Conformational changes in human hepatitis C virus NS3 protease upon binding of product-based inhibitors.

One of the most promising approaches to anti-hepatitis C virus drug discovery is the development of inhibitors of the virally encoded protease NS3. This chymotrypsin-like serine protease is essential for the maturation of the viral polyprotein, and processing requires complex formation between NS3 and its cofactor NS4A. Recently, we reported on the discovery of potent cleavage product-derived inhibitors [Ingallinella et al. (1998) Biochemistry 37, 8906-8914]. Here we study the interaction of these inhibitors with NS3 and the NS3/cofactor complex. Inhibitors bind NS3 according to an induced-fit mechanism. In the absence of cofactor different binding modes are apparent, while in the presence of cofactor all inhibitors show the same binding mode with a small rearrangement in the NS3 structure, as suggested by circular dichroism spectroscopy. These data are consistent with the hypothesis that NS4A complexation induces an NS3 structure that is already (but not entirely) preorganized for substrate binding not only for what concerns the S' site, as already suggested, but also for the S site. Inhibitor binding to the NS3/cofactor complex induces the stabilization of the enzyme structure as highlighted by limited proteolysis experiments. We envisage that this may occur through stabilization of the individual N-terminal and C-terminal domains where the cofactor and inhibitor, respectively, bind and subsequent tightening of the interdomain interaction in the ternary complex.     

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.     

Virus-specific cofactor requirement and chimeric hepatitis C virus/GB virus B nonstructural protein 3

GB virus B (GBV-B) is closely related to hepatitis C virus (HCV) and causes acute hepatitis in tamarins (Saguinus species), making it an attractive surrogate virus for in vivo testing of anti-HCV inhibitors in a small monkey model. It has been reported that the nonstructural protein 3 (NS3) serine protease of GBV-B shares similar substrate specificity with its counterpart in HCV. Authentic proteolytic processing of the HCV polyprotein junctions (NS4A/4B, NS4B/5A, and NS5A/5B) can be accomplished by the GBV-B NS3 protease in an HCV NS4A cofactor-independent fashion. We further characterized the protease activity of a full-length GBV-B NS3 protein and its cofactor requirement using in vitro-translated GBV-B substrates. Cleavages at the NS4A/4B and NS5A/5B junctions were readily detectable only in the presence of a cofactor peptide derived from the central region of GBV-B NS4A. Interestingly, the GBV-B substrates could also be cleaved by the HCV NS3 protease in an HCV NS4A cofactor-dependent manner, supporting the notion that HCV and GBV-B share similar NS3 protease specificity while retaining a virus-specific cofactor requirement. This finding of a strict virus-specific cofactor requirement is consistent with the lack of sequence homology in the NS4A cofactor regions of HCV and GBV-B. The minimum cofactor region that supported GBV-B protease activity was mapped to a central region of GBV-B NS4A (between amino acids Phe22 and Val36) which overlapped with the cofactor region of HCV. Alanine substitution analysis demonstrated that two amino acids, Val27 and Trp31, were essential for the cofactor activity, a finding reminiscent of the two critical residues in the HCV NS4A cofactor, Ile25 and Ile29. A model for the GBV-B NS3 protease domain and NS4A cofactor complex revealed that GBV-B might have developed a similar structural strategy in the activation and regulation of its NS3 protease activity. Finally, a chimeric HCV/GBV-B bifunctional NS3, consisting of an N-terminal HCV protease domain and a C-terminal GBV-B RNA helicase domain, was engineered. Both enzymatic activities were retained by the chimeric protein, which could lead to the development of a chimeric GBV-B virus that depends on HCV protease function.     

The N-terminal region of hepatitis C virus nonstructural protein 3 (NS3) is essential for stable complex formation with NS4A.

Hepatitis C virus proteins are produced by proteolytic processing of the viral precursor polyprotein that is encoded in the largest open reading frame of the viral genome. Processing of the nonstructural viral polyprotein requires the viral serine-type proteinase present in nonstructural protein 3 (NS3). The cleavage of the junction between NS4B and NS5A is mediated by NS3 only when NS4A is present. NS4A is thought to be a cofactor that enhances the cleavage efficiency of NS3 in hepatitis C virus protein-producing cells. Stable NS3-NS4A complex formation required the N-terminal 22 amino acid residues of NS3. This interaction contributed to stabilization of the NS3 product as well as increased the efficiency of cleavage at the NS4B/5A site. The N-terminal 22 amino acid residues fused to Escherichia coli dihydrofolate reductase also formed a stable complex with NS4A. NS3 derivatives which lacked the N-terminal 22 amino acid residues showed drastically reduced cleavage activity at the NS4B/5A site even in the presence of NS4A. These data suggested that the interaction with NS4A through the 22 amino acid residues of NS3 is primarily important for the NS4A-dependent processing of the NS4B/5A site by NS3.     

Hepatitis C NS3 protease: restoration of NS4A cofactor activity by N-biotinylation of mutated NS4A using synthetic peptides

The NS3 serine protase of Hepatitis C virus (HCV) requires NS4A protein as a cofactor for efficient cleavage at four sites in the nonstructural region. The cofactor activity has been mapped to the central hydrophobic region (aa 22-34) of this 54-amino-acid NS4A protein, and site-directed mutagenesis has identified alternating hydrophobic amino acids, particularly Ile25 and Ile29, as critically important. A double mutant of NS4A cofactor peptide, I25A/I29A, completely abolished the cofactor activity. We now report that the cofactor peptide activity in the I25A/I29A double mutant can be restored specifically by introducing a biotin-aminohexanoic acid fusion at the N-terminus. In addition, a similar N-terminal fusion of biotin-aminohexanoic acid with the wild-type 4A peptide significantly enhanced cofactor activity. Our data corroborate the crystal structure-based hypothesis of hydrophobic interaction between the N-terminus of NS4A and the N-terminal alpha(0) helix of NS3 protease.     

The hepatitis C virus NS4A protein: interactions with the NS4B and NS5A proteins.

Hepatitis C virus encodes a large polyprotein precursor that is proteolytically processed into at least 10 distinct products, in the order NH2-C-E1-E2-p7-NS2-NS3-NS4A-NS4B-NS5A-NS5B -COOH. A serine proteinase encoded in the N-terminal 181 residues of the NS3 nonstructural protein is responsible for cleavage at four sites (3/4A, 4A/4B, 4B/5A, and 5A/5B) in the nonstructural region. NS4A, a 54-residue nonstructural protein which forms a stable complex with the NS3 proteinase, is required as a cofactor for cleavage at the 3/4A and 4B/5A sites and enhances processing at the 4A/4B and 5A/5B sites. Recently reported crystal structures demonstrated that NS4A forms an integral part of the NS3 serine proteinase. In this report, we present evidence that NS4A forms a nonionic-detergent-stable complex with the NS4B5A polyprotein substrate, which may explain the requirement of NS4A for the 4B/5A cleavage. Isoleucine-29 of NS4A, which has been previously shown to be essential for its proteinase cofactor activity and formation of the NS3 complex, was found to be important for the interaction between NS4A and the NS4B5A substrate. In addition, two more hydrophobic residues in the NS4A central region (valine-23 and isoleucine-25) were also shown to be essential for the cofactor activity and for the interaction with either the NS3 proteinase or the NS4B5A polyprotein substrate. Finally, the possible mechanisms by which these viral proteins interact with each other are discussed.     

Expression and purification of a hepatitis C virus NS3/4A complex, and characterization of its helicase activity with the Scintillation Proximity Assay system

The C-terminal two-thirds of nonstructural protein 3 (NS3) of hepatitis C virus (HCV) possesses RNA helicase activity. This enzyme is considered to be involved in viral replication, and is expected to be one of the target molecules of anti-HCV drugs. Previously, we established a high-throughput screening system for HCV helicase inhibitors using the Scintillation Proximity Assay (SPA) system [Kyono, K. et al. (1998) ANAL: BIOCHEM: 257, 120-126]. Here, we show improvement of the preparation method for the HCV NS3/4A complex. Alteration of the expression region led to an increase in protein expression. The partially purified full-length NS3 protein showed higher NS3 protease activity without the cofactor NS4A peptide than the truncated protease domain with the cofactor peptide, suggesting that this protein formed a complex with NS4A. NS3 further purified to homogeneity, as judged on silver staining, remained in a complex with NS4A. Characterization of the helicase activity of this full NS3/4A complex using the SPA helicase assay system revealed that this enzyme preferred Mn(2+), and that the optimal pH was 6.0-6.5. The NS3/4A complex could act on a DNA template but could not unwind the M13DNA/DNA substrate.     

Determination of the stoichiometry of protein complexes using liquid chromatography with fluorescence and mass spectrometric detection of fluorescently labeled proteolytic peptides

A method for the determination of the stoichiometry of protein complexes has been developed, which is based on proteolytic digestion of the complex, labeling with a fluorescent reagent, specific for amino or sulfhydryl groups, and separation by liquid chromatography with fluorescence and mass spectrometric detection. The intensity of the fluorescence signal of the labeled peptides resulting from different proteins is directly proportional to the stoichiometry of these proteins in the complex. The performance of the method was evaluated with standard peptides and proteins to ensure that accurate molar ratios can be obtained from the fluorescence chromatogram. Standard deviations of the measured molar ratio from the expected molar ratio were below 10% for both peptides and proteins. The method was finally employed for the determination of the stoichiometry of the 1:1 complex of sFc gamma RIII and hFc1. Using the described methodology, a stoichiometry of 1:1.1 was measured, which agrees well with a 1:1 complex.     

Multiple determinants influence complex formation of the hepatitis C virus NS3 protease domain with its NS4A cofactor peptide

The interaction of the hepatitis C virus (HCV) NS3 protease domain with its NS4A cofactor peptide (Pep4AK) was investigated at equilibrium and at pre-steady state under different physicochemical conditions. Equilibrium dissociation constants of the NS3-Pep4AK complex varied by several orders of magnitude depending on buffer additives. Glycerol, NaCl, detergents, and peptide substrates were found to stabilize this interaction. The extent of glycerol-induced stabilization varied in an HCV strain-dependent way with at least one determinant mapping to an NS3-NS4A interaction site. Conformational transitions affecting at least the first 18 amino acids of NS3 were the main energy barriers for both the association and the dissociation reactions of the complex. However, deletion of this N-terminal portion of the protease molecule only slightly influenced equilibrium dissociation constants determined under different physicochemical conditions. Limited proteolysis experiments coupled with mass spectrometric identification of cleavage fragments suggested a high degree of conformational flexibility affecting at least the first 21 residues of NS3. The accessibility of this region of the protease to limited chymotryptic digestion did not significantly change in any condition tested, whereas a significant reduction of chymotryptic cleavages within the NS3 core was detected under conditions of high NS3-Pep4AK complex affinity. We conclude the following: (1) The N-terminus of the NS3 protease that, according to the X-ray crystal structure, makes extensive contacts with the cofactor peptide is highly flexible in solution and contributes only marginally to the thermodynamic stability of the complex. (2) Affinity enhancement is accomplished by several factors through a general stabilization of the fold of the NS3 molecule.     

Activity of the quorum-sensing regulator TraR of Agrobacterium tumefaciens is inhibited by a truncated, dominant defective TraR-like protein

Horizontal transfer of Agrobacterium tumefaciens tumour-inducing plasmids requires opines, which are released from plant tumours as nutrients for the bacteria. The opine octopine causes synthesis of the quorum-sensing TraR protein, which activates several tra promoters in the presence of a pheromone called Agrobacterium autoinducer (AAI). A gene, traS , was previously found on the same Ti plasmid in an operon that directs the uptake of mannopine, another opine. TraS strongly resembles TraR but lacks a DNA-binding module. TraS did not activate a TraR-dependent promoter and blocked TraR function, probably by forming inactive heteromultimers. Expression of traS was induced by mannopine, although this induction was strongly inhibited by the favoured catabolites succinate, glutamine and tryptone. Mannopine inhibited conjugation in a TraS-dependent fashion, and artificial overexpression of TraS also inhibited conjugation. Favoured catabolites restored tra gene expression in wild-type strains but not in strains that overexpress TraS. Downstream of traS is a gene encoding a truncated, defective chemoreceptor whose expression abolished chemotaxis.     

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.     

An uniquely purified HCV NS3 protease and NS4A(21-34) peptide form a highly active serine protease complex in peptide hydrolysis.

The N-terminal domain of the hepatitis C virus (HCV) polyprotein containing the NS3 protease (residues 1027 to 1206) was expressed in Escherichia coli as a soluble protein under the control of the T7 promoter. The enzyme has been purified to homogeneity with cation exchange (SP-Sepharose HR) and heparin affinity chromatography in the absence of any detergent. The purified enzyme preparation was soluble and remained stable in solution for several weeks at 4 degrees C. The proteolytic activity of the purified enzyme was examined, also in the absence of detergents, using a peptide mimicking the NS4A/4B cleavage site of the HCV polyprotein. Hydrolysis of this substrate at the expected Cys-Ala scissile bond was catalyzed by the recombinant protease with a pseudo second-order rate constant (k(cat)/K(M)) of 205 and 196,000 M(-1) s(-1), respectively, in the absence and presence of a central hydrophobic region (sequence represented by residues 21 to 34) of the NS4A protein. The rate constant in the presence of NS4A peptide cofactor was two orders of magnitude greater than reported previously for the NS3 protease domain. A significantly higher activity of the NS3 protease-NS4A cofactor complex was also observed with a substrate mimicking the NS4B/5A site (k(cat)/K(M) of 5180 +/- 670 M(-1) s(-1)). Finally, the optimal formation of a complex between the NS3 protease domain and the cofactor NS4A was critical for the high proteolytic activity observed.     

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.     

Cytosolic Arl2 is complexed with cofactor D and protein phosphatase 2A

Arl2 is a member of the ADP-ribosylation factor family of 20-kDa GTPases that is highly conserved in eukaryotes. Recent results revealed that a portion of cellular Arl2 and its binding partner, BART, localize to mitochondria. Because approximately 90% of cellular Arl2 is cytosolic, we investigated properties of the soluble protein and found that it is stably bound in a complex that migrates in gel filtration medium with a predicted molecular mass of approximately 300 kDa. This complex was purified approximately 500-fold from the soluble fraction of bovine brain. Protein components were identified by mass spectroscopy and revealed the presence of four other proteins that include the tubulin folding cochaperone cofactor D and all three subunits of at least two protein phosphatase 2A (PP2A) protein phosphatase trimers. The presence of more than one PP2A B-type subunit and the low stoichiometry of Arl2 indicate that the purified preparation still contains a mixture of complexes that cannot currently be completely resolved. Thus, although all the soluble Arl2 in bovine brain is in high molecular mass complexes, only a portion of the total cellular cofactor D and PP2A are associated with the Arl2. We further show that the Arl2 in the complex cannot bind GTP and that complexed cofactor D does not efficiently participate in tubulin refolding reactions in a manner comparable with free cofactor D. Our data suggest functional roles for the cytosolic Arl2 complex in modulating tubulin and microtubule behavior as well as a possible role in apoptosis.