Microbial fuel cell (MFC) primarily consists of anode, cathode, and membrane. To minimize the internal resistance and thus improve the MFC performances, abiotic stretagies such as coating effective catalysts on the anode and cathode have been thoroughly investigated. However, the microbial mechanisms of anodic/cathodic current generation were emphasized more in the present studies. For the anode, bacteria utilizing electron transfer pathway is called “exoelectrogens” or “anodophiles”, which were considerablely studied using two model mocrooganisms: Geobacter sp. and Shewanella sp. in the past studies. However, some other bacteria which can also utilize this pathway are successively found and isolated in many studies. In addition, the idea of bacterial catalysts is attractive due to the consideration of low cost and high efficiency. Accordingly, this study focuses on the microbial communities and isolates on the bio-anode and bio-cathode that were respectively inuculated with the mixed cultures obtained from the Hsinchu rice field and Dihua sewage treatment plant. Besides, to examine the ferric-citrate- and amorphous-iron reducing capabilities of anodic microorganisms and the oxygen-reduction enhancement by cathodic microorganisms, the current-generating mechanisms were directly observed in the MFCs by reading the results of power density curves, electrochemical impedance spectroscopy, and cyclic voltammetry. In this research, Macellibacteroides fermentans was isolates to be a new exoelectrogens from bio-anode. Stenotrophomonas maltophilia is the most effective microorganisms assisting cathodic process from oxygen reduction, but no significant electrochemical activity of it was detected. By selectively amending powerful bacteria on the anode and cathode, a better MFC performance can be anticipated in the future.