Enhanced anaerobic phenol degradation by conductive materials via EPS and microbial community alteration

[Display omitted] •CMs promoted phenol degradation and microbial resistance to oxygen impact.•Extracellular polymeric substance alternation, benefiting interspecies electron transfer.•CMs enriched functional genera in phenol degradation and electron transfer.•Microbial community structure varied wit...

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Published inChemical engineering journal (Lausanne, Switzerland : 1996) Vol. 352; pp. 1 - 9
Main Authors Yan, Wangwang, Sun, Faqian, Liu, Jianbo, Zhou, Yan
Format Journal Article
LanguageEnglish
Published Elsevier B.V 15.11.2018
Subjects
Electron shuttles
Extracellular electron transfer (EET)
Extracellular polymeric substances (EPS)
Humic substance (HS)
Microbial community
Phenol degradation
Electron shuttles
Extracellular electron transfer (EET)
Extracellular polymeric substances (EPS)
Phenol degradation
Humic substance (HS)
Microbial community
Online AccessGet full text
ISSN1385-8947
1873-3212
DOI10.1016/j.cej.2018.06.187

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Abstract [Display omitted] •CMs promoted phenol degradation and microbial resistance to oxygen impact.•Extracellular polymeric substance alternation, benefiting interspecies electron transfer.•CMs enriched functional genera in phenol degradation and electron transfer.•Microbial community structure varied with types of materials. Anaerobic biodegradation is a promising and economical process to remove phenol in the wastewater, although the reaction kinetics are often limited by the toxicity of phenol. This study proposed a strategy to accelerate phenol degradation and mitigate its inhibition on the bioprocess by adding conductive materials (CMs) into the anaerobic degradation system. The results showed that CMs could stimulate phenol degradation up to one–fold higher than that in control group. Certain extracellular polymeric substances (EPS) compounds that can act as electron shuttles, i.e. protein and humic substances, were greatly enriched with the existence of CMs. In particular, compared with control group, CMs supplemented groups had 2.3 and 10 to 20 folds low molecular weight protein in bound and soluble EPS, respectively. Carbon nanotube supplemented group exhibited 3 times higher humic substance in soluble EPS. The overall electron transport system activity in CMs groups was much higher than that in control groups. The addition of CMs enriched phenol degradation bacteria–Syntrophorhabdus, Brooklawnia, Treponema and Syntrophus, as well as electroactive methanogens–Methanosaeta. It is proposed that Syntrophus and Methanosaeta were the functional genera in methanogenic phenol degradation via extracellular electron transfer. This study revealed that the presence of CMs altered the EPS composition and microbial community of the system and made it become more favorable for extracellular electron transfer.
AbstractList [Display omitted] •CMs promoted phenol degradation and microbial resistance to oxygen impact.•Extracellular polymeric substance alternation, benefiting interspecies electron transfer.•CMs enriched functional genera in phenol degradation and electron transfer.•Microbial community structure varied with types of materials. Anaerobic biodegradation is a promising and economical process to remove phenol in the wastewater, although the reaction kinetics are often limited by the toxicity of phenol. This study proposed a strategy to accelerate phenol degradation and mitigate its inhibition on the bioprocess by adding conductive materials (CMs) into the anaerobic degradation system. The results showed that CMs could stimulate phenol degradation up to one–fold higher than that in control group. Certain extracellular polymeric substances (EPS) compounds that can act as electron shuttles, i.e. protein and humic substances, were greatly enriched with the existence of CMs. In particular, compared with control group, CMs supplemented groups had 2.3 and 10 to 20 folds low molecular weight protein in bound and soluble EPS, respectively. Carbon nanotube supplemented group exhibited 3 times higher humic substance in soluble EPS. The overall electron transport system activity in CMs groups was much higher than that in control groups. The addition of CMs enriched phenol degradation bacteria–Syntrophorhabdus, Brooklawnia, Treponema and Syntrophus, as well as electroactive methanogens–Methanosaeta. It is proposed that Syntrophus and Methanosaeta were the functional genera in methanogenic phenol degradation via extracellular electron transfer. This study revealed that the presence of CMs altered the EPS composition and microbial community of the system and made it become more favorable for extracellular electron transfer.
Author Sun, Faqian
Zhou, Yan
Yan, Wangwang
Liu, Jianbo
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  givenname: Yan
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  email: Zhouyan@ntu.edu.sg
  organization: School of Civil and Environmental Engineering, Nanyang Technological University, 639798, Singapore
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Keywords Electron shuttles
Extracellular electron transfer (EET)
Extracellular polymeric substances (EPS)
Phenol degradation
Humic substance (HS)
Microbial community
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Snippet [Display omitted] •CMs promoted phenol degradation and microbial resistance to oxygen impact.•Extracellular polymeric substance alternation, benefiting...
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SubjectTerms Electron shuttles
Extracellular electron transfer (EET)
Extracellular polymeric substances (EPS)
Humic substance (HS)
Microbial community
Phenol degradation
Title Enhanced anaerobic phenol degradation by conductive materials via EPS and microbial community alteration
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