Abstract
NS5B is the RNA-dependent RNA polymerase responsible for replicating hepatitis C virus (HCV) genomic RNA. Despite more than a decade of work, the formation of a highly active NS5B polymerase·RNA complex suitable for mechanistic and structural studies has remained elusive. Here, we report that through a novel way of optimizing initiation conditions, we were able to generate a productive NS5B·primer·template elongation complex stalled after formation of a 9-nucleotide primer. In contrast to previous reports of very low proportions of active NS5B, we observed that under optimized conditions up to 65% of NS5B could be converted into active elongation complexes. The elongation complex was extremely stable, allowing purification away from excess nucleotide and abortive initiation products so that the purified complex was suitable for pre-steady-state kinetic analyses of polymerase activity. Single turnover kinetic studies showed that CTP is incorporated with apparent K(d) and k(pol) values of 39 ± 3 μM and 16 ± 1 s(-1), respectively, giving a specificity constant of k(pol)/K(d) of 0.41 μM(-1) s(-1). The kinetics of multiple nucleotide incorporation during processive elongation also were determined. This work establishes a novel way to generate a highly active elongation complex of the medically important NS5B polymerase for structural and functional studies.
Highlights
Previous studies have failed to reconstitute an active replication complex with hepatitis C virus (HCV) RNA-dependent RNA polymerase
These data strongly suggested that the NS5B1⁄79-mer1⁄720-mer elongation complex precipitated during the extension and pause reaction under low salt conditions and was recovered in the pellet after centrifugation, whereas abortive reaction products such as GGA remained soluble in the supernatant
An NS5B1⁄7primer1⁄7template ternary complex is necessary for kinetic and structural analysis of the nucleotide incorporation reaction catalyzed by HCV NS5B during elongation
Summary
Previous studies have failed to reconstitute an active replication complex with hepatitis C virus (HCV) RNA-dependent RNA polymerase. To study the kinetics of nucleotide incorporation using pre-steady state kinetic methods, it is first necessary to obtain a stoichiometric polymerase1⁄7primer1⁄7 template ternary complex Unlike other polymerases, such a ternary complex cannot be formed productively with HCV NS5B [8, 13, 14]. The purified elongation complex was highly active and exceptionally stable, even under high salt conditions or in the presence of heparin, suggesting a major conformational change, leading to very slow RNA dissociation from NS5B in the elongation conformation Using this purified elongation complex, we examined the kinetics of single and multiple nucleotide incorporation catalyzed by NS5B using pre-steady-state kinetic methods. This elongation complex can be used to study the mechanisms of replication, drug inhibition, and drug resistance of HCV involving NS5B
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