Understanding the Overdispersed Molecular Clock

Understanding the Overdispersed Molecular Clock

David J. Cutler^a
^a Center for Population Biology, University of California, Davis, California 95616

Corresponding author: David J. Cutler, Rm. BRB 747B, Case Western Reserve University, 2109 Adelbert Rd., Cleveland, OH 44106-4955., djc14{at}cwru.edu (E-mail)

Communicating editor: G. B. GOLDING

Rates of molecular evolution at some protein-encoding loci aremore irregular than expected under a simple neutral model ofmolecular evolution. This pattern of excessive irregularityin protein substitutions is often called the "overdispersedmolecular clock" and is characterized by an index of dispersion,R(T) > 1. Assuming infinite sites, no recombination model ofthe gene R(T) is given for a general stationary model of molecularevolution. R(T) is shown to be affected by only three things:fluctuations that occur on a very slow time scale, advantageousor deleterious mutations, and interactions between mutations.In the absence of interactions, advantageous mutations are shownto lower R(T); deleterious mutations are shown to raise it.Previously described models for the overdispersed molecularclock are analyzed in terms of this work as are a few very simplenew models. A model of deleterious mutations is shown to besufficient to explain the observed values of R(T). Our currentbest estimates of R(T) suggest that either most mutations aredeleterious or some key population parameter changes on a veryslow time scale. No other interpretations seem plausible. Finally,a comment is made on how R(T) might be used to distinguish selectivesweeps from background selection.

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