Molecular evolution of hepatitis C virus quasispecies.

Abstract

The viral dynamics of the hepatitis C virus (HCV) in newly acquired infection are not well understood. HCV exists within an individual as a spectrum of minor variants termed quasispecies. The evolution of minor variants may contribute to viral escape of the host?s immune response, thereby facilitating development of chronic infection. The hypervariable 1 region (HVR1) is the most heterogeneous part of the HCV genome and contains a putative B-cell epitope. Thus, diversity in HVR1 could be a strategy used to evade neutralising antibodies. Acutely infected individuals (n=24) were examined with the aim of defining HVR1 quasispecies diversity in acute infection. The characterisation of the E1/HVR1 sequence and host specific evolution of HCV minor variants in treatment nonresponders was also investigated.

HCV E1/HVR1 fragments were amplified from 48 sera using a combined reverse transcription-polymerase chain reaction (RT-PCR). Products were TA cloned into pCRIITOPO and approximately 10-20 clones were sequenced from each sample. HVR1 quasispecies diversity was examined longitudinally via sequence analysis. Quasispecies diversity was characterised primarily by mean nucleotide diversity. The mean HVR1 diversity of the acute cohort (n=48; 2.12% ± 2.22) was lower than the diversity obtained for a cohort of chronically infected individuals (n=99; 4.5% ± 5.1). There was no significant difference in mean HVR1 diversity between the HIV/HCV co-infected and HCV mono-infected groups (p=0.99) or between the clearer and non-clearer groups (p=0.85). Examination of amino acid usage and the hydropathic profile of each position in HVR1 revealed that sequence variation was confined to specific sites. The investigation of host specific evolution of HVR1 quasispecies demonstrated that minor variants (comprising 10- 20% of a population) became the dominant species over time in two treatment non-responders. These variants bore mutations that were not reflected in the consensus sequence of their respective populations at the initial timepoint analysed. Common infection was identified by 98% HVR1 sequence homology within two pairs of individuals. The evolution of common strains appeared to be different between individuals, suggesting host pressures may influence quasispecies evolution. This thesis provided an insight into the viral dynamics and host specific evolution of acute phase quasispecies.