Different rates of non-synonymous mutations in astrovirus genes; correlation with gene functionReportar como inadecuado

Different rates of non-synonymous mutations in astrovirus genes; correlation with gene function - Descarga este documento en PDF. Documentación en PDF para descargar gratis. Disponible también para leer online.

Virology Journal

, 4:25

First Online: 07 March 2007Received: 11 January 2007Accepted: 07 March 2007


BackgroundComplete genome sequences of the Astroviridae include human, non-human mammalian and avian species. A consensus topology of astroviruses has been derived from nucleotide substitutions in the full-length genomes and from non-synonymous nucleotide substitutions in each of the three ORFs. Analyses of synonymous substitutions displayed a loss of tree structure, suggesting either saturation of the substitution model or a deviant pattern of synonymous substitutions in certain virus species.

ResultsWe analyzed the complete Astroviridae family for the inference of adaptive molecular evolution at sites and in branches. High rates of synonymous mutations are observed among the non-human virus species. Deviant patterns of synonymous substitutions are found in the capsid structural genes. Purifying selection is a dominant force among all astrovirus genes and only few codon sites showed values for the dN-dS ratio that may indicate site-specific molecular adaptation during virus evolution. One of these sites is the glycine residue of a RGD motif in ORF2 of human astrovirus serotype 1. RGD or similar integrin recognition motifs are present in nearly all astrovirus species.

ConclusionPhylogenetic analysis directed by maximum likelihood approximation allows the inclusion of significantly more evolutionary history and thereby, improves the estimation of dN and dS. Sites with enhanced values for dN-dS are prominent at domains in charge of environmental communication f.i. VP27 and domain 4 in ORF1a more than at domains dedicated to intrinsic virus functions f.i. VP34 and ORF1b the virus polymerase. Integrin recognition may play a key role in astrovirus to target cell attachment.

Electronic supplementary materialThe online version of this article doi:10.1186-1743-422X-4-25 contains supplementary material, which is available to authorized users.

Download fulltext PDF

Autor: Formijn J van Hemert - Vladimir V Lukashov - Ben Berkhout

Fuente: https://link.springer.com/

Documentos relacionados