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.     

Processing of the intracellular form of the west Nile virus capsid protein by the viral NS2B-NS3 protease: an in vitro study.

According to the existing model of flavivirus polyprotein processing, one of the cleavages in the amino-terminal part of the flavivirus polyprotein by host cell signalases results in formation of prM (precursor to one of the structural proteins, M) and the membrane-bound intracellular form of the viral capsid protein (Cint) retaining the prM signal sequence at its carboxy terminus. This hydrophobic anchor is subsequently removed by the viral protease, resulting in formation of the mature viral capsid protein found in virions (Cvir). We have prepared in vitro expression cassettes coding for both forms of the capsid protein, for the prM protein, for the C-prM precursor, and for the viral protease components of West Nile flavivirus and characterized their translation products. Using Cint and Cvir translation products as molecular markers, we have observed processing of the intracellular form of the West Nile capsid protein by the viral protease in vitro both upon cotranslation of the C-prM precursor and the viral protease-encoding cassette and by incubation of C-prM translation products with a detergent-solubilized extract of cells infected with a recombinant vaccinia virus expressing the active viral protease. The cleavage of Cint by the viral protease at the predicted dibasic site was verified by introduction of point mutations into the cleavage site and an adjacent region. These studies provide the first direct demonstration of processing of the intracellular form of the flavivirus capsid protein by the viral protease.     

NS2B-3 proteinase-mediated processing in the yellow fever virus structural region: in vitro and in vivo studies.

Several of the cleavages required to generate the mature nonstructural proteins from the flaviviral polyprotein are known to be mediated by a complex consisting of NS2B and a serine proteinase domain located in the N-terminal one-third of NS3. These cleavages typically occur after two basic residues followed by a short side chain residue. Cleavage at a similar dibasic site in the structural region is believed to produce the C terminus of the virion capsid protein. To study this cleavage, we developed a cell-free trans cleavage assay for yellow fever virus (YF)-specific proteolytic activity by using a substrate spanning the C protein dibasic site. Cleavage at the predicted site was observed when the substrate was incubated with detergent-solubilized lysates from YF-infected BHK cells. NS2B and the NS3 proteinase domain were the only YF-specific proteins required for this cleavage. Cell fractionation studies demonstrated that the YF-specific proteolytic activity was membrane associated and that activity could be detected only after detergent solubilization. Previous cell-free studies led to a hypothesis that processing in the C-prM region involves (i) translation of C followed by translocation and core glycosylation of prM by using an internal signal sequence, (ii) signalase cleavage to produce a membrane-anchored form of the C protein (anchC) and the N terminus of prM, and (iii) NS2B-3-mediated cleavage at the anchC dibasic site to produce the C terminus of the virion C protein. However, the results of in vivo transient-expression studies do not support this temporal cleavage order. Rather, expression of a YF polyprotein extending from C through the N-terminal one-third of NS3 revealed that C-prM processing, but not translocation, was dependent on an active NS2B-3 proteinase. This suggests that signalase-mediated cleavage in the lumen of the endoplasmic reticulum may be dependent on prior cleavage at the anchC dibasic site. Possible pathways for processing in the C-prM region are outlined and discussed.     

Inefficient signalase cleavage promotes efficient nucleocapsid incorporation into budding flavivirus membranes

The mechanism for efficient nucleocapsid (NC) uptake into flavivirus particles which form by budding through the membranes of the endoplasmic reticulum (ER) was investigated by using Murray Valley encephalitis virus as a model. Budding of flavivirus membranes is driven by the viral transmembrane proteins prM and E independently of NC interaction. We show that control of signalase cleavage of the multimembrane-spanning flavivirus polyprotein by the catalytic function of the viral protease is critical for efficient virus morphogenesis. In wild-type virus, signalase cleavage of prM remains inefficient until cleavage of capsid at the cytosolic side of the signal sequence separating the two proteins has occurred. This obligatory sequence of cleavages was uncoupled in a mutant virus with the consequence of greatly reduced incorporation of NC into budding membranes and augmented release of NC-free virus-like particles. Efficient signalase cleavage of prM in the mutant virus resulted in partial inhibition of cleavage of capsid by the viral NS2B-3 protease. Our results support a model for flavivirus morphogenesis involving temporal and spatial coordination of NC assembly and envelopment by regulated cleavages of an ER membrane-spanning capsid-prM intermediate.     

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

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

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.     

Functional analysis of potential carboxy-terminal cleavage sites of tick-borne encephalitis virus capsid protein

The mature capsid protein C of flaviviruses is generated through the proteolytic cleavage of the precursor polyprotein by the viral NS2B/3 protease. This cleavage is a prerequisite for the subsequent processing of the viral surface protein prM, and the concerted progression of these events plays a key role in the process of the assembly of infectious virions. Protein C of tick-borne encephalitis virus (TBEV) contains two amino acid sequence motifs within the carboxy-terminal region that match the canonical NS2B/3 recognition site. Site-specific mutagenesis in the context of the full-length TBEV genome was used to investigate the in vivo cleavage specificity of the viral protease in this functionally important domain. The results indicate that the downstream site is necessary and sufficient for efficient cleavage and virion assembly; in contrast, the upstream site is dispensable and placed in a structural context that renders it largely inaccessible to the viral protease. Mutants with impaired C-prM cleavage generally exhibited a significantly increased cytotoxicity. In spite of the clear preference of the protease for only one of the two naturally occurring motifs, the enzyme was unexpectedly tolerant to both the presence of a noncanonical threonine residue at position P2 and the position of cleavage relative to the adjacent internal prM signal sequence. The insertion of three amino acid residues downstream of the cleavage site did not change the viral phenotype. Thus, this study further illuminates the specificity of the TBEV protease and reveals that the carboxy-terminal region of protein C has a remarkable functional flexibility in its role in the assembly of infectious virions.     

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.     

Histidine at residue 99 and the transmembrane region of the precursor membrane prM protein are important for the prM-E heterodimeric complex formation of Japanese encephalitis virus

The formation of the flavivirus prM-E complex is an important step for the biogenesis of immature virions, which is followed by a subsequent cleavage of prM to M protein through cellular protease to result in the production and release of mature virions. In this study, the intracellular formation of the prM-E complex of Japanese encephalitis virus was investigated by baculovirus coexpression of prM and E in trans in Sf9 insect cells as analyzed by anti-E antibody immunoprecipitation and sucrose gradient sedimentation analysis. A series of carboxyl-terminally truncated prM mutant baculoviruses was constructed to demonstrate that the truncations of the transmembrane (TM) region resulted in a reduction of the formation of the stable prM-E complex by approximately 40% for the TM1 (at residues 130 to 147 [prM130-147]) truncation and 20% for TM2 (at prM153-167) truncation. Alanine-scanning site-directed mutagenesis on the prM99-103 region indicated that the His99 residue was the critical prM binding element for stable prM-E heterodimeric complex formation. The single amino acid mutation at the His99 residue of prM abolishing the prM-E interaction was not due to reduced expression or different subcellular location of the mutant prM protein involved in prM-E interactions as characterized by pulse-chase labeling and confocal scanning microscopic analysis. Recombinant subviral particles were detected in the Sf9 cell culture supernatants by baculovirus coexpression of prM and E proteins but not with the prM H99A mutant. Sequence alignment analysis was further conducted with different groups of flaviviruses to show that the prM H99 residues are generally conserved. Our findings are the first report to characterize the minimum binding elements of the prM protein that are involved in prM-E interactions of flaviviruses. This information, concerning a molecular framework for the prM protein, is considered to elucidate the structure/function relationship of the prM-E complex synthesis and provide the proper trajectory for flavivirus assembly and maturation.     

Cleavage at a novel site in the NS4A region by the yellow fever virus NS2B-3 proteinase is a prerequisite for processing at the downstream 4A/4B signalase site.

Flavivirus proteins are produced by co- and posttranslational proteolytic processing of a large polyprotein by both host- and virus-encoded proteinases. The viral serine proteinase, which consists of NS2B and NS3, is responsible for cleavage of at least four dibasic sites (2A/2B, 2B/3, 3/4A, and 4B/5) in the nonstructural region. Since the amino acid sequence preceding NS4B shares characteristics with signal peptides used for translocation of nascent polypeptides into the lumen of the endoplasmic reticulum, it has been proposed that cleavage at the 4A/4B site is mediated by a cellular signal peptidase. In this report, cell-free translation and in vivo transient expression assays were used to study processing in the NS4 region of the yellow fever virus polyprotein. With a construct which contained NS4B preceded by 17 residues constituting the putative signal peptide (sig4B), membrane-dependent cleavage at the 4A/4B site was demonstrated in vitro. Surprisingly, processing of NS4A-4B was not observed in cell-free translation studies, and in vivo expression of several yellow fever virus polyproteins revealed that the 4A/4B cleavage occurred only during coexpression of NS2B and the proteinase domain of NS3. Examination of mutant derivatives of the NS3 proteinase domain demonstrated that cleavage at the 4A/4B site correlated with expression of an active NS2B-3 proteinase. From these results, we propose a model in which the signalase cleavage generating the N terminus of NS4B requires a prior NS2B-3 proteinase-mediated cleavage at a novel site (called the 4A/2K site) which is conserved among flaviviruses and located 23 residues upstream of the signalase site. In support of this model, mutations at the 4A/4B signalase site did not eliminate processing in the NS4 region. In contrast, substitutions at the 4A/2K site, which were engineered to block NS2B-3 proteinase-mediated cleavage, eliminated signalase cleavage at the 4A/4B site. In addition, the size of the 3(502)-4A product generated by trans processing of a truncated polyprotein, 3(502)-5(356), was consistent with cleavage at the 4A/2K site rather than at the downstream 4A/4B signalase site.     

Highly Conserved Residues in the Helical Domain of Dengue Virus Type 1 Precursor Membrane Protein Are Involved in Assembly,Precursor Membrane (prM) Protein Cleavage,and Entry

The envelope and precursor membrane (prM) proteins of dengue virus (DENV) are present on the surface of immature virions. During maturation, prM protein is cleaved by furin protease into pr peptide and membrane (M) protein. Although previous studies mainly focusing on the pr region have identified several residues important for DENV replication, the functional role of M protein, particularly the α-helical domain (MH), which is predicted to undergo a large conformational change during maturation, remains largely unknown. In this study, we investigated the role of nine highly conserved MH domain residues in the replication cycle of DENV by site-directed mutagenesis in a DENV1 prME expression construct and found that alanine substitutions introduced to four highly conserved residues at the C terminus and one at the N terminus of the MH domain greatly affect the production of both virus-like particles and replicon particles. Eight of the nine alanine mutants affected the entry of replicon particles, which correlated with the impairment in prM cleavage. Moreover, seven mutants were found to have reduced prM-E interaction at low pH, which may inhibit the formation of smooth immature particles and exposure of prM cleavage site during maturation, thus contributing to inefficient prM cleavage. Taken together, these results are the first report showing that highly conserved MH domain residues, located at 20–38 amino acids downstream from the prM cleavage site, can modulate the prM cleavage, maturation of particles, and virus entry. The highly conserved nature of these residues suggests potential targets of antiviral strategy.     

Signal Peptidase Cleavage at the Flavivirus C-prM Junction: Dependence on the Viral NS2B-3 Protease for Efficient Processing Requires Determinants in C,the Signal Peptide,and prM

Signal peptidase cleavage at the C-prM junction in the flavivirus structural polyprotein is inefficient in the absence of the cytoplasmic viral protease, which catalyzes cleavage at the COOH terminus of the C protein. The signal peptidase cleavage occurs efficiently in circumstances where the C protein is deleted or if the viral protease complex is present. In this study, we used cDNA of Murray Valley encephalitis virus (MVE) to examine features of the structural polyprotein which allow this regulation of a luminal cleavage by a cytoplasmic protease. We found that the inefficiency of signal peptidase cleavage in the absence of the viral protease is not attributable solely to features of the C protein. Inhibition of cleavage still occurred when charged residues in C were mutated to uncharged residues or when an unrelated protein sequence (that of ubiquitin) was substituted for C. Also, fusion of the C protein did not inhibit processing of an alternative adjacent signal sequence. The cleavage region of the flavivirus prM translocation signal is unusually hydrophobic, and we established that altering this characteristic by making three point mutations near the signal peptidase cleavage site in MVE prM dramatically increased the extent of cleavage without requiring removal of the C protein. In addition, we demonstrated that luminal sequences downstream from the signal peptidase cleavage site contributed to the inefficiency of cleavage.Polyprotein processing is important in the regulation of gene expression of many plus-strand RNA viruses (16, 19, 29, 41). The production from a polyprotein of precursor and mature proteins, which may have different functional activities, can be quantitatively and temporally modulated (9, 22, 43). This involves predominantly the alteration of cleavage specificities of virus-encoded cytoplasmic proteases. The regulation of a signal peptidase cleavage in the lumen of the endoplasmic reticulum (ER) by a cytoplasmic viral protease has been described for the processing of the structural polyprotein region of several flaviviruses (1, 23, 42). This is intriguing since signal peptidase cleavages are generally assumed to take place rapidly, during protein translocation across the ER membrane (4).Flaviviruses are enveloped, positive-strand RNA viruses. The genome encodes a single polyprotein which is approximately 3,500 amino acids long and traverses the ER membrane multiple times (reviewed in reference 31). This polyprotein is cleaved to produce three structural and seven nonstructural proteins, and all but two of the necessary cleavages are catalyzed by the virus-encoded NS2B-3 protease in the cytoplasm or by signal peptidase at the luminal side of the ER membrane. The flavivirus structural proteins are encoded in the 5′ quarter of the genome. The capsid (C) protein, at the NH₂ terminus of the polyprotein, is separated from the prM (precursor to membrane) protein by a signal sequence directing the translocation of prM. The NS2B-3 protease complex catalyzes cleavage at the COOH terminus of the C protein on the cytoplasmic side of the ER membrane. This is the only site in the structural polyprotein region which is cleaved by this enzyme. The type I transmembrane protein prM is anchored in the lipid bilayer by a COOH-terminal membrane anchor, which is immediately followed by the signal sequence for translocation of the E (envelope) protein, also a type I transmembrane protein. Thus the NH₂ termini of the prM and E proteins are generated by signal peptidase cleavages. However, it has been noted for a number of flaviviruses that when the entire structural polyprotein region is expressed from cDNA, the signal peptidase-mediated cleavage at the NH₂ terminus of prM does not occur efficiently, in contrast to that at the NH₂ terminus of the E protein (23, 33, 36, 42). This inefficient production of prM is reflected in the deficiency of secretion of the prM-E heterodimer and, in turn, the lack of immunogenicity often observed when such constructs are used for vaccination (see, for example, references 10, 11, 18, 30, and 34).Signal peptidase cleavage at the C-prM junction is greatly enhanced in the presence of the viral NS2B-3 protease (1, 23, 42) or when prM is expressed by using constructs which do not include the C protein-coding region (23, 42). Furthermore, cleavage at the NH₂ terminus of prM by signal peptidase can be induced to occur posttranslationally following trypsin cleavage of the cytoplasmic C region of the C-prM precursor in crude microsomes in vitro (36). One of us has proposed that the covalent linkage of C to prM results in the positioning of the signal sequence of prM in the ER membrane such that the signal peptidase cleavage site is maintained in a cryptic conformation (23). In the present study we have investigated elements in the structural polyprotein region of a flavivirus, Murray Valley encephalitis virus (MVE), which allow the control of signal peptidase cleavage of prM by the viral protease.     

Mutagenesis of the NS3 Protease of Dengue Virus Type 2

The flavivirus protease is composed of two viral proteins, NS2B and NS3. The amino-terminal portion of NS3 contains sequence and structural motifs characteristic of bacterial and cellular trypsin-like proteases. We have undertaken a mutational analysis of the region of NS3 which contains the catalytic serine, five putative substrate binding residues, and several residues that are highly conserved among flavivirus proteases and among all serine proteases. In all, 46 single-amino-acid substitutions were created in a cloned NS2B-NS3 cDNA fragment of dengue virus type 2, and the effect of each mutation on the extent of self-cleavage of the NS2B-NS3 precursor at the NS2B-NS3 junction was assayed in vivo. Twelve mutations almost completely or completely inhibited protease activity, 9 significantly reduced it, 14 decreased cleavage, and 11 yielded wild-type levels of activity. Substitution of alanine at ultraconserved residues abolished NS3 protease activity. Cleavage was also inhibited by substituting some residues that are conserved among flavivirus NS3 proteins. Two (Y150 and G153) of the five putative substrate binding residues could not be replaced by alanine, and only Y150 and N152 could be replaced by a conservative change. The two other putative substrate binding residues, D129 and F130, were more freely substitutable. By analogy with the trypsin model, it was proposed that D129 is located at the bottom of the substrate binding pocket so as to directly interact with the basic amino acid at the substrate cleavage site. Interestingly, we found that significant cleavage activity was displayed by mutants in which D129 was replaced by E, S, or A and that low but detectable protease activity was exhibited by mutants in which D129 was replaced by K, R, or L. Contrary to the proposed model, these results indicate that D129 is not a major determinant of substrate binding and that its interaction with the substrate, if it occurs at all, is not essential. This mutagenesis study provided us with an array of mutations that alter the cleavage efficiency of the dengue virus protease. Mutations that decrease protease activity without abolishing it are candidates for introduction into the dengue virus infectious full-length cDNA clone with the aim of creating potentially attenuated virus stocks.     

Evidence that flavivirus NS1-NS2A cleavage is mediated by a membrane-bound host protease in the endoplasmic reticulum.

Previous deletion mutagenesis studies have shown that the flavivirus NS1-NS2A clevage requires the eight C-terminal residues of NS1, constituting the cleavage recognition sequence, and sequences in NS2A far downstream of the cleavage site. We now demonstrate that replacement of all of NS1 upstream of the cleavage recognition sequence with prM sequences still allows cleavage in vivo. Thus, other than the eight C-terminal residues, NS1 is dispensable for NS1-NS2A cleavage. However, deletion of the N-terminal signal sequence abrogated cleavage, suggesting that entry into the exocytic pathway is required. Cleavage in vivo was not blocked by brefeldin A, and cleavage could occur in vitro in the presence of dog pancreas microsomes, indicating that NS1-NS2A cleavage occurs in the endoplasmic reticulum. Four in-frame deletions in NS2A were cleavage defective in vitro, as were two mutants in which NS4A-NS4B sequences were substituted for NS2A, suggesting that most of NS2A is required. A series of substitution mutants were constructed in which all Asp, Cys, Glu, His, and Ser residues in NS2A were collectively replaced; all standard proteases require at least one of these residues in their active sites. No single mutant was cleavage defective, suggesting that NS2A is not a protease. Fractionation of the microsomes indicated that the lumenal contents were not required for NS1-NS2A cleavage. It seems most likely that NS1-NS2A cleavage is effected by a host membrane-bound endoplasmic reticulum-resident protease, quite possibly signalase, and that NS2A is required to present the cleavage recognition sequence in the correct conformation to the host enzyme for cleavage.     

Characterization of the GXXXG motif in the first transmembrane segment of Japanese encephalitis virus precursor membrane (prM) protein

The interaction between prM and E proteins in flavivirus-infected cells is a major driving force for the assembly of flavivirus particles. We used site-directed mutagenesis to study the potential role of the transmembrane domains of the prM proteins of Japanese encephalitis virus (JEV) in prM-E heterodimerization as well as subviral particle formation. Alanine insertion scanning mutagenesis within the GXXXG motif in the first transmembrane segment of JEV prM protein affected the prM-E heterodimerization; its specificity was confirmed by replacing the two glycines of the GXXXG motif with alanine, leucine and valine. The GXXXG motif was found to be conserved in the JEV serocomplex viruses but not other flavivirus groups. These mutants with alanine inserted in the two prM transmembrane segments all impaired subviral particle formation in cell cultures. The prM transmembrane domains of JEV may play importation roles in prM-E heterodimerization and viral particle assembly.     

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.     

Inhibitors of the Zika virus protease NS2B-NS3

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

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.