Molecular characterization of hepatitis C virus genotype 2a from the entire sequences of four isolates

The evolutionary patterns of hepatitis C virus subtype 2a and 6a isolates linked to an outbreak in China in 2012

An HCV outbreak occurred in 2012 in China, affecting hundreds of patients. We characterized HCV subtype 2a and 6a sequences from 60 and 102 patients, respectively, and co-analyzed them with 82 local controls and 103 calibrating references. The close grouping of the patients׳ sequences contrasted sharply with the diversity of local controls. Scaled by the calibrating references, the emergence of patients׳ isolates was estimated at 2-5 years before sampling. In contrast, the controls intermingled with the calibrating references that were much older. For both subtypes, the major and minor clusters could be defined, with the closeness to indicate linked transmission.

CONCLUSION

HCV sequences from the study patients grouped into three subtype 2a and two subtype 6a clusters, in addition to three 6a solitary branches, representing descendants of eight earlier strains that were distinct and otherwise sporadic. Due to iatrogenic transmission through reusing needles, five strains were highly selected and preferentially spread.

Taxonomy of genus Hepacivirus. Application of palindromic nucleotide substitutions for the determination of genotypes of human hepatitis C virus species

The palindromic nucleotide substitutions (PNS) in the 5'-untranslated region (UTR) of Pestivirus RNA have been described as a new, simple and practical method for genotyping. Given the genetic relatedness between Pestivirus and hepatitis C virus species, the application of the method was investigated preliminarily on 180 isolates, including reference strains. The keys for hepatitis C virus identification have been determined at the genus, species, genotype and subtype levels. Secondary structure nucleotide substitutions were characteristics to the genus included in a complex stem-loop structure composed of 112-115 nucleotides. Due to the worldwide importance of hepatitis C virus, and the difficulties encountered in the control of the disease, it is, therefore, important to understand the genetic aspects of the virus. The application of the PNS method might represent an additional useful tool for determining the genetic variations among hepatitis C virus strains. The identification of viral types or subtypes based on genetic changes should improve our understanding of hepatitis C virus and might provide markers for biological differences, such as virulence, and improve understanding of the evolution of the virus.