The causes of epistasis

Visser, Jaap; Cooper, Tim F.; Elena, Santiago F.

doi:10.1098/rspb.2011.1537

Cited by 186 publications

(221 citation statements)

References 102 publications

(92 reference statements)

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“…Pleiotropy and epistasis have strong parallelisms because the effect of an allele depends on the context in both cases, i.e., the host species for pleiotropy and the viral genetic background for epistasis. Indeed, it has been postulated that pleiotropy is a prerequisite for epistasis (3,40). This dependence is obvious for the case of sign pleiotropy, where mutations with a positive effect in the new host have a negative effect in the primary one (13).…”

Section: Resultsmentioning

confidence: 99%

“…For such simple landscapes, predicting the result of evolution is an easy task. In contrast, epistatic interactions create curvature in the landscape, and if they are of the sign or reciprocal sign type, they create multiple peaks separated by low-fitness valleys (1)(2)(3). The reproducibility of evolution in such complex landscapes, and therefore our ability to predict its outcome, diminishes as the number of possible peaks, that is, the ruggedness of the landscape, increases.…”

Section: Importancementioning

confidence: 99%

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Effect of Host Species on Topography of the Fitness Landscape for a Plant RNA Virus

Cervera

Lalić

Elena

2016

J Virol

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Adaptive fitness landscapes are a fundamental concept in evolutionary biology that relate the genotypes of individuals to their fitness. In the end, the evolutionary fate of evolving populations depends on the topography of the landscape, that is, the numbers of accessible mutational pathways and possible fitness peaks (i.e., adaptive solutions). For a long time, fitness landscapes were only theoretical constructions due to a lack of precise information on the mapping between genotypes and phenotypes. In recent years, however, efforts have been devoted to characterizing the properties of empirical fitness landscapes for individual proteins or for microbes adapting to artificial environments. In a previous study, we characterized the properties of the empirical fitness landscape defined by the first five mutations fixed during adaptation of tobacco etch potyvirus (TEV) to a new experimental host, Arabidopsis thaliana. Here we evaluate the topography of this landscape in the ancestral host Nicotiana tabacum. By comparing the topographies of the landscapes for the two hosts, we found that some features remained similar, such as the existence of fitness holes and the prevalence of epistasis, including cases of sign and reciprocal sign epistasis that created rugged, uncorrelated, and highly random topographies. However, we also observed significant differences in the fine-grained details between the two landscapes due to changes in the fitness and epistatic interactions of some genotypes. Our results support the idea that not only fitness tradeoffs between hosts but also topographical incongruences among fitness landscapes in alternative hosts may contribute to virus specialization. IMPORTANCEDespite its importance for understanding virus evolutionary dynamics, very little is known about the topography of virus adaptive fitness landscapes, and even less is known about the effects that different host species and environmental conditions may have on this topography. To bridge this gap, we evaluated the topography of a small fitness landscape formed by all genotypes that result from every possible combination of the first five mutations fixed during adaptation of TEV to the novel host A. thaliana. To assess the effect that host species may have on this topography, we evaluated the fitness of every genotype in both the ancestral and novel hosts. We found that both landscapes share some macroscopic properties, such as the existence of holes and being highly rugged and uncorrelated, yet they differ in microscopic details due to changes in the magnitude and sign of fitness and epistatic effects. T he effects of mutations can be influenced by their interactions with other mutations, with the environment, or both. Epistatic interactions among genetic loci determine the ruggedness of fitness landscapes. In the absence of epistasis, landscapes are single peaked and smooth (1). For such simple landscapes, predicting the result of evolution is an easy task. In contrast, epistatic interactions create curvature in the lands...

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Section: Resultsmentioning

confidence: 99%

Section: Importancementioning

confidence: 99%

Effect of Host Species on Topography of the Fitness Landscape for a Plant RNA Virus

Cervera

Lalić

Elena

2016

J Virol

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“…epistasis | mutation-by-genetic background interactions | beneficial mutations | horizontal gene transfer M utations can interact with one another and with their broader genetic background to affect fitness, a phenomenon known as epistasis (1). Epistasis plays a key role in many aspects of biology, including theories of speciation (2,3), the evolution and maintenance of sex (4,5), adaptation (6)(7)(8), and evolutionary contingency (9,10).…”

mentioning

confidence: 99%

Benefit of transferred mutations is better predicted by the fitness of recipients than by their ecological or genetic relatedness

Wang

Arenas

Stoebel

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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The effect of a mutation depends on its interaction with the genetic background in which it is assessed. Studies in experimental systems have demonstrated that such interactions are common among beneficial mutations and often follow a pattern consistent with declining evolvability of more fit genotypes. However, these studies generally examine the consequences of interactions between a small number of focal mutations. It is not clear, therefore, that findings can be extrapolated to natural populations, where new mutations may be transferred between genetically divergent backgrounds. We build on work that examined interactions between four beneficial mutations selected in a laboratory-evolved population of Escherichia coli to test how they interact with the genomes of diverse natural isolates of the same species. We find that the fitness effect of transferred mutations depends weakly on the genetic and ecological similarity of recipient strains relative to the donor strain in which the mutations were selected. By contrast, mutation effects were strongly inversely correlated to the initial fitness of the recipient strain. That is, there was a pattern of diminishing returns whereby fit strains benefited proportionally less from an added mutation. Our results strengthen the view that the fitness of a strain can be a major determinant of its ability to adapt. They also support a role for barriers of transmission, rather than differential selection of transferred DNA, as an explanation of observed phylogenetically determined patterns of restricted recombination among E. coli strains.

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“…Therefore, one extreme tail may include the non-fittest who cannot leave offspring and the other tail or the border flanking to the non-fittest tail may provide the founder or pioneer who is the key person for human terrestrial migration and local adaptation. In spite of the stochastic manner of the stochastic epistasis, the repeated purge of the same non-fittest extremes may be another process of evolutionary trends in which the phenotypic mean value can be passively changed [67]. In a liability-probability model, the non-fittest extreme tail possesses extremely low fecundity and the fecundity is continuously and sharply recovered at the majority of the bell-shaped population [73].…”

Section: Resultsmentioning

confidence: 99%

“…This diversification strategy is, no doubt, the only way to win the chance at survival [64] [65]. Interactions between polymorphic loci can make the organisms insensitive to the impact of novel mutations or environmental perturbation [59] [66] [67], and stochastic epistatic modules may have critical roles in this buffer system. A variant which was buffered and harbored in the stochastic genetic network is one of the modifiers of the module and can participate in an active evolutionary phenotypic change through a nonlinear alteration of the mean value or the position of the distribution in multi-dimensions of trait vectors [63] [68].…”

Section: Stochastic Epistasis and Evolutionmentioning

confidence: 99%

The Origin of Population Diversity: Stochastic Interactions between a Modifier Variant and the Individual Genetic Background

Ijichi¹,

Ijichi²,

Ijichi³

et al. 2015

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Stochastic epistasis that is one of the characteristics of epistatic gene modules can have an important role in the maintenance of intraspecific population diversity. The effect of an epistatic modifier variant can vary in size and direction among the modifier careers on the basis of stochastic genetic individuality and the entire module effect can be also individually stochastic. This stochastic genetic contribution under a genetic background may be conditional upon the presence of a monomorphic switch locus in the gene module. The genetic background includes multiple modifier variants and the gene module is composed of the switch and the modifiers. The bell-shaped distribution of quantitative traits can be well simulated by the involvement of multiple stochastic epistatic modules. The phenotypic stochasticity makes the presence of switch and modifiers cryptic or missing in the research field and this cryptic gene networks can maintain and innovate in the phenotypic diversity under selection as a process of the evolution of complexity.

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The causes of epistasis

Cited by 186 publications

References 102 publications

Effect of Host Species on Topography of the Fitness Landscape for a Plant RNA Virus

Effect of Host Species on Topography of the Fitness Landscape for a Plant RNA Virus

Benefit of transferred mutations is better predicted by the fitness of recipients than by their ecological or genetic relatedness

The Origin of Population Diversity: Stochastic Interactions between a Modifier Variant and the Individual Genetic Background

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