Comparison of dengue viruses and some other flaviviruses by cDNA-RNA hybridization analysis and detection of a close relationship between dengue virus serotype 2 and Edge Hill virus

Analysis of cell-associated DENV RNA by oligo(dT) primed 5' capture scRNAseq

Dengue is one of the most widespread vector-borne viral diseases in the world. However, the size, heterogeneity, and temporal dynamics of the cell-associated viral reservoir during acute dengue virus (DENV) infection remains unclear. In this study, we analyzed cells infected in vitro with DENV and PBMC from an individual experiencing a natural DENV infection utilizing 5’ capture single cell RNA sequencing (scRNAseq). Both positive- and negative-sense DENV RNA was detected in reactions containing either an oligo(dT) primer alone, or in reactions supplemented with a DENV-specific primer. The addition of a DENV-specific primer did not increase the total amount of DENV RNA captured or the fraction of cells identified as containing DENV RNA. However, inclusion of a DENV-specific cDNA primer did increase the viral genome coverage immediately 5’ to the primer binding site. Furthermore, while the majority of intracellular DENV sequence captured in this analysis mapped to the 5’ end of the viral genome, distinct patterns of enhanced coverage within the DENV polyprotein coding region were observed. The 5’ capture scRNAseq analysis of PBMC not only recapitulated previously published reports by detecting virally infected memory and naïve B cells, but also identified cell-associated genomic variants not observed in contemporaneous serum samples. These results demonstrate that oligo(dT) primed 5’ capture scRNAseq can detect DENV RNA and quantify virus-infected cells in physiologically relevant conditions, and provides insight into viral sequence variability within infected cells.

Molecular phylogeny of edge hill virus supports its position in the yellow Fever virus group and identifies a new genetic variant

Edge Hill virus (EHV) is a mosquito-borne flavivirus isolated throughout Australia during mosquito surveillance programs. While not posing an immediate threat to the human population, EHV is a taxonomically interesting flavivirus since it remains the only member of the yellow fever virus (YFV) sub-group to be detected within Australia. Here we present both an antigenic and genetic investigation of collected isolates, and confirm taxonomic classification of the virus within the YFV-group. Isolates were not clustered based on geographical origin or time of isolation, suggesting that minimal genetic evolution of EHV has occurred over geographic distance or time within the EHV cluster. However, two isolates showed significant differences in antigenic reactivity patterns, and had a much larger divergence from the EHV prototype (19% nucleotide and 6% amino acid divergence), indicating a distinct subtype or variant within the EHV subgroup.

Genetic diversity of the E protein of dengue type 3 virus

Background

Dengue is the most important arbovirus disease in tropical and subtropical countries. The viral envelope (E) protein is responsible for cell receptor binding and is the main target of neutralizing antibodies. The aim of this study was to analyze the diversity of the E protein gene of DENV-3. E protein gene sequences of 20 new viruses isolated in Ribeirao Preto, Brazil, and 427 sequences retrieved from GenBank were aligned for diversity and phylogenetic analysis.

Results

Comparison of the E protein gene sequences revealed the presence of 47 variable sites distributed in the protein; most of those amino acids changes are located on the viral surface. The phylogenetic analysis showed the distribution of DENV-3 in four genotypes. Genotypes I, II and III revealed internal groups that we have called lineages and sub-lineages. All amino acids that characterize a group (genotype, lineage, or sub-lineage) are located in the 47 variable sites of the E protein.

Conclusion

Our results provide information about the most frequent amino acid changes and diversity of the E protein of DENV-3.

Molecular epidemiology of dengue viruses in Brazil

Dengue viruses (DEN) are found as four antigenically distinct serotypes designated DEN-1, 2, 3, and 4. Laboratory evidence that strain-intratypical variation occurs among DEN viruses has been demonstrated since the 1970s, although only with the advances in molecular technologies has it been possible to determine the genetic variability of each serotype. Genotypical identification has proven to be a useful tool for determining the origin and spread of epidemics and to correlate virulence of strains. In this report we present the results of molecular epidemiological studies with the DEN-1 and DEN-2 viruses that caused dengue epidemics in Brazil during the last decade.

Detection of the disease severity-related molecular differences among new Thai dengue-2 isolates in 1993, based on their structural proteins and major non-structural protein NS1 sequences

We determined the nucleotide sequences of the whole structural protein gene of four new dengue-2 viruses by the primer extension dideoxy chain termination method, using multiple cDNA clones for six overlapping gene regions. The nucleotide sequences of the major non-structural protein NS1 gene of these viruses were also determined by direct sequencing of the reverse-transcription polymerase chain reaction products. These viruses were isolated from dengue patients with different clinical severities in Nakhon Phanom, Northeastern Thailand in 1993. The results were compared with the sequences of prototype New Guinea C strain and other reference strains. All four viruses revealed highest homology to New Guinea C strain. The homology between each of the four strains and New Guinea C strain varies from 95.09% to 95.29% in its nucleotide sequences, and from 97.24% to 97.78% in its amino acid sequences covering all structural proteins and NS1 protein. The PreM region shows the highest divergence (6.59% to 7.32%) in its nucleotide sequence, whereas C protein is most highly conserved (only 1.75% to 2.63% divergence). Our data showed that there are certain molecular differences in the genomic structure of these four new isolates, which indicate the possibility that these changes are related with the virulence of the virus strains.

Sequences of E/NS1 gene junction from four dengue-2 viruses of northeastern Thailand and their evolutionary relationships with other dengue-2 viruses

We determined the 240-nucleotide sequences of the E/NS1 gene junction of four dengue-2 viruses by the primer extension dideoxy chain termination method. These viruses were isolated from dengue patients with different clinical severities in Nakhon Phanom, Northeastern Thailand in 1993. The results were compared with the 52 published dengue-2 sequences of the same gene region. Sequence divergence of four new isolates varied from 4.17% to 5.42% compared with dengue-2 prototype New Guinea C strain whereas it varied from 5.42% to 6.67% and from 6.67% to 7.09% when compared with Jamaica 1409 strain and PR159/S1 strain, respectively. All nucleotide substitutions were found at the 3rd position of the codons which were silent mutations. All 56 isolates studied were classified into five genotypic groups by constructing the dendrogram. The results indicated that four new isolates from Northeastern Thailand belong to genotype II of dengue virus serotype 2, and were most closely related to prototype New Guinea C strain. We also observed the variation in nucleotide and amino acid sequences among clusters of isolates (Thailand-1980, Malaysia-1989 and Thailand-1993) which were obtained from the dengue patients with different clinical severities. The significance of these genetic differences have been discussed in terms of the possible correlation between genetic variability and virulence.

Molecular epidemiology and evolution of mosquito-borne flaviviruses and alphaviruses enzootic in Australia

Three distinct patterns in the molecular epidemiology and evolution are evident among the alphaviruses and flaviviruses enzootic in Australia. One pattern, exemplified by MVE and KUN viruses, is of a single genetic type evolving slowly and uniformly in geographically widely separated regions of Australia with no evidence of independent divergence. The second pattern, exemplified by RR virus, is of separate genotypes evolving in different geographic regions with significant nucleotide divergence between genotypes. The third pattern, exemplified by SIN virus, is of a succession of temporally related genotypes that extend over most of the Australian continent, with relatively low levels of nucleotide divergence within a genotype, and which are each replaced by the subsequent genotype. These patterns are associated in part due to the nature and dispersal of their vertebrate hosts. Nucleotide divergence rates for Australian alphaviruses are similar to those reported elsewhere. Genomic relationships between Australian flavivirus members of the JE virus serological complex and between Australian alphaviruses are discussed, and evidence is presented for a possible new genomic lineage of SIN virus.

Dengue: the risk to developed and developing countries

Dengue viruses are members of the Flaviviridae, transmitted principally in a cycle involving humans and mosquito vectors. In the last 20 years the incidence of dengue fever epidemics has increased and hyperendemic transmission has been established over a geographically expanding area. A severe form, dengue hemorrhagic fever (DHF), is an immunopathologic disease occurring in persons who experience sequential dengue infections. The risk of sequential infections, and consequently the incidence of DHF, has risen dramatically, first in Asia and now in the Americas. At the root of the emergence of dengue as a major health problem are changes in human demography and behavior, leading to unchecked populations of and increased exposure to the principal domestic mosquito vector, Aedes aegypti. Virus-specified factors also influence the epidemiology of dengue. Speculations on future events in the epidemiology, evolution, and biological expression of dengue are presented.

Geographical clusters of dengue virus type 2 isolates based on analysis of infected cell RNA by the chemical cleavage at mismatch method

Genetic variation in 12 strains of dengue virus type 2, isolated from several epidemic areas in different years, was studied by chemical cleavage at mismatched cytosine in DNA:RNA heteroduplexes. End-labelled cDNA probes derived from the E and NS2A genes of the New Guinea C strain were hybridized to total RNA extracted from cells infected by individual isolates. Following modification of mismatched cytosine by hydroxylamine and nucleic acid strand cleavage by piperidine, the resulting fragments of radiolabelled probe were analysed by electrophoresis and autoradiography. The patterns of bands generated corresponded to the geographical groupings of the isolates. Thus this method is suitable in epidemiological studies for rapidly surveying a large number of isolates for genetic variation in a particular gene of interest.

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.

NS 1 gene sequences from eight dengue-2 viruses and their evolutionary relationships with other dengue-2 viruses

The nucleotide sequences of the NS 1 genes from five Thai and three Sri Lankan dengue-2 viruses were determined by sequencing the viral RNA using synthetic oligonucleotide primers. The results were shown to be similar to four published dengue-2 NS 1 sequences and the classification of these genes was compared with the one obtained for the envelope genes of the same viruses. The classification was similar and showed that the Thai isolates could be divided into two separate groups and that the Sri Lankan isolates were distinct. We found no correlation between disease severity, serological response (1 degree or 2 degrees), or year of isolation and various aspects of NS 1 protein sequence variation; and no particular amino acid changes were correlated with virulence. The sequences were combined with those published and classified elsewhere to provide a comprehensive E/NS 1 gene taxonomy of dengue-2 virus isolates.

Variation of the nucleotide and encoded amino acid sequences of the envelope gene from eight dengue-2 viruses

The nucleotide sequences of the envelope genes from five Thai and three Sri Lankan dengue-2 viruses were determined by sequencing the viral RNA using synthetic oligonucleotide primers. The results were compared with the four published dengue-2 envelope sequences to obtain a classification of these viruses, which showed that the Thai isolates could be divided into two separate groups while the Sri Lankan isolates were distinct. There was no correlation between disease severity and envelope protein sequence, or between year of isolation and sequence. No particular amino acid changes were associated with virulence or a change in hydrophilic region which could perhaps act as an epitope.

Isolation and characterization of dengue viruses serotype 1 from an epidemic in northern Queensland, Australia

Thirteen strains of dengue type 1 were isolated from the lymphocyte fractions of 69 acute phase blood samples collected at Thursday Island Hospital during 1981 and 1982. One further strain of type 1 was isolated from 7 blood samples despatched by air from Cairns Base Hospital during 1982. Four of these Australian isolates representing the beginning, middle, and end of the epidemic were examined by restriction enzyme mapping and were found to be identical for the nine restriction enzymes used. The maps differed from those derived from two Malaysian dengue type 1 strains isolated during the epidemic of 1981-82 in that country. This suggests reliance on serological typing to establish global circulation patterns of epidemic dengue is insufficient and that more specific methods such as genome mapping are useful.

Nucleotide sequence comparisons of turnip yellow mosaic virus isolates from Australia and Europe

The genomic sequences of four isolates of turnip yellow mosaic virus (TYMV-Cd) from Australia, and three TYMV-1 (type) and three TYMV-2 (cauliflower) isolates from Europe were compared by cDNA-RNA hybridization tests, by analysis of the fragments produced from cDNA-RNA hybrids by restriction endonuclease treatment, and by determining the 3' terminal nucleotide sequences of their coat protein mRNAs. All three methods showed only slight differences (ca. 1%) between the mRNA sequences of different TYMV-1 and TYMV-Cd isolates, and did not distinguish between those groups of isolates. By contrast, the nucleotide sequences of TYMV-2 isolates differed from those of the other TYMVs by ca. 5% (sequence analysis) to 11% (restriction fragment analysis). Published biogeographic evidence has indicated that the TYMV-Cd and TYMV-1 populations probably separated more than 12,000 years ago. This implies that these TYMV genomes have changed at a rate of, at most, 1% in 10,000 years.

An enzyme immunoassay to detect Australian flaviviruses and identify the encephalitic subgroup using monoclonal antibodies

An antigen-capture enzyme-linked immunosorbent assay (ELISA) has been developed to detect antigens of Australian flaviviruses in mosquito pools, suckling mouse brain and infected cell culture supernatant fluid. A monoclonal antibody reactive to an epitope on the envelope glycoprotein common to all flaviviruses was used as the capture antibody. Purified rabbit IgG, produced against Murray Valley encephalitis (MVE) virus, which reacted with eight Australian flaviviruses in haemagglutination inhibition (HI) and in an indirect fluorescent antibody test, was used as the indicator antibody in direct and indirect antigen-capture ELISA. A monoclonal antibody specific for a subgroup of encephalitic flaviviruses was conjugated to horseradish peroxidase and used as the indicator antibody to distinguish MVE, Kunjin and Alfuy viruses from the remainder tested. This ELISA could detect viral antigen in mosquito cell culture fluids and suckling mouse brain preparations at titres as low as 1000 TCID50/100 microliters. Viral antigen in a single mosquito infected with MVE could be detected in a pool of 500.

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.

Partial sequence analysis of cloned dengue virus type 2 genome

Dengue virus (DEN) is a member of flaviviruses and contains a single, (+)-strand RNA of approx. 11 kb. Complementary DNA copy of the RNA was synthesized using reverse transcriptase and oligo(dT) as primer. The double-stranded DNA copy was cloned at the PstI site of pUC13'-1 vector and was used to transform Escherichia coli JM83. Eleven transfomants were found to contain DEN insert as screened by colony hybridization. Three clones were chosen for further characterization by nucleotide (nt), sequence analysis. Two of these clones overlapped by 470 bp. Sequences of these three clones totalling about 4.6 kb were obtained. Translation of this DNA in all possible reading frames revealed the presence of long open reading frames spanning the entire length of the cDNA clones. The putative polypeptides derived from the nt sequence are 885 and 643 amino acids in length and show homology to the region of polyprotein coded by the yellow fever virus genome corresponding to the non-structural proteins [Rice et al., Science 229 (1985) 726-733]. The significant homology between these two viruses in the regions coding for the non-structural proteins NS3 and NS5 suggests an important role for these two proteins in the life cycle of these viruses.

Analysis of Ross River virus genomic RNA using HaeIII digests of single-stranded cDNA to infected-cell RNA and virion RNA

To study genetic relationships between isolates of Ross River virus (RRV), an alphavirus with a chromosome of approximately 12,000 nucleotides, total high-molecular-weight RNA from RRV-infected baby hamster kidney (BHK) cells was transcribed into 32P-labeled, complementary DNA using reverse transcriptase and random calf-thymus DNA primers. The cDNA was digested with HaeIII or TaqI (restriction nucleases which cleave single-stranded DNA), and the restriction fragments separated on a standard DNA sequencing gel. The resulting HaeIII or TaqI restriction digest profiles mainly comprised virus-specific bands; cell RNAs were transcribed poorly. In reconstruction experiments, purified 49 S RRV genomic RNA and a 10-fold mass excess of mock-infected-cell RNA were reverse transcribed in the same reaction mix. Under these conditions there was no interference with the transcription of viral RNA sequences. When the level of viral RNA was lowered to one-hundredth that of cell RNA in the reaction mix, there was no qualitative change in restriction digest profiles. The procedure is rapid, simple, uses small amounts of 32P, does not require purification of virus or viral RNA, and permits cross-comparison between several virus strains on a single one-dimensional gel. The method should be applicable to other single-stranded RNA viruses of moderate genome complexity.