丙型肝炎病毒感染过程中其NS3/4A蛋白酶切割线粒体抗病毒信号蛋白的动态过程

已知丙型肝炎病毒(hepatitis C virus,HCV)可通过其蛋白酶NS3/4A切割线粒体抗病毒信号蛋白(mitochondrial antiviral signaling protein,MAVS)来逃逸天然免疫识别,但尚不清楚其切割动力学及切割在抑制干扰素中的作用。本研究旨在细胞模型中探讨HCV感染过程中病毒复制建立及病毒NS3/4A切割MAVS的动态过程,探究NS3/4A切割MAVS对病毒逃逸宿主天然免疫建立感染的贡献。首先构建基于绿色荧光蛋白(green fluorescent protein,GFP)的MAVS切割报告系统(GFP-NLS-MAVS-TM462),用 HCV Jc1-Gluc 感染Huh7.5/GFP-NLS-MAVS-TM462细胞。结果显示,病毒复制早期MAVS切割效率较低;NS3/4A高效切割MAVS发生于HCV复制晚期,且其切割效率与NS3蛋白水平相关。利用带有GFP ypet的HCV报告病毒Jc1-378-1感染Huh7.5/RFP-NLS-MAVS-TM462细胞,在单细胞水平观察HCV感染阳性细胞中MAVS被切割情况,发现HCV复制细胞中仅部分细胞MAVS被切割。进一步研究发现,不同基因型NS3/4A切割MAVS的效率仅与NS3表达水平相关。以上结果提示,HCV蛋白酶NS3/4A切割MAVS依赖NS3/4A蛋白在病毒复制过程中的累积,对在病毒复制早期逃逸宿主天然免疫建立感染可能无显著贡献。     

GB virus B disrupts RIG-I signaling by NS3/4A-mediated cleavage of the adaptor protein MAVS

Understanding the mechanisms of hepatitis C virus (HCV) pathogenesis and persistence has been hampered by the lack of small, convenient animal models. GB virus B (GBV-B) is phylogenetically the closest related virus to HCV. It causes generally acute and occasionally chronic hepatitis in small primates and is used as a surrogate model for HCV. It is not known, however, whether GBV-B has evolved strategies to circumvent host innate defenses similar to those of HCV, a property that may contribute to HCV persistence in vivo. We show here in cultured tamarin hepatocytes that GBV-B NS3/4A protease, but not a related catalytically inactive mutant, effectively blocks innate intracellular antiviral responses signaled through the RNA helicase, retinoic acid-inducible gene I (RIG-I), an essential sensor molecule that initiates host defenses against many RNA viruses, including HCV. GBV-B NS3/4A protease specifically cleaves mitochondrial antiviral signaling protein (MAVS; also known as IPS-1/Cardif/VISA) and dislodges it from mitochondria, thereby disrupting its function as a RIG-I adaptor and blocking downstream activation of both interferon regulatory factor 3 and nuclear factor kappa B. MAVS cleavage and abrogation of virus-induced interferon responses were also observed in Huh7 cells supporting autonomous replication of subgenomic GBV-B RNAs. Our data indicate that, as in the case of HCV, GBV-B has evolved to utilize its major protease to disrupt RIG-I signaling and impede innate antiviral defenses. These data provide further support for the use of GBV-B infection in small primates as an accurate surrogate model for deciphering virus-host interactions in hepacivirus pathogenesis.     

Differential requirements of NS4A for internal NS3 cleavage and polyprotein processing of hepatitis C virus

The NS3 protein of hepatitis C virus (HCV) possesses protease activity responsible for the proteolytic cleavage of the viral polyprotein at the junctions of nonstructural proteins downstream of NS3. The NS3 protein was also found to be internally cleaved. In this study, we demonstrated that internal cleavages occurred on the NS3 protein of genotype 1b in the presence of NS4A, both in culture cells and with a mouse model system. No internal cleavage products were detected with the NS3 and NS4A proteins of genotype 2a. Three potential cleavage sites were detected in the NS3 protein (genotype 1b), with IPT(402)|S being the major one. The internal cleavage requires the polyprotein processing activity of NS3 protease, but when supplemented in trans, the internal cleavage efficiency is reduced. In addition, several mutations in NS4A disrupted the internal cleavage of NS3 but did not affect polyprotein processing, indicating that NS4A contributes differently to these two proteolytic activities. Furthermore, Ile-25, Val-26, and Ile-29 of the NS4A protein, important for the NS4A-dependent internal cleavages, were also shown to be critical for the transforming activity of NS3, but mutations at these critical residues resulted only in a slight increase of HCV replicating efficiency. The internal cleavage-associated enhancement of the transforming activity of NS3 was reduced when a T402A substitution at the major internal cleavage site was introduced. The multiple roles of NS4A in viral multiplication and pathogenesis make NS4A an ideal molecular target for HCV therapy.     

Both NS3 and NS4A are required for proteolytic processing of hepatitis C virus nonstructural proteins.

The proteolytic cleavages at the NS3-NS4A, NS4A-NS4B, NS4B-NS5A, and NS5A-NS5B junctions of hepatitis C virus (HCV) polyprotein are effected by the virus-encoded serine protease contained within NS3. Using transient expression in HeLa cells of cDNA fragments that code for regions of the HCV polyprotein, we studied whether viral functions other than NS3 are required for proteolytic processing at these sites. We found that, in addition to NS3, a C-terminal 33-amino-acid sequence of the NS4A protein is required for cleavage at the NS3-NS4A and NS4B-NS5A sites and that it accelerates the rate of cleavage at the NS5A-NS5B junction. In addition, we show that NS4A can activate the NS3 protease when supplied in trans. Our data suggest that HCV NS4A may be the functional analog of flavivirus NS2B and pestivirus p10 proteins.     

Identification of the sequence on NS4A required for enhanced cleavage of the NS5A/5B site by hepatitis C virus NS3 protease.

In addition to NS3 protease, the NS4A protein is required for efficient cleavage of the nonstructural protein region of the hepatitis C virus polyprotein. To investigate the function and the sequence of NS4A required for the enhancement of NS3 protease activity, we developed an in vitro NS3 protease assay system consisting of three purified viral elements: (i) a recombinant NS3 protease which was expressed in Escherichia coli as a maltose-binding protein-NS3 fusion protein (MBP-NS3), (ii) synthetic NS4A fragments, and (iii) a synthetic peptide substrate which mimics the NS5A/5B junction. We showed that the NS3 protease activity of MBP-NS3 was enhanced in a dose-dependent manner by 4A18-40, which is a peptide composed of amino acid residues 18 to 40 of NS4A. The optimal activity was observed at a 10-fold molar excess of 4A18-40 over MBP-NS3. The coefficient for proteolytic efficiency, kcat/Km, of NS3 protease was increased by about 40 times by the addition of a 10-fold molar excess of 4A18-40. Using a series of truncations of 4A18-40, we estimated that amino acid residues 22 to 31 in NS4A (SVVIVGRIIL) constituted the core sequence for the effector activity. Single-substitution experiments with 4A21-34, a peptide composed of amino acid residues 21 to 34 of NS4A, suggested the importance of several residues (Val-23, Ile-25, Gly-27, Arg-28, Ile-29, and Leu-31) for its activity. In addition, we found that some single-amino-acid substitutions in 4A21-34 were able to inhibit the enhancement of NS3 protease activity by 4A18-40. This approach has potential as a novel strategy for inhibiting the NS3 protease activity important for hepatitis C virus proliferation.     

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.     

The membrane spanning domains of protein NS4B from hepatitis C virus

Determination of the membrane spanning domains of highly hydrophobic proteins from its primary structure, i.e., sequence, is cumbersome. However, transmembrane topology is better correlated with protein secondary structure than with the primary one. In this work we have determined the number and location of the transmembrane domains of the highly hydrophobic hepatitis C virus NS4B protein by studying the water-to-bilayer and water-to-interface transfer free energies of thirty-one different hepatitis C virus strains assuming that NS4B forms an α-helical wheel. Additionally, we have studied the effect of a peptide library encompassing the full length of the NS4B protein hepatitis C virus strain 1a_H77 on the phase transitions of DEPE through the use of differential scanning calorimetry. Our findings show that NS4B protein has five transmembrane domains and, as previously suggested, three interfacial segments. One of these segments, segment AH2, could behave similarly to viral pre-transmembrane segments, which would partition into and interact with the membrane and be responsible for the fluctuation of the protein between different topologies and therefore possible locations.     

Molecular determinants of TRIF proteolysis mediated by the hepatitis C virus NS3/4A protease

Persistent infections with hepatitis C virus (HCV) are a major cause of liver disease and reflect its ability to disrupt virus-induced signaling pathways activating cellular antiviral defenses. HCV evasion of double-stranded RNA signaling through Toll-like receptor 3 is mediated by the viral protease NS3/4A, which directs proteolysis of its proline-rich adaptor protein, Toll-IL-1 receptor domain containing adaptor-inducing interferon-beta (TRIF). The TRIF cleavage site has remarkable homology with the viral NS4B/5A substrate, although an 8-residue polyproline track extends upstream from the P(6) position in lieu of the acidic residue present in viral substrates. Circular dichroism (CD) spectroscopy confirmed that a substantial fraction of TRIF exists as polyproline II helices, and inclusion of the polyproline track increased affinity of P side TRIF peptides for the HCV-BK protease. A polyproline II peptide representing an SH3 binding motif (PPPVPPRRR, Sos) bound NS3 with moderate affinity, resulting in inhibition of proteolytic activity. Chemical shift perturbations in NMR spectra indicated that Sos binds a 3(10) helix close to the protease active site. Thus, a polyproline II interaction with the 3(10) helix likely facilitates NS3/4A recognition of TRIF, indicating a significant difference from NS3/4A recognition of viral substrates. Because SH3 binding motifs are also present in NS5A, a viral protein that interacts with NS3, we speculate that the NS3 3(10) helix may be a site of interaction with other viral proteins.     

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.     

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.     

Single-cell resolution imaging of membrane-anchored hepatitis C virus NS3/4A protease activity

The study of host and viral membrane-associated proteases has been hampered due to a lack of in vivo assays. We report here the development of a cell-based fluorescence assay for detecting hepatitis C virus (HCV) NS3/4A juxtamembrane protease activity. Intracellular membrane-anchored protein substrates were engineered comprising: (1) an endoplasmic reticulum targeting domain, the HCV NS5A N-terminal amphipathic alpha-helix; (2) a NS3/4A-specific cleavage site; and (3) a red fluorescent reporter group, DsRed. The results of our immunofluorescence and Western blotting studies demonstrate that our membrane-bound fluorescent probe was cleaved specifically and efficiently by NS3/4A expressed in human cells.     

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.     

Optimization of the P'-region of peptide inhibitors of hepatitis C virus NS3/4A protease

Infection by Hepatitis C Virus (HCV) leads to a slowly progressing disease that over two decades can lead to liver cirrhosis or liver cancer. Currently, one of the most promising approaches to anti-HCV therapy is the development of inhibitors of the NS3/4A protease, which is essential for maturation of the viral polyprotein. Several substrate-derived inhibitors of NS3/4A have been described, all taking advantage of binding to the S subsite of the enzyme. Inspection of the S' subsite of NS3/4A shows binding pockets which might be exploited for inhibitor binding, but due to the fact that ground-state binding to the S' subsite is not used by the substrate, this does not represent a suitable starting point. We have now optimized S'-binding in the context of noncleavable decapeptides spanning P6-P4'. Binding was sequentially increased by introduction of the previously optimized P-region [Ingallinella et al. (1998) Biochemistry 37, 8906-8914], change of the P4' residue, and combinatorial optimization of positions P2'-P3'. The overall process led to an increase in binding of more than 3 orders of magnitude, with the best decapeptide showing IC(50) < 200 pM. The binding mode of the decapeptides described in the present work shares features with the binding mode of the natural substrates, together with novel interactions within the S' subsite. Therefore, these peptides may represent an entry point for a novel class of NS3 inhibitors.     

Inhibition of hepatitis C virus NS2/3 processing by NS4A peptides. Implications for control of viral processing

The NS2/3 protease of hepatitis C virus is responsible for a single cleavage in the viral polyprotein between the nonstructural proteins NS2 and NS3. The minimal protein region necessary to catalyze this cleavage includes most of NS2 and the N-terminal one-third of NS3. Autocleavage reactions using NS2/3 protein translated in vitro are used here to investigate the inhibitory potential of peptides likely to affect the reaction. Peptides representing the cleaved sequence have no effect upon reaction rates, and the reaction rate is insensitive to dilution. Both results are consistent with prior suggestions that the NS2/3 cleavage is an intramolecular reaction. Surprisingly, peptides containing the 12-amino acid region of NS4A responsible for binding to NS3 inhibit the NS2/3 reaction with K(i) values as low as 3 microM. Unrelated peptide sequences of similar composition are not inhibitory, and neither are peptides containing incomplete segments of the NS4A region that binds to NS3. Inhibition of NS2/3 by NS4A peptides can be rationalized from the organizing effect of NS4A on the N terminus of NS3 (the NS2/3 cleavage point) as suggested by the known three-dimensional structure of the NS3 protease domain (Yan, Y., Li, Y., Munshi, S., Sardana, V., Cole, J. L., Sardana, M., Steinkuhler, C., Tomei, L., De Francesco, R., Kuo, L. C., and Chen, Z. (1998) Protein Sci. 7, 837-847). These findings may imply a sequential order to proteolytic maturation events in hepatitis C virus.     

Prime site binding inhibitors of a serine protease: NS3/4A of hepatitis C virus

Serine proteases are the most studied class of proteolytic enzymes and a primary target for drug discovery. Despite the large number of inhibitors developed so far, very few make contact with the prime site of the enzyme, which constitutes an almost untapped opportunity for drug design. In the course of our studies on the serine protease NS3/4A of hepatitis C virus (HCV), we found that this enzyme is an excellent example of both the opportunities and the challenges of such design. We had previously reported on two classes of peptide inhibitors of the enzyme: (a) product inhibitors, which include the P(6)-P(1) region of the substrate and derive much of their binding energy from binding of their C-terminal carboxylate in the active site, and (b) decapeptide inhibitors, which span the S(6)-S(4)' subsites of the enzyme, whose P(2)'-P(4)' tripeptide fragment crucially contributes to potency. Here we report on further work, which combined the key binding elements of the two series and led to the development of inhibitors binding exclusively to the prime site of NS3/4A. We prepared a small combinatorial library of tripeptides, capped with a variety of constrained and unconstrained diacids. The SAR was derived from multiple analogues of the initial micromolar lead. Binding of the inhibitor(s) to the enzyme was further characterized by circular dichroism, site-directed mutagenesis, a probe displacement assay, and NMR to unequivocally prove that, according to our design, the bound inhibitor(s) occupies (occupy) the S' subsite and the active site of the protease. In addition, on the basis of the information collected, the tripeptide series was evolved toward reduced peptide character, reduced molecular weight, and higher potency. Beyond their interest as HCV antivirals, these compounds represent the first example of prime site inhibitors of a serine protease. We further suggest that the design of an inhibitor with an analogous binding mode may be possible for other serine proteases.     

The identification of alpha-ketoamides as potent inhibitors of hepatitis C virus NS3-4A proteinase

Peptides based upon the non-prime side residues of the NS4A-4B cleavage site of hepatitis C virus (HCV) NS3-4A proteinase containing an alpha-ketoamide moiety in place of the scissile amide bond are potent inhibitors of this enzyme.     

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.