Your search keyword '"Hill-Robertson interference"' showing total 2 results

1. Higher rates of sex evolve during adaptation to more complex environments.

Author

Luijckx, Pepijn, Eddie Ka Ho Ho, Gasim, Majid, Suyang Chen, Stanic, Andrijana, Yanchus, Connor, Yun Seong Kim, and Agrawal, Aneil F.

Subjects

*REPRODUCTION, *ANIMAL adaptation, *BRACHIONUS, *ANIMAL population density, *ANIMAL development

Abstract

A leading hypothesis for the evolutionary maintenance of sexual reproduction proposes that sex is advantageous because it facilitates adaptation. Changes in the environment stimulate adaptation but not all changes are equivalent; a change may occur along one or multiple environmental dimensions. In two evolution experiments with the facultatively sexual rotifer Brachionus calyciflorus, we test how environmental complexity affects the evolution of sex by adapting replicate populations to various environments that differ from the original along one, two, or three environmental dimensions. Three different estimates of fitness (growth, lifetime reproduction, and population density) confirmed that populations adapted to their new environment. Growth measures revealed an intriguing cost of complex adaptations: populations that adapted to more complex environments lost greater amounts of fitness in the original environment. Furthermore, both experiments showed that B. calyciflorus became more sexual when adapting to a greater number of environmental dimensions. Common garden experiments confirmed that observed changes in sex were heritable. As environments in nature are inherently complex these findings help explain why sex is maintained in natural populations. [ABSTRACT FROM AUTHOR]

Published

2017

2. Coalescence and genetic diversity in sexual populations under selection.

Author

Neher, Richard A., Kessinger, Taylor A., and Shraiman, Boris I.

Subjects

*ALLELES, *GENETIC recombination, *QUANTITATIVE genetics, *HEREDITY, *GENOMICS

Abstract

In sexual populations, selection operates neither on the whole genome, which is repeatedly taken apart and reassembled by recombination, nor on individual alleles that are tightly linked to the chromosomal neighborhood. The resulting interference between linked alleles reduces the efficiency of selection and distorts patterns of genetic diversity. Inference of evolutionary history from diversity shaped by linked selection requires an understanding of these patterns. Here, we present a simple but powerful scaling analysis identifying the unit of selection as the genomic "linkage block" with a characteristic length, ξb, determined in a self-consistent manner by the condition that the rate of recombination within the block is comparable to the fitness differences between different alleles of the block. We find that an asexual model with the strength of selection tuned to that of the linkage block provides an excellent description of genetic diversity and the site frequency spectra compared with computer simulations. This linkage block approximation is accurate for the entire spectrum of strength of selection and is particularly powerful in scenarios with many weakly selected loci. The latter limit allows us to characterize coalescence, genetic diversity, and the speed of adaptation in the infinitesimal model of quantitative genetics. [ABSTRACT FROM AUTHOR]

Published

2013