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Author Notes:

Corresponding Author: dbweissman@gmail.com, ohallats@berkeley.edu

We thank Paul Marjoram, Magnus Nordborg, Stephan Schiffels, and Diethard Tautz for their very thoughtful and helpful review, with additional thanks to Dr. Schiffels for help with MSMC.

We also thank Kelley Harris and Rasmus Nielsen for help with human population genetic data, Peter Ralph and Benjamin H. Good for discussions of the mathematical analysis, Julia Palacios for comments on the preprint, Miaoyan Wang for comments on the beta version of the software, and Razib Khan for suggesting the name of the method.

The authors declare that no competing interests exist.

Subjects:

Research Funding:

This paper was supported by the following grants: Simons Foundation Simons Investigator Award to Oskar Hallatschek. National Institute of General Medical Sciences R01GM115851 to Oskar Hallatschek.

Keywords:

  • q-bio.PE
  • q-bio.PE

Minimal-assumption inference from population-genomic data

Tools:

Journal Title:

eLife

Volume:

Volume 6

Publisher:

Type of Work:

Article | Final Publisher PDF

Abstract:

Samples of multiple complete genome sequences contain vast amounts of information about the evolutionary history of populations, much of it in the associations among polymorphisms at different loci. Current methods that take advantage of this linkage information rely on models of recombination and coalescence, limiting the sample sizes and populations that they can analyze. We introduce a method, Minimal-Assumption Genomic Inference of Coalescence (MAGIC), that reconstructs key features of the evolutionary history, including the distribution of coalescence times, by integrating information across genomic length scales without using an explicit model of recombination, demography or selection. Using simulated data, we show that MAGIC's performance is comparable to PSMC' on single diploid samples generated with standard coalescent and recombination models. More importantly, MAGIC can also analyze arbitrarily large samples and is robust to changes in the coalescent and recombination processes. Using MAGIC, we show that the inferred coalescence time histories of samples of multiple human genomes exhibit inconsistencies with a description in terms of an effective population size based on single-genome data.

Copyright information:

© 2017, Weissman et al

This is an Open Access work distributed under the terms of the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0/).
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