Multiple Levels of Single-Strand Slippage at Cetacean Tri- and Tetranucleotide Repeat Microsatellite Loci

Multiple Levels of Single-Strand Slippage at Cetacean Tri- and Tetranucleotide Repeat Microsatellite Loci

Per J. Palsbøll^a,b, Martine Bérubé^b, and Hanne Jørgensen^b
^a Department of Ecology and Evolutionary Biology, University of California, Irvine, California 92697-2525,
^b Department of Population Biology, University of Copenhagen, DK-2100 Copenhagen, Denmark

Corresponding author: Per J. Palsbøll, School of Biological Sciences, University of Wales, Deiniol Rd., Bangor, Gwyneed LL57 2UW, Wales., p.palsboll{at}bangor.ac.uk (E-mail)

Communicating editor: S. YOKOYAMA

Between three and six tri- and tetranucleotide repeat microsatelliteloci were analyzed in 3720 samples collected from four differentspecies of baleen whales. Ten of the 18 species/locus combinationshad imperfect allele arrays, i.e., some alleles differed inlength by other than simple integer multiples of the basic repeatlength. The estimate of the average number of alleles and heterozygositywas higher at loci with imperfect allele arrays relative tothose with perfect allele arrays. Nucleotide sequences of 23different alleles at one tetranucleotide repeat microsatellitelocus in fin whales, Balaenoptera physalus, and humpback whales,Megaptera novaeangliae, revealed sequence changes includingperfect repeats only, multiple repeats, and partial repeats.The relative rate of the latter two categories of mutation wasestimated at 0.024 of the mutation rate involving perfect repeatsonly. It is hypothesized that single-strand slippage of partialrepeats may provide a mechanism for counteracting the continuousexpansion of microsatellite loci, which is the logical consequenceof recent reports demonstrating directional mutations. Partial-repeatmutations introduce imperfections in the repeat array, whichsubsequently could reduce the rate of single-strand slippage.Limited computer simulations confirmed this predicted effectof partial-repeat mutations.

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