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从低pH值污染的 former铀矿中鉴定锰(II)氧化细菌 。 注:这里former不太好准确翻译,结合语境可能是“废弃的”之类意思,但按要求不做过多解释,直接保留英文。

Identification of Mn(II)-oxidizing bacteria from a low-pH contaminated former uranium mine.

作者信息

Akob Denise M, Bohu Tsing, Beyer Andrea, Schäffner Franziska, Händel Matthias, Johnson Carol A, Merten Dirk, Büchel Georg, Totsche Kai Uwe, Küsel Kirsten

机构信息

Institute of Ecology, Friedrich Schiller University Jena, Jena, Germany U.S. Geological Survey, National Research Program, Reston, Virginia, USA

Institute of Ecology, Friedrich Schiller University Jena, Jena, Germany.

出版信息

Appl Environ Microbiol. 2014 Aug;80(16):5086-97. doi: 10.1128/AEM.01296-14. Epub 2014 Jun 13.

DOI:10.1128/AEM.01296-14
PMID:24928873
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4135758/
Abstract

Biological Mn oxidation is responsible for producing highly reactive and abundant Mn oxide phases in the environment that can mitigate metal contamination. However, little is known about Mn oxidation in low-pH environments, where metal contamination often is a problem as the result of mining activities. We isolated two Mn(II)-oxidizing bacteria (MOB) at pH 5.5 (Duganella isolate AB_14 and Albidiferax isolate TB-2) and nine strains at pH 7 from a former uranium mining site. Isolate TB-2 may contribute to Mn oxidation in the acidic Mn-rich subsoil, as a closely related clone represented 16% of the total community. All isolates oxidized Mn over a small pH range, and isolates from low-pH samples only oxidized Mn below pH 6. Two strains with different pH optima differed in their Fe requirements for Mn oxidation, suggesting that Mn oxidation by the strain found at neutral pH was linked to Fe oxidation. Isolates tolerated Ni, Cu, and Cd and produced Mn oxides with similarities to todorokite and birnessite, with the latter being present in subsurface layers where metal enrichment was associated with Mn oxides. This demonstrates that MOB can be involved in the formation of biogenic Mn oxides in both moderately acidic and neutral pH environments.

摘要

生物锰氧化作用促使环境中生成高活性且丰富的锰氧化物相,从而减轻金属污染。然而,对于低pH值环境中的锰氧化情况却知之甚少,在这种环境中,由于采矿活动,金属污染常常成为一个问题。我们从一个 former uranium mining site 中,在pH 5.5条件下分离出两株锰(II)氧化细菌(MOB)(杜氏菌属分离株AB_14和白色嗜铁杆菌属分离株TB - 2),在pH 7条件下分离出九株。分离株TB - 2可能在酸性富锰底土的锰氧化过程中发挥作用,因为一个密切相关的克隆体占群落总数的16%。所有分离株在较小的pH范围内氧化锰,并且来自低pH值样品的分离株仅在pH低于6时氧化锰。两株具有不同最适pH值的菌株在锰氧化对铁的需求方面存在差异,这表明在中性pH值下发现的菌株的锰氧化与铁氧化有关。分离株耐受镍、铜和镉,并产生与钙锰矿和水钠锰矿相似的锰氧化物,后者存在于与锰氧化物相关的金属富集的地下层中。这表明MOB可参与中等酸性和中性pH值环境中生物成因锰氧化物的形成。

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