Abstract

Hepatitis C virus (HCV) infection remains a major worldwide health problem despite development of highly effective direct-acting antivirals. HCV rapidly evolves upon acute infection and generates multiple viral variants (quasispecies), leading to immune evasion and persistent viral infection. Identification of epitopes of broadly neutralizing anti-HCV antibodies (nAbs) is critical to guide HCV vaccine development. In this study, we developed a new reverse genetics system for HCV infection based on trans-complementation of viral structural proteins. The HCV genome (JFH1 strain) lacking the structural protein-coding sequence can be efficiently rescued by ectopic expression of core-E1-E2-p7-NS2 (core-NS2) or core-E1-E2-p7 (core-p7) in trans, leading to production of single-round infectious virions designated HCVΔS. JFH1-based HCVΔS can be also rescued by expressing core-NS2 of other HCV genotypes, rendering it an efficient tool to display the structural proteins of HCV strains of interests. Furthermore, we successfully rescued HCVΔS with structural proteins from clinical isolates. Multiple viral structural proteins with different sensitivities to nAbs were identified from a same patient serum, demonstrating the genetic diversity of HCV quasispecies in vivo Interestingly, the structural protein-coding sequences of highly divergent viral quasispecies from the same patient can be clustered based on their hypervariable region 1 (HVR1) in viral envelope protein E2, which critically dictates the sensitivity to neutralizing antibodies. In summary, we developed a novel reverse genetics system that efficiently displays viral structural proteins from HCV clinical isolates, and analysis of quasispecies from the same patient using this system demonstrated that E2 HVR1 is the major determinant of viral evolution in vivoIMPORTANCE A cell culture model that can recapitulate the diversity of HCV quasispecies in patients is important for analysis of neutralizing epitopes and HCV vaccine development. In this study, we developed a new reverse genetics system for HCV infection based on trans-complementation of viral structural proteins (HCVΔS). This system can be used to display structural proteins of HCV strains of multiple genotypes as well as clinical isolates. By using this system, we showed that multiple different HCV structural proteins from a same patient were displayed on HCVΔS. Interestingly, these variant structural proteins within the same patient can be classified according to the sequence of HVR1in E2, which dictates viral sensitivity to nAbs and viral evolution in vivo Our work provided a new tool to study highly divergent HCV quasispecies and shed light on underlying mechanisms driving HCV evolution.

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