Astrocytes, not microglia, are the main cells responsible for viral persistence in Theiler's murine encephalomyelitis virus infection leading to demyelination.

The BeAn strain of Theiler's murine encephalomyelitis virus (TMEV) persists in the CNS and produces a chronic inflammatory demyelinating disease that is an animal model for human multiple sclerosis (MS). The mechanisms leading to TMEV-induced demyelination are still under study but most likely involve both immune-mediated and virus induced damage to cells in the CNS, both depending on viral persistence. It is therefore important to identify the cells in which continued virus production is permitted. In this study, we looked at virus infection in primary astrocytes, microglia and oligodendrocytes, derived from brains of neonatal susceptible SJL/J mice. As evidenced by Western blots and immunocytochemistry, we were able to detect viral antigens in all these brain-derived cells. In addition, we extended the study to spinal cord tissues from mice suffering TMEV-induced disease. Immunohistochemistry staining with anti-TMEV sera and antibodies to specific cell markers detected viral antigens in all these cells. We then asked the question whether viral antigen present in these cells, particularly in microglia/macrophages, represented true viral replication or not. By using different techniques, including immunoprecipitation experiments and the very sensitive method of negative RNA detection through RNase protection assay, we show that both astrocytes and oligodendroglia permit de novo viral replication and viral protein synthesis but with only minimal cytopathic effects. Of these two cell types, astrocytes carry the brunt of viral replication. In microglia, on the other hand, viral replication is restricted since only minimal amounts of negative RNA copies can be demonstrated, while there are clear signs that some of these cells undergo apoptosis. These findings show that the main cell for viral replication is the astrocyte, rather than the microglia/macrophage. Most of the viral antigen present in macrophages, therefore, is probably the result of phagocytosis, rather than actual viral replication. In view of the demonstrated presence of viral replication in astrocytes and of great amounts of viral antigens in microglia/macrophages, it is possible that both types of cells act as antigen presenting cells during this immunopathological disease.

A virus-induced molecular mimicry model of multiple sclerosis.

Molecular mimicry is the process by which virus infection activates T cells that are cross-reactive with self antigens. Infection of SJL/J mice with the neurotropic picornavirus Theiler's murine encephalomyelitis virus (TMEV) leads to a progressive CD4(+) T cell-mediated demyelinating disease similar to multiple sclerosis. To study the potential of virus-induced molecular mimicry to initiate autoimmune demyelination, a nonpathogenic TMEV variant was engineered to encode a 30-mer peptide encompassing the immunodominant encephalitogenic myelin proteolipid protein (PLP139-151) epitope. Infection with the PLP139-151-encoding TMEV led within 10-14 days to a rapid-onset paralytic demyelinating disease characterized by PLP139-151-specific CD4(+) Th1 responses; insertion of a non-self ovalbumin sequence led to restoration of the normal late-onset disease. Early-onset disease was also observed in mice infected with a TMEV encoding PLP139-151 with an amino acid substitution at the secondary T cell receptor (TCR) contact residue (H147A), but not in mice infected with TMEV encoding a PLP139-151 substitution at the primary TCR contact (W144A). Most significantly, mice infected with TMEV encoding a Haemophilus influenzae mimic peptide, sharing only 6 of 13 amino acids with PLP139-151, displayed rapid-onset disease and developed cross-reactive PLP139-151-specific CD4(+) Th1 responses. To our knowledge, this is the first study showing that a naturally infectious virus encoding a myelin epitope mimic can directly initiate organ-specific T cell-mediated autoimmunity.

Lymphocytes from mice chronically infected with Theiler's murine encephalomyelitis virus produce demyelination of organotypic cultures after stimulation with the major encephalitogenic epitope of myelin proteolipid protein. Epitope spreading in TMEV infection has functional activity.

Theiler's murine encephalomyelitis virus (TMEV) infection produces a chronic inflammatory disease of the spinal cord white matter, with striking similarities to both experimental allergic encephalomyelitis (EAE) and human multiple sclerosis (MS). The first phase of demyelination in this model appears to be dependent on a delayed-type hypersensitivity (DTH) response to viral antigens, driven by CD4+, Th1 lymphocytes. Macrophages, recruited in the infected CNS, would be responsible for most of the myelin damage. Recently, new populations of CD4+ lymphocytes were demonstrated in infected mice, this time with specificity for myelin antigens, particularly PLP. This suggests that, in the chronic phase of the disease, an autoimmune mechanism of demyelination, similar to EAE, may participate in the process of myelin destruction. The present study represents a first step in exploring the functional activity of these anti-myelin lymphocytes that emerge during the chronic phase of the disease. Lymphocytes were removed from chronically infected animals, they were stimulated with the major PLP encephalitogenic epitope for SJL/J mice, and they were added to organotypic myelinated spinal cord cultures for different lengths of time. Results show that lymphocytes stimulated with the major PLP epitope have a powerful capacity for demyelinating these cultures, while MBP stimulated lymphocytes and lymphocytes from control animals do not. This study, suggests that the anti-myelin response that emerges during the chronic phase of the infection is functionally active. A similar phenomenon of epitope spreading from virus to organ specific antigens may take place in humans and be involved in a number of immune-mediated diseases, including MS.

The leader polypeptide of Theiler's murine encephalomyelitis virus is required for the assembly of virions in mouse L cells.

Deletion of the entire leader polypeptide of the GDVII strain of Theiler's murine encephalomyelitis virus (TMEV) results in the production of an attenuated virus that grows in baby hamster kidney (BHK) cells but cannot grow at all in mouse L-929 cells. This study examined the reasons for the failure of dl-L, the GDVII variant that lacks the leader polypeptide, to grow in mouse cells. At low multiplicities of infection, it was difficult to detect any viral proteins in mouse cells. However, levels of positive- and negative-strand RNA molecules were only moderately reduced in these infections. Viral RNA showed no major defect in translatability, as the mutant viral RNA was nearly as efficient as that of the wild-type (WT) virus in directing protein synthesis in vitro in assays using extracts prepared from mouse L cells. Viral protein synthesis was detected in dl-L-infected mouse cells as multiplicities of infection were increased and approached the levels observed in WT infections. Despite this, there was a total lack of virus production in high-multiplicity infections, and this was found to correlate with the failure of viral proteins and early virion precursors to assemble into virions in mouse cells. Thus, the inability of dl-L to grow in mouse cells reflects complex effects on various stages of the virus infection but is primarily a defect in virus assembly.

Attenuation of neurovirulence of Theiler's murine encephalomyelitis virus strain GDVII is not sufficient to establish persistence in the central nervous system.

Virus recombinants constructed from Theiler's murine encephalomyelitis virus (TMEV) strain GDVII, which causes a rapidly fatal encephalitis in mice, and the less virulent BeAn, which persists in the murine central nervous system (CNS) and causes inflammatory demyelination, and a GDVII mutant deleted of 46 of 76 leader protein amino acids were analysed for virus persistence in the CNS. The two recombinant and mutant viruses principally contain GDVII sequences including the nucleotides encoding the polyprotein and 3' untranslated region. These viruses were found to replicate in the CNS of mice but they did not produce acute encephalitis or paralysis, i.e. they were attenuated in neurovirulence compared to the GDVII parent. More important, none of the viruses persisted in the mouse CNS nor caused chronic demyelination. Thus, attenuation of GDVII neurovirulence alone is not sufficient to establish TMEV persistence. This result is discussed in the context of a genomic determinant for persistence.

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.

A single base deletion in the 5' noncoding region of Theiler's virus attenuates neurovirulence.

Viral chimeras have been constructed through in vitro manipulations of the infectious cDNA clones of two prototypes of Theiler's murine encephalomyelitis virus: (i) the virulent GDVII strain and (ii) the less virulent BeAn and VL strains. Previous studies have suggested that the phenotypic differences in virulence between the BeAn and GDVII strains map to both the 5' noncoding and the coat protein regions of these viral genomes. It is shown here that attenuation mapped to the 5' noncoding region is due, at least in part, to an inadvertent deletion resulting from a cloning artifact of one C nucleotide out of four between positions 876 and 879 in the BeAn sequences. The in vitro growth characteristics in BHK-21 cells, however, do not reflect the large differences in neurovirulence between chimeras that are identical except for the deleted C. Another chimera with a mutation at position 877 and a deletion at 976 is also attenuated. The wild-type sequences from the less virulent strains BeAn and VL between nucleotides 1 and 933, in an otherwise GDVII chimera, do not attenuate virulence. Sequences of the 500 nucleotides of the 5' noncoding region proximal to the translation initiation codon were obtained for nine additional Theiler's virus strains. The attenuating deletions are discussed in the context of these sequences and the proposed secondary structures for the 5' noncoding region.

Genomic regions of neurovirulence and attenuation in Theiler murine encephalomyelitis virus.

Full-length cDNA clones of two Theiler murine encephalomyelitis virus (TMEV) strains, one highly virulent and the other less virulent, were constructed in the bacterial plasmid pGEMR-3. Transfection of BHK-21 cells with RNA transcribed from these cDNAs yielded progeny viruses with the exact in vitro growth phenotype and mouse neurovirulence pattern of the respective parental virus strains. RNA transcripts derived from recombinant chimeras constructed by exchanging corresponding genomic regions [5' noncoding, leader/P1 (L/P1), P2, P3, and 3' noncoding] between the parental cDNAs were infectious and enabled analysis of the growth characteristics in vitro and mouse neurovirulence of the chimeras. A correlation was found between plaque size and temperature sensitivity and the origin of the L/P1 region. Neurovirulence mapped primarily to the L/P1 region encoding the leader and coat proteins. Depending on parental origin, the 5' noncoding region either influenced virus attenuation or augmented virulence.

Human colon adenocarcinoma cells. III. In vitro organoid expression and carcinoembryonic antigen kinetics in hollow fiber culture.

Cell line LS174T was established in our laboratory from a primary human colon adenocarcinoma and was serially cultured for 4 years. Following 1 month of culture in perfused hollow fiber matrices, organoid growth reminiscent of the patient's original tumor was observed. The cellular organization was predominantly glandular with mucin located within gland lumina and cells. Glands had irregular brush borders, well-developed junctional complexes, and intracytoplasmic lumina lined with microvilli, features found in adenocarcinoma tissue. Alternate-day determinations of carcinoembryonic antigen (CEA) revealed biphasic kinetics in the extracapillary fluids of the hollow fiber system but not in identically treated monolayer cultures. The initial rate of CEA release was similar to that of monolayer cultures. A significantly accelerated secondary CEA release phase was observed in 10,000- and 50,000-molecular weight (MW)-exclusion fiber cultures (P less than or equal to 0.001 and P = 0.05, respectively). Totals of 43.8 micrograms and 112.6 micrograms CEA were released into the extracapillary fluids of 10,000- and 50,000-MW-exclusion fiber cultures, respectively, which were onefold and 2.3-fold increases, respectively, over monolayer supernatant yields. Most CEA was released during the final days of the secondary phase. In monolayer cultures, maximum CEA release occurred during the stationary phase of growth.