Ledipasvir, a direct acting antiviral agent (DAA) targeting the Hepatitis C Virus NS5A protein, exhibits picomolar activity in replicon cells. While its mechanism of action is unclear, mutations that confer resistance to ledipasvir in HCV replicon cells are located in NS5A, suggesting that NS5A is the direct target of ledipasvir. To date co-precipitation and cross-linking experiments in replicon or NS5A transfected cells have not conclusively shown a direct, specific interaction between NS5A and ledipasvir. Using recombinant, full length NS5A, we show that ledipasvir binds directly, with high affinity and specificity, to NS5A. Ledipasvir binding to recombinant NS5A is saturable with a dissociation constant in the low nanomolar range. A mutant form of NS5A (Y93H) that confers resistance to ledipasvir shows diminished binding to ledipasvir. The current study shows that ledipasvir inhibits NS5A through direct binding and that resistance to ledipasvir is the result of a reduction in binding affinity to NS5A mutants.
Genotype 6 (GT6) hepatitis C virus (HCV) is prevalent in Southeast Asia and southern China, where it can constitute up to 50% of HCV infections. Despite this, no direct-acting antivirals are approved to treat GT6 HCV infection, and no cell culture systems have been described. In this study, we aimed to develop a GT6 HCV subgenomic replicon to facilitate the identification and development of new HCV therapies with pan-genotype activity. A subgenomic replicon cDNA encoding a GT6a consensus sequence plus an NS5A amino acid substitution (S232I) was synthesized. Electroporation of RNA encoding the GT6a replicon into Huh-7-derived cells consistently yielded 20 to 100 stable replicon colonies. Genotypic analyses of individual replicon colonies revealed new adaptive mutations across multiple viral nonstructural proteins. The E30V and K272R mutations in NS3 and the K34R mutation in NS4A were observed most frequently and were confirmed to enhance GT6a replicon replication in the presence of the NS5A amino acid substitution S232I. These new adaptive mutations allowed establishment of robust luciferase-encoding GT6a replicons for reproducible quantification of HCV replication, and the luciferase-encoding replicons enabled efficient determinations of antiviral activity for HCV inhibitors in a 384-well assay format. While nucleoside/nucleotide NS5B inhibitors and cyclophilin A inhibitors had similar antiviral activities against both GT6a and GT1b replicons, some nonnucleoside NS5B inhibitors, NS3 protease inhibitors, and NS5A inhibitors had less antiviral activity against GT6a replicons. In conjunction with other genotype replicons, this robust GT6a replicon system will aid in the development of pan-genotypic HCV regimens.
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