@article{1241, abstract = {How likely is it that a population escapes extinction through adaptive evolution? The answer to this question is of great relevance in conservation biology, where we aim at species’ rescue and the maintenance of biodiversity, and in agriculture and medicine, where we seek to hamper the emergence of pesticide or drug resistance. By reshuffling the genome, recombination has two antagonistic effects on the probability of evolutionary rescue: It generates and it breaks up favorable gene combinations. Which of the two effects prevails depends on the fitness effects of mutations and on the impact of stochasticity on the allele frequencies. In this article, we analyze a mathematical model for rescue after a sudden environmental change when adaptation is contingent on mutations at two loci. The analysis reveals a complex nonlinear dependence of population survival on recombination. We moreover find that, counterintuitively, a fast eradication of the wild type can promote rescue in the presence of recombination. The model also shows that two-step rescue is not unlikely to happen and can even be more likely than single-step rescue (where adaptation relies on a single mutation), depending on the circumstances.}, author = {Uecker, Hildegard and Hermisson, Joachim}, journal = {Genetics}, number = {2}, pages = {721 -- 732}, publisher = {Genetics Society of America}, title = {{The role of recombination in evolutionary rescue}}, doi = {10.1534/genetics.115.180299}, volume = {202}, year = {2016}, } @inproceedings{1349, abstract = {Crossing fitness valleys is one of the major obstacles to function optimization. In this paper we investigate how the structure of the fitness valley, namely its depth d and length ℓ, influence the runtime of different strategies for crossing these valleys. We present a runtime comparison between the (1+1) EA and two non-elitist nature-inspired algorithms, Strong Selection Weak Mutation (SSWM) and the Metropolis algorithm. While the (1+1) EA has to jump across the valley to a point of higher fitness because it does not accept decreasing moves, the non-elitist algorithms may cross the valley by accepting worsening moves. We show that while the runtime of the (1+1) EA algorithm depends critically on the length of the valley, the runtimes of the non-elitist algorithms depend crucially only on the depth of the valley. In particular, the expected runtime of both SSWM and Metropolis is polynomial in ℓ and exponential in d while the (1+1) EA is efficient only for valleys of small length. Moreover, we show that both SSWM and Metropolis can also efficiently optimize a rugged function consisting of consecutive valleys.}, author = {Oliveto, Pietro and Paixao, Tiago and Heredia, Jorge and Sudholt, Dirk and Trubenova, Barbora}, booktitle = {Proceedings of the Genetic and Evolutionary Computation Conference 2016 }, location = {Denver, CO, USA}, pages = {1163 -- 1170}, publisher = {ACM}, title = {{When non-elitism outperforms elitism for crossing fitness valleys}}, doi = {10.1145/2908812.2908909}, year = {2016}, } @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}, }