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Exoelectrogens: Recent advances in molecular drivers involved in extracellular electron transfer and strategies used to improve it for microbial fuel cell applications

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  • Kumar, Ravinder
  • Singh, Lakhveer
  • Zularisam, A.W.

Abstract

The use of exoelectrogens in microbial fuel cells (MFCs) has given a wide berth to the addition of artificial electron shuttles/conduits as they have the molecular machinery to transfer the electrons exogenously to the electrode surface or to soluble or insoluble electron acceptors. Exoelectrogens transfer the electrons either directly to the electrode surface (via c-Cyts or pili) and/or mediate them by secreting electron shuttles such as, flavins or pyocyanin. Such microorganisms form electroactive biofilms on the electrode surface. They produce cyclopropane fatty acids and exopolysaccahride matrix to modify surface charge, which also provides favorable anchoring points for the retention of c-type cytochromes (c-Cyts). The longer subunit of PilA plays a vital role in cell attachment in the case of a well-known exoelectrogen Geobacter sulfurreducens during biofilm formation. G. sulfurreducens relies on flavin molecules for mediated electron transfer (MET) during initial biofilm formation and on c-Cyts and pili for the direct electron transfer (DET) during the later phase of biofilm formation. A new protein, cbcl inner membrane multiheme c-Cyt has been revealed in G. sulfurreducens that participates in the electron transfer when electron acceptor with low reduction potential (below 0.1 V) is used in the MFCs. On the other hand, inner membrane c-type cytochrome ImcH is involved in the reduction of electron acceptors exhibiting the potential above 0.1V. Shewanella oneidensis, another exoelectrogen expresses CheA-3 histidine protein kinase for chemotactic responses to electron acceptors. S. oneidensis do not produce pili and utilizes flavin-cytochrome complexes to regulate the electron transfer to the electrode surfaces. The inherent electron transfer rates can be increased in order to improve the MFC performance. Such strategies as the anode surface modification with nanoparticles, expression of the genes for flavin biosynthesis pathway in the exoelectrogens, and chemical treatment of the microbial membrane have shown to increase the current outputs in the MFCs. This article provides the latest information about the exoelectrogens and molecular drivers involved in extracellular electron transfer (EET) mechanisms, and also summarizes the important characteristics of electroactive biofilms. It also highlights the different approaches that have been employed to facilitate the EET mechanisms and some uncommon exoelectrogens used in the MFCs recently.

Suggested Citation

  • Kumar, Ravinder & Singh, Lakhveer & Zularisam, A.W., 2016. "Exoelectrogens: Recent advances in molecular drivers involved in extracellular electron transfer and strategies used to improve it for microbial fuel cell applications," Renewable and Sustainable Energy Reviews, Elsevier, vol. 56(C), pages 1322-1336.
    • Handle: RePEc:eee:rensus:v:56:y:2016:i:c:p:1322-1336
    DOI: 10.1016/j.rser.2015.12.029
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    5. Kumar, R. & Strezov, V., 2021. "Thermochemical production of bio-oil: A review of downstream processing technologies for bio-oil upgrading, production of hydrogen and high value-added products," Renewable and Sustainable Energy Reviews, Elsevier, vol. 135(C).
    6. Tian, Hailin & Li, Jie & Yan, Miao & Tong, Yen Wah & Wang, Chi-Hwa & Wang, Xiaonan, 2019. "Organic waste to biohydrogen: A critical review from technological development and environmental impact analysis perspective," Applied Energy, Elsevier, vol. 256(C).
    7. Hu, Jianjun & Zhang, Quanguo & Lee, Duu-Jong & Ngo, Huu Hao, 2018. "Feasible use of microbial fuel cells for pollution treatment," Renewable Energy, Elsevier, vol. 129(PB), pages 824-829.
    8. He, Li & Du, Peng & Chen, Yizhong & Lu, Hongwei & Cheng, Xi & Chang, Bei & Wang, Zheng, 2017. "Advances in microbial fuel cells for wastewater treatment," Renewable and Sustainable Energy Reviews, Elsevier, vol. 71(C), pages 388-403.
    9. Slate, Anthony J. & Whitehead, Kathryn A. & Brownson, Dale A.C. & Banks, Craig E., 2019. "Microbial fuel cells: An overview of current technology," Renewable and Sustainable Energy Reviews, Elsevier, vol. 101(C), pages 60-81.
    10. Littfinski, Tobias & Stricker, Max & Nettmann, Edith & Gehring, Tito & Hiegemann, Heinz & Krimmler, Stefan & Lübken, Manfred & Pant, Deepak & Wichern, Marc, 2022. "A generalized whole-cell model for wastewater-fed microbial fuel cells," Applied Energy, Elsevier, vol. 321(C).
    11. Ahmed, Shams Forruque & Mofijur, M. & Islam, Nafisa & Parisa, Tahlil Ahmed & Rafa, Nazifa & Bokhari, Awais & Klemeš, Jiří Jaromír & Indra Mahlia, Teuku Meurah, 2022. "Insights into the development of microbial fuel cells for generating biohydrogen, bioelectricity, and treating wastewater," Energy, Elsevier, vol. 254(PA).

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