Abstract
SummaryExtracellular electron transfer (EET) from microorganisms to inorganic electrodes is a unique ability of electrochemically active bacteria. Despite rigorous genetic and biochemical screening of the c-type cytochromes that make up the EET network, the individual electron transfer steps over the cell membrane remain mostly unresolved. As such, attempts to transplant entire EET chains from native into non-native exoelectrogens have resulted in inferior electron transfer rates. In this study we investigate how nanostructured electrodes can interface with Shewanella oneidensis to establish an alternative EET pathway. Improved biocompatibility was observed for densely packed nanostructured surfaces with a low cell-nanowire load distribution during applied external forces. External gravitational forces were needed to establish a bioelectrochemical cell-nanorod interface. Bioelectrochemical analysis showed evidence of nanorod penetration beyond the outer cell membrane of a deletion mutant lacking all outer membrane cytochrome encoding genes that was only electroactive on a nanostructured surface and under external force.
Highlights
Direct electron transfer is made possible by a conductive multiprotein electron transport chain that extends through the cell membrane allowing electron flow outside of the cell
The yeast extract in the LB medium is known to contain flavins that could function as redox active shuttles and contribute to an increased mediated electron transfer (MET) between the organisms and the nanostructured electrode (Logan et al, 2019)
As the aim of the study was to investigate the intracellular direct electron transfer (DET) pathway, it would be best to minimize the effect of MET and the flavin-free medium M4 was selected
Summary
Active bacteria have sparked intense scientific interest recently, mainly due to their ability of converting various different organic substrates to higher oxidized compounds of biotechnological interest while producing electrical energy as a by-product in bioelectrochemical systems such as microbial fuel or electrolysis cells (Logan 2009; Logan et al, 2019; Richter et al, 2012) To balance their redox metabolism, respiratory microorganisms require a pathway to transfer electrons to an external terminal electron acceptor.
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