Role of mutator alleles in adaptive evolution

Taddéi, François; Radman, Miroslav; Maynard-Smith, John; Toupance, Bruno; Gouyon, Pierre‐Henri; Godelle, Bernard

doi:10.1038/42696

Cited by 640 publications

(581 citation statements)

References 28 publications

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“…By so doing, mutagenesis is favoured over cell death, and it has been widely discussed that mutator phenotypes have an adaptive value in prokaryotes 118,119 . The paradigm of the XPV syndrome, in which a TLS polymerase deficiency results in sunlight sensitivity and an increased risk of skin cancers, suggests an alternative scenario in higher organisms.…”

Section: Resultsmentioning

confidence: 99%

DNA polymerases in adaptive immunity

Weill

Reynaud

2008

Nat Rev Immunol

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PrefaceTo cope with an unpredictable variety of potential pathogenic insults, the immune system must generate an enormous diversity of recognition structures, and it does so by making stepwise modifications of key genetic loci in each lymphoid cell. This proceeds through the action of lymphoid-specific proteins acting together with the general DNA-repair machinery of the cell. Strikingly, these general mechanisms are usually diverted from their normal functions, being used in rather atypical ways in order to privilege diversity over accuracy. In this Review, we focus on the contribution of a set of DNA polymerases discovered in the last decade to these unique DNA transactions.

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Section: Resultsmentioning

confidence: 99%

DNA polymerases in adaptive immunity

Weill

Reynaud

2008

Nat Rev Immunol

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“…As the mutators produce not only deleterious but also beneficial mutations at a higher rate than the nonmutators, the mutator allele can hitchhike to fixation with favorable mutations (Smith and Haigh 1974; Taddei et al. 1997). However, once the population has reached a high fitness level, high mutation rates are detrimental because most mutations will now be deleterious, and in such a situation, the mutation rate is expected to decrease (Liberman and Feldman 1986).…”

Section: Introductionmentioning

confidence: 99%

“…An important difference between the previous works on mutator hitchhiking (Taddei et al. 1997; Andre and Godelle 2006; Wylie et al. 2009; Desai and Fisher 2011) and our study is that here the mutator population is assumed to be at mutation‐selection equilibrium and is therefore not under positive selection.…”

Section: Introductionmentioning

confidence: 99%

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Fixation probability of rare nonmutator and evolution of mutation rates

James

Jain

2016

Ecology and Evolution

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Although mutations drive the evolutionary process, the rates at which the mutations occur are themselves subject to evolutionary forces. Our purpose here is to understand the role of selection and random genetic drift in the evolution of mutation rates, and we address this question in asexual populations at mutation‐selection equilibrium neglecting selective sweeps. Using a multitype branching process, we calculate the fixation probability of a rare nonmutator in a large asexual population of mutators and find that a nonmutator is more likely to fix when the deleterious mutation rate of the mutator population is high. Compensatory mutations in the mutator population are found to decrease the fixation probability of a nonmutator when the selection coefficient is large. But, surprisingly, the fixation probability changes nonmonotonically with increasing compensatory mutation rate when the selection is mild. Using these results for the fixation probability and a drift‐barrier argument, we find a novel relationship between the mutation rates and the population size. We also discuss the time to fix the nonmutator in an adapted population of asexual mutators, and compare our results with experiments.

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“…On the one hand, this means that we are able to obtain analytical expressions for the exponential evolution and saturation of the mutation probability, which could eventually be used when studying in vitro long‐term evolutionary experiments with cancer populations, using serial transfer methods similar to those performed on viruses (see e.g., Drake, 1993; Sanjuán et al., 2010; Solé et al., 1999) or bacterial populations (see e.g., Moxon et al., 1994; Sniegowski, Gerrish, & Lenski, 1997; Barrick et al., 2009 for experiments and Taddei et al., 1997 for an early model for mutator alleles). Given the remarkable similarities found between microbial communities found both in the ecological and evolutionary time scales (Lambert et al., 2011), it would be worth exploring the evolution of instability of cancer cell cultures over many transfer generations (Langdon, 2004).…”

Section: Discussionmentioning

confidence: 99%

Adaptive dynamics of unstable cancer populations: The canonical equation

Aguadé-Gorgorió

Solé

2018

Evolutionary Applications

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In most instances of tumour development, genetic instability plays a role in allowing cancer cell populations to respond to selection barriers, such as physical constraints or immune responses, and rapidly adapt to an always changing environment. Modelling instability is a nontrivial task, since by definition evolving instability leads to changes in the underlying landscape. In this article, we explore mathematically a simple version of unstable tumour progression using the formalism of adaptive dynamics (AD) where selection and mutation are explicitly coupled. Using a set of basic fitness landscapes, the so‐called canonical equation for the evolution of genetic instability on a minimal scenario associated with a population of unstable cells is derived. We obtain explicit expressions for the evolution of mutation probabilities, and the implications of the model on further experimental studies and potential mutagenic therapies are discussed.

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Role of mutator alleles in adaptive evolution

Cited by 640 publications

References 28 publications

DNA polymerases in adaptive immunity

DNA polymerases in adaptive immunity

Fixation probability of rare nonmutator and evolution of mutation rates

Adaptive dynamics of unstable cancer populations: The canonical equation

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