NS5B

About: NS5B is a research topic. Over the lifetime, 1314 publications have been published within this topic receiving 59534 citations.

Dual Allosteric Inhibitors Jointly Modulate Protein Structure and Dynamics in the Hepatitis C Virus Polymerase.

Abstract: The hepatitis C virus (HCV) infects close to 200 million people globally, resulting in a significant need for effective HCV therapies. The HCV polymerase (gene product NS5B) is a valuable target for therapeutics because of its role in replicating the viral genome. Various studies have identified inhibitors for this enzyme, including non-nucleoside inhibitors (NNIs) that bind distal to the enzyme active site. Recently, it has been shown that simultaneously challenging the enzyme with two NNIs results in enhanced inhibition relative to that observed after challenge with individual inhibitors, suggesting that employing multiple NNIs might be the basis of more effective therapeutics. Nevertheless, the molecular mechanisms responsible for this enhanced inhibition remain unclear. We employ molecular dynamics simulations to determine the origin of enhanced inhibition when two NNIs bind to NS5B. Our results suggest that nonoverlapping NNI sites are compatible with simultaneous binding of dual NNIs. We observe that both inhibitors act in concert to induce novel enzyme conformations and dynamics, allowing us to identify molecular mechanisms underlying enhanced inhibition of NS5B. This knowledge will be useful in optimizing combinations of NNIs to target NS5B, helping to prevent the acquisition of viral resistance that remains a significant barrier to the development of HCV therapeutics.

Development of an Infectious Cell Culture System for Hepatitis C Virus Genotype 6a Clinical Isolate Using a Novel Strategy and Its Sensitivity to Direct-Acting Antivirals.

Abstract: Hepatitis C virus (HCV) is classified into seven major genotypes, and genotype 6 is commonly prevalent in Asia, thus reverse genetic system representing genotype 6 isolates in prevalence is required. Here, we developed an infectious clone for a Chinese HCV 6a isolate (CH6a) using a novel strategy. We determined CH6a consensus sequence from patient serum and assembled a CH6a full-length (CH6aFL) cDNA using overlapped PCR product-derived clones that shared the highest homology with the consensus. CH6aFL was non-infectious in hepatoma Huh7.5 cells. Next, we constructed recombinants containing Core-NS5A or 5'UTR-NS5A from CH6a and the remaining sequences from JFH1 (genotype 2a), and both were engineered with 7 mutations identified previously. However, they replicated inefficiently without virus spread in Huh7.5 cells. Addition of adaptive mutations from CH6a Core-NS2 recombinant, with JFH1 5'UTR and NS3-3'UTR, enhanced the viability of Core-NS5A recombinant and acquired replication-enhancing mutations. Combination of 22 mutations in CH6a recombinant with JFH1 5'UTR and 3'UTR (CH6aORF) enabled virus replication and recovered additional four mutations. Adding these four mutations, we generated two efficient recombinants containing 26 mutations (26m), CH6aORF_26m and CH6aFL_26m (designated "CH6acc"), releasing HCV of 104.3-104.5 focus-forming units (FFU)/ml in Huh7.5.1-VISI-mCherry and Huh7.5 cells. Seven newly identified mutations were important for HCV replication, assembly, and release. The CH6aORF_26m virus was inhibited in a dose- and genotype-dependent manner by direct-acting-antivirals targeting NS3/4A, NS5A, and NS5B. The CH6acc enriches the toolbox of HCV culture systems, and the strategy and mutations applied here will facilitate the culture development of other HCV isolates and related viruses.