Molecular evolution of GB virus B hepatitis virus during acute resolving and persistent infections in experimentally infected tamarins.

GB virus B (GBV-B) causes acute hepatitis in experimentally infected tamarins. We compared evolutionary features in acute resolving and persistent GBV-B infection. We detected no evidence of evolution in four animals with clearance during weeks 9-12, whereas three animals with clearance during weeks 13-26 had several substitutions in their polyprotein sequence. A single tamarin had long-term GBV-B viraemia; analysis of virus recovered at weeks 2, 5, 12, 20, 26, 52 and 104 demonstrated that mutations accumulated over time. Overall, the amino acid substitution rate was 3.5x10(-3) and 1.1x10(-3) substitutions per site year(-1) during weeks 1-52 and 53-104, respectively. Thus, there was a significant decrease in evolution over time, as found for hepatitis C virus. The rate of non-synonymous substitution per non-synonymous site compared with that of synonymous substitution per synonymous site decreased over time, suggesting reduction of positive selective pressure. These data demonstrate that prolonged GBV-B infection is associated with viral evolution.

The entire core protein of HCV JFH1 is required for efficient formation of infectious JFH1 pseudoparticles.

The vast majority of hepatitis C virus (HCV) strains cannot be grown in cell culture. Therefore, tests for neutralizing antibodies have relied heavily on retrovirus pseudoparticles displaying the envelope glycoproteins of HCV on their surface (HCVpp). Unfortunately, the envelope proteins of some strains, especially of JFH1, did not efficiently form functional HCVpp. We have manipulated the length and composition of the HCV core gene in the HCVpp expression vectors for three strains of HCV in an attempt to obtain more efficient production of pseudoparticles. The results demonstrated that the truncated core region included in the HCV expression plasmids of the classic pseudoparticle system was optimal for formation of strain H77pp, suboptimal for strain J6pp, and insufficient for strain JFH1pp. Efficiency of JFH1pp formation increased 20-fold when the truncated core gene was replaced with the entire core gene. The full core from J6 and HK had modest effect on the production of infectious J6 and HKpp. The data suggested that pairs of HCV glycoproteins differ inherently in their ability to associate into functional heterodimers and that the core protein, provided in cis as the beginning of the polyprotein product, can in some cases facilitate this process, possibly by increasing the rate of proper folding of the glycoproteins.

Apolipoprotein c1 association with hepatitis C virus.

Accumulating evidence suggests that cellular lipoprotein components are involved in hepatitis C virus (HCV) morphogenesis, but the precise contribution of these components remains unclear. We investigated the involvement of apolipoprotein C1 (ApoC1) in HCV infection in the HCV pseudotyped particle system (HCVpp), in the recently developed cell culture infection model (HCVcc), and in authentic HCV isolated from viremic chimpanzees. Viral genomes associated with HCVcc or authentic HCV were efficiently immunoprecipitated by anti-ApoC1, demonstrating that ApoC1 was a normal component of HCV. The infectivities of HCVpp that had been mixed with ApoC1 and, more importantly, untreated HCVcc collected from lysates or media of infected Huh7.5 cells were directly neutralized by anti-ApoC1. Indeed, convalescent anti-HCV immunoglobulin G and anti-ApoC1 each neutralized over 75% of infectious HCVcc particles, indicating that many, if not all, infectious particles were recognized by both antibodies. Moreover, peptides corresponding to the C-terminal region of ApoC1 blocked infectivity of both HCVpp and HCVcc. Altogether, these results suggest that ApoC1 associates intracellularly via its C-terminal region with surface components of virions during viral morphogenesis and may play a major role in the replication cycle of HCV.

Isolation and characterization of broadly neutralizing human monoclonal antibodies to the e1 glycoprotein of hepatitis C virus.

The relative importance of humoral and cellular immunity in the prevention or clearance of hepatitis C virus (HCV) infection is poorly understood. However, there is considerable evidence that neutralizing antibodies are involved in disease control. Here we describe the detailed analysis of human monoclonal antibodies (MAbs) directed against HCV glycoprotein E1, which may have the potential to control HCV infection. We have identified two MAbs that can strongly neutralize HCV-pseudotyped particles (HCVpp) bearing the envelope glycoproteins of genotypes 1a, 1b, 4a, 5a, and 6a and less strongly neutralize HCVpp bearing the envelope glycoproteins of genotype 2a. Genotype 3a was not neutralized. The epitopes for both MAbs were mapped to the region encompassing amino acids 313 to 327. In addition, robust neutralization was also observed against cell culture-adapted viruses of genotypes 1a and 2a. Results from this study suggest that these MAbs may have the potential to prevent HCV infection.