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At present, most analyses that aim to detect the action of natural selection upon viral gene sequences use phylogenetic estimates of the ratio of silent to replacement mutations. Such methods, however, are impractical to compute on large data sets comprising hundreds of complete viral genomes, which are becoming increasingly common due to advances in genome sequencing technology. Here we investigate the statistical performance of computationally efficient tests that are based on sequence summary statistics, and explore their applicability to RNA virus data sets in two ways. Firstly, we perform extensive simulations in order to measure the type I error of two well-known summary statistic methods - Tajima's D and the McDonald-Kreitman test - under a range of virus-like mutational and demographic scenarios. Secondly, we apply these methods to a compilation of approximately 100 RNA virus alignments that represent natural RNA virus populations. In addition, we develop and introduce a new implementation of the McDonald-Kreitman test and show that it greatly improves the test's statistical reliability on typical viral data sets. Our results suggest that variants of the McDonald-Kreitman test could prove useful in the analysis of very large sets of highly diverse viral genetic data.

Original publication

DOI

10.1016/j.meegid.2009.06.001

Type

Journal article

Journal

Infect Genet Evol

Publication Date

04/2010

Volume

10

Pages

421 - 430

Keywords

Algorithms, Evolution, Molecular, Genetic Variation, Genome, Viral, Phylogeny, RNA Viruses, RNA, Viral, Selection, Genetic, Sequence Alignment, Sequence Analysis, RNA, Species Specificity, Statistics as Topic