The leader polypeptide of Theiler's virus is essential for neurovirulence but not for virus growth in BHK cells.

A leader polypeptide of unknown function is encoded by cardioviruses, such as Theiler's murine encephalomyelitis virus. Although the deletion of this polypeptide has little effect on the growth of parental GDVII virus in baby hamster kidney (BHK) cells, the mutant virus is completely attenuated and fails to kill mice receiving intracerebral inoculations of high doses of the virus.

Class II-restricted T cell responses in Theiler's murine encephalomyelitis virus-induced demyelinating disease. VI. Potentiation of demyelination with and characterization of an immunopathologic CD4+ T cell line specific for an immunodominant VP2 epitope.

Theiler's murine encephalomyelitis virus (TMEV)-induced demyelinating disease is a relevant mouse model of multiple sclerosis. Demyelination is linked to persistent TMEV infection of the central nervous system and characterized by perivascular inflammatory mononuclear infiltrates and primary demyelination. Our previous results have shown that susceptibility correlates with the temporal development of chronic virus-specific delayed-type hypersensitivity (DTH) responses and suggest that inflammatory processes mediated by T cells specific for an immunodominant determinant on virus capsid protein 2 (VP2(74-86)) play a major immunopathologic role in SJL/J mice. In this study we have further defined the T cell-dependent nature and specificity of the demyelinating process in susceptible SJL/J mice by showing that thymectomized irradiated bone marrow-restored mice fail to develop chronic demyelination and that i.v. adoptive transfer of polyclonal TMEV-specific T cells before intracerebral infection with a suboptimal dose of the BeAn strain of TMEV led to increased incidence and accelerated onset of clinical disease. The data also show that demyelination is dependent on the activity of virus-specific CD4+ T cells because in vivo depletion with anti-CD4, but not anti-CD8, mAb led to significantly diminished incidence and severity of demyelination concomitant with a decrease in TMEV-specific DTH reactivity. In addition, the adoptive transfer of a TMEV-specific, DTH-mediating CD4+ I-A(s)-restricted Th1 line (sTV1) specific for the immunodominant VP2(74-86) epitope also led to increased incidence and accelerated onset of clinical disease only in TMEV-infected recipients. Collectively, the results of this and the companion paper demonstrate the highly significant immunopathologic contribution of CD4+ T cell responses specific for an immunodominant viral epitope to the chronic central nervous system demyelination observed in TMEV-infected SJL/J mice.

Class II-restricted T cell responses in Theiler's murine encephalomyelitis virus-induced demyelinating disease. V. Mapping of a dominant immunopathologic VP2 T cell epitope in susceptible SJL/J mice.

Theiler's murine encephalomyelitis virus (TMEV)-induced demyelinating disease is a relevant mouse model of multiple sclerosis. Demyelination is linked to persistent TMEV infection of the central nervous system and characterized by perivascular inflammatory mononuclear infiltrates and primary demyelination. Myelin damage is a T cell-dependent process and susceptibility correlates with the temporal development of chronic virus-specific delayed-type hypersensitivity (DTH) responses. Our previous results have shown that inflammatory processes mediated by Th1 cells specific for a determinant(s) on virus capsid protein 2 (VP2) play a major immunopathologic role in SJL/J mice. This study identifies a 13 amino acid peptide on VP2 (VP2(74-86)) as the immunodominant T cell epitope in TMEV-infected and -immunized SJL/J mice, and demonstrates the ability of that sequence to prime for the majority of the SJL/J DTH T cell response to intact TMEV. The importance of T cell responses to this epitope in the demyelinating process was illustrated by experiments in which SJL/J mice displayed an increased incidence and accelerated onset of clinical disease after peripheral immunization with a fusion protein containing VP2(74-84) before intracerebral infection with a suboptimal dose of the BeAn strain of TMEV. Identification of this immunopathologic TMEV T cell epitope will be critically important for delineation of the mechanisms of T cell-mediated myelin damage and for potential use to prevent and/or treat TMEV-induced demyelinating disease via the induction of epitope-specific tolerance.

Class II-restricted T cell responses in Theiler's murine encephalomyelitis virus-induced demyelinating disease. IV. Identification of an immunodominant T cell determinant on the N-terminal end of the VP2 capsid protein in susceptible SJL/J mice.

Theiler's murine encephalomyelitis virus (TMEV)-induced demyelinating disease serves as a relevant animal model of human multiple sclerosis. Myelin damage induced by TMEV infection appears to be immune mediated. Disease susceptibility correlates best with the temporal development of chronic, high levels of TMEV-specific, MHC class II-restricted delayed-type hypersensitivity (DTH) responses. We have proposed a model wherein these responses result in CNS demyelination via a macrophage-mediated terminal nonspecific bystander response. As virus-specific DTH responses appear to be intimately involved in the pathogenicity of CNS demyelination, it is critical to determine the specificity of these responses so that effector T cells specific for potential pathogenic epitopes can be targeted to serve as the focus of specific immunoregulatory processes. In the current study, the capsid protein specificity of the TMEV-susceptible SJL/J and TMEV-resistant C57BL/6 mouse strains was examined. DTH and Tprlf responses in both infected and immunized SJL/J mice were found to be predominantly directed toward the VP2 capsid protein, specifically to an epitope(s) contained within the N-terminal 150 amino acids of VP2. This same epitope was also found to be dominant in priming SJL/J mice for responses to challenge with intact virions. In contrast, the T cell-mediated responses of TMEV-resistant C57BL/6 mice did not show preferential reactivity towards VP2, because all three major capsid proteins (VP1, VP2, and VP3) elicited responses with essentially equal potency. The relationship of the restricted VP2 T cell epitope to predicted neutralizing antibody sites on the VP2 protein is discussed as is the potential use of this epitope for prevention and/or treatment of TMEV-induced demyelinating disease via the induction of epitope-specific tolerance.

Suppression of the translation defect phenotype specific for a virus-associated RNA-deficient adenovirus mutant in monkey cells by simian virus 40.

Human cells infected with adenovirus type 2 (Ad2) or Ad5 require VAI RNA for efficient translation of viral mRNAs at late times after infection. The Ad5 mutant dl-sub720 synthesized neither virus-associated I (VAI) nor VAII RNAs, and infection of human cells with this mutant resulted in reduced virion polypeptide synthesis. Infection of monkey cells with this mutant also resulted in drastic reduction of polypeptide synthesis compared with wild-type (WT) adenovirus infections. Steady-state levels of hexon-specific mRNA were found to be comparable in WT- and mutant-infected monkey cells. The in vitro translation experiments showed that double-mutant- and WT-infected cells contained comparable levels of translatable hexon mRNA (and other adenovirus late mRNAs), suggesting that the severe inhibition of hexon protein synthesis in the VA mutant involves a translation block. Preinfection of monkey cells with simian virus 40 fully restored the efficient translation of this mRNA in the VA mutant infections to the level observed in WT-infected cultures. These results raise the possibility that simian virus 40 may encode or induce factors that suppress the translation block that occurs during adenovirus infections in the absence of the VA RNAs.

Persistent infection of a temperature-sensitive G31 vesicular stomatitis virus mutant in neural and nonneural cells: biological and virological characteristics.

Mouse L-929 cells (L cells), human oligodendroglioma cells, and rat glioma cells were persistently infected with vesicular stomatitis virus (VSV) mutant tsG31 and maintained for at least 4 years at 37 degrees C. The striking observation in this study was that there is a marked difference in neurovirulence among the persistent infections (PIs) derived from the three cell lines. tsG31 VSV derived from persistently infected L cells and oligodendroglioma cells remained highly virulent as assayed by intracerebral (i.c.) inoculation into 3-week-old Swiss mice. In contrast, tsG31 VSV isolated from glioma cells lost neurovirulence by passage 20. Persistently infected glioma cells were carried through more than 180 passages without reemergence of neurovirulent virus. Importantly, glioma PI virus neurovirulence was restored quickly by i.c. passage in mice and more slowly by passage through normal L cells. In contrast, the neurovirulence of L-cell PI virus was enhanced by i.c. passage in mice and slowly reduced by passage through normal glioma cells. Furthermore, no alteration in neurovirulence was observed in the case of oligodendroglioma PI virus. Although the mechanism(s) underlying the loss of virulence in glioma cells is unclear, our studies suggest that either strict temperature sensitivity or the presence of a heat-labile transcriptase or both play a major role in this phenomenon.

Large-T-antigen-p53 complex formation is not cold sensitive in a cold-sensitive transformant induced by simian virus 40 mutant tsA1499.

F111 rat cells transformed by simian virus 40 mutant tsA1499 are cold sensitive for the expression of transformation. Yet, unlike F111 cells transformed by tsA58, they do not lose the ability to stabilize the transformation-associated host cell protein p53 at the temperature at which transformation is extinguished.