Structural and Regulatory Elements of HCV NS5B Polymerase – β-Loop and C-Terminal Tail – Are Required for Activity of Allosteric Thumb Site II Inhibitors

Elucidation of the mechanism of action of the HCV NS5B polymerase thumb site II inhibitors has presented a challenge. Current opinion holds that these allosteric inhibitors stabilize the closed, inactive enzyme conformation, but how this inhibition is accomplished mechanistically is not well understood. Here, using a panel of NS5B proteins with mutations in key regulatory motifs of NS5B – the C-terminal tail and β-loop – in conjunction with a diverse set of NS5B allosteric inhibitors, we show that thumb site II inhibitors possess a distinct mechanism of action. A combination of enzyme activity studies and direct binding assays reveals that these inhibitors require both regulatory elements to maintain the polymerase inhibitory activity. Removal of either element has little impact on the binding affinity of thumb site II inhibitors, but significantly reduces their potency. NS5B in complex with a thumb site II inhibitor displays a characteristic melting profile that suggests stabilization not only of the thumb domain but also the whole polymerase. Successive truncations of the C-terminal tail and/or removal of the β-loop lead to progressive destabilization of the protein. Furthermore, the thermal unfolding transitions characteristic for thumb site II inhibitor – NS5B complex are absent in the inhibitor – bound constructs in which interactions between C-terminal tail and β-loop are abolished, pointing to the pivotal role of both regulatory elements in communication between domains. Taken together, a comprehensive picture of inhibition by compounds binding to thumb site II emerges: inhibitor binding provides stabilization of the entire polymerase in an inactive, closed conformation, propagated via coupled interactions between the C-terminal tail and β-loop.     

Non-nucleoside inhibitors binding to hepatitis C virus NS5B polymerase reveal a novel mechanism of inhibition

The RNA-dependent RNA polymerase (NS5B) from hepatitis C virus (HCV) is a key enzyme in HCV replication. NS5B is a major target for the development of antiviral compounds directed against HCV. Here we present the structures of three thiophene-based non-nucleoside inhibitors (NNIs) bound non-covalently to NS5B. Each of the inhibitors binds to NS5B non-competitively to a common binding site in the "thumb" domain that is approximately 35 Angstroms from the polymerase active site located in the "palm" domain. The three compounds exhibit IC(50) values in the range of 270 nM to 307 nM and have common binding features that result in relatively large conformational changes of residues that interact directly with the inhibitors as well as for other residues adjacent to the binding site. Detailed comparisons of the unbound NS5B structure with those having the bound inhibitors present show that residues Pro495 to Arg505 (the N terminus of the "T" helix) exhibit some of the largest changes. It has been reported that Pro495, Pro496, Val499 and Arg503 are part of the guanosine triphosphate (GTP) specific allosteric binding site located in close proximity to our binding site. It has also been reported that the introduction of mutations to key residues in this region (i.e. Val499Gly) ablate in vivo sub-genomic HCV RNA replication. The details of NS5B polymerase/inhibitor binding interactions coupled with the observed induced conformational changes provide new insights into the design of novel NNIs of HCV.     

Crystallographic identification of a noncompetitive inhibitor binding site on the hepatitis C virus NS5B RNA polymerase enzyme

The virus-encoded nonstructural protein 5B (NS5B) of hepatitis C virus (HCV) is an RNA-dependent RNA polymerase and is absolutely required for replication of the virus. NS5B exhibits significant differences from cellular polymerases and therefore has become an attractive target for anti-HCV therapy. Using a high-throughput screen, we discovered a novel NS5B inhibitor that binds to the enzyme noncompetitively with respect to nucleotide substrates. Here we report the crystal structure of NS5B complexed with this small molecule inhibitor. Unexpectedly, the inhibitor is bound within a narrow cleft on the protein's surface in the "thumb" domain, about 30 A from the enzyme's catalytic center. The interaction between this inhibitor and NS5B occurs without dramatic changes to the structure of the protein, and sequence analysis suggests that the binding site is conserved across known HCV genotypes. Possible mechanisms of inhibition include perturbation of protein dynamics, interference with RNA binding, and disruption of enzyme oligomerization.     

Binding site characterization and resistance to a class of non-nucleoside inhibitors of the hepatitis C virus NS5B polymerase

The virally encoded NS5B RNA-dependent RNA polymerase has emerged as a prime target in the search for specific HCV antivirals. A series of benzimidazole 5-carboxamide compounds inhibit the cellular RNA replication of a HCV subgenomic replicon and we have advanced our understanding of this class of inhibitors through a combination of complementary approaches that include biochemical cross-linking experiments with a photoreactive analogue followed by mass spectrometry analysis of the enzyme. A novel binding site has been localized for these inhibitors at the junction of the thumb domain and the N-terminal finger loop. Furthermore, the isolation and characterization of resistant replicon mutants that co-localize to this region distinguished this class of compounds from other non-nucleoside NS5B inhibitors that bind to distinct allosteric sites. Resistant mutations that emerged with the benzimidazole 5-carboxamide and related compounds were found at three amino acid positions in the thumb domain: Pro(495) with substitutions to Ser, Leu, Ala, or Thr; Pro(496) substitutions to Ser or Ala; and a V499A substitution. Mutations at each of these positions conferred different levels of resistance to this drug class: the Pro(495) changes provided the greatest shifts in compound potency, followed by moderate changes in potency with the Pro(496) substitutions, and finally only minor shifts in potency with V499A. Combinations that include the benzimidazole 5-carboxamide polymerase inhibitors and compounds that bind other sites or other HCV targets, including HCV protease inhibitors, are complementary in cell culture models of HCV RNA replication at suppressing the emergence of resistant variants. This novel class of compounds and unique binding site expand the diversity of HCV antivirals currently under development and offer the potential to improve the treatment of chronic HCV infection.     

Slow Binding Inhibition and Mechanism of Resistance of Non-nucleoside Polymerase Inhibitors of Hepatitis C Virus

The binding affinity of four palm and thumb site representative non-nucleoside inhibitors (NNIs) of HCV polymerase NS5B to wild-type and resistant NS5B polymerase proteins was determined, and the influence of RNA binding on NNI binding affinity was investigated. NNIs with high binding affinity potently inhibited HCV RNA polymerase activity and replicon replication. Among the compounds tested, HCV-796 showed slow binding kinetics to NS5B. The binding affinity of HCV-796 to NS5B increased 27-fold over a 3-h incubation period with an equilibrium K_d of 71 ± 2 nm. Slow binding kinetics of HCV-796 was driven by slow dissociation from NS5B with a k_off of 4.9 ± 0.5 × 10⁻⁴ s⁻¹. NS5B bound a long, 378-nucleotide HCV RNA oligonucleotide with high affinity (K_d = 6.9 ± 0.3 nm), whereas the binding affinity was significantly lower for a short, 21-nucleotide RNA (K_d = 155.1 ± 16.2 nm). The formation of the NS5B-HCV RNA complex did not affect the slow binding kinetics profile and only slightly reduced NS5B binding affinity of HCV-796. The magnitude of reduction of NNI binding affinity for the NS5B proteins with various resistance mutations in the palm and thumb binding sites correlated well with resistance -fold shifts in NS5B polymerase activity and replicon assays. Co-crystal structures of NS5B-Con1 and NS5B-BK with HCV-796 revealed a deep hydrophobic binding pocket at the palm region of NS5B. HCV-796 interaction with the induced binding pocket on NS5B is consistent with slow binding kinetics and loss of binding affinity with mutations at amino acid position 316.Hepatitis C virus (HCV)4 constitutes a global health problem. Current therapies are unable to effectively eliminate viral infection in a significant number of patients. The RNA-dependent RNA polymerase (RdRp) of HCV NS5B is an attractive target for the development of orally bioavailable small molecule inhibitors (1, 2). The structure of the NS5B apoenzyme and the NS5B-RNA complex reveals the characteristic right hand architecture of polymerase enzymes, comprising three distinct domains (palm, thumb, and finger) encircling the enzyme active site located in the palm domain (3–6). The structural and biochemical characterization of HCV NS5B polymerase can provide a basis for drug design efforts, and the elucidation of the mechanism of inhibition can guide the optimization of inhibitor efficiency against wild-type and resistant mutants.Among the extensively investigated non-nucleosides documented to inhibit the RdRp activity of HCV NS5B, derivatives of various benzofuran and benzothiadiazine have been reported to bind to allosteric binding sites in the palm domain of NS5B (7, 8). The palm domain, whose geometry is conserved in virtually all DNA and RNA polymerases, contains catalytic aspartic acids responsible for the nucleotidyl transfer reaction. The benzofuran compound HCV-796 has been shown to have significant antiviral effects in patients chronically infected with HCV (9, 10). In addition, two series of compounds based on the thiophene and benzimidazole scaffolds have been reported to inhibit NS5B by binding to two different binding pockets in the thumb domain of NS5B (11, 12). The thumb domain is connected to the palm domain by a β-hairpin termed the primer grip motif. The C-terminal region of the thumb protrudes toward the active site (3). The thumb binding inhibitors have been proposed to inhibit the RdRp activity of NS5B, perhaps by interfering with template/primer interaction and conformational dynamics of the protein (13, 14).Despite the elucidation of a number of NNIs that bind to the thumb and palm binding sites, the mechanism by which NNIs cause inhibition of RNA synthesis is unclear. Also, our understanding of the kinetics of NNI interaction with NS5B, the role of NNI binding and kinetics for inhibition, and the inhibitor efficacy on NS5B-resistant mutations remains incomplete. The four representative palm- and thumb-binding NNIs selected in this study have been reported to effectively inhibit replication of subgenomic replicons with low toxicity. Noncompetitive inhibition of NS5B polymerase activity with respect to NTPs has been reported (2, 15, 16). Based on co-crystallization studies with NS5B, it has been proposed that allosteric inhibitors may lock the NS5B protein in an inactive formation by binding tightly to the protein (16, 17). It is important to understand how the binding affinity relates to inhibition potency and resistance to HCV inhibition. Because the intrinsic potency of slowly binding compounds can be underestimated in the short time scale of biochemical studies, insights into slowly binding compounds may help to identify potent inhibitors. Moreover, the effect of the HCV RNA template on binding of NNIs to the enzyme-RNA complex remains to be addressed.Due to the error-prone nature of HCV polymerase in HCV replication, drug resistance can occur in patients who are treated with antiviral therapy directed at HCV-specific enzymes, and this resistance can limit their efficacy (16). Various in vitro studies using an HCV subgenomic replicon system have identified mutations that can confer resistance to inhibition by NNIs (2, 8, 16). Many of the mutations produce cross-resistance to the same family of inhibitors, which will affect the design of optimal combination therapies. Achieving optimal and sustained binding of these antiviral agents to the NS5B polymerase is crucial to ensure a high probability of clinical success.In this work, we have used biochemical and biophysical approaches to investigate binding affinities and binding kinetics of structurally diverse palm- and thumb-binding allosteric NS5B inhibitors. The binding of NNIs to wild-type and NNI-resistant NS5B proteins was studied and compared with inhibition and resistance. First, the NNI binding affinity for the NS5B protein was determined in the presence and absence of HCV RNA template, using a newly developed assay measuring the quenching of NS5B intrinsic fluorescence (FQ) in 96-well plates. The time-dependent NNI binding affinities and NNI binding equilibrium were used to identify slowly binding NNIs. Second, various palm and thumb site-specific mutant proteins were used to determine the mechanism of HCV resistance, and the binding affinities of NNIs were compared with the inhibition potencies determined in the HCV RdRp polymerase assay and HCV replicon assay. Finally, co-crystallization of HCV-796 with NS5B proteins from the Con1 and BK strains was performed to address the role of critical residues involved in HCV-796 resistance and NS5B polymorphism.     

Allosteric Inhibitors Have Distinct Effects,but Also Common Modes of Action,in the HCV Polymerase

The RNA-dependent RNA polymerase from the Hepatitis C Virus (gene product NS5B) is a validated drug target because of its critical role in genome replication. There are at least four distinct allosteric sites on the polymerase to which several small molecule inhibitors bind. In addition, numerous crystal structures have been solved with different allosteric inhibitors bound to the polymerase. However, the molecular mechanisms by which these small molecules inhibit the enzyme have not been fully elucidated. There is evidence that allosteric inhibitors alter the intrinsic motions and distribution of conformations sampled by the enzyme. In this study we use molecular dynamics simulations to understand the structural and dynamic changes that result when inhibitors are bound at three different allosteric binding sites on the enzyme. We observe that ligand binding at each site alters the structure and dynamics of NS5B in a distinct manner. Nonetheless, our studies also highlight commonalities in the mechanisms of action of the different inhibitors. Each inhibitor alters the conformational states sampled by the enzyme, either by rigidifying the enzyme and preventing transitions between functional conformational states or by destabilizing the enzyme and preventing functionally relevant conformations from being adequately sampled. By illuminating the molecular mechanisms of allosteric inhibition, these studies delineate the intrinsic functional properties of the enzyme and pave the way for designing novel and more effective polymerase inhibitors. This information may also be important to understand how allosteric regulation occurs in related viral polymerases and other enzymes.     

Pyridobenzothiazole derivatives as new chemotype targeting the HCV NS5B polymerase

Hepatitis C virus (HCV) infection has been recognized as the major cause of liver failure that can lead to hepatocellular carcinoma. Among all the HCV proteins, NS5B polymerase represents a leading target for drug discovery strategies. Herein, we describe our initial research efforts towards the identification of new chemotypes as allosteric NS5B inhibitors. In particular, the design, synthesis, in vitro anti-NS5B and in cellulo anti-HCV evaluation of a series of 1-oxo-1H-pyrido[2,1-b][1,3]benzothiazole-4-carboxylate derivatives are reported. Some of the newly synthesized compounds showed an IC(50) ranging from 11 to 23 μM, and molecular modeling and biochemical studies suggested that the thumb domain could be the target site for this new class of NS5B inhibitors.     

Selection and characterization of replicon variants dually resistant to thumb- and palm-binding nonnucleoside polymerase inhibitors of the hepatitis C virus

Multiple nonnucleoside inhibitor binding sites have been identified within the hepatitis C virus (HCV) polymerase, including in the palm and thumb domains. After a single treatment with a thumb site inhibitor (thiophene-2-carboxylic acid NNI-1), resistant HCV replicon variants emerged that contained mutations at residues Leu419, Met423, and Ile482 in the polymerase thumb domain. Binding studies using wild-type (WT) and mutant enzymes and structure-based modeling showed that the mechanism of resistance is through the reduced binding of the inhibitor to the mutant enzymes. Combined treatment with a thumb- and a palm-binding polymerase inhibitor had a dramatic impact on the number of replicon colonies able to replicate in the presence of both inhibitors. A more exact characterization through molecular cloning showed that 97.7% of replicons contained amino acid substitutions that conferred resistance to either of the inhibitors. Of those, 65% contained simultaneously multiple amino acid substitutions that conferred resistance to both inhibitors. Double-mutant replicons Met414Leu and Met423Thr were predominantly selected, which showed reduced replication capacity compared to the WT replicon. These findings demonstrate the selection of replicon variants dually resistant to two NS5B polymerase inhibitors binding to different sites of the enzyme. Additionally, these findings provide initial insights into the in vitro mutational threshold of the HCV NS5B polymerase and the potential impact of viral fitness on the selection of multiple-resistant mutants.     

Discovery and initial optimization of alkoxyanthranilic acid derivatives as inhibitors of HCV NS5B polymerase

Alkoxyanthranilic acid derivatives have been identified to inhibit HCV NS5B polymerase, binding in an allosteric site located at the convergence of the palm and thumb regions. Information from co-crystal structures guided the structural design strategy. Ultimately, two independent structural modifications led to a similar shift in binding mode that when combined led to a synergistic improvement in potency and the identification of inhibitors with sub-micromolar HCV NS5B binding potency.     

Mechanism of action and antiviral activity of benzimidazole-based allosteric inhibitors of the hepatitis C virus RNA-dependent RNA polymerase

The RNA-dependent RNA polymerase of hepatitis C virus (HCV) is the catalytic subunit of the viral RNA amplification machinery and is an appealing target for the development of new therapeutic agents against HCV infection. Nonnucleoside inhibitors based on a benzimidazole scaffold have been recently reported. Compounds of this class are efficient inhibitors of HCV RNA replication in cell culture, thus providing attractive candidates for further development. Here we report the detailed analysis of the mechanism of action of selected benzimidazole inhibitors. Kinetic data and binding experiments indicated that these compounds act as allosteric inhibitors that block the activity of the polymerase prior to the elongation step. Escape mutations that confer resistance to these compounds map to proline 495, a residue located on the surface of the polymerase thumb domain and away from the active site. Substitution of this residue is sufficient to make the HCV enzyme and replicons resistant to the inhibitors. Interestingly, proline 495 lies in a recently identified noncatalytic GTP-binding site, thus validating it as a potential allosteric site that can be targeted by small-molecule inhibitors of HCV polymerase.     

Selection of RNA aptamers that are specific and high-affinity ligands of the hepatitis C virus RNA-dependent RNA polymerase

In order to find small RNA molecules that are specific and high-affinity ligands of nonstructural 5B (NS5B) polymerase, we screened by SELEX (systematic evolution of ligands by exponential amplification) a structurally constrained RNA library with an NS5BDeltaC55 enzyme carrying a C-terminal biotinylation sequence. Among the selected clones, two aptamers appeared to be high-affinity ligands of NS5B, with apparent dissociation constants in the low nanomolar range. They share a sequence that can assume a stem-loop structure. By mutation analysis, this structure has been shown to correspond to the RNA motif responsible for the tight interaction with NS5B. The aptamers appeared to be highly specific for the hepatitis C virus (HCV) polymerase since interaction with the GB virus B (GBV-B) NS5B protein cannot be observed. This is consistent with the observation that the activity of the HCV NS5B polymerase is efficiently inhibited by the selected aptamers, while neither GBV-B nor poliovirus 3D polymerases are affected. The mechanism of inhibition of the NS5B activity turned out to be noncompetitive with respect to template RNA, suggesting that aptamers and template RNA do not bind to the same site. As a matter of fact, mutations introduced in a basic exposed surface of the thumb domain severely impaired both the binding of and activity inhibition by the RNA aptamers.     

Identification of halosalicylamide derivatives as a novel class of allosteric inhibitors of HCV NS5B polymerase

Halosalicylamide derivatives were identified from high-throughput screening as potent inhibitors of HCV NS5B polymerase. The subsequent structure and activity relationship revealed the absolute requirement of the salicylamide moiety for optimum activity. Methylation of either the hydroxyl group or the amide group of the salicylamide moiety abolished the activity while the substitutions on both phenyl rings are acceptable. The halosalicylamide derivatives were shown to be non-competitive with respect to elongation nucleotide and demonstrated broad genotype activity against genotype 1-3 HCV NS5B polymerases. Inhibitor competition studies indicated an additive binding mode to the initiation pocket that is occupied by the thiadiazine class of compounds and an additive binding mode to the elongation pocket that is occupied by diketoacids, but a mutually exclusive binding mode with respect to the allosteric thumb pocket that is occupied by the benzimidazole class of inhibitors. Therefore, halosalicylamides represent a novel class of allosteric inhibitors of HCV NS5B polymerase.     

Dynamics of Hepatitis C Virus (HCV) RNA-dependent RNA Polymerase NS5B in Complex with RNA

The hepatitis C virus (HCV) non-structural protein 5B (NS5B) is an RNA-dependent RNA polymerase that is essentially required for viral replication. Although previous studies revealed important properties of static NS5B-RNA complexes, the nature and relevance of dynamic interactions have yet to be elucidated. Here, we devised a single molecule Förster Resonance Energy Transfer (SM-FRET) assay to monitor temporal changes upon binding of NS5B to surface immobilized RNA templates. The data show enzyme association-dissociation events that occur within the time resolution of our setup as well as FRET-fluctuations in association with stable binary complexes that extend over prolonged periods of time. Fluctuations are shown to be dependent on the length of the RNA substrate, and enzyme concentration. Mutations in close proximity to the template entrance (K98E, K100E), and in the center of the RNA binding channel (R394E), reduce both the population of RNA-bound enzyme and the fluctuations associated to the binary complex. Similar observations are reported with an allosteric nonnucleoside NS5B inhibitor. Our assay enables for the first time the visualization of association-dissociation events of HCV-NS5B with RNA, and also the direct monitoring of the interaction between HCV NS5B, its RNA template, and finger loop inhibitors. We observe both a remarkably low dissociation rate for wild type HCV NS5B, and a highly dynamic enzyme-RNA binary complex. These results provide a plausible mechanism for formation of a productive binary NS5B-RNA complex, here NS5B slides along the RNA template facilitating positioning of its 3′ terminus at the enzyme active site.     

Crystal structures of the RNA-dependent RNA polymerase genotype 2a of hepatitis C virus reveal two conformations and suggest mechanisms of inhibition by non-nucleoside inhibitors

Crystal structures of the RNA-dependent RNA polymerase genotype 2a of hepatitis C virus (HCV) from two crystal forms have been determined. Similar to the three-dimensional structures of HCV polymerase genotype 1b and other known polymerases, the structures of the HCV polymerase genotype 2a in both crystal forms can be depicted in the classical right-hand arrangement with fingers, palm, and thumb domains. The main structural differences between the molecules in the two crystal forms lie at the interface of the fingers and thumb domains. The relative orientation of the thumb domain with respect to the fingers and palm domains and the beta-flap region is altered. Structural analysis reveals that the NS5B polymerase in crystal form I adopts a "closed" conformation that is believed to be the active form, whereas NS5B in crystal form II adopts an "open" conformation and is thus in the inactive form. In addition, we have determined the structures of two NS5B polymerase/non-nucleoside inhibitor complexes. Both inhibitors bind at a common binding site, which is nearly 35 A away from the polymerase active site and is located in the thumb domain. The binding pocket is predominantly hydrophobic in nature, and the enzyme inhibitor complexes are stabilized by hydrogen bonding and van der Waals interactions. Inhibitors can only be soaked in crystal form I and not in form II; examination of the enzyme-inhibitor complex reveals that the enzyme has undergone a dramatic conformational change from the form I (active) complex to the form II (inactive).     

Interdomain communication in hepatitis C virus polymerase abolished by small molecule inhibitors bound to a novel allosteric site

The hepatitis C virus (HCV) polymerase is required for replication of the viral genome and is a key target for therapeutic intervention against HCV. We have determined the crystal structures of the HCV polymerase complexed with two indole-based allosteric inhibitors at 2.3- and 2.4-Angstroms resolution. The structures show that these inhibitors bind to a site on the surface of the thumb domain. A cyclohexyl and phenyl ring substituents, bridged by an indole moiety, fill two closely spaced pockets, whereas a carboxylate substituent forms a salt bridge with an exposed arginine side chain. Interestingly, in the apoenzyme, the inhibitor binding site is occupied by a small alpha-helix at the tip of the N-terminal loop that connects the fingers and thumb domains. Thus, these molecules inhibit the enzyme by preventing formation of intramolecular contacts between these two domains and consequently precluding their coordinated movements during RNA synthesis. Our structures identify a novel mechanism by which a new class of allosteric inhibitors inhibits the HCV polymerase and open the way to the development of novel antiviral agents against this clinically relevant human pathogen.     

Identification and structure-based optimization of novel dihydropyrones as potent HCV RNA polymerase inhibitors

A novel class of non-nucleoside HCV NS5B polymerase inhibitors has been identified from screening. A co-crystal structure revealed an allosteric binding site in the protein that required a unique conformational change to accommodate inhibitor binding. Herein we report the structure-activity relationships (SARs) of this novel class of dihydropyrone-containing compounds that show potent inhibitory activities against the HCV RNA polymerase in biochemical assays.     

Mechanistic study of HCV polymerase inhibitors at individual steps of the polymerization reaction

Little is known about the mechanism of HCV polymerase-catalyzed nucleotide incorporation and the individual steps employed by this enzyme during a catalytic cycle. In this paper, we applied various biochemical tools and examined the mechanism of polymerase catalysis. We found that formation of a productive RNA-enzyme complex is the slowest step followed by RNA dissociation and initiation of primer strand synthesis. Various groups have reported several classes of small molecule inhibitors of hepatitis C virus NS5B polymerase; however, the mechanism of inhibition for many of these inhibitors is not clear. We undertook a series of detailed mechanistic studies to characterize the mechanisms of inhibition for these HCV polymerase inhibitors. We found that the diketoacid derivatives competitively bind to the elongation NTP pocket in the active site and inhibit both the initiation and elongation steps of polymerization. While both benzimidazoles and benzothiadiazines are noncompetitive with respect to the active site elongation NTP pocket, benzothiadiazine compounds competitively bind to the initiation pocket in the active site and inhibit only the initiation step of de novo RNA polymerization. The benzimidazoles bind to the thumb allosteric pocket and inhibit the conformational changes during RNA synthesis. We also observed a cross interaction between the thumb allosteric pocket and the initiation pocket using inhibitor-inhibitor cross competition studies. This information will be very important in designing combination therapies using two small molecule drugs to treat hepatitis C virus.     

Probing the “fingers” domain binding pocket of Hepatitis C virus NS5B RdRp and D559G resistance mutation via molecular docking,molecular dynamics simulation and binding free energy calculations

The NS5B RdRp polymerase is a prominent enzyme for the replication of Hepatitis C virus (HCV). During the HCV replication, the template RNA binding takes place in the “fingers” sub-domain of NS5B. The “fingers” domain is a new emerging allosteric site for the HCV drug development. The inhibitors of the “fingers” sub-domain adopt a new antiviral mechanism called RNA intervention. The details of essential amino acid residues, binding mode of the ligand, and the active site intermolecular interactions of RNA intervention reflect that this mechanism is ambiguous in the experimental study. To elucidate these details, we performed molecular docking analysis of the fingers domain inhibitor quercetagetin (QGN) with NS5B polymerase. The detailed analysis of QGN-NS5B intermolecular interactions was carried out and found that QGN interacts with the binding pocket amino acid residues Ala97, Ala140, Ile160, Phe162, Gly283, Gly557, and Asp559; and also forms π?π stacking interaction with Phe162 and hydrogen bonding interaction with Gly283. These are found to be the essential interactions for the RNA intervention mechanism. Among the strong hydrogen bonding interactions, the QGN?Ala140 is a newly identified important hydrogen bonding interaction by the present work and this interaction was not resolved by the previously reported crystal structure. Since D559G mutation at the fingers domain was reported for reducing the inhibition percentage of QGN to sevenfold, we carried out molecular dynamics (MD) simulation for wild and D559G mutated complexes to study the stability of protein conformation and intermolecular interactions. At the end of 50?ns MD simulation, the π?π stacking interaction of Phe162 with QGN found in the wild-type complex is altered into T-shaped π stacking interaction, which reduces the inhibition strength. The origin of the D559G resistance mutation was studied using combined MD simulation, binding free energy calculations and principal component analysis. The results were compared with the wild-type complex. The mutation D559G reduces the binding affinity of the QGN molecule to the fingers domain. The free energy decomposition analysis of each residue of wild-type and mutated complexes revealed that the loss of non-polar energy contribution is the origin of the resistance.

Communicated by Ramaswamy H. Sarma     

Identification of thieno[3,2-b]pyrroles as allosteric inhibitors of hepatitis C virus NS5B polymerase

Thieno[3,2-b]pyrroles are a novel class of allosteric inhibitors of HCV NS5B RNA-dependent RNA polymerase which show potent affinity for the NS5B enzyme. Introduction of a polar substituent in the position N1 led to a compound that efficiently blocks subgenomic HCV RNA replication in HUH-7 cells with an EC50 of 2.9 microM.     

Identification and characterization of coumestans as novel HCV NS5B polymerase inhibitors

The hepatitis C virus (HCV) NS5B is essential for viral RNA replication and is therefore a prime target for development of HCV replication inhibitors. Here, we report the identification of a new class of HCV NS5B inhibitors belonging to the coumestan family of phytoestrogens. Based on the in vitro NS5B RNA-dependent RNA polymerase (RdRp) inhibition in the low micromolar range by wedelolactone, a naturally occurring coumestan, we evaluated the anti-NS5B activity of four synthetic coumestan analogues bearing different patterns of substitutions in their A and D rings, and observed a good structure-activity correlation. Kinetic characterization of coumestans revealed a noncompetitive mode of inhibition with respect to nucleoside triphosphate (rNTP) substrate and a mixed mode of inhibition towards the nucleic acid template, with a major competitive component. The modified order of addition experiments with coumestans and nucleic acid substrates affected the potencies of the coumestan inhibitors. Coumestan interference at the step of NS5B-RNA binary complex formation was confirmed by cross-linking experiments. Molecular docking of coumestans within the allosteric site of NS5B yielded significant correlation between their calculated binding energies and IC(50) values. Coumestans thus add to the diversifying pool of anti-NS5B agents and provide a novel scaffold for structural refinement and development of potent NS5B inhibitors.