Comparative Analysis of Full-Length Genomic Sequences of 10 Dengue Serotype 1 Viruses Associated with Different Genotypes, Epidemics, and Disease Severity Isolated in Thailand over 22 Years

Tang, Yuxin; Rodpradit, Prinyada; Chinnawirotpisan, Piyawan; Mammen, Mammen P.; Tao, Lei; Lynch, Julia; Putnak, Robert; Zhang, Chunlin

doi:10.4269/ajtmh.2010.10-0052

Cited by 17 publications

(14 citation statements)

References 59 publications

(66 reference statements)

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“…These studies suggested adaptive evolution of DENV in natural populations but indicated that the adaptive selection pressures differ among serotypes, genotypes and the encoded proteins of the virus. Furthermore, fixation of beneficial mutations may lead to virus evolution with altered antigenicity, virulence, or tissue tropism; and eventually influence disease patterns and transmission [17]. Similarly, genetic recombination is also a significant factor in diversity of DENV in natural populations [18].…”

Section: Introductionmentioning

confidence: 99%

Nucleotide substitutions in dengue virus serotypes from Asian and American countries: insights into intracodon recombination and purifying selection

Behura

Severson

2013

BMC Microbiol

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BackgroundDengue virus (DENV) infection represents a significant public health problem in many subtropical and tropical countries. Although genetically closely related, the four serotypes of DENV differ in antigenicity for which cross protection among serotypes is limited. It is also believed that both multi-serotype infection as well as the evolution of viral antigenicity may have confounding effects in increased dengue epidemics. Numerous studies have been performed that investigated genetic diversity of DENV, but the precise mechanism(s) of dengue virus evolution are not well understood.ResultsWe investigated genome-wide genetic diversity and nucleotide substitution patterns in the four serotypes among samples collected from different countries in Asia and Central and South America and sequenced as part of the Genome Sequencing Center for Infectious Diseases at the Broad Institute. We applied bioinformatics, statistical and coalescent simulation methods to investigate diversity of codon sequences of DENV samples representing the four serotypes. We show that fixation of nucleotide substitutions is more prominent among the inter-continental isolates (Asian and American) of serotypes 1, 2 and 3 compared to serotype 4 isolates (South and Central America) and are distributed in a non-random manner among the genes encoded by the virus. Nearly one third of the negatively selected sites are associated with fixed mutation sites within serotypes. Our results further show that of all the sites showing evidence of recombination, the majority (~84%) correspond to sites under purifying selection in the four serotypes. The analysis further shows that genetic recombination occurs within specific codons, albeit with low frequency (< 5% of all recombination sites) throughout the DENV genome of the four serotypes and reveals significant enrichment (p < 0.05) among sites under purifying selection in the virus.ConclusionThe study provides the first evidence for intracodon recombination in DENV and suggests that within codons, genetic recombination has a significant role in maintaining extensive purifying selection of DENV in natural populations. Our study also suggests that fixation of beneficial mutations may lead to virus evolution via translational selection of specific sites in the DENV genome.

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Section: Introductionmentioning

confidence: 99%

Nucleotide substitutions in dengue virus serotypes from Asian and American countries: insights into intracodon recombination and purifying selection

Behura

Severson

2013

BMC Microbiol

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“…Dengue virus is a surprisingly conserved RNA virus (Choudhury, Lott, Banu, Cheng, & Teo, ; Lequime, Fontaine, Ar Gouilh, Moltini‐Conclois, & Lambrechts, ; Thai, Henn, Zody, Tricou, & Nguyet, ; Amarilla, de Almeida, Jorge, Alfonso, & de Castro‐Jorge, ; Holmes, ). Even though its serotypes present seemingly competitive dynamics, similar to the behaviour of antigenic strains of other fast evolving pathogens, observations of positive selection are rare (Tang et al., ; Filomatori et al., ; Waman et al., ; Hang et al., ; Choudhury et al., ; Martin, Chirivella, Co, Santiago, & Gubler, ; Sim, Aw, Wilm, Teoh, & Hue, ). Dengue transmission models have offered insight, but have so far failed to reach consensus on the possible biological drivers of the observed dynamic behaviour.…”

Section: Challenges and Opportunities In Computational Researchmentioning

confidence: 99%

“…There are also reports of sporadic episodes of positive selection and fixation of particular lineages (Tang et al., ; Filomatori et al., ; Waman et al., ; Hang et al., ; Choudhury et al., ; Martin et al., ), and it is generally believed that most events of lineage replacement go unnoticed, as the majority of endemic regions rely on syndromic surveillance, and as these events are not expected to result in significant changes in disease incidence (Lourenço & Recker, ). While there are rare examples of well‐described lineage shifts in the literature (OhAinle et al., ; Bennett, Holmes, Chirivella, Rodriguez, & Beltran, ), not much is known about the epidemiological and ecological contexts in which emergence of fitter lineages is favoured.…”

Section: Challenges and Opportunities In Computational Researchmentioning

confidence: 99%

“…Since then, a wide number of sylvatic strains (i.e., of animal origin) have been isolated and reported to belong to each of the lineages of human‐bearing serotypes, proposing a zoonotic origin for the pathogen (Holmes & Twiddy, ). Introduction of each serotype into the human population was extrapolated to have taken place at different time points, with DENV2's most recent common ancestor being the oldest, estimated to be approximately 1,000 years old (Twiddy, Holmes, & Rambaut, ; Weaver & Vasilakis, ), roughly corresponding to some of the first reports of dengue‐like illnesses (Vasilakis & Weaver, ; Tang et al., ; Weaver & Vasilakis, ). The genetic distance between currently circulating serotypes is likely a by‐product of allopatric evolution due to ecological partitioning of ancestral sylvatic strains (Holmes & Twiddy, ; Weaver & Vasilakis, ).…”

Section: Introductionmentioning

confidence: 99%

“…Within each serotype, nucleic acid sequencing techniques have identified genetic subgroups or lineages, commonly denominated as dengue genotypes (Tang et al., ; Weaver & Vasilakis, ). Notably, the overall amino acid sequence similarity among genotypes is generally above 90% (Holmes & Twiddy, ; Leitmeyer et al., ), whereas between serotypes, it can range between 60% and 80% (Irie, Mohan, Sasaguri, Putnak, & Padmanabhan, ; Rothman, ).…”

Section: Introductionmentioning

confidence: 99%

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Challenges in dengue research: A computational perspective

Lourenço

Tennant

Faria

et al. 2017

Evolutionary Applications

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The dengue virus is now the most widespread arbovirus affecting human populations, causing significant economic and social impact in South America and South‐East Asia. Increasing urbanization and globalization, coupled with insufficient resources for control, misguided policies or lack of political will, and expansion of its mosquito vectors are some of the reasons why interventions have so far failed to curb this major public health problem. Computational approaches have elucidated on dengue's population dynamics with the aim to provide not only a better understanding of the evolution and epidemiology of the virus but also robust intervention strategies. It is clear, however, that these have been insufficient to address key aspects of dengue's biology, many of which will play a crucial role for the success of future control programmes, including vaccination. Within a multiscale perspective on this biological system, with the aim of linking evolutionary, ecological and epidemiological thinking, as well as to expand on classic modelling assumptions, we here propose, discuss and exemplify a few major computational avenues—real‐time computational analysis of genetic data, phylodynamic modelling frameworks, within‐host model frameworks and GPU‐accelerated computing. We argue that these emerging approaches should offer valuable research opportunities over the coming years, as previously applied and demonstrated in the context of other pathogens.

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