Inhibiting viral proteases: challenges and opportunities

Inhibitor design against viral targets must take into account the peculiar characteristics of viral biology-in particular, the plasticity of their replicative machinery. This includes maturational cleavage of the polyprotein, which is mediated by virally encoded proteases. Designing against a movable target is particularly challenging, but at the same time it offers new opportunities. Here we describe our experience with the NS3/4A (NS: nonstructural) serine protease of human hepatitis C virus (HCV). By extensive use of combinatorial peptide libraries, various inhibitor types were generated, including product inhibitors, serine traps, P-P' inhibitors, and prime side inhibitors. The latter represent a first case for a serine protease. A key finding, derived from structural studies utilizing these inhibitors, was that NS3 is an induced-fit protease, requiring both the NS4A cofactor protein and the substrate to fully activate its catalytic machinery. In the absence of cofactor and/or substrate, NS3 exists in solution as a large conformational ensemble, which can be matched by a correspondingly large set of peptide inhibitors, each one stabilizing a given conformer. In the perspective of inhibiting viral proteases in general, we suggest that combinatorial ligand ensembles may be a powerful tool, to contrast the adaptive potential of the viral quasispecies.     

丙型肝炎病毒NS3蛋白酶在酵母系统中的可溶性表达

利用毕赤酵母系统表达具有催化活性的丙型肝炎病毒 (HCV)NS3蛋白酶 .将PCR直接扩增的病毒NS3丝氨酸蛋白酶基因和重组的带有辅酶的单链NS3 NS4A蛋白酶基因 ,分别插入表达载体pPICZαA的EcoRⅠ和XbaⅠ克隆位点 ,转化毕赤酵母GS115 ,可溶性表达NS3蛋白酶和单链NS3 4A蛋白酶 ;ELISA法测定表达蛋白酶的抗原性 ;原核高效表达载体pBVIL1表达酶切底物NS5A B片段 ,体外与蛋白酶共同温育 ,SDS PAGE鉴定蛋白酶催化活性 .载体测序结果表明 ,重组载体pPICZαA NS3和pPICZαA NS3 4A中的目的基因序列插入正确 ;SDS PAGE结果显示 ,培养物上清中存在分泌型目的蛋白带 ;ELISA结果证实 ,表达蛋白与HCV阳性血清有结合活性 ;蛋白酶与底物NS5A B片段不同作用时间的SDS PAGE ,看到约 2 4kD处底物条带的分解 .说明用毕赤酵母表达系统成功地表达了可溶性HCVNS3和单链NS3 4A蛋白酶 ;两种结构形式的蛋白酶在体外系统中都有催化活性 ,同时也都具有抗原性 .该研究为大量和方便地获得有催化活性的HCVNS3蛋白酶提供了有效途径 .     

Mechanistic role of NS4A and substrate in the activation of HCV NS3 protease

Hepatitis C virus (HCV) NS3 protease is the key enzyme for its maturation. Three hypotheses have been advanced in the literature to demonstrate the mechanism of the activation of the HCV NS3 protease. A virus-encoded protein NS4A and substrate are proposed to be involved in the activation of the HCV NS3 protease. However, the three hypotheses are not completely consistent with one another. Multiple molecular dynamics simulations were performed on various NS3 protease systems: free NS3 protease, NS3/4A, NS3/inhibitor, and NS3/4A/inhibitor complexes, to further unravel the mechanism of the activation of the NS3 protease. Simulation results suggest that the binding of NS4A induces a classic serine protease conformation of the catalytic triad of the NS3 protease. NS4A rearranges the secondary structure of both the N-terminus and catalytic site of the NS3 protease, reduces the mobility of the global structure of the NS3 protease, especially the catalytic site, and provides a rigid and tight structure, except for the S1 pocket, for the binding and hydrolysis of substrates. The binding of substrate also contributes to the activation of the NS3 protease by an induced-fit of the classic serine protease catalytic triad. However, the global structure of the NS3 protease is still loose and highly flexible without stable secondary structural elements, such as helix α0 at the N-terminus and helix α1 and β-sheet E1-F1 at the catalytic site. The structure of the NS3 protease without NS4A is not suitable for the binding and hydrolysis of substrates.     

Structure of West Nile Virus NS3 Protease: Ligand Stabilization of the Catalytic Conformation

Over the last decade, West Nile virus has spread rapidly via mosquito transmission from infected migratory birds to humans. One potential therapeutic approach to treating infection is to inhibit the virally encoded serine protease that is essential for viral replication. Here we report the crystal structure of the viral NS3 protease tethered to its essential NS2B cofactor and bound to a potent substrate-based tripeptide inhibitor, 2-naphthoyl-Lys-Lys-Arg-H (K_i = 41 nM), capped at the N-terminus by 2-naphthoyl and capped at the C-terminus by aldehyde. An important and unexpected feature of this structure is the presence of two conformations of the catalytic histidine suggesting a role for ligand stabilization of the catalytically competent His conformation. Analysis of other West Nile virus NS3 protease structures and related serine proteases supports this hypothesis, suggesting that the common catalytic mechanism involves an induced-fit mechanism.     

The design of a potent inhibitor of the hepatitis C virus NS3 protease: BILN 2061--from the NMR tube to the clinic

The virally encoded serine protease NS3/NS4A is essential to the life cycle of the hepatitis C virus (HCV), an important human pathogen causing chronic hepatitis, cirrhosis of the liver, and hepatocellular carcinoma. Until very recently, the design of inhibitors for the HCV NS3 protease was limited to large peptidomimetic compounds with poor pharmacokinetic properties, making drug discovery an extremely challenging endeavor. In our quest for the discovery of a small-molecule lead that could block replication of the hepatitis C virus by binding to the HCV NS3 protease, the critical protein-polypeptide interactions between the virally encoded NS3 serine protease and its polyprotein substrate were investigated. Lead optimization of a substrate-based hexapeptide, guided by structural data, led to the understanding of the molecular dynamics and electronic effects that modulate the affinity of peptidomimetic ligands for the active site of this enzyme. Macrocyclic beta-strand scaffolds were designed that allowed the discovery of potent, highly selective, and orally bioavailable compounds. These molecules were the first HCV NS3 protease inhibitors reported that inhibit replication of HCV subgenomic RNA in a cell-based replicon assay at low nanomolar concentrations. Optimization of their biopharmaceutical properties led to the discovery of the clinical candidate BILN 2061. Oral administration of BILN 2061 to patients infected with the hepatitis C genotype 1 virus resulted in an impressive reduction of viral RNA levels, establishing proof-of-concept for HCV NS3 protease inhibitors as therapeutic agents in humans.     

Polynucleotide modulation of the protease, nucleoside triphosphatase, and helicase activities of a hepatitis C virus NS3-NS4A complex isolated from transfected COS cells.

The hepatitis C virus (HCV) nonstructural 3 protein (NS3) is a 70-kDa multifunctional enzyme with three known catalytic activities segregated in two somewhat independent domains. The essential machinery of a serine protease is localized in the N-terminal one-third of the protein, and nucleoside triphosphatase (NTPase) and helicase activities reside in the remaining C-terminal region. NS4A is a 54-residue protein expressed immediately downstream of NS3 in the viral polyprotein, and a central stretch of hydrophobic residues in NS4A form an integral structural component of the NS3 serine protease domain. There is no evidence to suggest that the two domains of NS3 are separated by proteolytic processing in vivo. This may reflect economical packaging of essential viral replicative components, but it could also mean that there is functional interdependence between the two domains. In this study, a full-length NS3-NS4A complex was isolated after expression and autoprocessing in transiently transfected COS cells. The protein was used to examine the effects of polynucleotides on the NTPase, helicase, and protease activities. Unlike the previously reported behavior of a separately expressed NS3 helicase domain, the full NS3-NS4A complex demonstrated optimal NTPase activity between pH 7.5 and 8.5. All three NS3-NS4A activities were modulated by polynucleotides, with poly(U) having the most remarkable effect. These findings suggest that the domains within NS3 may influence the activity of one another and that the interplay of HCV genomic elements may regulate the enzyme activities of this complex HCV replicase component.     

Crystal structure of Dengue virus NS3 protease in complex with a Bowman-Birk inhibitor: implications for flaviviral polyprotein processing and drug design

Dengue viruses are members of the Flaviviridae and cause dengue fever and the more severe dengue hemorrhagic fever. Although nearly 40 % of the world's population is at risk of dengue infection, there is currently no effective vaccine or chemotherapy for the disease. Processing of the dengue polyprotein into structural and non-structural proteins in a host, which is essential for assembly of infective virions, is carried out by the combined action of host proteases and the trypsin-like, two-component viral NS2B/NS3 serine protease. Although NS2B strongly stimulates the catalytic NS3 protease domain, the latter is fully active against small substrates and possesses detectable activity against larger substrates, making both forms of the enzyme possible targets for drug design. In the crystal structure of a complex of the protease with a Bowman-Birk inhibitor reported here, an Arg residue at the P1 position of the inhibitor is bound in a manner distinctly different from that in other serine proteases of comparable specificity. However, because the regulatory component, NS2B, is not present in the complex, the physiological implications of this observations are currently unclear. The redundant nature of interaction of P1 Arg and Lys residues with Asp129, Tyr150 and Ser163 of the enzyme provides an explanation for the observed behavior of several site-specific mutants of Asp129 in the protease. The strong level of conservation of residues in the protease that interact with the P1 Arg, along with conservation of Arg at P1 of most cleavage sites in other flaviviruses, suggests that observations from this structure are likely to be applicable to many flaviviruses. The structure provides a starting point for design of site-specific mutations to probe the mechanism of catalysis by the catalytic domain, its activation by the regulatory domain and for design of specific inhibitors of enzymatic activity.     

Hepatitis C viral NS3-4A protease activity is enhanced by the NS3 helicase

Non-structural protein 3 (NS3) is a multifunctional enzyme possessing serine protease, NTPase, and RNA unwinding activities that are required for hepatitis C viral (HCV) replication. HCV non-structural protein 4A (NS4A) binds to the N-terminal NS3 protease domain to stimulate NS3 serine protease activity. In addition, the NS3 protease domain enhances the RNA binding, ATPase, and RNA unwinding activities of the C-terminal NS3 helicase domain (NS3hel). To determine whether NS3hel enhances the NS3 serine protease activity, we purified truncated and full-length NS3-4A complexes and examined their serine protease activities under a variety of salt and pH conditions. Our results indicate that the helicase domain enhances serine protease activity, just as the protease domain enhances helicase activity. Thus, the two enzymatic domains of NS3-4A are highly interdependent. This is the first time that such a complete interdependence has been demonstrated for a multifunctional, single chain enzyme. NS3-4A domain interdependence has important implications for function during the viral lifecycle as well as for the design of inhibitor screens that target the NS3-4A protease.     

Serpin mechanism of hepatitis C virus nonstructural 3 (NS3) protease inhibition: induced fit as a mechanism for narrow specificity

Hepatitis C virus (HCV) nonstructural 3 (NS3) serine protease disrupts important cellular antiviral signaling pathways and plays a pivotal role in the proteolytic maturation of the HCV polyprotein precursor. This recent discovery has fostered the search for NS3 protease inhibitors. However, the enzyme's unusual induced fit behavior and peculiar molecular architecture have imposed considerable obstacles to the development of small molecule inhibitors. In this article, we demonstrate that such unique induced fit behavior and the chymotrypsin-like catalytic domain can provide the structural plasticity necessary to generate protein-based inhibitors of the NS3 protease. We took advantage of the macromolecular scaffold of a Drosophila serpin, SP6, which intrinsically supports chymotrypsin-like enzyme inhibition, to design a novel class of potent and selective inhibitors. We show that altering the SP6 reactive site loop (RSL) resulted in the development of the first effective (K(i) of 34 nm) and selective serpin, SP6(EVC/S), directed at the NS3 protease. SP6(EVC/S) operates as a suicide substrate inhibitor, and its partitioning between the complex-forming and proteolytic pathways for the NS3 protease is HCV NS4A cofactor-dependent and -specific. Once bound to the protease active site, SP6(EVC/S) partitions with equal probability to undergo proteolysis by NS3 at the C-terminal site of the engineered RSL, (P(6))Glu-Ile-(P(4))Val-Met-Thr-(P(1))Cys- downward arrow -(P(1)')Ser, or to form a covalent acyl-enzyme complex characteristic of cognate protease-serpin pairs. Our results also reveal a novel cofactor-induced serpin mechanism of enzyme inhibition that could be explored for developing effective and selective inhibitors of other important induced fit viral proteases of the Flaviviridae family such as the West Nile virus NS3 endoprotease.     

Selection of Functional Variants of the NS3-NS4A Protease of Hepatitis C Virus by Using Chimeric Sindbis Viruses

The NS3-NS4A serine protease of hepatitis C virus (HCV) mediates four specific cleavages of the viral polyprotein and its activity is considered essential for the biogenesis of the HCV replication machinery. Despite extensive biochemical and structural characterization, the analysis of natural variants of this enzyme has been limited by the lack of an efficient replication system for HCV in cultured cells. We have recently described the generation of chimeric HCV-Sindbis viruses whose propagation depends on the NS3-NS4A catalytic activity. NS3-NS4A gene sequences were fused to the gene coding for the Sindbis virus structural polyprotein in such a way that processing of the chimeric polyprotein, nucleocapsid assembly, and production of infectious viruses required NS3-NS4A-mediated proteolysis (G. Filocamo, L. Pacini, and G. Migliaccio, J. Virol. 71:1417–1427, 1997). Here we report the use of these chimeric viruses to select and characterize active variants of the NS3-NS4A protease. Our original chimeric viruses displayed a temperature-sensitive phenotype and formed lysis plaques much smaller than those formed by wild-type (wt) Sindbis virus. By serially passaging these chimeric viruses on BHK cells, we have selected virus variants which formed lysis plaques larger than those produced by their progenitors and produced NS3-NS4A proteins different in size and/or sequence from those of the original viruses. Characterization of the selected protease variants revealed that all of the mutated proteases still efficiently processed the chimeric polyprotein in infected cells and also cleaved an HCV substrate in vitro. One of the selected proteases was expressed in a bacterial system and showed a catalytic efficiency comparable to that of the wt recombinant protease.     

GB virus B and hepatitis C virus NS3 serine proteases share substrate specificity.

GB virus B (GBV-B) is a recently discovered virus responsible for hepatitis in tamarins (Saguinus species). GBV-B belongs to the Flaviviridae family and is closely related to the human pathogen hepatitis C virus (HCV). Nonstructural protein 3 (NS3) of HCV has been shown to encompass a serine protease domain required for viral maturation. GBV-B and HCV share only about 30% of the amino acid sequence within the NS3 protease domain. The catalytic triad is conserved, and the residue Phe-154, presumed to be a crucial amino acid for determining the S1 specificity pocket of the HCV NS3 protease, is also conserved. We have expressed a synthetic gene encoding the GBV-B NS3 protease domain in Escherichia coli and have characterized the purified recombinant protein for its activity on HCV substrates. We have shown that the NS3 region of the GBV-B genome actually encodes a serine protease that, despite the low sequence homology, shares substrate specificity with the HCV NS3 protease.     

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.     

Enzymatic characterization of membrane-associated hepatitis C virus NS3-4A heterocomplex serine protease activity expressed in human cells

The hepatitis C virus (HCV) nonstructural (NS)3-NS4A serine protease heterocomplex is a prime target for development of novel HCV therapies, due to its essential role in maturation of the viral polyprotein. While the mode of substrate/inhibitor recognition of the HCV NS3/NS4A serine protease has been extensively studied in vitro, important molecular aspects of the mechanism of action for this membrane-bound multifunctional enzyme remain unresolved in vivo. In particular, what influence does membrane association exert on the specificity and catalysis of NS3-4A protease? To carry out this study, we developed a specific and sensitive protease assay using a unique internally quenched fluorogenic substrate (IQFS). Our IQFS enables for the first time the direct, specific detection of NS3-4A protease activity within membrane fractions isolated from human cells expressing NS3-4A and the determination of its steady-state kinetic parameters, which were found to be K(m) = 51 +/- 3 microM and k(cat) = 0.39 min(-1). We also show that our fluorescence-based bioassay can be used to evaluate specifically the potency and mode of action of NS3-4A directed inhibitors, such as in the case of a known NS3-4A substrate-analogue inhibitor (K(i) = 22 nM). Our results indicate that the membrane anchoring of NS3 by NS4A does not affect the substrate/inhibitor recognition by the NS3-4A protease domain. Further investigation may reveal whether membrane association could be important for regulating other enzymatic activities associated with NS3 (e.g., helicase and/or ATPase) and/or regulating the recently proposed cross-talk between the protease and helicase activities.     

A Conserved NS3 Surface Patch Orchestrates NS2 Protease Stimulation,NS5A Hyperphosphorylation and HCV Genome Replication

Hepatitis C virus (HCV) infection is a leading cause of liver disease worldwide. The HCV RNA genome is translated into a single polyprotein. Most of the cleavage sites in the non-structural (NS) polyprotein region are processed by the NS3/NS4A serine protease. The vital NS2-NS3 cleavage is catalyzed by the NS2 autoprotease. For efficient processing at the NS2/NS3 site, the NS2 cysteine protease depends on the NS3 serine protease domain. Despite its importance for the viral life cycle, the molecular details of the NS2 autoprotease activation by NS3 are poorly understood. Here, we report the identification of a conserved hydrophobic NS3 surface patch that is essential for NS2 protease activation. One residue within this surface region is also critical for RNA replication and NS5A hyperphosphorylation, two processes known to depend on functional replicase assembly. This dual function of the NS3 surface patch prompted us to reinvestigate the impact of the NS2-NS3 cleavage on NS5A hyperphosphorylation. Interestingly, NS2-NS3 cleavage turned out to be a prerequisite for NS5A hyperphosphorylation, indicating that this cleavage has to occur prior to replicase assembly. Based on our data, we propose a sequential cascade of molecular events: in uncleaved NS2-NS3, the hydrophobic NS3 surface patch promotes NS2 protease stimulation; upon NS2-NS3 cleavage, this surface region becomes available for functional replicase assembly. This model explains why efficient NS2-3 cleavage is pivotal for HCV RNA replication. According to our model, the hydrophobic surface patch on NS3 represents a module critically involved in the temporal coordination of HCV replicase assembly.     

Engineered toxins "zymoxins" are activated by the HCV NS3 protease by removal of an inhibitory protein domain

The synthesis of inactive enzyme precursors, also known as "zymogens," serves as a mechanism for regulating the execution of selected catalytic activities in a desirable time and/or site. Zymogens are usually activated by proteolytic cleavage. Many viruses encode proteases that execute key proteolytic steps of the viral life cycle. Here, we describe a proof of concept for a therapeutic approach to fighting viral infections through eradication of virally infected cells exclusively, thus limiting virus production and spread. Using the hepatitis C virus (HCV) as a model, we designed two HCV NS3 protease-activated "zymogenized" chimeric toxins (which we denote "zymoxins"). In these recombinant constructs, the bacterial and plant toxins diphtheria toxin A (DTA) and Ricin A chain (RTA), respectively, were fused to rationally designed inhibitor peptides/domains via an HCV NS3 protease-cleavable linker. The above toxins were then fused to the binding and translocation domains of Pseudomonas exotoxin A in order to enable translocation into the mammalian cells cytoplasm. We show that these toxins exhibit NS3 cleavage dependent increase in enzymatic activity upon NS3 protease cleavage in vitro. Moreover, a higher level of cytotoxicity was observed when zymoxins were applied to NS3 expressing cells or to HCV infected cells, demonstrating a potential therapeutic window. The increase in toxin activity correlated with NS3 protease activity in the treated cells, thus the therapeutic window was larger in cells expressing recombinant NS3 than in HCV infected cells. This suggests that the "zymoxin" approach may be most appropriate for application to life-threatening acute infections where much higher levels of the activating protease would be expected.     

An NS3 serine protease inhibitor abrogates replication of subgenomic hepatitis C virus RNA

The hepatitis C virus (HCV) NS3 protease is essential for polyprotein maturation and viral propagation, and it has been proposed as a suitable target for antiviral drug discovery. An N-terminal hexapeptide cleavage product of a dodecapeptide substrate identified as a weak competitive inhibitor of the NS3 protease activity was optimized to a potent and highly specific inhibitor of the enzyme. The effect of this potent NS3 protease inhibitor was evaluated on replication of subgenomic HCV RNA and compared with interferon-alpha (IFN-alpha), which is currently used in the treatment of HCV-infected patients. Treatment of replicon-containing cells with the NS3 protease inhibitor or IFN-alpha showed a dose-dependent decrease in subgenomic HCV RNA that reached undetectable levels following a 14-day treatment. Kinetic studies in the presence of either NS3 protease inhibitor or IFN-alpha also revealed similar profiles in HCV RNA decay with half-lives of 11 and 14 h, respectively. The finding that an antiviral specifically targeting the NS3 protease activity inhibits HCV RNA replication further validates the NS3 enzyme as a prime target for drug discovery and supports the development of NS3 protease inhibitors as a novel therapeutic approach for HCV infection.     

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.     

HCV非结构蛋白(NS2/NS3)基因表达载体的构建及其一级结构分析

应用逆转录－聚合酶链反应（ＲＴ－ＰＣＲ）技术,从ＨＣＶ感染者血清中扩增编码ＨＣＶ病毒蛋白酶的ＮＳ２－ＮＳ３ｃＤＮＡ片段,在其５′和３′端分别引入ＥｃｏＲⅠ和ＸｂａⅠ限制性内切酶位点,定向克隆至真核表达载体ｐｃＤＮＡ３,构建重组载体ｐｃＤＮＡ－ＮＳ２３,重组表达载体经限制性内切酶消化鉴定．用ＳＰ６和Ｔ７通用引物对目的基因片断进行序列分析．序列同源性分析结果表明,与ＨＣＶ－Ｊ、ＨＣ－Ｃ２有高度的同源性,与ＨＣＶ－１、ＨＣＶ－Ｊ６、ＨＣＶ－Ｊ８同源性差,提示所克隆的基因属ＨＣＶⅡ型．该区内重要的功能位点如Ｚｎ２＋依赖性金属蛋白酶催化中心、丝氨酸蛋白酶催化中心等均高度保守     

Development of a cell-based assay for monitoring specific hepatitis C virus NS3/4A protease activity in mammalian cells

The hepatitis C virus (HCV) contains a positive-sense RNA genome that encodes a unique polyprotein precursor, which must be processed by proteases to enable viral maturation. Virally encoded NS3/4A protease has thus become an attractive target for the development of antiviral drugs. To establish an assay system for monitoring NS3/4A protease activity in mammalian cells, this study describes a substrate vector, pEG(Delta4AB)SEAP, in which enhanced green fluorescent protein (EGFP) was fused to secreted alkaline phosphatase (SEAP) through the NS3/4A protease decapeptide recognition sequence, Delta4AB, which spans the NS4A and NS4B junction region. Secretion of SEAP into the culture medium was demonstrated to depend on the cleavage of Delta4AB by HCV NS3/4A protease. We demonstrated that the accumulation of SEAP activity in the culture medium depends on time up to 60h with the coexpression of active NS3/4A protease. The amount of SEAP in the culture medium was around 10 times greater than that of cells with coexpression of inactive NS3/4A mutant protease. This strategy has made it possible to monitor NS3/4A activity inside mammalian cells. Moreover, by using cells containing the HCV subgenomic replicon, the EG(Delta4AB)SEAP reporter can be used to detect the anti-HCV activity of interferon-alpha (IFN-alpha). Consequently, this EG(Delta4AB)SEAP reporter can be used to screen for NS3/4A protease inhibitors in the cellular environment and for anti-HCV drugs in replicon cells.