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Dantas, JM, Tomaz DM, Morgado L, Salgueiro CA.  2013.  Functional characterization of PccH, a key cytochrome for electron transfer from electrodes to the bacterium Geobacter sulfurreducens. FEBS Letters. 587(16):2662-2668. AbstractWebsite

The cytochrome PccH from Geobacter sulfurreducens (Gs) plays a crucial role in current-consuming fumarate-reducing biofilms. Deletion of pccH gene inhibited completely electron transfer from electrodes toward Gs cells. The pccH gene was cloned and the protein heterologously expressed in Escherichia coli. Complementary biophysical techniques including CD, UV-visible and NMR spectroscopy were used to characterize PccH. This cytochrome contains one low-spin c-type heme with His-Met axial coordination and unusual low-reduction potential. This reduction potential is pH-dependent, within the Gs physiological pH range, and is discussed within the context of the electron transfer mechanisms from electrodes to Gs cells.

Salgueiro, CA, Morgado L, Silva MA, Ferreira MR, Fernandes TM, Portela PC.  2022.  From iron to bacterial electroconductive filaments: Exploring cytochrome diversity using Geobacter bacteria. Coordination Chemistry Reviews. 452:214284. AbstractWebsite

Iron is the most versatile of all biochemically active metals, with variability encompassing its electronic configuration, number of unpaired electrons, type of ligands and iron-complexes stability. The versatility of iron properties is transposed to the proteins it can be associated to, especially relevant in the case of heme proteins. In this Review, the structural and functional properties of heme proteins are revisited, with particular focus on c-type cytochromes. The genome of Geobacter bacteria encodes for an unusually high number of assorted c-type cytochromes and, for this reason, they are used in this Review as a showcase of the cytochrome diversity. In the last decades, a vast portfolio of cytochromes has been revealed in these bacteria, with most of them defining new classes, ranging from monoheme to the recently identified polymeric assembly of multiheme cytochromes that forms micrometer-long electrically conductive filaments. These discoveries were on pace with the development of modern NMR equipment and advances in protein isotopic labeling methods, which are also revisited in this Review. Finally, following the description of the current state of the art of Geobacter cytochromes, examples on how the available structural and functional information was explored to structurally map protein–protein and protein–ligand interacting regions in redox complexes, and hence elucidate Geobacter’s respiratory pathways, are presented.

Morgado, L, Dantas JM, Bruix M, Londer YY, Salgueiro CA.  2012.  Fine Tuning of Redox Networks on Multiheme Cytochromes from Geobacter sulfurreducens Drives Physiological Electron/Proton Energy Transduction. Bioinorganic Chemistry and Applications. 2012(Article ID 298739):1-9. AbstractWebsite

The bacterium Geobacter sulfurreducens (Gs) can grow in the presence of extracellular terminal acceptors, a property that is currently explored to harvest electricity from aquatic sediments and waste organic matter into microbial fuel cells. A family composed of five triheme cytochromes (PpcA-E) was identified in Gs. These cytochromes play a crucial role by bridging the electron transfer from oxidation of cytoplasmic donors to the cell exterior and assisting the reduction of extracellular terminal acceptors. The detailed thermodynamic characterization of such proteins showed that PpcA and PpcD have an important redox-Bohr effect that might implicate these proteins in the e−/H+ coupling mechanisms to sustain cellular growth. The physiological relevance of the redox-Bohr effect in these proteins was studied by determining the fractional contribution of each individual redox-microstate at different pH values. For both proteins, oxidation progresses from a particular protonated microstate to a particular deprotonated one, over specific pH ranges. The preferred e−/H+ transfer pathway established by the selected microstates indicates that both proteins are functionally designed to couple e−/H+ transfer at the physiological pH range for cellular growth.