mer（Tn21）介导天然水体中Hg2+还原为Hg0的可能性的环境意义。

Environmental significance of the potential for mer(Tn21)-mediated reduction of Hg2+ to Hg0 in natural waters.

作者信息

Barkay T, Liebert C, Gillman M

机构信息

Microbial Ecology and Biotechnology Branch, Environmental Research Laboratory, U.S. Environmental Protection Agency, Gulf Breeze, Florida 32561.

出版信息

Appl Environ Microbiol. 1989 May;55(5):1196-202. doi: 10.1128/aem.55.5.1196-1202.1989.

DOI:10.1128/aem.55.5.1196-1202.1989

PMID:2547336

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC184276/

Abstract

The role of mer(Tn21) in the adaptation of aquatic microbial communities to Hg2+ was investigated. Elemental mercury was the sole product of Hg2+ volatilization by freshwater and saline water microbial communities. Bacterial activity was responsible for biotransformation because most microeucaryotes did not survive the exposure conditions, and removal of larger microbes (greater than 1 micromole) from adapted communities did not significantly (P greater than 0.01) reduce Hg2+ volatilization rates. DNA sequences homologous to mer(Tn21) were found in 50% of Hg2+-resistant bacterial strains representing two freshwater communities, but in only 12% of strains representing two saline communities (the difference was highly significant; P less than 0.001). Thus, mer(Tn21) played a significant role in Hg2+ resistance among strains isolated from fresh waters, in which microbial activity had a limited role in Hg2+ volatilization. In saline water environments in which microbially mediated volatilization was the major mechanism of Hg2+ loss, other bacterial genes coded for this biotransformation.

摘要

研究了mer(Tn21)在水生微生物群落适应Hg2+过程中的作用。元素汞是淡水和咸水微生物群落挥发Hg2+的唯一产物。细菌活性负责生物转化，因为大多数微真核生物在暴露条件下无法存活，并且从适应的群落中去除较大的微生物（大于1微摩尔）并不会显著（P大于0.01）降低Hg2+的挥发速率。在代表两个淡水群落的50%的Hg2+抗性细菌菌株中发现了与mer(Tn21)同源的DNA序列，但在代表两个咸水群落的菌株中仅发现了12%（差异非常显著；P小于0.001）。因此，mer(Tn21)在从淡水中分离的菌株对Hg2+的抗性中起重要作用，其中微生物活性在Hg2+挥发中作用有限。在咸水环境中，微生物介导的挥发是Hg2+损失的主要机制，其他细菌基因编码这种生物转化。

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