NS5B

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

Identification of hepatitis C virus 2k/1b intergenotypic recombinants in Georgia

Abstract: Background and Aims This study aimed to evaluate the prevalence of the hepatitis C virus intergenotype recombinant strain RF1_2k/1b in Georgia, confirm viral recombination by full genome sequencing, and determine a genetic relationship with previously described recombinant hepatitis C viruses. Methods We retrospectively analysed data from 1421 Georgian patients with chronic hepatitis C. Genotyping was performed with the INNO-LiPA VERSANT HCV Genotype 2.0 Assay. Results Virus isolates were assigned to nonspecific hepatitis C genotypes 2a/2c (n = 387) as performed by sequencing of core and NS5B genes. Subsequently, sequencing results classified the core region as genotype 2k and the NS5B region as genotype 1b for 72% (n = 280) of genotype 2 patients, corresponding to 19.7% of hepatitis C patients in Georgia. Eight samples were randomly selected for full genome sequencing which was successful in 7 of 8 samples. Analysis of the generated consensus sequences confirmed that all 7 viruses were 2k/1b recombinants, with the recombination breakpoint located within 73-77 amino acids before the NS2-NS3 junction, similar to the previously described RF1_2k/1b virus. Phylogenetic analysis revealed clustering of the Georgian 2k/1b viruses and RF1_2k/1b, suggesting that they are genetically related. Conclusions The 19.7% prevalence of RF1_2k/1b in Georgia patients is far higher than has generally been reported to date worldwide. Identification of recombinants in low income countries with a high prevalence of HCV infection might be reasonable for choosing the most cost-effective treatment regimens.

The variable N-terminal region of DDX5 contains structural elements and auto-inhibits its interaction with NS5B of hepatitis C virus.

Abstract: RNA helicases of the DEAD (Asp-Glu-Ala-Asp)-box family of proteins are involved in many aspects of RNA metabolism from transcription to RNA decay, but most of them have also been shown to be multifunctional. The DEAD-box helicase DDX5 of host cells has been shown to interact with the RNA-dependent RNA polymerase (NS5B) of HCV (hepatitis C virus). In the present study, we report the presence of two independent NS5B-binding sites in DDX5, one located at the N-terminus and another at the C-terminus. The N-terminal fragment of DDX5, which consists of the first 305 amino acids and shall be referred as DDX5-N, was expressed and crystallized. The crystal structure shows that domain 1 (residues 79-303) of DDX5 contains the typical features found in the structures of other DEAD-box helicases. DDX5-N also contains the highly variable NTR (N-terminal region) of unknown function and the crystal structure reveals structural elements in part of the NTR, namely residues 52-78. This region forms an extensive loop and an α-helix. From co-immunoprecipitation experiments, the NTR of DDX5-N was observed to auto-inhibit its interaction with NS5B. Interestingly, the α-helix in NTR is essential for this auto-inhibition and seems to mediate the interaction between the highly flexible 1-51 residues in NTR and the NS5B-binding site in DDX5-N. Furthermore, NMR investigations reveal that there is a direct interaction between DDX5 and NS5B in vitro.

Serological response to infection with different isolates of hepatitis C virus.

Abstract: Different isolates of hepatitis C virus (HCV) show nucleotide sequence variability throughout the genome. Detection of antibodies to recombinant proteins derived from hepatitis C virus genotype 1, the prototype HCV clone HCV-PT, constitutes the main method for screening HCV infection. The influence of the genomic variability on the serological diagnosis of HCV by enzyme immunoassay remains poorly defined. The aim of this study was to assess the serological reactivity of a panel of well characterized French HCV isolates typed by sequence analysis from patients with chronic hepatitis. The 73 sera samples were tested in three third generation EIA tests and three confirmatory assays. HCV isolates were determined by RT-PCR and sequencing in NS5B region of the genome. The 73 sera were positive in the three EIA tests. The three confirmatory tests showed a weaker reactivity with NS5 protein whatever the genotype, and a lower reactivity in NS4 antigens of non-type 1 sequences, particularly for genotype 3. Even though the reactivity of the antigens differed among the HCV isolates, the 73 isolates from genotype 1-6 were reactive with the three commercial screening assays. These results demonstrate that using a single test is adequate in the routine diagnosis of HCV infection in clinical laboratory, as recommended by the last French and European consensus conference.

A unique intra-molecular fidelity-modulating mechanism identified in a viral RNA-dependent RNA polymerase.

Abstract: Typically not assisted by proofreading, the RNA-dependent RNA polymerases (RdRPs) encoded by the RNA viruses may need to independently control its fidelity to fulfill virus viability and fitness However, the precise mechanism by which the RdRP maintains its optimal fidelity level remains largely elusive By solving 21-25 A resolution crystal structures of the classical swine fever virus (CSFV) NS5B, an RdRP with a unique naturally fused N-terminal domain (NTD), we identified high-resolution intra-molecular interactions between the NTD and the RdRP palm domain In order to dissect possible regulatory functions of NTD, we designed mutations at residues Y471 and E472 to perturb key interactions at the NTD-RdRP interface When crystallized, some of these NS5B interface mutants maintained the interface, while the others adopted an 'open' conformation that no longer retained the intra-molecular interactions Data from multiple in vitro RdRP assays indicated that the perturbation of the NTD-RdRP interactions clearly reduced the fidelity level of the RNA synthesis, while the processivity of the NS5B elongation complex was not affected Collectively, our work demonstrates an explicit and unique mode of polymerase fidelity modulation and provides a vivid example of co-evolution in multi-domain enzymes