Mutation Patterns of Mitochondrial H- and L-Strand DNA in Closely Related Cyprinid Fishes

Mutation Patterns of Mitochondrial H- and L-Strand DNA in Closely Related Cyprinid Fishes

Joseph P. Bielawski^a,b and John R. Gold^a
^a Center for Biosystematics and Biodiversity, Texas A&M University, College Station, Texas 77843-2258
^b Department of Biology, University College London, London WC1E 6BT, United Kingdom

Corresponding author: Joseph P. Bielawski, University College London, Darwin Bldg., Gower St., London WC1E 6BT, United Kingdom., j.bielawski{at}ucl.ac.uk (E-mail)

Communicating editor: H. OCHMAN

Mitochondrial genome replication is asymmetric. Replicationstarts from the origin of heavy (H)-strand replication, displacingthe parental H-strand as it proceeds along the molecule. TheH-strand remains single stranded until light (L)-strand replicationis initiated from a second origin of replication. It has beensuggested that single-stranded H-strand DNA is more sensitiveto mutational damage, giving rise to substitutional rate differencesbetween the two strands and among genes in mammalian mitochondrialDNA. In this study, we analyzed sequences of the cytochromeb, ND4, ND4L, and COI genes of cyprinid fishes to investigaterates and patterns of nucleotide substitution in the mitochondrialgenome. To test for strand-asymmetric mutation pressure, a likelihood-ratiotest was developed and applied to the cyprinid sequences. Patternsof substitution and levels of strand-asymmetric mutation pressurewere largely consistent with a mutation gradient between theH- and L-strand origins of replication. Significant strand biaswas observed among rates of transitional substitution. However,biological interpretation of the direction and strength of strandasymmetry for specific classes of substitutions is problematic.The problem occurs because the rate of any single class of substitutioninferred from one strand is actually a sum of rates on two strands.The validity of the likelihood-ratio test is not affected bythis problem.

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