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高浓度氯仿的厌氧生物转化:富集培养物和两种细菌分离物的作用。

Anaerobic biotransformation of high concentrations of chloroform by an enrichment culture and two bacterial isolates.

机构信息

CH2MHILL, Atlanta, GA 30328, USA.

出版信息

Appl Environ Microbiol. 2010 Oct;76(19):6463-9. doi: 10.1128/AEM.01191-10. Epub 2010 Aug 6.

DOI:10.1128/AEM.01191-10
PMID:20693443
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2950468/
Abstract

A fermentative enrichment culture (designated DHM-1) was developed that is capable of cometabolically biotransforming high concentrations of chloroform (CF) to nontoxic end products. Two Pantoea spp. were isolated from DHM-1 that also possess this dechlorination capability. Following acclimation to increasing levels of CF, corn syrup-grown DHM-1 was able to transform over 500 mg/liter CF in the presence of vitamin B(12) (approximately 3% of CF on a molar basis) at a rate as high as 22 mg/liter/day in a mineral salts medium. CO, CO(2), and organic acids were the predominant biodegradation products, suggesting that hydrolytic reactions predominate during CF transformation. DHM-1 was capable of growing on corn syrup in the presence of high concentrations of CF (as may be present near contaminant source zones in groundwater), which makes it a promising culture for bioaugmentation. Strains DHM-1B and DHM-1T transform CF at rates similar to that of the DHM-1 enrichment culture. The ability of these strains to grow in the presence of high concentrations of CF appears to be related to alteration of membrane fluidity or homeoviscous and homeophasic adaptation.

摘要

一种能够共代谢生物转化高浓度氯仿(CF)为无毒终产物的发酵富集培养物(命名为 DHM-1)被开发出来。从 DHM-1 中分离出两种 Pantoea 属细菌,它们也具有这种脱氯能力。在适应 CF 浓度增加后,用玉米糖浆培养的 DHM-1 在维生素 B(12)(约为 CF 摩尔基础的 3%)存在下,能够在矿盐培养基中以高达 22 毫克/升/天的速度转化超过 500 毫克/升 CF。CO、CO(2)和有机酸是主要的生物降解产物,这表明水解反应在 CF 转化过程中占主导地位。DHM-1 能够在高浓度 CF(如地下水污染源区附近可能存在的浓度)存在的情况下,利用玉米糖浆生长,这使其成为生物增强的有前途的培养物。DHM-1B 和 DHM-1T 菌株以类似于 DHM-1 富集培养物的速率转化 CF。这些菌株在高浓度 CF 存在下生长的能力似乎与细胞膜流动性或同型和同相适应的改变有关。

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