Response of antimicrobial nitrofurazone-degrading biocathode communities to different cathode potentials

•NFZ bioelectrodegradation degree was related to different cathode potentials.•Different cathode potentials enriched specific biocathode communities respectively.•Dominant genera possess nitroaromatics reduction and electron transfer functions.•Higher potential modes enriched a Gram negative nitroar...

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Bibliographic Details
Published in:Bioresource technology 2017-10, Vol.241, p.951-958
Main Authors: Kong, Deyong, Yun, Hui, Cui, Dan, Qi, Mengyuan, Shao, Chunyan, Cui, Dichen, Ren, Nanqi, Liang, Bin, Wang, Aijie
Format: Article
Language:English
Subjects:
Anti-Infective Agents
Bacteria
Biocathode community structure
Bioelectric Energy Sources
Biofilms
Cathode potential regulation
Electrodes
NFZ bioelectrodegradation
Nitrofurans nitrofurazone (NFZ)
Nitrofurazone
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Summary:•NFZ bioelectrodegradation degree was related to different cathode potentials.•Different cathode potentials enriched specific biocathode communities respectively.•Dominant genera possess nitroaromatics reduction and electron transfer functions.•Higher potential modes enriched a Gram negative nitroaromatic reducer Klebsiella.•Lower potential mode enriched a Gram positive nitroaromatic reducer Enterococcus. Bioelectrodegradation of various organic pollutants has been extensively studied. However, whether different cathode potentials could alter the antimicrobial-degrading biocathode community structure and composition remain poorly understood. Here, the microbial community structure and composition of the nitrofurans nitrofurazone (NFZ) degrading biocathode in response to different cathode potentials (−0.45±0.01, −0.65±0.01 and −0.86±0.05V vs standard hydrogen electrode, with applied cell voltages of 0.2, 0.5 and 0.8V, respectively) were investigated. The bioelectrodegradation efficiency and degree of NFZ were highly related to different cathode potentials. The 0.2 and 0.5V performed biocathode communities were similar but significantly differed from those of the 0.8V and open circuit biofilms. The bacteria possessing functions of nitroaromatics reduction and electrons transfer (e.g. Klebsiella, Enterococcus, Citrobacter and Desulfovibrio) were selectively enriched in different biocathode communities. This study offers new insights into the ecological response of antimicrobial-degrading biocathode communities to different cathode potentials.
ISSN:0960-8524
1873-2976
DOI:10.1016/j.biortech.2017.06.056