Abstract
Extracellular electron transfer pathways allow bacteria to transfer electrons from the cell metabolism to extracellular substrates, such as metal oxides in natural environments and electrodes in microbial electrochemical technologies (MET). Studies of electroactive microorganism and mainly of Shewanella oneidensis MR-1 have demonstrated that extracellular electron transfer pathways relies on several multiheme c-type cytochromes. The small tetraheme cytochrome c (STC) is highly conserved among Shewanella species and is one of the most abundant cytochromes in the periplasmic space. It transfers electrons from the cell metabolism delivered by the inner-membrane tetraheme cytochrome CymA, to the porin-cytochrome complex MtrCAB in the outer-membrane, to reduce solid electron acceptors outside the cell, or electrodes in the case of MET. In this work knock-out strains of STC of S. oneidensis MR-1, expressing STC from distinct Shewanella species were tested for their ability to perform extracellular electron transfer, allowing to explore the effect of protein mutations in living organisms. These studies, complemented by a biochemical evaluation of the electron transfer properties of the individual proteins, revealed a considerable plasticity in the molecular components involved in extracellular electron transfer. The results of this work are pioneering and of significant relevance for future rational design of cytochromes in order to enhance extracellular electron transfer and thus contribute to the practical implementation of MET.
Highlights
The growing demand of renewable energy sources has increased the interest in microbial electrochemical technologies (MET), in particular of microbial fuel cells (MFC) (Logan and Regan, 2006; Arends and Verstraete, 2012; Ucar et al, 2017)
In this study we investigated the ability of the electroactive bacterium Shewanella oneidensis molecular replacement (MR)-1 to perform extracellular electron transfer with small tetraheme cytochrome c (STC) orthologs
Cells from S. algae were grown under aerobic conditions (180 rpm) in a batch culture at 37◦C, using Terrific Broth (TB) medium supplemented with 10 g/L NaCl
Summary
The growing demand of renewable energy sources has increased the interest in microbial electrochemical technologies (MET), in particular of microbial fuel cells (MFC) (Logan and Regan, 2006; Arends and Verstraete, 2012; Ucar et al, 2017). Accompanying the growth of this research field, MET have seen significant developments and nowadays, besides electrical power generation, they can promote different sustainable technologies including wastewater treatment, water desalination, bioremediation of soils and aquifers and production of added value compounds (Logan and Rabaey, 2012; Bajracharya et al, 2016) It is the ability of electroactive organisms [i.e., organisms capable of interacting with an electrode (Koch and Harnisch, 2016)] to perform extracellular electron transfer that is at the heart of these systems, allowing them to exchange electrons with electrodes in MET (Richardson et al, 2012; White et al, 2016). This is a consequence of the fact that the organisms used in MET function as they would in their natural environment and did not evolved to grow and live in the conditions used in MET (Torres et al, 2010; Torres, 2014)
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