Biochemical and structural analysis of the NS5B RNA-dependent RNA polymerase of the hepatitis C virus.

Hepatitis C virus (HCV), the major causative agent of chronic and sporadic non-A, non-B hepatitis worldwide, is a distinct member of the Flaviviridae virus family. These viruses have in common a plus-strand RNA genome that is replicated in the cytoplasm of the infected cell via minus-strand RNA intermediates. Owing to the lack of reliable cell culture systems and convenient animal models for HCV, the mechanisms governing RNA replication are not known. As a first step towards the development of appropriate in vitro systems, we expressed the NS5B RNA-dependent RNA polymerase (RdRp) in insect cells, purified the protein to near homogeneity and studied its biochemical properties. It is a primer- and RNA template-dependent RNA polymerase able to copy long heteropolymeric templates without additional viral or cellular cofactors. We determined the optimal reaction parameters, the kinetic constants and the substrate specificity of the enzyme, which turned out to be similar to those described for the 3D polymerase of poliovirus. By analysing a series of nucleosidic and non-nucleosidic compounds for their effect on RdRp activity, we found that ribavirin triphosphates have no inhibitory effect, providing direct experimental proof that the therapeutic effect observed in patients is not related to a direct inhibition of the viral polymerase. Finally, mutation analysis was performed to map the minimal NS5B sequence required for enzymatic activity and to identify the 'classical' polymerase motifs important for template and NTP binding and catalysis.

Modulation of hepatitis C virus NS5A hyperphosphorylation by nonstructural proteins NS3, NS4A, and NS4B.

NS5A of the hepatitis C virus (HCV) is a highly phosphorylated protein involved in resistance against interferon and required most likely for replication of the viral genome. Phosphorylation of this protein is mediated by a cellular kinase(s) generating multiple proteins with different electrophoretic mobilities. In the case of the genotype 1b isolate HCV-J, in addition to the basal phosphorylated NS5A (designated pp56), a hyperphosphorylated form (pp58) was found on coexpression of NS4A (T. Kaneko, Y. Tanji, S. Satoh, M. Hijikata, S. Asabe, K. Kimura, and K. Shimotohno, Biochem. Biophys. Res. Commun. 205:320-326, 1994). Using a comparative analysis of two full-length genomes of genotype 1b, competent or defective for NS5A hyperphosphorylation, we investigated the requirements for this NS5A modification. We found that hyperphosphorylation occurs when NS5A is expressed as part of a continuous NS3-5A polyprotein but not when it is expressed on its own or trans complemented with one or several other viral proteins. Results obtained with chimeras of both genomes show that single amino acid substitutions within NS3 that do not affect polyprotein cleavage can enhance or reduce NS5A hyperphosphorylation. Furthermore, mutations in the central or carboxy-terminal NS4A domain as well as small deletions in NS4B can also reduce or block hyperphosphorylation without affecting polyprotein processing. These requirements most likely reflect the formation of a highly ordered NS3-5A multisubunit complex responsible for the differential phosphorylation of NS5A and probably also for modulation of its biological activities.

Biochemical and kinetic analyses of NS5B RNA-dependent RNA polymerase of the hepatitis C virus.

The biochemical properties of the RNA-dependent RNA polymerase (RdRp) of the hepatitis C virus were analyzed. A hexahistidine affinity-tagged NS5B fusion protein was expressed with recombinant baculoviruses in insect cells and purified to near homogeneity. Enzymatic activity of the purified protein was inhibited by KCl or high concentrations of NaCl and was absolutely dependent on Mg2+, which could be replaced by Mn2+. NS5B was found to be processive and able to copy long heteropolymeric templates with an elongation rate of 150-200 nucleotides/min at 22 degreesC. Kinetic constants were determined for all four nucleoside triphosphates and different templates. In case of a heteropolymeric RNA template corresponding to the last 319 nucleotides of the hepatitis C virus genome, Km values for UTP, GTP, ATP, and CTP were approximately 1.0, approximately 0.5, approximately 10, and approximately 0.3 microM, respectively. The profile of several inhibitors of RdRp activity and substrate analogs indicated that the enzyme has a strong preference for ribonucleoside 5'-triphosphates and that it closely resembles 3Dpol of picornaviruses.

Determinants of substrate specificity in the NS3 serine proteinase of the hepatitis C virus.

Processing of the nonstructural polyprotein of the hepatitis C virus (HCV) requires the serine-type proteinase located in the amino-terminal domain of NS3. To identify residues within NS3 determining substrate specificity, a mutation analysis was performed. Using sequence alignments and three-dimensional structure predictions, amino acids assumed to be important for specificity were replaced and the enzymes were tested in an intracellular trans-processing assay for their effects on cleavage of an NS4B-5B substrate. For some of the substitutions at positions 133, 134, 135, 136, 138, 152, 155, 157, and 169, slightly reduced processing efficiencies were observed but in no case was the substrate specificity altered. In contrast, substitutions of the phenylalanine at position 154 resulted in a modified cleavage pattern, suggesting an important role for this residue in substrate specificity. To substantiate this assumption, a panel of NS4B-5B substrates carrying different P1 residues at the NS4B/5A site were tested for cleavage by these altered proteinases. We found that substitution of Phe-154 by alanine, by valine, and particularly by threonine generated enzymes with the following affinities for aliphatic P1 residues: C > L > I > V for 154 F --> A, C = L > I > V for 154 F --> V and L > C > I > V for 154 F --> T. Neither leucine nor isoleucine nor valine was accepted by the parental NS3 proteinase, showing that Phe-154 is an important determinant for substrate specificity. Furthermore, we present evidence that Ala-157 plays an additional but minor role for this property.

In vitro studies on the activation of the hepatitis C virus NS3 proteinase by the NS4A cofactor.

Proteolytic processing of the nonstructural proteins of the hepatitis C virus (HCV) is mediated by two viral proteinases: the NS2-3 proteinase cleaving at the NS2/3 junction and the NS3 serine-type proteinase responsible for processing at the NS3/4A, NS4A/B, NS4B/5A, and NS5A/B sites. Activity of the NS3 proteinase is modulated by NS4A. In the absence of this cofactor processing at the NS3-dependent sites does not occur or, in the case of the NS5A/B junction, is poor but increased when NS4A is present. Although recent studies demonstrated that proteinase activation requires direct interaction between NS3 and NS4A, the mechanism by which NS4A exerts the activation function is not known. To further analyze the conditions of proteinase activation and to characterize the NS3 sequences important for complex formation and activation we used an in vitro assay in which radiolabeled HCV substrates were mixed with NS3 proteinase and synthetic NS4A peptides. We found that microsomal membranes are not required for proteinase activation. However, they are important for efficient accessibility of the NS4A/B site but not the other trans-cleavage sites. Studies with NS3 deletion mutants identified a region between amino acids 15 and 22 which is essential for proteinase activation. Results obtained with several mutations introduced into this sequence show that a weak overall association between NS3 and NS4A is sufficient for proteinase activation and suggest that a beta-sheet at the NS3 amino terminus plays an important role. Although not essential for proteinase activation the amino terminal 14 NS3 residues were found to have an auxiliary function probably by stabilizing the NS3/4A interaction. Finally, we could demonstrate intracellular, peptide-mediated modulation of proteinase activity providing the basis for the development of a novel therapeutic concept.

Processing pathways of the hepatitis C virus proteins.

Hepatitis C virus (HCV) is the major etiological agent of posttransfusion and community-acquired non-A, non-B hepatitis. It is an enveloped virus, grouped as a separate genus in the Flaviviridae family. The plus-stranded RNA genome encodes a polyprotein of about 3000 amino acids with the structural proteins core, E1 and E2 residing in the amino terminal quarter of the polyprotein and the nonstructural proteins NS2, NS3, NS4A, NS4B, NS5A and NS5B in the remainder. Maturation of the structural proteins is mediated by host cell signalases located in the lumen of the endoplasmic reticulum and cleaving behind stretches of hydrophobic amino acids. At least two virally encoded proteinases are responsible for processing of the NS proteins: a zinc-dependent metallo-proteinase encompassing the NS2 domain and the amino terminal portion of NS3, which is essential for cleavage at the NS2/3 junction; a serine-type proteinase located in the amino terminal domain of NS3 is required for cleavage at all sites downstream of the NS3 carboxy terminus. However, although the NS3 domain contains proteolytic activity, with the exception of the NS5A/5B junction cleavage only occurs in the presence of NS4A. This 54 amino acid long peptide can modulate the proteolytic activity of the enzyme in cis and in trans, probably by the formation of a stable NS3/NS4A complex. Modulation of the proteinase activity may be a way to regulate the expression and replication of the HCV genome.

Complex formation between the NS3 serine-type proteinase of the hepatitis C virus and NS4A and its importance for polyprotein maturation.

Processing of the hepatitis C virus polyprotein is mediated by host cell signalases and at least two virally encoded proteinases. Of these, the serine-type proteinase encompassing the amino-terminal one-third of NS3 is responsible for cleavage at the four sites carboxy terminal of NS3. The activity of this proteinase is modulated by NS4A, a 54-amino-acid polyprotein cleavage product essential for processing at the NS3/4A, NS4A/4B, and NS4B/5A sites and enhancing cleavage efficiency between NS5A and NS5B. Using the vaccinia virus-T7 hybrid system to express hepatitis C virus polypeptides in BHK-21 cells, we studied the role of NS4A in proteinase activation. We found that the NS3 proteinase and NS4A form a stable complex when expressed as a single polyprotein or as separate molecules. Results from deletion mapping show that the minimal NS4A domain required for proteinase activation is located in the center of NS4A between amino acids 1675 and 1686 of the polyprotein. Amino acid substitutions within this domain destabilizing the NS3-NS4A complex also impair trans cleavage at the NS4A-dependent sites. Similarly, deletion of amino-terminal NS3 sequences impairs complex formation as well as cleavage at the NS4B/5A site but not at the NS4A-independent NS5A/5B site. These results suggest that a stable NS3-NS4A interaction is important for cleavage at the NS4A-dependent sites and that amino-terminal NS3 sequences and the central NS4A domain are directly involved in complex formation.