In vitro processing of dengue virus structural proteins: cleavage of the pre-membrane protein

Dengue virus premembrane and membrane proteins elicit a protective immune response

We have constructed recombinant vaccinia viruses that express the premembrane (pre-M), membrane (M), or the cleaved, residual portion of pre-M (non-M) proteins of dengue 4 virus, or the pre-M, non-M, or envelope (E) proteins of dengue 2 virus, to evaluate their ability to induce protective immunity in mice. Cells infected with these recombinants make proteins of expected size. Mice immunized with recombinants expressing dengue 4 pre-M or M were protected against subsequent dengue 4 encephalitis challenge, but non-M was not protective. However, a recombinant that expressed both pre-M and E as a polyprotein gave solid protection, while the simultaneous administration of the two recombinants expressing pre-M and E gave a significant level of protection. Pre-M and M function as antigens eliciting a protective immune response, and the combination of pre-M plus E is more protective than E alone.

Processing of the yellow fever virus nonstructural polyprotein: a catalytically active NS3 proteinase domain and NS2B are required for cleavages at dibasic sites

The vaccinia virus-T7 transient expression system was used to further examine the role of the NS3 proteinase in processing of the yellow fever (YF) virus nonstructural polyprotein in BHK cells. YF virus-specific polyproteins and cleavage products were identified by immunoprecipitation with region-specific antisera, by size, and by comparison with authentic YF virus polypeptides. A YF virus polyprotein initiating with a signal sequence derived from the E protein fused to the N terminus of NS2A and extending through the N-terminal 356 amino acids of NS5 exhibited processing at the 2A-2B, 2B-3, 3-4A, 4A-4B, and 4B-5 cleavage sites. Similar results were obtained with polyproteins whose N termini began within NS2A (position 110) or with NS2B. When the NS3 proteinase domain was inactivated by replacing the proposed catalytic Ser-138 with Ala, processing at all sites was abolished. The results suggest that an active NS3 proteinase domain is necessary for cleavage at the diabasic nonstructural cleavage sites and that cleavage at the proposed 4A-4B signalase site requires prior cleavage at the 4B-5 site. Cleavages were not observed with a polyprotein whose N terminus began with NS3, but cleavage at the 4B-5 site could be restored by supplying the the NS2B protein in trans. Several experimental results suggested that trans cleavage at the 4B-5 site requires association of NS2B and the NS3 proteinase domain. Coexpression of different proteinases and catalytically inactive polyprotein substrates revealed that trans cleavage at the 2B-3 and 4B-5 sites was relatively efficient when compared with trans cleavage at the 2A-2B and 3-4A sites.

Flavivirus enzyme-substrate interactions studied with chimeric proteinases: identification of an intragenic locus important for substrate recognition

The proteins of flaviviruses are translated as a single long polyprotein which is co- and posttranslationally processed by both cellular and viral proteinases. We have studied the processing of flavivirus polyproteins in vitro by a viral proteinase located within protein NS3 that cleaves at least three sites within the nonstructural region of the polyprotein, acting primarily autocatalytically. Recombinant polyproteins in which part of the polyprotein is derived from yellow fever virus and part from dengue virus were used. We found that polyproteins containing the yellow fever virus cleavage sites were processed efficiently by the yellow fever virus enzyme, by the dengue virus enzyme, and by various chimeric enzymes. In contrast, dengue virus cleavage sites were cleaved inefficiently by the dengue virus enzyme and not at all by the yellow fever virus enzyme. Studies with chimeric proteinases and with site-directed mutants provided evidence for a direct interaction between the cleavage sites and the proposed substrate-binding pocket of the enzyme. We also found that the efficiency and order of processing could be altered by site-directed mutagenesis of the proposed substrate-binding pocket.

Gene mapping of the putative structural region of the hepatitis C virus genome by in vitro processing analysis

Processing of the putative structural proteins of hepatitis C virus was examined by using an in vitro expression system. An RNA transcript for cell-free translation was prepared from a cDNA construct that encompasses the region encoding the 980 amino-terminal residues of the viral polyprotein precursor. Processing of the in vitro translation product proceeded cotranslationally in the presence of microsomal membranes and generated four major membrane-associated products. Two of these four major products, named gp35 and gp70, were shown to be transported into microsomes and heavily glycosylated, suggesting that the processing events are partly mediated by the signal peptidase of the endoplasmic reticulum. The other two products, p19 and p21, were probably associated with the outer surface of the microsomal membrane. Analysis of processed proteins translated from a series of truncated forms of the cDNA construct as well as determination of amino-terminal amino acid sequences of gp35 and gp70 indicated that these four products are arranged from the amino-terminal end of the polyprotein precursor in the order: NH2-p22-gp35-gp70-p19. Both gp35 and gp70 could be candidates of initially processed forms of envelope proteins of the hepatitis C virus.

Infectious RNA transcribed from stably cloned full-length cDNA of dengue type 4 virus

Dengue virus is an enveloped positive-strand RNA virus with a genome approximately 11 kilobases in length. The four serotypes of dengue virus are currently the most important members of the flavivirus family in terms of geographical distribution and the incidence of infection in humans. In this communication we describe successful cloning of a stable full-length cDNA copy of dengue type 4 virus that can be used as the template for in vitro transcription of infectious RNA. Evidence is presented that dengue virus recovered from permissive cells transfected with the in vitro RNA transcripts retained a mutation that was engineered into full-length cDNA. The properties of the virus produced by cells transfected with infectious RNA transcripts of dengue cDNA resembled those of the virus from which the cDNA clone was derived. The dengue virus recombinant DNA system should prove helpful in gaining a better understanding of the molecular biology of dengue viruses and should facilitate the development of a safe and effective live vaccine for use in humans.

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.

The sensitivity of cell-associated dengue virus proteins to trypsin and the detection of trypsin-resistant fragments of the nonstructural glycoprotein NS1

Extracts of Vero cells infected with dengue virus type 2 were digested by trypsin in the presence and absence of detergents. The experiments were designed to test the models proposed for flavivirus translation in which the glycoproteins prM, E, and NS1 are inserted into the endoplasmic reticulum of the cell, whereas certain other nonstructural proteins are not. Viral polypeptides were detected by the use of radiolabel, by immunoprecipitation, or by immunoblotting. The results obtained for NS3 and NS5 were as predicted by the models, with membranes providing no protection against digestion by trypsin. Similarly, the results obtained for prM and E were consistent with the models, with membranes protecting against proteolysis. Some molecules of NS1 were protected, while others were sensitive to proteolysis; novel trypsin-resistant fragments of 69,000, 60,000, and 50,000 Mr (all heat-labile), and of 37,000 and 24,000 Mr were detected following treatment of cell extracts with various combinations of trypsin, detergent, and reducing agent. Preliminary experiments suggested that these tryptic fragments are potentially useful in mapping the antigenic epitopes of NS1.

The dengue viruses

Dengue, a major public health problem throughout subtropical and tropical regions, is an acute infectious disease characterized by biphasic fever, headache, pain in various parts of the body, prostration, rash, lymphadenopathy, and leukopenia. In more severe or complicated dengue, patients present with a severe febrile illness characterized by abnormalities of hemostasis and increased vascular permeability, which in some instances results in a hypovolemic shock. Four distinct serotypes of the dengue virus (dengue-1, dengue-2, dengue-3, and dengue-4) exist, with numerous virus strains found worldwide. Molecular cloning methods have led to a greater understanding of the structure of the RNA genome and definition of virus-specific structural and nonstructural proteins. Progress towards producing safe, effective dengue virus vaccines, a goal for over 45 years, has been made.

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.

Expression of the structural proteins of dengue 2 virus and yellow fever virus by recombinant vaccinia viruses

Vaccinia virus recombinants were constructed which contained cDNA sequences encoding the structural region of dengue 2 virus (PR159/S1 strain) or yellow fever virus (17D strain). The flavivirus cDNA sequences were expressed under the control of the vaccinia 7.5k early/late promotor. Cultured cells infected with these recombinants expressed immunologically reactive flavivirus structural proteins, precursor prM and E. These proteins appeared to be cleaved and glycosylated properly since they comigrated with the authentic proteins from dengue 2 virus- and yellow fever virus-infected cells. Mice immunized with the dengue/vaccinia recombinant showed a dengue-specific immune response that included low levels of neutralizing antibodies. Immunization of mice with the yellow fever/vaccinia recombinant was less effective at inducing an immune response to yellow fever virus and in only some of the mice were low titers of neutralizing antibodies produced.

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)