平衡
转录因子
转录组
调节器
突变体
超氧化物歧化酶
生物化学
酵母
化学
细胞生物学
基因
活性氧
氧化应激
拉伤
细胞内
转录调控
突变
生物
基因表达
酿酒酵母
细胞
抄写(语言学)
焊剂(冶金)
氧化磷酸化
基因表达调控
基因组
代谢工程
生产过剩
作者
Li Sun,XIANHAO XU,Y. Wu,Yanfeng Liu,Tianmin Zhang,Jianghua Li,Guocheng Du,Long Liu,Xueqin Lv
标识
DOI:10.1021/acs.jafc.5c10561
摘要
mutant strain TAMC, which can tolerate an acidic environment of pH 2.3, was isolated via adaptive laboratory evolution; however, the genetic basis underlying the acid tolerance of this strain remained unclear. Herein, we aimed to elucidate the genetic basis of TAMC's acid tolerance via genome sequencing and functional analysis. The results revealed that a mutation (mROX1) in transcriptional regulator ROX1 was crucial for acid tolerance. Comparative transcriptome mining and reverse engineering revealed that the mROX1 mutation mediated cellular oxidation-reduction stress homeostasis maintenance by upregulating the expression of superoxide dismutase homologues and catalase, facilitating tolerance to acidity and detoxifying reactive oxygen species. This work uncovers a novel yeast intracellular homeostasis mechanism, providing a potential strategy for engineering novel acid-tolerant microbial cell chassis.
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