Multiple peaks and reciprocal sign epistasis in an empirically determined genotype-phenotype landscape

Dawid, Alexandre; Kiviet, Daniel J.; Kogenaru, Manjunatha; Vos, Marjon G. J. de; Tans, Sander J.

doi:10.1063/1.3453602

Cited by 38 publications

(44 citation statements)

References 35 publications

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“…Note that the repression ability (R) is, thus, not the inverse of the expression ability (E). We constructed four lac repressor-operator variants that have been predicted (45)(46)(47)(48) to display binding: PK:agga, PS: acca, MK:acca, and YQ:tggt, where the first two letters indicate the controlling repressor residues and the last four letters indicate the controlling operator bases ( Fig. 1 A and B).…”

Section: Resultsmentioning

confidence: 99%

Breaking evolutionary constraint with a tradeoff ratchet

Vos

Dawid

Šunderlíková

et al. 2015

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

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Epistatic interactions can frustrate and shape evolutionary change. Indeed, phenotypes may fail to evolve when essential mutations are only accessible through positive selection if they are fixed simultaneously. How environmental variability affects such constraints is poorly understood. Here, we studied genetic constraints in fixed and fluctuating environments using the Escherichia coli lac operon as a model system for genotypeenvironment interactions. We found that, in different fixed environments, all trajectories that were reconstructed by applying point mutations within the transcription factor-operator interface became trapped at suboptima, where no additional improvements were possible. Paradoxically, repeated switching between these same environments allows unconstrained adaptation by continuous improvements. This evolutionary mode is explained by pervasive cross-environmental tradeoffs that reposition the peaks in such a way that trapped genotypes can repeatedly climb ascending slopes and hence, escape adaptive stasis. Using a Markov approach, we developed a mathematical framework to quantify the landscape-crossing rates and show that this ratchet-like adaptive mechanism is robust in a wide spectrum of fluctuating environments. Overall, this study shows that genetic constraints can be overcome by environmental change and that crossenvironmental tradeoffs do not necessarily impede but also, can facilitate adaptive evolution. Because tradeoffs and environmental variability are ubiquitous in nature, we speculate this evolutionary mode to be of general relevance.evolution | environment | epistasis | fitness landscape | constraint I t is widely believed that epistatic interactions can direct evolutionary change (1-7). Epistasis has been implicated in shaping RNA (8) and protein (4, 6, 7, 9) sequences, sensing (5) and translation (10) functions, and developmental programs (11) and speciation (12)(13)(14). Phenotypes may be difficult to evolve not because they are impossible biochemically or physically, but because essential mutations are mutually dependent and must be fixed together to be selected positively (5,(15)(16)(17). How such genetic constraints can be overcome has been considered previously: population expansion or subdivision can limit negative selection and maintain less fit phenotypes (18,19), and large populations and long waiting times can enable the joint fixation of multiple mutations (20), whereas recombination can join mutant alleles (21-23). Other mechanisms include drift (24-26), partial penetrance (27), and nonheritable lifetime plasticity (28, 29). However, how the constraining effects of such genetic interactions are affected by environmental variability remains poorly understood. It has been shown that mutational effects (30-33) and epistasis itself (34, 35) can depend on the environment, that bacterial resistance evolution can be contingent on the rate of antibiotic increase (36), and that adaptation in silico can be accelerated by environmental change (37-40). These observations sugg...

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Section: Resultsmentioning

confidence: 99%

Breaking evolutionary constraint with a tradeoff ratchet

Vos

Dawid

Šunderlíková

et al. 2015

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

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“…These studies show that only a limited number of pathways to the highly adapted genotype are feasible (continuously increasing in fitness), suggesting that epistatic interactions impose constraints that may render evolution more predictable 1,2,11 . However, adaptive landscapes can often have multiple distinct adaptive peaks, of which some may be more readily attainable than others 5,12,13 . Key to the predictability of evolution is whether and how early does evolution commit to a final genotypic state.…”

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confidence: 99%

Delayed commitment to evolutionary fate in antibiotic resistance fitness landscapes

et al. 2015

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Predicting evolutionary paths to antibiotic resistance is key for understanding and controlling drug resistance. When considering a single final resistant genotype, epistatic contingencies among mutations restricts evolution to a small number of adaptive paths. Less attention has been given to multi-peak landscapes, and while specific peaks can be favored, it is unknown whether and how early a commitment to final fate is made. Here we characterized a multi-peaked adaptive landscape for trimethoprim resistance by constructing all combinatorial alleles of seven resistance-conferring mutations in dihydrofolate reductase. We observe that epistatic interactions increase rather than decrease the accessibility of each peak; while they restrict the number of direct paths, they generate more indirect paths, where mutations are adaptively gained and later adaptively lost or changed. This enhanced accessibility allows evolution to proceed through many adaptive steps while delaying commitment to genotypic fate, hindering our ability to predict or control evolutionary outcomes.

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“…Is it a protein’s activity [14] or its cofactor binding affinity [15]? Is it the regulatory response of a repressor-operator pair [16] or is it the rate of a process such as CO 2 assimilation [9]? And if it actually is true Darwinian fitness, is fitness estimated in terms of differential reproduction [17] or in terms of differential survivorship [7], or as is possible in microbial studies, both?…”

Section: Introductionmentioning

confidence: 99%

“…But how often do empirical fitness landscapes exhibit such topography? Analysis of in vivo data on repressor-operator pairs in the lac system of Escherichia coli reveals 19 distinct peaks [16]. Multiple, deep fitness valleys have recently been demonstrated in adaptation of HIV-1 to its secondary cell-surface chemokine co-receptor, CXCR4 [30, 31].…”

Section: Introductionmentioning

confidence: 99%

The Valley-of-Death: Reciprocal sign epistasis constrains adaptive trajectories in a constant, nutrient limiting environment

et al. 2014

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The fitness landscape is a powerful metaphor for describing the relationship between genotype and phenotype for a population under selection. However, empirical data as to the topography of fitness landscapes are limited, owing to difficulties in measuring fitness for large numbers of genotypes under any condition. We previously reported a case of reciprocal sign epistasis (RSE), where two mutations individually increased yeast fitness in a glucose-limited environment, but reduced fitness when combined, suggesting the existence of two peaks on the fitness landscape. We sought to determine whether a ridge connected these peaks so that populations founded by one mutant could reach the peak created by the other, avoiding the low-fitness “Valley-of-Death” between them. Sequencing clones after 250 generations of further evolution provided no evidence for such a ridge, but did reveal many presumptive beneficial mutations, adding to a growing body of evidence that clonal interference pervades evolving microbial populations.

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Multiple peaks and reciprocal sign epistasis in an empirically determined genotype-phenotype landscape

Cited by 38 publications

References 35 publications

Breaking evolutionary constraint with a tradeoff ratchet

Breaking evolutionary constraint with a tradeoff ratchet

Delayed commitment to evolutionary fate in antibiotic resistance fitness landscapes

The Valley-of-Death: Reciprocal sign epistasis constrains adaptive trajectories in a constant, nutrient limiting environment

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