Cellular mechanisms contributing to multiple stress tolerance in Saccharomyces cerevisiae strains with potential use in high-temperature ethanol fermentation

发酵 酵母 酿酒酵母 海藻糖 乙醇燃料 渗透性休克 乙醇发酵 乙醇 热休克蛋白 细胞外 生物 生物化学 溶解 热冲击 活力测定 热冲击 食品科学 细胞 基因 材料科学 复合材料
作者
Yasin Kitichantaropas,Chuenchit Boonchird,Minetaka Sugiyama,Yoshinobu Kaneko,Satoshi Harashima,Choowong Auesukaree
出处
期刊:AMB Express [Springer Nature]
卷期号:6 (1) 被引量:78
标识
DOI:10.1186/s13568-016-0285-x
摘要

High-temperature ethanol fermentation has several benefits including a reduction in cooling cost, minimizing risk of bacterial contamination, and enabling simultaneous saccharification and fermentation. To achieve the efficient ethanol fermentation at high temperature, yeast strain that tolerates to not only high temperature but also the other stresses present during fermentation, e.g., ethanol, osmotic, and oxidative stresses, is indispensable. The C3253, C3751, and C4377 Saccharomyces cerevisiae strains, which have been previously isolated as thermotolerant yeasts, were found to be multiple stress-tolerant. In these strains, continuous expression of heat shock protein genes and intracellular trehalose accumulation were induced in response to stresses causing protein denaturation. Compared to the control strains, these multiple stress-tolerant strains displayed low intracellular reactive oxygen species levels and effective cell wall remodeling upon exposures to almost all stresses tested. In response to simultaneous multi-stress mimicking fermentation stress, cell wall remodeling and redox homeostasis seem to be the primary mechanisms required for protection against cell damage. Moreover, these strains showed better performances of ethanol production than the control strains at both optimal and high temperatures, suggesting their potential use in high-temperature ethanol fermentation.

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