Evolution of viral quasispecies in interferon-treated patients with chronic hepatitis C virus infection

Genetic diversity of hepatitis C virus predicts recurrent disease after liver transplantation

Approximately 20% of patients receiving liver transplants for end-stage hepatitis C rapidly develop severe allograph fibrosis within the first 24 months after transplant. Hepatitis C virus (HCV) variants were studied in 56 genotype-1-infected subjects with end-stage hepatitis C disease at the time before and 12 months after liver transplant, and post-transplant outcome was followed with serial liver biopsies. In 15 cases, pre-transplant HCV genetic diversity was studied in detail in liver (n=15), serum (n=15), peripheral blood mononuclear cells (n=13), and perihepatic lymph nodes (n=10). Our results revealed that pre-transplant HCV genetic diversity predicted the histological outcome of recurrent hepatitis C disease after transplant. Mild disease recurrence after transplant was significantly associated with higher genetic diversity and greater diversity changes between the pre- and post-transplant time points (p=0.004). Meanwhile, pre-transplant genetic differences between serum and liver were related to a higher likelihood of development of mild recurrent disease after transplant (p=0.039).

Complexity of the HVR-1 quasispecies and disease activity in patients with hepatitis C

BACKGROUND

Hepatitis C virus (HCV) easily undergoes genomic changes, especially in the hypervariable region (HVR) in the N-terminus of the E2/NS1 region. The quasispecies nature of HCV may have important biological implications in relation to viral persistence; however, the relationship between disease activity of chronic HCV infection and development of the genomic complexity have yielded conflicting results. We explored the changes in the complexity of the HVR-1 in the natural course of chronic HCV infection with and without elevation of serum alanine transaminase (ALT) levels.

MATERIALS AND METHODS

Ten patients with chronic hepatitis C proven by liver biopsy, who showed persistent elevation of the serum ALT levels, and 15 patients with chronic HCV infection and persistently normal serum ALT levels (PNAL) were enrolled in this study. The number of the HCV quasispecies was determined twice for each patient at an interval of mean 2.5 years by fluorescence single-strand conformation polymorphism and sequence analysis.

RESULTS

There was no significant difference in the changes in the number of quasispecies during the follow-up period between chronic hepatitis C and PNAL. There was also no significant difference in the change in the number of variable nucleotides sites between the two groups. In these patients, the number of quasispecies and the diversity of HVR-1 were correlated with platelet counts and serum hyaluronic acid levels previously shown to be associated with disease progression.

CONCLUSION

Our results suggested that the disease activity is not always related to the generation of the HVR-1 quasispecies complexity.

Viral evolution of hepatitis C in injection drug users

Injection drug users represent the largest cohort of patients with established hepatitis C virus (HCV) infection as well as the group that is at highest risk for new infections. Most published studies have focused on the clinical consequences of established HCV infection and have not examined the consequences of new infection. The aim of the current study was to measure the virological consequences of HCV in patients with ongoing injection drug use that might pose a risk for new and/or for superinfection with additional strains of HCV. We examined the following groups: (a) those with resolved HCV infection with ongoing injection drug use, (b) those with chronic infection who continued to inject and (c) those with chronic infection who no longer injected. Our study demonstrated a spectrum of responses. The majority of patients appeared to be 'protected' from new infection. None of six patients with resolved infection had detectable HCV RNA by quantitative or qualitative PCR when followed for 1 year. Similarly, despite ongoing injection drug use, no patient with persistent infection had a 'switch' in HCV genotype indicative of possible superinfection. Virological analysis of HCV quasispecies to detect possible infection with new variants of HCV in patients with apparently 'stable' infection, indicated divergence of virus over time, divergence that was unrelated to injection drug behaviour. Thus, patients with ongoing or prior HCV infection appear to develop immunity that protects against further infection with HCV despite repeated exposure.

Quasispecies heterogeneity within the E1/E2 region as a pretreatment variable during pegylated interferon therapy of chronic hepatitis C virus infection

A series of 29 patients undergoing treatment for chronic hepatitis C virus (HCV) genotype 1 infection with pegylated alpha-2a interferon plus ribavirin were studied for patterns of response to antiviral therapy and viral quasispecies evolution. All patients were treatment naive and had chronic inflammation and fibrosis on biopsy. As part of an analysis of pretreatment variables that might affect the outcome of treatment, genetic heterogeneity within the viral E1-E2 glycoprotein region (nucleotides 851 to 2280) was assessed by sequencing 10 to 15 quasispecies clones per patient from serum-derived PCR products. Genetic parameters were examined with respect to response to therapy based on serum viral RNA loads at 12 weeks (early viral response) and at 24 weeks posttreatment (sustained viral response). Nucleotide and amino acid quasispecies complexities of the hypervariable region 1 (HVR-1) were less in the responder group in comparison to the nonresponder group at 12 weeks, and genetic diversity was also less both within and outside of the HVR-1, with the difference being most pronounced for the non-HVR-1 region of E2. However, these genetic parameters did not distinguish responders from nonresponders for sustained viral responses. Follow-up studies of genetic heterogeneity based on the HVR-1 in selected responders and nonresponders while on therapy revealed greater evolutionary drift in the responder subgroup. The pretreatment population sequences for the NS5A interferon sensitivity determinant region were also analyzed for all patients, but no correlations were found between treatment response and any distinct genetic markers. These findings support previous studies indicating a high level of genetic heterogeneity among chronically infected HCV patients. One interpretation of these data is that early viral responses are governed to some extent by viral factors, whereas sustained responses may be more influenced by host factors, in addition to effects of viral complexity and diversity.

Molecular biology and clinical implication of hepatitis C virus

Hepatitis C virus (HCV) was first described in 1989 as the putative viral agent of non-A non-B hepatitis. It is a member of the Flaviviridae family and has been recognized as the major causative agent of chronic liver disease, including chronic active hepatitis, cirrhosis and hepatocellular carcinoma. HCV is a positive RNA virus with a genome containing approximately 9500 nucleotides. It has an open reading frame that encodes a large polyprotein of about 3000 amino acids and is characterized by extensive genetic diversity. HCV has been classified into at least 6 major genotypes with many subtypes and circulates within an infected individual as a number of closely related but distinct variants known as quasispecies. This article reviews aspects of the molecular biology of HCV and their clinical implication.

Evolutionary study of HVR1 of E2 in chronic hepatitis C virus infection

Hypervariable region 1 (HVR1) of the hepatitis C virus (HCV) genome was directly sequenced from 12 chronically infected patients who had not responded to interferon (IFN) treatment. Due to the quasispecies nature of HCV circulating genomes, serum samples from four patients showing different evolutionary characteristics were further analysed. Serial samples from each patient were taken before, soon after and 14-23 months after a 6 month IFN treatment. HVR1 from each sample was amplified, cloned and the clones sequenced. For each patient, a phylogenetic analysis of the clones was performed and quasispecies complexity and genetic distances were calculated. The amino acid sequences and predicted antigenic profiles were analysed. The pre-treatment samples of the different patients presented dissimilar genetic quasispecies composition. For three of the patients, we showed that, regardless of the complexity or diversity of the viral populations before treatment, they evolved towards genetic diversification following selective pressure. Once the environment became stable, the entire population tended towards homogeneity. The fourth patient represented a case where different components of the quasispecies coexisted for long periods without replacement. We propose herein that the evolution of HVR1 of E2 is more likely to be directed by selection of clearly different subpopulations (modification of quasispecies equilibrium) than by a continuous mechanism related to the successive accumulation of point mutations. The prevalence of a quasispecies shift mechanism was revealed by the cloning analysis during the follow-up period of the evolutionary process.

An heteroduplex mobility analysis assay based on capillary electrophoresis for the study of HCV quasispecies

The quasispecies nature of the hepatitis C virus (HCV) genome is central to the transmission, persistence and pathogenesis of the infection. Heteroduplex mobility analysis (HMA) is a simple and an inexpensive technique for the qualitative and quantitative analysis of genetic variation of viral quasispecies. An original HMA for the HVR1 region of HCV was developed, based on a semi-automated, non-radioactive capillary electrophoresis system, which allows the processing of large numbers of samples in short times, the accurate measure of mobility shifts and the quantitation of heteroduplexes. A set of 120 HVR1 clones of known sequence was used to develop the assay, which was tested on HVR1 sequences amplified directly from sera of 17 HCV-infected patients. HVR1 sequence divergence directly correlated with the heteroduplex mobility ratio (HMR) of hybrid molecules between six and 40 mismatches. Heteroduplexes between one and six mismatches were resolved, although HMRs were not proportional to base changes, likely due to an effect of type and position of the substitutions. The assay sensitivity was 1% of the total sample size. This assay may allow the application of quasispecies analysis to a wider range of clinical and basic investigations.

Evolution of viral quasispecies in four dominant HlA-A2 restricted T cell epitopes is not a major reason for viral persistence in interferon-treated patients with chronic hepatitis C

In most patients, chronic hepatitis C virus (HCV) infection persists despite antiviral treatment with interferon-alpha (IFN-alpha) and ribavirin. The aim of the study was to determine whether HCV could evade cellular immune responses through mutations within T cell epitopes. Viral sequences flanking four major CTL epitopes within the HCV core and envelope regions were analyzed by PCR amplification, cloning and sequencing in seven HLA-A2 positive HCV patients before, during and after antiviral therapy. In addition, cytotoxic T lymphocyte precursor (CTLp) frequencies specific to these epitopes were quantitated by ELISPOT. A total of 13 coding mutations were observed among 650 cloned and sequenced PCR products under or post IFN treatment but no clear selection of viral variants. In detail, the diversity of quasispecies in the two core epitopes remained fairly stable over time despite variable CTLp induction in some individuals. The overall mutation rate in the two envelope epitopes was higher but there was no correlation with specific CTLp frequencies. In conclusion, although evolution of the viral quasispecies during and after antiviral therapy was demonstrated, immune evasion by epitope specific mutations seemed to be not common in interferon nonresponders because the viral complexity did not increase.