Aerobic degradation of 2- and 3-fluoroaniline in mixed culture systems and microbial community analysis

Journal of Environmental Science and Health, Part A Pub Date : 2019-11-10 DOI:10.1080/10934529.2019.1688044

Zhi-Qing Zhao, Xiaoli Shen, T. Zheng, Liang Lv, Yao Su, Abbas Ghulam

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Abstract

Abstract Among three monofluoroanilines, 2-fluoroaniline (2-FA) and 3-fluoroaniline (3-FA) exhibit relatively poor biodegradability. This work examined their degradation characteristics in a mixed culture system and also analyzed the microorganism community. After acclimation for 58 d and 43 d, the high removal efficiency of 100% of 2-FA and 95.3% of 3-FA was obtained by adding 25 mg L−1 of 2-FA or 3-FA to the two reactors, respectively. In addition, the high defluorination rates of 2-FA and 3-FA were observed to be 87.0% and 89.3%, respectively. The degradation kinetics showed that the maximum specific degradation rates of 2-FA and 3-FA were (21.23 ± 0.91) mg FA (g•VSS·h)−1, and (11.75 ± 0.99) mg FA (g•VSS·h)−1, respectively. PCR-DGGE analysis revealed that the unique bacteria degrading 2-FA were mainly composed of six genera (Novosphingobium, Bradyrhizobium, Aquaspirillum, Aminobacter, Ochrobactrum, and Labrys), and five genera that degraded 3-FA (Ochrobactrum, Aquaspirillum, Lachnobacterium, Bradyrhizobium, and Variovorax). Analysis of the key catabolic enzyme activities indicated that the simultaneous hydroxylation and dehalogenation were involved in monooxygenase elimination of 2-FA and conversion of 3-FA to 4-fluorocatechol by dioxygenase, indicating that enriched mixed cultures were effective to metabolize 2-FA or 3-FA by unconventional pathways to prevent the accumulation of toxic metabolites.

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2-和3-氟苯胺在混合培养系统中的好氧降解及微生物群落分析

摘要在三种单氟苯胺中，2-氟苯胺(2-FA)和3-氟苯胺(3-FA)的生物降解性相对较差。本文研究了它们在混合培养系统中的降解特性，并分析了微生物群落。驯化58 d和43 d后，在两个反应器中分别添加25 mg L−1的2-FA和3-FA, 2-FA的去除率达到100%，3-FA的去除率达到95.3%。2-FA和3-FA的除氟率分别为87.0%和89.3%。降解动力学表明，2-FA和3-FA的最大特定降解率分别为(21.23±0.91)mg FA (g•VSS·h)−1和(11.75±0.99)mg FA (g•VSS·h)−1。PCR-DGGE分析显示，降解2-FA的独特细菌主要由6个属(Novosphingobium、Bradyrhizobium、Aquaspirillum、Aminobacter、Ochrobactrum和Labrys)和5个属(Ochrobactrum、Aquaspirillum、Lachnobacterium、Bradyrhizobium和Variovorax)组成。关键分解代谢酶活性分析表明，双加氧酶对2-FA的消除和3-FA向4-氟儿茶酚的转化同时发生羟基化和脱卤作用，表明富集的混合培养可以有效地通过非常规途径代谢2-FA或3-FA，以防止有毒代谢物的积累。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Environmental Science and Health, Part A

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