Article Electro-polarization of protein-like substances accelerates trans-cell-wall electron transfer in microbial extracellular respiration

Electrical stimulation has been used to strengthen microbial extracellular electron transfer (EET), however, the deep-seated reasons remain unclear. Here we reported that Bacillus subtilis, a typical gram-positive bacterium capable of extra -cellular respiration, obtained a higher EET capacity after the electrical domestication. After the electrical domestication, the current generated by the EET of B. subtilis was 23.4-fold that of the control group without pre-domestication. Multiple lines of evidence in bacterial cells of B. subtilis, their cell walls, and a model tripeptide indicated that the polarization of amide groups after the electrical stimulation forwarded the H-bonds recombination and radical generation of protein-like substances to develop extracellular electron transfer via the proton-coupled pattern. The improved electrochemical properties of protein-like substances benefited the trans-cell-wall electron transfer and strengthen extra -cellular respiration. This study was the first exploration to promote microbial extracellular respiration by improving the electrochemical properties of protein-like substances in cell envelopes.

Automated summary

Electrical stimulation was found to enhance microbial extracellular electron transfer (EET), but the underlying reasons were unclear. This study showed that Bacillus subtilis, a gram-positive bacterium capable of extracellular respiration, had a higher EET capacity after electrical domestication. It was discovered that the polarization of amide groups induced by electrical stimulation promoted H-bond recombination and radical generation of protein-like substances, facilitating extracellular electron transfer via proton-coupled mechanism.