Assembly of Theiler's virus recombinants used in mapping determinants of neurovirulence.

A major determinant of neurovirulence for the GDVII strain of Theiler's virus, a murine picornavirus, was mapped to the P1 capsid protein region. Chimeric viruses were constructed by using sequences from the 5' noncoding and P1 regions of the virulent GDVII strain to replace equivalent regions of the less virulent BeAn strain. Neurovirulence in mice progressively increased as larger regions of BeAn capsid protein-encoding sequences were replaced. The in vitro growth characteristics of the chimeras showed that some chimeras were growth delayed in BHK-21 cells even though the viral constructs exhibited larger plaque sizes, were less temperature sensitive, and were more thermally stable than BeAn. Examination of assembly intermediates revealed an altered pentamer conformation and delayed empty capsid formation for the growth-compromised viruses. For these constructs, their chimeric nature inadvertently resulted in virion assembly defects that complicated finer-scale mapping of the determinants of virulence within the capsid region. These results demonstrate the importance of determining in vitro growth characteristics of chimeras to correctly decipher the significance of their phenotypes. VP1 does not contain a complete determinate for virulence because a chimera with VP1-encoding sequences from GDVII in an otherwise BeAn virus has an attenuated phenotype but is not growth compromised in vitro. The source of sequences, BeAn or GDVII, in the 5' noncoding region had only slight effects on the virulence of recombinant constructs.

Three-dimensional structure of Theiler virus.

Theiler murine encephalomyelitis virus strains are categorized into two groups, a neurovirulent group that rapidly kills the host, and a demyelinating group that causes a generally nonlethal infection of motor neurons followed by a persistent infection of the white matter with demyelinating lesions similar to those found in multiple sclerosis. The three-dimensional structure of the DA strain, a member of the demyelinating group, has been determined at 2.8 A resolution. As in other picornaviruses, the icosahedral capsid is formed by the packing of wedge-shaped eight-stranded antiparallel beta barrels. The surface of Theiler virus has large star-shaped plateaus at the fivefold axes and broad depressions spanning the twofold axes. Several unusual structural features are clustered near one edge of the depression. These include two finger-like loops projecting from the surface (one formed by residues 78-85 of VP1, and the other formed by residues 56-65 of VP3) and a third loop containing three cysteines (residues 87, 89, and 91 of VP3), which appear to be covalently modified. Most of the sequence differences between the demyelinating and neurovirulent groups that could play a role in determining pathogenesis map to the surface of the star-shaped plateau. The distribution of these sequence differences on the surface of the virion is consistent with models in which the differences in the pathogenesis of the two groups of Theiler viruses are the result of differences in immunological or receptor-mediated recognition processes.

Three-dimensional structure of Theiler murine encephalomyelitis virus (BeAn strain).

Depending on the strain, Theiler murine encephalomyelitis virus (TMEV) may cause acute encephalitis or chronic demyelinating disease, which is associated with viral persistence in mice. Persistent central nervous system infection and demyelination by the less-virulent TMEV has provided a useful animal model for the human demyelinating disease multiple sclerosis. The less-virulent BeAn strain of TMEV was crystallized and its atomic structure was determined by x-ray crystallography. The alpha-carbon coordinates of the closely related Mengo virus were used to calculate the initial phases to 3.5 A resolution and the interpretable electron density map was produced by 10 cycles of 30-fold noncrystallographic molecular replacement averaging. The structure revealed a high degree of overall structural similarity to Mengo virus as well as substantial differences in the surface loops. These structural changes might be correlated with TMEV host-specific recognition, pH-related stability, and neurovirulence.

Monocytes/macrophages isolated from the mouse central nervous system contain infectious Theiler's murine encephalomyelitis virus (TMEV).

Knowledge of the cells in which Theiler's murine encephalomyelitis virus (TMEV) persists is crucial to understanding the pathogenesis of TMEV-induced demyelinating disease; however, it is still uncertain whether oligodendrocytes or macrophages are the primary target for persistence. In this study, mononuclear cells (MNC) isolated directly from central nervous system (CNS) inflammatory infiltrates of TMEV-infected mice on discontinuous Percoll gradients were found to contain infectious TMEV. Macrophages appeared to be the principal MNC infected as determined by two-color immunofluorescence. Infectious center assay and double immunostaining together indicated the presence and possible synthesis of TMEV in approximately 1 in 225 to 1 in 1000 CNS macrophages, with 1 to 7 PFU produced per macrophage. On the basis of these findings, limited replication in macrophages is consistent with the total CNS virus content detected at any time during the persistent phase of the infection as well as the slow pace of the infection.

Is Theiler's murine encephalomyelitis virus infection of mice an autoimmune disease?

Viruses can initiate disease by many different means. Direct viral, immune mediated and host factors all play important parts. Molecular mimicry or having cross-reacting determinants that result in immune responses which have the potential to cause damage can be incorporated into this framework. Here, autoimmune responses generated by virus infection have been presented in relation to these other parameters. The cross-reacting immune response originally generated by virus would have to be directed toward or involve a disease inducing site such as an EAE (encephalitogenic), thyroiditis, or diabetogenic site. If the cross-reaction took place at a nondisease inducing site, the ensuring immune response may result in the production of autoantibodies, however no disease would occur. In other systems autoantibodies can potentiate an ongoing inflammatory response. This may be the case that is described here with Theiler's murine encephalomyelitis virus infection. Lastly, viruses having common determinants with MHC determinants may modify immune responses leading to immunosuppression and allowing virus to persist. In addition, similar determinants may lead to disease by an alternative route. For example, we have described a region of human cytomegalovirus that has a common determinant with HLA DR beta chain. This region is associated with diabetes in humans (Todd et al. 1988). Thus, many factors are involved in the outcome of disease induction by viruses of which autoimmunity is one.

Three-dimensional model of the capsid proteins of two biologically different Theiler virus strains: clustering of amino acid difference identifies possible locations of immunogenic sites on the virion.

To explore structural features of the Theiler murine encephalomyelitis virion, we have constructed a three-dimensional model of the capsid proteins (VP1, VP2, and VP3) of the BeAn strain based on the atomic coordinates of the closely related Mengo virus. By superimposition of amino acid differences between BeAn virus and another Theiler virus strain, GDVII, on the three-dimensional model, clusters of differences were found in four distinct sites; the VP1 third corner, the VP2 "puff," and the VP3 first corner and "knob." These clusters, which are found on the surface of the virion, may represent neutralizing immunogenic sites that have come under selective pressure from neutralizing antibodies. Furthermore, the putative viral receptor binding site ("pit") of the two Theiler virus strains was found to be markedly conserved.

Theiler's virus replication in isolated Schwann cell cultures.

Theiler's murine encephalomyelitis viruses causing both fatal encephalitis (GDVII virus) and chronic demyelinating disease (WW virus) are capable of replicating in isolated Schwann cell cultures. Light microscopy combined with immunohistochemical staining of viral antigens revealed that large numbers of Schwann cells infected with the two viruses show cytopathic effect (rounding) and contain viral antigens. Electron microscopy of virus-infected Schwann cells shows that the morphological alterations that the cells undergo following infection by the two virus isolates are different. In the early stages of GDVII and WW virus infection, different inclusion bodies are formed in the cells cytoplasm. At late stages of the infection GDVII virions are found in all infected cells and are arranged in crystalline arrays around inclusion bodies. In contrast, in WW virus-infected Schwann cells only in few cells virions were observed and they appeared aligned between two membrane units.

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.