Sequential infection of glial cells by the murine hepatitis virus JHM strain (MHV-4) leads to a characteristic distribution of demyelination.

An antigenic variant of the neurotropic murine coronavirus JHMV, designated 2.2-V-1, causes marked demyelination in the relative absence of encephalitis. It is thus useful for the study of the pathogenesis of demyelinating lesions. To better understand the sequential events leading to demyelination, we have examined murine brain and spinal cord tissue at daily intervals after intracerebral inoculation, evaluating them for the distribution of viral antigen, leukocyte infiltration, and demyelination. Immunohistochemical staining indicated that virus established primary infection in the ependymal cells in both brain and spinal cord before spreading into nearby structures and along white matter tracts by cell-to-cell contact. Spread from brain to spinal cord appeared to occur via cerebrospinal fluid. Viral replication was focally cytocidal for ependymal cells, and essentially noncytocidal for other neural cells including glia. In brain, viral antigen and inflammation reached a peak at day 5 postinfection, and rapidly subsided by day 10 postinfection. In spinal cord, viral antigen was less abundant than in brain and was maximal between days 7 and 9 postinfection. The inflammatory response and demyelination, however, were more severe persisting from day 7 through day 19. In the spinal cord, demyelinating lesions developed initially in areas closer to the central canal and were detected most prominently in the anterior funiculi. This finding suggests that the permissiveness of the ependymal cell is crucial to viral entry and that sequential infection of glial cells leads to the characteristic distribution of demyelination.     

Neutralization of chemokines RANTES and MIG increases virus antigen expression and spinal cord pathology during Theiler's virus infection

The role of chemokines during some viral infections is unpredictable because the inflammatory response regulated by these molecules can have two, contrasting effects-viral immunity and immunopathologic injury to host tissues. Using Theiler's virus infection of SJL mice as a model of this type of disease, we have investigated the roles of two chemokines-regulated on activation, normal T cell-expressed and secreted (RANTES) chemokine and monokine induced by IFN-gamma (MIG)-by treating mice with antisera that block lymphocyte migration. Control, infected mice showed virus persistence, mild inflammation and a small degree of demyelination in the white matter of the spinal cord at 6 weeks post-infection. Treatment of mice with RANTES antiserum starting at 2 weeks post-infection increased both viral antigen expression and the severity of inflammatory demyelination at 6 weeks post-infection. MIG antiserum increased the spread of virus and the proportion of spinal cord white matter with demyelination. Overall, viral antigen levels correlated strongly with the extent of pathology. At the RNA level, high virus expression was associated with low IL-2 and high IL-10 levels, and RANTES antiserum decreased the IL-2/IL-10 ratio. Our results suggest that RANTES and MIG participate in an immune response that attempts to restrict viral expression while limiting immunopathology and that anti-chemokine treatment poses the risk of exacerbating both conditions in the long term.     

Axonal injury heralds virus-induced demyelination

Axonal pathology has been highlighted as a cause of neurological disability in multiple sclerosis. The Daniels (DA) strain of Theiler's murine encephalomyelitis virus infects the gray matter of the central nervous system of mice during the acute phase and persistently infects the white matter of the spinal cord during the chronic phase, leading to demyelination. This experimental infection has been used as an animal model for multiple sclerosis. The GDVII strain causes an acute fatal polioencephalomyelitis without demyelination. Injured axons were detected in normal appearing white matter at 1 week after infection with DA virus by immunohistochemistry using antibodies specific for neurofilament protein. The number of damaged axons increased throughout time. By 2 and 3 weeks after infection, injured axons were accompanied by parenchymal infiltration of Ricinus communis agglutinin I(+) microglia/macrophages, but never associated with perivascular T-cell infiltration or obvious demyelination until the chronic phase. GDVII virus infection resulted in severe axonal injury in normal appearing white matter at 1 week after infection, without the presence of macrophages, T cells, or viral antigen-positive cells. The distribution of axonal injury observed during the early phase corresponded to regions where subsequent demyelination occurs during the chronic phase. The results suggest that axonal injury might herald or trigger demyelination.     

Detection of Tissue Culture-Adapted Theiler''s Virus RNA in Spinal Cord White Matter Cells Throughout Infection

The appearance of histological lesions and the localization of viral RNA in the central nervous system of mice infected with tissue culture-adapted Theiler's murine encephalomyelitis virus (WW strain) (TMEV-WW) was studied. Viral RNA was detected by autoradiography after in situ hybridization, using a ³H-labeled DNA probe complementary to virion RNA, which was applied to deparaffinized sections of central nervous system tissues from infected mice. Subjacent histological sections of tissues were used to assess the location and extent of lesions. Lesions were first observed at 20 days post-inoculation and appeared to enlarge throughout infection. They consisted of infiltrates of mononuclear cells and lymphocytes in spinal cord white matter and leptomeninges; at 78 days post-inoculation severe necrotizing and demyelinative myelitis and gliosis were observed. In contrast to the pathogenesis of brain-derived TMEV-WW-infected mice, no lesions were found in the central nervous system gray matter of mice infected with tissue culture-adapted TMEV-WW at any time post-infection. Tissue culture-adapted viral RNA was found in the cells of spinal cord white matter throughout infection; only one neuron in close proximity to the injection site was found to contain viral RNA shortly after infection. At early times after infection, spinal cord white matter cells containing viral RNA were found before development of inflammatory lesions; at later days post-inoculation, positive cells were found within, at the periphery of, or at a distance from lesions. The number of infected cells and the amount of viral RNA per cell appeared to remain constant from 20 to 78 days post-inoculation despite the increasing intensity of the inflammatory response. The nearly exclusive spinal cord white matter tropism of tissue culture-adapted TMEV-WW appeared to directly correlate with the disease-inducing potential of this virus.     

Primary demyelination in Theiler's virus infection. An ultrastructural study.

Theiler's virus infection in SJL/J mice was studied ultrastructurally at subsequent intervals after intracerebral inoculation. Extensive spinal cord lesions consisting of leptomeningeal and white matter mononuclear cell infiltrates with concomitant primary demylination were seen by 15 days. Stripping of myelin lamellae by invading mononuclear cell processes and vesicular disruption of myelin were demonstrated to be the patterns of myelin breakdown. Oligodendrocytes in the vicinity of demyelinating lesions never showed degenerative changes, and viral inclusions could not be found in any cells in the central nervous system. Remyelinating axons, first detected 21 days after infections, were more frequently seen in the late phase of the disease when conspicuous gliosis was also present. Active demyelination could still be observed as late as one year after infection at which time inflammation was decreased. However, plasma cells were relatively more numerous at later times after infection. These ultrastructural findings are similar to experimental allergic encephalomyelitis, and suggest an immune-mediated mechanism of demyelination in Theiler's virus infection.     

Mechanism of Theiler's virus-induced demyelination in nude mice

In its natural murine host, infection with Theiler's murine encephalomyelitis virus (TMEV) produces a chronic, progressive demyelinating disease. To help elucidate the role of host immune mechanisms involved in demyelination, we studied TMEV infection in Nude mice. These animals demonstrated rising titers of infectious virus within the central nervous system and failed to produce anti-TMEV antibody. Neurologic signs including the development of severe hind limb paralysis were evident approximately 2 weeks postinfection with most animals succumbing within the first month. Immunoperoxidase studies demonstrated viral antigen in the cytoplasm of neurons and glial cells for the entire period of observation. Plaques of demyelination associated with scanty inflammatory infiltrates were present in the spinal cord by 14 days postinfection. Electron microscopic studies of the involved white matter revealed numerous degenerating glial cells, many of which contained paracrystalline arrays of picornavirus within their cytoplasm. Some of the infected glial cells were identified as oligodendrocytes by demonstrating their myelin-plasma membrane connections. The studies indicate that in Nude mice TMEV causes a lytic infection of oligodendrocytes producing demyelination independent of the T lymphocyte immune system.     

Ultrastructural immunohistochemical localization of virus in acute and chronic demyelinating Theiler's virus infection.

Mice experimentally infected with Theiler's murine encephalomyelitis virus (TMEV) develop a persistent infection of the central nervous system (CNS). The most striking feature of this infection is the occurrence of inflammatory primary demyelination in the spinal cord white matter. The pathogenesis of myelin degeneration in this model has not been clarified, but morphologic and immunologic data suggest that the host immune response plays a major role in the production of myelin injury. Because of low virus titers in infected adult mice and of the small size of TMEV, virus particles have never been observed in this demyelinating model. Yet elucidation of the types of cells in the CNS supporting virus replication would be important for a better understanding of both virus persistence and virus-induced demyelinating pathology. The present paper is a sequential study of the localization of TMEV in the spinal cord in infected mice by ultrastructural immunohistochemical techniques. Results indicate that virus replication is mainly in neurons during the acute phase of the disease, while in the chronic phase viral inclusions are mainly found in macrophages in and around demyelinating lesions. Other cells are also infected, but to a lesser degree. In the neuronal system both axoplasmic and dendritic flow appear to facilitate the spread of virus in the CNS. In macrophages, the presence of virus particles and the association of virus with altered components of the cytoskeleton support active virus production rather than simple internalization. The macrophage appears to play an important role in both the establishment of virus persistence and in the process of demyelination in this animal model.     

Uncoupled relationship between demyelination and primary infection of myelinating cells in Theiler''s virus encephalomyelitis.

Theiler's virus infection in mice produces a chronic demyelinating disease which appears to be based on an immune pathogenesis rather than on direct viral destruction of myelin-supporting cells. The purpose of the present study is to ascertain whether viral antigen is present in the cytoplasm of such cells in areas of demyelination. Because of the difficulty of identifying oligodendrocytes in tissues rich in infiltrating mononuclear cells and fixed for immunohistochemistry, I turned to a recently described form of Theiler's virus encephalomyelitis which follows inoculation with the attenuated ww strain and is characterized by extensive spinal cord remyelination by invading Schwann cells and by recurrent demyelination of Schwann cell-remyelinated axons. The unlabeled antibody peroxidase-antiperoxidase technique was employed to study whether such spinal cord Schwann cells were primarily infected by virus at the time when recurrent demyelination was occurring. Whereas other types of cells, including neurons, astrocytes, and macrophages, contained abundant viral antigen, no positive immune reaction was observed in Schwann cells. These results correlate with our previous studies which had suggested that demyelination in this viral model is not dependent on primary viral attack on myelinating cells but is probably dependent on the host immune response.     

Theiler''s virus infection in mice: an unusual biphasic disease process leading to demyelination.

An unusual biphasic central nervous system disease developed in 3-week-old Swiss outbred mice after intracerebral inoculation of the DA strain of Theiler's murine encephalomyelitis virus. Nine to 20 days postinfection 86% of mice became paralyzed, and approximately one-half of these animals survived. During this period neuronal necrosis and microglial proliferation were seen in thalamus, brainstem, and spinal cord. There was an initial phase of virus growth in spinal cord followed by persistent infection at a lower concentration. Virus antigen was readily found in the cytoplasm of neurons by immunofluorescent staining early in the course of infection, whereas after 30 days there was a paucity of cells containing virus antigen which were present only in the spinal cord white matter. Between 1 and 5 months, an intense mononuclear inflammatory cell lesion evolved in the spinal cord leptomeninges and white matter, which coincided with a mild gait disturbance in some surviving mice, and patchy demyelination was found in areas of inflammation. The acute gray matter pathology would appear to be the result of direct virus lytic effect. Although the late white matter lesion culminating in demyelination probably represents a cytocidal infection similar to the situation that exists in certain picornavirus carrier culture systems, a virus-induced immunopathological process merits further study.     

Murine central nervous system infection by a viral temperature-sensitive mutant: a subacute disease leading to demyelination.

Temperature-sensitive (ts) mutants of viruses may represent an important mechanism for viral persistence. Ts mutants of different complementation groups of vesicular stomatitus virus (VSV) have shown various disease patterns in infected mice which were at variance with the clinical and pathologic features of wild-type virus infection. To investigate whether neurovirulence of different ts mutants was dependent on the individual mutant or on the biochemical defect(s) common to all members of a complementation group, we infected mice with ts G32 VSV, a mutant of the same complementation group III as the previously described ts G31 VSV. Pathologic changes in infected mice were sharply different from those produced by ts G31 VSV and actually similar to those produced by ts G41 VSV, a member of Complementation Group IV, also previously described. These results suggest that the biologic behavior of ts mutants is dependent on the individual characteristics of each mutant. The most important alterations by ts G32 VSV were in the white matter of brain and spinal cord, where extensive inflammatory demyelination was observed. Lack of inflammation and demyelination in similarly infected nude mice would suggest that, in this infection, demyelination is produced by the host immune response rather than by direct viral myelinolytic activity. Such findings are similar to those we described in other viral infections and support the hypothesis of a common host-mediated pathway leading to demyelination in a variety of unrelated viral infections. These conclusions may have relevance to human demyelinating diseases.     

Identification of the spinal cord as a major site of persistence during chronic infection with a murine coronavirus

After intranasal inoculation, mouse hepatitis virus (MHV) gains entry into the central nervous system (CNS) via the olfactory and trigeminal nerves. Under the appropriate conditions, some mice develop clinically apparent demyelinating encephalomyelitis several weeks later, with virus always present in the spinal cord. To determine the pathway by which virus reaches the cord, brains and spinal cords of infected, asymptomatic mice were analyzed by in situ hybridization. Viral RNA was always detected in the anterior part of the upper spinal cord. A similar analysis of mice with the recent onset of hindlimb weakness showed that viral RNA was detected in the same location. The results suggest that MHV is transported to the spinal cord via well-defined neuroanatomic pathways and that viral amplification with resultant clinical disease occurs from this site of persistence in the anterior spinal cord. This process of viral amplification may involve the generation of viral variants as has been described for MHV-infected rats. No major changes in viral RNA or protein could be detected when MHV isolated from mice with hindlimb paralysis was analyzed. The data suggest that the generation of viral variants is not important in the pathogenesis of the late onset of neurological disease induced by MHV in mice.     

Location and distribution of virus antigen in the central nervous system of mice persistently infected with Theiler's virus.

The present study has shown that virus can be readily detected by immunofluorescent staining in the central nervous system (CNS) of SJL mice persistently infected with Theiler''s murine encephalomyelitis virus (TMEV). Considering the low CNS virus content, large amounts of virus antigen were found in the white matter, the site of demyelinating lesions. Virus antigen was detected in all animals killed after post-infection (PI) Day 21, a time which can be considered as the beginning of the persistent phase of this infection, and the appearance of virus antigen in white matter corresponded closely in time with the onset of demyelination. The pathogensis of this persistent infection can now be reasonably well reconstructed from the temporal observations made in this study. It would appear that between the second and third week PI, virus replication largely shifts from neurons in spinal cord gray matter to other cell types located in white matter. While a lower-grade persistent infection (in terms of the relative number of cells containing virus antigen) is established and maintained in cells in the gray matter and inflammatory and leptomeningeal infiltrates, cells in white matter appear to be mainly responsible for perpetuating the infection. Why these cells should supplant neurons as the most susceptible host cell during the chronic phase of the infection is discussed.     

Location and distribution of virus antigen in the central nervous system of mice persistently infected with Theiler's virus

The present study has shown that virus can be readily detected by immunofluorescent staining in the central nervous system (CNS) of SJL mice persistently infected with Theiler's murine encephalomyelitis virus (TMEV). Considering the low CNS virus content, large amounts of virus antigen were found in the white matter, the site of demyelinating lesions. Virus antigen was detected in all animals killed after post-infection (PI) Day 21, a time which can be considered as the beginning of the persistent phase of this infection, and the appearance of virus antigen in white matter corresponded closely in time with the onset of demyelination. The pathogensis of this persistent infection can now be reasonably well reconstructed from the temporal observations made in this study. It would appear that between the second and third week PI, virus replication largely shifts from neurons in spinal cord gray matter to other cell types located in white matter. While a lower-grade persistent infection (in terms of the relative number of cells containing virus antigen) is established and maintained in cells in the gray matter and inflammatory and leptomeningeal infiltrates, cells in white matter appear to be mainly responsible for perpetuating the infection. Why these cells should supplant neurons as the most susceptible host cell during the chronic phase of the infection is discussed.     

Genetic deletion of a single immunodominant T-cell response confers susceptibility to virus-induced demyelination

An important question in neuropathology involves determining the antigens that are targeted during demyelinating disease. Viral infection of the central nervous system (CNS) leads to T-cell responses that can be protective as well as pathogenic. In the Theiler's murine encephalomyelitis virus (TMEV) model of demyelination it is known that the immune response to the viral capsid protein 2 (VP2) is critical for disease pathogenesis. This study shows that expressing the whole viral capsid VP2 or the minimal CD8-specific peptide VP2(121-130) as "self" leads to a loss of VP2-specific immune responses. Loss of responsiveness is caused by T cell-specific tolerance, as VP2-specific antibodies are generated in response to infection. More importantly, these mice lose the CD8 T-cell response to the immunodominant peptide VP2(121-130), which is critical for the development of demyelinating disease. The transgenic mice fail to clear the infection and develop chronic demyelinating disease in the spinal cord white matter. These findings demonstrate that T-cell responses can be removed by transgenic expression and that lack of responsiveness alters viral clearance and CNS pathology. This model will be important for understanding the mechanisms involved in antigen-specific T-cell deletion and the contribution of this response to CNS pathology.     

Regional localization of virus in the central nervous system of mice persistently infected with murine coronavirus JHM

Suckling C57BL/6 mice infected with mouse hepatitis virus strain JHM (MHV-JHM) develop either a fatal acute encephalomyelitis or a late onset demyelinating disease, depending on whether they are nursed by unimmunized or immunized dams. To determine the localization of virus-specific RNA, serial sections of brains from infected and uninfected mice were annealed with a 35S-labeled antisense RNA probe and analyzed by film autoradiography. In the mice with acute encephalomyelitis, viral RNA was present in the mesencephalon, hypothalamus, hippocampus, basal ganglia, subcortical white matter, and thalamus. Viral RNA was detected in the spinal cords of all mice with the late onset, demyelinating encephalomyelitis, but was distributed into three different patterns in the brains of these mice, even though all had the same clinical disease. In the first group, viral RNA was detected only in the brainstem. In the second group, viral RNA was detected in the brainstem, thalamus, and cerebral grey matter. This distribution was consistent with viral spread along well-defined tracts connecting these parts of the brain. In the third group, viral RNA could be detected both in the brainstem and in several white matter tracts within close physical proximity to the optic chiasm. This distribution was consistent with viral spread by an extracellular route from one white matter tract to other tracts which were physically close, but which were not part of the same pathways. These results suggest that MHV-JHM spreads through the central nervous system both along well-defined neuronal pathways and by spread from contiguous structures, but also suggest that viral replicates preferentially in a limited number of areas of the brain. The technique of in situ hybridization with film autoradiography should be generally useful for analyzing macroscopic movements of virus within infected organs.     

Direct comparison of demyelinating disease induced by the Daniel's strain and BeAn strain of Theiler's murine encephalomyelitis virus

We compared CNS disease following intracerebral injection of SJL mice with Daniel's (DA) and BeAn 8386 (BeAn) strains of Theiler's murine encephalomyelitis virus (TMEV). In tissue culture, DA was more virulent then BeAn. There was a higher incidence of demyelination in the spinal cords of SJL/J mice infected with DA as compared to BeAn. However, the extent of demyelination was similar between virus strains when comparing those mice that developed demyelination. Even though BeAn infection resulted in lower incidence of demyelination in the spinal cord, these mice showed significant brain disease similar to that observed with DA. There was approximately 100 times more virus specific RNA in the CNS of DA infected mice as compared to BeAn infected mice. This was reflected by more virus antigen positive cells (macrophages/microglia and oligodendrocytes) in the spinal cord white matter of DA infected mice as compared to BeAn. There was no difference in the brain infiltrating immune cells of DA or BeAn infected mice. However, BeAn infected mice showed higher titers of TMEV specific antibody. Functional deficits as measured by Rotarod were more severe in DA infected versus BeAn infected mice. These findings indicate that the diseases induced by DA or BeAn are distinct.     

Theiler's virus-induced demyelination in mice immunosuppressed with anti-IgM and in mice expressing the xid gene

Intracerebral infection with Theiler's murine encephalomyelitis virus produces chronic immune-mediated demyelination in susceptible strains of mice. We examined the role of Ig in the pathogenesis of demyelination. In susceptible SJL/J mice (H-2s), suppression of B cell responses with IgG fraction of goat anti-mu (anti-mu IgG) from birth resulted in increased numbers and severity of demyelinating lesions in the spinal cord 35 days after infection. In contrast, treatment of resistant C57BL/10 (H-2b), C57BL/6 (H-2b), or B10.D2 (H-2d) mice with anti-mu IgG had no apparent effect since these mice did not develop demyelination or inflammation in the spinal cord following infection. Similar results were obtained with certain strains of B-cell deficient mice that exhibit the xid gene mutation. Male CBA/NJ (xid) showed increased meningeal inflammation and demyelination compared to male CBA/J mice. However, B6.CBAN, C3.CBAN, or C.CBAn mice showed no or minimal evidence of demyelination despite the presence of the xid mutation. In the SJL/J mouse, the majority of the humoral immune response to virus antigen was restricted to the IgG2b and IgM isotypes. These data indirectly support the hypothesis that immunoglobulins protect partially against development of virus-induced demyelination in susceptible but not resistant animals. In addition, the data argue strongly against the hypothesis that TMEV-induced demyelination is mediated predominantly by humoral autoimmune or humoral viral immune mechanisms.     

Remyelination during remission in Theiler's virus infection.

Inoculation of the cell-adapted WW strain of Theiler's virus into mice produces a chronic demyelinating infection of the central nervous system (CNS) characterized by a remitting relapsing course. During remission, extensive remyelination of spinal cord white matter is observed. Remyelination is carried out by both Schwann cells and oligodendrocytes. This paper examines the possible mechanisms of entry of Schwann cells into the CNS, their possible source in different regions of the white matter, their relations with various CNS elements, and the relative activity of these cells versus that of oligodendrocytes. Observations suggest that Schwann cells, originating from peripheral roots and from perivascular areas, migrate into white matter through gaps in the glial limiting membrane ( GLM ), probably caused by active mononuclear inflammatory cells. Schwann cell invasion and axonal contact appear to be facilitated by the presence of collagen matrix along their pathway of migration. No alterations of astrocytes in the immediate vicinity of Schwann cells were observed, and free contact between Schwann cells and different neuroglial elements was present in the initial stages of Schwann cell migration. While Schwann cells were the predominant myelinating cells in the outer white matter, oligodendrocytes were numerous and very active in the inner portions of the spinal cord column. Although oligodendrocytes produced thinner myelin than normal, in most areas essentially complete remyelination by these cells was observed. These results contrast with those of previous studies of DA infected mice in which remyelination is sporadic in the presence of unabated inflammation which continues without remission for many months after infection. It is suggested that oligodendroglial cells are quite capable of extensive remyelinating activity in this infection, provided the noxa responsible for myelin injury subsides. The host inflammatory response appears to be the most likely noxa impeding remyelination in this model.