In: PLOS ONE
6(5), e18155
[PDF, 370kB]
Abstract
Understanding the processes and conditions under which populations diverge to give rise to distinct species is a central question in evolutionary biology. Since recently diverged populations have high levels of shared polymorphisms, it is challenging to distinguish between recent divergence with no (or very low) inter-population gene flow and older splitting events with subsequent gene flow. Recently published methods to infer speciation parameters under the isolation-migration framework are based on summarizing polymorphism data at multiple loci in two species using the joint site-frequency spectrum (JSFS). We have developed two improvements of these methods based on a more extensive use of the JSFS classes of polymorphisms for species with high intra-locus recombination rates. First, using a likelihood based method, we demonstrate that taking into account low-frequency polymorphisms shared between species significantly improves the joint estimation of the divergence time and gene flow between species. Second, we introduce a local linear regression algorithm that considerably reduces the computational time and allows for the estimation of unequal rates of gene flow between species. We also investigate which summary statistics from the JSFS allow the greatest estimation accuracy for divergence time and migration rates for low (around 10) and high (around 100) numbers of loci. Focusing on cases with low numbers of loci and high intra-locus recombination rates we show that our methods for the estimation of divergence time and migration rates are more precise than existing approaches.
Item Type: | Journal article |
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Form of publication: | Publisher's Version |
Faculties: | Biology |
Subjects: | 500 Science > 570 Life sciences; biology |
URN: | urn:nbn:de:bvb:19-epub-15067-2 |
ISSN: | 1932-6203 |
Annotation: | This work was supported by grants of the DFG Forschergruppe 1078, “Natural selection in structured populations”, to D.M., P.P., and L.E.R.; DFG grants STE 325/9 and STE 325/13 to W.S.; Swiss National Science Foundation grant 31003A_130702 to T.S.; and Volkswagen Foundation grant I/82752 to A.T. |
Language: | English |
Item ID: | 15067 |
Date Deposited: | 06. May 2013, 07:49 |
Last Modified: | 04. Nov 2020, 12:55 |