ATP-binding domain of NTPase/helicase as a target for hepatitis C antiviral therapy

To enhance the inhibitory potential of 1-beta-D-ribofuranosyl-1,2,4-triazole-3-carboxamide (ribavirin) vs hepatitis C virus (HCV) NTPase/helicase, ribavirin-5'-triphosphate (ribavirin-TP) was synthesized and investigated. Ribavirin-TP was prepared with the use of modified Yoshikawa-Ludwig-Mishra-Broom procedure (cf. Mishra & Broom, 1991, J. Chem. Soc., Chem. Commun, 1276-1277) involving phosphorylation of unprotected nucleoside. Kinetic analysis revealed enhanced inhibitory potential of ribavirin-TP (IC50=40 microM) as compared to ribavirin (IC50 > 500 microM). Analysis of the inhibition type by means of graphical methods showed a competitive type of inhibition with respect to ATP. In view of the relatively low specificity towards nucleoside-5'-triphosphates (NTP) of the viral NTPase/helicases, it could not be ruled out that the investigated enzyme hydrolyzed the ribavirin-TP to less potent products. Investigations on non- hydrolysable analogs of ribavirin-TP or ribavirin-5'-diphosphate (ribavirin-DP) are currently under way.     

5'-O-fluorosulfonylbenzoyl esters of purine nucleosides as potential inhibitors of NTPase/helicase and polymerase of Flaviviridae viruses

Synthesis and interactions of guanosine, inosine and ribavirin 5'-fluorosulfonylbenzoyl esters with hepatitis C virus (HCV) and Flaviviruses NTPase/helicase and polymerase are described.     

The NTPase/helicase domain of hepatitis C virus nonstructural protein 3 inhibits protein kinase C independently of its NTPase activity

Helicase motif VI is a short arginine-rich motif within the NTPase/helicase domain of the non-structural protein 3 (NS3) of the hepatitis C virus (HCV). We previously demonstrated that it reduces the catalytic activity and intracellular shuttling of protein kinase C (PKC). Thus, NS3-mediated PKC inhibition may be involved in HCV-associated hepatocellular carcinoma (HCC). In this study, we expand on our earlier results, which were obtained in experiments with short fragments of NS3, to show for the first time that the catalytically active, longer C-terminal NTPase/helicase of NS3 acts as a potent PKC inhibitor in vitro. PKC inhibition assays with the NTPase-inactive mutant NS3h-D1316A revealed a mixed type kinetic inhibition pattern. A broad range of 11 PKC isotypes was tested and all of the PKC isotypes were inhibited with IC50-values in the low micromolar range. These findings were confirmed for the wild-type NTPase/helicase domain in a non-radiometric PKC inhibition assay with ATP regeneration to rule out any effect of ATP hydrolysis caused by its NTPase activity. PKCα was inhibited with a micromolar IC₅₀ in this assay, which compares well with our result for NS3h-D1316A (IC₅₀ = 0.7 μM). In summary, these results confirm that catalytically active NS3 NTPase/helicase can act in an analogous manner to shorter NS3 fragments as a pseudosubstrate inhibitor of PKC.     

Hepatitis C virus helicase/NTPase: an efficient expression system and new inhibitors

A method has been developed for obtaining a full-length protein NS3 of hepatitis C virus with the yield of 6.5 mg/liter of cell culture, and conditions for measuring its NTPase and helicase activities have been optimized. The helicase reaction can proceed in two modes depending on the enzyme and substrate concentration ratio: it can be non-catalytic in the case of enzyme excess and catalytic in the case of tenfold substrate excess. In the latter case, helicase activity is coupled with NTPase and is stimulated by ATP. A number of NTP and inorganic pyrophosphate analogs were studied as substrates and/or inhibitors of NS3 NTPase activity, and it was found that the structure of nucleic base and ribose fragment of NTP molecule has a slight effect on its inhibitory (substrate) properties. Among the nucleotide derivatives, the most efficient inhibitor of NTPase activity is 2 -deoxythymidine 5 -phosphoryl-beta,gamma-hypophosphate, and among pyrophosphate analogs imidodiphosphate exhibited maximal inhibitory activity. These compounds were studied as inhibitors of the helicase reaction, and it was shown that imidodiphosphate efficiently inhibited the ATP-dependent helicase reaction and had almost no effect on the ATP-independent duplex unwinding. However, the inhibitory effect of 2 -deoxythymidine 5 -phosphoryl-beta,gamma-hypophosphate was insignificant in both cases, which is due to the possibility of helicase activation by this ATP analog.     

Biological evaluation of hepatitis C virus helicase inhibitors.

A small chemical library has been synthesized and assayed for inhibition of HCV helicase activity. This study provides the structure-activity relationship of the reported inhibitors, with emphasis placed on the aminophenylbenzimidazole moiety and the linkers. Our data highlight the importance of preserving the aminophenylbenzimidazole core and the hydrophobic linkers for biological activity. The development of a robust HCV helicase assay is also described.     

Hepatitis C virus NS3 NTPase/helicase: different stereoselectivity in nucleoside triphosphate utilisation suggests that NTPase and helicase activities are coupled by a nucleotide-dependent rate limiting step.

Hepatitis C virus (HCV) NS3 protein is a multifunctional enzyme, possessing protease, NTPase and helicase activities within a single polypeptide of 625 amino acid residues. These activities are essential for the virus life cycle and are considered attractive targets for anti-HCV chemotherapy. Beside ATP, the NS3 protein has the ability to utilise deoxynucleoside triphosphates (dNTPs) as the energy source for nucleic acid unwinding. We have performed an extensive analysis of the substrate specificities of both NS3 NTPase and helicase activities with respect to all four dNTPs as well as with dideoxynucleoside triphoshate (ddNTP) analogs, including both d-(beta) and l-(beta)-deoxy and dideoxy-nucleoside triphosphates. Our results show that almost all dNTPs and ddNTPs tested were able to inhibit hydrolysis of ATP by the NTPase activity, albeit with different efficiencies. Moreover, this activity showed almost no stereoselectivity, being able to recognise both d-(beta), l-(beta)-deoxy and ddNTPs. On the contrary, the helicase activity had more strict substrate selectivity, since, among d-(beta)-nucleotides, only ddTTP and its analog 2',3'-didehydro-thymidine triphosphate could be used as substrates with an efficiency comparable to ATP, whereas among l-(beta)-nucleotides, only l-(beta)-dATP was utilised. Comparison of the steady-state kinetic parameters for both reactions, suggested that dATP, l-(beta)-dCTP and l-(beta)-dTTP, specifically reduced a rate limiting step present in the helicase, but not in the NTPase, reaction pathway. These results suggest that NS3-associated NTPase and helicase activities have different sensitivities towards different classes of deoxy and dideoxy-nucleoside analogs, depending on a specific step in the reaction, as well as show different enantioselectivity for the d-(beta) and l-(beta)-conformations of the sugar ring. These observations provide an essential mechanistic background for the development of specific nucleotide analogs targeting either activity as potential anti-HCV agents.     

Biochemical properties of a minimal functional domain with ATP-binding activity of the NTPase/helicase of hepatitis C virus.

The RNA-stimulated nucleoside triphosphatase (NTPase) and helicase of hepatitis C virus (HCV) consists of three domains with highly conserved NTP binding motifs located in the first domain. The ATP-binding domain was obtained by limited proteolysis of a greater fragment of the HCV polyprotein, and it was purified to homogenity by column chromatography. The identity of the domain, comprising amino acids 1203 to 1364 of the HCV polyprotein, was confirmed by N- and C-terminal sequencing and by its capability to bind 5'-fluorosulfonylbenzoyladenosine (FSBA). The analyses of the kinetics of ATP binding revealed a single class of binding site with the Kd of 43.6 microM. The binding is saturable and dependent on Mn2+ or Mg2+ ions. Poly(A) and poly(dA) show interesting properties as regulators of the ATP-binding capacity of the domain. Polynucleotides bind to the domain and enhance its affinity for ATP. In addition, ATP enhances the affinity of the domain for the polynucleotides. Different compounds, which are known to interact with nucleotide binding sites of various classes of enzymes, were tested for their ability to inhibit the binding of ATP to the domain. Of the compounds tested, two agents behaved as inhibitors: paclitaxel, which inhibits the ATP binding competitively (IC50 = 22 microM), and trifluoperazine, which inhibits the ATP binding by a noncompetitive mechanism (IC50 = 98 microM). Kinetic experiments with the NTPase/helicase indicate that both compounds inhibit the NTPase activity of the holoenzyme by interacting with its ATP-binding domain.     

The NTPase/helicase activities of Drosophila maleless, an essential factor in dosage compensation.

Drosophila maleless (mle) is required for X chromosome dosage compensation and is essential for male viability. Maleless protein (MLE) is highly homologous to human RNA helicase A and the bovine counterpart of RNA helicase A, nuclear helicase II. In this report, we demonstrate that MLE protein, overexpressed and purified from Sf9 cells infected with recombinant baculovirus, possesses RNA/DNA helicase, adenosine triphosphatase (ATPase) and single-stranded (ss) RNA/ssDNA binding activities, properties identical to RNA helicase A. Using site-directed mutagenesis, we created a mutant of MLE (mle-GET) that contains a glutamic acid in place of lysine in the conserved ATP binding site A. In vitro biochemical analysis showed that this mutation abolished both NTPase and helicase activities of MLE but affected the ability of MLE to bind to ssRNA, ssDNA and guanosine triphosphate (GTP) less severely. In vivo, mle-GET protein could still localize to the male X chromosome coincidentally with the male-specific lethal-1 protein, MSL-1, but failed to complement mle1 mutant males. These results indicate that the NTPase/helicase activities are essential functions of MLE for dosage compensation, perhaps utilized for chromatin remodeling of X-linked genes.     

Halogenated epoxides and related compounds as inhibitors of epoxide hydrase

A variety of chlorinated and fluorinated epoxides and related compounds were synthesized and evaluated as inhibitors of epoxide hydrase. The compounds were tested using chicken liver microsomes and a radiometric assay based on [³H]styrene oxide, and using partially purified chicken liver microsomal epoxide hydrase and a continuous photometric assay based on p-nitrostyrene oxide, whose hydration could be monitored at 310 nm. For the 16 compounds studied both assays gave similar patterns of inhibitory activity. As expected from the relative K_m values of the two substrates, all inhibitors were considerably more active against styrene oxide (K_m =1.0 mM) than against p-nitrostyrene oxide (K_m = 4.2 μM), and styrene oxide was a weak alternate-substrate inhibitor against p-nitrostyrene oxide. 1,1,1-Trichloropropene oxide, however, was a potent alternate-substrate inhibitor against p-nitrostyrene oxide. Addition of various substituents to the α-carbon of styrene oxide generated a series of compounds whose inhibitory potency toward p-nitrostyrene oxide increased in the order H ≈ CF₃ < CH₃ < CH₂Cl < CHCl₂ < CCl₃ ≈ 1,1,1-trichloropropene oxide. In contrast, addition of a CH₃ or CCl₃ group to the β-carbon of styrene oxide resulted in only a modest increase in inhibitory potency. 2-Phenyl- and 3-phenyloxetane showed no pronounced inhibitory activity toward either styrene oxide or p-nitrostyrene oxide, but pentafluorophenyl ethylene oxide and 1,1, 1-trichlorobutane-3,4-oxide were moderately active inhibitors, although significantly less potent than 1,1,1-trichloroproene oxide. These results show that electronegativity, steric effects, and hydrophobic effects are each important in governing the interaction of epoxide hydrase substrates with the enzyme, although it is not yet possible to analyze separately the effects of each of these parameters on K_m, V, and the catalytic mechanism.     

Purification and characterization of West Nile virus nucleoside triphosphatase (NTPase)/helicase: evidence for dissociation of the NTPase and helicase activities of the enzyme

The nucleoside triphosphatase (NTPase)/helicase associated with nonstructural protein 3 of West Nile (WN) virus was purified from cell culture medium harvested from virus-infected Vero cells. The purification procedure included sequential chromatography on Superdex-200 and Reactive Red 120 columns, followed by a concentration step on an Ultrogel hydroxyapatite column. The nature of the purified protein was confirmed by immunoblot analysis using a WN virus-positive antiserum, determination of its NH(2) terminus by microsequencing, and a binding assay with 5'-[(14)C]fluorosulfonylbenzoyladenosine. Under optimized reaction conditions the enzyme catalyzed the hydrolysis of ATP and the unwinding of the DNA duplex with k(cat) values of 133 and 5.5 x 10(-3) s(-1), respectively. Characterization of the NTPase activity of the WN virus enzyme revealed that optimum conditions with respect to the Mg(2+) requirement and the monovalent salt or polynucleotide response differed from those of other flavivirus NTPases. Initial kinetic studies demonstrated that the inhibition (or activation) of ATPase activity by ribavirin-5'-triphosphate is not directly related to changes in the helicase activity of the enzyme. Further analysis using guanine and O(6)-benzoylguanine derivatives revealed that the ATPase activity of WN virus NTPase/helicase may be modulated, i.e., increased or reduced, with no effect on the helicase activity of the enzyme. On the other hand the helicase activity could be modulated without changing the ATPase activity. Our observations show that the number of ATP hydrolysis events per unwinding cycle is not a constant value.     

Peptide-based inhibitors of hepatitis C virus full-length NS3 (protease-helicase/NTPase): model compounds towards small molecule inhibitors

From L-alpha-aminobutyric acid (Abu) a set of electrophilic and non-electrophilic replacements for the P1 cysteine of substrate and product inhibitors of hepatitis C virus full-length NS3 (protease-helicase/NTPase) serine protease have been synthesised and coupled to a model pentapeptide furnishing a set of hexapeptide inhibitors. Promising inhibitory activities with K(i) values of 0.18 microM (11b, P1 electrophilic alpha,beta-unsaturated ketone), 0.46 microM (12e, P1 electrophilic alkyl ketone) and 0.98 microM (10e, P1 non-electrophilic alkenyl alcohol as diastereomeric mixture). The reference hexapeptide product inhibitor had a K(i) value of 1.54 microM (14, P1 Abu-OH). The electrophilic inhibitors exhibit increased potency as compared with the corresponding product inhibitor, and notably also the non-electrophilic P1 alkenyl alcohol 10e. This represents the first example of non-electrophilic inhibitors that are not P1 amides or product inhibitors.     

High-throughput screening assay of hepatitis C virus helicase inhibitors using fluorescence-quenching phenomenon

We have developed a novel high-throughput screening assay of hepatitis C virus (HCV) nonstructural protein 3 (NS3) helicase inhibitors using the fluorescence-quenching phenomenon via photoinduced electron transfer between fluorescent dyes and guanine bases. We prepared double-stranded DNA (dsDNA) with a 5′-fluorescent-dye (BODIPY FL)-labeled strand hybridized with a complementary strand, the 3′-end of which has guanine bases. When dsDNA is unwound by helicase, the dye emits fluorescence owing to its release from the guanine bases. Our results demonstrate that this assay is suitable for quantitative assay of HCV NS3 helicase activity and useful for high-throughput screening for inhibitors. Furthermore, we applied this assay to the screening for NS3 helicase inhibitors from cell extracts of microorganisms, and found several cell extracts containing potential inhibitors.     

Tetrapeptides as potent protease inhibitors of Hepatitis C Virus full-length NS3 (protease-helicase/NTPase)

A library of tetrapeptides was evaluated for Hepatitis C Virus NS3 protease inhibitor activity in an in vitro assay system comprising the native bifunctional full-length NS3 (protease-helicase/NTPase) protein. Tetrapeptides with K_i values in the high nanomolar range were identified, for example Suc-Chg-Glu-2-Nal-Cys (K_i=0.27±0.03 μM) and Suc-Dif-Glu-Glu-Cys (K_i=0.40±0.10 μM). Furthermore, it was shown that the inhibitory potencies are not affected significantly by assay ionic strength. As suggested by molecular modelling, potential binding interactions of the tetrapeptide inhibitors with the helicase domain might explain the data and structure–activity relationships thus obtained. Hence, we postulate that the full-length NS3 assay is a relevant system for inhibitor identification, offering new opportunities for inhibitor design.     

The helicase from hepatitis C virus is active as an oligomer.

The helicase from hepatitis C virus (HCV NS3h) residing on the C-terminal domain of nonstructural protein 3 was considered to be monomeric by several researchers. Here we demonstrate, based on biochemical kinetic data, that the HCV helicase acts as an oligomer. The increase in the ATPase k(cat) of the NS3h protein with increasing protein concentration provided evidence for oligomerization. A sharp decrease in the unwinding rate was observed when the wild type NS3h was mixed with the ATPase deficient mutants of NS3h protein. This provided strong support for both mixed oligomer formation and subunit interactions for the HCV helicase. Chemical cross-linking of NS3h protein was an inefficient process, but yielded cross-linked protein oligomers of various sizes. The information currently available for HCV helicase is consistent with the hypothesis that oligomers of NS3h are not stable and the helicase subunits exchange during unwinding. Nevertheless, oligomerization of HCV helicase stimulates the ATPase activity, and it is required for the helicase activity.     

An RNA ligand inhibits hepatitis C virus NS3 protease and helicase activities

The hepatitis C virus non-structural protein 3 (HCV NS3) possesses both protease and helicase activities that are essential for viral replication. In a previous study, we obtained RNA aptamers that specifically and efficiently inhibited NS3 protease activity (G9 aptamers). In order to add helicase-inhibition capability, we attached (U)14 to the 3'-terminal end of a minimized G9 aptamer, DeltaNEO-III. NEO-III-14U was shown to inhibit the NS3 protease activity more efficiently than the original aptamer and, furthermore, to efficiently inhibit the unwinding reaction by NS3 helicase. In addition, NEO-III-14U has the potential to diminish specific interactions between NS3 and the 3'-UTR of HCV-positive and -negative strands. NEO-III-14U showed effective inhibition against NS3 protease in living cells.     

Acyl sulfonamides as potent protease inhibitors of the hepatitis C virus full-Length NS3 (protease-helicase/NTPase): a comparative study of different C-terminals

Synthesis and inhibitory potencies of three types of protease inhibitors of the hepatitis C virus (HCV) full-length NS3 (protease-helicase/NTPase) are reported: (i) inhibitors comprising electrophilic serine traps (pentafluoroethyl ketones, alpha-keto acids, and alpha-ketotetrazoles), (ii) product-based inhibitors comprising a C-terminal carboxylate group, and (iii) previously unexplored inhibitors comprising C-terminal carboxylic acid bioisosteres (tetrazoles and acyl sulfonamides). Bioisosteric replacement with the tetrazole group provided inhibitors equally potent to the corresponding carboxylates, and substitution with the phenyl acyl sulfonamide group yielded more potent inhibitors. The hexapeptide inhibitors Suc-Asp-D-Glu-Leu-Ile-Cha-Nva-NHSO(2)Ph and Suc-Asp-D-Glu-Leu-Ile-Cha-ACPC-NHSO(2)Ph with K(i) values of 13.6 and 3.8 nM, respectively, were approximately 20 times more potent than the corresponding inhibitors with a C-terminal carboxylate and were comparable to the carboxylate-based inhibitor containing the native cysteine, Suc-Asp-D-Glu-Leu-Ile-Cha-Cys-OH (K(i)=28 nM). The acyl sulfonamide group constitutes a very promising C-terminal functionality that allows for prime site optimization.     

Discovery of potent nucleotide-mimicking competitive inhibitors of hepatitis C virus NS3 helicase

Among the enzymes involved in the life cycle of HCV, the non-structural protein NS3, with its double function of protease and NTPase/helicase, is essential for the virus replication. Exploiting our previous knowledge in the development of nucleotide-mimicking NS3 helicase (NS3h) inhibitors endowed with key structural and electronic features necessary for an optimal ligand-enzyme interaction, we developed the tetrahydroacridinyl derivative 3a as the most potent NS3h competitive inhibitor reported to date (HCV NS3h K(i)=20 nM).     

Mutational analysis of the hepatitis C virus RNA helicase.

The carboxyl-terminal three-fourths of the hepatitis C virus (HCV) NS3 protein has been shown to possess an RNA helicase activity, typical of members of the DEAD box family of RNA helicases. In addition, the NS3 protein contains four amino acid motifs conserved in DEAD box proteins. In order to inspect the roles of individual amino acid residues in the four conserved motifs (AXXXXGKS, DECH, TAT, and QRRGRTGR) of the NS3 protein, mutational analysis was used in this study. Thirteen mutant proteins were constructed, and their biochemical activities were examined. Lys1235 in the AXXXXGKS motif was important for basal nucleoside triphosphatase (NTPase) activity in the absence of polynucleotide cofactor. A serine in the X position of the DEXH motif disrupted the NTPase and RNA helicase activities. Alanine substitution at His1318 of the DEXH motif made the protein possess high NTPase activity. In addition, we now report inhibition of NTPase activity of NS3 by polynucleotide cofactor. Gln1486 was indispensable for the enzyme activity, and this residue represents a distinguishing feature between DEAD box and DEXH proteins. There are four Arg residues in the QRRGRTGR motif of the HCV NS3 protein, and the second, Arg1488, was important for RNA binding and enzyme activity, even though it is less well conserved than other Arg residues. Arg1490 and Arg1493 were essential for the enzymatic activity. As the various enzymatic activities were altered by mutation, the enzyme characteristics were also changed.     

Characterization of the NTPase, RNA-binding, and RNA helicase activities of the DEAH-box splicing factor Prp22

The DEAH protein Prp22 is important for the second transesterification step of pre-mRNA splicing, and it is essential for releasing mature mRNA from the spliceosome. Recombinant Prp22 has RNA-stimulated ATPase and ATP-dependent unwinding activities, which are crucial for the mRNA release step. In this study, we characterize the RNA-binding, NTP hydrolysis, and RNA unwinding functions of Prp22. Using nitrocellulose filter binding assays, we determined that the apparent affinity of Prp22 is approximately 20-fold greater for single-stranded RNA than for single-stranded DNA or duplex nucleic acids. Inclusion of hydrolyzable ATP in binding reactions increased the apparent K(D) for RNA by 3-4-fold. The Prp22-RNA interaction is influenced by the length of the RNA chain, and the apparent K(D) values for poly(A)(40) and poly(A)(10) are 17 and 140 nM, respectively. RNA-stimulated ATP hydrolysis is similarly affected by chain length, and optimal activity requires RNA oligomers of >or=20 nt. We show that Prp22 can hydrolyze all common NTPs and dNTPs with comparable efficiencies and that Prp22 unwinds RNA duplexes with 3' to 5' directionality.