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1. Survival of the first rather than the fittest in a Shewanella electrode biofilm

Author

Eric D. Kees, Caleb E. Levar, Stephen P. Miller, Daniel R. Bond, Jeffrey A. Gralnick, and Antony M. Dean

Subjects
Biology (General), QH301-705.5
Abstract

Eric Kees et al. explore whether ecological competition differs between surface-attached biofilms and planktonic culture using two differentially-reproducing strains of Shewanella oneidensis. They observed that, regardless of different growth rates, the first bacterial species to colonize a surface would persist and would not be excluded by a faster growing competitor.

Published
2021
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2. An Inner Membrane Cytochrome Required Only for Reduction of High Redox Potential Extracellular Electron Acceptors

Author

Caleb E. Levar, Chi Ho Chan, Misha G. Mehta-Kolte, and Daniel R. Bond

Subjects
Microbiology, QR1-502
Abstract

ABSTRACT Dissimilatory metal-reducing bacteria, such as Geobacter sulfurreducens, transfer electrons beyond their outer membranes to Fe(III) and Mn(IV) oxides, heavy metals, and electrodes in electrochemical devices. In the environment, metal acceptors exist in multiple chelated and insoluble forms that span a range of redox potentials and offer different amounts of available energy. Despite this, metal-reducing bacteria have not been shown to alter their electron transfer strategies to take advantage of these energy differences. Disruption of imcH, encoding an inner membrane c-type cytochrome, eliminated the ability of G. sulfurreducens to reduce Fe(III) citrate, Fe(III)-EDTA, and insoluble Mn(IV) oxides, electron acceptors with potentials greater than 0.1 V versus the standard hydrogen electrode (SHE), but the imcH mutant retained the ability to reduce Fe(III) oxides with potentials of ≤−0.1 V versus SHE. The imcH mutant failed to grow on electrodes poised at +0.24 V versus SHE, but switching electrodes to −0.1 V versus SHE triggered exponential growth. At potentials of ≤−0.1 V versus SHE, both the wild type and the imcH mutant doubled 60% slower than at higher potentials. Electrodes poised even 100 mV higher (0.0 V versus SHE) could not trigger imcH mutant growth. These results demonstrate that G. sulfurreducens possesses multiple respiratory pathways, that some of these pathways are in operation only after exposure to low redox potentials, and that electron flow can be coupled to generation of different amounts of energy for growth. The redox potentials that trigger these behaviors mirror those of metal acceptors common in subsurface environments where Geobacter is found. IMPORTANCE Insoluble metal oxides in the environment represent a common and vast reservoir of energy for respiratory microbes capable of transferring electrons across their insulating membranes to external acceptors, a process termed extracellular electron transfer. Despite the global biogeochemical importance of metal cycling and the ability of such organisms to produce electricity at electrodes, fundamental gaps in the understanding of extracellular electron transfer biochemistry exist. Here, we describe a conserved inner membrane redox protein in Geobacter sulfurreducens which is required only for electron transfer to high-potential compounds, and we show that G. sulfurreducens has the ability to utilize different electron transfer pathways in response to the amount of energy available in a metal or electrode distant from the cell.

Published
2014
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5. Survival of the first rather than the fittest in a Shewanella electrode biofilm

Author

Caleb E. Levar, Antony M. Dean, Eric D. Kees, Jeffrey A. Gralnick, Daniel R. Bond, and Stephen P. Miller

Subjects
Shewanella, Bioelectric Energy Sources, Surface Properties, QH301-705.5, Offspring, Survival of the fittest, Population, Medicine (miscellaneous), Biology, Article, General Biochemistry, Genetics and Molecular Biology, Electron Transport, 03 medical and health sciences, Biology (General), Shewanella oneidensis, education, Electrodes, Selection (genetic algorithm), 030304 developmental biology, 0303 health sciences, education.field_of_study, Natural selection, 030306 microbiology, Ecology, Biofilm, Bacteriology, biology.organism_classification, Experimental evolution, Biofilms, General Agricultural and Biological Sciences
Abstract

For natural selection to operate there must exist heritable variation among individuals that affects their survival and reproduction. Among free-living microbes, where differences in growth rates largely define selection intensities, competitive exclusion is common. However, among surface attached communities, these dynamics become less predictable. If extreme circumstances were to dictate that a surface population is immortal and all offspring must emigrate, the offspring would be unable to contribute to the composition of the population. Meanwhile, the immortals, regardless of reproductive capacity, would remain unchanged in relative abundance. The normal cycle of birth, death, and competitive exclusion would be broken. We tested whether conditions required to set up this idealized scenario can be approximated in a microbial biofilm. Using two differentially-reproducing strains of Shewanella oneidensis grown on an anode as the sole terminal electron acceptor – a system in which metabolism is obligately tied to surface attachment – we found that selection against a slow-growing competitor is drastically reduced. This work furthers understanding of natural selection dynamics in sessile microbial communities, and provides a framework for designing stable microbial communities for industrial and experimental applications., Eric Kees et al. explore whether ecological competition differs between surface-attached biofilms and planktonic culture using two differentially-reproducing strains of Shewanella oneidensis. They observed that, regardless of different growth rates, the first bacterial species to colonize a surface would persist and would not be excluded by a faster growing competitor.

Published
2021

6. Genome Scale Mutational Analysis of Geobacter sulfurreducens Reveals Distinct Molecular Mechanisms for Respiration and Sensing of Poised Electrodes versus Fe(III) Oxides

Author

Chi Ho Chan, Daniel R. Bond, Caleb E. Levar, and Fernanda Jiménez Otero

Subjects
0301 basic medicine, Standard hydrogen electrode, 030106 microbiology, Mutant, Tn-Seq, multiheme cytochrome, Microbiology, Ferric Compounds, Electron Transport, 03 medical and health sciences, Electron transfer, Bacterial Proteins, Fumarates, Extracellular, Molecular Biology, Geobacter sulfurreducens, Electrodes, chemistry.chemical_classification, Genomic Library, extracellular electron transfer, biology, Biofilm, Electron acceptor, biology.organism_classification, chemistry, Biofilms, Mutation, Biophysics, DNA Transposable Elements, Geobacter, Oxidation-Reduction, Genome, Bacterial, extracellular respiration, Research Article
Abstract

Geobacter sulfurreducensgenerates electrical current by coupling intracellular oxidation of organic acids to the reduction of proteins on the cell surface that are able to interface with electrodes. This ability is attributed to the bacterium's capacity to respire other extracellular electron acceptors that require contact, such as insoluble metal oxides. To directly investigate the genetic basis of electrode-based respiration, we constructedGeobacter sulfurreducenstransposon-insertion sequencing (Tn-Seq) libraries for growth, with soluble fumarate or an electrode as the electron acceptor. Libraries with >33,000 unique insertions and an average of 9 insertions/kb allowed an assessment of each gene's fitness in a single experiment. Mutations in 1,214 different genomic features impaired growth with fumarate, and the significance of 270 genes unresolved by annotation due to the presence of one or more functional homologs was determined. Tn-Seq analysis of −0.1 V versus standard hydrogen electrode (SHE) electrode-grown cells identified mutations in a subset of genes encoding cytochromes, processing systems for proline-rich proteins, sensory networks, extracellular structures, polysaccharides, and metabolic enzymes that caused at least a 50% reduction in apparent growth rate. Scarless deletion mutants of select genes identified via Tn-Seq revealed a new putative porin-cytochrome conduit complex (extABCD) crucial for growth with electrodes, which was not required for Fe(III) oxide reduction. In addition, four mutants lacking components of a putative methyl-accepting chemotaxis–cyclic dinucleotide sensing network (esnABCD) were defective in electrode colonization but grew normally with Fe(III) oxides. These results suggest thatG. sulfurreducenspossesses distinct mechanisms for recognition, colonization, and reduction of electrodes compared to Fe(III) oxides.IMPORTANCESince metal oxide electron acceptors are insoluble, one hypothesis is that cells sense and reduce metals using the same molecular mechanisms used to form biofilms on electrodes and produce electricity. However, by simultaneously comparing thousands ofGeobacter sulfurreducenstransposon mutants undergoing electrode-dependent respiration, we discovered new cytochromes and chemosensory proteins supporting growth with electrodes that are not required for metal respiration. This supports an emerging model whereG. sulfurreducensrecognizes surfaces and forms conductive biofilms using mechanisms distinct from those used for growth with metal oxides. These findings provide a possible explanation for studies that correlate electricity generation with syntrophic interspecies electron transfer byGeobacterand reveal many previously unrecognized targets for engineering this useful capability in other organisms.

Published
2017

7. Genome scale mutational analysis ofGeobacter sulfurreducensreveals distinct molecular mechanisms for respiration of poised electrodes vs. Fe(III) oxides

Author

Caleb E. Levar, Fernanda Jiménez Otero, Chi Ho Chan, and Daniel R. Bond

Subjects
Transposable element, chemistry.chemical_classification, biology, Cytochrome, Mutant, Biofilm, Electron acceptor, biology.organism_classification, Electron transfer, Biochemistry, chemistry, biology.protein, Geobacter sulfurreducens, Geobacter
Abstract

Geobacter sulfurreducens generates electricity by coupling intracellular oxidation of organic acids with electron transfer to the cell exterior, while maintaining a conductive connection to electrode surfaces. This unique ability has been attributed to the bacterium9s capacity to also respire extracellular terminal electron acceptors that require contact, such as insoluble metal oxides. To expand the molecular understanding of electricity generation mechanisms, we constructed Geobacter sulfurreducens transposon mutant (Tn-Seq) libraries for growth with soluble fumarate or an electrode surface as the electron acceptor. Mutant libraries with over 33,000 unique transposon insertions and an average of 9 transposon insertions per kb allowed identification of 1,214 genomic features essential for growth with fumarate, including over 270 genes with one or more functional homologs that could not be resolved by previous annotation or in silico modeling. Tn-Seq analysis of electrode-grown cells identified mutations in over 50 genes encoding cytochromes, processing systems for proline-rich proteins, sensory systems, extracellular structures, polysaccharides, metabolic enzymes and hypothetical proteins that caused at least a 50% reduction in apparent growth rate. Scarless deletion mutants of genes identified via Tn-Seq revealed a new putative c-type cytochrome conduit complex ( extABCD ) essential for growth with electrodes, which was not required for Fe(III)-oxide reduction. In addition, mutants lacking components of a putative methyl-accepting chemotaxis/cyclic dinucleotide sensing network ( esnABCD ) were defective in electrode growth, but grew normally with Fe(III)-oxides. These results suggest that G. sulfurreducens possesses distinct mechanisms for recognition, colonization, and reduction of electrodes compared to other environmental electron acceptors. Importance: Many metal-reducing organisms can also generate electricity at anodes. Because metal oxide electron acceptors are insoluble, one hypothesis is that cells sense and reduce metal particles using the same molecular mechanisms used to form biofilms on electrodes and produce electricity. However, by simultaneously comparing thousands of Geobacter sulfurreducens transposon mutants undergoing electrode-dependent respiration, we discovered new cytochromes and chemosensory proteins essential for growth with electrodes that are not required for metal respiration. This supports an emerging hypothesis where G. sulfurreducens recognizes surfaces and forms conductive biofilms using sensing and electron transfer pathways distinct from those used for growth with metal oxides. These findings provide a molecular explanation for studies that correlate electricity generation on electrode surfaces with direct interspecies electron transfer rather than metal reduction by Geobacter species, and reveal many previously unrecognized targets for improving and engineering this biotechnologically useful capability in other organisms.

Published
2016

8. Redox potential as a master variable controlling pathways of metal reduction byGeobacter sulfurreducens

Author

Brandy M. Toner, Caleb E. Levar, Aubrey J Dunshee, Daniel R. Bond, and Colleen L. Hoffman

Subjects
0301 basic medicine, Standard hydrogen electrode, 030106 microbiology, Biology, Microbiology, Redox, Electron Transport, Metal, 03 medical and health sciences, Electron transfer, Bacterial Proteins, Oxidizing agent, Electrodes, Geobacter sulfurreducens, Ecology, Evolution, Behavior and Systematics, chemistry.chemical_classification, Oxides, Gene Expression Regulation, Bacterial, Electron acceptor, biology.organism_classification, Quinone, Biochemistry, chemistry, Metals, visual_art, Biophysics, visual_art.visual_art_medium, Original Article, Geobacter, Oxidation-Reduction
Abstract

Geobacter sulfurreducensuses at least two different pathways to transport electrons out of the inner membrane quinone pool before reducing acceptors beyond the outer membrane. When growing on electrodes poised at oxidizing potentials, the CbcL-dependent pathway operates at or below redox potentials of −0.10 V vs. the Standard Hydrogen Electrode (SHE), while the ImcH-dependent pathway operates only above this value. Here, we provide evidence thatG. sulfurreducensalso requires different electron transfer proteins for reduction of a wide range of Fe(III)- and Mn(IV)- (oxyhydr)oxides, and must transition from a high- to low-potential pathway during reduction of commonly studied soluble and insoluble metal electron acceptors. Freshly precipitated Fe(III)-(oxyhydr)oxides could not be reduced by mutants lacking the high potential pathway. Aging these minerals by autoclaving did not change their powder X-ray diffraction pattern, but restored reduction by mutants lacking the high-potential pathway. Mutants lacking the low-potential, CbcL-dependent pathway had higher growth yields with both soluble and insoluble Fe(III). Together, these data suggest that the ImcH-dependent pathway exists to harvest additional energy when conditions permit, and CbcL switches on to allow respiration closer to thermodynamic equilibrium conditions. With evidence of multiple pathways within a single organism, the study of extracellular respiration should consider not only the crystal structure or solubility of a mineral electron acceptor, but rather the redox potential, as this variable determines the energetic reward affecting reduction rates, extents, and final microbial growth yields in the environment.

Published
2016

9. Identification of Genes Involved in Biofilm Formation and Respiration via Mini- Himar Transposon Mutagenesis of Geobacter sulfurreducens

Author

Daniel R. Bond, Janet B. Rollefson, and Caleb E. Levar

Subjects
Physiology and Metabolism, Auxotrophy, Cell Respiration, Protein domain, Mutagenesis (molecular biology technique), medicine.disease_cause, Microbiology, Bacterial Proteins, Electrochemistry, medicine, Molecular Biology, Escherichia coli, Geobacter sulfurreducens, Microscopy, Confocal, biology, Genetic Complementation Test, Biofilm, Gene Expression Regulation, Bacterial, Sequence Analysis, DNA, biology.organism_classification, Cell biology, Phenotype, Mutagenesis, Biofilms, DNA Transposable Elements, Transposon mutagenesis, Geobacter, Plasmids
Abstract

Electron transfer from cells to metals and electrodes by the Fe(III)-reducing anaerobe Geobacter sulfurreducens requires proper expression of redox proteins and attachment mechanisms to interface bacteria with surfaces and neighboring cells. We hypothesized that transposon mutagenesis would complement targeted knockout studies in Geobacter spp. and identify novel genes involved in this process. Escherichia coli mating strains and plasmids were used to develop a conjugation protocol and deliver mini- Himar transposons, creating a library of over 8,000 mutants that was anaerobically arrayed and screened for a range of phenotypes, including auxotrophy for amino acids, inability to reduce Fe(III) citrate, and attachment to surfaces. Following protocol validation, mutants with strong phenotypes were further characterized in a three-electrode system to simultaneously quantify attachment, biofilm development, and respiratory parameters, revealing mutants defective in Fe(III) reduction but unaffected in electron transfer to electrodes (such as an insertion in GSU1330, a putative metal export protein) or defective in electrode reduction but demonstrating wild-type biofilm formation (due to an insertion upstream of the NHL domain protein GSU2505). An insertion in a putative ATP-dependent transporter (GSU1501) eliminated electrode colonization but not Fe(III) citrate reduction. A more complex phenotype was demonstrated by a mutant containing an insertion in a transglutaminase domain protein (GSU3361), which suddenly ceased to respire when biofilms reached approximately 50% of the wild-type levels. As most insertions were not in cytochromes but rather in transporters, two-component signaling proteins, and proteins of unknown function, this collection illustrates how biofilm formation and electron transfer are separate but complementary phenotypes, controlled by multiple loci not commonly studied in Geobacter spp.

Published
2009

10. Scarless Genome Editing and Stable Inducible Expression Vectors for Geobacter sulfurreducens

Author

Caleb E. Levar, Chi Ho Chan, Daniel R. Bond, Jonathan P. Badalamenti, and Lori Zacharoff

Subjects
Genetics, Transposable element, Ecology, biology, Mutant, Genetic Vectors, Molecular Sequence Data, Biofilm, biology.organism_classification, Applied Microbiology and Biotechnology, Complementation, Electron Transport, Plasmid, Biochemistry, Methods, Geobacter, Geobacter sulfurreducens, Genome, Bacterial, Food Science, Biotechnology, Regulator gene, Plasmids
Abstract

Metal reduction by members of the Geobacteraceae is encoded by multiple gene clusters, and the study of extracellular electron transfer often requires biofilm development on surfaces. Genetic tools that utilize polar antibiotic cassette insertions limit mutant construction and complementation. In addition, unstable plasmids create metabolic burdens that slow growth, and the presence of antibiotics such as kanamycin can interfere with the rate and extent of Geobacter biofilm growth. We report here genetic system improvements for the model anaerobic metal-reducing bacterium Geobacter sulfurreducens . A motile strain of G. sulfurreducens was constructed by precise removal of a transposon interrupting the fgrM flagellar regulator gene using SacB/sucrose counterselection, and Fe(III) citrate reduction was eliminated by deletion of the gene encoding the inner membrane cytochrome imcH . We also show that RK2-based plasmids were maintained in G. sulfurreducens for over 15 generations in the absence of antibiotic selection in contrast to unstable pBBR1 plasmids. Therefore, we engineered a series of new RK2 vectors containing native constitutive Geobacter promoters, and modified one of these promoters for VanR-dependent induction by the small aromatic carboxylic acid vanillate. Inducible plasmids fully complemented Δ imcH mutants for Fe(III) reduction, Mn(IV) oxide reduction, and growth on poised electrodes. A real-time, high-throughput Fe(III) citrate reduction assay is described that can screen numerous G. sulfurreducens strain constructs simultaneously and shows the sensitivity of imcH expression by the vanillate system. These tools will enable more sophisticated genetic studies in G. sulfurreducens without polar insertion effects or need for multiple antibiotics.

Published
2015

11. An Inner Membrane Cytochrome Required Only for Reduction of High Redox Potential Extracellular Electron Acceptors

Author

Daniel R. Bond, Caleb E. Levar, Chi Ho Chan, and Misha G. Mehta-Kolte

Subjects
chemistry.chemical_classification, biology, Standard hydrogen electrode, Cell Membrane, Cytochromes c, Electron acceptor, biology.organism_classification, Electrochemistry, Redox, Microbiology, QR1-502, Electron transfer, Membrane, chemistry, Biochemistry, Electricity, Metals, Virology, Biophysics, Geobacter, Geobacter sulfurreducens, Oxidation-Reduction, Gene Deletion, Research Article
Abstract

Dissimilatory metal-reducing bacteria, such as Geobacter sulfurreducens, transfer electrons beyond their outer membranes to Fe(III) and Mn(IV) oxides, heavy metals, and electrodes in electrochemical devices. In the environment, metal acceptors exist in multiple chelated and insoluble forms that span a range of redox potentials and offer different amounts of available energy. Despite this, metal-reducing bacteria have not been shown to alter their electron transfer strategies to take advantage of these energy differences. Disruption of imcH, encoding an inner membrane c-type cytochrome, eliminated the ability of G. sulfurreducens to reduce Fe(III) citrate, Fe(III)-EDTA, and insoluble Mn(IV) oxides, electron acceptors with potentials greater than 0.1 V versus the standard hydrogen electrode (SHE), but the imcH mutant retained the ability to reduce Fe(III) oxides with potentials of ≤−0.1 V versus SHE. The imcH mutant failed to grow on electrodes poised at +0.24 V versus SHE, but switching electrodes to −0.1 V versus SHE triggered exponential growth. At potentials of ≤−0.1 V versus SHE, both the wild type and the imcH mutant doubled 60% slower than at higher potentials. Electrodes poised even 100 mV higher (0.0 V versus SHE) could not trigger imcH mutant growth. These results demonstrate that G. sulfurreducens possesses multiple respiratory pathways, that some of these pathways are in operation only after exposure to low redox potentials, and that electron flow can be coupled to generation of different amounts of energy for growth. The redox potentials that trigger these behaviors mirror those of metal acceptors common in subsurface environments where Geobacter is found., IMPORTANCE Insoluble metal oxides in the environment represent a common and vast reservoir of energy for respiratory microbes capable of transferring electrons across their insulating membranes to external acceptors, a process termed extracellular electron transfer. Despite the global biogeochemical importance of metal cycling and the ability of such organisms to produce electricity at electrodes, fundamental gaps in the understanding of extracellular electron transfer biochemistry exist. Here, we describe a conserved inner membrane redox protein in Geobacter sulfurreducens which is required only for electron transfer to high-potential compounds, and we show that G. sulfurreducens has the ability to utilize different electron transfer pathways in response to the amount of energy available in a metal or electrode distant from the cell.

Published
2014

12. A trans-outer membrane porin-cytochrome protein complex for extracellular electron transfer by Geobacter sulfurreducens PCA

Author

Daniel R. Bond, Juan Liu, Marcus J. Edwards, David J. Richardson, James K. Fredrickson, Zhi Shi, John M. Zachara, Julea N. Butt, Thomas A. Clarke, Haluk Beyenal, Liang Shi, Jerome T. Babauta, Caleb E. Levar, Zheming Wang, David W. Kennedy, Kevin M. Rosso, and Yimo Liu

Subjects
biology, Cytochrome, Cytochromes c, Porins, Periplasmic space, biology.organism_classification, Agricultural and Biological Sciences (miscellaneous), Electron Transport, Biochemistry, Bacterial Proteins, Multigene Family, Porin, Gene cluster, biology.protein, Brief Reports, Bacterial outer membrane, Lipid bilayer, Geobacter, Geobacter sulfurreducens, Oxidation-Reduction, Ecology, Evolution, Behavior and Systematics, Bacterial Outer Membrane Proteins, Protein Binding
Abstract

The multi-heme, outer membrane c-type cytochrome (c-Cyt) OmcB of Geobacter sulfurreducens was previously proposed to mediate electron transfer across the outer membrane. However, the underlying mechanism has remained uncharacterized. In G. sulfurreducens, the omcB gene is part of two tandem four-gene clusters, each is predicted to encode a transcriptional factor (OrfR/OrfS), a porin-like outer membrane protein (OmbB/OmbC), a periplasmic c-type cytochrome (OmaB/OmaC) and an outer membrane c-Cyt (OmcB/OmcC) respectively. Here, we showed that OmbB/OmbC, OmaB/OmaC and OmcB/OmcC of G. sulfurreducens PCA formed the porin-cytochrome (Pcc) protein complexes, which were involved in transferring electrons across the outer membrane. The isolated Pcc protein complexes reconstituted in proteoliposomes transferred electrons from reduced methyl viologen across the lipid bilayer of liposomes to Fe(III)-citrate and ferrihydrite. The pcc clusters were found in all eight sequenced Geobacter and 11 other bacterial genomes from six different phyla, demonstrating a widespread distribution of Pcc protein complexes in phylogenetically diverse bacteria. Deletion of ombB-omaB-omcB-orfS-ombC-omaC-omcC gene clusters had no impact on the growth of G. sulfurreducens PCA with fumarate but diminished the ability of G. sulfurreducens PCA to reduce Fe(III)-citrate and ferrihydrite. Complementation with the ombB-omaB-omcB gene cluster restored the ability of G. sulfurreducens PCA to reduce Fe(III)-citrate and ferrihydrite.

Published
2014

13. Energetic and Molecular Constraints on the Mechanism of Environmental Fe(III) Reduction by Geobacter

Author

Caleb E. Levar, Janet B. Rollefson, and Daniel R. Bond

Subjects
chemistry.chemical_classification, biology, Chemistry, Nanotechnology, Electron donor, Electron, Electron acceptor, biology.organism_classification, Acceptor, Metal, chemistry.chemical_compound, Electron transfer, Chemical physics, visual_art, visual_art.visual_art_medium, Extracellular, Geobacter
Abstract

This review aims to discuss how Geobacter and its relatives are shaped by the nature of their electron donor and acceptor, where electrons liberated during complete cytoplasmic oxidation of organics must travel far beyond the cell to reduce extracellular metals without the aid of soluble shuttles. This sequence of reactions must often occur in permanently anoxic habitats where reactant concentrations lower the ∆G to only tens of kJ/mol, severely limiting the energy available for protein synthesis. Extracellular Fe(III) reduction is additionally challenging, from a bioenergetic perspective, as oxidation of organic matter (releasing protons and electrons) occurs in the cell interior, but only the negatively charged electrons are transferred outside the cell. Finally, the low amount of energy available from metals in direct contact with a cell predicts that Geobacter must organize electron transfer proteins to extend outward, to take advantage of the Fe(III) in the volume available a few microns beyond its outer membrane. This review will discuss these thermodynamic constraints on environmental metal reduction, and briefly mention recently described aspects of the molecular mechanism of electron transfer by Geobacter spp. when viewed through this lens.

Published
2012

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