毒性、曝气和还原剂供应对混合甲烷营养菌培养物转化三氯乙烯的影响。
Effects of toxicity, aeration, and reductant supply on trichloroethylene transformation by a mixed methanotrophic culture.
作者信息
Alvarez-Cohen L, McCarty P L
机构信息
Department of Civil Engineering, University of California, Berkeley 94720.
出版信息
Appl Environ Microbiol. 1991 Jan;57(1):228-35. doi: 10.1128/aem.57.1.228-235.1991.
Abstract
The trichloroethylene (TCE) transformation rate and capacity of a mixed methanotrophic culture at room temperature were measured to determine the effects of time without methane (resting), use of an alternative energy source (formate), aeration, and toxicity of TCE and its transformation products. The initial specific TCE transformation rate of resting cells was 0.6 mg of TCE per mg of cells per day, and they had a finite TCE transformation capacity of 0.036 mg of TCE per mg of cells. Formate addition resulted in increased initial specific TCE transformation rates (2.1 mg/mg of cells per day) and elevated transformation capacity (0.073 mg of TCE per mg of cells). Significant declines in methane conversion rates following exposure to TCE were observed for both resting and formate-fed cells, suggesting toxic effects caused by TCE or its transformation products. TCE transformation and methane consumption rates of resting cells decreased with time much more rapidly when cells were shaken and aerated than when they remained dormant, suggesting that the transformation ability of methanotrophs is best preserved by storage under anoxic conditions.
摘要
测定了混合甲烷营养培养物在室温下三氯乙烯(TCE)的转化率和转化能力,以确定无甲烷培养时间(静息)、使用替代能源(甲酸盐)、曝气以及TCE及其转化产物的毒性的影响。静息细胞的初始比TCE转化率为每天每毫克细胞0.6毫克TCE,其TCE转化能力有限,为每毫克细胞0.036毫克TCE。添加甲酸盐导致初始比TCE转化率提高(每天每毫克细胞2.1毫克),转化能力增强(每毫克细胞0.073毫克TCE)。对于静息细胞和添加甲酸盐的细胞,暴露于TCE后甲烷转化率均显著下降,表明TCE或其转化产物具有毒性作用。与保持休眠状态相比,当细胞振荡和曝气时,静息细胞的TCE转化率和甲烷消耗率随时间下降得更快,这表明甲烷营养菌的转化能力在缺氧条件下储存时能得到最佳保存。
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