Ming Ming Chua

Murine Coronavirus Spike Glycoprotein Mediates Degree of Viral Spread, Inflammation, and Virus-Induced Immunopathology in the Central Nervous System

Abstract The mouse hepatitis virus (MHV) spike glycoprotein is a major determinant of neurovirulence. We investigated how alterations in spike affect neurovirulence using two isogenic recombinant viruses differing exclusively in spike. S4R, containing the MHV-4 spike gene, is dramatically more neurovirulent than SA59R, containing the MHV-A59 spike gene (J. J. Phillips, M. M. Chua, E. Lavi, and S. R. Weiss, 1999, J. Virol. 73, 7752–7760). We examined the contribution of differences in cellular tropism, viral spread, and the immune response to infection to the differential neurovirulence of S4R and SA59R. MHV-4 spike-mediated neurovirulence was associated with extensive viral spread in the brain in both neurons and astrocytes. Infection of primary hippocampal neuron cultures demonstrated that S4R spread more rapidly than SA59R and suggested that spread may occur between cells in close physical contact. In addition, S4R infection induced a massive influx of lymphocytes into the brain, a higher percentage of CD8+ T cells, and a higher frequency of MHV-specific CD8+ T cells relative SA59R infection. Despite this robust and viral-specific immune response to S4R infection, infection of RAG1−/− mice suggested that immune-mediated pathology also contributes to the high neurovirulence of S4R.

Murine Coronavirus Spike Protein Determines the Ability of the Virus To Replicate in the Liver and Cause Hepatitis

ABSTRACT Recombinant mouse hepatitis viruses (MHV) differing only in the spike gene, containing A59, MHV-4, and MHV-2 spike genes in the background of the A59 genome, were compared for their ability to replicate in the liver and induce hepatitis in weanling C57BL/6 mice infected with 500 PFU of each virus by intrahepatic injection. Penn98-1, expressing the MHV-2 spike gene, replicated to high titer in the liver, similar to MHV-2, and induced severe hepatitis with extensive hepatocellular necrosis. SA59R13, expressing the A59 spike gene, replicated to a somewhat lower titer and induced moderate to severe hepatitis with zonal necrosis, similar to MHV-A59. S4R21, expressing the MHV-4 spike gene, replicated to a minimal extent and induced few if any pathological changes, similar to MHV-4. Thus, the extent of replication and the degree of hepatitis in the liver induced by these recombinant viruses were determined largely by the spike protein.

Altered Pathogenesis of a Mutant of the Murine Coronavirus MHV-A59 Is Associated with a Q159L Amino Acid Substitution in the Spike Protein

Abstract C12, an attenuated, fusion delayed, very weakly hepatotropic mutant of mouse hepatitis virus strain A59 (MHV-A59) has been further characterized. We have previously shown that C12 has two amino acid substitutions relative to wild type virus in the spike protein, Q159L (within a region of S1 shown to bind to viral receptor in anin vitroassay) and H716D (in the proteolytic cleavage recognition site). We have sequenced the rest of the 31-kb genome of C12 and compared it to wild type virus. Only three additional amino acids substitutions were found, all encoded within the replicase gene. Analysis of C12in vivoin C57Bl/6 mice has shown that despite the fact that this virus replicates in the brain to titers at least as high as wild type and causes acute encephalitis similar to wild type, this virus causes a minimal level of demyelination and only at very high levels of virus inoculation. Thus acute encephalitis is not sufficient for the induction of demyelination by MHV-A59. Analysis of mutants isolated at earlier times from the same persistently infected glial cell culture as C12, as well as mutants isolated from a second independent culture of persistently infected glial cells, suggests that both the weakly demyelinating and the weakly hepatotropic phenotypes of C12 are associated with the Q159L amino acid substitution.

Perforin-Mediated CTL Cytolysis Counteracts Direct Cell-Cell Spread of Listeria monocytogenes

The immune system has evolved various effector cells and functions to combat diverse infectious agents equipped with different virulence strategies. CD8 T cells play a critical role in protective immunity to Listeria monocytogenes (Lm), a bacterium that grows within the host cell cytosol and spreads directly into neighboring cells. The importance of CD8 T cells during Lm infection is currently attributed to the cytosolic niche of this organism, which allows it to evade many aspects of immune surveillance. CTL lysis of infected cells is believed to be an essential protective mechanism, presumably functioning to release intracellular bacteria, although its precise role remains to be fully defined. In this study, we examined the contribution of perforin-mediated CTL cytolysis to protective immunity against recombinant Lm capable of or defective in cell-cell spread. We found that CTL cytolysis is critical for protective immunity to Lm capable of cell-cell spread while protective immunity against spread-defective Lm is largely independent of CTL cytolysis. These results demonstrate that an important function of CTL cytolysis is to counter the microbial virulence strategy of direct cell-cell spread. We propose a model that advances the current view of the role of CTL cytolysis in immunity to intracellular pathogens.

Organ-Specific Attenuation of Murine Hepatitis Virus Strain A59 by Replacement of Catalytic Residues in the Putative Viral Cyclic Phosphodiesterase ns2

ABSTRACT The Murine hepatitis virus (MHV) strain A59 ns2 protein is a 30-kDa nonstructural protein that is expressed from a subgenomic mRNA in the cytoplasm of virus-infected cells. Its homologs are also encoded in other closely related group 2a coronaviruses and more distantly related toroviruses. Together, these proteins comprise a subset of a large superfamily of 2H phosphoesterase proteins that are distinguished by a pair of conserved His-x-Thr/Ser motifs encompassing catalytically important residues. We have used a vaccinia virus-based reverse genetic system to produce recombinant viruses encoding ns2 proteins with single-amino-acid substitutions in, or adjacent to, these conserved motifs, namely, inf-ns2 H46A, inf-ns2 S48A, inf-ns2-S120A, and inf-ns2-H126R. All of the mutant viruses replicate in mouse 17 clone 1 fibroblast cells and mouse embryonic cells to the same extent as the parental wild-type recombinant virus, inf-MHV-A59. However, compared to inf-MHV-A59, the inf-ns2 H46A and inf-ns2-H126R mutants are highly attenuated for replication in mouse liver following intrahepatic inoculation. Interestingly, none of the mutant viruses were attenuated for replication in mouse brain following intracranial inoculation. These results show that the ns2 protein of MHV-A59 has an important role in virus pathogenicity and that a substitution of the histidine residues of the MHV-A59 ns2 His-x-Thr/Ser motifs is critical for virus virulence in the liver but not in the brain. This novel phenotype suggests a strategy to investigate the function of the MHV-A59 ns2 protein involving the search for organ-specific proteins or RNAs that react differentially to wild-type and mutant ns2 proteins.

Effects of an Epitope-Specific CD8+ T-Cell Response on Murine Coronavirus Central Nervous System Disease: Protection from Virus Replication and Antigen Spread and Selection of Epitope Escape Mutants

ABSTRACT Both CD4+ and CD8+ T cells are required for clearance of the murine coronavirus mouse hepatitis virus (MHV) during acute infection. We investigated the effects of an epitope-specific CD8+ T-cell response on acute infection of MHV, strain A59, in the murine CNS. Mice with CD8+ T cells specific for gp33-41 (an H-2Db-restricted CD8+ T-cell epitope derived from lymphocytic choriomeningitis glycoprotein) were infected with a recombinant MHV-A59, also expressing gp33-41, as a fusion protein with enhanced green fluorescent protein (EGFP). By 5 days postinfection, these mice showed significantly (approximately 20-fold) lower titers of infectious virus in the brain compared to control mice. Furthermore mice with gp33-41-specific CD8+ cells exhibited much reduced levels of viral antigen in the brain as measured by immunohistochemistry using an antibody directed against viral nucleocapsid. More than 90% of the viruses recovered from brain lysates of such protected mice, at 5 days postinfection, had lost the ability to express EGFP and had deletions in their genomes encompassing EGFP and gp33-41. In addition, genomes of viruses from about half the plaques that retained the EGFP gene had mutations within the gp33-41 epitope. On the other hand, gp33-41-specific cells failed to protect perforin-deficient mice from infection by the recombinant MHV expressing gp33, indicating that perforin-mediated mechanisms were needed. Virus recovered from perforin-deficient mice did not exhibit loss of EGFP expression and the gp33-41 epitope. These observations suggest that the cytotoxic T-cell response to gp33-41 exerts a strong immune pressure that quickly selects epitope escape mutants to gp33-41.

Contributions of the Viral Genetic Background and a Single Amino Acid Substitution in an Immunodominant CD8+ T-Cell Epitope to Murine Coronavirus Neurovirulence

ABSTRACT The immunodominant CD8+ T-cell epitope of a highly neurovirulent strain of mouse hepatitis virus (MHV), JHM, is thought to be essential for protection against virus persistence within the central nervous system. To test whether abrogation of this H-2Db-restricted epitope, located within the spike glycoprotein at residues S510 to 518 (S510), resulted in delayed virus clearance and/or virus persistence we selected isogenic recombinants which express either the wild-type JHM spike protein (RJHM) or spike containing the N514S mutation (RJHMN514S), which abrogates the response to S510. In contrast to observations in suckling mice in which viruses encoding inactivating mutations within the S510 epitope (epitope escape mutants) were associated with persistent virus and increased neurovirulence (Pewe et al., J Virol. 72:5912-5918, 1998), RJHMN514S was not more virulent than the parental, RJHM, in 4-week-old C57BL/6 (H-2b) mice after intracranial injection. Recombinant viruses expressing the JHM spike, wild type or encoding the N514S substitution, were also selected in which background genes were derived from the neuroattenuated A59 strain of MHV. Whereas recombinants expressing the wild-type JHM spike (SJHM/RA59) were highly neurovirulent, A59 recombinants containing the N514S mutation (SJHMN514S/RA59) were attenuated, replicated less efficiently, and exhibited reduced virus spread in the brain at 5 days postinfection (peak of infectious virus titers in the central nervous system) compared to parental virus encoding wild-type spike. Virulence assays in BALB/c mice (H-2d), which do not recognize the S510 epitope, revealed that attenuation of the epitope escape mutants was not due to the loss of a pathogenic immune response directed against the S510 epitope. Thus, an intact immunodominant S510 epitope is not essential for virus clearance from the CNS, the S510 inactivating mutation results in decreased virulence in weanling mice but not in suckling mice, suggesting that specific host conditions are required for epitope escape mutants to display increased virulence, and the N514S mutation causes increased attenuation in the context of A59 background genes, demonstrating that genes other than that for the spike are also important in determining neurovirulence.

Priming of CD8+ T Cells during Central Nervous System Infection with a Murine Coronavirus Is Strain Dependent

ABSTRACT Virus-specific CD8+ T cells are critical for protection against neurotropic coronaviruses; however, central nervous system (CNS) infection with the recombinant JHM (RJHM) strain of mouse hepatitis virus (MHV) elicits a weak CD8+ T-cell response in the brain and causes lethal encephalomyelitis. An adoptive transfer model was used to elucidate the kinetics of CD8+ T-cell priming during CNS infection with RJHM as well as with two MHV strains that induce a robust CD8+ T-cell response (RA59 and SJHM/RA59, a recombinant A59 virus expressing the JHM spike). While RA59 and SJHM/RA59 infections resulted in CD8+ T-cell priming within the first 2 days postinfection, RJHM infection did not lead to proliferation of naïve CD8+ T cells. While all three viruses replicated efficiently in the brain, only RA59 and SJHM/RA59 replicated to appreciable levels in the cervical lymph nodes (CLN), the site of T-cell priming during acute CNS infection. RJHM was unable to suppress the CD8+ T-cell response elicited by RA59 in mice simultaneously infected with both strains, suggesting that RJHM does not cause generalized immunosuppression. RJHM was also unable to elicit a secondary CD8+ T-cell response in the brain following peripheral immunization against a viral epitope. Notably, the weak CD8+ T-cell response elicited by RJHM was unique to CNS infection, since peripheral inoculation induced a robust CD8+ T-cell response in the spleen. These findings suggest that the failure of RJHM to prime a robust CD8+ T-cell response during CNS infection is likely due to its failure to replicate in the CLN.

Replicase Genes of Murine Coronavirus Strains A59 and JHM Are Interchangeable: Differences in Pathogenesis Map to the 3′ One-Third of the Genome

ABSTRACT The important roles of the spike protein and other structural proteins in murine coronavirus (MHV) pathogenesis have been demonstrated; however, the role of the replicase gene remains unexplored. We assessed the influence of the replicase genes of the highly neurovirulent MHV-JHM strain and the hepatotropic and mildly neurovirulent A59 strain in acute infection of the mouse. Analysis of chimeric A59/JHM recombinant viruses indicates that the replicase genes are interchangeable and that it is the 3′ end of the genome, encoding the structural proteins, rather than the replicase gene, that determines the pathogenic properties of these chimeras.

Genetic Determinants of Mouse Hepatitis Virus Strain 1 Pneumovirulence

ABSTRACT We report here investigation into the genetic basis of mouse hepatitis virus strain 1 (MHV-1) pneumovirulence. Sequencing of the 3′ one-third of the MHV-1 genome demonstrated that the genetic organization of MHV-1 was similar to that of other strains of MHV. The hemagglutinin esterase (HE) protein was truncated, and reverse transcription-PCR (RT-PCR) studies confirmed previous work that suggested that the MHV-1 HE is a pseudogene. Targeted recombination was used to select chimeric viruses containing either the MHV-1 S gene or genes encoding all of the MHV-1 structural proteins, on an MHV-A59 background. Challenge studies in mice demonstrated that expression of the MHV-1 S gene within the MHV-A59 background (rA59/SMHV-1) increased the pneumovirulence of MHV-A59, and mice infected with this recombinant virus developed pulmonary lesions that were similar to those observed with MHV-1, although rA59/SMHV-1 was significantly less virulent. Chimeras containing all of the MHV-1 structural genes on an MHV-A59 background were able to reproduce the severe acute respiratory syndrome (SARS)-like pathology observed with MHV-1 and reproducibly increased pneumovirulence relative to rA59/SMHV-1, but were still much less virulent than MHV-1. These data suggest that important determinants of pneumopathogenicity are contained within the 3′ one-third of the MHV-1 genome, but additional important virulence factors must be encoded in the genome upstream of the S gene. The severity of the pulmonary lesions observed correlates better with elevated levels of inflammatory cytokines than with viral replication in the lungs, suggesting that pulmonary disease has an important immunological component.