Mutation bias can shape adaptation in large asexual populations experiencing clonal interference

Gomez, Kevin; Bertram, Jason; Masel, Joanna

doi:10.1098/rspb.2020.1503

Cited by 30 publications

(39 citation statements)

References 46 publications

(94 reference statements)

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“…These results leverage the findings of Schiffels et al (2011), and later work by Gomez et al (2020) and Venkataram et al (2019), to illustrate that asexual adaptation is not just slower than adaptation with recombination, but differs in other significant aspects. Other models have predicted differences in the nature of adaptation in asexual versus sexual organisms, such as difference in epistasis among fixed mutations (Livnat et al 2008) and, as discussed above, asexuality is linked with extreme generalism in some insects (Gibson 2019).…”

Section: Discussionsupporting

confidence: 79%

“…In assessing the causes and generality of asymmetric evolvability and the resulting evolution of specialism, I applied the results of Schiffels et al (2011) and Gomez et al (2020) to make two predictions. First, I expected the likelihood of specialization to be sensitive to population-genetic parameters determining evolvability, principally N, , s and L. Second, in asexual populations, increasing N or  will worsen clonal interference and exacerbate the asymmetry between the rates of evolution in the common and rare environments.…”

Section: The Propensity For Adaptive Specialization Is Sensitive To Dmentioning

confidence: 99%

“…Recent theory focusing on asexual evolution has predicted that adaptation among sites with small selection coefficients can be effectively stalled by interference from rapidly evolving sites with larger effects (Schiffels et al 2011). Extending this model to multiple traits, Gomez et al (2019) showed that clonal interference can produce a false signature of trade-offs where none exist, and Gomez et al (2020) showed that a trait with more frequent or larger beneficial mutations can effectively stall adaptation in a trait with lower evolvability, an effect that Venkataram et al (2019) recently demonstrated experimentally. Here, specialization is seen to evolve when a rare environment becomes unprofitable in comparison to the more common environment, solely because of slow relative improvement in how organisms can exploit the rare environment.…”

Section: Introductionmentioning

confidence: 97%

“…plots mean fitness in each environment, comparing treatments when each trait evolves alone (no mutation in the other trait) versus when it evolves simultaneously with the other fitness trait. With complete linkage (r = 0) and therefore clonal interference between traits (seeSchiffels et al 2011;Gomez et al 2020),…”

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confidence: 99%

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Asymmetric Evolvability Leads to Specialization without Trade-Offs

Draghi

2021

The American Naturalist

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Many organisms are specialized, and these narrow niches are often explained with trade-offs-inability for one organism to express maximal performance in two or more environments. However, evidence is lacking that trade-offs are sufficient to explain specialists. Several lines of theoretical inquiry suggest that populations can specialize without explicit trade-offs, as a result of relaxed selection in generalists for their performance in rare environments. Here I synthesize and extend these approaches, showing that emergent asymmetries in evolvability can push a population toward specialization in the absence of trade-offs and in the presence of substantial ecological costs of specialism. Simulations are used to demonstrate how adaptation to a more common environment interferes with adaptation to a less common but otherwise equal alternative environment, and that this interference is greatly exacerbated at low recombination rates. This adaptive process of specialization can effectively trap populations in a suboptimal niche. These modeling results predict that transient differences in evolvability across traits during a single episode of adaptation could have long-term consequences for a population's niche.

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Section: Discussionsupporting

confidence: 79%

Section: The Propensity For Adaptive Specialization Is Sensitive To Dmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 97%

mentioning

confidence: 99%

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Asymmetric Evolvability Leads to Specialization without Trade-Offs

Draghi

2021

The American Naturalist

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“…As large populations suffer less from genetic drift and contain more adaptive variants than small populations, natural selection will likely filter out the small set of most beneficial mutants, even if they are rare, leading to more repeatable evolution through selection bias. By contrast, in small populations adaptation relies more heavily on the chance occurrence of beneficial mutations and, hence, mutation bias has a relatively stronger impact [9,10].…”

Section: Introductionmentioning

confidence: 99%

Clonal Interference and Mutation Bias in Small Bacterial Populations in Droplets

Ruelens

Visser

2021

Genes

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Experimental evolution studies have provided key insights into the fundamental mechanisms of evolution. One striking observation is that parallel and convergent evolution during laboratory evolution can be surprisingly common. However, these experiments are typically performed with well-mixed cultures and large effective population sizes, while pathogenic microbes typically experience strong bottlenecks during infection or drug treatment. Yet, our knowledge about adaptation in very small populations, where selection strength and mutation supplies are limited, is scant. In this study, wild-type and mutator strains of the bacterium Escherichia coli were evolved for about 100 generations towards increased resistance to the β-lactam antibiotic cefotaxime in millifluidic droplets of 0.5 µL and effective population size of approximately 27,000 cells. The small effective population size limited the adaptive potential of wild-type populations, where adaptation was limited to inactivating mutations, which caused the increased production of outer-membrane vesicles, leading to modest fitness increases. In contrast, mutator clones with an average of ~30-fold higher mutation rate adapted much faster by acquiring both inactivating mutations of an outer-membrane porin and particularly inactivating and gain-of-function mutations, causing the upregulation or activation of a common efflux pump, respectively. Our results demonstrate how in very small populations, clonal interference and mutation bias together affect the choice of adaptive trajectories by mediating the balance between high-rate and large-benefit mutations.

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Exploring the expanse between theoretical questions and experimental approaches in the modern study of evolvability

Draghi

Ogbunugafor

2022

J Exp Zool Pt B

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Despite several decades of computational and experimental work across many systems, evolvability remains on the periphery with regards to its status as a widely accepted and regularly applied theoretical concept. Here we propose that its marginal status is partly a result of large gaps between the diverse but disconnected theoretical treatments of evolvability and the relatively narrower range of studies that have tested it empirically. To make this case, we draw on a range of examples—from experimental evolution in microbes, to molecular evolution in proteins—where attempts have been made to mend this disconnect. We highlight some examples of progress that has been made and point to areas where synthesis and translation of existing theory can lead to further progress in the still‐new field of empirical measurements of evolvability.

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Mutation bias can shape adaptation in large asexual populations experiencing clonal interference

Cited by 30 publications

References 46 publications

Asymmetric Evolvability Leads to Specialization without Trade-Offs

Asymmetric Evolvability Leads to Specialization without Trade-Offs

Clonal Interference and Mutation Bias in Small Bacterial Populations in Droplets

Exploring the expanse between theoretical questions and experimental approaches in the modern study of evolvability

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