A Maximum-Likelihood Approach to Fitting Equilibrium Models of Microsatellite Evolution

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Molecular Biology and Evolution 18:413-417 (2001)
© 2001 Society for Molecular Biology and Evolution

ARTICLE

A Maximum-Likelihood Approach to Fitting Equilibrium Models of Microsatellite Evolution

Richard M. Sibly, John C. Whittaker and Melanie Talbot

*School of Animal and Microbial Sciences
${dagger}$ Department of Applied Statistics, University of Reading, Reading, England

Here, we develop a new approach to Markov chain modeling ofmicrosatellite evolution through polymerase slippage and introducenew models: a "constant-slippage-rate" model, in which thereis no dependence of slippage rate on microsatellite length,as envisaged by Moran; and a "linear-with-constant" model, inwhich slippage rate increases linearly with microsatellite length,but the line of best fit is not constrained to go through theorigin. We show how these and a linear no-constant model canbe fitted to data hierarchically using maximum likelihood. Thishas advantages over previous methods in allowing statisticalcomparisons between models. When applied to a previously analyzeddata set, the method allowed us to statistically establish thatslippage rate increases with microsatellite length for dinucleotidemicrosatellites in humans, mice, and fruit flies, and suggestedthat no slippage occurs in very short microsatellites of oneto four repeats. The suggestion that slippage rates are zeroor close to zero for very short microsatellites of one to fourrepeats has important implications for understanding the mechanismof polymerase slippage.

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