Template requirements for RNA synthesis by a recombinant hepatitis C virus RNA-dependent RNA polymerase

The RNA-dependent RNA polymerase (RdRp) from hepatitis C virus (HCV), nonstructural protein 5B (NS5B), has recently been shown to direct de novo initiation using a number of complex RNA templates. In this study, we analyzed the features in simple RNA templates that are required to direct de novo initiation of RNA synthesis by HCV NS5B. NS5B was found to protect RNA fragments of 8 to 10 nucleotides (nt) from RNase digestion. However, NS5B could not direct RNA synthesis unless the template contained a stable secondary structure and a single-stranded sequence that contained at least one 3' cytidylate. The structure of a 25-nt template, named SLD3, was determined by nuclear magnetic resonance spectroscopy to contain an 8-bp stem and a 6-nt single-stranded sequence. Systematic analysis of changes in SLD3 revealed which features in the stem, loop, and 3' single-stranded sequence were required for efficient RNA synthesis. Also, chimeric molecules composed of DNA and RNA demonstrated that a DNA molecule containing a 3'-terminal ribocytidylate was able to direct RNA synthesis as efficiently as a sequence composed entirely of RNA. These results define the template sequence and structure sufficient to direct the de novo initiation of RNA synthesis by HCV RdRp.     

Multiple interactions within the hepatitis C virus RNA polymerase repress primer-dependent RNA synthesis

The hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp) initiates RNA synthesis in vivo by a de novo mechanism. In vitro, however, the HCV RdRp can initiate de novo or extend from a primed template. A novel beta-loop near the RdRp active site was previously found to prevent the use of primed templates. We found that, in addition to the beta-loop, the C-terminal tail of the HCV RdRp and the de novo initiation GTP are required to exclude the use of primed-templates. GTP binding to the NTPi site of the HCV RdRp orchestrates the participation of other structures. The interactions of the beta-loop, C-terminal tail, and GTP provide an elegant solution to ensure de novo initiation of HCV RNA synthesis.     

Oligomerization and cooperative RNA synthesis activity of hepatitis C virus RNA-dependent RNA polymerase

The NS5B RNA-dependent RNA polymerase encoded by hepatitis C virus (HCV) plays a key role in viral replication. Reported here is evidence that HCV NS5B polymerase acts as a functional oligomer. Oligomerization of HCV NS5B protein was demonstrated by gel filtration, chemical cross-linking, temperature sensitivity, and yeast cell two-hybrid analysis. Mutagenesis studies showed that the C-terminal hydrophobic region of the protein was not essential for its oligomerization. Importantly, HCV NS5B polymerase exhibited cooperative RNA synthesis activity with a dissociation constant, K(d), of approximately 22 nM, suggesting a role for the polymerase-polymerase interaction in the regulation of HCV replicase activity. Further functional evidence includes the inhibition of the wild-type NS5B polymerase activity by a catalytically inactive form of NS5B. Finally, the X-ray crystal structure of HCV NS5B polymerase was solved at 2.9 A. Two extensive interfaces have been identified from the packing of the NS5B molecules in the crystal lattice, suggesting a higher-order structure that is consistent with the biochemical data.     

Functional analysis of RNA binding by the hepatitis C virus RNA-dependent RNA polymerase

Protein-RNA interaction plays a critical role in regulating RNA synthesis by the hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp). RNAs of 7 nucleotides (nt) or longer had affinities 5-fold better than an RNA of 5 nt, suggesting a minimal length required for binding. To identify RNA contact sites on the HCV RdRp, a biotinylated 7-nt RNA capable of directing de novo initiation was used in a process that coupled reversible formaldehyde cross-linking, RNA affinity chromatography, and mass spectrometry. By this process, we identified 18 peptides cross-linked to the 7-nt RNA. When these identified peptides were overlaid on the three-dimensional structures of NS5B, most mapped to the fingers subdomain, connecting loops between fingers and thumb subdomains and in the putative RNA binding channel. Two of the identified peptides resided in the active site cavity of the RdRp. Recombinant HCV RdRp with single residue changes in likely RNA contact sites were generated and characterized for effects on HCV RdRp activity. Mutant proteins had significant effects on cross-linking to 7-nt RNA and reduced RNA synthesis in vitro by 2- to 20-fold compared with wild type protein. When the mutations were tested for the replication of HCV RNA in the context of the cells transfected with the HCV subgenomic replicon, all except one prevented colony formation, indicating a defect in HCV RNA replication. These biochemical and functional analyses identified a number of residues in the HCV RdRp that are important for HCV RNA synthesis.     

A locking mechanism regulates RNA synthesis and host protein interaction by the hepatitis C virus polymerase

Mutational analysis of the hepatitis C virus (HCV) RNA-dependent RNA polymerase (RdRp) template channel identified two residues, Trp(397) and His(428), which are required for de novo initiation but not for extension from a primer. These two residues interact with the Delta1 loop on the surface of the RdRp. A deletion within the Delta1 loop also resulted in comparable activities. The mutant proteins exhibit increased double-stranded RNA binding compared with the wild type, suggesting that the Delta1 loop serves as a flexible locking mechanism to regulate the conformations needed for de novo initiation and for elongative RNA synthesis. A similar locking motif can be found in other viral RdRps. Products associated with the open conformation of the HCV RdRp were inhibited by interaction with the retinoblastoma protein but not cyclophilin A. Different conformations of the HCV RdRp can thus affect RNA synthesis and interaction with cellular proteins.     

De novo initiation of RNA synthesis by the RNA-dependent RNA polymerase (NS5B) of hepatitis C virus

Hepatitis C virus (HCV) NS5B protein possesses an RNA-dependent RNA polymerase (RdRp) activity, a major function responsible for replication of the viral RNA genome. To further characterize the RdRp activity, NS5B proteins were expressed from recombinant baculoviruses, purified to near homogeneity, and examined for their ability to synthesize RNA in vitro. As a result, a highly active NS5B RdRp (1b-42), which contains an 18-amino acid C-terminal truncation resulting from a newly created stop codon, was identified among a number of independent isolates. The RdRp activity of the truncated NS5B is comparable to the activity of the full-length protein and is 20 times higher in the presence of Mn(2+) than in the presence of Mg(2+). When a 384-nucleotide RNA was used as the template, two major RNA products were synthesized by 1b-42. One is a complementary RNA identical in size to the input RNA template (monomer), while the other is a hairpin dimer RNA synthesized by a "copy-back" mechanism. Substantial evidence derived from several experiments demonstrated that the RNA monomer was synthesized through de novo initiation by NS5B rather than by a terminal transferase activity. Synthesis of the RNA monomer requires all four ribonucleotides. The RNA monomer product was verified to be the result of de novo RNA synthesis, as two expected RNA products were generated from monomer RNA by RNase H digestion. In addition, modification of the RNA template by the addition of the chain terminator cordycepin at the 3' end did not affect synthesis of the RNA monomer but eliminated synthesis of the self-priming hairpin dimer RNA. Moreover, synthesis of RNA on poly(C) and poly(U) homopolymer templates by 1b-42 NS5B did not require the oligonucleotide primer at high concentrations (>/=50 microM) of GTP and ATP, further supporting a de novo initiation mechanism. These findings suggest that HCV NS5B is able to initiate RNA synthesis de novo.     

RNA template-mediated inhibition of hepatitis C virus RNA-dependent RNA polymerase activity

The enzymatic activity of hepatitis C virus (HCV) RNA-dependent RNA polymerase NS5B is modulated by the molar ratio of NS5B enzyme and RNA template. Depending on the ratio, either template or enzyme can inhibit activity. Inhibition of NS5B activity by RNA template exhibited characteristics of substrate inhibition, suggesting the template binds to a secondary site on the enzyme forming an inactive complex. Template inhibition was modulated by primer. Increasing concentrations of primer restored NS5B activity and decreased the affinity of template for the secondary site. Conversely, increasing template concentration reduced the affinity of primer binding. The kinetic profiles suggest template inhibition results from the binding of template to a site that interferes with primer binding and the formation of productive replication complexes.     

Mechanism of de novo initiation by the hepatitis C virus RNA-dependent RNA polymerase: role of divalent metals

We functionally analyzed the role of metal ions in RNA-dependent RNA synthesis by three recombinant RNA-dependent RNA polymerases (RdRps) from GB virus-B (GBV), bovine viral diarrhea virus (BVDV), and hepatitis C virus (HCV), with emphasis on the HCV RdRp. Using templates capable of both de novo initiation and primer extension and RdRps purified in the absence of metal, we found that only reactions with exogenously provided Mg(2+) and Mn(2+) gave rise to significant amounts of synthesis. Mg(2+) and Mn(2+) affected the mode of RNA synthesis by the three RdRps. Both metals supported primer-dependent and de novo-initiated RNA by the GBV RdRp, while Mn(2+) significantly increased the amount of de novo-initiated products by the HCV and BVDV RdRps. For the HCV RdRp, Mn(2+) reduced the K(m) for the initiation nucleotide, a GTP, from 103 to 3 micro M. However, it increased de novo initiation even at GTP concentrations that are comparable to physiological levels. We hypothesize that a change in RdRp structure occurs upon GTP binding to prevent primer extension. Analysis of deleted proteins revealed that the C terminus of the HCV RdRp plays a role in Mn(2+)-induced de novo initiation and can contribute to the suppression of primer extension. Spectroscopy examining the intrinsic fluorescence of tyrosine and tryptophan residues in the HCV RdRp produced results consistent with the protein undergoing a conformational change in the presence of metal. These results document the fact that metal can affect de novo initiation or primer extension by flaviviral RdRps.     

Assays for RNA synthesis and replication by the hepatitis C virus

At least six major genotypes of Hepatitis C virus (HCV) cause liver diseases worldwide.The efficacy rates with current standard of care are about 50％ against genotype 1,the most prevalent strain in the...     

Cyclophilin B is a functional regulator of hepatitis C virus RNA polymerase

Viruses depend on host-derived factors for their efficient genome replication. Here, we demonstrate that a cellular peptidyl-prolyl cis-trans isomerase (PPIase), cyclophilin B (CyPB), is critical for the efficient replication of the hepatitis C virus (HCV) genome. CyPB interacted with the HCV RNA polymerase NS5B to directly stimulate its RNA binding activity. Both the RNA interference (RNAi)-mediated reduction of endogenous CyPB expression and the induced loss of NS5B binding to CyPB decreased the levels of HCV replication. Thus, CyPB functions as a stimulatory regulator of NS5B in HCV replication machinery. This regulation mechanism for viral replication identifies CyPB as a target for antiviral therapeutic strategies.     

Template requirements for de novo RNA synthesis by hepatitis C virus nonstructural protein 5B polymerase on the viral X RNA

The hepatitis C virus (HCV)-encoded NS5B protein is an RNA-dependent RNA polymerase which plays a substantial role in viral replication. We expressed and purified the recombinant NS5B of an HCV genotype 3a from Esherichia coli, and we investigated its ability to bind to the viral RNA and its enzymatic activity. The results presented here demonstrate that NS5B interacts strongly with the coding region of positive-strand RNA, although not in a sequence-specific manner. It was also determined that more than two molecules of polymerase bound sequentially to this region with the direction 3' to 5'. Also, we attempted to determine the initiation site(s) of de novo synthesis by NS5B on X RNA, which contains the last 98 nucleotides of HCV positive-strand RNA. The initiation site(s) on X RNA was localized in the pyrimidine-rich region of stem I. However, when more than five of the nucleotides of stem I in X RNA were deleted from the 3' end, RNA synthesis initiated at another site of the specific ribonucleotide. Our study also showed that the efficiency of RNA synthesis, which was directed by X RNA, was maximized by the GC base pair at the penultimate position from the 3' end of the stem. These results will provide some clues to understanding the mechanism of HCV genomic RNA replication in terms of viral RNA-NS5B interaction and the initiation of de novo RNA synthesis.     

The essential role of C-terminal residues in regulating the activity of hepatitis C virus RNA-dependent RNA polymerase

We have previously determined the crystal structure of a non-structural 5B (NS5B) protein, an RNA-dependent RNA polymerase (RdRp) of hepatitis C virus (HCV). NS5B protein with the hydrophobic C-terminal 21 amino acid residues truncated, designated NS5B(570), shows a typical nucleotide polymerase structure resembling a right-hand shape. In the crystal structure, a C-terminal region between Leu545 and His562 occupies a putative RNA-binding cleft of this polymerase and seems to inhibit the polymerase activity. Varieties of recombinant NS5B proteins (NS5B(552), NS5B(544), NS5B(536) or NS5B(531), with C-terminal 39, 47, 55 or 60 amino acid residues truncated, respectively) were systematically constructed to elucidate effects of the region on the polymerase activity. NS5B(544), NS5B(536) and NS5B(531) showed markedly higher RdRp activities compared to the activities of NS5B(570) or NS5B(552). Furthermore, when the hydrophobic amino acid residues Leu547, Trp550 and Phe551 (LWF) in NS5B(570) and NS5B(552) were changed to alanine, their activities were higher than that of the original NS5B(570). The crystal structures of the various recombinant NS5B proteins were also determined. Structural comparison of the NS5B proteins indicates that the activation was caused by elimination of a unique hydrophobic interaction between the three C-terminal residues and a shallowly concave pocket consisting of thumb and palm domains.     

Structure of hepatitis C virus polymerase in complex with primer-template RNA

The replication of the hepatitis C viral (HCV) genome is accomplished by the NS5B RNA-dependent RNA polymerase (RdRp), for which mechanistic understanding and structure-guided drug design efforts have been hampered by its propensity to crystallize in a closed, polymerization-incompetent state. The removal of an autoinhibitory β-hairpin loop from genotype 2a HCV NS5B increases de novo RNA synthesis by >100-fold, promotes RNA binding, and facilitated the determination of the first crystallographic structures of HCV polymerase in complex with RNA primer-template pairs. These crystal structures demonstrate the structural realignment required for primer-template recognition and elongation, provide new insights into HCV RNA synthesis at the molecular level, and may prove useful in the structure-based design of novel antiviral compounds. Additionally, our approach for obtaining the RNA primer-template-bound structure of HCV polymerase may be generally applicable to solving RNA-bound complexes for other viral RdRps that contain similar regulatory β-hairpin loops, including bovine viral diarrhea virus, dengue virus, and West Nile virus.     

Elongation of synthetic RNA templates by hepatitis C virus NS5B polymerase

Here we examine the ability of seven, 3'-related, short synthetic RNAs to serve as templates for the hepatitis C virus (HCV) polymerase, non-structural protein 5B (NS5B). These RNAs, termed HL, range from 8 to 16 nucleotides in length, each with ACC at the 3' terminus. Interestingly HL12 and longer templates have a predicted secondary structure. Those with one or two unpaired adenylates at the 5'-end of a stem were increased in size by one or two nucleotides, respectively, following incubation with NS5B and UTP. Using labeled template RNA and cold UTP, extension in size could be inhibited by addition of non-labeled template of the same size. This template elongation was not inhibited by cold linear HL10 template unless pGpG was added. Fluorescence anisotropy demonstrated HL14, a template with secondary structure, bound with an apparent K(d) of 22 nm. A linear template, HL10, plus pGpG primer was bound by NS5B with a K(d) of 45 nm, whereas HL10 alone bound with an apparent K(d) of 182 nm. The amplitude of the template extension product was increased by a brief preincubation at 4 degrees C followed by incubation at 23 or 30 degrees C. The nucleotide-mediated increase in size occurred for both templates that required a mismatch or bulge at the 3'-end as well as for those without the mismatch. These results suggest an NS5B active site pocket can readily accommodate short templates with four or five base stems and initiate copy-back replication in the presence of a one nucleotide mismatch.