Hepatitis C virus: kinetics and quasispecies evolution during anti-viral therapy.

The balance of virus production and clearance for untreated patients with chronic hepatitis C changes into a decline of viraemia when initiating effective anti-viral treatment. During the first phase of interferon-alpha (IFN-a) therapy, the kinetics of the viral load is characterised by a rapid dose-dependent decline starting after a delay of about eight to nine hours. This early response can be observed for almost all patients treated with IFN-a. After about 24 to 48 hours, the viral decline slows down leading to a second phase with a relatively stable exponential decay. Some non-responding patients show a nearly constant viraemia and some even a rebound throughout this second phase. Kinetic models allow the estimation of rates of viral production and clearance and reveal high turnover rates of hepatitis C virus (HCV) and an in vivo half-life of hepatitis C virions of a few hours, only. Due to the continuous and high replication rate in vivo, the low fidelity of the ribonucleic acid (RNA)-dependent RNA polymerase, and the immune surveillance of the host, HCV exists in an individual patient as a heterogeneous population of related viruses (quasispecies). A high degree of quasispecies variability correlates with a lower response to IFN-a therapy. Changes of the quasispecies population are more pronounced after initiation of treatment with IFN-a or interleukin-12 than during the natural course of disease. Ribavirin, however, has not been found to affect the HCV quasispecies population. Identification of a specific region within an envelope-encoding gene as the most variable region of HCV and as a critical neutralisation domain suggests that viral escape mechanisms are a possible cause for chronification and poses a major challenge for the development of a broadly reactive vaccine against HCV.