用于从酸性/中性水性废物中生物修复重金属的重组耐辐射球菌细胞。

Recombinant D. radiodurans cells for bioremediation of heavy metals from acidic/neutral aqueous wastes.

作者信息

Misra Chitra Seetharam, Appukuttan Deepti, Kantamreddi Venkata Siva Satyanarayana, Rao Amara S, Apte Shree Kumar

机构信息

Molecular Biology Division, Bhabha Atomic Research Centre, Mumbai, India.

出版信息

Bioeng Bugs. 2012 Jan 1;3(1):44-8. doi: 10.4161/bbug.3.1.18878.

DOI:10.4161/bbug.3.1.18878

PMID:22179144

Abstract

The stability and superior metal bioremediation ability of genetically engineered Deinococcus radiodurans cells, expressing a non-specific acid phosphatase, PhoN in high radiation environment has already been established. The lyophilized recombinant DrPhoN cells retained PhoN activity and uranium precipitation ability. Such cells also displayed an extended shelf life of 6 months during storage at room temperature and showed surface associated precipitation of uranium as well as other metals like cadmium. Lyophilized cells, immobilized in polyacrylamide gels could be used for uranium bioprecipitation in a flow through system resulting in 70% removal from 1mM input uranium solution and a loading of 1 g uranium/g dry weight cells. Compared with a batch process which achieved a loading of 5.7 g uranium/g biomass, the efficiency of the column process was low due to clogging of the column by the precipitate.

摘要

已证实，在高辐射环境中，表达非特异性酸性磷酸酶PhoN的基因工程耐辐射奇异球菌细胞具有稳定性和卓越的金属生物修复能力。冻干的重组DrPhoN细胞保留了PhoN活性和铀沉淀能力。这类细胞在室温储存期间还表现出6个月的延长保质期，并显示出铀以及镉等其他金属的表面相关沉淀。固定在聚丙烯酰胺凝胶中的冻干细胞可用于流通系统中的铀生物沉淀，能从1mM输入铀溶液中去除70%的铀，且铀负载量为1g铀/克干重细胞。与实现5.7g铀/克生物质负载量的分批工艺相比，柱式工艺的效率较低，因为沉淀物会堵塞柱子。

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用于从酸性/中性水性废物中生物修复重金属的重组耐辐射球菌细胞。

Recombinant D. radiodurans cells for bioremediation of heavy metals from acidic/neutral aqueous wastes.

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