@article{1359, abstract = {The role of gene interactions in the evolutionary process has long been controversial. Although some argue that they are not of importance, because most variation is additive, others claim that their effect in the long term can be substantial. Here, we focus on the long-term effects of genetic interactions under directional selection assuming no mutation or dominance, and that epistasis is symmetrical overall. We ask by how much the mean of a complex trait can be increased by selection and analyze two extreme regimes, in which either drift or selection dominate the dynamics of allele frequencies. In both scenarios, epistatic interactions affect the long-term response to selection by modulating the additive genetic variance. When drift dominates, we extend Robertson ’ s [Robertson A (1960) Proc R Soc Lond B Biol Sci 153(951):234 − 249] argument to show that, for any form of epistasis, the total response of a haploid population is proportional to the initial total genotypic variance. In contrast, the total response of a diploid population is increased by epistasis, for a given initial genotypic variance. When selection dominates, we show that the total selection response can only be increased by epistasis when s ome initially deleterious alleles become favored as the genetic background changes. We find a sim- ple approximation for this effect and show that, in this regime, it is the structure of the genotype - phenotype map that matters and not the variance components of the population.}, author = {Paixao, Tiago and Barton, Nicholas H}, journal = {PNAS}, number = {16}, pages = {4422 -- 4427}, publisher = {National Academy of Sciences}, title = {{The effect of gene interactions on the long-term response to selection}}, doi = {10.1073/pnas.1518830113}, volume = {113}, year = {2016}, } @article{1356, author = {Barton, Nicholas H}, journal = {Genetics}, number = {1}, pages = {3 -- 4}, publisher = {Genetics Society of America}, title = {{Sewall Wright on evolution in Mendelian populations and the “Shifting Balance”}}, doi = {10.1534/genetics.115.184796}, volume = {202}, year = {2016}, } @article{1357, author = {Barton, Nicholas H}, journal = {Genetics}, number = {3}, pages = {865 -- 866}, publisher = {Genetics Society of America}, title = {{Richard Hudson and Norman Kaplan on the coalescent process}}, doi = {10.1534/genetics.116.187542}, volume = {202}, year = {2016}, } @article{1409, author = {Abbott, Richard and Barton, Nicholas H and Good, Jeffrey}, journal = {Molecular Ecology}, number = {11}, pages = {2325 -- 2332}, publisher = {Wiley-Blackwell}, title = {{Genomics of hybridization and its evolutionary consequences}}, doi = {10.1111/mec.13685}, volume = {25}, year = {2016}, } @article{1420, abstract = {Selection, mutation, and random drift affect the dynamics of allele frequencies and consequently of quantitative traits. While the macroscopic dynamics of quantitative traits can be measured, the underlying allele frequencies are typically unobserved. Can we understand how the macroscopic observables evolve without following these microscopic processes? This problem has been studied previously by analogy with statistical mechanics: the allele frequency distribution at each time point is approximated by the stationary form, which maximizes entropy. We explore the limitations of this method when mutation is small (4Nμ < 1) so that populations are typically close to fixation, and we extend the theory in this regime to account for changes in mutation strength. We consider a single diallelic locus either under directional selection or with overdominance and then generalize to multiple unlinked biallelic loci with unequal effects. We find that the maximum-entropy approximation is remarkably accurate, even when mutation and selection change rapidly. }, author = {Bod'ová, Katarína and Tkacik, Gasper and Barton, Nicholas H}, journal = {Genetics}, number = {4}, pages = {1523 -- 1548}, publisher = {Genetics Society of America}, title = {{A general approximation for the dynamics of quantitative traits}}, doi = {10.1534/genetics.115.184127}, volume = {202}, year = {2016}, } @article{1518, abstract = {The inference of demographic history from genome data is hindered by a lack of efficient computational approaches. In particular, it has proved difficult to exploit the information contained in the distribution of genealogies across the genome. We have previously shown that the generating function (GF) of genealogies can be used to analytically compute likelihoods of demographic models from configurations of mutations in short sequence blocks (Lohse et al. 2011). Although the GF has a simple, recursive form, the size of such likelihood calculations explodes quickly with the number of individuals and applications of this framework have so far been mainly limited to small samples (pairs and triplets) for which the GF can be written by hand. Here we investigate several strategies for exploiting the inherent symmetries of the coalescent. In particular, we show that the GF of genealogies can be decomposed into a set of equivalence classes that allows likelihood calculations from nontrivial samples. Using this strategy, we automated blockwise likelihood calculations for a general set of demographic scenarios in Mathematica. These histories may involve population size changes, continuous migration, discrete divergence, and admixture between multiple populations. To give a concrete example, we calculate the likelihood for a model of isolation with migration (IM), assuming two diploid samples without phase and outgroup information. We demonstrate the new inference scheme with an analysis of two individual butterfly genomes from the sister species Heliconius melpomene rosina and H. cydno.}, author = {Lohse, Konrad and Chmelik, Martin and Martin, Simon and Barton, Nicholas H}, journal = {Genetics}, number = {2}, pages = {775 -- 786}, publisher = {Genetics Society of America}, title = {{Efficient strategies for calculating blockwise likelihoods under the coalescent}}, doi = {10.1534/genetics.115.183814}, volume = {202}, year = {2016}, } @article{1631, abstract = {Ancestral processes are fundamental to modern population genetics and spatial structure has been the subject of intense interest for many years. Despite this interest, almost nothing is known about the distribution of the locations of pedigree or genetic ancestors. Using both spatially continuous and stepping-stone models, we show that the distribution of pedigree ancestors approaches a travelling wave, for which we develop two alternative approximations. The speed and width of the wave are sensitive to the local details of the model. After a short time, genetic ancestors spread far more slowly than pedigree ancestors, ultimately diffusing out with radius ## rather than spreading at constant speed. In contrast to the wave of pedigree ancestors, the spread of genetic ancestry is insensitive to the local details of the models.}, author = {Kelleher, Jerome and Etheridge, Alison and Véber, Amandine and Barton, Nicholas H}, journal = {Theoretical Population Biology}, pages = {1 -- 12}, publisher = {Academic Press}, title = {{Spread of pedigree versus genetic ancestry in spatially distributed populations}}, doi = {10.1016/j.tpb.2015.10.008}, volume = {108}, year = {2016}, } @article{1158, abstract = {Speciation results from the progressive accumulation of mutations that decrease the probability of mating between parental populations or reduce the fitness of hybrids—the so-called species barriers. The speciation genomic literature, however, is mainly a collection of case studies, each with its own approach and specificities, such that a global view of the gradual process of evolution from one to two species is currently lacking. Of primary importance is the prevalence of gene flow between diverging entities, which is central in most species concepts and has been widely discussed in recent years. Here, we explore the continuum of speciation thanks to a comparative analysis of genomic data from 61 pairs of populations/species of animals with variable levels of divergence. Gene flow between diverging gene pools is assessed under an approximate Bayesian computation (ABC) framework. We show that the intermediate "grey zone" of speciation, in which taxonomy is often controversial, spans from 0.5% to 2% of net synonymous divergence, irrespective of species life history traits or ecology. Thanks to appropriate modeling of among-locus variation in genetic drift and introgression rate, we clarify the status of the majority of ambiguous cases and uncover a number of cryptic species. Our analysis also reveals the high incidence in animals of semi-isolated species (when some but not all loci are affected by barriers to gene flow) and highlights the intrinsic difficulty, both statistical and conceptual, of delineating species in the grey zone of speciation.}, author = {Roux, Camille and Fraisse, Christelle and Romiguier, Jonathan and Anciaux, Youann and Galtier, Nicolas and Bierne, Nicolas}, journal = {PLoS Biology}, number = {12}, publisher = {Public Library of Science}, title = {{Shedding light on the grey zone of speciation along a continuum of genomic divergence}}, doi = {10.1371/journal.pbio.2000234}, volume = {14}, year = {2016}, } @misc{9862, author = {Roux, Camille and Fraisse, Christelle and Romiguier, Jonathan and Anciaux, Youann and Galtier, Nicolas and Bierne, Nicolas}, publisher = {Public Library of Science}, title = {{Simulation study to test the robustness of ABC in face of recent times of divergence}}, doi = {10.1371/journal.pbio.2000234.s016}, year = {2016}, } @misc{9863, author = {Roux, Camille and Fraisse, Christelle and Romiguier, Jonathan and Anciaux, Youann and Galtier, Nicolas and Bierne, Nicolas}, publisher = {Public Library of Science}, title = {{Accessions of surveyed individuals, geographic locations and summary statistics}}, doi = {10.1371/journal.pbio.2000234.s017}, year = {2016}, }