초록
<P><I>Pseudomonas aeruginosa</I> is an important, thriving member of microbial communities of microbial bioelectrochemical systems (BES) through the production of versatile phenazine redox mediators. Pure culture experiments with a model strain revealed synergistic interactions of <I>P. aeruginosa</I> with fermenting microorganisms whereby the synergism was mediated through the shared fermentation product 2,3-butanediol. Our work here shows that the behavior and efficiency of <I>P. aeruginosa</I> in mediated current production is strongly dependent on the strain of <I>P. aeruginosa</I>. We compared levels of phenazine production by the previously investigated model strain <I>P. aeruginosa</I> PA14, the alternative model strain <I>P. aeruginosa</I> PAO1, and the BES isolate <I>Pseudomonas</I> sp. strain KRP1 with glucose and the fermentation products 2,3-butanediol and ethanol as carbon substrates. We found significant differences in substrate-dependent phenazine production and resulting anodic current generation for the three strains, with the BES isolate KRP1 being overall the best current producer and showing the highest electrochemical activity with glucose as a substrate (19 μA cm<SUP>−2</SUP> with ∼150 μg ml<SUP>−1</SUP> phenazine carboxylic acid as a redox mediator). Surprisingly, <I>P. aeruginosa</I> PAO1 showed very low phenazine production and electrochemical activity under all tested conditions.</P><P><B>IMPORTANCE</B> Microbial fuel cells and other microbial bioelectrochemical systems hold great promise for environmental technologies such as wastewater treatment and bioremediation. While there is much emphasis on the development of materials and devices to realize such systems, the investigation and a deeper understanding of the underlying microbiology and ecology are lagging behind. Physiological investigations focus on microorganisms exhibiting direct electron transfer in pure culture systems. Meanwhile, mediated electron transfer with natural redox compounds produced by, for example, <I>Pseudomonas aeruginosa</I> might enable an entire microbial community to access a solid electrode as an alternative electron acceptor. To better understand the ecological relationships between mediator producers and mediator utilizers, we here present a comparison of the phenazine-dependent electroactivities of three <I>Pseudomonas</I> strains. This work forms the foundation for more complex coculture investigations of mediated electron transfer in microbial fuel cells.</P>