生物转化
俘获
Mercury(编程语言)
环境化学
环境修复
生物修复
化学
氧化还原
人体净化
硒化物
生物催化
生物反应器
氧阴离子
三硝基甲苯
电子转移
电子传输链
纳米技术
纳米颗粒
胞外聚合物
生物吸附
组合化学
环境友好型
生化工程
膜
资源回收
废水
细胞外
生物降解
细胞内
苯并菲
电化学
生物矿化
生物累积
作者
Yuting Wang,Zhenghao Li,Sheng-Lan Gong,Jun Jiang,Yulu Jiang,Yong Guan,Zhao Wu,Gang Liu,Yangchao Tian,Li‐Jiao Tian
标识
DOI:10.1021/acs.est.5c08193
摘要
Dissimilatory metal-reducing bacteria (DMRB) have the talent to convert mercury ions (Hg2+) into elemental mercury (Hg0). Here, we shed light on the directed biomineralization of Hg2+ into mercury selenide (HgSe), which is a promising environmental sink for Hg with minimal ecological risk. This process displays a controlled subcellular localization, improved efficiency, and redistribution of Hg species through the coordination of three modules, including reinforced respiratory, reconfigured electron flow, and anchored trap in Shewanella oneidensis MR-1, a model DMRB. By supplementing redox substance, we first construct a golden Hg2+ capture system, that is S. oneidensis-Se0 hybrid. Redox substance triggers a transition from intracellular selenite reduction to extracellular biosynthesis of Se0 nanoparticles (NPs), resulting in a notably increased yield of Se0 NPs. Importantly, this hybrid alters the biotransformation fate of Hg2+, enabling the efficient formation of less toxic HgSe nanoparticles and decreasing the percentage of volatile Hg0. Such a biological decontamination process relies on sufficient bioelectron donation, unimpeded electron channels, and highly effective Hg2+ traps, all of which can be initiated, directed, and coordinated by the redox-active compound. The resulting S. oneidensis-Se0 hybrid is feasible to scale up for the depuration of Hg2+ in artificial wastewater by using a membrane bioreactor (MBR). Our work provides an integrated strategy for designing biological capture to immobilize Hg2+, offering fundamental guidance to improve biotechnologies in environmental remediation and resource recovery.
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