Mapping Ethanol Tolerance in Budding Yeast Reveals High Genetic Variation in a Wild Isolate

Haas, Roni; Horev, Guy; Lipkin, E.; Kesten, Inbar; Portnoy, Maya; Buhnik-Rosenblau, Keren; Soller, M.; Kashi, Yechezkel

doi:10.3389/fgene.2019.00998

Cited by 13 publications

(7 citation statements)

References 93 publications

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“…Ethanol also exhibits a general cell toxicity that yeasts used to control competitors’ growth. This duality (nutrient and stressor) generates great concerns in the biotechnological industries (by its applications) and in the scientific community (by its molecular basis), highlighting the importance of systems biology studies (reviewed in references 9 to 12 ).…”

Section: Introductionmentioning

confidence: 99%

Transcriptional Rewiring, Adaptation, and the Role of Gene Duplication in the Metabolism of Ethanol of Saccharomyces cerevisiae

et al. 2020

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Ethanol is the main by-product of yeast sugar fermentation that affects microbial growth parameters, being considered a dual molecule, a nutrient and a stressor. Previous works demonstrated that the budding yeast arose after an ancient hybridization process resulted in a tier of duplicated genes within its genome, many of them with implications in this ethanol “produce-accumulate-consume” strategy. The evolutionary link between ethanol production, consumption, and tolerance versus ploidy and stability of the hybrids is an ongoing debatable issue. The implication of ancestral duplicates in this metabolic rewiring, and how these duplicates differ transcriptionally, remains unsolved. Here, we study the transcriptomic adaptive signatures to ethanol as a nonfermentative carbon source to sustain clonal yeast growth by experimental evolution, emphasizing the role of duplicated genes in the adaptive process. As expected, ethanol was able to sustain growth but at a lower rate than glucose. Our results demonstrate that in asexual populations a complete transcriptomic rewiring was produced, strikingly by downregulation of duplicated genes, mainly whole-genome duplicates, whereas small-scale duplicates exhibited significant transcriptional divergence between copies. Overall, this study contributes to the understanding of evolution after gene duplication, linking transcriptional divergence with duplicates’ fate in a multigene trait as ethanol tolerance. IMPORTANCE Gene duplication events have been related with increasing biological complexity through the tree of life, but also with illnesses, including cancer. Early evolutionary theories indicated that duplicated genes could explore alternative functions due to relaxation of selective constraints in one of the copies, as the other remains as ancestral-function backup. In unicellular eukaryotes like yeasts, it has been demonstrated that the fate and persistence of duplicates depend on duplication mechanism (whole-genome or small-scale events), shaping their actual genomes. Although it has been shown that small-scale duplicates tend to innovate and whole-genome duplicates specialize in ancestral functions, the implication of duplicates’ transcriptional plasticity and transcriptional divergence on environmental and metabolic responses remains largely obscure. Here, by experimental adaptive evolution, we show that Saccharomyces cerevisiae is able to respond to metabolic stress (ethanol as nonfermentative carbon source) due to the persistence of duplicated genes. These duplicates respond by transcriptional rewiring, depending on their transcriptional background. Our results shed light on the mechanisms that determine the role of duplicates, and on their evolvability.

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Section: Introductionmentioning

confidence: 99%

Transcriptional Rewiring, Adaptation, and the Role of Gene Duplication in the Metabolism of Ethanol of Saccharomyces cerevisiae

et al. 2020

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“…Fifty‐one quantitative trait loci (QTLs) have been found to affect the growth while 96 QTLs to affect the survival of the yeast under ethanol stress. For example, MOG1, MGS1, and YJR154W have been mapped as novel genes for phenotyping of growth variation (34%) and survival (72%) (Haas et al, 2019). In another study, Kluyveromyces marxianus was subjected to adaptive evolution at 6% ethanol concentration for 100 days.…”

Section: Evolutionary Basis For Multiple Stress Conditionsmentioning

confidence: 99%

Recent advances in yeast genome evolution with stress tolerance for green biological manufacturing

Zhang

Guo

et al. 2022

Biotech & Bioengineering

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Green biological manufacturing is a revolutionary industrial model utilizing yeast as a significant microbial cell factory to produce biofuels and other biochemicals. However, biotransformation efficiency is often limited owing to several stress factors resulting from environmental changes or metabolic imbalance, leading to the slow growth of cells, compromised yield, and enhanced energy consumption. These factors make biological manufacturing competitively less economical. In this regard, minimizing the stress impact on microbial cell factories and strong robust performance have been an interesting area of interest in the last few decades. In this review, we focused on revealing the stress factors and their associated mechanisms for yeast in biological manufacturing. To improve yeast tolerance, rational and irrational strategies were introduced, and the molecular basis of genome evolution in yeast was also summarized. Furthermore, strategies of genome‐directed evolution such as homology directed repair and nonhomologous end‐joining, and the synthetic chromosome recombination and modification by LoxP‐mediated evolution and their association with stress tolerance was highlighted. We hope that genome evolution provides new insights for solving the limitations of the natural phenotypes of microorganisms in industrial fermentation for the production of valuable compounds.

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“…Genetic mapping of the variants associated with the phenotype of interest in strain SA-1 utilized a combined approach of individual phenotyping and bulk whole-genome analysis, followed by a bioinformatics pipeline to identify rare NS mutations in the candidate gene. Previous studies employing a QTL mapping strategy to infer causative genes for ethanol tolerance in yeast have already been documented (Haas et al, 2019; Ho et al, 2021; Riles and Fay, 2019; Swinnen et al, 2012). These investigations have proven the following genes are linked to this phenotype: MOG1, MGS1 , and YJR154W (Haas et al, 2019); SEC24 (Riles and Fay, 2019); MKT1 , SWS2 , and APJ1 (Swinnen et al, 2012).…”

Section: Discussionmentioning

confidence: 99%

Unveiling genetic anchors in Saccharomyces cerevisiae: QTL mapping identifies IRA2 as a key player in ethanol tolerance and beyond

Tristão,

de Sousa,

Vargas

et al. 2024

Preprint

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Ethanol stress inSaccharomyces cerevisiaeis a well-studied phenomenon, but pinpointing specific genes or polymorphisms governing ethanol tolerance remains a subject of ongoing debate. Naturally found in sugar-rich environments, this yeast has evolved to withstand high ethanol concentrations, primarily produced during fermentation in the presence of suitable oxygen or sugar levels. Originally a defense mechanism against competing microorganisms, yeast-produced ethanol is now a cornerstone of brewing and bioethanol industries, where customized yeasts require high ethanol resistance for economic viability. However, yeast strains exhibit varying degrees of ethanol tolerance, ranging from 8% to 20%, making the genetic architecture of this trait complex and challenging to decipher. In this study, we introduce a novel QTL mapping pipeline to investigate the genetic markers underlying ethanol tolerance in an industrial bioethanolS. cerevisiaestrain. By calculating missense mutation frequency in a prominent QTL region within a population of 1011S. cerevisiaestrains, we uncovered rare occurrences in geneIRA2. Following molecular validation, we confirmed the significant contribution of this gene to ethanol tolerance, particularly in concentrations exceeding 12% of ethanol.IRA2pivotal role in stress tolerance due to its participation in the Ras-cAMP pathway was further supported by its involvement in other tolerance responses, including thermotolerance, low pH tolerance, and resistance to acetic acid. Understanding the genetic basis of ethanol stress inS. cerevisiaeholds promise for developing robust yeast strains tailored for industrial applications.

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Mapping Ethanol Tolerance in Budding Yeast Reveals High Genetic Variation in a Wild Isolate

Cited by 13 publications

References 93 publications

Transcriptional Rewiring, Adaptation, and the Role of Gene Duplication in the Metabolism of Ethanol of Saccharomyces cerevisiae

Transcriptional Rewiring, Adaptation, and the Role of Gene Duplication in the Metabolism of Ethanol of Saccharomyces cerevisiae

Recent advances in yeast genome evolution with stress tolerance for green biological manufacturing

Unveiling genetic anchors in Saccharomyces cerevisiae: QTL mapping identifies IRA2 as a key player in ethanol tolerance and beyond

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