光催化
细菌
化学
膜
细菌细胞结构
单元格信封
生物物理学
化学工程
催化作用
生物化学
生物
大肠杆菌
遗传学
基因
工程类
作者
Kemeng Xiao,Tianqi Wang,Mingzhe Sun,Aamir Hanif,Qinfen Gu,Bingbing Tian,Zhifeng Jiang,Bo Wang,Hongli Sun,Jin Shang,Po Keung Wong
标识
DOI:10.1021/acs.est.9b05627
摘要
and •OH), played major roles in inactivating bacteria. The antioxidant system of bacteria exhibited a self-protection capacity by eliminating the photogenerated RSs from PM biohybrid at the early stage of inactivation. With the accumulation of RSs, the cell membrane and membrane-associated functions were destroyed, as suggested by the collapse of cell envelope and subsequent loss of cell respiration and ATP synthesis capacity. The microscopic images further confirmed the destruction of the bacterial membrane. After losing the membrane barrier, the oxidation of cytoplasmic proteins and lipids caused by invaded RSs occurred readily. Finally, the leakage of DNA and RNA announced the irreversible death of bacteria. These results indicated that the bacterial inactivation began with the membrane rupture, followed by the oxidation and leakage of intracellular substances. This work not only provided a new insight into the combination of semiconductors with earth-abundant biomaterials for fabricating high-performance photocatalysts, but also revealed the underlying mechanisms of photocatalytic bacterial inactivation in depth.
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