Product release is the major contributor to kcat for the hepatitis C virus helicase-catalyzed strand separation of short duplex DNA.

Hepatitis C virus (HCV) helicase catalyzes the ATP-dependent strand separation of duplex RNA and DNA containing a 3' single-stranded tail. Equilibrium and velocity sedimentation centrifugation experiments demonstrated that the enzyme was monomeric in the presence of DNA and ATP analogues. Steady-state and pre-steady-state kinetics for helicase activity were monitored by the fluorescence changes associated with strand separation of F21:HF31 that was formed from a 5'-hexachlorofluorescein-tagged 31-mer (HF31) and a complementary 3'-fluorescein-tagged 21-mer (F21). kcat for this reaction was 0.12 s-1. The fluorescence change associated with strand separation of F21:HF31 by excess enzyme and ATP was a biphasic process. The time course of the early phase (duplex unwinding) suggested only a few base pairs ( approximately 2) were disrupted concertedly. The maximal value of the rate constant (keff) describing the late phase of the reaction (strand separation) was 0. 5 s-1, which was 4-fold greater than kcat. Release of HF31 from E. HF31 in the presence of ATP (0.21 s-1) was the major contributor to kcat. At saturating ATP and competitor DNA concentrations, the enzyme unwound 44% of F21:HF31 that was initially bound to the enzyme (low processivity). These results are consistent with a passive mechanism for strand separation of F21:HF31 by HCV helicase.