Characterization of a novel strain phylogenetically related to Kocuria rhizophila and its chemical modification to improve performance of microbial fuel cells.

It is certainly an important research area to discovery new exoelectrogens for microbial fuel cells (MFCs), and how to effectively manipulate its cell property to improve power performance is still a great challenge. In this study, a new electrochemically active bacterium phylogenetically related to Kocuria rhizophila was first isolated and found electrogenic in MFCs, which was identified through the combination methods of molecular biology, physiological, biochemical and morphological characteristics. The MFCs inoculated with this strain generated power from a wide variety of substrates, reached a maximum power density of 75mW/m(2) in the substrate of 1g/L glucose. And the electron transfer mechanism was confirmed to be dominantly direct biofilm mechanism. Chemical treatment with five reagents was verified to be a feasible strategy to improve the power density of MFCs, increasing approximately 1.75 fold at most after treated with lysozyme. This enhancement was contributed to the significant enhancement on cell permeability, cell membrane fluidity and Coenzyme Q10 (the electron carrier). Thus this work offered a novel Gram-positive electrogenic bacterium and proved chemical treatment was a feasible strategy to improve electron transfer for application in MFCs.