2016
DOI: 10.1038/srep23517
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Thermally activated charge transport in microbial protein nanowires

Abstract: The bacterium Geobacter sulfurreducens requires the expression of conductive protein filaments or pili to respire extracellular electron acceptors such as iron oxides and uranium and to wire electroactive biofilms, but the contribution of the protein fiber to charge transport has remained elusive. Here we demonstrate efficient long-range charge transport along individual pili purified free of metal and redox organic cofactors at rates high enough to satisfy the respiratory rates of the cell. Carrier characteri… Show more

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Cited by 101 publications
(132 citation statements)
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“…Discharging electrons onto the minerals is predicted to be fast. The charge transport capacity of individual pilus fibres purified free of metal and organic cofactors (~ 1 billion electrons per second at 100 mV) is, for example, two orders of magnitude greater than the rates of iron oxide respiration per cell (Lampa‐Pastirk et al ., 2016). These measurements were obtained for purified pilus fibres deposited onto a substrate without extensive evaporation and/or chemical fixation (Lampa‐Pastirk et al ., 2016).…”
Section: A Nanowire Pathway For Metal Reductionmentioning
confidence: 99%
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“…Discharging electrons onto the minerals is predicted to be fast. The charge transport capacity of individual pilus fibres purified free of metal and organic cofactors (~ 1 billion electrons per second at 100 mV) is, for example, two orders of magnitude greater than the rates of iron oxide respiration per cell (Lampa‐Pastirk et al ., 2016). These measurements were obtained for purified pilus fibres deposited onto a substrate without extensive evaporation and/or chemical fixation (Lampa‐Pastirk et al ., 2016).…”
Section: A Nanowire Pathway For Metal Reductionmentioning
confidence: 99%
“…The charge transport capacity of individual pilus fibres purified free of metal and organic cofactors (~ 1 billion electrons per second at 100 mV) is, for example, two orders of magnitude greater than the rates of iron oxide respiration per cell (Lampa‐Pastirk et al ., 2016). These measurements were obtained for purified pilus fibres deposited onto a substrate without extensive evaporation and/or chemical fixation (Lampa‐Pastirk et al ., 2016). Although these conditions preserved the structural and electronic signatures described for cell‐associated pili (Veazey et al ., 2011), the assay was performed with T4P immobilized on a surface.…”
Section: A Nanowire Pathway For Metal Reductionmentioning
confidence: 99%
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