Experimental evolution of Saccharomyces cerevisiae for caffeine tolerance alters multidrug resistance and target of rapamycin signaling pathways.

IF 2.1 3区生物学 Q3 GENETICS & HEREDITY

G3: Genes|Genomes|Genetics Pub Date : 2024-09-04 DOI:10.1093/g3journal/jkae148

Renee C Geck, Naomi G Moresi, Leah M Anderson, Rebecca Brewer, Timothy R Renz, Matthew Bryce Taylor, Maitreya J Dunham

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引用次数: 0

Abstract

Caffeine is a natural compound that inhibits the major cellular signaling regulator target of rapamycin (TOR), leading to widespread effects including growth inhibition. Saccharomyces cerevisiae yeast can adapt to tolerate high concentrations of caffeine in coffee and cacao fermentations and in experimental systems. While many factors affecting caffeine tolerance and TOR signaling have been identified, further characterization of their interactions and regulation remain to be studied. We used experimental evolution of S. cerevisiae to study the genetic contributions to caffeine tolerance in yeast, through a collaboration between high school students evolving yeast populations coupled with further research exploration in university labs. We identified multiple evolved yeast populations with mutations in PDR1 and PDR5, which contribute to multidrug resistance, and showed that gain-of-function mutations in multidrug resistance family transcription factors Pdr1, Pdr3, and Yrr1 differentially contribute to caffeine tolerance. We also identified loss-of-function mutations in TOR effectors Sit4, Sky1, and Tip41 and showed that these mutations contribute to caffeine tolerance. These findings support the importance of both the multidrug resistance family and TOR signaling in caffeine tolerance and can inform future exploration of networks affected by caffeine and other TOR inhibitors in model systems and industrial applications.

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实验进化 S. cerevisiae 对咖啡因的耐受性改变了多药耐受性和 TOR 信号通路。

咖啡因是一种天然化合物，可抑制主要的细胞信号调节因子 TOR，从而产生包括生长抑制在内的广泛影响。在咖啡和可可发酵过程中以及在实验系统中，S. cerevisiae 酵母菌能适应高浓度咖啡因的耐受性。虽然已经发现了许多影响咖啡因耐受性和 TOR 信号转导的因素，但它们之间的相互作用和调控仍有待进一步研究。通过高中生合作进化酵母种群以及大学实验室的进一步研究探索，我们利用 S. cerevisiae 的实验进化来研究酵母对咖啡因耐受性的遗传贡献。我们发现了多个进化酵母种群中存在PDR1和PDR5的突变，这两个基因突变导致了多药耐受性，并表明多药耐受性家族转录因子Pdr1、Pdr3和Yrr1的功能增益突变对咖啡因耐受性有不同的贡献。我们还发现了TOR效应因子Sit4、Sky1和Tip41的功能缺失突变，并表明这些突变有助于提高咖啡因耐受性。这些发现证明了多药耐药性家族和 TOR 信号转导在咖啡因耐受性中的重要性，并为今后在模型系统和工业应用中探索受咖啡因和其他 TOR 抑制剂影响的网络提供了信息。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

G3: Genes|Genomes|Genetics GENETICS & HEREDITY-

CiteScore

5.10

自引率

3.80%

发文量

305

审稿时长

3-8 weeks

期刊介绍： G3: Genes, Genomes, Genetics provides a forum for the publication of high‐quality foundational research, particularly research that generates useful genetic and genomic information such as genome maps, single gene studies, genome‐wide association and QTL studies, as well as genome reports, mutant screens, and advances in methods and technology. The Editorial Board of G3 believes that rapid dissemination of these data is the necessary foundation for analysis that leads to mechanistic insights. G3, published by the Genetics Society of America, meets the critical and growing need of the genetics community for rapid review and publication of important results in all areas of genetics. G3 offers the opportunity to publish the puzzling finding or to present unpublished results that may not have been submitted for review and publication due to a perceived lack of a potential high-impact finding. G3 has earned the DOAJ Seal, which is a mark of certification for open access journals, awarded by DOAJ to journals that achieve a high level of openness, adhere to Best Practice and high publishing standards.