Phenotypic and molecular evolution across 10,000 generations in laboratory budding yeast populations

Johnson, Milo S.; Gopalakrishnan, Shreyas; Goyal, Juhee; Dillingham, Megan E; Bakerlee, Christopher W; Humphrey, Parris T.; Jagdish, Tanush; Jerison, Elizabeth R.; Kosheleva, Katya; Lawrence, Katherine R.; Min, Jiseon; Moulana, Alief; Phillips, Angela M; Piper, Julia C; Purkanti, Ramya; Rego-Costa, Artur; McDonald, Michael J.; Ba, Alex N Nguyen; Desai, Michael M.

doi:10.7554/elife.63910

Cited by 78 publications

(93 citation statements)

References 70 publications

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“…Further, after 50,000 generations of purely asexual evolution, (Tenaillon et al, 2016) found an average fitness increase of ~1.7-fold amongst all replicate Escherichia coli populations during adaptation to nutrient limitation. These comparisons suggest that the presence of recombination and high levels of standing variation lead to much larger fitness gains than are normally seen in experiments with less variation and/or no recombination, at least over short bursts of evolution in a novel environment, consistent with early studies that have more directly made this observation (Johnson et al, 2021).…”

Section: Fitness Increased Substantially After 12 Weeks Of Evolutionsupporting

confidence: 76%

“…Under this asexual isogenic paradigm forces such as historical contingency (Toprak et al, 2011), genetic parallelism at the level of genes but not (except for rare exceptions, see (Toprak et al, 2011)) specific mutations (Tenaillon et al, 2012;Toprak et al, 2011), and diminishing returns epistasis (Toprak et al, 2011;Wang et al, 2016) matter a great deal to the evolutionary process. Similar studies in asexual isogenic diploids have shown that ploidy can influence the dynamics of adaptation, with diploids often adapting more slowly than haploids, likely due to the effects of Haldane's sieve (Fisher et al, 2018;Gerstein et al, 2014;Johnson et al, 2021;Marad et al, 2018;Sellis et al, 2016;Sellis et al, 2011;Zeyl et al, 2003). Diploids also appear to accumulate more potentially deleterious mutations (increased mutational load), and continue to adapt longer than haploids, likely due to the effects of mitotic recombination (Forche et al, 2011;Gerstein et al, 2014;Johnson et al, 2021).…”

Section: Introductionmentioning

confidence: 76%

“…Similar studies in asexual isogenic diploids have shown that ploidy can influence the dynamics of adaptation, with diploids often adapting more slowly than haploids, likely due to the effects of Haldane's sieve (Fisher et al, 2018;Gerstein et al, 2014;Johnson et al, 2021;Marad et al, 2018;Sellis et al, 2016;Sellis et al, 2011;Zeyl et al, 2003). Diploids also appear to accumulate more potentially deleterious mutations (increased mutational load), and continue to adapt longer than haploids, likely due to the effects of mitotic recombination (Forche et al, 2011;Gerstein et al, 2014;Johnson et al, 2021). Despite these differences, general aspects of adaptation are shared with asexual haploids, including clonal interference and the fixation of beneficial mutations.…”

Section: Introductionmentioning

confidence: 76%

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Adaptation in outbred sexual yeast is repeatable, polygenic, and favors rare haplotypes

Linder

Zabanavar

Majumder

et al. 2021

Preprint

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We describe the results of a 200 generation Evolve and Resequence (E&R) study initiated from an outbred dipliod recombined synthetic base population derived from 18 genetically diverse founders. Replicate populations were maintained at large effective population sizes (>105 individuals), exposed to several different chemical challenges over 12 weeks of evolution, and whole-genome resequenced. Weekly forced outcrossing implies a per gene per cell-division recombination rate higher than that achieved in Drosophila E&R studies. In 55 sexual populations we observe large fitness gains and highly repeatable patterns of genome-wide haplotype change within each chemical challenge. There was little evidence for pervasive pleiotropy, as evidenced by patterns of haplotype change between drug treatments. Within treatment adaptation appears highly polygenic with almost the entire genome showing significant consistent haplotype change. Finally, adaptation was almost always associated with only one of the 18 founder alleles, suggesting selection primarily acts on rare variants private to a founder or haplotype blocks harboring multiple mutations. This observation contradicts the notion that adaptation is often due to subtle frequency shifts at intermediate frequency variants.

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Section: Fitness Increased Substantially After 12 Weeks Of Evolutionsupporting

confidence: 76%

Section: Introductionmentioning

confidence: 76%

Section: Introductionmentioning

confidence: 76%

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Adaptation in outbred sexual yeast is repeatable, polygenic, and favors rare haplotypes

Linder

Zabanavar

Majumder

et al. 2021

Preprint

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“…Kozela and Johnston [8] examined the effects of growth-limiting salt stress on mutational variation and the mutation rate. Johnson et al [9] performed a large-scale evolutionary experiment in three environments and identified several features of adaptation thought to be common across many species. Other fungal species are rarely used in experimental evolution, although fungi, especially microfungi, are generally good experimental subjects due to their relatively short generation times, compact genomes, and large effective population sizes compared to other eukaryotes.…”

Section: Introductionmentioning

confidence: 99%

Seven Years at High Salinity—Experimental Evolution of the Extremely Halotolerant Black Yeast Hortaea werneckii

Gostinčar

Stajich

Kejžar

et al. 2021

JoF

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The experimental evolution of microorganisms exposed to extreme conditions can provide insight into cellular adaptation to stress. Typically, stress-sensitive species are exposed to stress over many generations and then examined for improvements in their stress tolerance. In contrast, when starting with an already stress-tolerant progenitor there may be less room for further improvement, it may still be able to tweak its cellular machinery to increase extremotolerance, perhaps at the cost of poorer performance under non-extreme conditions. To investigate these possibilities, a strain of extremely halotolerant black yeast Hortaea werneckii was grown for over seven years through at least 800 generations in a medium containing 4.3 M NaCl. Although this salinity is well above the optimum (0.8–1.7 M) for the species, the growth rate of the evolved H. werneckii did not change in the absence of salt or at high concentrations of NaCl, KCl, sorbitol, or glycerol. Other phenotypic traits did change during the course of the experimental evolution, including fewer multicellular chains in the evolved strains, significantly narrower cells, increased resistance to caspofungin, and altered melanisation. Whole-genome sequencing revealed the occurrence of multiple aneuploidies during the experimental evolution of the otherwise diploid H. werneckii. A significant overrepresentation of several gene groups was observed in aneuploid regions. Taken together, these changes suggest that long-term growth at extreme salinity led to alterations in cell wall and morphology, signalling pathways, and the pentose phosphate cycle. Although there is currently limited evidence for the adaptive value of these changes, they offer promising starting points for future studies of fungal halotolerance.

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“…Whether the multiple unlinked genes underlying a complex adaptation depend on each other to this degree is less well understood. Laboratory evolution has allowed genomic surveys (Blount et al, 2012; Good et al, 2017; Johnson et al, 2021; Kryazhimskiy et al, 2014) and, in some cases, experimental validation (Chou et al, 2011; Khan et al, 2011) of interactions between adaptive genes. Testing these principles in the context of evolution from the wild has posed a key challenge (although see Marcusson et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Joint effects of genes underlying a temperature specialization tradeoff in yeast

AlZaben

Chuong

Abrams

et al. 2021

Preprint

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A central goal of evolutionary genetics is to understand, at the molecular level, how organisms adapt to their environments. Landmark work has characterized steric clashes between variants arising in a given protein as it evolves a new function. For many traits, any such single gene represents only part of a complex architecture, whose genetic mechanisms remain poorly understood. We studied the joint effect of eight genes underlying thermotolerance in Saccharomyces cerevisiae, when introduced into a thermosensitive species, S. paradoxus. The data revealed no sign epistasis: most gene combinations boosted thermotolerance, and none was deleterious. And the genes also governed a heretofore unknown advantage in cold growth by S. paradoxus. These results shed light on how and why thermotolerance arose in S. cerevisiae, and they suggest a paradigm in which, if protein repacking is a difficult step in adaptation, combining whole-gene modules may be far less constrained.Author summaryThe building of new traits by evolution can be difficult and slow. A given DNA variant may be the linchpin of a beneficial trait in some individuals and, in others, have the opposite effect—torpedo fitness altogether. Such effects have been best studied among amino acids in a given protein, whose changing side chains crowd each other unless they arise in a particular order. We set out to complement this literature by studying adaptive variants that are not in the same protein, but rather scattered across unlinked genes. We used as a model system eight genes that govern the ability of the unicellular yeast Saccharomyces cerevisiae to grow at high temperature. We introduced this suite of genes stepwise into a non-thermotolerant sister species, and found that the more S. cerevisiae loci we added, the better the phenotype. We saw no evidence for toxic interactions between the variant genes as they were combined. We also used the eight-fold transgenic to dissect the mechanism and the evolutionary forces underlying the thermotolerance trait. Together, our data suggest a principle for the field in which repacking a given protein is the hard part of evolution, and assembling combinations of unlinked loci is far easier.

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Phenotypic and molecular evolution across 10,000 generations in laboratory budding yeast populations

Cited by 78 publications

References 70 publications

Adaptation in outbred sexual yeast is repeatable, polygenic, and favors rare haplotypes

Adaptation in outbred sexual yeast is repeatable, polygenic, and favors rare haplotypes

Seven Years at High Salinity—Experimental Evolution of the Extremely Halotolerant Black Yeast Hortaea werneckii

Joint effects of genes underlying a temperature specialization tradeoff in yeast

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