Inferring the Rate and Time-Scale of Dengue Virus Evolution

doi:10.1093/molbev/msg010

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Mol. Biol. Evol. 20(1):122-129. 2003
DOI: 10.1093/molbev/msg010
© 2003 by the Society for Molecular Biology and Evolution. ISSN: 0737-4038

Inferring the Rate and Time-Scale of Dengue Virus Evolution

S. Susanna Twiddy, Edward C. Holmes and Andrew Rambaut

Department of Zoology, University of Oxford, Oxford, United Kingdom

Dengue is often referred to as an emerging disease because ofthe rapid increases in incidence and prevalence that have beenobserved in recent decades. To understand the rate at whichgenetic diversification occurs in dengue virus and to inferthe time-scale of its evolution, we employed a maximum likelihoodmethod that uses information about times of virus sampling toestimate the rate of molecular evolution in a large number ofviral envelope (E) gene sequences and to place bounds aroundthe dates of appearance of all serotypes and specific genotypes.Our analysis reveals that dengue virus generally evolves accordingto a molecular clock, although some serotype-specific and genotype-specificrate differences were observed, and that its origin is morerecent than previously suggested, with the virus appearing approximately1000 years ago. Furthermore, we estimate that the zoonotic transferof dengue from sylvatic (monkey) to sustained human transmissionoccurred between 125 and 320 years ago, that the current globalgenetic diversity in the four serotypes of dengue virus onlyappeared during the past century, and that the recent rise ingenetic diversity can be loosely correlated both to human activitiessuch as population growth, urbanization, and mass transportand to the emergence of dengue hemorrhagic fever as a majordisease problem.

Key Words: dengue virus • substitution rate • divergence time • maximum likelihood • E gene

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