Impact of epistasis and pleiotropy on evolutionary adaptation.

Supporting Material: Impact of Epistasis and Pleiotropy on Evolutionary Adaptation

Emerging viruses: why they are not jacks of all trades?

In order to limit the impact of the recent pandemics ignited by viral host jumps, it is necessary to better understand the ecological and evolutionary factors influencing the early steps of emergence and the interactions between them. Antagonistic pleiotropy, that is, the negative fitness effect in the primary host of mutations allowing the infection of and the multiplication in a new host, has...

Effects of Genetic Architecture on Evolution of Multiple Traits

The phenomena of pleiotropy, the influence of individual genes on multiple traits of an organism, and epistasis, the interaction of multiple genes in influencing a single trait, are ubiquitous characteristics of organization of genomes of living organisms. In evolutionary computation, a high degree of epistasis and pleiotropy is often considered an indication of hardness of the problem. The exp...

Effects of Epistasis and Pleiotropy on Fitness Landscapes

The factors that influence genetic architecture shape the structure of the fitness landscape, and therefore play a large role in the evolutionary dynamics. Here the NK model is used to investigate how epistasis and pleiotropy – key components of genetic architecture – affect the structure of the fitness landscape, and how they affect the ability of evolving populations to adapt despite the diff...

Understanding specialism when the Jack of all trades can be the master of all.

Specialism is widespread in nature, generating and maintaining diversity, but recent work has demonstrated that generalists can be equally fit as specialists in some shared environments. This no-cost generalism challenges the maxim that 'the jack of all trades is the master of none', and requires evolutionary genetic mechanisms explaining the existence of specialism and no-cost generalism, and ...