2024
DOI: 10.3389/fmicb.2023.1340033
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Isolation and Cs+ resistance mechanism of Escherichia coli strain ZX-1

Daiki Kojima,
Shunsuke Tanaka,
Ayane Kurosaki
et al.

Abstract: This research aims to elucidate the physiological mechanisms behind the accidental acquisition of high-concentration cesium ions (Cs+) tolerance of Escherichia coli and apply this understanding to develop bioremediation technologies. Bacterial Cs+ resistance has attracted attention, but its physiological mechanism remains largely unknown and poorly understood. In a prior study, we identified the Cs+/H+ antiporter TS_CshA in Microbacterium sp. TS-1, resistant to high Cs+ concentrations, exhibits a low Cs+ affin… Show more

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“…This process is facilitated by the presence of arsenate reductase genes (arsC), resulting in an impressive degradation efficiency of 60%-80% (Wu et al, 2023a).• E. coli is vital in the chemical transformation and biosorption of volatile organic compounds and heavy metals, causing it to be critical in the chemical and metallurgical sectors. The cueO and cusA genes are crucial in maintaining a copper balance, exhibiting 50%-70% efficiency in copper degradation (Kojima et al, 2024).• Sphingomonas sp. is highly proficient in the enzymatic breakdown of polychlorinated biphenyls (PCBs) and dioxins.…”
Section: ) Genetic Modification Techniques Utilizing the Crispr-cas9mentioning
confidence: 99%
“…This process is facilitated by the presence of arsenate reductase genes (arsC), resulting in an impressive degradation efficiency of 60%-80% (Wu et al, 2023a).• E. coli is vital in the chemical transformation and biosorption of volatile organic compounds and heavy metals, causing it to be critical in the chemical and metallurgical sectors. The cueO and cusA genes are crucial in maintaining a copper balance, exhibiting 50%-70% efficiency in copper degradation (Kojima et al, 2024).• Sphingomonas sp. is highly proficient in the enzymatic breakdown of polychlorinated biphenyls (PCBs) and dioxins.…”
Section: ) Genetic Modification Techniques Utilizing the Crispr-cas9mentioning
confidence: 99%