Periodic Extinctions of Transposable Elements in Bacterial Lineages: Evidence from Intragenomic Variation in Multiple Genomes

doi:10.1093/molbev/msj085

MBE Advance Access originally published online on December 22, 2005
Molecular Biology and Evolution 2006 23(4):723-733; doi:10.1093/molbev/msj085

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© The Author 2005. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oxfordjournals.org

Research Article

Periodic Extinctions of Transposable Elements in Bacterial Lineages: Evidence from Intragenomic Variation in Multiple Genomes

Andreas Wagner

Department of Biology, The University of New Mexico

E-mail: wagnera{at}unm.edu.

Most previous work on the evolution of mobile DNA was limitedby incomplete sequence information. Whole genome sequences allowus to overcome this limitation. I study the nucleotide diversityof prominent members of five insertion sequence families whosetransposition activity is encoded by a single transposase gene.Eighteen among 376 completely sequenced bacterial genomes andplasmids carry between 3 and 20 copies of a given insertionsequence. I show that these copies generally show very low DNAdivergence. Specifically, more than 68% of the transposase genesare identical within a genome. The average number of amino acidreplacement substitutions at amino acid replacement sites isK_a = 0.013, that at silent sites is K_s = 0.1. This low intragenomicdiversity stands in stark contrast to a much higher divergenceof the same insertion sequences among distantly related genomes.Gene conversion among protein-coding genes is unlikely to accountfor this lack of diversity. The relation between transpositionfrequencies and silent substitution rates suggests that mostinsertion sequences in a typical genome are evolutionarily youngand have been recently acquired. They may undergo periodic extinctionin bacterial lineages. By implication, they are detrimentalto their host in the long run. This is also suggested by thehighly skewed and patchy distribution of insertion sequencesamong genomes. In sum, one can think of insertion sequencesas slow-acting infectious diseases of cell lineages.

Key Words: mobile DNA • transposon • infection • extinction

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