Microbial Nanowires: A New Paradigm for Biological Electron Transfer and Bioelectronics

The discovery that Geobacter sulfurreducens can produce protein filaments with metallic‐like conductivity, known as microbial nanowires, that facilitate long‐range electron transport is a paradigm shift in biological electron transfer and has important implications for biogeochemistry, microbial eco...

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Veröffentlicht in:	ChemSusChem 2012-06, Vol.5 (6), p.1039-1046
Hauptverfasser:	Malvankar, Nikhil S., Lovley, Derek R.
Format:	Artikel
Sprache:	eng
Schlagworte:	Bacterial Physiological Phenomena Biofilms biophysics Biotechnology Electric Conductivity electron transfer Ferric Compounds - chemistry Fimbriae Proteins - metabolism Fimbriae, Bacterial - metabolism fuel cell geobacter Nanostructures nanotechnology Oxidation-Reduction
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creator	Malvankar, Nikhil S. Lovley, Derek R.
description	The discovery that Geobacter sulfurreducens can produce protein filaments with metallic‐like conductivity, known as microbial nanowires, that facilitate long‐range electron transport is a paradigm shift in biological electron transfer and has important implications for biogeochemistry, microbial ecology, and the emerging field of bioelectronics. Although filaments in a wide diversity of microorganisms have been called microbial nanowires, the type IV pili of G. sulfurreducens and G. metallireducens are the only filaments that have been shown to be required for extracellular electron transport to extracellular electron acceptors or for conduction of electrons through biofilms. Studies of G. sulfurreducens pili preparations and intact biofilms under physiologically relevant conditions have provided multiple lines of evidence for metallic‐like conduction along the length of pili and for the possibility of pili networks to confer high conductivity within biofilms. This mechanism of electron conduction contrasts with the previously known mechanism for biological electron transfer via electron tunneling or hopping between closely associated molecules, a strategy unlikely to be well adapted for long‐range electron transport outside the cell. In addition to promoting electron exchange with abiotic electron acceptors, microbial nanowires have recently been shown to be involved in direct interspecies electron transfer between syntrophic partners. An improved understanding of the mechanisms for metallic‐like conductivity in microbial nanowires, as well as engineering microorganisms with desirable catalytic abilities with nanowires, could lead to new applications in microbial electrosynthesis and bioelectronics. Live wires: This concept article summarizes the current understanding of how microbial nanowires (see graph; scale bar: 100 nm) function, where they can be found, and their potential practical applications in bioenergy and bioelectronics.
doi_str_mv	10.1002/cssc.201100733
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Although filaments in a wide diversity of microorganisms have been called microbial nanowires, the type IV pili of G. sulfurreducens and G. metallireducens are the only filaments that have been shown to be required for extracellular electron transport to extracellular electron acceptors or for conduction of electrons through biofilms. Studies of G. sulfurreducens pili preparations and intact biofilms under physiologically relevant conditions have provided multiple lines of evidence for metallic‐like conduction along the length of pili and for the possibility of pili networks to confer high conductivity within biofilms. This mechanism of electron conduction contrasts with the previously known mechanism for biological electron transfer via electron tunneling or hopping between closely associated molecules, a strategy unlikely to be well adapted for long‐range electron transport outside the cell. In addition to promoting electron exchange with abiotic electron acceptors, microbial nanowires have recently been shown to be involved in direct interspecies electron transfer between syntrophic partners. An improved understanding of the mechanisms for metallic‐like conductivity in microbial nanowires, as well as engineering microorganisms with desirable catalytic abilities with nanowires, could lead to new applications in microbial electrosynthesis and bioelectronics. 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subjects	Bacterial Physiological Phenomena Biofilms biophysics Biotechnology Electric Conductivity electron transfer Ferric Compounds - chemistry Fimbriae Proteins - metabolism Fimbriae, Bacterial - metabolism fuel cell geobacter Nanostructures nanotechnology Oxidation-Reduction
title	Microbial Nanowires: A New Paradigm for Biological Electron Transfer and Bioelectronics
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