Both nonstructural proteins NS2B and NS3 are required for the proteolytic processing of dengue virus nonstructural proteins.

The cleavages at the junctions of the flavivirus nonstructural (NS) proteins NS2A/NS2B, NS2B/NS3, NS3/NS4A, and NS4B/NS5 share an amino acid sequence motif and are presumably catalyzed by a virus-encoded protease. We constructed recombinant vaccinia viruses expressing various portions of the NS region of the dengue virus type 4 polyprotein. By analyzing immune precipitates of 35S-labeled lysates of recombinant virus-infected cells, we could monitor the NS2A/NS2B, NS2B/NS3, and NS3/NS4A cleavages. A polyprotein composed of NS2A, NS2B, and the N-terminal 184 amino acids of NS3 was cleaved at the NS2A/NS2B and NS2B/NS3 junctions, whereas a similar polyprotein containing only the first 77 amino acids of NS3 was not cleaved. This finding is consistent with the proposal that the N-terminal 180 amino acids of NS3 constitute a protease domain. Polyproteins containing NS2A and NS3 with large in-frame deletions of NS2B were not cleaved at the NS2A/NS2B or NS2B/NS3 junctions. Coinfection with a recombinant expressing NS2B complemented these NS2B deletions for NS2B/NS3 cleavage and probably also for NS2A/NS2B cleavage. Thus, NS2B is also required for the NS2A/NS2B and NS2B/NS3 cleavages and can act in trans. Other experiments showed that NS2B was needed, apparently in cis, for NS3/NS4A cleavage and for a series of internal cleavages in NS3. Indirect evidence that NS3 can also act in trans was obtained. Models are discussed for a two-component protease activity requiring both NS2B and NS3.     

Expression of dengue virus structural proteins and nonstructural protein NS1 by a recombinant vaccinia virus.

A recombinant vaccinia virus containing cloned DNA sequences coding for the three structural proteins and nonstructural proteins NS1 and NS2a of dengue type 4 virus was constructed. Infection of CV-1 cells with this recombinant virus produced dengue virus structural proteins as well as the nonstructural protein NS1. These proteins were precipitated by specific antisera and exhibited the same molecular size and glycosylation patterns as authentic dengue virus proteins. Infection of cotton rats with the recombinant virus induced NS1 antibodies in 1 of 11 animals. However, an immune response to the PreM and E glycoproteins was not detected. A reduced level of gene expression was probably the reason for the limited serologic response to these dengue virus antigens.     

Cleavage of dengue virus NS1-NS2A requires an octapeptide sequence at the C terminus of NS1.

The length of amino acid sequence at the NS1-NS2A juncture of dengue virus that is required for specific cleavage effected by the cis-acting function of NS2A was identified by deletion analysis. Recombinant DNA sequences of NS1-NS2A, each containing a deletion in NS1 followed by a sequence of 3 to 20 amino acids at the C terminus of NS1 preceding the cleavage site, were constructed and expressed with vaccinia virus as a vector. The NS1 product of recombinant vaccinia virus-infected cells was immunoprecipitated and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The occurrence of cleavage between NS1 and NS2A was indicated by the appearance of shortened NS1. Failure to cleave this site yielded a large NS1-NS2A fusion protein. This analysis indicated that a minimum length of eight amino acids at the NS1 C terminus preceding the NS1-NS2A juncture is required for cleavage to take place. Comparison of this eight-amino-acid sequence of the NS1 C terminus of dengue type 4 virus with the analogous sequences of 12 other flaviviruses suggests that the consensus cleavage site sequence is as follows: (table; see text)     

In vitro processing of dengue virus type 2 nonstructural proteins NS2A, NS2B, and NS3.

We have tested the hypothesis that the flavivirus nonstructural protein NS3 is a viral proteinase that generates the termini of several nonstructural proteins by using an efficient in vitro expression system and monospecific antisera directed against the nonstructural proteins NS2B and NS3. A series of cDNA constructs was transcribed by using T7 RNA polymerase, and the RNA was translated in reticulocyte lysates. The resulting protein patterns indicated that proteolytic processing occurred in vitro to generate NS2B and NS3. The amino termini of NS2B and NS3 produced in vitro were found to be the same as the termini of NS2B and NS3 isolated from infected cells. Deletion analysis of cDNA constructs localized the protease domain within NS3 to the first 184 amino acids but did not eliminate the possibility that sequences within NS2B were also required for proper cleavage. Kinetic analysis of processing events in vitro and experiments to examine the sensitivity of processing to dilution suggested that an intramolecular cleavage between NS2A and NS2B preceded an intramolecular cleavage between NS2B and NS3. The data from these expression experiments confirm that NS3 is the viral proteinase responsible for cleavage events generating the amino termini of NS2B and NS3 and presumably for cleavages generating the termini of NS4A and NS5 as well.     

Analysis of N-terminal processing of hepatitis C virus nonstructural protein 2.

We determined the partial amino (N)-terminal amino acid sequence of hepatitis C virus p21 (nonstructural protein 2 [NS2]). Cleavage at the p21 (NS2) N terminus depended on the presence of microsomal membranes. The amino-terminal position of p21 (NS2) was assigned to amino acid 810 of the hepatitis C virus strain IIJ precursor polyprotein. Mutation of the alanine residue at position P1 of the putative cleavage site inhibited membrane-dependent processing. This alteration in processing together with the fact that hydrophobic amino acid residues are clustered upstream of the putative cleavage site suggested the involvement of a signal peptidase(s) in the cleavage. Furthermore, mutation analysis of this possible cleavage site revealed the presence of another microsome membrane-dependent cleavage site upstream of the N terminus of p21 (NS2).     

Immunization of mice with recombinant vaccinia virus expressing authentic dengue virus nonstructural protein NS1 protects against lethal dengue virus encephalitis.

The protective immunity conferred by a set of recombinant vaccinia viruses containing the entire coding sequence of dengue virus type 4 nonstructural glycoprotein NS1 plus various flanking sequences was evaluated by using a mouse encephalitis model. Mice immunized with recombinant vNS1-NS2a, which expresses authentic NS1, were solidly protected against intracerebral dengue virus challenge. However, mice immunized with recombinants vNS1-15%NS2a and vRSVG/NS1-15%NS2a, which express aberrant forms of NS1, were only partially protected (63 to 67% survival rate). Serologic analysis showed that mice immunized with vNS1-NS2a developed high titers of antibodies to NS1 as measured by radioimmunoprecipitation, enzyme-linked immunosorbent assay, and complement-mediated cytolytic assays. In addition, a pool of sera from these animals was protective in a passive transfer experiment. Lower titers of NS1-specific antibodies were detected in sera of animals immunized with vNS1-15%NS2a or vRSVG/NS1-15%NS2a by all three assays. These data support the view that protection against dengue virus infection in mice may be mediated at least in part by NS1-specific antibodies through a mechanism of complement-mediated lysis of infected cells. Additionally, immunization with two recombinant viruses expressing authentic NS1 of dengue virus type 2 conferred partial protection (30-50%) against dengue virus type 2 challenge.     

Deletion analysis of dengue virus type 4 nonstructural protein NS2B: identification of a domain required for NS2B-NS3 protease activity.

Most proteolytic cleavages in the nonstructural protein (NS) region of the flavivirus polyprotein are effected by a virus-encoded protease composed of two viral proteins, NS2B and NS3. The N-terminal 180-amino-acid-region of NS3 includes sequences with homology to the active sites of serine proteases, and there is evidence that this portion of NS3 can mediate proteolytic cleavages. In contrast, nothing is known about required sequences in NS2B. We constructed a series of deletion mutations in the NS2B portion of plasmid pTM/NS2B-30% NS3, which expresses dengue virus type 4 (DEN4) cDNA encoding NS2B and the N-terminal 184 residues of NS3 from the T7 RNA polymerase promoter. Mutant or wild-type plasmids were transfected into cells that had been infected with a recombinant vaccinia virus expressing T7 RNA polymerase, and the protease activities of the expressed polyproteins were assayed by examining the extent of self-cleavage at the NS2B-NS3 junction. The results identify a 40-amino-acid segment of NS2B (DEN4 amino acids 1396 to 1435) essential for protease activity. A hydrophobicity profile of DEN4 NS2B predicts this segment constitutes a hydrophilic domain surrounded by hydrophobic regions. Hydrophobicity profiles of the NS2B proteins of other flaviviruses show similar patterns. Amino acid sequence alignment of this domain of DEN4 NS2B with comparable regions of other proteins of flaviviruses indicates significant sequence conservation, especially at the N-terminal end. These observations suggest that the central hydrophilic domain of NS2B of these other flaviviruses will also prove to be essential for protease activity.     

Immunization of mice with dengue structural proteins and nonstructural protein NS1 expressed by baculovirus recombinant induces resistance to dengue virus encephalitis.

We have constructed a recombinant baculovirus containing a 4.0-kilobase dengue virus cDNA sequence that codes for the three virus structural proteins, capsid (C) protein, premembrane (PreM) protein, and envelope glycoprotein (E), and nonstructural proteins NS1 and NS2a. Infection of cultured Spodoptera frugiperda cells with this recombinant virus resulted in the production of E and NS1 proteins that were similar in size to the corresponding viral proteins expressed in dengue virus-infected simian cells. Other dengue virus-encoded proteins such as PreM and C were also synthesized. Rabbits immunized with the dengue virus protein products of the recombinant virus developed antibodies to PreM, E, and NS1, although the titers were low, especially to PreM and E. Nevertheless, the dengue virus antigens produced by the recombinant virus induced resistance in mice to fatal dengue encephalitis.     

Mice immunized with recombinant vaccinia virus expressing dengue 4 virus structural proteins with or without nonstructural protein NS1 are protected against fatal dengue virus encephalitis.

We have constructed vaccinia virus recombinants expressing dengue virus proteins from cloned DNA for use in experimental immunoprophylaxis. A recombinant virus containing a 4.0-kilobase DNA sequence that codes for three structural proteins, capsid (C), premembrane (pre-M), and envelope (E), and for nonstructural proteins NS1 and NS2a produced authentic pre-M, E, and NS1 in infected CV-1 cells. Mice immunized with this recombinant were protected against an intracerebral injection of 100 50% lethal doses of dengue 4 virus. A recombinant containing only genes C, pre-M, and E also induced solid resistance to challenge. Deletion of the putative C-terminal hydrophobic anchor of the E glycoprotein did not result in secretion of E from recombinant-virus-infected cells. Recombinants expressing only the E protein preceded by its own predicted N-terminal hydrophobic signal or by the signal of influenza A virus hemagglutinin or by the N-terminal 71 amino acids of the G glycoprotein of respiratory syncytial virus produced glycosylated E protein products of expected molecular sizes. These vaccinia virus recombinants also protected mice.     

Two nuclear location signals in the influenza virus NS1 nonstructural protein.

The NS1 protein of influenza A virus has been shown to enter and accumulate in the nuclei of virus-infected cells independently of any other influenza viral protein. Therefore, the NS1 protein contains within its polypeptide sequence the information that codes for its nuclear localization. To define the nuclear signal of the NS1 protein, a series of recombinant simian virus 40 vectors that express deletion mutants or fusion proteins was constructed. Analysis of the proteins expressed resulted in identification of two regions of the NS1 protein which affect its cellular location. Nuclear localization signal 1 (NLS1) contains the stretch of basic amino acids Asp-Arg-Leu-Arg-Arg (codons 34 to 38). This sequence is conserved in all NS1 proteins of influenza A viruses, as well as in that of influenza B viruses. NLS2 is defined within the region between amino acids 203 and 237. This domain is present in the NS1 proteins of most influenza A virus strains. NLS1 and NLS2 contain basic amino acids and are similar to previously defined nuclear signal sequences of other proteins.     

Proper maturation of the Japanese encephalitis virus envelope glycoprotein requires cosynthesis with the premembrane protein.

The role of the Japanese encephalitis virus (JEV) premembrane (prM) protein in maturation of the envelope (E) glycoprotein was evaluated by using recombinant vaccinia viruses encoding E in the presence (vP829) or absence (vP658) of prM. Immunofluorescence analyses showed that E appeared to be localized in the endoplasmic reticulum of cells infected with JEV, vP829, or vP658. However, reactivity with monoclonal antibodies and behavior in Triton X-114 indicated that E produced in the absence of prM behaved abnormally. Furthermore, E produced in the presence of prM by recombinant vaccinia viruses could be incorporated into flavivirus pseudotypes, whereas E synthesized in the absence of prM could not. These results demonstrate that cosynthesis of prM is required for proper folding, membrane association, and assembly of the flavivirus E protein.     

The complete sequence of genome segment 8 of bluetongue virus, serotype 1, which encodes the nonstructural protein, NS2.

Bluetongue virus has a ten-segment double-stranded RNA genome, of which segment 8 encodes a nonstructural protein NS2. This protein is the only bluetongue viral protein to be phosphorylated and also has the ability to bind single-stranded RNA. At present, the function of NS2 is unknown and in order to analyse its characteristics in more detail, it was first necessary to obtain a full-length cDNA clone of the genome segment.     

Molecular characterization of the CAN1 locus in Saccharomyces cerevisiae. A transmembrane protein without N-terminal hydrophobic signal sequence

The complete DNA sequence of the CAN1 locus of the yeast Saccharomyces cerevisiae is presented. The predicted primary translation product consists of 590 amino acids. From the hydropathic profile of the amino acid sequence (as calculated by the algorithm of Kyte and Doolittle (Kyte, J., and Doolittle, R. F. (1982) J. Mol. Biol. 157, 105-132)), one can divide the protein into two distinct regions. The 93-amino acid long N-terminal domain is extremely hydrophilic and does not exhibit any cleavable signal sequence. The rest of the protein (from amino acids 94 to 590) shows features typical for an integral membrane protein. The proposal for the N terminus of the primary translation product is based on results obtained by S1 mapping, insertion mutagenesis, and gene fusion experiments.     

Absence of a cleavable signal sequence in Sindbis virus glycoprotein PE2.

Partial NH2-terminal sequence analysis has been performed on some products that result from the translation of 26 S mRNA of Sindbis virus either in vivo or in vitro. In vivo products were obtained after pulse-labeling of virus-infected cells. In vitro products were obtained after cell-free translation either in the absence or presence of microsomal membrane vesicles from dog pancreas. The sequence data indicate that the selective translocation across the microsomal membrane required for a distinct portion of one of the integral viral envelope proteins (PE2) is not accompanied by cleavage of its putative signal sequence. Furthermore, the NH2-terminal sequence of a proteolytic derivative (PE'2) that contains the bulk of PE2 and that is generated after exposure of the microsomal vesicles to proteolytic enzymes is identical to that of intact PE2, strongly suggesting that only a COOH-terminal portion of PE2 is excluded from translocation across the microsomal membrane.     

Expression of influenza virus NS2 nonstructural protein in bacteria and localization of NS2 in infected eucaryotic cells.

The nonstructural NS2 protein of influenza A/PR/8/34 virus was efficiently expressed in bacteria, and monospecific antisera were prepared against the bacterially synthesized polypeptide. These antisera were cross-reactive among the NS2 proteins of various influenza A viruses. However, they did not react with the NS2 of influenza B/Lee/40 virus nor with other proteins of influenza A viruses such as NS1. Antisera against NS2 were used to determine that the NS2 protein is localized in the cell nucleus during influenza virus infection, as shown by immunofluorescence microscopy. Cells infected with simian virus 40 recombinants containing the influenza virus NS gene revealed that both the NS1 and NS2 proteins appeared in the nucleus, even in the absence of expression of other influenza virus-specific components.     

Identification of human hnRNP C1/C2 as a dengue virus NS1-interacting protein

Dengue virus nonstructural protein 1 (NS1) is a key glycoprotein involved in the production of infectious virus and the pathogenesis of dengue diseases. Very little is known how NS1 interacts with host cellular proteins and functions in dengue virus-infected cells. This study aimed at identifying NS1-interacting host cellular proteins in dengue virus-infected cells by employing co-immunoprecipitation, two-dimensional gel electrophoresis, and mass spectrometry. Using lysates of dengue virus-infected human embryonic kidney cells (HEK 293T), immunoprecipitation with an anti-NS1 monoclonal antibody revealed eight isoforms of dengue virus NS1 and a 40-kDa protein, which was subsequently identified by quadrupole time-of-flight tandem mass spectrometry (Q-TOF MS/MS) as human heterogeneous nuclear ribonucleoprotein (hnRNP) C1/C2. Further investigation by co-immunoprecipitation and co-localization confirmed the association of hnRNP C1/C2 and dengue virus NS1 proteins in dengue virus-infected cells. Their interaction may have implications in virus replication and/or cellular responses favorable to survival of the virus in host cells.     

The N-terminal (pre-S2) domain of a hepatitis B virus surface glycoprotein is translocated across membranes by downstream signal sequences.

The coding region for the hepatitis B virus surface antigens contains three in-phase ATG codons which direct the synthesis of three related polypeptides. The 24-kilodalton major surface (or S) glycoprotein is initiated at the most distal ATG and is a transmembrane protein whose translocation across the bilayer is mediated by at least two uncleaved signal sequences. The product of the next upstream ATG is the 31-kilodalton pre-S2 protein, which contains 55 additional amino acids attached to the N terminus of the S protein. This pre-S2-specific domain is translocated into the endoplasmic reticulum. Using a coupled in vitro translation-translocation system, we showed that (i) the pre-S2 domain itself lacks functional signal sequence activity, (ii) its translocation across the endoplasmic reticulum membrane is mediated by downstream signals within the S domain, and (iii) the N-terminal signal sequence of the S protein can translocate upstream protein domains in the absence of other signals. The hepatitis B virus pre-S2 protein is an example of a natural protein which displays upstream domain translocation, a phenomenon whose existence was originally inferred from the behavior of synthetic fusion proteins in vitro.     

Determination of the disulfide bond arrangement of dengue virus NS1 protein

The 12 half-cystines of NS1 proteins are absolutely conserved among flaviviruses, suggesting their importance to the structure and function of these proteins. In the present study, peptides from recombinant Dengue-2 virus NS1 were produced by tryptic digestion in 100% H(2)(16)O, peptic digestion in 50% H(2)(18)O, thermolytic digestion in 50% H(2)(18)O, or combinations of these digestion conditions. Peptides were separated by size exclusion and/or reverse phase high performance liquid chromatography and examined by matrix-assisted laser desorption ionization-time of flight mass spectrometry, matrix-assisted laser desorption ionization post-source decay, and matrix-assisted laser desorption ionization tandem mass spectrometry. Where digests were performed in 50% H(2)(18)O, isotope profiles of peptide ions aided in the identification and characterization of disulfide-linked peptides. It was possible to produce two-chain peptides containing C1/C2, C3/C4, C5/C6, and C7/C12 linkages as revealed by comparison of the peptide masses before and after reduction and by post-source decay analysis. However, the remaining four half-cystines (C8, C9, C10, and C11) were located in a three-chain peptide of which one chain contained adjacent half-cystines (C9 and C10). The linkages of C8/C10 and C9/C11 were determined by tandem mass spectrometry of an in-source decay fragment ion containing C9, C10, and C11. This disulfide bond arrangement provides the basis for further refinement of flavivirus NS1 protein structural models.