Identification of key transcription factors, including DAL80 and CRZ1, involved in heat and ethanol tolerance in Saccharomyces cerevisiae

IF 6.1 1区工程技术 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Biotechnology for Biofuels Pub Date : 2025-05-03 DOI:10.1186/s13068-025-02653-2

Rong-Rong Chen, Li Wang, Xue-Xue Ji, Cai-Yun Xie, Yue-Qin Tang

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Abstract

Background

High temperature and ethanol are two critical stress factors that significantly challenge bioethanol production using Saccharomyces cerevisiae. In this study, the tolerance mechanisms of the multi-tolerant S. cerevisiae strain E-158 to heat stress and combined heat-ethanol stress were investigated using comparative transcriptomics.

Results

Under heat stress at 44 °C, glucose transport and reactive oxygen species (ROS) scavenging were significantly upregulated, while gluconeogenesis, acetate formation, and dNDP formation showed significant downregulation. Under combined heat (43 °C) and ethanol (3% v/v) stress, glucose transport, glycolysis, acetate formation, peroxisome activity, ROS scavenging, and ribosome synthesis were significantly upregulated, while glycerol formation, cellular respiration and dNDP formation exhibited significant downregulation. Fourteen transcription factors (TFs), considered to play a key role in both stress conditions, were individually overexpressed and deleted in S. cerevisiae strain KF-7 in this study. Among these TFs, Gis1p, Crz1p, Tos8p, Yap1p, Dal80p, Uga3p, Mig1p, and Opi1p were found to contribute to enhanced heat tolerance in S. cerevisiae. Compared with KF-7, strains overexpressing DAL80 and CRZ1 demonstrated markedly improved fermentation performance under stress conditions. Under heat stress at 44 °C, glucose consumption increased by 10% and 12%, respectively, for strains KF7DAL80 and KF7CRZ1, while ethanol production increased by 12% and 15%, respectively, compared to KF-7. Under combined stress conditions of 43 °C and 3% (v/v) ethanol, glucose consumption increased by 67% and 44%, ethanol production by 116% and 77%, and ethanol yield by 29% and 22%, respectively, for KF7DAL80 and KF7CRZ1 compared to KF-7. KF7CRZ1 performs comparably to E-158, while KF7DAL80 outperforms E-158.

Conclusions

This study provides valuable theoretical insights and identifies critical TF targets, contributing to the development of robust S. cerevisiae strains for improved bioethanol production.

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酿酒酵母耐热和乙醇耐受关键转录因子DAL80和CRZ1的鉴定

高温和乙醇是影响酿酒酵母生产生物乙醇的两个关键胁迫因素。本研究利用比较转录组学方法研究了多耐酿酒葡萄球菌E-158对热胁迫和热乙醇联合胁迫的耐受机制。结果44℃热应激下，葡萄糖转运和活性氧清除显著上调，糖异生、醋酸盐生成和dNDP生成显著下调。在高温（43°C）和乙醇（3% v/v）复合胁迫下，葡萄糖转运、糖酵解、乙酸形成、过氧化物酶体活性、ROS清除和核糖体合成显著上调，甘油形成、细胞呼吸和dNDP形成显著下调。在本研究中，酿酒葡萄球菌菌株KF-7中有14个转录因子（TFs）分别过表达和缺失，这些转录因子被认为在两种应激条件下都起着关键作用。在这些TFs中，Gis1p、Crz1p、Tos8p、Yap1p、Dal80p、Uga3p、Mig1p和Opi1p参与了酿酒葡萄耐热性的增强。与KF-7相比，过表达DAL80和CRZ1的菌株在应激条件下的发酵性能明显提高。在44℃高温胁迫下，菌株KF7DAL80和KF7CRZ1的葡萄糖消耗量分别比KF-7增加了10%和12%，乙醇产量分别比KF-7增加了12%和15%。与KF-7相比，在43°C和3% （v/v）乙醇的组合胁迫条件下，KF7DAL80和KF7CRZ1的葡萄糖消耗增加了67%和44%，乙醇产量分别增加了116%和77%，乙醇产量分别增加了29%和22%。KF7CRZ1性能与E-158相当，而KF7DAL80性能优于E-158。结论本研究提供了有价值的理论见解，并确定了关键的TF靶点，有助于开发健壮的酿酒葡萄球菌菌株，以提高生物乙醇的产量。

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来源期刊

Biotechnology for Biofuels 工程技术-生物工程与应用微生物

自引率

0.00%

发文量

审稿时长

2.7 months

期刊介绍： Biotechnology for Biofuels is an open access peer-reviewed journal featuring high-quality studies describing technological and operational advances in the production of biofuels, chemicals and other bioproducts. The journal emphasizes understanding and advancing the application of biotechnology and synergistic operations to improve plants and biological conversion systems for the biological production of these products from biomass, intermediates derived from biomass, or CO2, as well as upstream or downstream operations that are integral to biological conversion of biomass. Biotechnology for Biofuels focuses on the following areas: • Development of terrestrial plant feedstocks • Development of algal feedstocks • Biomass pretreatment, fractionation and extraction for biological conversion • Enzyme engineering, production and analysis • Bacterial genetics, physiology and metabolic engineering • Fungal/yeast genetics, physiology and metabolic engineering • Fermentation, biocatalytic conversion and reaction dynamics • Biological production of chemicals and bioproducts from biomass • Anaerobic digestion, biohydrogen and bioelectricity • Bioprocess integration, techno-economic analysis, modelling and policy • Life cycle assessment and environmental impact analysis