The influenza A virus M2 protein is an integral membrane protein of 97 amino acids that is expressed at the surface of infected cells with an extracellular N-terminal domain of 18 to 23 amino acid residues, an internal hydrophobic domain of approximately 19 residues, and a C-terminal cytoplasmic domain of 54 residues. To gain an understanding of the M2 protein function in the influenza virus replicative pathway, we produced and characterized a monoclonal antibody to M2. The antibody-binding site was located to the extracellular N terminus of M2 as shown by the loss of recognition after proteolysis at the infected-cell surface, which removes 18 N-terminal residues, and by the finding that the antibody recognizes M2 in cell surface fluorescence. The epitope was further defined to involve residues 11 and 14 by comparing the predicted amino acid sequences of M2 from several avian and human strains and the ability of the M2 protein to be recognized by the antibody. The M2-specific monoclonal antibody was used in a sensitive immunoblot assay to show that M2 protein could be detected in virion preparations. Quantitation of the amount of M2 associated with virions by two unrelated methods indicated that in the virion preparations used there are 14 to 68 molecules of M2 per virion. The monoclonal antibody, when included in a plaque assay overlay, considerably showed the growth of some influenza virus strains. This plaque size reduction is a specific effect for the M2 antibody as determined by an analysis of recombinants with defined genome composition and by the observation that competition by an N-terminal peptide prevents the antibody restriction of virus growth.
A panel of 20 recombinant Fab fragments reactive with the surface glycoprotein gpl20 of human type 1 immunodeficiency virus (HIV-1) were examined for their ability to neutralize MN and hUB strains of the virus. Neutralization was determined as the ability of the Fab fragments to inhibit infection as measured in both a p24 ELISA and a syncytium-formation assay. One group of closely sequencerelated Fab fragments was found to neutralize virus in both assays with a 50% neutralization titer at -1 ,ug/ml. AnotherFab neutralized in the p24 ELISA but not in the syncytium assay. The other Fab fragments showed weak or no neutralizing ability. The results imply that virion aggregation or crosslinking of gp120 molecules on the virion surface is not an absolute requirement for HIV-1 neutralization. Further, all of the Fab fragments were shown to be competitive with soluble CD4 for binding to gpl20 and yet few neutralized the virus effectively, implying that the mechanism of neutralization in this case may not involve receptor blocking. The observation of a preponderance ofhigh-affminty Fab fragments with poor or no neutralizing ability could have implications for vaccine strategies.
Genomic RNA from the human prototype strain H of the hepatitis C virus (HCV-H) has been molecularly cloned and sequenced. The HCV-H sequence reported consists of 9416 nucleotides including the 5' and 3' untranslated regions. HCV-H shows 96% amino acid identity with the American isolate HCV-1 but only 84.9% with the Japanese isolates HCV-J and HCV-BK. In addition to the hypervariable region (region V) previously identified in the putative E2 domain, three other variable domains were identified: region V1 (putative El), region V2 (putative E2), and region V3 (putative NS5). These regions appear rather conserved (86-100%) among the American isolates (HCV-1 and HC-J1) or among various Japanese isolates (HCV-J, HCV-BK, HCV-JH, and HC-J4) but show striking heterogeneity when the two subgroups are compared (42-87.5% amino acid difference). A structural similarity between the 5'-terminal hairpin structure of HCV and of poliovirus was observed. This study further suggests the existence of at least two genomic subtypes of HCV and confirms a distant relationship between HCV and pestiviruses.
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