Nucleotide sequence and deduced amino acid sequence of the structural proteins of dengue type 2 virus, Jamaica genotype

The nucleotide sequence of the 5'-terminal 2469 bases of dengue 2 (Jamaica genotype) virus has been determined and the encoded proteins compared with those of yellow fever and West Nile viruses, which belong to different flavivirus serogroups. The cDNA clone which was sequenced contains a 5'-noncoding region of 96 nucleotides followed by a single open reading frame coding for the structural proteins 5'-C-prM(M)-E-3' and the beginning of the NS1 nonstructural protein. The amino acid sequence homology between the structural polyprotein precursor of dengue 2 virus and those of yellow fever and West Nile viruses is 36.5 and 42%, respectively. The dengue virus structural proteins are similar in size and composition to those of the other flaviviruses. The basic capsid protein and the membrane and envelope proteins have hydrophobic regions at their C termini. The dengue 2 capsid C, membrane M, and envelope E proteins share 13, 36, and 43% homology, respectively, with the cognate proteins of yellow fever virus, and 33, 32, and 47% homology with the cognate proteins of West Nile virus. All 6 cysteine residues in the dengue 2 premembrane protein and all 12 cysteine residues in the dengue 2 envelope protein are conserved in the cognate proteins of yellow fever and West Nile viruses.     

Nonstructural Protein 1-Specific Immunoglobulin M and G Antibody Capture Enzyme-Linked Immunosorbent Assays in Diagnosis of Flaviviral Infections in Humans

IgM antibody- and IgG antibody-capture enzyme-linked immunosorbent assays (MAC/GAC-ELISAs) targeted at envelope protein (E) of dengue viruses (DENV), West Nile virus, and Japanese encephalitis virus (JEV) are widely used as serodiagnostic tests for presumptive confirmation of viral infection. Antibodies directed against the flavivirus nonstructural protein 1 (NS1) have been proposed as serological markers of natural infections among vaccinated populations. The aim of the current study is to optimize an IgM and IgG antibody-capture ELISA (MAC/GAC-ELISA) to detect anti-NS1 antibodies and compare it with anti-E MAC/GAC-ELISA. Plasmids to express premembrane/envelope (prM/E) or NS1 proteins of six medically important flaviviruses, including dengue viruses (DENV-1 to DENV-4), West Nile virus (WNV), and Japanese encephalitis virus (JEV), were constructed. These plasmids were used for the production of prM/E-containing virus-like particles (VLPs) and secreted NS1 (sNS1) from COS-1 cells. Archived clinical specimens from patients with confirmed DENV, JEV, and WNV infections, along with naive sera, were subjected to NS1-MAC/GAC-ELISAs before or after depletion of anti-prM/E antibodies by preabsorption with or without VLPs. Human serum specimens from previously confirmed DENV infections showed significantly enhanced positive-to-negative (P/N) ratios for NS1-MAC/GAC-ELISAs after the depletion of anti-prM/E antibodies. No statistical differences in sensitivities and specificities were found between the newly developed NS1- and VLP-MAC/GAC-ELISAs. Further application of the assays to WNV- and JEV-infected serum panels showed similar results. A novel approach to perform MAC/GAC-ELISAs for NS1 antibody detection was successfully developed with great potential to differentiate antibodies elicited by the tetravalent chimeric yellow fever-17D/dengue vaccine or DENV infection.     

A single tube RT-PCR assay for the detection of mosquito-borne flaviviruses

Mosquito-borne flaviviruses include several important agents of human disease and have provided striking examples of emerging infections. In this study we present the design and validation of a single tube RT-PCR assay using a pair of consensus primers for the detection of mosquito-borne flaviviruses. Sequencing of the amplicons permits the species identification. The assay was validated using RNA from the yellow fever virus vaccine strain and from representative strains of dengue viruses 1, 2, 3 and 4, West Nile virus, Kunjin virus (a clade of West Nile virus), and St. Louis encephalitis virus.     

Nucleotide and deduced amino acid sequences of genes encoding the structural and nonstructural NS1 proteins of a dengue-2 virus isolated in China

We have determined the nucleotide and encoded amino acid sequences of the capsid, membrane precursor, membrane, envelope, and nonstructural NS1 protein genes of a dengue-2 virus (D2-04) isolated from a patient in Hainan, China. The sequenced region contains a gene organization similar to that of other flaviviruses. The overall amino acid sequence similarity between D2-04 and other dengue-2 viruses is greater than 92%, whereas that between D2-04 and members of the other dengue serotypes is about 65%.The nucleotide sequence data reported in this paper have been deposited in the EMBL database under the following accession numbers: X 65239 for the capsid (C), X 65240 for the envelope (E), X 65241 for the nonstructural (NS1), and X 65242 for the premembrane/membrane (prM/M) protein genes.     

Analyses of mutations selected by passaging a chimeric flavivirus identify mutations that alter infectivity and reveal an interaction between the structural proteins and the nonstructural glycoprotein NS1

We previously described a single-cycle dengue vaccine (RepliVAX D2) engineered from a capsid (C) gene-deleted West Nile virus (WNV) expressing dengue virus serotype 2 (DENV2) prM/E genes in place of the corresponding WNV genes. That work demonstrated that adaptation of RepliVAX D2 to grow in WNV C-expressing cells resulted in acquisition of non-synonymous mutations in the DENV2 prM/E and WNV NS2A/NS3 genes. Here we demonstrate that the prM/E mutations increase the specific infectivity of chimeric virions and the NS2A/NS3 mutations independently enhance packaging. Studies with the NS2A mutant demonstrated that it was unable to produce a larger form of NS1 (NS1'), suggesting that the mutation had been selected to eliminate a ribosomal frame-shift “slippage site” in NS2A. Evaluation of a synonymous mutation at this slippage site confirmed that genomes that failed to make NS1' were packaged more efficiently than WT genomes supporting a role for NS1/NS1' in orchestrating virion assembly.     

Nucleotide sequence of dengue 2 RNA and comparison of the encoded proteins with those of other flaviviruses

We have determined the complete sequence of the RNA of dengue 2 virus (S1 candidate vaccine strain derived from the PR-159 isolate) with the exception of about 15 nucleotides at the 5' end. The genome organization is the same as that deduced earlier for other flaviviruses and the amino acid sequences of the encoded dengue 2 proteins show striking homology to those of other flaviviruses. The overall amino acid sequence similarity between dengue 2 and yellow fever virus is 44.7%, whereas that between dengue 2 and West Nile virus is 50.7%. These viruses represent three different serological subgroups of mosquito-borne flaviviruses. Comparison of the amino acid sequences shows that amino acid sequence homology is not uniformly distributed among the proteins; highest homology is found in some domains of nonstructural protein NS5 and lowest homology in the hydrophobic polypeptides ns2a and 2b. In general the structural proteins are less well conserved than the nonstructural proteins. Hydrophobicity profiles, however, are remarkably similar throughout the translated region. Comparison of the dengue 2 PR-159 sequence to partial sequence data from dengue 4 and another strain of dengue 2 virus reveals amino acid sequence homologies of about 64 and 96%, respectively, in the structural protein region. Thus as a general rule for flaviviruses examined to date, members of different serological subgroups demonstrate 50% or less amino acid sequence homology, members of the same subgroup average 65-75% homology, and strains of the same virus demonstrate greater than 95% amino acid sequence similarity.     

Role of BC loop residues in structure, function and antigenicity of the West Nile virus envelope protein receptor-binding domain III

Site-directed mutagenesis of residues in the BC loop (residues 329-333) of the envelope (E) protein domain III in a West Nile virus (WNV) infectious clone and in plasmids encoding recombinant WNV and dengue type 2 virus domain III proteins demonstrated a critical role for residues in this loop in the function and antigenicity of the E protein. This included a strict requirement for the tyrosine at residue 329 of WNV for virus viability and E domain III folding. The absence of an equivalent residue in this region of yellow fever group viruses and most tick-borne flavivirus suggests there is an evolutionary divergence in the molecular mechanisms of domain III folding employed by different flaviviruses.     

Trafficking mechanism of West Nile (Sarafend) virus structural proteins

Previous studies have shown that West Nile (Sarafend) virus matured by budding at the plasma membrane, which differs from the usual intracellular maturation of other flaviviruses. The present study investigated the trafficking mechanism of the envelope (E) and capsid (C) proteins of West Nile (Sarafend) virus during the replication cycle. The use of time-based double-immunofluorescence labelling coupled with the Triton X-100 extraction procedure revealed that both the E and C proteins were transported from the perinuclear region towards the plasma membrane along the microtubules simultaneously. The strong association of these virus proteins with the microtubules was demonstrated further with Triton X-100 extraction procedure coupled with double immunogold-labelling. Extraction of infected cells with Triton X-100 in high salt also revealed that virus E proteins were associated with the microtubules via protein-protein interaction. The disruption of microtubules with vinblastine sulphate inhibited the trafficking of both the virus E and C proteins. Both virus structural proteins were observed to co-localise and retained within vinblastine sulphate-induced microtubulin paracrystals. Extracellular virus production was also reduced drastically by vinblastine sulphate at non-cytotoxic concentration. Subsequent studies revealed that the transportation of virus E protein was associated with the microtubules-based motor protein, kinesin.     

Amino acid substitution(s) in the stem-anchor region of langat virus envelope protein attenuates mouse neurovirulence.

The identification of variants that are unable to bind membrane receptor preparations (MRPs) has previously been shown to select attenuated yellow fever and Japanese encephalitis viruses. In this study, this methodology has been extended to the tick-borne serocomplex of flaviviruses. Langat (LGT) virus strain TP21 was bound to mouse or human brain MRPs and viruses that escaped binding were isolated and characterized. In addition, variant viruses escaping neutralization by the monoclonal antibody (MAb) 9F9 were also isolated. All of the variant viruses were attenuated for mouse neurovirulence (> or =13-fold). Sequence analysis of the prM/E region of the variant viruses identified mutations within the stem-anchor region of the E protein in variants isolated following incubation with mouse or human brain MRPs at a pH > or = 7.0. The MAb 9F9 variants and MRP variants isolated at pH 5.0, which should induce a conformational shift in the viral E protein, had nearly identical mutations in the prM/M protein immediately N-terminal to the prM/E cleavage site. MAb 9F9 neutralized none of the variant viruses and hemagglutination inhibition assays suggest that the variant virus surface proteins have slightly different conformations compared to the parental virus. These data support previous work indicating that the stem-anchor region of the E protein is important to the surface architecture of the tick-borne flaviviruses. In addition, this study demonstrates that the M protein is at least partially solvent accessible on the virion surface and that the M protein plays a role in maintaining the conformation of the M/E surface complex.     

Computer analysis of antigenic domains and RGD-like sequences (RGWG) in the E glycoprotein of flaviviruses: An approach to vaccine development

Antigenic domains and RGD-like sequences in the E glycoprotein of the flaviviruses Japanese encephalitis virus, yellow fever virus, West Nile virus, dengue type 4 virus, and tick-borne encephalitis virus were analyzed by computer programs that provide information on the physical properties of the polypeptides. The use of computer programs for the development of vaccines based on the synthesis of antigenic peptides is discussed. Synthetic viral peptides are proposed to be used for topical application so as to interfere with the virus-cell interaction. Viral peptides with antigenic epitopes to protect against dengue virus infection without enhancing pathogenesis may also be developed on the basis of the computer analysis.     

Novel anti-dengue monoclonal antibody recognizing conformational structure of the prM-E heterodimeric complex of dengue virus

An interaction between the premembrane (prM) and envelope (E) glycoproteins as prM-E heterodimer is required for proper folding and transport of E during the formation and release of new flaviviral progeny. More evidence, however, is needed to confirm this interaction of prM and E during dengue virus replication. In this study, 2E11, a mouse monoclonal antibody (Mab) that specifically recognizes dengue prM-E heterodimeric complex in either intracellular or secreted dengue virions, was generated and characterized. In immunofluorescence and immuno-pull down assays, the Mab 2E11 recognized an epitope present in 293T transfectants that co-expressed prM and the full-length form of E in cis and in trans, but it failed to react with prM or E protein expressed individually. The reactivity of Mab 2E11 was diminished in transfected cells that co-express prM together with a truncated form of E lacking the 84-residue stretch at the C-terminal transmembrane region, presumably essential for prM and E interaction. The Mab 2E11 described in this study is a novel Mab with a unique capability in detecting the conformational structure of prM-E heterodimeric complex of dengue virus. It will be a new biological tool for identification and characterization of dengue prM-E heterodimer as well as virus maturation and export.     

Sequence of the dengue-1 virus genome in the region encoding the three structural proteins and the major nonstructural protein NS1

Sequence results are presented for a 3745-nucleotide region at the 5' end of the dengue type-1 virus (DEN-1) genome. The strain characterized is a Western Pacific isolate from Nauru Island. The sequenced region contains the beginning of a continuous open reading frame which specifies the capsid (C), membrane (M), and envelope (E) structural proteins and the nonstructural protein NS1. The sequences are compared with corresponding segments for seven other flaviviruses, including two of the three remaining dengue serotypes, DEN-2 and DEN-4. The results show the DEN-1 genome size and organization to be similar to those of other characterized flaviviruses and that major features of the individual proteins are conserved. It is of special interest that comparisons of the E glycoprotein sequences between the dengue serotypes (DEN-1, -2, -4) reveal only moderately greater sequence relatedness (63-68%) than occurs in comparisons of DEN-1 with five other flaviviruses (46-54%). For the other structural proteins, C and M, the relatedness values are 59-74% for comparisons between DEN-1 and the other dengue serotypes and 31-45% for comparisons between DEN-1 and the five other flaviviruses.     

DNA microarray technique for detection and identification of seven flaviviruses pathogenic for man

A flavivirus microarray was developed for detection and identification of yellow fever (YF), West Nile, Japanese encephalitis (JE), and the dengue 1-4 viruses, which are causing severe human disease all over the world. The microarray was based on 500-nucleotide probe fragments from five different parts of the seven viral genomes. A low-stringent amplification method targeting the corresponding regions of the viral genomic RNA was developed and combined with hybridization to the microarray for detection and identification. For distinction of the generated virus-specific fluorescence-patterns a fitting analysis procedure was adapted. The method was verified as functional for all seven flaviviruses and the strategy for the amplification, combined with the long probes, provided a high tolerance for smaller genetic variability, most suitable for these rapidly changing RNA viruses. A potentially high detection and identification capacity was proven on diverged strains of West Nile and dengue viruses. The lower limit for detection was equivalent, or better, when compared to routinely used RT-PCR methods. The performance of the method was verified on human patient samples containing dengue viruses, or normal human serum spiked with YF or JE viruses. The results demonstrated the ability of the flavivirus microarray to screen simultaneously a sample for several viruses in parallel, in combination with a good lower limit of detection.     

Use of a recombinant envelope protein subunit antigen for specific serological diagnosis of West Nile virus infection

Serological diagnosis of West Nile virus (WNV) infection is complicated by extensive antigenic cross-reactivity with other closely related flaviviruses, such as St. Louis encephalitis virus. Here we describe a recombinant, bacterially expressed antigen equivalent to structural domain III of the WNV envelope protein that has allowed clear discrimination of antibody responses to WNV from those against other related flaviviruses in indirect enzyme-linked immunosorbent assays using standardized control antisera and field-collected samples.     

DNA probe array for the simultaneous identification of herpesviruses, enteroviruses, and flaviviruses

Viral infections of the central nervous system (CNS) are caused by a variety of viruses, namely, herpesviruses, enteroviruses, and flaviviruses. The similar clinical signs provoked by these viruses make the diagnosis difficult. We report on the simultaneous detection of these major CNS pathogens using amplification by PCR and detection of amplified products using DNA microarray technology. Consensus primers were used for the amplification of all members of each genus. Sequences specific for the identification of each virus species were selected from the sequence alignments of each target gene and were synthesized on a high-density microarray. The amplified products were pooled, labeled, and cleaved, followed by hybridization on a single array. This method was successfully used to identify herpesviruses, namely, herpes simplex virus type 1 (HSV-1), HSV-2, and cytomegalovirus; all serotypes of human enteroviruses; and five flaviviruses (West Nile virus, dengue viruses, and Langat virus). This approach, which used highly conserved consensus primers for amplification and specific sequences for identification, would be extremely useful for the detection of variants and would probably help solve some unexplained cases of encephalitis. The analytical sensitivity of the method was shown to be 500 genome equivalents ml(-1) for HSV-1, 0.3 50% tissue culture infectious doses (TCID50s) ml(-1) for the enterovirus coxsackievirus A9, and 200 TCID50s ml(-1) for West Nile virus. The clinical sensitivity of this method must now be evaluated.     

Four human diseases with significant public health impact caused by mosquito-borne flaviviruses: West Nile,Zika, dengue and yellow fever

In this review we will discuss the epidemiology, clinical characteristics, diagnostic tests, pathologic features, treatment and disease prevention strategies for four mosquito-borne flaviviruses. West Nile and Zika viruses, once thought to be restricted geographically, emerged on the American continent in the first part of the 21st century. They have been constantly in the lay press and have caused a heightened awareness of emerging infections by the public, particularly given the manifestation of microcephaly in congenital Zika syndrome. Yellow fever and dengue viruses, with mosquito vectors similar to West Nile and Zika viruses, are endemic in many tropical areas of the world and produce frequent outbreaks. The global distribution of yellow fever and dengue viruses could also change and has great potential to do so. Factors that could contribute to reemergence of the diseases in areas of the world where they are currently only seen in travelers, include the presence of yellow fever and dengue virus vectors in temperate climates and growing urbanization. These two factors increase potential contact between vectors and naïve human hosts, thus could result in reemergence of yellow fever or dengue virus infections.     

Single rapid TaqMan fluorogenic probe based PCR assay that detects all four dengue serotypes

Public health laboratories require rapid diagnosis of dengue outbreaks for application of measures such as vector control. We have developed a rapid single fluorogenic probe-based polymerase chain reaction assay for the detection of all four dengue serotypes (FUDRT-PCR). The method employs primers and probe that are complementary to the evolutionarily conserved 3' untranslated region of the dengue genome. The assay detected viral RNA of strains of all four dengue serotypes but not of the flaviviruses Japanese encephalitis virus, Murray Valley encephalitis virus, Kunjin, Stratford, West Nile, Alfuy or Yellow fever. When compared to an existing nested-PCR assay for the detection of dengue on clinical samples, FUDRT-PCR detected dengue 1 (100%, n=14), dengue 2 (85%, n=13), dengue 3 (64%, n=14) and dengue 4 (100%, n=3) with the indicated sensitivities. FUDRT-PCR enables diagnosis of acute dengue infection in four hours from sample receipt. In addition, a single-test procedure should result in a reduction in the number of tests performed with considerable cost savings for diagnostic laboratories.     

Comparison of a dengue-2 virus and its candidate vaccine derivative: sequence relationships with the flaviviruses and other viruses.

A comparison of the sequence of the dengue-2 16681 virus with that of the candidate vaccine strain (16681-PDK53) derived from it identified 53 of the 10,723 nucleotides which differed between the strains. Nucleotide changes occurred in genes coding for all virion and nonvirion proteins, and in the 5' and 3' untranslated regions. Twenty-seven of the nucleotide changes resulted in amino acid alterations. The greatest amino acid sequence differences in the virion proteins occurred in prM (2.20%; 2/91 amino acids) followed by the M protein (1.33%; 1/75 amino acids), the C protein (0.88%; 1/114 amino acid), and the E protein (0.61%; 3/495 amino acids). Differences in the amino acid sequence of nonvirion proteins ranged from 1.51% (6/398 amino acids) in NS4 to 0.33% (3/900 amino acids) in NS5. The encoded protein sequences of 16681-PDK53 were also compared with the published sequences of other flaviviruses to obtain a detailed classification of 17 flaviviruses using the neighbor-joining tree method. The analyses of the sequence data produced dendrograms which supported the traditional groupings based on serological evidence, and they suggested that the flaviviruses have evolved by divergent mutational change and there was no evidence of genetic recombination between members of the group. Comparisons of the sequences of the flavivirus polymerase and helicase-like proteins (NS5 and NS3, respectively) with those from other viruses yielded a classification of the flaviviruses indicating that the primary division of the flaviviruses was between those transmitted by mosquitoes and those transmitted by ticks.     

登革Ⅰ型病毒E蛋白在293T细胞中的分泌表达

目的 分泌表达登革Ⅰ型病毒prM/E基因,为研究该蛋白的免疫学功能和特性奠定基础.方法 用RT-PCR法获得登革Ⅰ型病毒广州分离株全长prM/E基因,在prM基因前添加乙型脑炎病毒的信号肽或同时替换E基因羧基末端的20%为乙脑病毒E基因相应的部分,分别将其克隆入真核表达载体pcDNAS/FRT中,获得三种重组质粒DlprME-pc5,D1JsprME-pc5,D1JsprM80E20JE-pc5.用脂质体法分别将重组质粒DNA转入293T细胞,通过免疫荧光、Western印迹检测外源基因在真核细胞中的分泌表达.结果 用免疫荧光法检测到分别转染了三种重组质粒的293T细胞的胞质中均有登革Ⅰ型病毒蛋白的表达.Western印迹检测转染了D1prME-pc5重组质粒的293T细胞上清中没有特异蛋白条带,转染了经基因改造的重组质粒D1JsprME-pc5和D1JsprM80E20JE-pc5的细胞上清中均存在登革Ⅰ型病毒的特异蛋白条带.结论 转染了三种重组质粒的293T细胞均可表达登革Ⅰ型病毒prM/E蛋白,只有在prM基因前添加了信号肽的重组质粒转染后蛋白才获得分泌表达.