Spatial Covariation of Mutation and Nonsynonymous Substitution Rates in Vertebrate Mitochondrial Genomes

doi:10.1093/molbev/msl013

MBE Advance Access originally published online on May 16, 2006
Molecular Biology and Evolution 2006 23(8):1516-1524; doi:10.1093/molbev/msl013

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© The Author 2006. 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

Spatial Covariation of Mutation and Nonsynonymous Substitution Rates in Vertebrate Mitochondrial Genomes

Richard E. Broughton and Paulette C. Reneau

Oklahoma Biological Survey and Department of Zoology, University of Oklahoma

E-mail: rbroughton{at}ou.edu.

Mitochondrial genomes encode fundamental subunits of the basicenergy producing machinery of eukaryotic cells that are understrong functional constraint. Paradoxically, these genes evolverapidly in general, and there is substantial variation in evolutionaryrates among genes within genomes. In order to investigate spatialvariation in selection intensity, we conducted tests of neutralityusing ratios of synonymous to nonsynonymous substitutions (d_N/d_S= ${omega}$ ) on numerous protein gene segments from fishes and mammals.Values of ${omega}$ were very low for nearly all genomic regions. However,values of both ${omega}$ and d_N varied in a clinal pattern with increasingdistance from the light-strand origin of replication. Spatialheterogeneity of nonsynonymous substitution rates exhibits asignificantly positive correlation with variation in mutationrates that are related to the mode of mitochondrial DNA replication.The finding that nonsynonymous substitution rates are proportionalto mutation rates is expected if a majority of substitutionsare selectively neutral or slightly deleterious. Spatial patternsof among-gene variation in nonsynonymous rates were highly similarbetween fishes and mammals, suggesting that forces governingmitochondrial gene evolution have remained relatively constantover 450 Myr of vertebrate evolution. Conservation of substitutionpatterns despite major shifts in thermal habit and metabolicdemands among taxa implicates a conserved replication mechanismcontrolling relative mutation rates as a major determinant ofmitochondrial protein evolution.

Key Words: natural selection • neutral theory • nonsynonymous substitution • mitochondria

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