The Coalescent in a Continuous, Finite, Linear Population

The Coalescent in a Continuous, Finite, Linear Population

Jon F. Wilkins^a and John Wakeley^b
^a Program in Biophysics, Harvard University, Cambridge, Massachusetts 02138
^b Department of Organismic and Evolutionary Biology, Harvard University, Cambridge, Massachusetts 02138

Corresponding author: Jon F. Wilkins, Biological Laboratories-2102, 16 Divinity Ave., Cambridge, MA 02138., jfwilkin{at}fas.harvard.edu (E-mail)

Communicating editor: M. W. FELDMAN

In this article we present a model for analyzing patterns ofgenetic diversity in a continuous, finite, linear habitat withrestricted gene flow. The distribution of coalescent times andlocations is derived for a pair of sequences sampled from arbitrarylocations along the habitat. The results for mean time to coalescenceare compared to simulated data. As expected, mean time to commonancestry increases with the distance separating the two sequences.Additionally, this mean time is greater near the center of thehabitat than near the ends. In the distant past, lineages thathave not undergone coalescence are more likely to have beenat opposite ends of the population range, whereas coalescentevents in the distant past are biased toward the center. Allof these effects are more pronounced when gene flow is morelimited. The pattern of pairwise nucleotide differences predictedby the model is compared to data collected from sardine populations.The sardine data are used to illustrate how demographic parameterscan be estimated using the model.

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