Abstract

The multispecies coalescent provides an elegant theoretical framework for estimating species trees and species demographics from genetic markers. However, practical applications of the multispecies coalescent model are limited by the need to integrate or sample over all gene trees possible for each genetic marker. Here we describe a polynomial-time algorithm that computes the likelihood of a species tree directly from the markers under a finite-sites model of mutation effectively integrating over all possible gene trees. The method applies to independent (unlinked) biallelic markers such as well-spaced single nucleotide polymorphisms, and we have implemented it in SNAPP, a Markov chain Monte Carlo sampler for inferring species trees, divergence dates, and population sizes. We report results from simulation experiments and from an analysis of 1997 amplified fragment length polymorphism loci in 69 individuals sampled from six species of Ourisia (New Zealand native foxglove).

Keywords

Coalescent theoryBiologyGeneticsPopulationEvolutionary biologyMarkov chain Monte CarloTree (set theory)Population geneticsDivergence (linguistics)GenePhylogenetic treeBayesian probabilityStatisticsMathematics

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Publication Info

Year
2012
Type
article
Volume
29
Issue
8
Pages
1917-1932
Citations
1003
Access
Closed

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David Bryant, Remco Bouckaert, Joseph Felsenstein et al. (2012). Inferring Species Trees Directly from Biallelic Genetic Markers: Bypassing Gene Trees in a Full Coalescent Analysis. Molecular Biology and Evolution , 29 (8) , 1917-1932. https://doi.org/10.1093/molbev/mss086

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DOI
10.1093/molbev/mss086