lacked the ability to express IFN‐γ receptor. We demonstrate that IFN‐γ receptor must be present on central nervous system glia, but not bone marrow‐derived lymphocytes, in order to maintain resistance to TMEV‐induced demyelination.

Assessment of hindlimb gait as a powerful indicator of axonal loss in a murine model of progressive CNS demyelination

Identifying the role of axonal injury in the development of permanent, irreversible neurologic disability is important to the study of central nervous system (CNS) demyelinating diseases. Our understanding of neurologic dysfunction in demyelinating diseases and the ability to assess therapeutic interventions depends on the development of objective functional assays that can non-invasively measure axonal loss. In this study, we demonstrate in a murine model of progressive CNS demyelination that assessment of the hindlimb width of stride provides a powerful indicator of axonal loss and can dissociate between deficits induced by demyelination versus axonal loss.

Do Antibodies Stimulate Myelin Repair in Multiple Sclerosis

One of the major goals in the study of multiple sclerosis (MS) is to identify a beneficial therapeutic intervention that mimics the intrinsic reparative process and results in long- term clinical improvement. As yet, the therapeutic strategies tested in MS have failed to accomplish this task. However, one potential therapy that has shown some promise in rodent models of demyelination involves the administration of antibodies. Studies in var ious models of demyelination (virus-induced, autoimmune, and toxic) indicate that a sub set of autoantibodies with reactivity to CNS antigens promote remyelination. We have identified a prototypic germline IgMk monoclonal antibody, designated SCH 94.03, with reactivity to a surface antigen on oligodendrocytes that promotes CNS remyelination. This antibody has the phenotypic features of polyreactive physiological natural autoan tibodies. Additionally, treatment of MS patients with intravenous immunoglobulin, which contains these natural autoantibodies, may be efficacious in a subset of patients. We propose three mechanisms (direct stimulation of oligodendrocytes, immunomodulation, and opsonization of debris) by which polyreactive natural autoantibodies directed against CNS antigen may promote remyelination. Remyelination has the potential to not only improve conduction velocity but also may protect axons from injury and improve neuro logical function. NEUROSCIENTIST 5:19-28, 1999

HLA-DQ Polymorphism Influences Progression of Demyelination and Neurologic Deficits in a Viral Model of Multiple Sclerosis

The importance of genetic susceptibility in determining the progression of demyelination and neurologic deficits is a major focus in neuroscience. We studied the influence of human leukocyte antigen (HLA)-DQ polymorphisms on disease course and neurologic impairment in virus-induced demyelination. HLA-DQ6 or DQ8 was inserted as a transgene into mice lacking endogenous expression of MHC class I (beta(2)m) and class II (H2-A(beta)) molecules. Following Theilers murine encephalomyelitis virus (TMEV) infection, we assessed survival, virus persistence, demyelination, and clinical disease. Mice lacking expression of endogenous class I and class II molecules (beta(2)m(o) Abeta(o) mice) died 3 to 4 weeks postinfection (p.i.) due to overwhelming virus replication in neurons. beta(2)m(o) Abeta(o) DQ6 and beta(2)m(o) Abeta(o) DQ8 mice had increased survival and decreased gray matter disease and virus replication compared to nontransgenic littermate controls. Both beta(2)m(o) Abeta(o) DQ6 and beta(2)m(o) Abeta(o) DQ8 mice developed chronic virus persistence in glial cells of the white matter of the spinal cord, with greater numbers of virus antigen-positive cells in beta(2)m(o) Abeta(o) DQ8 than in beta(2)m(o) Abeta(o) DQ6 mice. At day 45 p.i., the demyelinating lesions in the spinal cord of beta(2)m(o) Abeta(o) DQ8 were larger than those in the beta(2)m(o) Abeta(o) DQ6 mice. Earlier and more profound neurologic deficits were observed in beta(2)m(o) Abeta (o) DQ8 mice compared to beta(2)m(o) Abeta(o) DQ6 mice, although by 120 days p.i. both strains of mice showed similar extent of demyelination and neurologic deficits. Delayed-type hypersensitivity and antibody responses to TMEV demonstrated that the mice mounted class II-mediated cellular and humoral immune responses. The results are consistent with the hypothesis that rates of progression of demyelination and neurologic deficits are related to the differential ability of DQ6 and DQ8 transgenes to modulate the immune response and control virus.