Induction of heterotypic virus resistance in adult inbred mice immunized with a variant of Coxsackievirus B3.

Infection of adult male C3H/HeJ mice with a host range variant of Coxsackievirus B3 (CB3W-RD) induced resistance in these mice to an otherwise lethal dose of Coxsackievirus B1 (CB1). The protective effect induced by CB3W-RD was detectable as early as 1 day post-vaccination and was still present 10 weeks later. While untreated mice infected with CB1 died within 5 days because of massive hepatic necrosis, the liver was spared in mice immunized with CB3W-RD and then challenged with CB1. In general, CB1 titers in heart, liver, and pancreas of CB3W-RD-vaccinated animals were lower than that found in unvaccinated animals. Virus neutralizing antibody was not a mediator of this heterotypic, virus-induced protective effect. In addition, the outcome of CB1 infection could be modified if superinfection with CB3W-RD took place within 1-4 days following CB1 infection. In this regard, maximum therapeutic efficacy was observed when CB1 infected mice were superinfected 2 days after CB1 infection. CB1-infected mice that survived as a result of treatment with CB3W-RD exhibited liver regeneration but did develop myocardial necrosis.

Separation of functional West Nile virus replication complexes from intracellular membrane fragments.

Flaviviruses encode seven non-structural proteins for which functions have not yet been described. The identification of the viral and possible host proteins which may be involved in flavivirus replication has been impeded by the fact that the viral replication complexes are tightly associated with endoplasmic reticular membranes within infected cells and that in vitro polymerase activity is associated with large membrane fragments. To facilitate further study of flavivirus replication complexes, selected ultrapure detergents were analysed for their effect on West Nile virus (WNV) in vitro RNA-dependent RNA polymerase activity and for their ability to release functional replication complexes from partially purified intracellular BHK-21 membrane fragments. A few previous reports indicated that flavivirus in vitro polymerase activity was sensitive to detergent treatment. The present study indicates that WNV polymerase activity is variably inhibited depending on the concentration and identity of the detergent used. Of the five detergents (Tween 20, maltoside, octylglucoside, lubrol PX and sodium deoxycholate) tested, sodium deoxycholate was the most efficient at releasing functional viral replication complexes from intracellular membranes.

Pathogenesis of acute myocardial necrosis in inbred mice infected with coxsackievirus B3.

The pathogenesis of myocardial necrosis due to CB3W infection was studied in BALB/c and C3H/HeJ mice. BALB/c mice infected with 5 x 10(4) pfu were found to die of massive hepatic coagulative necrosis before myocardial changes occurred. Reducing the inoculum size to 5 x 10(2) pfu resulted in sublethal hepatic involvement and multifocal myocardial coagulative necrosis by day 7 p.i. In contrast, C3H/HeJ mice survived infection and developed multifocal myocardial coagulative necrosis, but not liver disease following inoculation with as much as 5 x 10(6) pfu of CB3W. As with BALB/c mice infected with 5 x 10(2) pfu, myocardial lesions became apparent in C3H/HeJ mice a few days after peak cardiac virus titer was attained. Minimal inflammatory infiltrate was seen following development of cellular necrosis and was restricted to the areas of virus-induced pathologic change. However, no evidence was found for virus-specific cytotoxic T cell activity or for delayed type hypersensitivity responses. Furthermore, myocardial necrosis in CB3W-infected, T cell-depleted C3H/HeJ mice was as severe as in CB3W-infected, immunocompetent mice. These data have led us to conclude that cardiac lesions were due to virus-induced cytopathology rather than immunopathogenic mechanisms.

Dissociation of NS5 from cell fractions containing West Nile virus-specific polymerase activity.

West Nile virus replication complexes were partially purified from cytoplasmic extracts of virus-infected cells by centrifugation through a 20% glycerol cushion. Numerous cell proteins, as well as the largest nonstructural protein, NS5, were separated from the replication complexes without significant loss of in vitro West Nile virus polymerase activity.

Characterization of West Nile virus RNA-dependent RNA polymerase and cellular terminal adenylyl and uridylyl transferases in cell-free extracts.

To facilitate further studies of flavivirus transcription, cell extraction methods and in vitro reaction conditions which increased West Nile virus (WNV) RNA-dependent RNA polymerase activity were determined. Subcellular fractions from WNV-infected BHK-21/W12 cells were characterized with regard to their protein and RNA content and in vitro polymerase activity. In both a cytoplasmic fraction, designated S1, and a fraction enriched for outer nuclear membranes, designated S2, seven virus-specific proteins, NS5 (96 kilodaltons [kDa]), NS3 (67 kDa), E (48 kDa), NS1 (47 kDa), ns4a (26 kDa), ns2a (17 kDa), and ns2b (14.5 kDa), were detected. The fractions also contained virus-specific RNA and cellular rRNA and mRNA. Polymerase activity in S1 and S2 fractions from WNV-infected cells was concentrated by pelleting and consisted of two types of enzyme activities: the WNV RNA-dependent RNA polymerase and terminal transferases of cellular origin. Enhanced levels of WNV polymerase activity were obtained from these cell fractions by altering several of the in vitro reaction conditions. Although Mg2+ was the divalent cation preferred by WNV polymerase, virus-specific in vitro transcription was detected at reduced levels when Mn2+ (0.05 or 0.5 mM) was present as the sole divalent cation. Product analysis revealed that the viral polymerase incorporated radiolabeled ribonucleotides into three distinct RNA species. Free single-stranded genome-sized RNA which was LiCl insoluble and RNase sensitive was found by fingerprint analysis to have an oligonucleotide pattern similar to that of WNV genomic RNA. RNA molecules which comigrated as a broad band near the top of the gel were separable into LiCl-insoluble, partially RNase-sensitive replicative-intermediate RNA and LiCl-soluble, RNase-resistant replicative-form RNA. The cellular transferases added UMP or AMP residues to the 3'-termini of cellular mRNA, tRNA, and 18S and 28S rRNA. Although a cellular terminal transferase has been reported to function in initiation of poliovirus transcription, no labeling of the WNV RNA by either of these cellular enzymes was detected. Therefore, they appear to play no specific role in flavivirus RNA synthesis.