Cleavage of the dengue virus polyprotein at the NS3/NS4A and NS4B/NS5 junctions is mediated by viral protease NS2B-NS3, whereas NS4A/NS4B may be processed by a cellular protease.

The cleavage mechanism utilized for processing of the NS3-NS4A-NS4B-NS5 domain of the dengue virus polyprotein was studied by using the vaccinia virus expression system. Recombinant vaccinia viruses vNS2B-NS3-NS4A-NS4B-NS5, vNS3-NS4A-NS4B-NS5, vNS4A-NS4B-NS5, and vNS4B-NS5 were constructed. These recombinants were used to infect cells, and the labeled lysates were analyzed by immunoprecipitation. Recombinant vNS2B-NS3-NS4A-NS4B-NS5 expressed the authentic NS3 and NS5 proteins, but the other recombinants produced uncleaved polyproteins. These findings indicate that NS2B is required for processing of the downstream nonstructural proteins, including the NS3/NS4A and NS4B/NS5 junctions, both of which contain a dibasic amino acid sequence preceding the cleavage site. The flavivirus NS4A/NS4B cleavage site follows a long hydrophobic sequence. The polyprotein NS4A-NS4B-NS5 was cleaved at the NS4A/NS4B junction in the absence of other dengue virus functions. One interpretation for this finding is that NS4A/NS4B cleavage is mediated by a host protease, presumably a signal peptidase. Although vNS3-NS4A-NS4B-NS5 expressed only the polyprotein, earlier results demonstrated that cleavage at the NS4A/NS4B junction occurred when an analogous recombinant, vNS3-NS4A-84%NS4B, was expressed. Thus, it appears that uncleaved NS3 plus NS5 inhibit NS4A/NS4B cleavage presumably because the putative signal sequence is not accessible for recognition by the responsible protease. Finally, recombinants that expressed an uncleaved NS4B-NS5 polyprotein, such as vNS4A-NS4B-NS5 or vNS4B-NS5, produced NS5 when complemented with vNS2B-30%NS3 or with vNS2B plus v30%NS3. These results indicate that cleavage at the NS4B/NS5 junction can be mediated by NS2B and NS3 in trans.     

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.     

Processing and localization of Dengue virus type 2 polyprotein precursor NS3-NS4A-NS4B-NS5.

Processing of dengue virus type 2 polyprotein precursor NS3-NS4A-NS4B-NS5 could be mediated by the catalytically active NS3 protease domain and NS2B in trans at the dibasic sites NS3-NS4A and NS4B-NS5. Subcellular localization of the unprocessed precursor NS3-NS4A-NS4B-NS5 showed that it was confined to a distinct subcellular organelle in the cytoplasm, which was distinct from the distribution of the mature NS5.     

Characterization of the hepatitis C virus-encoded serine proteinase: determination of proteinase-dependent polyprotein cleavage sites.

Processing of the hepatitis C virus (HCV) H strain polyprotein yields at least nine distinct cleavage products: NH2-C-E1-E2-NS2-NS3-NS4A-NS4B-NS5A-NS5B-CO OH. As described in this report, site-directed mutagenesis and transient expression analyses were used to study the role of a putative serine proteinase domain, located in the N-terminal one-third of the NS3 protein, in proteolytic processing of HCV polyproteins. All four cleavages which occur C terminal to the proteinase domain (3/4A, 4A/4B, 4B/5A, and 5A/5B) were abolished by substitution of alanine for either of two predicted residues (His-1083 and Ser-1165) in the proteinase catalytic triad. However, such substitutions have no observable effect on cleavages in the structural region or at the 2/3 site. Deletion analyses suggest that the structural and NS2 regions of the polyprotein are not required for the HCV NS3 proteinase activity. NS3 proteinase-dependent cleavage sites were localized by N-terminal sequence analysis of NS4A, NS4B, NS5A, and NS5B. Sequence comparison of the residues flanking these cleavage sites for all sequenced HCV strains reveals conserved residues which may play a role in determining HCV NS3 proteinase substrate specificity. These features include an acidic residue (Asp or Glu) at the P6 position, a Cys or Thr residue at the P1 position, and a Ser or Ala residue at the P1' position.     

Processing in the hepatitis C virus E2-NS2 region: identification of p7 and two distinct E2-specific products with different C termini.

The hepatitis C virus (HCV) H strain polyprotein is cleaved to produce at least nine distinct products: NH2-C-E1-E2-NS2-NS3-NS4A-NS4B-NS5A-NS5B-CO OH. In this report, a series of C-terminal truncations and fusion with a human c-myc epitope tag allowed identification of a tenth HCV-encoded cleavage product, p7, which is located between the E2 and NS2 proteins. As determined by N-terminal sequence analysis, p7 begins with position 747 of the HCV H strain polyprotein. p7 is preceded by a hydrophobic sequence at the C terminus of E2 which may direct its translocation into the endoplasmic reticulum, allowing cleavage at the E2/p7 site by host signal peptidase. This hypothesis is supported by the observation that cleavage at the E2/p7 and p7/NS2 sites in cell-free translation studies was dependent upon the addition of microsomal membranes. However, unlike typical cotranslational signal peptidase cleavages, pulse-chase experiments indicate that cleavage at the E2/p7 site is incomplete, leading to the production of two E2-specific species, E2 and E2-p7. Possible roles of p7 and E2-p7 in the HCV life cycle are discussed.     

Steady-state cleavage kinetics for dengue virus type 2 ns2b-ns3(pro) serine protease with synthetic peptides

The N-terminal part of the NS3 protein from dengue virus contains a trypsin-like serine protease responsible for processing the nonstructural region of the viral polyprotein. Enzymatic activity of the NS2B-NS3(pro) precursor incorporating a full-length NS2B cofactor of dengue virus type 2 was examined by using synthetic dodecamer peptide substrates encompassing native cleavage sequences of the NS2A/NS2B, NS2B/NS3, NS3/NS4A and NS4B/NS5 polyprotein junctions. Cleavage of the dansylated substrates was monitored by a HPLC-based assay and kinetic parameters for K(1M), k(cat) and k(cat)/K(m) were obtained. The data presented here show that NS2B-NS3(pro) expressed in recombinant E. coli can be renatured to an active protease which reacts in the absence of microsomal membranes with all 4 substrate peptides, albeit the molecule does not exhibit autoproteolytic processing at the NS2B/NS3 site. A marked difference in cleavage efficiency was found for the NS2B/NS3 substrate and the remaining 3 peptides based on the NS2A/NS2B, NS3/NS4A and NS4A/NS5 cleavage sites.     

Hepatitis C virus NS3 serine proteinase: trans-cleavage requirements and processing kinetics.

The hepatitis C virus H strain (HCV-H) polyprotein is cleaved to produce at least 10 distinct products, in the order of NH2-C-E1-E2-p7-NS2-NS3-NS4A-NS4B-NS5A-NS5B -COOH. An HCV-encoded serine proteinase activity in NS3 is required for cleavage at four sites in the nonstructural region (3/4A, 4A/4B, 4B/5A, and 5A/5B). In this report, the HCV-H serine proteinase domain (the N-terminal 181 residues of NS3) was tested for its ability to mediate trans-processing at these four sites. By using an NS3-5B substrate with an inactivated serine proteinase domain, trans-cleavage was observed at all sites except for the 3/4A site. Deletion of the inactive proteinase domain led to efficient trans-processing at the 3/4A site. Smaller NS4A-4B and NS5A-5B substrates were processed efficiently in trans; however, cleavage of an NS4B-5A substrate occurred only when the serine proteinase domain was coexpressed with NS4A. Only the N-terminal 35 amino acids of NS4A were required for this activity. Thus, while NS4A appears to be absolutely required for trans-cleavage at the 4B/5A site, it is not an essential cofactor for serine proteinase activity. To begin to examine the conservation (or divergence) of serine proteinase-substrate interactions during HCV evolution, we demonstrated that similar trans-processing occurred when the proteinase domains and substrates were derived from two different HCV subtypes. These results are encouraging for the development of broadly effective HCV serine proteinase inhibitors as antiviral agents. Finally, the kinetics of processing in the nonstructural region was examined by pulse-chase analysis. NS3-containing precursors were absent, indicating that the 2/3 and 3/4A cleavages occur rapidly. In contrast, processing of the NS4A-5B region appeared to involve multiple pathways, and significant quantities of various polyprotein intermediates were observed. NS5B, the putative RNA polymerase, was found to be significantly less stable than the other mature cleavage products. This instability appeared to be an inherent property of NS5B and did not depend on expression of other viral polypeptides, including the HCV-encoded proteinases.     

In vitro determination of dengue virus type 2 NS2B-NS3 protease activity with fluorescent peptide substrates

The NS2B-NS3(pro) polyprotein segment from the dengue virus serotype 2 strain 16681 was purified from overexpressing E. coli by metal chelate affinity chromatography and gel filtration. Enzymatic activity of the refolded NS2B-NS3(pro) protease complex was determined in vitro with dansyl-labeled peptide substrates, based upon native dengue virus type 2 cleavage sites. The 12mer substrate peptides and the cleavage products could be separated by reversed-phase HPLC, and were identified by UV and fluorescence detection. All of the peptide substrates (representing the DEN polyprotein junction sequences at the NS2A/NS2B, NS2B/NS3, NS3/NS4A and NS4B/NS5 sites) were cleaved by the recombinant protease NS2B-NS3(pro). No cleavage was observed with an enzymatically inactive S135A mutant of the NS3 protein, or with a modified substrate peptide of the NS3/NS4A polyprotein site that contained a K2093A substitution. Enzymatic activity was dependent on the salt concentration. A 50% decrease of activity was observed in the presence of 0.1 M sodium chloride. Our results show that the NS3 protease activity of the refolded NS2BNS3(pro) protein can be assayed in vitro with high specificity by using cleavage-junction derived peptide substrates.     

Serine protease of pestiviruses: determination of cleavage sites.

The single-stranded genomic RNA of pestiviruses is of positive polarity and encompasses one large open reading frame of about 4,000 codons. The resulting polyprotein is processed co- and posttranslationally by virus-encoded and host cell proteases to give rise to the mature viral proteins. A serine protease residing in the nonstructural (NS) protein NS3 (p80) has been shown to be essential for the release of the NS proteins located downstream of NS3. In this report the NS3 serine protease-dependent cleavage sites for bovine viral diarrhea virus (BVDV) strain CP7 are described. Proteins used for analysis were generated in Escherichia coli or in eukaryotic cells by the use of the T7 vaccinia virus system. The N termini of NS4A, NS4B, NS5A, and NS5B were determined by protein sequencing. Analysis of the data obtained showed that leucine at P1 is the only position conserved for all cleavage sites. At P1' alanine is found at the NS4A-NS4B site, whereas serine resides at this position at the NS3-NS4A, NS4B-NS5A, and NS5A-NS5B cleavage sites. For all cleavage sites the amino acids found at P1 and P1' are conserved for different genotypes of pestiviruses, despite the high degree of sequence variation found between these viruses. It is therefore assumed that the cleavage sites determined for BVDV CP7 are representative of those for all pestiviruses.     

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.     

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 .     

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.     

Functional characterization of cis and trans activity of the Flavivirus NS2B-NS3 protease

Flaviviruses are serious human pathogens for which treatments are generally lacking. The proteolytic maturation of the 375-kDa viral polyprotein is one target for antiviral development. The flavivirus serine protease consists of the N-terminal domain of the multifunctional nonstructural protein 3 (NS3) and an essential 40-residue cofactor (NS2B(40)) within viral protein NS2B. The NS2B-NS3 protease is responsible for all cytoplasmic cleavage events in viral polyprotein maturation. This study describes the first biochemical characterization of flavivirus protease activity using full-length NS3. Recombinant proteases were created by fusion of West Nile virus (WNV) NS2B(40) to full-length WNV NS3. The protease catalyzed two autolytic cleavages. The NS2B/NS3 junction was cleaved before protein purification. A second site at Arg(459) decreasing Gly(460) within the C-terminal helicase region of NS3 was cleaved more slowly. Autolytic cleavage reactions also occurred in NS2B-NS3 recombinant proteins from yellow fever virus, dengue virus types 2 and 4, and Japanese encephalitis virus. Cis and trans cleavages were distinguished using a noncleavable WNV protease variant and two types of substrates as follows: an inactive variant of recombinant WNV NS2B-NS3, and cyan and yellow fluorescent proteins fused by a dodecamer peptide encompassing a natural cleavage site. With these materials, the autolytic cleavages were found to be intramolecular only. Autolytic cleavage of the helicase site was insensitive to protein dilution, confirming that autolysis is intramolecular. Formation of an active protease was found to require neither cleavage of NS2B from NS3 nor a free NS3 N terminus. Evidence was also obtained for product inhibition of the protease by the cleaved C terminus of NS2B.     

Molecular views of viral polyprotein processing revealed by the crystal structure of the hepatitis C virus bifunctional protease-helicase

BACKGROUND: Hepatitis C virus (HCV) currently infects approximately 3% of the world's population. HCV RNA is translated into a polyprotein that during maturation is cleaved into functional components. One component, nonstructural protein 3 (NS3), is a 631-residue bifunctional enzyme with protease and helicase activities. The NS3 serine protease processes the HCV polyprotein by both cis and trans mechanisms. The structural aspects of cis processing, the autoproteolysis step whereby the protease releases itself from the polyprotein, have not been characterized. The structural basis for inclusion of protease and helicase activities in a single polypeptide is also unknown. RESULTS: We report here the 2.5 A resolution structure of an engineered molecule containing the complete NS3 sequence and the protease activation domain of nonstructural protein 4A (NS4A) in a single polypeptide chain (single chain or scNS3-NS4A). In the molecule, the helicase and protease domains are segregated and connected by a single strand. The helicase necleoside triphosphate and RNA interaction sites are exposed to solvent. The protease active site of scNS3-NS4A is occupied by the NS3 C terminus, which is part of the helicase domain. Thus, the intramolecular complex shows one product of NS3-mediated cleavage at the NS3-NS4A junction of the HCV polyprotein bound at the protease active site. CONCLUSIONS: The scNS3-NS4A structure provides the first atomic view of polyprotein cis processing. Both local and global structural rearrangements follow the cis cleavage reaction, and large segments of the polyprotein can be folded prior to proteolytic processing. That the product complex of the cis cleavage reaction exists in a stable molecular conformation suggests autoinhibition and substrate-induced activation mechanisms for regulation of NS3 protease activity.     

Upregulation of signalase processing and induction of prM-E secretion by the flavivirus NS2B-NS3 protease: roles of protease components.

Recently, we have shown that the ability of the flavivirus NS2B-NS3 protease complex to promote efficient signalase processing of the C-prM precursor, as well as secretion of prM and E, does not appear to depend strictly on cleavage of the precursor at its Lys-Arg-Gly dibasic site by the protease. We suggested that the association of the protease with the precursor via NS2B may be sufficient by itself for the above effects. To study the proposed association in more detail, we have developed an assay in which processing at the C-prM dibasic cleavage site is abolished by Lys-->Gly conversion. We constructed deletion mutants and chimeras of the West Nile (WN) flavivirus NS2B protein and expressed them in the context of [5'-C-->NS3(243)] containing either wild-type C-prM or its cleavage site mutant. All NS2B variants were able to form active protease complexes. Deletion of the carboxy-terminal cluster of hydrophobic amino acids in NS2B had no apparent effect on the formation of prM and prM-E secretion for the cassettes containing either wild-type or mutated C-prM precursor. Deletion of the amino-terminal hydrophobic cluster in NS2B did not affect prM-E secretion for the cassettes with wild-type C-prM but abrogated prM-E secretion for the cassettes with the mutated dibasic cleavage site in C-prM. Similarly, the NS2B-NS3(178) protease of Japanese encephalitis (JE) virus, when substituted for the WN virus NS2B-NS3(243) protease, was able to promote prM-E secretion for the cassette with the wild-type C-prM precursor but not with the mutated one. Replacement of the deleted amino-terminal hydrophobic cluster in the WN virus NS2B protein with an analogous JE virus sequence restored the ability of the protease to promote prM-E secretion. On the basis of these observations, roles of individual protease components in upregulation of C-prM signalase processing are discussed.     

An Uniquely Purified HCV NS3 Protease and NS4A21–34 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°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.     

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.     

Formation of the flavivirus envelope: role of the viral NS2B-NS3 protease.

One of the late processing events in the flavivirus replication cycle involves cleavage of the intracellular form of the flavivirus capsid protein (Cint) to the mature virion form (Cvir) lacking the carboxy-terminal stretch of hydrophobic amino acids which serves as a signal peptide for the downstream prM protein. This cleavage event was hypothesized to be effected by a viral protease and to be associated with virion formation. We have proposed a model of flavivirus virion formation in which processing of the C-prM precursor at the upstream signalase site is upregulated by interaction of the NS2B part of the protease with the prM signal peptide or with an adjacent carboxy-terminal region of the capsid protein in the precursor, and processing of Cint by the NS2B-NS3 protease follows the signalase cleavage. Recently, an alternative hypothesis was proposed which suggests a reverse order of these two cleavage events, namely, that cleavage of the C-prM precursor by the NS2B-NS3 protease at the Cint-->Cvir dibasic cleavage site is a prerequisite for the subsequent signalase cleavage of the prM signal peptide. To distinguish between these alternative models, we prepared a series of expression cassettes carrying mutations at the Cint-->Cvir dibasic cleavage site and investigated the effects of these mutations on signalase processing of C-prM and on formation and secretion of prM-E heterodimers. For certain mutated C-prM precursors, namely, for those with Lys-->Gly disruption of the dibasic site, efficient formation of prM was observed upon expression from larger cassettes encoding the viral protease, despite the absence of processing at the Cint-->Cvir cleavage site. Surprisingly, formation and secretion of prM-E heterodimers accompanied by late cleavage of prM was also observed for these cassettes, with an efficiency comparable to that of the wild-type expression cassette. These observations contradict the model in which cleavage of the C-prM precursor at the Cint-->Cvir dibasic site is a prerequisite for signalase cleavage.     

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.     

Functional characterization of the cleavage specificity of the sapovirus chymotrypsin-like protease

Sapovirus is a positive-stranded RNA virus with a translational strategy based on processing of a polyprotein precursor by a chymotrypsin-like protease. So far, the molecular mechanisms regulating cleavage specificity of the viral protease are poorly understood. In this study, the catalytic activities and substrate specificities of the predicted forms of the viral protease, the 3C-like protease (NS6) and the 3CD-like protease-polymerase (NS6-7), were examined in vitro. The purified NS6 and NS6-7 were able to cleave synthetic peptides (15 to 17 residues) displaying the cleavage sites of the sapovirus polyprotein, both NS6 and NS6-7 proteins being active forms of the viral protease. High-performance liquid chromatography and subsequent mass spectrometry analysis of digested products showed a specific trans cleavage of peptides bearing Gln-Gly, Gln-Ala, Glu-Gly, Glu-Pro, or Glu-Lys at the scissile bond. In contrast, peptides bearing Glu-Ala or Gln-Asp at the scissile bond (NS4-NS5 and NS5-NS6, or NS6-NS7 junctions, respectively) were resistant to trans cleavage by NS6 or NS6-7 proteins, whereas cis cleavage of the Glu-Ala scissile bond of the NS5-NS6 junction was evidenced. Interestingly, the presence of a Phe at position P4 overruled the resistance to trans cleavage of the Glu-Ala junction (NS5-NS6), whereas substitutions at the P1 and P2′ positions altered the cleavage efficiency. The differential cleavage observed is supported by a model of the substrate-binding site of the sapovirus protease, indicating that the P4, P1, and P2′ positions in the substrate modulate the cleavage specificity and efficiency of the sapovirus chymotrypsin-like protease.