可生存细胞中氢化酶活性的放射测定法及生活在极端环境中的需氧产氢细菌的记录。
Radioassay for hydrogenase activity in viable cells and documentation of aerobic hydrogen-consuming bacteria living in extreme environments.
机构信息
Department of Bacteriology, University of Wisconsin-Madison, Madison, Wisconsin 53706.
出版信息
Appl Environ Microbiol. 1983 May;45(5):1491-500. doi: 10.1128/aem.45.5.1491-1500.1983.
Abstract
An isotopic tracer assay based on the hydrogenase-dependent formation of tritiated water from tritium gas was developed for in life analysis of microbial hydrogen transformation. This method allowed detection of bacterial hydrogen metabolism in pure cultures or in natural samples obtained from aquatic ecosystems. A differentiation between chemical-biological and aerobic-anaerobic hydrogen metabolism was established by variation of the experimental incubation temperature or by addition of selective inhibitors. Hydrogenase activity was shown to be proportional to the consumption or production of hydrogen by cultures of Desulfovibrio vulgaris, Clostridium pasteurianum, and Methanosarcina barkeri. This method was applied, in connection with measurements of free hydrogen and most-probable-number enumerations, in aerobic natural source waters to establish the activity and document the ecology of hydrogen-consuming bacteria in extreme acid, thermal, or saline environments. The utility of the assay is based in part on the ability to quantify bacterial hydrogen transformation at natural hydrogen partial pressures, without the use of artificial electron acceptors.
摘要
基于氢化酶将氚气转化为氚水的同位素示踪剂测定法,被开发用于活体分析微生物的氢转化。该方法可用于检测纯培养物或从水生生态系统获得的天然样品中的细菌氢代谢。通过改变实验孵育温度或添加选择性抑制剂,可区分化学-生物和需氧-厌氧氢代谢。通过对脱硫弧菌、巴氏梭菌和产甲烷菌的培养物进行氢酶活性测定,发现其活性与氢的消耗或产生呈正相关。该方法与自由氢测量和最可能数计数相结合,应用于需氧天然源水中,以确定活性并记录极端酸、热或盐环境中消耗氢的细菌的生态学。该测定法的应用部分基于在不使用人工电子受体的情况下,定量测量自然氢分压下细菌氢转化的能力。
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