key: cord-0698730-grarghun
authors: Lavi, Ehud; Das Sarma, Jayasri; Weiss, Susan R.
title: Cellular Reservoirs for Coronavirus Infection of the Brain in β(2)-Microglobulin Knockout Mice
date: 1999-02-22
journal: Pathobiology
DOI: 10.1159/000028054
sha: 54e7613db665a936a70e50bc9edf9cfed65922c9
doc_id: 698730
cord_uid: grarghun

Mouse hepatitis virus (MHV) A59 infection which causes acute encephalitis, hepatitis, and chronic demyelination, is one of the experimental models for multiple sclerosis. Previous studies showed that lethal infection of β(2)-microglobulin ‘knockout’ (β(2)M(-/-)) mice required 500-fold less virus and viral clearance was delayed as compared to infection of immunocompetent C57Bl/6 (B6) mice. To investigate the mechanism of the increased susceptibility of β(2)M(-/-) mice to MHV-A59, we studied organ pathology and the distribution of viral antigen and RNA during acute and chronic infection. A59-infected β(2)M(-/-) mice were more susceptible to acute encephalitis and hepatitis, but did not have increased susceptibility to demyelination. Viral antigen and RNA distribution in the brain was increased in microglia, lymphocytes, and small vessel endothelial cells while the distribution in neurons and glia was similar in β(2)M(-/-) mice and B6 mice. Acute hepatitis and thymus cortical hypoplasia in β(2)M(-/-) mice were delayed in onset but pathologic changes in these organs were similar to those in B6 mice. The low rate of demyelination in β(2)M(-/-) mice was consistent with the low dose of the virus given. A less neurotropic virus MHV-2, caused increased parenchymal inflammation in β(2)M(-/-) mice, but without demyelination. Thus, CD8+ cells were important for viral clearance from endothelial cells, microglia and inflammatory cells, but not from neuronal and glial cells. In addition, CD8+ cells played a role in preventing the spread of encephalitis.

Coronavirus mouse hepatitis virus (MHV) is a singlestranded enveloped RNA virus of positive polarity [1] [2] [3] . MHV infection of mice provides an excellent model for studying acute and chronic persistent diseases of the central nervous system (CNS) [2, [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] . Certain strains of the MHV (such as A59 and JHM), produce a chronic demyelinating disease, probably due to immune mediated mechanisms, sharing many of the pathologic hallmarks with those of the human demyelinating disease multiple sclerosis (MS) [12] [13] [14] .

The nature of the immune component responsible for the demyelinating process in MHV is not clearly understood. MHV infection of the CNS induces enhanced expression of MHC class I antigens on brain cells in vitro and in vivo [15] [16] [17] [18] [19] . However, the significance of MHC induction in mHV infection is still not clear. It can poten-tially enable cytotoxic phenomena on neural cells including oligodendrocytes, by CD8+ cells which require recognition by MHC class I antigens on the surface of the target cells. In SCID mice, in which the B-and T-cell immune components are nonfunctional, infection by MHV does not produce significant demyelination [20] , suggesting that a subset of the affected immune cells in SCID mice are important for demyelination. The cells which affect the rate and quality of the demyelinating process were characterized as Thy1+ cells [21] , presumably a subset of T cells.

Cytotoxic, CD8+, T cells, were shown to be important for clearance of MHV infection [22] , although, perforinmediated cytolysis was not essential for viral clearance [23] . In order to examine whether CD8+ cells also affected demyelination, we previously studied the ability of MHV-A59 to produce demyelination in ß 2 -microglobulin 'knockout' (ß 2 M(-/-)) mice [24, 25] . Since the ß 2microglobulin is part of the MHC class I protein, disruption of ß 2 -microglobulin expression interferes with normal expression of MHC class I and the development of functional CD8+ cells in ß 2 M(-/-) mice [26] . We found that demyelination developed in some ß 2 M(-/-) mice following infection with a lethal dose of MHV-A59, thus CD8+ cells were not an absolute requirement for demyelination [24] . However, the pathogenesis of the disease and the reasons for the increased susceptibility of ß 2 M(-/-) mice to MHV infection were still unknown. Thus, in the present study we investigated the effect of lack of CD8+ cells on organ pathology, and the cellular reservoirs for viral infection, in both acute and chronic MHV infection of ß 2 M(-/-) mice.

Viruses Cells and Mice MHV-A59 [10] and MHV-2 [27] were used in this study. Viruses were propagated and assayed on L2 murine fibroblast cells at 37°C, propagated in DMEM (Gibco) containing 10% heat-inactivated fetal bovine serum and 1% penicillin/streptomycin.

Four-week-old, C57Bl/6 (B6) mice (Jackson Laboratories, Bar Harbor, Me., USA), were used. ß 2 M(-/-) mice were originally obtained from Dr. Beverly Koller [26] , and were inbred at the University of Pennsylvania. Mice were produced by the combination of B6 and 129/J [24] . Additional ß 2 M(-/-) mice were purchased from Jackson Laboratories. The lethal dose of MHV-A59 that killed 50% of the mice (LD 50 dose) was found to be 5 PFU/mouse, compared to 3,000 PFU in B6 mice [24] . Groups of 3-5 per time point, 4-week-old mice, were inoculated intracerebrally (IC) with 20 Ìl of the viruses, and were sacrificed by methoxyflurane overdose at various intervals postinoculation (1, 3, 5, 7, 9, 11, 15, 30 days postinoculation) and perfused intracardially with PBS and 10% phosphate-buffered for-malin. Control mice were mock-infected with the same volume of sterile L2 cell lysate not containing virus. To ensure that the colony of ß 2 M(-/-) mice was truly deficient of CD8+ cells, random analyses of cells from the spleen and lymph nodes from uninfected ß 2 M(-/-) mice were carried out. These populations of cells were consistently negative for the presence of CD8+ or ß 2 -microglobulin as assayed by fluorescence-activated cell-sorting assays [24] .

Mice were perfused with 10 ml PBS, then 10 ml of 10% buffered formalin (Sigma, St. Louis, Mo., USA) and organs, including thymus, liver, brain and spinal cord, were removed and fixed in formalin for at least an additional 48 h. In selected mice the entire block of internal organs was removed and fixed in formalin. Individual organs were then dissected and processed for embedding in paraffin. Tissues were embedded in paraffin, sectioned at 5 ÌM and stained with hematoxylin and eosin (HE). Brain and spinal cord sections were also stained with Luxol Fast Blue for myelin. For each animal at least 5 coronal sections of brain and multiple sections of cervical, thoracic, and lumbar spinal cord were prepared. Additional mice were perfused with 2% glutaraldehyde (Sigma) and spinal cord sections were embedded in Epon, sectioned at 1 ÌM and stained with toluidine blue [10] . The sections were examined for evidence of primary demyelination (loss of myelin sheaths surrounding intact neuronal axons).

For assessment of viral titers, organs were removed from mice aseptically following PBS perfusion and kept frozen at -80°C. These samples were homogenized, and tested for viral titers by plaque assays in 6-well plates [10, 24] .

Formalin-fixed, paraffin-embedded unstained 5-ÌM sections were used. Immunohistochemistry was performed using the ABC Elite immunoperoxidase kit (Vector Laboratories, Burlingame, Calif., USA) with diaminobenzidine as substrate and rabbit polyclonal anti-MHV antibodies used at a 1:100 dilution [28] . Control experiments included incubation of sections with the same concentration of an irrelevant antibody of matched haplotype.

To detect viral RNA, in situ hybridization was performed on tissue sections from MHV-A59-infected ß 2 M(-/-) mice. The nature of the cell types infected with the virus was determined using a combination of in situ hybridization for viral RNA with cell-specific markers (GFAP antibodies for astrocytes and RCA-1 for microglia and endothelial cells) as previously described [29] . Paraffin-embedded, formalin-fixed tissues were placed on heavy teflon (HTC) slides (Cell-Line Associates, Newfield, N.J., USA) deparaffinized, air-dried and histochemistry performed with anti-GFAP monoclonal antibodies at 1:500 dilution [30] , or RCA-1 (Sigma). After permeabilization with pepsin (2 mg/ml in 0.1 N HCl for 15 min at 37°C) the slides were washed in 0.1 M Tris buffer (pH 7.4) for 1 min, then in 100% ethanol, and then air-dried. MHV RNA was detected by in situ hybridization with a biotinylated oligonucleotide probe composed of S-gene sequences 5)TATAAGAGTGATTGGCGTCC3). An oligonucleotide probe derived from the HIV gag gene 5)ATCCTGGGAT-TAAATAAAATAGTAAGAATGTATAGCCCTAC3) was used as control. The hybridization mixture contained 1 nmol/100 Ìl of probe, 5 ! SSC, 1% blocking reagent (BMB), 0.1% N-lauroylsarcosine and 0.2% SDS. The slides were covered, incubated on a heat block for 10 min at 95°C, and transferred to a humidified chamber for 12 h at 45°C. After incubation the slides were first washed in 2 ! SSC, 0.1% SDS for 15 min, and then in 0.1% SDS for 15 min at 37°C. Slides were then incubated with streptavidin alkaline phosphatase (sheep) for 2 h at 37°C. After incubation, the slides were washed in 0.1 M Tris buffer (pH 7.4). The signal was colorized with NBT/BCIP.

We previously found that ß 2 M(-/-) mice were significantly more susceptible to infection with MHV-A59, as compared to the two parental strains of mice that were used for the development of these transgenic mice, i.e. B6 and 129/J [24] . Disease in either B6 or 129/J mice was identical. Normal susceptible mice (B6) infected with 5,000 PFU/mouse (1-2 LD 50 dose) of the neurotropic virus MHV-A59 developed both encephalitis and hepatitis. Following IC inoculation with 10 PFU of MHV-A59 (2 LD 50 ), ß 2 M(-/-) mice developed clinical signs of acute disease including ruffled fur, hunched position, decreased motility and appetite, lethargy, limb weakness, and eventually death. These clinical signs were similar to the ones observed in B6 mice infected with 5,000 PFU of MHV-A59. Thus, ß 2 M(-/-) mice required 500-fold less virus than B6 mice to produce a similar mortality rate and clinical disease. Previous analysis of viral titers in organs of the two types of mice infected with MHV-A59 showed that ß 2 M(-/-) mice infected with 10 PFU had higher and more sustained titers of virus as compared to B6 mice infected with 5,000 PFU of MHV-A59 [24] . These results were consistent with the hypothesis that CD8+ cells play an important role in MHV clearance from the organs of infected mice.

We next sought to investigate the cellular reservoirs which cause the increased susceptibility to and the increase in virulence of MHV-A59 in ß 2 M(-/-) mice. Therefore, we compared the histopathological changes in ß 2 M(-/-) mice and B6 mice both injected with doses that produce comparable clinical effect, i.e. 1-2 LD 50 dose. We also compared the pathological changes in these two strains of mice given the same dose of virus. A dose of 10 PFU of MHV-A59 in B6 mice did not produce any clinical disease and the only pathologic change was minimal meningeal infiltration. A dose of 5,000 PFU of MHV-A59 in ß 2 M(-/-) mice killed all the mice but the pathologic changes obtained at necropsy were similar to the ones seen with 10 PFU.

The histopathologic changes in ß 2 M(-/-) mice infected with 10 PFU of MHV-A59 are summarized in table 1. Between 7 and 13 days postinoculation, 100% of the mice had pathological changes in the brain, liver and thymus. We analyzed all of the other organs for histopathological change in order to determine if organs other than liver and brain may be involved in acute infection in ß 2 M(-/-) mice, providing additional cellular reservoirs for viral replication. No pathologic changes were seen in the heart, lung, gastrointestinal tract, spleen, pancreas, adrenals, genital organs, salivary glands, bone marrow, skin or muscle in any of the mice.

Examination of the livers of ß 2 M(-/-) mice infected with 10 PFU of MHV-A59 revealed a more prolonged course of acute hepatitis. In B6 mice, hepatitis began 3 days postinfection and was cleared by 2 weeks postinfection; whereas in ß 2 M(-/-) mice, hepatitis was not seen before 7-8 days postinfection. On day 21 postinfection, 2 of 3 mice still exhibited chronic persistent hepatitis, with mononuclear inflammatory infiltrates within foci of damaged hepatocytes and the beginning of microvacuolar lipidization of hepatocytes. Thus acute hepatitis in ß 2 M(-/-) mice was delayed in onset and clearance, but was similar in morphologic aspects and in the extent of tissue damage to acute hepatitis in B6 mice.

Examination of the thymus of ß 2 M(-/-) mice infected with 10 PFU of MHV-A59 showed evidence of cortical depletion of lymphocytes. The thymus cortex was transformed into a skeleton of epithelial cells and blood vessels and only a small number of lymphocytes remaining. The thymic cortex of uninfected or mock-infected ß 2 M(-/-) mice was densely populated with lymphocytes. There were no significant changes in the thymic medulla. These changes were observed between days 7 and 13 postinfection and were similar to the ones observed in B6 mice infected with MHV-A59. Viral titers of thymus from infected mice were negative by plaque assay.

Brain pathology following MHV-A59 infection in B6 mice consisted of focal acute encephalitis, characterized by microglial nodules, neuronophagia and inflammatory infiltrates, mostly lymphocytes, in regions of the brain typically susceptible to MHV-A59 infection. These areas included the olfactory bulbs, the prepiriform and piriform cortex, the septal nuclei, the claustrum, the lateral habenula, the parahippocampal and entorhinal cortex, the subiculum, amygdala, subthalamic nuclei and substantia nigra, the ventral tegmental area, and the locus ceruleus. Areas of the neocortex and cerebellum were generally Pathobiology 1999;67:75-83

Lavi/Sarma/Weiss spared as previously described [10, 28, 31] . Histopathologic examination of the brain of ß 2 M(-/-) mice infected with 10 PFU of MHV-A59 also showed meningoencephalitis with predilection for olfactory-limbic structures similar to the changes seen in MHV-A59-infected B6 mice. However, there was more extensive involvement of the basal ganglia and thalamus of ß 2 M(-/-) mice as compared to B6-infected mice. Both B6 and ß 2 M(-/-) mice showed no significant involvement of neocortex and cerebellum in infected ß 2 M(-/-) mice.

The brain of MHV-A59-infected ß 2 M(-/-) mice was infiltrated by mononuclear inflammatory cells, mostly lymphocytes, as in MHV-A59-infected B6 mice. However, there was more extensive proliferation of rodshaped microglial cells in involved areas in ß 2 M(-/-) mice as compared to acute encephalitis in B6 mice. Control mock-infected mice did not exhibit any specific pathological changes in any of the organs.

Since viral titers in brains of ß 2 M(-/-) mice were generally 2 logs higher at the peak of acute infection of the brain [24] , we wanted to analyze the spread of viral antigens and genome. We asked whether the number of infected cells was increased and whether additional cell types served as reservoirs for viral replication during infection of ß 2 M(-/-) mice with MHV-A59. We performed immunohistochemistry on brain sections from ß 2 M(-/-) mice, during acute infection with MHV-A59, to detect the presence of viral antigen. Immunohistochemistry in ß 2 M(-/-) mice revealed viral antigen in neurons in a similar intensity and anatomic distribution to that seen in B6 mice [28] . The infected neurons seen during acute encephalitis were generally found in the same anatomic location of the inflammatory infiltrates (as described in the previous section). However, there was increased viral antigen in numerous microglia, lymphocytes, endothelial and meningeal cells in ß 2 M(-/-) mice as compared to B6 mice [28] which rarely presented viral antigens in these cell types during infection with MHV-A59 ( fig. 1 ). We performed in situ hybridization on tissue sections of MHV-A59-infected ß 2 M(-/-) mice with MHV-specific probes, in order to determine the distribution of viral genome during acute encephalitis. Viral RNA and antigen had similar distribution. The signal of viral RNA in MHV-A59-infected ß 2 M(-/-) mice was seen within neurons in olfactory-limbic areas in addition to many microglia, perivascular lymphocytes, and in capillary endothelial cells. Double staining with GFAP revealed many GFAP-negative cells, positive for viral RNA. There were also many GFAP-positive cells which were negative for viral RNA. Many of these cells had abundant cytoplasm and ramified thick processes characteristic of reactive astrocytes, indicating reactive gliosis. Occasional GFAPpositive cells were also positive for viral RNA suggesting that only a small percent of astrocytes are infected ( fig. 1 ). Thus during acute infection of ß 2 M(-/-) mice with MHV-A59, the distribution of viral RNA and antigen were similar in neurons, microglia endothelial cells and a small number of glial cells including GFAP-positive astrocytes. The pathologic changes during acute meningoencephalitis also included reactive gliosis. In situ hybridization for viral genome combined with RCA-1 staining showed viral genome in microglia and endothelial cells, similar to the immunohistochemical results for viral antigens.

Liver sections from MHV-A59-infected ß 2 M(-/-) mice were also examined by immunohistochemistry for the presence of viral antigen. Staining revealed similar distribution of viral antigen in ß 2 M(-/-) and B6-infected mice. The thymus was the only other organ, besides the brain and liver, to exhibit pathologic changes. Immunohistochemistry with anti-MHV antibodies was performed on thymus sections from MHV-A59-infected ß 2 M(-/-) mice, to rule out possible viral replication in the thymus. However, there was no evidence of viral antigen present in the thymus of MHV-A59-infected ß 2 M(-/-) mice. Control immunohistochemical and in situ hybridization experiments using irrelevant antibodies and probes on adjacent sections were all negative.

We showed previously that chronic demyelinating lesions can develop in ß 2 M(-/-) mice; thus CD8+ lymphocytes were not an absolute requirement for MHV-induced demyelination [24] . To further quantify the degree of demyelination in chronically infected ß 2 M(-/-) mice, we examined demyelination using Epon-embedded, 1-ÌM thick spinal cord sections, stained with toluidine blue and examined by light microscopy. We found only minute foci of demyelination in 14 of 200 quadrants of spinal cord cross sections in 15 ß 2 M(-/-) mice infected with 10 PFU of MHV-A59 (table 1). In the majority of the cases, the lesions were significantly smaller than the ones seen in B6 mice infected with 5,000 PFU of MHV-A59. In some spinal cord sections we found foci of inflammatory cells within the meninges but no evidence of demyelination in adjacent white matter. This degree of demyelination was similar to that observed in B6 mice receiving the same amount of virus (10 PFU) [32] . In B6 mice receiving 5,000 PFU, demyelination was found in all of 5 mice in 65% of the quadrants, which is the usual degree of demyelination produced by MHV-A59 in B6 mice [32] .

A less neurotropic strain of MHV, MHV-2, which normally does not invade the brain parenchyma in B6 mice, was used in comparison to A59 in order to evaluate the protective effect of CD8+ cells on viral invasion of the brain. Four-week-old ß 2 M(-/-) mice were inoculated i.c. with MHV-2 and analyzed, at various intervals postinfection, for histopathology and viral titers in organs. Histology revealed both acute hepatitis and acute encephalitis. Acute encephalitis was observed in several periventricular areas especially the lateral and 4th ventricles. Mononuclear lymphocytic infiltration involved the choroid plexus, the ependyma and in the surrounding brain parenchyma especially in the brainstem ( fig. 2 ). There was no involvement of other areas of the brain including areas that are typically involved in A59 infection of B6 mice. By contrast, B6 mice infected with MHV-2 showed mostly inflammation of the meninges and choroid plexus while brain parenchyma was only minimally involved. Sustained titers of infectious virus were detected by plaque assay were detected in both brains and livers of ß 2 M(-/-) mice infected with MHV-2. Titers peaked at 3 and 5 days after MHV-2 infection of B6 mice ( fig. 3 ). Neither B6 mice nor 5 ß 2 M(-/-) mice sacrificed 30 days postinfection with 1 LD 50 dose of MHV-2, showed any evidence of demyelination in Epon-embedded sections stained with toluidine blue.

The ability of mice devoid of ß 2 -microglobulins and MHC class I expression to survive without functional CD8+ cytotoxic T cells [26] provided a unique opportunity to study the contribution of CD8+ cells to the disease process induced in mice by coronavirus infection. Al- though ß 2 M(-/-) mice may occasionally retain a very small number of functional CD8+ lymphocytes [33] , ß 2 M(-/-) mice have been useful for studies of viral pathogenesis. For example, ß 2 M(-/-) mice exhibited delayed clearance and increased mortality following influenza virus challenge [34] . Lymphocytic choriomeningitis virus (LCMV) infection induced a chronic wasting disease in ß 2 M(-/-) mice [35] . In the LCMV model system, CD4+ CTLs may partially compensate for the lack of CD8+ CTLs [36] . However, CD8+ lymphocytes were not required for clearance of vaccinia virus or cytomegalovirus infections [37, 38] .

We carefully dissected and compared the disease process in ß 2 M(-/-) mice to that produced in normal B6-susceptible mice in order to further study the role of CD8+ cells in the pathogenesis of MHV infection. ß 2 M(-/-) mice were more susceptible to the virus, showed prolonged course of the disease and had sustained titers of the virus in the brain and liver. The time frame for initiation of disease in the meninges and brain was not significantly different in ß 2 M(-/-) mice compared to B6infected mice. However, following i.c. inoculation, hepatitis was delayed in onset in ß 2 M(-/-) mice compared to B6 mice. The lack of CD8+ cells had a different effect on various components of the disease process induced by MHV, suggesting that each part of this disease process is independently controlled. In addition, the lack of CD8+ cells increased MHV-2-induced encephalitis without affecting the ability of mice to develop demyelination.

We performed an exhaustive search for additional reservoir of infection in organs other than the brain and . ß 2 M(-/-) mice were infected IC with 5 ! 10 3 PFU of virus and B6 mice were infected IC with 5 ! 10 5 PFU of virus then sacrificed at various intervals postinfection; organs were aseptically removed and viral titers were determined by plaque assay. liver in order to explain the increased susceptibility of ß 2 M(-/-) mice to MHV infection. We ruled out the thymus as a potential reservoir since there was no evidence of active viral replication in the thymus of infected ß 2 M(-/-) mice or B6 mice by immunohistochemistry and plaque assay. This was consistent with a previous report showing that thymic pathology of lymphocytic depletion in mice infected with MHV is mainly due to apoptosis, possibly mediated by cytotoxic cytokines and not due to active viral replication [39] .

Since the extent of hepatitis and the histopathologic changes in the livers of ß 2 M(-/-) mice were similar to B6 mice during acute infection and no additional organs showed any pathologic abnormalities, we concluded that the main cause of the increased virulence and mortality in ß 2 M(-/-) mice was the increased CNS replication. During acute encephalitis in ß 2 M(-/-) mice there was slight change in the anatomical pattern of spread of the virus, in that the thalamus and basal ganglia had more extensive involvement. The amount of involvement of neuronal and glial cells infection was relatively similar in ß 2 M(-/-) mice and B6 mice. The main change in CNS disease in ß 2 M(-/-) mice was in additional cellular reservoirs of infectious virus in cell types that are not typically involved or only minimally infected in MHV-A59 infection of B6 mice. This included perivascular lymphocytes, microglia, and endothelial cells. Thus, CD8+ cells may play a role in clearance of virus from these cell types, causing increased susceptibility of the ß 2 M(-/-) mice to MHV-A59.

We then compared infection of ß 2 M(-/-) mice by two different strains of MHV, which have different neurotropic phenotypes in B6 mice, in order to further assess the role of CD8+ cells in preventing spread of MHV within the brain. MHV-2 and MHV-A59 are closely related strains of MHV exhibiting over 80% homology in nucleotide sequences [Das Sarma et al., manuscript in preparation]. However, the two strains differ in the degree of CNS involvement. While MHV-A59 produces acute encephalitis and chronic demyelination, MHV-2 produced much less encephalitis and no demyelination. We asked whether mice lacking CD8+ show more parenchymal involvement in MHV-2 infection, in order to explore the possible role of CD8+ cells in brain invasion and demyelination. Our results demonstrated that MHV-2 infection in ß 2 M(-/-) mice produced significant brainstem encephalitis without demyelination, while parenchymal involvement in MHV-2-infected B6 mice was minimal. Thus, CD8+ cells may affect the spread of MHV within the brain, but have no effect on demyelination.

As previously demonstrated [24] , the extent of demyelination was reduced in ß 2 M(-/-) mice as compared to B6 mice when each type of mice are given 1-2 LD 50 dose of virus (10 PFU in ß 2 M(-/-) mice and 3,000 PFU in B6 mice). The reduced rate of demyelination in ß 2 M(-/-) mice may be due to the lower dose of virus used and the finding that the lack of CD8+ cells did not affect the susceptibility of mice to demyelination, despite the increased susceptibility to hepatitis and encephalitis [32] .

Studies of ß 2 M(-/-) mice with Theiler's virus, another experimental model system of virus-induced demyelination, showed that CD8+ cells were required for clearance of virus and protection of the brain from infection and subsequent demyelination in a resistant strain [40] [41] [42] . In addition, remyelination was more extensive in the ß 2 M(-/-) mice infected with Theiler's virus which suggested that CD8+ cells may have a role in preventing remyelination [43] .

In conclusion, CD8+ cells may have an important role in clearance of virus from infected inflammatory cells, endothelial cells and microglial cells, during acute MHV infection of the brain. However, CD8+ cells had less effect on viral clearance from primary CNS cells such as neurons astrocytes and oligodendrocytes which probably use different mechanisms of clearance. Failure to achieve complete viral clearance from the CNS, especially in oligodendrocytes and astrocytes, may result in viral persistence and chronic demyelination. Our studies showed no evidence of a direct role of CD8+ cells in chronic demyelination.

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