硫还原地杆菌在具有不同氧化还原电位的阳极上生长时的代谢效率。

Metabolic efficiency of Geobacter sulfurreducens growing on anodes with different redox potentials.

作者信息

Bosch Julian, Lee Keun-Young, Hong Siang-Fu, Harnisch Falk, Schröder Uwe, Meckenstock Rainer U

机构信息

Institute of Groundwater Ecology, Helmholtz Zentrum München, Ingolstädter Landstr. 1, 85764, Neuherberg, Germany,

出版信息

Curr Microbiol. 2014 Jun;68(6):763-8. doi: 10.1007/s00284-014-0539-2. Epub 2014 Feb 20.

DOI:10.1007/s00284-014-0539-2

PMID:24554342

Abstract

Microorganisms respiring Fe(III) in the environment face a range of redox potentials of the prospective terminal ferric electron acceptors, because Fe(III) can be present in different minerals or organic complexes. We investigated the adaptation of Geobacter sulfurreducens to this range by exposing the bacteria to different redox potentials between the electron donor acetate and solid, extracellular anodes in a microbial fuel-cell set-up. Over a range of anode potentials from -0.105 to +0.645 V versus standard hydrogen electrode, G. sulfurreducens produced identical amounts of biomass per electron respired. This indicated that the organism cannot utilize higher available energies for energy conservation to ATP, and confirmed recent studies. Either the high potentials cannot be used due to physiological limitations, or G. sulfurreducens decreased its metabolic efficiency, and less biomass per unit of energy was produced. In this case, G. sulfurreducens "wasted" energy at high-potential differences, most likely as heat to fuel growth kinetics.

摘要

在环境中以Fe(III)为呼吸底物的微生物面临着一系列潜在的终端三价铁电子受体的氧化还原电位，因为Fe(III)可以存在于不同的矿物质或有机复合物中。我们通过在微生物燃料电池装置中，将细菌暴露于电子供体乙酸盐和固体细胞外阳极之间的不同氧化还原电位下，研究了硫还原地杆菌对该电位范围的适应性。相对于标准氢电极，在从-0.105到+0.645 V的一系列阳极电位范围内，硫还原地杆菌每呼吸一个电子产生相同量的生物量。这表明该生物体无法利用更高的可用能量来进行能量守恒以合成ATP，并证实了最近的研究。要么由于生理限制而无法使用高电位，要么硫还原地杆菌降低了其代谢效率，并且每单位能量产生的生物量减少。在这种情况下，硫还原地杆菌在高电位差下“浪费”能量，最有可能是以热量的形式来促进生长动力学。

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硫还原地杆菌在具有不同氧化还原电位的阳极上生长时的代谢效率。

Metabolic efficiency of Geobacter sulfurreducens growing on anodes with different redox potentials.

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