Molecular Biology and Evolution, Vol 15, 1332-1336, Copyright © 1998 by Society for Molecular Biology and Evolution
W Stephan and Y Kim
Given that most microsatellite arrays are of no obvious functional
significance, it is natural to ask how long these sequences persist during
evolution. The expected persistence time was calculated for microsatellite
arrays undergoing replication slippage and random genetic drift using
diffusion theory and Monte Carlo simulation. In each of the three models of
replication slippage compared, copy number changes involve only single
steps. In one model, the rates of addition or loss of repeat units are
constant; in the other two models, they are dependent on array length in a
linear or quadratic way. For all three models, it was found that
persistence time of microsatellite loci increases with population size in a
sublinear fashion. A heuristic argument is presented as to why this result
holds true for a more general class of mutation mechanisms, including
models that incorporate base substitutions in addition to replication
slippage. This suggests that the approximately 30% deficiency of
microsatellite loci on chromosome X (relative to autosomes) that has been
well documented for several mammalian species cannot be explained by the
fact that the X chromosome has a smaller effective population size than do
autosomes, as has been hypothesized.
ORIGINAL ARTICLE
Persistence of microsatellite arrays in finite populations
Department of Biology, University of Rochester, New York 14627-0211, USA. stephan@troi.cc.rochester.edu
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