James L. Gombold scite author profile

Infection of primary mouse glial cell cultures with mouse hepatitis virus strain A59 results in a productive, persistent infection, but without any obvious cytopathic effect. Mutant viruses isolated from infected glial cultures 16 to 18 weeks postinfection replicate with kinetics similar to those of wild-type virus but produce small plaques on fibroblasts and cause only minimal levels of cell-to-cell fusion under conditions in which wild type causes nearly complete cell fusion. However, since extensive fusion is present in mutant-infected cells at late times postinfection, the defect is actually a delay in kinetics rather than an absolute block in activity. Addition of trypsin to mutant-infected fibroblast cultures enhanced cell fusion a small (two- to fivefold) but significant degree, indicating that the defect could be due to a lack of cleavage of the viral spike (fusion) protein. Sequencing of portions of the spike genes of six fusion-defective mutants revealed that all contained the same single nucleotide mutation resulting in a substitution of aspartic acid for histidine in the spike cleavage signal. Mutant virions contained only the 180-kDa form of spike protein, suggesting that this mutation prevented the normal proteolytic cleavage of the 180-kDa protein into the 90-kDa subunits. Examination of revertants of the mutants supports this hypothesis. Acquisition of fusion competence correlates with the replacement of the negatively charged aspartic acid with either the wild-type histidine or a nonpolar amino acid and the restoration of spike protein cleavage. These data confirm and extend previous reports concluding cleavage of S is required for efficient cell-cell fusion by mouse hepatitis virus but not for virus-cell fusion (infectivity).

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MHV-A59 Fusion Mutants Are Attenuated and Display Altered Hepatotropism

Hingley

et al. 1994

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Coronavirus-Induced Membrane Fusion Requires the Cysteine-Rich Domain in the Spike Protein

2000

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The spike glycoprotein of mouse hepatitis virus strain A59 mediates the early events leading to infection of cells, including fusion of the viral and cellular membranes. The spike is a type I membrane glycoprotein that possesses a conserved transmembrane anchor and an unusual cysteine-rich (cys) domain that bridges the putative junction of the anchor and the cytoplasmic tail. In this study, we examined the role of these carboxyl-terminal domains in spike-mediated membrane fusion. We show that the cytoplasmic tail is not required for fusion but has the capacity to enhance membrane fusion activity. Chimeric spike protein mutants containing substitutions of the entire transmembrane anchor and cys domain with the herpes simplex virus type 1 glycoprotein D (gD-1) anchor demonstrated that fusion activity requires the presence of the A59 membrane-spanning domain and the portion of the cys domain that lies upstream of the cytoplasmic tail. The cys domain is a required element since its deletion from the wild-type spike protein abrogates fusion activity. However, addition of the cys domain to fusion-defective chimeric proteins was unable to restore fusion activity. Thus, the cys domain is necessary but is not sufficient to complement the gD-1 anchor and allow for membrane fusion. Site-specific mutations of conserved cysteine residues in the cys domain markedly reduce membrane fusion, which further supports the conclusion that this region is crucial for spike function. The results indicate that the carboxyl-terminus of the spike transmembrane anchor contains at least two distinct domains, both of which are necessary for full membrane fusion.

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Analysis of reassortment of genome segments in mice mixedly infected with rotaviruses SA11 and RRV

Gombold¹,

Ramig²

1986

J Virol

105

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Seven-day-old CD-1 mice born to seronegative dams were orally inoculated with a mixture of wild-type simian rotavirus SAil and wild-type rhesus rotavirus RRV. At various times postinfection, progeny clones were randomly isolated from intestinal homogenates by limiting dilution. Analysis of genome RNAs by polyacrylamide gel electrophoresis was used to identify and genotype reassortant progeny. Reassortment of genome segments was observed in 252 of 662 (38%) clones analyzed from in vivo mixed infections. Kinetic studies indicated that reassortment was an early event in the in vivo infectious cycle; more than 25% of the progeny clones were reassortant by 12 h postinfection. The frequency of reassortant progeny increased to 80 to 100% by 72 to 96 h postinfection. A few reassortants with specific constellations of SAil and RRV genome segments were repeatedly isolated from different litters or different animals within single litters, suggesting that these genotypes were independently and specifically selected in vivo. Analysis of segregation of individual genome segments among the 252 reassortant progeny revealed that, although most segments segregated randomly, segments 3 and 5 nonrandomly segregated from the SAll parent. The possible selective pressures active during in vivo reassortment of rotavirus genome segments are discussed.

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Antibody Is Required for Clearance of Infectious Murine Hepatitis Virus A59 from the Central Nervous System, But Not the Liver

Matthews

Weiss

Shlomchik

et al. 2001

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Intracerebral inoculation with mouse hepatitis virus strain A59 results in viral replication in the CNS and liver. To investigate whether B cells are important for controlling mouse hepatitis virus strain A59 infection, we infected muMT mice who lack membrane-bound IgM and therefore mature B lymphocytes. Infectious virus peaked and was cleared from the livers of muMT and wild-type mice. However, while virus was cleared from the CNS of wild-type mice, virus persisted in the CNS of muMT mice. To determine how B cells mediate viral clearance, we first assessed CD4+ T cell activation in the absence of B cells as APC. CD4+ T cells express wild-type levels of CD69 after infection in muMT mice. IFN-γ production in response to viral Ag in muMT mice was also normal during acute infection, but was decreased 31 days postinfection compared with that in wild-type mice. The role of Ab in viral clearance was also assessed. In wild-type mice plasma cells appeared in the CNS around the time that virus is cleared. The muMT mice that received A59-specific Ab had decreased virus, while mice with B cells deficient in Ab secretion did not clear virus from the CNS. Viral persistence was not detected in FcR or complement knockout mice. These data suggest that clearance of infectious mouse hepatitis virus strain A59 from the CNS requires Ab production and perhaps B cell support of T cells; however, virus is cleared from the liver without the involvement of Abs or B cells.

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James L. Gombold

Fusion-defective mutants of mouse hepatitis virus A59 contain a mutation in the spike protein cleavage signal

MHV-A59 Fusion Mutants Are Attenuated and Display Altered Hepatotropism

Coronavirus-Induced Membrane Fusion Requires the Cysteine-Rich Domain in the Spike Protein

Analysis of reassortment of genome segments in mice mixedly infected with rotaviruses SA11 and RRV

Antibody Is Required for Clearance of Infectious Murine Hepatitis Virus A59 from the Central Nervous System, But Not the Liver

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