Rapid electron exchange between surface-exposed bacterial cytochromes and Fe(III) minerals

White, Gaye F.; Shi, Zhi; Shi, Liang; Wang, Zheming; Dohnálková, Alice; Marshall, Matthew J.; Fredrickson, James K.; Zachara, John M.; Butt, Julea N.; Richardson, David J.; Clarke, Thomas A.

doi:10.1073/pnas.1220074110

Cited by 184 publications

(226 citation statements)

References 30 publications

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“…Therefore, a significant KIE on EET by the OM Cyt c complex may indicate that the rate of proton removal from the periplasm limits the rate of EET. This idea is in accordance with previous experiments that compared the rate of EET in whole‐cell systems with that of purified OM Cyt c complexes 12. The in vivo EET rate per OM Cyt c complex is at least 10‐fold lower (10 2 –10 3 electrons s −1 ) than that in a purified system 13.…”

supporting

confidence: 91%

Proton Transport in the Outer‐Membrane Flavocytochrome Complex Limits the Rate of Extracellular Electron Transport

et al. 2017

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The microbial transfer of electrons to extracellularly located solid compounds, termed extracellular electron transport (EET), is critical for microbial electrode catalysis. Although the components of the EET pathway in the outer membrane (OM) have been identified, the role of electron/cation coupling in EET kinetics is poorly understood. We studied the dynamics of proton transport associated with EET in an OM flavocytochrome complex in Shewanella oneidensis MR‐1. Using a whole‐cell electrochemical assay, a significant kinetic isotope effect (KIE) was observed following the addition of deuterated water (D2O). The removal of a flavin cofactor or key components of the OM flavocytochrome complex significantly increased the KIE in the presence of D2O to values that were significantly larger than those reported for proton channels and ATP synthase, thus indicating that proton transport by OM flavocytochrome complexes limits the rate of EET.

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supporting

confidence: 91%

Proton Transport in the Outer‐Membrane Flavocytochrome Complex Limits the Rate of Extracellular Electron Transport

et al. 2017

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“…In fact, the rates for the thermodynamically unfavorable ET steps do not fall below those for the thermodynamically reversible steps. As a result, the maximum intrinsic electron flux through the heme wire is maintained at 10 4 −10 5 s −1 , just slightly higher than recently measured acceptor-limited transport rates through the multiheme protein complex MtrCAB (18). The structural similarity of MtrF with homologs UndA (19) and MtrC (20) allows us to generalize our findings to these cytochromes also, suggesting an important electron transfer strategy in nature well conserved because of its efficiency for long-range electron transport.…”

Section: Significancesupporting

confidence: 52%

“…4 can be used to interpret recent experiments where MtrCAB was assembled into a proteoliposome and the rates for ET from an internal chemical electron donor (methyl viologen) across the lipid membrane via MtrCAB to solid phase Fe(III) oxides were measured (18). The overall rate constant reported was dependent on the type of Fe(III) mineral used, ranging from 1,133 to 8,500 s −1 .…”

Section: Discussionmentioning

confidence: 99%

Electron flow in multiheme bacterial cytochromes is a balancing act between heme electronic interaction and redox potentials

Breuer

Rosso

Blumberger

2014

Proc. Natl. Acad. Sci. U.S.A.

172

189

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The naturally widespread process of electron transfer from metal reducing bacteria to extracellular solid metal oxides entails unique biomolecular machinery optimized for long-range electron transport. To perform this function efficiently, microorganisms have adapted multiheme c-type cytochromes to arrange heme cofactors into wires that cooperatively span the cellular envelope, transmitting electrons along distances greater than 100 Å. Implications and opportunities for bionanotechnological device design are selfevident. However, at the molecular level, how these proteins shuttle electrons along their heme wires, navigating intraprotein intersections and interprotein interfaces efficiently, remains a mystery thus far inaccessible to experiment. To shed light on this critical topic, we carried out extensive quantum mechanics/molecular mechanics simulations to calculate stepwise heme-to-heme electron transfer rates in the recently crystallized outer membrane deca-heme cytochrome MtrF. By solving a master equation for electron hopping, we estimate an intrinsic, maximum possible electron flux through solvated MtrF of 10 4 -10 5 s −1 , consistent with recently measured rates for the related multiheme protein complex MtrCAB. Intriguingly, our calculations show that the rapid electron transport through MtrF is the result of a clear correlation between heme redox potential and the strength of electronic coupling along the wire: thermodynamically uphill steps occur only between electronically well-connected stacked heme pairs. This observation suggests that the protein evolved to harbor low-potential hemes without slowing down electron flow. These findings are particularly profound in light of the apparently well-conserved staggered cross-heme wire structural motif in functionally related outer membrane proteins.respiration | density functional theory

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“…The result is electron transfer from OMMC to the bound flavin cofactor that is 10 3 -to 10 5 -fold faster than to free flavin. Recent studies on MtrCAB-containing proteoliposomes showed that the MtrCAB porin-cytochrome complex represents the minimal requirement for rapid electron transfer to the microbe-mineral interface (17). However, this work does not exclude a role for flavins in enhancing the rates of electron transfer under certain conditions.…”

mentioning

confidence: 64%

“…Protein film voltammetry measurements have shown that S. oneidensis OmcA and MtrC can transfer electrons rapidly and directly to graphite and hematite electrodes (13)(14)(15)(16). Most recently, the MtrCAB complex was reconstituted in proteoliposomes and shown to move electrons rapidly from an intravesicular electron pool to extravesicular nanoparticle suspensions of goethite, hematite, and lepidocrocite (17).…”

mentioning

confidence: 99%

Controlling electron transfer at the microbe–mineral interface

Richardson

Butt

Clarke

2013

Proc. Natl. Acad. Sci. U.S.A.

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Rapid electron exchange between surface-exposed bacterial cytochromes and Fe(III) minerals

Cited by 184 publications

References 30 publications

Proton Transport in the Outer‐Membrane Flavocytochrome Complex Limits the Rate of Extracellular Electron Transport

Proton Transport in the Outer‐Membrane Flavocytochrome Complex Limits the Rate of Extracellular Electron Transport

Electron flow in multiheme bacterial cytochromes is a balancing act between heme electronic interaction and redox potentials

Controlling electron transfer at the microbe–mineral interface

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