来自陆地深部地下的需氧化学异养细菌的金属抗性

Metal resistance among aerobic chemoheterotrophic bacteria from the deep terrestrial subsurface.

作者信息

Benyehuda G, Coombs J, Ward P L, Balkwill D, Barkay T

机构信息

Department of Biochemistry and Microbiology, Cook College, Rutgers University, 76 Lipman Dr., New Brunswick, NJ 08901, USA.

出版信息

Can J Microbiol. 2003 Feb;49(2):151-6. doi: 10.1139/w03-012.

DOI:10.1139/w03-012

PMID:12718404

Abstract

The metal resistance of 350 subsurface bacterial strains from two U.S. Department of Energy facilities, the Savannah River Site (SRS), South Carolina, and the Hanford site, Washington, was determined to assess the effect of metal toxicity on microorganisms in the deep terrestrial subsurface. Resistance was measured by growth inhibition around discs containing optimized amounts of Hg(II), Pb(II), and Cr(VI). A broad range of resistance levels was observed, with some strains of Arthrobacter spp. demonstrating exceptional tolerance. A higher level of resistance to Hg(II) and Pb(II) (P < 0.05) and a higher occurrence of multiple resistances suggested that metals more effectively influenced microbial evolution in subsurface sediments of the SRS than in those of the Hanford site. Common resistance to heavy metals suggests that toxic metals are unlikely to inhibit bioremediation in deep subsurface environments that are contaminated with mixed wastes.

摘要

为评估金属毒性对陆地深层地下微生物的影响，测定了来自美国能源部两个设施（南卡罗来纳州萨凡纳河工厂[SRS]和华盛顿州汉福德工厂）的350株地下细菌菌株的金属抗性。通过含优化量Hg(II)、Pb(II)和Cr(VI)的圆盘周围的生长抑制来测量抗性。观察到广泛的抗性水平，一些节杆菌属菌株表现出非凡的耐受性。对Hg(II)和Pb(II)的抗性水平更高（P < 0.05）以及多重抗性的发生率更高，这表明与汉福德工厂的地下沉积物相比，金属对SRS地下沉积物中微生物进化的影响更有效。对重金属的共同抗性表明，有毒金属不太可能抑制被混合废物污染的深层地下环境中的生物修复。

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来自陆地深部地下的需氧化学异养细菌的金属抗性

Metal resistance among aerobic chemoheterotrophic bacteria from the deep terrestrial subsurface.

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