Your search keyword '"electron bifurcation"' showing total 202 results

1. Kinetic studies of bifurcating flavoproteins

Author

Hille, Russ, Niks, Dimitri, Vigil, Wayne, Jr., Tran, Jessica, Ortiz, Steve, Menjivar, Kevin, and Nguyen, Derek

Published

2025

2. The rapid-reaction kinetics of an electron-bifurcating flavoprotein, the crotonyl-CoA-dependent NADH:ferredoxin oxidoreductase EtfAB:bcd.

Author

Nguyen, Derek, Vigil, Wayne, Niks, Dimitri, and Hille, Charles

Subjects

electron bifurcation, electron-transferring flavoprotein, ferredoxin, flavoprotein, rapid-reaction kinetics

Abstract

We have investigated the kinetic behavior of the electron-bifurcating crotonyl-CoA-dependent NADH: ferredoxin oxidoreductase EtfAB:bcd from Megasphaera elsdenii. The overall behavior of the complex in both the reductive and the oxidative half-reactions is consistent with that previously determined for the individual EtfAB and bcd components. This includes an uncrossing of the half-potentials of the bifurcating flavin of the EtfAB component in the course of ferredoxin-reducing catalysis, ionization of the bcd flavin semiquinone and the appearance of a charge transfer complex upon binding of the high potential acceptor crotonyl-CoA. The observed rapid-reaction rates of ferredoxin reduction are independent of [NADH], [crotonyl-CoA], and [ferredoxin], with an observed rate of ∼0.2 s-1, consistent with the observed steady-state kinetics. In enzyme-monitored turnover experiments, an approach to steady-state where the complexs flavins become reduced but no ferredoxin is generated is followed by a steady-state phase characterized by extensive ferredoxin reduction but little change in overall levels of flavin reduction. The approach to the steady-state phase can be eliminated by prior reduction of the complex, in which case there is no lag in the onset of ferredoxin reduction; this is consistent with the et FAD needing to be reduced to the level of the (anionic) semiquinone for bifurcation and concomitant ferredoxin reduction to occur. Single-turnover experiments support this conclusion, with the accumulation of the anionic semiquinone of the et FAD apparently required to prime the system for subsequent bifurcation and ferredoxin reduction.

Published

2024

3. Rapid-reaction kinetics of the bifurcating NAD+-dependent NADPH:ferredoxin oxidoreductase NfnI from Pyrococcus furiosus

Author

Ortiz, Steve, Niks, Dimitri, Wiley, Seth, Lubner, Carolyn E, and Hille, Russ

Subjects

Biochemistry and Cell Biology, Biological Sciences, Ferredoxins, Kinetics, NAD, NADP, Oxidation-Reduction, Oxidoreductases, Pyrococcus furiosus, Archaeal Proteins, electron bifurcation, electron paramagnetic resonance, electron transfer, flavoprotein, Chemical Sciences, Medical and Health Sciences, Biochemistry & Molecular Biology, Biological sciences, Biomedical and clinical sciences, Chemical sciences

Abstract

We have investigated the kinetics of NAD+-dependent NADPH:ferredoxin oxidoreductase (NfnI), a bifurcating transhydrogenase that takes two electron pairs from NADPH to reduce two ferredoxins and one NAD+ through successive bifurcation events. NADPH reduction takes place at the bifurcating FAD of NfnI's large subunit, with high-potential electrons transferred to the [2Fe-2S] cluster and S-FADH of the small subunit, ultimately on to NAD+; low-potential electrons are transferred to two [4Fe-4S] clusters of the large subunit and on to ferredoxin. Reduction of NfnI by NADPH goes to completion only at higher pH, with a limiting kred of 36 ± 1.6 s-1 and apparent KdNADPH of 5 ± 1.2 μM. Reduction of one of the [4Fe-4S] clusters of NfnI occurs within a second, indicating that in the absence of NAD+, the system can bifurcate and generate low-potential electrons without NAD+. When enzyme is reduced by NADPH in the absence of NAD+ but the presence of ferredoxin, up to three equivalents of ferredoxin become reduced, although the reaction is considerably slower than seen during steady-state turnover. Bifurcation appears to be limited by transfer of the first, high-potential electron into the high-potential pathway. Ferredoxin reduction without NAD+ demonstrates that electron bifurcation is an intrinsic property of the bifurcating FAD and is not dependent on the simultaneous presence of NAD+ and ferredoxin. The tight coupling between NAD+ and ferredoxin reduction observed under multiple-turnover conditions is instead simply due to the need to remove reducing equivalents from the high-potential electron pathway under multiple-turnover conditions.

Published

2023

4. Rethinking life and predicting its origin.

Author

Gonçalves, Diogo

Subjects

*ORIGIN of life, *HYDROTHERMAL vents, *ELECTRONS, *DEFINITIONS, *FORECASTING

Abstract

The definition, origin and recreation of life remain elusive. As others have suggested, only once we put life into reductionist physical terms will we be able to solve those questions. To that end, this work proposes the phenomenon of life to be the product of two dissipative mechanisms. From them, one characterises extant biological life and deduces a testable scenario for its origin. The proposed theory of life allows its replication, reinterprets ecological evolution and creates new constraints on the search for life. [ABSTRACT FROM AUTHOR]

Published

2024

5. Structures and Electron Transport Paths in the Four Families of Flavin-Based Electron Bifurcation Enzymes

Author

Feng, Xiang, Schut, Gerrit J., Adams, Michael W. W., Li, Huilin, Harris, J. Robin, Series Editor, and Marles-Wright, Jon, editor

Published

2024

6. Diverse non-canonical electron bifurcating [FeFe]-hydrogenases of separate evolutionary origins in Hydrogenedentota

Author

Xiaowei Zheng and Li Huang

Subjects

Hydrogenedentota, electron bifurcation, [FeFe]-hydrogenase, gene transfer and loss, Microbiology, QR1-502

Abstract

ABSTRACT Hydrogenedentota, a globally distributed bacterial phylum-level lineage, is poorly understood. Here, we established a comprehensive genomic catalog of Hydrogenedentota, including a total of seven clades (or families) with 179 genomes, and explored the metabolic potential and evolutionary history of these organisms. We show that a single genome, especially those belonging to Clade 6, often encodes multiple hydrogenases with genomes in Clade 2, which rarely encode hydrogenases being the exception. Notably, most members of Hydrogenedentota contain a group A3 [FeFe]-hydrogenase (BfuABC) with a non-canonical electron bifurcation mechanism, in addition to substrate-level phosphorylation and electron transport-linked phosphorylation pathways, in energy conservation. Furthermore, we show that BfuABC from Hydrogenedentota fall into five sub-types. Phylogenetic analysis reveals five independent routes for the evolution of BfuABC homologs in Hydrogenedentota. We speculate that the five sub-types of BfuABC might be acquired from Bacillota (synonym Firmicutes) through separate horizontal gene transfer events. These data shed light on the diversity and evolution of bifurcating [FeFe]-hydrogenases and provide insight into the strategy of Hydrogenedentota to adapt to survival in various habitats.IMPORTANCEThe phylum Hydrogenedentota is widely distributed in various environments. However, their physiology, ecology, and evolutionary history remain unknown, primarily due to the limited availability of the genomes and the lack of cultured representatives of the phylum. Our results have increased the knowledge of the genetic and metabolic diversity of these organisms and shed light on their diverse energy conservation strategies, especially those involving electron bifurcation with a non-canonical mechanism, which are likely responsible for their wide distribution. Besides, the organization and phylogenetic relationships of gene clusters coding for BfuABC in Hydrogenedentota provide valuable clues to the evolutionary history of group A3 electron bifurcating [FeFe]-hydrogenases.

Published

2024

7. The reductive half-reaction of two bifurcating electron-transferring flavoproteins Evidence for changes in flavin reduction potentials mediated by specific conformational changes

Author

Vigil, Wayne, Tran, Jessica, Niks, Dimitri, Schut, Gerrit J, Ge, Xiaoxuan, Adams, Michael WW, and Hille, Russ

Subjects

Biochemistry and Cell Biology, Biological Sciences, Electron Transport, Electron-Transferring Flavoproteins, Ferredoxins, Flavin-Adenine Dinucleotide, Flavins, NAD, Oxidation-Reduction, Oxidoreductases, Protein Structure, Tertiary, electron bifurcation, electron paramagnetic resonance, electron-transferring flavoprotein, rapid-reaction kinetics, Chemical Sciences, Medical and Health Sciences, Biochemistry & Molecular Biology, Biological sciences, Biomedical and clinical sciences, Chemical sciences

Abstract

The EtfAB components of two bifurcating flavoprotein systems, the crotonyl-CoA-dependent NADH:ferredoxin oxidoreductase from the bacterium Megasphaera elsdenii and the menaquinone-dependent NADH:ferredoxin oxidoreductase from the archaeon Pyrobaculum aerophilum, have been investigated. With both proteins, we find that removal of the electron-transferring flavin adenine dinucleotide (FAD) moiety from both proteins results in an uncrossing of the reduction potentials of the remaining bifurcating FAD; this significantly stabilizes the otherwise very unstable semiquinone state, which accumulates over the course of reductive titrations with sodium dithionite. Furthermore, reduction of both EtfABs depleted of their electron-transferring FAD by NADH was monophasic with a hyperbolic dependence of reaction rate on the concentration of NADH. On the other hand, NADH reduction of the replete proteins containing the electron-transferring FAD was multiphasic, consisting of a fast phase comparable to that seen with the depleted proteins followed by an intermediate phase that involves significant accumulation of FAD⋅-, again reflecting uncrossing of the half-potentials of the bifurcating FAD. This is then followed by a slow phase that represents the slow reduction of the electron-transferring FAD to FADH-, with reduction of the now fully reoxidized bifurcating FAD by a second equivalent of NADH. We suggest that the crossing and uncrossing of the reduction half-potentials of the bifurcating FAD is due to specific conformational changes that have been structurally characterized.

Published

2022

8. Spectral deconvolution of redox species in the crotonyl-CoA-dependent NADH:ferredoxin oxidoreductase from Megasphaera elsdenii. A flavin-dependent bifurcating enzyme

Author

Vigil, Wayne, Niks, Dimitri, Franz-Badur, Sophie, Chowdhury, Nilanjan, Buckel, Wolfgang, and Hille, Russ

Subjects

Biochemistry and Cell Biology, Biological Sciences, Acyl Coenzyme A, Bacterial Proteins, Megasphaera elsdenii, NAD, NADH, NADPH Oxidoreductases, Oxidation-Reduction, Electron bifurcation, Flavoprotein, Rapid-reaction kinetics, Electron paramagnetic resonance, Enzyme kinetics, Spectral deconvolution, Biochemistry & Molecular Biology

Abstract

We have undertaken a spectral deconvolution of the three FADs of EtfAB/bcd to the spectral changes seen in the course of reduction, including the spectrally distinct anionic and neutral semiquinone states of electron-transferring and bcd flavins. We also demonstrate that, unlike similar systems, no charge-transfer complex is observed on titration of the reduced M. elsdenii EtfAB with NAD+. Finally, and significantly, we find that removal of the et FAD from EtfAB results in an uncrossing of the half-potentials of the bifurcating FAD that remains in the protein, as reflected in the accumulation of substantial FAD•- in the course of reductive titrations of the depleted EtfAB with sodium dithionite.

Published

2021

9. The Kinetic Mechanism of Flavin-Based Electron Bifurcation (FBEB) in the Crotonyl-CoA-Dependent NADH:ferredoxin Oxidoreductase Complex From the Bacterium Megasphaera elsdenii

Author

Vigil Jr., Wayne Walter

Subjects

Biophysics, Electron bifurcation, Flavin-based electron bifurcation, Flavoprotein, Rapid-reaction kinetics

Abstract

Flavin-based electron bifurcation (FBEB) is an evolutionarily ancient mode of energy conservation found in a multitude of archaea and bacteria. FBEB allows these organisms to conserve energy by coupling the generation of low-potential reducing equivalents to the reduction of a high-potential electron acceptor/pathway. The thermodynamics of these separate pathways and the bifurcating cofactor (flavin adenine dinucleotide or FAD) have all been previously well-studied. However, in the context of FBEB the kinetics and nature of electron transfer (ET) in the system remain unknown.The present work serves to elucidate the discrete steps of ET involved in bifurcation of the crotonyl-CoA-dependent NADH:ferredoxin oxidoreductase complex from the bacterium Megasphaera elsdenii. The complex consists of two flavoenzymes, an electron transferring flavoprotein (EtfAB) and a butyryl-CoA dehydrogenase (bcd). The kinetics of the reductive and oxidative half-reactions of the individual proteins, the intact-complex, and the reduction of ferredoxin have been investigated. The various techniques that have been employed include: spectral deconvolution of the UV-vis spectra, kinetic steady-state assays, rapid-reaction kinetics, enzyme monitored turnover and electron paramagnetic resonance (EPR) spectroscopy. The work has revealed, despite the favorability of transfer of the low-potential electron into the high-potential pathway, this does not occur in an enzymatic time-frame. There is no “leakage” into the high-potential pathway that would “short-circuit” bifurcation. Spectral deconvolution and EPR analysis have confirmed not only the presence, but also the importance of, the flavin semiquinone in ET. Rapid-reaction kinetic studies of both reductive and oxidative half-reactions have revealed that after the initial reduction by NADH there are a series of slower ETs in the high-potential pathway that impede the immediate transfer of the low-potential electrons, thus preserving the fidelity of ferredoxin reduction. Enzyme-monitored turnover and steady-state studies have shown that the rate of ferredoxin reduction is significantly slower than the initial reduction of the complex. The experimental findings provide evidence supporting the rate of bifurcation being preserved through controlled, slow ET into the high-potential pathway, with the FAD constituting the first site in the high-potential pathway operating exclusively between the semiquinone and hydroquinone oxidation states.

Published

2024

10. Environmental Degradation of Cellulose Under Anaerobic Conditions

Author

Eleanor G. Schut

Subjects

cellulose, carbon cycle, anaerobic, hydrogen, ethanol, acetate, electron bifurcation, Biotechnology, TP248.13-248.65

Abstract

Cellulose is a primary structural component of plants and is one of the most abundant polymers on the Earth. Degradation of this recalcitrant component of plant biomass is an important process in the global carbon cycle and can potentially provide feedstock for biofuels. Fungi and bacteria are the primary organisms able to breakdown biomass-derived cellulose. Anaerobic bacteria, present in cellulose degrading ecosystems, such as compost piles, soils rich in organic matter, aquatic sediments, and digestive systems of herbivores, have developed efficient pathways to maximize metabolic energy from biomass degradation. In the absence of terminal electron acceptors, such as oxygen, hydrogen-producing pathways are common methods of electron carrier recycling. Electron bifurcating systems linked to hydrogen metabolism play an important role in anaerobic metabolism. In this study, samples from environmental cellulose-degrading microbial communities were collected, and the metabolic products produced during anaerobic cellulose degradation were examined. Samples from different environments produced different fermentation products from cellulose, suggesting flexibility in the fermentative degradation pathways. The most abundant products observed included hydrogen, acetate, propionate, butyrate, ethanol, and methane.

Published

2022

11. Looking for the mechanism of arsenate respiration of Fusibacter sp. strain 3D3, independent of ArrAB

Author

Mauricio Acosta-Grinok, Susana Vázquez, Nicolás Guiliani, Sabrina Marín, and Cecilia Demergasso

Subjects

Fusibacter, arsenic respiration, electron bifurcation, Rnf complex, ferredoxin, thioredoxin, Microbiology, QR1-502

Abstract

The literature has reported the isolation of arsenate-dependent growing microorganisms which lack a canonical homolog for respiratory arsenate reductase, ArrAB. We recently isolated an arsenate-dependent growing bacterium from volcanic arsenic-bearing environments in Northern Chile, Fusibacter sp. strain 3D3 (Fas) and studied the arsenic metabolism in this Gram-positive isolate. Features of Fas deduced from genome analysis and comparative analysis with other arsenate-reducing microorganisms revealed the lack of ArrAB coding genes and the occurrence of two arsC genes encoding for putative cytoplasmic arsenate reductases named ArsC-1 and ArsC-2. Interestingly, ArsC-1 and ArsC-2 belong to the thioredoxin-coupled family (because of the redox-active disulfide protein used as reductant), but they conferred differential arsenate resistance to the E. coli WC3110 ΔarsC strain. PCR experiments confirmed the absence of arrAB genes and results obtained using uncouplers revealed that Fas growth is linked to the proton gradient. In addition, Fas harbors ferredoxin-NAD+ oxidoreductase (Rnf) and electron transfer flavoprotein (etf) coding genes. These are key molecular markers of a recently discovered flavin-based electron bifurcation mechanism involved in energy conservation, mainly in anaerobic metabolisms regulated by the cellular redox state and mostly associated with cytoplasmic enzyme complexes. At least three electron-bifurcating flavoenzyme complexes were evidenced in Fas, some of them shared in conserved genomic regions by other members of the Fusibacter genus. These physiological and genomic findings permit us to hypothesize the existence of an uncharacterized arsenate-dependent growth metabolism regulated by the cellular redox state in the Fusibacter genus.

Published

2022

12. Site-Differentiated Iron–Sulfur Cluster Ligation Affects Flavin-Based Electron Bifurcation Activity.

Author

Wise, Courtney E., Ledinina, Anastasia E., and Lubner, Carolyn E.

Subjects

NICOTINAMIDE adenine dinucleotide phosphate, BIOENERGETICS, OXIDATION-reduction reaction, ELECTRON distribution, ELECTRONS, CHARGE exchange, COMPLEX ions

Abstract

Electron bifurcation is an elegant mechanism of biological energy conversion that effectively couples three different physiologically relevant substrates. As such, enzymes that perform this function often play critical roles in modulating cellular redox metabolism. One such enzyme is NADH-dependent reduced-ferredoxin: NADP+ oxidoreductase (NfnSL), which couples the thermodynamically favorable reduction of NAD+ to drive the unfavorable reduction of ferredoxin from NADPH. The interaction of NfnSL with its substrates is constrained to strict stoichiometric conditions, which ensures minimal energy losses from non-productive intramolecular electron transfer reactions. However, the determinants for this are not well understood. One curious feature of NfnSL is that both initial acceptors of bifurcated electrons are unique iron–sulfur (FeS) clusters containing one non-cysteinyl ligand each. The biochemical impact and mechanistic roles of site-differentiated FeS ligands are enigmatic, despite their incidence in many redox active enzymes. Herein, we describe the biochemical study of wild-type NfnSL and a variant in which one of the site-differentiated ligands has been replaced with a cysteine. Results of dye-based steady-state kinetics experiments, substrate-binding measurements, biochemical activity assays, and assessments of electron distribution across the enzyme indicate that this site-differentiated ligand in NfnSL plays a role in maintaining fidelity of the coordinated reactions performed by the two electron transfer pathways. Given the commonality of these cofactors, our findings have broad implications beyond electron bifurcation and mechanistic biochemistry and may inform on means of modulating the redox balance of the cell for targeted metabolic engineering approaches. [ABSTRACT FROM AUTHOR]

Published

2022

13. Customized exogenous ferredoxin functions as an efficient electron carrier

Author

Zhan Song, Cancan Wei, Chao Li, Xin Gao, Shuhong Mao, Fuping Lu, and Hui-Min Qin

Subjects

Ferredoxin, Electron transfer, Electron bifurcation, [2Fe–2S] clusters, Technology, Chemical technology, TP1-1185, Biotechnology, TP248.13-248.65

Abstract

Abstract Ferredoxin (Fdx) is regarded as the main electron carrier in biological electron transfer and acts as an electron donor in metabolic pathways of many organisms. Here, we screened a self-sufficient P450-derived reductase PRF with promising production yield of 9OHAD (9α-hydroxy4-androstene-3,17-dione) from AD, and further proved the importance of [2Fe–2S] clusters of ferredoxin-oxidoreductase in transferring electrons in steroidal conversion. The results of truncated Fdx domain in all oxidoreductases and mutagenesis data elucidated the indispensable role of [2Fe–2S] clusters in the electron transfer process. By adding the independent plant-type Fdx to the reaction system, the AD (4-androstene-3,17-dione) conversion rate have been significantly improved. A novel efficient electron transfer pathway of PRF + Fdx + KshA (KshA, Rieske-type oxygenase of 3-ketosteroid-9-hydroxylase) in the reaction system rather than KshAB complex system was proposed based on analysis of protein–protein interactions and redox potential measurement. Adding free Fdx created a new conduit for electrons to travel from reductase to oxygenase. This electron transfer pathway provides new insight for the development of efficient exogenous Fdx as an electron carrier. Graphical Abstract

Published

2021

14. Mechanistic insights into energy conservation by flavin-based electron bifurcation

Author

Peters, John [Montana State Univ., Bozeman, MT (United States); Washington State Univ., Pullman, WA (United States)]

Published

2017

15. Latest Knowledge of Electromicrobiology

Author

Wakai, Satoshi, Ishii, Masaharu, editor, and Wakai, Satoshi, editor

Published

2020

16. Importance of Electron Flow in Microbiological Metabolism

Author

Kameya, Masafumi, Arai, Hiroyuki, Ishii, Masaharu, Ishii, Masaharu, editor, and Wakai, Satoshi, editor

Published

2020

17. Structural insight on the mechanism of an electron-bifurcating [FeFe] hydrogenase

Author

Chris Furlan, Nipa Chongdar, Pooja Gupta, Wolfgang Lubitz, Hideaki Ogata, James N Blaza, and James A Birrell

Subjects

hydrogenase, electron bifurcation, electron cryomicroscopy, enzyme mechanism, Medicine, Science, Biology (General), QH301-705.5

Abstract

Electron bifurcation is a fundamental energy conservation mechanism in nature in which two electrons from an intermediate-potential electron donor are split so that one is sent along a high-potential pathway to a high-potential acceptor and the other is sent along a low-potential pathway to a low-potential acceptor. This process allows endergonic reactions to be driven by exergonic ones and is an alternative, less recognized, mechanism of energy coupling to the well-known chemiosmotic principle. The electron-bifurcating [FeFe] hydrogenase from Thermotoga maritima (HydABC) requires both NADH and ferredoxin to reduce protons generating hydrogen. The mechanism of electron bifurcation in HydABC remains enigmatic in spite of intense research efforts over the last few years. Structural information may provide the basis for a better understanding of spectroscopic and functional information. Here, we present a 2.3 Å electron cryo-microscopy structure of HydABC. The structure shows a heterododecamer composed of two independent ‘halves’ each made of two strongly interacting HydABC heterotrimers connected via a [4Fe–4S] cluster. A central electron transfer pathway connects the active sites for NADH oxidation and for proton reduction. We identified two conformations of a flexible iron–sulfur cluster domain: a ‘closed bridge’ and an ‘open bridge’ conformation, where a Zn2+ site may act as a ‘hinge’ allowing domain movement. Based on these structural revelations, we propose a possible mechanism of electron bifurcation in HydABC where the flavin mononucleotide serves a dual role as both the electron bifurcation center and as the NAD+ reduction/NADH oxidation site.

Published

2022

18. Genome-Scale Mining of Acetogens of the Genus Clostridium Unveils Distinctive Traits in [FeFe]- and [NiFe]-Hydrogenase Content and Maturation

Author

Pier Francesco Di Leonardo, Giacomo Antonicelli, Valeria Agostino, and Angela Re

Subjects

Clostridium, acetogen, cofactor, electron bifurcation, hydrogenase, Microbiology, QR1-502

Abstract

ABSTRACT Knowledge of the organizational and functional properties of hydrogen metabolism is pivotal to the construction of a framework supportive of a hydrogen-fueled low-carbon economy. Hydrogen metabolism relies on the mechanism of action of hydrogenases. In this study, we investigated the genomes of several industrially relevant acetogens of the genus Clostridium (C. autoethanogenum, C. ljungdahlii, C. carboxidivorans, C. drakei, C. scatologenes, C. coskatii, C. ragsdalei, C. sp. AWRP) to systematically identify their intriguingly diversified hydrogenases’ repertoire. An entirely computational annotation pipeline unveiled common and strain-specific traits in the functional content of [NiFe]- and [FeFe]-hydrogenases. Hydrogenases were identified and categorized into functionally distinct classes by the combination of sequence homology, with respect to a database of curated nonredundant hydrogenases, with the analysis of sequence patterns characteristic of the mode of action of [FeFe]- and [NiFe]-hydrogenases. The inspection of the genes in the neighborhood of the catalytic subunits unveiled a wide agreement between their genomic arrangement and the gene organization templates previously developed for the predicted hydrogenase classes. Subunits’ characterization of the identified hydrogenases allowed us to glean some insights on the redox cofactor-binding determinants in the diaphorase subunits of the electron-bifurcating [FeFe]-hydrogenases. Finally, the reliability of the inferred hydrogenases was corroborated by the punctual analysis of the maturation proteins necessary for the biosynthesis of [NiFe]- and [FeFe]-hydrogenases. IMPORTANCE Mastering hydrogen metabolism can support a sustainable carbon-neutral economy. Of the many microorganisms metabolizing hydrogen, acetogens of the genus Clostridium are appealing, with some of them already in usage as industrial workhorses. Having provided detailed information on the hydrogenase content of an unprecedented number of clostridial acetogens at the gene level, our study represents a valuable knowledge base to deepen our understanding of hydrogenases’ functional specificity and/or redundancy and to develop a large array of biotechnological processes. We also believe our study could serve as a basis for future strain-engineering approaches, acting at the hydrogenases’ level or at the level of their maturation proteins. On the other side, the wealth of functional elements discussed in relation to the identified hydrogenases is worthy of further investigation by biochemical and structural studies to ultimately lead to the usage of these enzymes as valuable catalysts.

Published

2022

19. Structure-based electron-confurcation mechanism of the Ldh-EtfAB complex

Author

Kanwal Kayastha, Alexander Katsyv, Christina Himmrich, Sonja Welsch, Jan M Schuller, Ulrich Ermler, and Volker Müller

Subjects

electron bifurcation, bioenergetics, flavin, lactate dehydrogenase, electron-transferring flavoprotein, cryo-EM structure, Medicine, Science, Biology (General), QH301-705.5

Abstract

Lactate oxidation with NAD+ as electron acceptor is a highly endergonic reaction. Some anaerobic bacteria overcome the energetic hurdle by flavin-based electron bifurcation/confurcation (FBEB/FBEC) using a lactate dehydrogenase (Ldh) in concert with the electron-transferring proteins EtfA and EtfB. The electron cryo-microscopically characterized (Ldh-EtfAB)2 complex of Acetobacterium woodii at 2.43 Å resolution consists of a mobile EtfAB shuttle domain located between the rigid central Ldh and the peripheral EtfAB base units. The FADs of Ldh and the EtfAB shuttle domain contact each other thereby forming the D (dehydrogenation-connected) state. The intermediary Glu37 and Glu139 may harmonize the redox potentials between the FADs and the pyruvate/lactate pair crucial for FBEC. By integrating Alphafold2 calculations a plausible novel B (bifurcation-connected) state was obtained allowing electron transfer between the EtfAB base and shuttle FADs. Kinetic analysis of enzyme variants suggests a correlation between NAD+ binding site and D-to-B-state transition implicating a 75° rotation of the EtfAB shuttle domain. The FBEC inactivity when truncating the ferredoxin domain of EtfA substantiates its role as redox relay. Lactate oxidation in Ldh is assisted by the catalytic base His423 and a metal center. On this basis, a comprehensive catalytic mechanism of the FBEC process was proposed.

Published

2022

20. Unification of [FeFe]-hydrogenases into three structural and functional groups

Author

Boyd, Eric [Montana State Univ., Bozeman, MT (United States)]

Published

2016

21. Molecular mechanisms of electron transfer employed by native proteins and biological-inorganic hybrid systems

Author

Michael Lienemann

Subjects

Electron transfer, Electron bifurcation, Redox potential, Redox protein, Enzymatic electrosynthesis, Protein engineering, Biotechnology, TP248.13-248.65

Abstract

Recent advances in enzymatic electrosynthesis of desired chemicals in biological-inorganic hybrid systems has generated interest because it can use renewable energy inputs and employs highly specific catalysts that are active at ambient conditions. However, the development of such innovative processes is currently limited by a deficient understanding of the molecular mechanisms involved in electrode-based electron transfer and biocatalysis. Mechanistic studies of non-electrosynthetic electron transferring proteins have provided a fundamental understanding of the processes that take place during enzymatic electrosynthesis. Thus, they may help explain how redox proteins stringently control the reduction potential of the transferred electron and efficiently transfer it to a specific electron acceptor. The redox sites at which electron donor oxidation and electron acceptor reduction take place are typically located in distant regions of the redox protein complex and are electrically connected by an array of closely spaced cofactors. These groups function as electron relay centers and are shielded from the surrounding environment by the electrically insulating apoporotein. In this matrix, electrons travel via electron tunneling, i.e. hopping between neighboring cofactors, over impressive distances of upto several nanometers and, as in the case of the Shewanella oneidensis Mtr electron conduit, traverse the bacterial cell wall to extracellular electron acceptors such as solid ferrihydrite. Here, the biochemical strategies of protein-based electron transfer are presented in order to provide a basis for future studies on the basis of which a more comprehensive understanding of the structural biology of enzymatic electrosynthesis may be attained.

Published

2021

22. The electron‐bifurcating FeFe‐hydrogenase Hnd is involved in ethanol metabolism in Desulfovibrio fructosovorans grown on pyruvate.

Author

Payne, Natalie, Kpebe, Arlette, Guendon, Chloé, Baffert, Carole, Ros, Julien, Lebrun, Régine, Denis, Yann, Shintu, Laetitia, and Brugna, Myriam

Subjects

*ALDEHYDE dehydrogenase, *ALCOHOL dehydrogenase, *PYRUVATES, *HYDROGENASE, *NAD (Coenzyme), *SULFATE-reducing bacteria, *OXIDOREDUCTASES

Abstract

Desulfovibrio fructosovorans, a sulfate‐reducing bacterium, possesses six gene clusters encoding six hydrogenases catalyzing the reversible oxidation of H2 into protons and electrons. Among them, Hnd is an electron‐bifurcating hydrogenase, coupling the exergonic reduction of NAD+ to the endergonic reduction of a ferredoxin with electrons derived from H2. It was previously hypothesized that its biological function involves the production of NADPH necessary for biosynthetic purposes. However, it was subsequently demonstrated that Hnd is instead a NAD+‐reducing enzyme, thus its specific function has yet to be established. To understand the physiological role of Hnd in D. fructosovorans, we compared the hnd deletion mutant with the wild‐type strain grown on pyruvate. Growth, metabolite production and consumption, and gene expression were compared under three different growth conditions. Our results indicate that hnd is strongly regulated at the transcriptional level and that its deletion has a drastic effect on the expression of genes for two enzymes, an aldehyde ferredoxin oxidoreductase and an alcohol dehydrogenase. We demonstrated here that Hnd is involved in ethanol metabolism when bacteria grow fermentatively and proposed that Hnd might oxidize part of the H2 produced during fermentation generating both NADH and reduced ferredoxin for ethanol production via its electron bifurcation mechanism. [ABSTRACT FROM AUTHOR]

Published

2022

23. An uncharacteristically low-potential flavin governs the energy landscape of electron bifurcation.

Author

Wise, Courtney E., Ledinina, Anastasia E., Mulder, David W., Chou, Katherine J., Peters, John W., King, Paul W., and Lubner, Carolyn E.

Subjects

*OXIDATION-reduction reaction, *EXERGONIC reactions, *ELECTRONS

Abstract

Electron bifurcation, an energy-conserving process utilized extensively throughout all domains of life, represents an elegant means of generating high-energy products from substrates with less reducing potential. The coordinated coupling of exergonic and endergonic reactions has been shown to operate over an electrochemical potential of ∼1.3 V through the activity of a unique flavin cofactor in the enzyme NADH-dependent ferredoxin-NADP+ oxidoreductase I. The inferred energy landscape has features unprecedented in biochemistry and presents novel energetic challenges, the most intriguing being a large thermodynamically uphill step for the first electron transfer of the bifurcation reaction. However, ambiguities in the energy landscape at the bifurcating site deriving from overlapping flavin spectral signatures have impeded a comprehensive understanding of the specific mechanistic contributions afforded by thermodynamic and kinetic factors. Here, we elucidate an uncharacteristically low two-electron potential of the bifurcating flavin, resolving the energetic challenge of the first bifurcation event. [ABSTRACT FROM AUTHOR]

Published

2022

24. Facilitating Intracellular Electron Bifurcation by Mediating Flavin-Based Extracellular and Transmembrane Electron Transfer: A Novel Role of Pyrogenic Carbon in Dark Fermentation for Hydrogen Production.

Author

Tian W, Tang Y, Ducey TF, Khan E, and Tsang DCW

Subjects

Electron Transport, Carbon metabolism, Flavins metabolism, Electrons, Hydrogen metabolism, Fermentation

Abstract

Pyrogenic carbon is considered an enhancer to H 2 -yielding dark fermentation (DF), but little is known about how it regulates extracellular electron transfer (EET) and influences transmembrane respiratory chains and intracellular metabolisms. This study addressed these knowledge gaps and demonstrated that wood waste pyrogenic carbon (biochar) could significantly improve the DF performance; e.g., addition of pyrogenic carbon produced by pyrolysis at 800 °C (PC800) increased H 2 yield by 369.7%. Biochemical quantification, electrochemical analysis, and electron respiratory chain inhibition tests revealed that PC800 promoted the extracellular flavin-based electron transfer process and further activated the acceleration of the transmembrane electron transfer. Comparative metagenome/metatranscriptome analyses indicated that the flavin-containing Rnf complex was the potential transmembrane respiratory enzyme associated with PC800-mediated EET. Based on NADH/NAD + circulation, the promoted Rnf complex could stimulate the functions of the electron bifurcating Etf/Bcd complex and startup of glycolysis. The promoted Etf/Bcd could further contribute to balance the NADH/NAD + level for glycolytic reactions and meanwhile provide reduced ferredoxin for group A1 [FeFe]-hydrogenases. This proton-energy-linked mechanism could achieve coupling production of ATP and H 2 . This study verified the important roles of pyrogenic carbon in mediating EET and transmembrane/intracellular pathways and revealed the crucial roles of electron bifurcation in DF for hydrogen production.

Published

2024

25. Designer Flavoproteins for the Elucidation of the Fundamental Mechanism of Potential Inversion

Author

Lerner, Mary

Subjects

Biochemistry, Electron Bifurcation, Flavin, Potential Inversion

Abstract

Flavins are arguably one of the most versatile cofactors in biology, resulting from their ability to facilitate both 1e- and 2e- transfer reactions, as well as their widely-varying reduction potentials that can be tuned by the local protein environment. Flavins have three redox states: oxidized (OX), 1e--reduced semiquinone (SQ), and 2e--reduced hydroquinone (HQ). Their reactivity in redox processes is determined by E’OX/SQ and E’SQ/HQ, which is affected by electrostatic and H-bonding interactions in the flavin binding site. Free in solution, flavins exhibit “inverted potentials”, where the 1e– reduced state is more unstable than the fully-reduced state. The flavin binding site of flavodoxins, a class of electron transfer flavoproteins, alters the 1e- reduction potentials such that they become “normally” ordered, stabilizing E’OX/SQ relative to E’SQ/HQ. In other cases, the protein environment can increase potential inversion. A dramatic example can be found in flavin-based electron bifurcation (FBEB), which utilizes significant potential separation (ΔE) to conserve energy from exergonic redox reactions by concomitantly driving endergonic ET. The properties of the flavin binding site that induce this inversion are unknown, largely due to the limited mutagenesis space in authentic EB-ases and lack of physical methods for measuring highly-inverted 1e- reduction potentials. Since potential separation is fundamental to the mechanism of energy conservation in FBEB, understanding its cause is both interesting from a basic science perspective, and valuable to the field of electrocatalysis. To move towards this goal, it is essential to develop minimalist models for potential inversion, since the study of this phenomenon in native EB-ases is nontrivial. We have demonstrated that iLOV can be used as a model flavoprotein to evidence the effects of near-flavin mutations on redox behavior and potential inversion, substituting Lys to illustrate the influence of an ionizable and H-bonding functional group on semiquinone stability. We have designed expression and reconstitution methods to recombinantly produce iLOV WT, Q104K, and Q104A in high holoprotein yield. The 2e- reduction potential of iLOV WT and Q104K was measured by protein film voltammetry, and equilibration studies with a redox dye were conducted to confirm that protein-film electrochemistry corresponded to bulk properties. The semiquinone protonation state was characterized by EPR and UV-vis. Using spectral data to infer concentrations of the three flavin redox states at electrochemical equilibrium, ΔE was calculated for iLOV WT, iLOV Q104K and iLOV Q104A. The results suggest that iLOV WT has the most inverted 1e- potentials, followed by Q104A, with Q104K having the least potential separation. The substitution of Ala at the N5 position appeared to stabilize the SQ, although this is likely due to exposure to ambient light. The addition of Lys at N5 appears to influence the thermodynamic properties of the flavin such that E’OX/SQ, and seemingly E’SQ/HQ, is more positive. This can be rationalized by its relative acidity and closer pKa matching between the flavin and Lys, as compared to Gln in iLOV WT. Our discoveries on the crucial elements of potential inversion in flavin redox chemistry may shed light on the mechanisms of potential tuning in natural systems, particularly extreme potential inversion of EB-ases.

Published

2022

26. Energy Conservation in Fermentations of Anaerobic Bacteria

Author

Wolfgang Buckel

Subjects

ΔμNa+, decarboxylation, ferredoxin, Rnf, electron bifurcation, coenzyme B12, Microbiology, QR1-502

Abstract

Anaerobic bacteria ferment carbohydrates and amino acids to obtain energy for growth. Due to the absence of oxygen and other inorganic electron acceptors, the substrate of a fermentation has to serve as electron donor as well as acceptor, which results in low free energies as compared to that of aerobic oxidations. Until about 10 years ago, anaerobes were thought to exclusively use substrate level phosphorylation (SLP), by which only part of the available energy could be conserved. Therefore, anaerobes were regarded as unproductive and inefficient energy conservers. The discovery of electrochemical Na+ gradients generated by biotin-dependent decarboxylations or by reduction of NAD+ with ferredoxin changed this view. Reduced ferredoxin is provided by oxidative decarboxylation of 2-oxoacids and the recently discovered flavin based electron bifurcation (FBEB). In this review, the two different fermentation pathways of glutamate to ammonia, CO2, acetate, butyrate and H2 via 3-methylaspartate or via 2-hydroxyglutarate by members of the Firmicutes are discussed as prototypical examples in which all processes characteristic for fermentations occur. Though the fermentations proceed on two entirely different pathways, the maximum theoretical amount of ATP is conserved in each pathway. The occurrence of the 3-methylaspartate pathway in clostridia from soil and the 2-hydroxyglutarate pathway in the human microbiome of the large intestine is traced back to the oxygen-sensitivity of the radical enzymes. The coenzyme B12-dependent glutamate mutase in the 3-methylaspartate pathway tolerates oxygen, whereas 2-hydroxyglutaryl-CoA dehydratase is extremely oxygen-sensitive and can only survive in the gut, where the combustion of butyrate produced by the microbiome consumes the oxygen and provides a strict anaerobic environment. Examples of coenzyme B12-dependent eliminases are given, which in the gut are replaced by simpler extremely oxygen sensitive glycyl radical enzymes.

Published

2021

27. Customized exogenous ferredoxin functions as an efficient electron carrier.

Author

Song, Zhan, Wei, Cancan, Li, Chao, Gao, Xin, Mao, Shuhong, Lu, Fuping, and Qin, Hui-Min

Subjects

CHARGE exchange, ELECTRONS, ELECTRON donors, PROTEIN-protein interactions, REDUCTION potential, OXIDOREDUCTASES

Abstract

Ferredoxin (Fdx) is regarded as the main electron carrier in biological electron transfer and acts as an electron donor in metabolic pathways of many organisms. Here, we screened a self-sufficient P450-derived reductase PRF with promising production yield of 9OHAD (9α-hydroxy4-androstene-3,17-dione) from AD, and further proved the importance of [2Fe–2S] clusters of ferredoxin-oxidoreductase in transferring electrons in steroidal conversion. The results of truncated Fdx domain in all oxidoreductases and mutagenesis data elucidated the indispensable role of [2Fe–2S] clusters in the electron transfer process. By adding the independent plant-type Fdx to the reaction system, the AD (4-androstene-3,17-dione) conversion rate have been significantly improved. A novel efficient electron transfer pathway of PRF + Fdx + KshA (KshA, Rieske-type oxygenase of 3-ketosteroid-9-hydroxylase) in the reaction system rather than KshAB complex system was proposed based on analysis of protein–protein interactions and redox potential measurement. Adding free Fdx created a new conduit for electrons to travel from reductase to oxygenase. This electron transfer pathway provides new insight for the development of efficient exogenous Fdx as an electron carrier. [ABSTRACT FROM AUTHOR]

Published

2021

28. Energy Conservation in Fermentations of Anaerobic Bacteria.

Author

Buckel, Wolfgang

Subjects

BUTYRATES, ANAEROBIC bacteria, ENERGY conservation, FERMENTATION, ELECTRON donors, LARGE intestine, AMMONIA

Abstract

Anaerobic bacteria ferment carbohydrates and amino acids to obtain energy for growth. Due to the absence of oxygen and other inorganic electron acceptors, the substrate of a fermentation has to serve as electron donor as well as acceptor, which results in low free energies as compared to that of aerobic oxidations. Until about 10 years ago, anaerobes were thought to exclusively use substrate level phosphorylation (SLP), by which only part of the available energy could be conserved. Therefore, anaerobes were regarded as unproductive and inefficient energy conservers. The discovery of electrochemical Na+ gradients generated by biotin-dependent decarboxylations or by reduction of NAD+ with ferredoxin changed this view. Reduced ferredoxin is provided by oxidative decarboxylation of 2-oxoacids and the recently discovered flavin based electron bifurcation (FBEB). In this review, the two different fermentation pathways of glutamate to ammonia, CO2, acetate, butyrate and H2 via 3-methylaspartate or via 2-hydroxyglutarate by members of the Firmicutes are discussed as prototypical examples in which all processes characteristic for fermentations occur. Though the fermentations proceed on two entirely different pathways, the maximum theoretical amount of ATP is conserved in each pathway. The occurrence of the 3-methylaspartate pathway in clostridia from soil and the 2-hydroxyglutarate pathway in the human microbiome of the large intestine is traced back to the oxygen-sensitivity of the radical enzymes. The coenzyme B12-dependent glutamate mutase in the 3-methylaspartate pathway tolerates oxygen, whereas 2-hydroxyglutaryl-CoA dehydratase is extremely oxygen-sensitive and can only survive in the gut, where the combustion of butyrate produced by the microbiome consumes the oxygen and provides a strict anaerobic environment. Examples of coenzyme B12-dependent eliminases are given, which in the gut are replaced by simpler extremely oxygen sensitive glycyl radical enzymes. [ABSTRACT FROM AUTHOR]

Published

2021

29. The genetic basis of energy conservation in the sulfate-reducing bacterium Desulfovibrio alaskensis G20

Author

Arkin, Adam [Lawrence Berkeley National Lab. (LBNL), Berkeley, CA (United States); Univ. of California, Berkeley, CA (United States)]

Published

2014

30. Site-Differentiated Iron–Sulfur Cluster Ligation Affects Flavin-Based Electron Bifurcation Activity

Author

Courtney E. Wise, Anastasia E. Ledinina, and Carolyn E. Lubner

Subjects

electron bifurcation, biochemistry, iron–sulfur cluster, flavoenzyme, energy conservation, bioenergetics, Microbiology, QR1-502

Abstract

Electron bifurcation is an elegant mechanism of biological energy conversion that effectively couples three different physiologically relevant substrates. As such, enzymes that perform this function often play critical roles in modulating cellular redox metabolism. One such enzyme is NADH-dependent reduced-ferredoxin: NADP+ oxidoreductase (NfnSL), which couples the thermodynamically favorable reduction of NAD+ to drive the unfavorable reduction of ferredoxin from NADPH. The interaction of NfnSL with its substrates is constrained to strict stoichiometric conditions, which ensures minimal energy losses from non-productive intramolecular electron transfer reactions. However, the determinants for this are not well understood. One curious feature of NfnSL is that both initial acceptors of bifurcated electrons are unique iron–sulfur (FeS) clusters containing one non-cysteinyl ligand each. The biochemical impact and mechanistic roles of site-differentiated FeS ligands are enigmatic, despite their incidence in many redox active enzymes. Herein, we describe the biochemical study of wild-type NfnSL and a variant in which one of the site-differentiated ligands has been replaced with a cysteine. Results of dye-based steady-state kinetics experiments, substrate-binding measurements, biochemical activity assays, and assessments of electron distribution across the enzyme indicate that this site-differentiated ligand in NfnSL plays a role in maintaining fidelity of the coordinated reactions performed by the two electron transfer pathways. Given the commonality of these cofactors, our findings have broad implications beyond electron bifurcation and mechanistic biochemistry and may inform on means of modulating the redox balance of the cell for targeted metabolic engineering approaches.

Published

2022

31. The Biochemistry and Physiology of Respiratory-Driven Reversed Methanogenesis

Author

Nazem-Bokaee, Hadi, Yan, Zhen, Maranas, Costas D., Ferry, James G., Kalyuzhnaya, Marina G., editor, and Xing, Xin-Hui, editor

Published

2018

32. The genetic basis of energy conservation in the sulfate-reducing bacterium Desulfovibrio alaskensis G20

Author

Price, Morgan N, Ray, Jayashree, Wetmore, Kelly M, Kuehl, Jennifer V, Bauer, Stefan, Deutschbauer, Adam M, and Arkin, Adam P

Subjects

Genetics, energy metabolism, sulfate reducing bacteria, membrane complexes, Desulfovibrio, electron bifurcation, Environmental Science and Management, Soil Sciences, Microbiology

Abstract

Sulfate-reducing bacteria play major roles in the global carbon and sulfur cycles, but it remains unclear how reducing sulfate yields energy. To determine the genetic basis of energy conservation, we measured the fitness of thousands of pooled mutants of Desulfovibrio alaskensis G20 during growth in 12 different combinations of electron donors and acceptors. We show that ion pumping by the ferredoxin:NADH oxidoreductase Rnf is required whenever substrate-level phosphorylation is not possible. The uncharacterized complex Hdr/flox-1 (Dde_1207:13) is sometimes important alongside Rnf and may perform an electron bifurcation to generate more reduced ferredoxin from NADH to allow further ion pumping. Similarly, during the oxidation of malate or fumarate, the electron-bifurcating transhydrogenase NfnAB-2 (Dde_1250:1) is important and may generate reduced ferredoxin to allow additional ion pumping by Rnf. During formate oxidation, the periplasmic [NiFeSe] hydrogenase HysAB is required, which suggests that hydrogen forms in the periplasm, diffuses to the cytoplasm, and is used to reduce ferredoxin, thus providing a substrate for Rnf. During hydrogen utilization, the transmembrane electron transport complex Tmc is important and may move electrons from the periplasm into the cytoplasmic sulfite reduction pathway. Finally, mutants of many other putative electron carriers have no clear phenotype, which suggests that they are not important under our growth conditions, although we cannot rule out genetic redundancy.

Published

2014

33. Acetogens: Biochemistry, Bioenergetics, Genetics, and Biotechnological Potential.

Author

Debabov, V. G.

Subjects

*BUTYRIC acid, *RENEWABLE energy sources, *BIOENERGETICS, *BIOCHEMISTRY, *GENETICS, *GRAM-positive bacteria

Abstract

The review discusses the present-day data on the biochemistry, bioenergetics, and genetics of acetogens, as well as their biotechnological potential. Acetogens are anaerobic gram-positive bacteria capable of growth on gaseous substrates: CO2, CO, H2. These bacteria have a characteristic biochemical pathway of CO2 reduction to acetyl-CoA, termed the reductive acetyl-CoA pathway or the Wood‒Ljungdahl pathway. This is the only pathway of CO2 fixation coupled to energy storage. Due to their efficient non-photosynthetic CO2 fixation, acetogens may be used for production of chemicals and biofuel in the expected economy based on renewable energy and resources. The shortcomings of acetogens growing on gaseous substrates are low energy provision and a narrow spectrum of terminal metabolites, primarily acetic acid and ethanol with low amounts of butanol and butyric acid. Acetogens are capable of heterotrophic growth on such substrates as sugars, lactate, or alcohols. Mixotrophy, i.e., simultaneous utilization of different substrates by acetogens, is a promising approach to increasing the energy provision. Application of the methods of metabolic engineering is required both for successful coupling of different metabolic pathways and for broadening the range of synthesized products. Genetic tools for the transformation of genomes of acetogens have been considerably improved in recent years. [ABSTRACT FROM AUTHOR]

Published

2021

34. Structural and spectroscopic characterization of a HdrA‐like subunit from Hyphomicrobium denitrificans.

Author

Ernst, Corvin, Kayastha, Kanwal, Koch, Tobias, Venceslau, Sofia S., Pereira, Inês A. C., Demmer, Ulrike, Ermler, Ulrich, and Dahl, Christiane

Subjects

*ELECTRON paramagnetic resonance spectroscopy, *FLAVIN adenine dinucleotide, *ELECTRON paramagnetic resonance, *NAD (Coenzyme), *MULTIENZYME complexes, *RECOMBINANT proteins, *REDUCTION potential

Abstract

Many bacteria and archaea employ a novel pathway of sulfur oxidation involving an enzyme complex that is related to the heterodisulfide reductase (Hdr or HdrABC) of methanogens. As a first step in the biochemical characterization of Hdr‐like proteins from sulfur oxidizers (sHdr), we structurally analyzed the recombinant sHdrA protein from the Alphaproteobacterium Hyphomicrobium denitrificans at 1.4 Å resolution. The sHdrA core structure is similar to that of methanogenic HdrA (mHdrA) which binds the electron‐bifurcating flavin adenine dinucleotide (FAD), the heart of the HdrABC‐[NiFe]‐hydrogenase catalyzed reaction. Each sHdrA homodimer carries two FADs and two [4Fe–4S] clusters being linked by electron conductivity. Redox titrations monitored by electron paramagnetic resonance and visible spectroscopy revealed a redox potential between −203 and −188 mV for the [4Fe–4S] center. The potentials for the FADH•/FADH− and FAD/FADH• pairs reside between −174 and −156 mV and between −81 and −19 mV, respectively. The resulting stable semiquinone FADH• species already detectable in the visible and electron paramagnetic resonance spectra of the as‐isolated state of sHdrA is incompatible with basic principles of flavin‐based electron bifurcation such that the sHdr complex does not apply this new mode of energy coupling. The inverted one‐electron FAD redox potentials of sHdr and mHdr are clearly reflected in the different FAD‐polypeptide interactions. According to this finding and the assumption that the sHdr complex forms an asymmetric HdrAA′B1C1B2C2 hexamer, we tentatively propose a mechanism that links protein‐bound sulfane oxidation to sulfite on HdrB1 with NAD+ reduction via lipoamide disulfide reduction on HdrB2. The FAD of HdrA thereby serves as an electron storage unit. Database: Structural data are available in PDB database under the accession number 6TJR. [ABSTRACT FROM AUTHOR]

Published

2021

35. Electrochemical Characterization of a Complex FeFe Hydrogenase, the Electron-Bifurcating Hnd From Desulfovibrio fructosovorans

Author

Aurore Jacq-Bailly, Martino Benvenuti, Natalie Payne, Arlette Kpebe, Christina Felbek, Vincent Fourmond, Christophe Léger, Myriam Brugna, and Carole Baffert

Subjects

direct electrochemistry, FeFe hydrogenase, electron bifurcation, Desulfovibrio fructosovorans, inactivation, Chemistry, QD1-999

Abstract

Hnd, an FeFe hydrogenase from Desulfovibrio fructosovorans, is a tetrameric enzyme that can perform flavin-based electron bifurcation. It couples the oxidation of H2 to both the exergonic reduction of NAD+ and the endergonic reduction of a ferredoxin. We previously showed that Hnd retains activity even when purified aerobically unlike other electron-bifurcating hydrogenases. In this study, we describe the purification of the enzyme under O2-free atmosphere and its biochemical and electrochemical characterization. Despite its complexity due to its multimeric composition, Hnd can catalytically and directly exchange electrons with an electrode. We characterized the catalytic and inhibition properties of this electron-bifurcating hydrogenase using protein film electrochemistry of Hnd by purifying Hnd aerobically or anaerobically, then comparing the electrochemical properties of the enzyme purified under the two conditions via protein film electrochemistry. Hydrogenases are usually inactivated under oxidizing conditions in the absence of dioxygen and can then be reactivated, to some extent, under reducing conditions. We demonstrate that the kinetics of this high potential inactivation/reactivation for Hnd show original properties: it depends on the enzyme purification conditions and varies with time, suggesting the coexistence and the interconversion of two forms of the enzyme. We also show that Hnd catalytic properties (Km for H2, diffusion and reaction at the active site of CO and O2) are comparable to those of standard hydrogenases (those which cannot catalyze electron bifurcation). These results suggest that the presence of the additional subunits, needed for electron bifurcation, changes neither the catalytic behavior at the active site, nor the gas diffusion kinetics but induces unusual rates of high potential inactivation/reactivation.

Published

2021

36. Universal free-energy landscape produces efficient and reversible electron bifurcation.

Author

Yuly, J. L., Zhang, P., Lubner, C. E., Peters, J. W., and Beratan, D. N.

Subjects

*ELECTRONS, *BIOENERGETICS, *ENERGY conversion, *CHARGE exchange

Abstract

For decades, it was unknown how electron-bifurcating systems in nature prevented energy-wasting short-circuiting reactions that have large driving forces, so synthetic electron-bifurcating molecular machines could not be designed and built. The underpinning free-energy landscapes for electron bifurcation were also enigmatic. We predict that a simple and universal free-energy landscape enables electron bifurcation, and we show that it enables high-efficiency bifurcation with limited short-circuiting (the EB scheme). The landscape relies on steep free-energy slopes in the two redox branches to insulate against short-circuiting using an electron occupancy blockade effect, without relying on nuanced changes in the microscopic rate constants for the short-circuiting reactions. The EB scheme thus unifies a body of observations on biological catalysis and energy conversion, and the scheme provides a blueprint to guide future campaigns to establish synthetic electron bifurcation machines. [ABSTRACT FROM AUTHOR]

Published

2020

37. Spectroscopic and biochemical insight into an electron-bifurcating [FeFe] hydrogenase.

Author

Chongdar, Nipa, Pawlak, Krzysztof, Rüdiger, Olaf, Reijerse, Edward J., Rodríguez-Maciá, Patricia, Lubitz, Wolfgang, Birrell, James A., and Ogata, Hideaki

Subjects

*ELECTRON paramagnetic resonance spectroscopy, *NAD (Coenzyme), *FOURIER transform infrared spectroscopy, *COFACTORS (Biochemistry), *THERMOTOGA maritima, *ESCHERICHIA coli, *ELECTRONS

Abstract

The heterotrimeric electron-bifurcating [FeFe] hydrogenase (HydABC) from Thermotoga maritima (Tm) couples the endergonic reduction of protons (H+) by dihydronicotinamide adenine dinucleotide (NADH) (∆G0 ≈ 18 kJ mol−1) to the exergonic reduction of H+ by reduced ferredoxin (Fdred) (∆G0 ≈ − 16 kJ mol−1). The specific mechanism by which HydABC functions is not understood. In the current study, we describe the biochemical and spectroscopic characterization of TmHydABC recombinantly produced in Escherichia coli and artificially maturated with a synthetic diiron cofactor. We found that TmHydABC catalyzed the hydrogen (H2)-dependent reduction of nicotinamide adenine dinucleotide (NAD+) in the presence of oxidized ferredoxin (Fdox) at a rate of ≈17 μmol NADH min−1 mg−1. Our data suggest that only one flavin is present in the enzyme and is not likely to be the site of electron bifurcation. FTIR and EPR spectroscopy, as well as FTIR spectroelectrochemistry, demonstrated that the active site for H2 conversion, the H-cluster, in TmHydABC behaves essentially the same as in prototypical [FeFe] hydrogenases, and is most likely also not the site of electron bifurcation. The implications of these results are discussed with respect to the current hypotheses on the electron bifurcation mechanism of [FeFe] hydrogenases. Overall, the results provide insight into the electron-bifurcating mechanism and present a well-defined system for further investigations of this fascinating class of [FeFe] hydrogenases. [ABSTRACT FROM AUTHOR]

Published

2020

38. Complex Multimeric [FeFe] Hydrogenases: Biochemistry, Physiology and New Opportunities for the Hydrogen Economy

Author

Kai Schuchmann, Nilanjan Pal Chowdhury, and Volker Müller

Subjects

hydrogenase, formate dehydrogenase, CO2 reduction, electron bifurcation, hydrogen production, acetogenesis, Microbiology, QR1-502

Abstract

Hydrogenases are key enzymes of the energy metabolism of many microorganisms. Especially in anoxic habitats where molecular hydrogen (H2) is an important intermediate, these enzymes are used to expel excess reducing power by reducing protons or they are used for the oxidation of H2 as energy and electron source. Despite the fact that hydrogenases catalyze the simplest chemical reaction of reducing two protons with two electrons it turned out that they are often parts of multimeric enzyme complexes catalyzing complex chemical reactions with a multitude of functions in the metabolism. Recent findings revealed multimeric hydrogenases with so far unknown functions particularly in bacteria from the class Clostridia. The discovery of [FeFe] hydrogenases coupled to electron bifurcating subunits solved the enigma of how the otherwise highly endergonic reduction of the electron carrier ferredoxin can be carried out and how H2 production from NADH is possible. Complexes of [FeFe] hydrogenases with formate dehydrogenases revealed a novel enzymatic coupling of the two electron carriers H2 and formate. These novel hydrogenase enzyme complex could also contribute to biotechnological H2 production and H2 storage, both processes essential for an envisaged economy based on H2 as energy carrier.

Published

2018

39. Origin and Evolution of Flavin-Based Electron Bifurcating Enzymes

Author

Saroj Poudel, Eric C. Dunham, Melody R. Lindsay, Maximiliano J. Amenabar, Elizabeth M. Fones, Daniel R. Colman, and Eric S. Boyd

Subjects

electron bifurcation, flavin, ferredoxin, anoxic, subsurface, oxidoreductase, Microbiology, QR1-502

Abstract

Twelve evolutionarily unrelated oxidoreductases form enzyme complexes that catalyze the simultaneous coupling of exergonic and endergonic oxidation–reduction reactions to circumvent thermodynamic barriers and minimize free energy loss in a process known as flavin-based electron bifurcation. Common to these 12 bifurcating (Bf) enzymes are protein-bound flavin, the proposed site of bifurcation, and the electron carrier ferredoxin. Despite the documented role of Bf enzymes in balancing the redox state of intracellular electron carriers and in improving the efficiency of cellular metabolism, a comprehensive description of the diversity and evolutionary history of Bf enzymes is lacking. Here, we report the taxonomic distribution, functional diversity, and evolutionary history of Bf enzyme homologs in 4,588 archaeal, bacterial, and eukaryal genomes and 3,136 community metagenomes. Bf homologs were primarily detected in the genomes of anaerobes, including those of sulfate-reducers, acetogens, fermenters, and methanogens. Phylogenetic analyses of Bf enzyme catalytic subunits (oxidoreductases) suggest they were not a property of the Last Universal Common Ancestor of Archaea and Bacteria, which is consistent with the limited and unique taxonomic distributions of enzyme homologs among genomes. Further, phylogenetic analyses of oxidoreductase subunits reveal that non-Bf homologs predate Bf homologs. These observations indicate that multiple independent recruitments of flavoproteins to existing oxidoreductases enabled coupling of numerous new electron Bf reactions. Consistent with the role of these enzymes in the energy metabolism of anaerobes, homologs of Bf enzymes were enriched in metagenomes from subsurface environments relative to those from surface environments. Phylogenetic analyses of homologs from metagenomes reveal that the earliest evolving homologs of most Bf enzymes are from subsurface environments, including fluids from subsurface rock fractures and hydrothermal systems. Collectively, these data suggest strong selective pressures drove the emergence of Bf enzyme complexes via recruitment of flavoproteins that allowed for an increase in the efficiency of cellular metabolism and improvement in energy capture in anaerobes inhabiting a variety of subsurface anoxic habitats where the energy yield of oxidation-reduction reactions is generally low.

Published

2018

40. Effects of Applied Potential and Reactants to Hydrogen-Producing Biocathode in a Microbial Electrolysis Cell

Author

Swee Su Lim, Byung Hong Kim, Da Li, Yujie Feng, Wan Ramli Wan Daud, Keith Scott, and Eileen Hao Yu

Subjects

hydrogen-producing biocathode, microbial electrolysis cell, electron bifurcation, sulfate reduction, bicarbonate conversion, Chemistry, QD1-999

Abstract

Understanding the mechanism of electron transfer between the cathode and microorganisms in cathode biofilms in microbial electrolysis cells (MECs) for hydrogen production is important. In this study, biocathodes of MECs were successfully re-enriched and subjected to different operating parameters: applied potential, sulfate use and inorganic carbon consumption. It was hypothesized that biocathode catalytic activity would be affected by the applied potentials that initiate electron transfer. While inorganic carbon, in the form of bicarbonate, could be a main carbon source for biocathode growth, sulfate could be a terminal electron acceptor and thus reduced to elemental sulfurs. It was found that potentials more negative than −0.8 V (vs. standard hydrogen electrode) were required for hydrogen production by the biocathode. In additional, a maximum hydrogen production was observed at sulfate and bicarbonate concentrations of 288 and 610 mg/L respectively. Organic carbons were found in the cathode effluents, suggesting that microbial interactions probably happen between acetogens and sulfate reducing bacteria (SRB). The hydrogen-producing biocathode was sulfate-dependent and hydrogen production could be inhibited by excessive sulfate because more energy was directed to reduce sulfate (E° SO42-/H2S = −0.35 V) than proton (E° H+/H2 = −0.41 V). This resulted in a restriction to the hydrogen production when sulfate concentration was high. Domestic wastewaters contain low amounts of organic compounds and sulfate would be a better medium to enrich and maintain a hydrogen-producing biocathode dominated by SRB. Besides the risks of limited mass transport and precipitation caused by low potential, methane contamination in the hydrogen-rich environment was inevitable in the biocathode after long term operation due to methanogenic activities.

Published

2018

41. The Role of Mass Spectrometry in Structural Studies of Flavin-Based Electron Bifurcating Enzymes

Author

Monika Tokmina-Lukaszewska, Angela Patterson, Luke Berry, Liam Scott, Narayanaganesh Balasubramanian, and Brian Bothner

Subjects

chemical cross-linking, hydrogen deuterium exchange, protein labeling, native mass spectrometry, electron bifurcation, protein structure, Microbiology, QR1-502

Abstract

For decades, biologists and biochemists have taken advantage of atomic resolution structural models of proteins from X-ray crystallography, nuclear magnetic resonance spectroscopy, and more recently cryo-electron microscopy. However, not all proteins relent to structural analyses using these approaches, and as the depth of knowledge increases, additional data elucidating a mechanistic understanding of protein function is desired. Flavin-based electron bifurcating enzymes, which are responsible for producing high energy compounds through the simultaneous endergonic and exergonic reduction of two intercellular electron carriers (i.e., NAD+ and ferredoxin) are one class of proteins that have challenged structural biologists and in which there is great interest to understand the mechanism behind electron gating. A limited number of X-ray crystallography projects have been successful; however, it is clear that to understand how these enzymes function, techniques that can reveal detailed in solution information about protein structure, dynamics, and interactions involved in the bifurcating reaction are needed. In this review, we cover a general set of mass spectrometry-based techniques that, combined with protein modeling, are capable of providing information on both protein structure and dynamics. Techniques discussed include surface labeling, covalent cross-linking, native mass spectrometry, and hydrogen/deuterium exchange. We cover how biophysical data can be used to validate computationally generated protein models and develop mechanistic explanations for regulation and performance of enzymes and protein complexes. Our focus will be on flavin-based electron bifurcating enzymes, but the broad applicability of the techniques will be showcased.

Published

2018

42. On the Natural History of Flavin-Based Electron Bifurcation

Author

Frauke Baymann, Barbara Schoepp-Cothenet, Simon Duval, Marianne Guiral, Myriam Brugna, Carole Baffert, Michael J. Russell, and Wolfgang Nitschke

Subjects

electron bifurcation, redox cooperativity, flavoenzymes, emergence of life, redox enzyme construction kit, bioenergetics, Microbiology, QR1-502

Abstract

Electron bifurcation is here described as a special case of the continuum of electron transfer reactions accessible to two-electron redox compounds with redox cooperativity. We argue that electron bifurcation is foremost an electrochemical phenomenon based on (a) strongly inverted redox potentials of the individual redox transitions, (b) a high endergonicity of the first redox transition, and (c) an escapement-type mechanism rendering completion of the first electron transfer contingent on occurrence of the second one. This mechanism is proposed to govern both the traditional quinone-based and the newly discovered flavin-based versions of electron bifurcation. Conserved and variable aspects of the spatial arrangement of electron transfer partners in flavoenzymes are assayed by comparing the presently available 3D structures. A wide sample of flavoenzymes is analyzed with respect to conserved structural modules and three major structural groups are identified which serve as basic frames for the evolutionary construction of a plethora of flavin-containing redox enzymes. We argue that flavin-based and other types of electron bifurcation are of primordial importance to free energy conversion, the quintessential foundation of life, and discuss a plausible evolutionary ancestry of the mechanism.

Published

2018

43. Flavin-Based Electron Bifurcation, Ferredoxin, Flavodoxin, and Anaerobic Respiration With Protons (Ech) or NAD+ (Rnf) as Electron Acceptors: A Historical Review

Author

Wolfgang Buckel and Rudolf K. Thauer

Subjects

electron bifurcation, ferredoxin, flavodoxin, electron-transferring flavoproteins (EtfAB), Rnf-complex, Ech-complex, Microbiology, QR1-502

Abstract

Flavin-based electron bifurcation is a newly discovered mechanism, by which a hydride electron pair from NAD(P)H, coenzyme F420H2, H2, or formate is split by flavoproteins into one-electron with a more negative reduction potential and one with a more positive reduction potential than that of the electron pair. Via this mechanism microorganisms generate low- potential electrons for the reduction of ferredoxins (Fd) and flavodoxins (Fld). The first example was described in 2008 when it was found that the butyryl-CoA dehydrogenase-electron-transferring flavoprotein complex (Bcd-EtfAB) of Clostridium kluyveri couples the endergonic reduction of ferredoxin (E0′ = −420 mV) with NADH (−320 mV) to the exergonic reduction of crotonyl-CoA to butyryl-CoA (−10 mV) with NADH. The discovery was followed by the finding of an electron-bifurcating Fd- and NAD-dependent [FeFe]-hydrogenase (HydABC) in Thermotoga maritima (2009), Fd-dependent transhydrogenase (NfnAB) in various bacteria and archaea (2010), Fd- and H2-dependent heterodisulfide reductase (MvhADG-HdrABC) in methanogenic archaea (2011), Fd- and NADH-dependent caffeyl-CoA reductase (CarCDE) in Acetobacterium woodii (2013), Fd- and NAD-dependent formate dehydrogenase (HylABC-FdhF2) in Clostridium acidi-urici (2013), Fd- and NADP-dependent [FeFe]-hydrogenase (HytA-E) in Clostridium autoethanogrenum (2013), Fd(?)- and NADH-dependent methylene-tetrahydrofolate reductase (MetFV-HdrABC-MvhD) in Moorella thermoacetica (2014), Fd- and NAD-dependent lactate dehydrogenase (LctBCD) in A. woodii (2015), Fd- and F420H2-dependent heterodisulfide reductase (HdrA2B2C2) in Methanosarcina acetivorans (2017), and Fd- and NADH-dependent ubiquinol reductase (FixABCX) in Azotobacter vinelandii (2017). The electron-bifurcating flavoprotein complexes known to date fall into four groups that have evolved independently, namely those containing EtfAB (CarED, LctCB, FixBA) with bound FAD, a NuoF homolog (HydB, HytB, or HylB) harboring FMN, NfnB with bound FAD, or HdrA harboring FAD. All these flavoproteins are cytoplasmic except for the membrane-associated protein FixABCX. The organisms—in which they have been found—are strictly anaerobic microorganisms except for the aerobe A. vinelandii. The electron-bifurcating complexes are involved in a variety of processes such as butyric acid fermentation, methanogenesis, acetogenesis, anaerobic lactate oxidation, dissimilatory sulfate reduction, anaerobic- dearomatization, nitrogen fixation, and CO2 fixation. They contribute to energy conservation via the energy-converting ferredoxin: NAD+ reductase complex Rnf or the energy-converting ferredoxin-dependent hydrogenase complex Ech. This Review describes how this mechanism was discovered.

Published

2018

44. Functionally redundant formate dehydrogenases enable formate-dependent growth in Methanococcus maripaludis.

Author

Abdul Halim MF, Fonseca DR, Niehaus TD, and Costa KC

Subjects

Flavins metabolism, Formates metabolism, Protein Isoforms metabolism, Formate Dehydrogenases genetics, Formate Dehydrogenases metabolism, Methanococcus genetics, Methanococcus metabolism

Abstract

Methanogens are essential for the complete remineralization of organic matter in anoxic environments. Most cultured methanogens are hydrogenotrophic, using H 2 as an electron donor to reduce CO 2 to CH 4 , but in the absence of H 2 many can also use formate. Formate dehydrogenase (Fdh) is essential for formate oxidation, where it transfers electrons for the reduction of coenzyme F 420 or to a flavin-based electron bifurcating reaction catalyzed by heterodisulfide reductase (Hdr), the terminal reaction of methanogenesis. Furthermore, methanogens that use formate encode at least two isoforms of Fdh in their genomes, but how these different isoforms participate in methanogenesis is unknown. Using Methanococcus maripaludis, we undertook a biochemical characterization of both Fdh isoforms involved in methanogenesis. Both Fdh1 and Fdh2 interacted with Hdr to catalyze the flavin-based electron bifurcating reaction, and both reduced F 420 at similar rates. F 420 reduction preceded flavin-based electron bifurcation activity for both enzymes. In a Δfdh1 mutant background, a suppressor mutation was required for Fdh2 activity. Genome sequencing revealed that this mutation resulted in the loss of a specific molybdopterin transferase (moeA), allowing for Fdh2-dependent growth, and the metal content of the proteins suggested that isoforms are dependent on either molybdenum or tungsten for activity. These data suggest that both isoforms of Fdh are functionally redundant, but their activities in vivo may be limited by gene regulation or metal availability under different growth conditions. Together these results expand our understanding of formate oxidation and the role of Fdh in methanogenesis., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

45. Rapid-reaction kinetics of the bifurcating NAD + -dependent NADPH:ferredoxin oxidoreductase NfnI from Pyrococcus furiosus.

Author

Ortiz S, Niks D, Wiley S, Lubner CE, and Hille R

Subjects

Kinetics, NAD metabolism, NADP metabolism, Oxidation-Reduction, Ferredoxins metabolism, Oxidoreductases metabolism, Pyrococcus furiosus enzymology, Archaeal Proteins metabolism

Abstract

We have investigated the kinetics of NAD + -dependent NADPH:ferredoxin oxidoreductase (NfnI), a bifurcating transhydrogenase that takes two electron pairs from NADPH to reduce two ferredoxins and one NAD +  through successive bifurcation events. NADPH reduction takes place at the bifurcating FAD of NfnI's large subunit, with high-potential electrons transferred to the [2Fe-2S] cluster and S-FADH of the small subunit, ultimately on to NAD + ; low-potential electrons are transferred to two [4Fe-4S] clusters of the large subunit and on to ferredoxin. Reduction of NfnI by NADPH goes to completion only at higher pH, with a limiting k red  of 36 ± 1.6 s -1  and apparent K d NADPH  of 5 ± 1.2 μM. Reduction of one of the [4Fe-4S] clusters of NfnI occurs within a second, indicating that in the absence of NAD + , the system can bifurcate and generate low-potential electrons without NAD + . When enzyme is reduced by NADPH in the absence of NAD +  demonstrates that electron bifurcation is an intrinsic property of the bifurcating FAD and is not dependent on the simultaneous presence of NAD +  demonstrates that electron bifurcation is an intrinsic property of the bifurcating FAD and is not dependent on the simultaneous presence of NAD +  and ferredoxin. The tight coupling between NAD +  and ferredoxin reduction observed under multiple-turnover conditions is instead simply due to the need to remove reducing equivalents from the high-potential electron pathway under multiple-turnover conditions., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

46. A new mechanistic model for an O2-protected electron-bifurcating hydrogenase, Hnd from Desulfovibrio fructosovorans.

Author

Kpebe, Arlette, Benvenuti, Martino, Guendon, Chloé, Rebai, Amani, Fernandez, Victoria, Le Laz, Sébastien, Etienne, Emilien, Guigliarelli, Bruno, García-Molina, Gabriel, de Lacey, Antonio L., Baffert, Carole, and Brugna, Myriam

Subjects

*GENOMES, *ANAEROBIC bacteria, *NICOTINAMIDE adenine dinucleotide phosphate, *HYDROGENASE, *FERREDOXINS

Abstract

Abstract The genome of the sulfate-reducing and anaerobic bacterium Desulfovibrio fructosovorans encodes different hydrogenases. Among them is Hnd, a tetrameric cytoplasmic [FeFe] hydrogenase that has previously been described as an NADP-specific enzyme (Malki et al., 1995). In this study, we purified and characterized a recombinant Strep-tagged form of Hnd and demonstrated that it is an electron-bifurcating enzyme. Flavin-based electron-bifurcation is a mechanism that couples an exergonic redox reaction to an endergonic one allowing energy conservation in anaerobic microorganisms. One of the three ferredoxins of the bacterium, that was named FdxB, was also purified and characterized. It contains a low-potential (E m = −450 mV) [4Fe4S] cluster. We found that Hnd was not able to reduce NADP+, and that it catalyzes the simultaneous reduction of FdxB and NAD+. Moreover, Hnd is the first electron-bifurcating hydrogenase that retains activity when purified aerobically due to formation of an inactive state of its catalytic site protecting against O 2 damage (H inact). Hnd is highly active with the artificial redox partner (methyl viologen) and can perform the electron-bifurcation reaction to oxidize H 2 with a specific activity of 10 μmol of NADH/min/mg of enzyme. Surprisingly, the ratio between NADH and reduced FdxB varies over the reaction with a decreasing amount of FdxB reduced per NADH produced, indicating a more complex mechanism than previously described. We proposed a new mechanistic model in which the ferredoxin is recycled at the hydrogenase catalytic subunit. Highlights • Hnd from Desulfovibrio fructosovorans is an [FeFe] electron-bifurcating hydrogenase. • Hnd catalyzes the simultaneous reduction of NAD+ and ferredoxin. • Hnd forms an O 2 -protected state of its catalytic site (H inact). • During electron-bifurcating reaction, Hnd produces less FdxB red than NADH. [ABSTRACT FROM AUTHOR]

Published

2018

47. Electron bifurcation mechanism and homoacetogenesis explain products yields in mixed culture anaerobic fermentations.

Author

Regueira, A., González-Cabaleiro, R., Ofiţeru, I.D., Rodríguez, J., and Lema, J.M.

Subjects

*ELECTRONS, *FERMENTATION, *RIVER bifurcation, *NICOTINAMIDE adenine dinucleotide phosphate, *CARBON dioxide in water

Abstract

Anaerobic fermentation of organic wastes using microbial mixed cultures is a promising avenue to treat residues and obtain added-value products. However, the process has some important limitations that prevented so far any industrial application. One of the main issues is that we are not able to predict reliably the product spectrum (i.e. the stoichiometry of the process) because the complex microbial community behaviour is not completely understood. To address this issue, in this work we propose a new metabolic network of glucose fermentation by microbial mixed cultures that incorporates electron bifurcation and homoacetogenesis. Our methodology uses NADH balances to analyse published experimental data and evaluate the new stoichiometry proposed. Our results prove for the first time the inclusion of electron bifurcation in the metabolic network as a better description of the experimental results. Homoacetogenesis has been used to explain the discrepancies between observed and theoretically predicted yields of gaseous H 2 and CO 2 and it appears as the best solution among other options studied. Overall, this work supports the consideration of electron bifurcation as an important biochemical mechanism in microbial mixed cultures fermentations and underlines the importance of considering homoacetogenesis when analysing anaerobic fermentations. [ABSTRACT FROM AUTHOR]

Published

2018

48. Origin and Evolution of Flavin-Based Electron Bifurcating Enzymes.

Author

Poudel, Saroj, Dunham, Eric C., Lindsay, Melody R., Amenabar, Maximiliano J., Fones, Elizabeth M., Colman, Daniel R., and Boyd, Eric S.

Subjects

FLAVINS, ELECTRONS

Abstract

Twelve evolutionarily unrelated oxidoreductases form enzyme complexes that catalyze the simultaneous coupling of exergonic and endergonic oxidation-reduction reactions to circumvent thermodynamic barriers and minimize free energy loss in a process known as flavin-based electron bifurcation. Common to these 12 bifurcating (Bf) enzymes are protein-bound flavin, the proposed site of bifurcation, and the electron carrier ferredoxin. Despite the documented role of Bf enzymes in balancing the redox state of intracellular electron carriers and in improving the efficiency of cellular metabolism, a comprehensive description of the diversity and evolutionary history of Bf enzymes is lacking. Here, we report the taxonomic distribution, functional diversity, and evolutionary history of Bf enzyme homologs in 4,588 archaeal, bacterial, and eukaryal genomes and 3,136 community metagenomes. Bf homologs were primarily detected in the genomes of anaerobes, including those of sulfate-reducers, acetogens, fermenters, and methanogens. Phylogenetic analyses of Bf enzyme catalytic subunits (oxidoreductases) suggest they were not a property of the Last Universal Common Ancestor of Archaea and Bacteria, which is consistent with the limited and unique taxonomic distributions of enzyme homologs among genomes. Further, phylogenetic analyses of oxidoreductase subunits reveal that non-Bf homologs predate Bf homologs. These observations indicate that multiple independent recruitments of flavoproteins to existing oxidoreductases enabled coupling of numerous new electron Bf reactions. Consistent with the role of these enzymes in the energy metabolism of anaerobes, homologs of Bf enzymes were enriched in metagenomes from subsurface environments relative to those from surface environments. Phylogenetic analyses of homologs from metagenomes reveal that the earliest evolving homologs of most Bf enzymes are from subsurface environments, including fluids from subsurface rock fractures and hydrothermal systems. Collectively, these data suggest strong selective pressures drove the emergence of Bf enzyme complexes via recruitment of flavoproteins that allowed for an increase in the efficiency of cellular metabolism and improvement in energy capture in anaerobes inhabiting a variety of subsurface anoxic habitats where the energy yield of oxidation-reduction reactions is generally low. [ABSTRACT FROM AUTHOR]

Published

2018

49. The Role of Mass Spectrometry in Structural Studies of Flavin-Based Electron Bifurcating Enzymes.

Author

Tokmina-Lukaszewska, Monika, Patterson, Angela, Berry, Luke, Scott, Liam, Balasubramanian, Narayanaganesh, and Bothner, Brian

Subjects

FLAVINS, MASS spectrometry, X-ray crystallography

Abstract

For decades, biologists and biochemists have taken advantage of atomic resolution structural models of proteins from X-ray crystallography, nuclear magnetic resonance spectroscopy, and more recently cryo-electron microscopy. However, not all proteins relent to structural analyses using these approaches, and as the depth of knowledge increases, additional data elucidating a mechanistic understanding of protein function is desired. Flavin-based electron bifurcating enzymes, which are responsible for producing high energy compounds through the simultaneous endergonic and exergonic reduction of two intercellular electron carriers (i.e., NAD+ and ferredoxin) are one class of proteins that have challenged structural biologists and in which there is great interest to understand the mechanism behind electron gating. A limited number of X-ray crystallography projects have been successful; however, it is clear that to understand how these enzymes function, techniques that can reveal detailed in solution information about protein structure, dynamics, and interactions involved in the bifurcating reaction are needed. In this review, we cover a general set of mass spectrometry-based techniques that, combined with protein modeling, are capable of providing information on both protein structure and dynamics. Techniques discussed include surface labeling, covalent cross-linking, native mass spectrometry, and hydrogen/deuterium exchange. We cover how biophysical data can be used to validate computationally generated protein models and develop mechanistic explanations for regulation and performance of enzymes and protein complexes. Our focus will be on flavin-based electron bifurcating enzymes, but the broad applicability of the techniques will be showcased. [ABSTRACT FROM AUTHOR]

Published

2018

50. On the Natural History of Flavin-Based Electron Bifurcation.

Author

Baymann, Frauke, Schoepp-Cothenet, Barbara, Duval, Simon, Guiral, Marianne, Brugna, Myriam, Baffert, Carole, Russell, Michael J., and Nitschke, Wolfgang

Subjects

FLAVINS, FLAVOPROTEINS, CHARGE exchange

Abstract

Electron bifurcation is here described as a special case of the continuum of electron transfer reactions accessible to two-electron redox compounds with redox cooperativity. We argue that electron bifurcation is foremost an electrochemical phenomenon based on (a) strongly inverted redox potentials of the individual redox transitions, (b) a high endergonicity of the first redox transition, and (c) an escapement-type mechanism rendering completion of the first electron transfer contingent on occurrence of the second one. This mechanism is proposed to govern both the traditional quinone-based and the newly discovered flavin-based versions of electron bifurcation. Conserved and variable aspects of the spatial arrangement of electron transfer partners in flavoenzymes are assayed by comparing the presently available 3D structures. A wide sample of flavoenzymes is analyzed with respect to conserved structural modules and three major structural groups are identified which serve as basic frames for the evolutionary construction of a plethora of flavin-containing redox enzymes. We argue that flavin-based and other types of electron bifurcation are of primordial importance to free energy conversion, the quintessential foundation of life, and discuss a plausible evolutionary ancestry of the mechanism. [ABSTRACT FROM AUTHOR]

Published

2018