Inhibitors of hepatitis C virus NS3.4A protease 1. Non-charged tetrapeptide variants

Tetrapeptide-based peptidomimetic compounds have been shown to effectively inhibit the hepatitis C virus NS3.4A protease without the need of a charged functionality. An aldehyde is used as a prototype reversible electrophilic warhead. The SAR of the P1 and P2 inhibitor positions is discussed.     

Inhibitors of hepatitis C virus NS3.4A protease. Part 3: P2 proline variants

We recently described the identification of an optimized alpha-ketoamide warhead for our series of HCV NS3.4A inhibitors. We report herein a series of HCV protease inhibitors incorporating 3-alkyl-substituted prolines in P(2). These compounds show exceptional enzymatic and cellular potency given their relatively small size. The marked enhancement of activity of these 3-substituted proline derivatives relative to previously reported 4-hydroxyproline derivatives constitutes additional evidence for the importance of the S(2) binding pocket as the defining pharmacophore for inhibition of the NS3.4A enzyme.     

Inhibitors of hepatitis C virus NS3.4A protease. Effect of P4 capping groups on inhibitory potency and pharmacokinetics

Reversible tetrapeptide-based compounds have been shown to effectively inhibit the hepatitis C virus NS3.4A protease. Inhibition of viral replicon RNA production in Huh-7 cells has also been demonstrated. We show herein that the inclusion of hydrogen bond donors on the P4 capping group of tetrapeptide-based inhibitors result in increased binding potency to the NS3.4A protease. The capping groups also impart significant effects on the pharmacokinetic profile of these inhibitors.     

Functional and therapeutic analysis of hepatitis C virus NS3.4A protease control of antiviral immune defense

Chronic hepatitis C virus (HCV) infection is a major global public health problem. HCV infection is supported by viral strategies to evade the innate antiviral response wherein the viral NS3.4A protease complex targets and cleaves the interferon promoter stimulator-1 (IPS-1) adaptor protein to ablate signaling of interferon alpha/beta immune defenses. Here we examined the structural requirements of NS3.4A and the therapeutic potential of NS3.4A inhibitors to control the innate immune response against virus infection. The structural composition of NS3 includes an amino-terminal serine protease domain and a carboxyl-terminal RNA helicase domain. NS3 mutants lacking the helicase domain retained the ability to control virus signaling initiated by retinoic acid-inducible gene-I (RIG-I) or melanoma differentiation antigen 5 and suppressed the downstream activation of interferon regulatory factor-3 (IRF-3) and nuclear factor kappaB (NF-kappaB) through the targeted proteolysis of IPS-1. This regulation was abrogated by truncation of the NS3 protease domain or by point mutations that ablated protease activity. NS3.4A protease control of antiviral immune signaling was due to targeted proteolysis of IPS-1 by the NS3 protease domain and minimal NS4A cofactor. Treatment of HCV-infected cells with an NS3 protease inhibitor prevented IPS-1 proteolysis by the HCV protease and restored RIG-I immune defense signaling during infection. Thus, the NS3.4A protease domain can target IPS-1 for cleavage and is essential for blocking RIG-I signaling to IRF-3 and NF-kappaB, whereas the helicase domain is dispensable for this action. Our results indicate that NS3.4A protease inhibitors have immunomodulatory potential to restore innate immune defenses to HCV infection.     

The hepatitis C virus NS2/3 protease

The hepatitis C virus NS2/3 protein is a highly hydrophobic protease responsible for the cleavage of the viral polypeptide between non-structural proteins NS2 and NS3. However, many aspects of the NS2/3 protease's role in the viral life cycle and mechanism of action remain unknown. Based on the recently elucidated crystal structure of NS2, NS2/3 has been proposed to function as a cysteine protease despite its lack of sequence homology to proteases of known function. In addition, although shown to be required for HCV genome replication and persistent infection in a chimpanzee, the role of NS2/3 cleavage in the viral life cycle has not yet been fully investigated. However, several recent studies are beginning to clarify possible roles of the cleaved NS2 protein in modulation of host cell gene expression and apoptosis.     

SAR and pharmacokinetic studies on phenethylamide inhibitors of the hepatitis C virus NS3/NS4A serine protease

SAR on the phenethylamide 1 (Ki 1.2 microM) in the P2- and the P'-position led to potent inhibitors, one of which showed good exposure and low clearance when administered intramuscularly to rat.     

Evolution, synthesis and SAR of tripeptide alpha-ketoacid inhibitors of the hepatitis C virus NS3/NS4A serine protease

N-terminal truncation of the hexapeptide ketoacid 1 gave rise to potent tripeptide inhibitors of the hepatitis C virus NS3 protease/NS4A cofactor complex. Optimization of these tripeptides led to ketoacid 30 with an IC50 of 0.38 microM. The SAR of these tripeptides is discussed in the light of the recently published crystal structures of a ternary tripetide/NS3/NS4A complexes.     

Conformational stability of hepatitis C virus NS3 protease

The hepatitis C virus NS3 protease is responsible for the processing of the nonstructural region of viral precursor polyprotein in infected hepatic cells. NS3 has been considered a target for drug discovery for a long time. NS3 is a zinc-dependent serine protease. However, the zinc ion is not involved in the catalytic mechanism, because it is bound far away from the active site. Thus, zinc is essential for the structural integrity of the protein and it is considered to have a structural role. The first thermodynamic study on the conformational equilibrium and stability of NS3 and the effect of zinc on such equilibrium is presented here. In agreement with a previous calorimetric study on the binding of zinc to NS3, the global unfolding heat capacity is dominated by the zinc dissociation step, suggesting that the binding of zinc induces a significant structural rearrangement of the protein. In addition, contrary to other homologous zinc-dependent proteases, the zinc-free NS3 protease is not completely unstructured. It is apparent that the conformational landscape of hepatitis C virus NS3 protease is fairly complex due to its intrinsic plasticity, and to the interactions with its different effectors (zinc and the accessory viral protein NS4A) and their modulation of the population of the different conformational states.     

Inhibitors of the Zika virus protease NS2B-NS3

In recent years, the Zika virus has emerged from a neglected flavivirus to a health-threatening pathogen that causes epidemic outbreaks associated with neurological disorders and congenital malformations. In addition to vaccine development, the discovery of specific antiviral agents has been pursued intensely. The Zika virus protease NS2B-NS3 catalyses the processing of the viral precursor polyprotein as an essential step during viral replication. Since the epidemic Zika virus outbreak in the Americas, several inhibitors of this protease have been reported. Substrate-derived peptides revealed important structural information about the active site, whilst more drug-like small molecules have been discovered as allosteric inhibitors.     

In vitro study of the NS2-3 protease of hepatitis C virus.

Processing at the C terminus of the NS2 protein of hepatitis C virus (HCV) is mediated by a virus-encoded protease which spans most of the NS2 protein and part of the NS3 polypeptide. In vitro cotranslational cleavage at the 2-3 junction is stimulated by the presence of microsomal membranes and ultimately results in the membrane insertion of the NS2 polypeptide. To characterize the biochemical properties of this viral protease, we have established an in vitro assay whereby the NS2-3 protease of HCV BK can be activated posttranslationally by the addition of detergents. The cleavage proficiency of several deletion and single point mutants was the same as that observed with microsomal membranes, indicating that the overall sequence requirements for proper cleavage at this site are maintained even under these artificial conditions. The processing efficiency of the NS2-3 protease varied according to the type of detergent used and its concentration. Also, the incubation temperature affected the cleavage at the 2-3 junction. The autoproteolytic activity of the NS2-3 protease could be inhibited by alkylating agents such as iodoacetamide and N-ethylmaleimide. Metal chelators such as EDTA and phenanthroline also inhibited the viral enzyme. The EDTA inhibition of NS2-3 cleavage could be reversed, at least in part, by the addition of ZnCl2 and CdCl2. Among the common protease inhibitors tested, tosyl phenylalanyl chloromethyl ketone and soybean trypsin inhibitor inactivated the NS2-3 protease. By means of gel filtration analysis, it was observed that the redox state of the reaction mixture greatly influenced the processing efficiency at the 2-3 site and that factors present in the rabbit reticulocyte lysate, wheat germ extract, and HeLa cell extract were required for efficient processing at this site. Thus, the in vitro assay should allow further characterization of the biochemical properties of the NS2-3 protease of HCV and the identification of host components that contribute to the efficient processing at the 2-3 junction.     

Activity of purified hepatitis C virus protease NS3 on peptide substrates.

The protease domain of the hepatitis C virus (HCV) protein NS3 was expressed in Escherichia coli, purified to homogeneity, and shown to be active on peptides derived from the sequence of the NS4A-NS4B junction. Experiments were carried out to optimize protease activity. Buffer requirements included the presence of detergent, glycerol, and dithiothreitol, pH between 7.5 and 8.5, and low ionic strength. C- and N-terminal deletion experiments defined a peptide spanning from the P6 to the P4' residue as a suitable substrate. Cleavage kinetics were subsequently measured by using decamer P6-P4' peptides corresponding to all intermolecular cleavage sites of the HCV polyprotein. The following order of cleavage efficiency, in terms of kcat/Km, was determined: NS5A-NS5B > NS4A-NS4B >> NS4B-NS5A. A 14-mer peptide containing residues 21 to 34 of the protease cofactor NS4A (Pep4A 21-34), when added in stoichiometric amounts, was shown to increase cleavage rates of all peptides, the largest effect (100-fold) being observed on the hydrolysis of the NS4B-NS5A decamer. From the kinetic analysis of cleavage data, we conclude that (i) primary structure is an important determinant of the efficiency with which each site is cleaved during polyprotein processing, (ii) slow cleavage of the NS4B-NS5A site in the absence of NS4A is due to low binding affinity of the enzyme for this site, and (iii) formation of a 1:1 complex between the protease and Pep4A 21-34 is sufficient and required for maximum activation.     

Peptide inhibitors of Dengue virus NS3 protease. Part 1: Warhead

Substrate-based tetrapeptide inhibitors with various warheads were designed, synthesized, and evaluated against the Dengue virus NS3 protease. Effective inhibition was achieved by peptide inhibitors with electrophilic warheads such as aldehyde, trifluoromethyl ketone, and boronic acid. A boronic acid has the highest affinity, exhibiting a K(i) of 43 nM.     

Modulation of hepatitis C virus NS3 protease and helicase activities through the interaction with NS4A

The hepatitis C virus nonstructural 3 protein (NS3) possesses a serine protease activity in the N-terminal one-third, whereas RNA-stimulated NTPase and helicase activities reside in the C-terminal portion. The serine protease activity is required for proteolytic processing at the NS3-NS4A, NS4A-NS4B, NS4B-NS5A, and NS5A-NS5B polyprotein cleavage sites. NS3 forms a complex with NS4A, a 54-residue polypeptide that was shown to act as an essential cofactor of the NS3 protease. We have expressed in Escherichia coli the NS3-NS4A precursor; cleavage at the junction between NS3 and NS4A occurs during expression in the bacteria cells, resulting in the formation of a soluble noncovalent complex with a sub-nanomolar dissociation constant. We have assessed the minimal ionic strength and detergent and glycerol concentrations required for maximal proteolytic activity and stability of the purified NS3-NS4A complex. Using a peptide substrate derived from the NS5A-NS5B junction, the catalytic efficiency (kcat/Km) of NS3-NS4A-associated protease under optimized conditions was 55 000 s-1 M-1, very similar to that measured with a recombinant complex purified from eukaryotic cells. Dissociation of the NS3-NS4A complex was found to be fully reversible. No helicase activity was exhibited by the purified NS3-NS4A complex, but NS3 was fully active as a helicase upon dissociation of NS4A. On the other hand, both basal and poly(U)-induced NTPase activity and ssRNA binding activity associated with the NS3-NS4A complex were very similar to those exhibited by NS3 alone. Therefore, NS4A appears to uncouple the ATPase/ssRNA binding and RNA unwinding activities associated with NS3.     

Solution structure and dynamics of the single-chain hepatitis C virus NS3 protease NS4A cofactor complex

The backbone assignments, secondary structure, topology, and dynamics of the single-chain hepatitis C virus NS3 protease NS4A cofactor complex have been determined by NMR spectroscopy. Residues I34 to S181 of NS3 and the central three residues of the NS4A cofactor were assigned and the secondary structure was verified for these residues. In several X-ray structures of NS4A-bound NS3 protease, residues 1 to 28 are stabilized by crystal packing, which allows for the formation of the A0 strand and alpha0 helix. In solution, these N-terminal residues are largely unassigned and no evidence of a well-structured A0 strand or alpha0 helix was detected. NOEs between residues in the E1-F1 loop (containing D81) and the alpha1 helix (containing H57) together with the detection of a D81-H57 hydrogen bond indicate that in solution the catalytic triad (D81, H57, S139) of the protease is better ordered in the presence of the NS4A cofactor. This is consistent with the earlier crystallographic results and may explain the observed increase in catalytic activity of the enzyme due to NS4A binding. A model-free analysis of our relaxation data indicates substantial exchange rates for residues V51-D81, which comprise the upper part of the N-terminal beta-barrel. A comparison of chemical-shift differences between NS3 protease and the NS3 protease-NS4A complex shows extensive chemical-shift changes for residues V51-D81 indicating that non-local structural changes occur upon NS4A binding to the NS3 protease that are propagated well beyond the protease-cofactor interaction site. This is consistent with crystallographic data that reveal large structural rearrangements of the strand and loop regions formed by residues V51-D81 as a result of NS4A binding. The coincidence of large exchange rates for the NS3 protease-NS4A complex with chemical-shift differences due to NS4A binding suggests that residues V51-D81 of the NS3 protease NS4A complex are in slow exchange with a NS4A-free conformation of NS3 protease.     

P2-P4 macrocyclic inhibitors of hepatitis C virus NS3-4A serine protease

Synthesis and HCV NS3 serine protease inhibitory activity of 4-hydroxyproline derived macrocyclic inhibitors and SAR around this macrocyclic core is described in this communication. X-ray structure of inhibitor 38 bound to the protease is discussed.     

Chimeric Sindbis viruses dependent on the NS3 protease of hepatitis C virus.

The hepatitis C virus (HCV) NS3 protease cleaves the viral polyprotein at specific sites to release the putative components of the HCV replication machinery. Selective inhibition of this enzyme is predicted to block virus replication, and NS3 is thus considered an attractive candidate for development of anti-HCV therapeutics. To set up a system for analysis of NS3 protease activity in cultured cells, we constructed a family of chimeric Sindbis viruses which carry sequences coding for NS3 and its activator, NS4A, in their genomes. HCV sequences were fused to the gene coding for the Sindbis virus structural polyprotein via an NS3-specific cleavage site, with the expectation that processing of the chimeric polyprotein, nucleocapsid assembly, and generation of viable viral particles would occur only upon NS3-dependent proteolysis. Indeed, the chimeric genomes encoding an active NS3 protease produced infectious viruses in mammalian cells, while those encoding NS3 inactivated by alanine substitution of the catalytic serine did not. However, in infected cells chimeric genomes recombined, splicing out HCV sequences and reverting to pseudo-wild-type Sindbis virus. To force retention of HCV sequences, we modified one of the initial chimeras by introducing a second NS3 cleavage site in the Sindbis virus portion of the recombinant polyprotein, anticipating that revertants not encoding an active NS3 protease would not be viable. The resulting chimera produced infectious viruses which replicated at a lower rate than the parental construct and displayed a marked temperature dependence in the formation of lysis plaques yet stably expressed NS3.     

An amino-terminal domain of the hepatitis C virus NS3 protease is essential for interaction with NS4A.

Hepatitis C virus (HCV) genomic RNA is translated into a large polyprotein that is processed into structural and nonstructural proteins. Processing at the N termini of several nonstructural proteins requires sequences contained in both NS3 and NS4A. NS3 contains a serine protease, whereas the function of NS4A in proteolysis is yet to be determined. By using the vaccinia virus-T7 hybrid expression system to transiently express HCV polypeptides in HeLa cells, we studied the effect of several N-terminal and C-terminal deletions of HCV NS3 on the processing activity at all the downstream cleavage sites. In this way, we have delineated the minimal domain of NS3 required for the serine protease activity associated with this protein. In addition, we demonstrate the formation of a stable complex between NS3 and NS4A: analysis of the deletion mutants reveals a region at the N terminus of NS3 that is necessary for both complex formation and modulation of the proteolytic activity by NS4A but not for the NS4A-independent serine protease activity of NS3.     

A ribonuclease zymogen activated by the NS3 protease of the hepatitis C virus

Translating proteases as inactive precursors, or zymogens, protects cells from the potentially lethal action of unregulated proteolytic activity. Here, we impose this strategy on bovine pancreatic ribonuclease (RNase A) by creating a zymogen in which quiescent ribonucleolytic activity is activated by the NS3 protease of the hepatitis C virus. Connecting the N-terminus and C-terminus of RNase A with a 14-residue linker was found to diminish its ribonucleolytic activity by both occluding an RNA substrate and dislocating active-site residues, which are devices used by natural zymogens. After cleavage of the linker by the NS3 protease, the ribonucleolytic activity of the RNase A zymogen increased 105-fold. Both before and after activation, the RNase A zymogen displayed high conformational stability and evasion of the endogenous ribonuclease inhibitor protein of the mammalian cytosol. Thus, the creation of ribonuclease zymogens provides a means to control ribonucleolytic activity and has the potential to provide a new class of antiviral chemotherapeutic agents.     

Mechanistic and kinetic characterization of hepatitis C virus NS3 protein interactions with NS4A and protease inhibitors

The mechanism and kinetics of the interactions between ligands and immobilized full‐length hepatitis C virus (HCV) genotype 1a NS3 have been characterized by SPR biosensor technology. The NS3 interactions for a series of NS3 protease inhibitors as well as for the NS4A cofactor, represented by a peptide corresponding to the sequence interacting with the enzyme, were found to be heterogeneous. It may represent interactions with two stable conformations of the protein. The NS3–NS4A interaction consisted of a high‐affinity (K_D = 50 nM) and a low‐affinity (K_D = 2 µM) interaction, contributing equally to the overall binding. By immobilizing NS3 alone or together with NS4A it was shown that all inhibitors had a higher affinity for NS3 in the presence of NS4A. NS4A thus has a direct effect on the binding of inhibitors to NS3 and not only on catalysis. As predicted, the mechanism‐based inhibitor VX 950 exhibited a time‐dependent interaction with a slow formation of a stable complex. BILN 2061 or ITMN‐191 showed no signs of time‐dependent interactions, but ITMN‐191 had the highest affinity of the tested compounds, with both the slowest dissociation (k_off) and fastest association rate, closely followed by BILN 2061. The k_off for the inhibitors correlated strongly with their NS3 protease inhibitory effect as well as with their effect on replication of viral proteins in replicon cell cultures, confirming the relevance of the kinetic data. This approach for obtaining kinetic and mechanistic data for NS3 protease inhibitor and cofactor interactions is expected to be of importance for understanding the characteristics of HCV NS3 functionality as well as for anti‐HCV lead discovery and optimization. Copyright © 2010 John Wiley & Sons, Ltd.