关于细菌生长模式调节芘降解途径和基因型双加氧酶表达的直接证据。

Direct evidences on bacterial growth pattern regulating pyrene degradation pathway and genotypic dioxygenase expression.

作者信息

Chen Baowei, Huang Jinyin, Yuan Ke, Lin Li, Wang Xiaowei, Yang Lihua, Luan Tiangang

机构信息

MOE Key Laboratory of Aquatic Product Safety, South China Sea Bio-Resource Exploitation and Utilization Collaborative Innovation Center, School of Marine Sciences, School of Life Sciences, Sun Yat-Sen University, Guangzhou 510275, People's Republic of China; Guangdong Provincial Key Laboratory of Marine Resources and Coastal Engineering, School of Marine Sciences, Sun Yat-Sen University, Guangzhou 510275, People's Republic of China.

出版信息

Mar Pollut Bull. 2016 Apr 15;105(1):73-80. doi: 10.1016/j.marpolbul.2016.02.054. Epub 2016 Mar 4.

DOI:10.1016/j.marpolbul.2016.02.054

PMID:26952991

Abstract

Pyrene degradation by Mycobacterium sp. strain A1-PYR was investigated in the presence of nutrient broth, phenanthrene and fluoranthene, respectively. Fast bacterial growth in the nutrient broth considerably enhanced pyrene degradation rate, whereas degradation efficiency per cell was substantially decreased. The addition of nutrient broth could not alter the transcription levels of all dioxygenase genotypes. In the PAH-only substrates, bacterial growth completely relied on biological conversion of PAHs into the effective carbon sources, which led to a higher degradation efficiency of pyrene per cell than the case of nutrient broth. Significant correlations were only observed between nidA-related dioxygenase expression and pyrene degradation or bacterial growth. The highest pyrene degradation rate in the presence of phenanthrene was consistent with the highest transcription level of nidA and 4,5-pyrenediol as the sole initial metabolite. This study reveals that bacterial growth requirement can invigorate degradation of PAHs by regulating metabolic pathway and genotypic enzyme expression.

摘要

分别在营养肉汤、菲和荧蒽存在的情况下，对分枝杆菌属菌株A1-PYR降解芘的情况进行了研究。营养肉汤中细菌的快速生长显著提高了芘的降解率，而每个细胞的降解效率则大幅降低。添加营养肉汤并不能改变所有双加氧酶基因型的转录水平。在仅含多环芳烃的底物中，细菌生长完全依赖于多环芳烃向有效碳源的生物转化，这导致每个细胞对芘的降解效率高于在营养肉汤中的情况。仅在与nidA相关的双加氧酶表达与芘降解或细菌生长之间观察到显著相关性。在菲存在的情况下，芘的最高降解率与nidA的最高转录水平以及4,5-芘二醇作为唯一初始代谢物一致。本研究表明，细菌生长需求可通过调节代谢途径和基因型酶表达来促进多环芳烃的降解。

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关于细菌生长模式调节芘降解途径和基因型双加氧酶表达的直接证据。

Direct evidences on bacterial growth pattern regulating pyrene degradation pathway and genotypic dioxygenase expression.

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