Your search keyword '"Happe, T."' showing total 68 results

1. Oxygen sensitivity of [FeFe]-hydrogenase: a comparative study of active site mimics inside vs. outside the enzyme.

Author

Yadav S, Haas R, Boydas EB, Roemelt M, Happe T, Apfel UP, and Stripp ST

Subjects

Density Functional Theory, Hydrogenase chemistry, Hydrogenase metabolism, Catalytic Domain, Oxygen chemistry, Oxygen metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism

Abstract

[FeFe]-hydrogenase is nature's most efficient proton reducing and H 2 -oxidizing enzyme. However, biotechnological applications are hampered by the O 2 sensitivity of this metalloenzyme, and the mechanism of aerobic deactivation is not well understood. Here, we explore the oxygen sensitivity of four mimics of the organometallic active site cofactor of [FeFe]-hydrogenase, [Fe 2 (adt)(CO) 6- x (CN) x ] x - and [Fe 2 (pdt)(CO) 6- x (CN) x ] x - ( x = 1, 2) as well as the corresponding cofactor variants of the enzyme by means of infrared, Mössbauer, and NMR spectroscopy. Additionally, we describe a straightforward synthetic recipe for the active site precursor complex Fe 2 (adt)(CO) 6 . Our data indicate that the aminodithiolate (adt) complex, which is the synthetic precursor of the natural active site cofactor, is most oxygen sensitive. This observation highlights the significance of proton transfer in aerobic deactivation, and supported by DFT calculations facilitates an identification of the responsible reactive oxygen species (ROS). Moreover, we show that the ligand environment of the iron ions critically influences the reactivity with O 2 and ROS like superoxide and H 2 O 2 as the oxygen sensitivity increases with the exchange of ligands from CO to CN - . The trends in aerobic deactivation observed for the model complexes are in line with the respective enzyme variants. Based on experimental and computational data, a model for the initial reaction of [FeFe]-hydrogenase with O 2 is developed. Our study underscores the relevance of model systems in understanding biocatalysis and validates their potential as important tools for elucidating the chemistry of oxygen-induced deactivation of [FeFe]-hydrogenase.

Published

2024

2. A Conserved Binding Pocket in HydF is Essential for Biological Assembly and Coordination of the Diiron Site of [FeFe]-Hydrogenases.

Author

Haas R, Lampret O, Yadav S, Apfel UP, and Happe T

Subjects

Binding Sites, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Iron chemistry, Iron metabolism, Models, Molecular, Hydrogenase chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism

Abstract

The active site cofactor of [FeFe]-hydrogenases consists of a cubane [4Fe-4S]-cluster and a unique [2Fe-2S]-cluster, harboring unusual CO- and CN - -ligands. The biosynthesis of the [2Fe-2S]-cluster requires three dedicated maturation enzymes called HydG, HydE and HydF. HydG and HydE are both involved in synthesizing a [2Fe-2S]-precursor, still lacking parts of the azadithiolate (adt) moiety that bridge the two iron atoms. This [2Fe-2S]-precursor is then finalized within the scaffold protein HydF, which binds and transfers the [2Fe-2S]-precursor to the hydrogenase. However, its exact binding mode within HydF is still elusive. Herein, we identified the binding location of the [2Fe-2S]-precursor by altering size and charge of a highly conserved protein pocket via site directed mutagenesis (SDM). Moreover, we identified two serine residues that are essential for binding and assembling the [2Fe-2S]-precursor. By combining SDM and molecular docking simulations, we provide a new model on how the [2Fe-2S]-cluster is bound to HydF and demonstrate the important role of one highly conserved aspartate residue, presumably during the bioassembly of the adt moiety.

Published

2024

3. H 2 production under stress: [FeFe]‑hydrogenases reveal strong stability in high pressure environments.

Author

Edenharter K, Jaworek MW, Engelbrecht V, Winter R, and Happe T

Subjects

Protons, Catalysis, Hydrogen chemistry, Hydrogen metabolism, Hydrogenase chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry, Metalloproteins

Abstract

Hydrogenases are a diverse group of metalloenzymes that catalyze the conversion of H 2 into protons and electrons and the reverse reaction. A subgroup is formed by the [FeFe]‑hydrogenases, which are the most efficient enzymes of microbes for catalytic H 2 conversion. We have determined the stability and activity of two [FeFe]‑hydrogenases under high temperature and pressure conditions employing FTIR spectroscopy and the high-pressure stopped-flow methodology in combination with fast UV/Vis detection. Our data show high temperature stability and an increase in activity up to the unfolding temperatures of the enzymes. Remarkably, both enzymes reveal a very high pressure stability of their structure, even up to pressures of several kbars. Their high pressure-stability enables high enzymatic activity up to 2 kbar, which largely exceeds the pressure limit encountered by organisms in the deep sea and sub-seafloor on Earth., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

4. A Dynamic Water Channel Affects O 2 Stability in [FeFe]-Hydrogenases.

Author

Brocks C, Das CK, Duan J, Yadav S, Apfel UP, Ghosh S, Hofmann E, Winkler M, Engelbrecht V, Schäfer LV, and Happe T

Subjects

Hydrogen chemistry, Protons, Oxygen chemistry, Hydrogenase chemistry, Aquaporins, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism

Abstract

[FeFe]-hydrogenases are capable of reducing protons at a high rate. However, molecular oxygen (O 2 ) induces the degradation of their catalytic cofactor, the H-cluster, which consists of a cubane [4Fe4S] subcluster (4Fe H ) and a unique diiron moiety (2Fe H ). Previous attempts to prevent O 2 -induced damage have focused on enhancing the protein's sieving effect for O 2 by blocking the hydrophobic gas channels that connect the protein surface and the 2Fe H . In this study, we aimed to block an O 2 diffusion pathway and shield 4Fe H instead. Molecular dynamics (MD) simulations identified a novel water channel (W H ) surrounding the H-cluster. As this hydrophilic path may be accessible for O 2 molecules we applied site-directed mutagenesis targeting amino acids along W H in proximity to 4Fe H to block O 2 diffusion. Protein film electrochemistry experiments demonstrate increased O 2 stabilities for variants G302S and S357T, and MD simulations based on high-resolution crystal structures confirmed an enhanced local sieving effect for O 2 in the environment of the 4Fe H in both cases. The results strongly suggest that, in wild type proteins, O 2 diffuses from the 4Fe H to the 2Fe H . These results reveal new strategies for improving the O 2 stability of [FeFe]-hydrogenases by focusing on the O 2 diffusion network near the active site., (© 2023 The Authors. ChemSusChem published by Wiley-VCH GmbH.)

Published

2024

5. The Alga Uronema belkae Has Two Structural Types of [FeFe]-Hydrogenases with Different Biochemical Properties.

Author

Alavi G, Engelbrecht V, Hemschemeier A, and Happe T

Subjects

Phylogeny, Ferredoxins metabolism, Photosynthesis, Hydrogen chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins metabolism

Abstract

Several species of microalgae can convert light energy into molecular hydrogen (H 2 ) by employing enzymes of early phylogenetic origin, [FeFe]-hydrogenases, coupled to the photosynthetic electron transport chain. Bacterial [FeFe]-hydrogenases consist of a conserved domain that harbors the active site cofactor, the H-domain, and an additional domain that binds electron-conducting FeS clusters, the F-domain. In contrast, most algal hydrogenases characterized so far have a structurally reduced, so-termed M1-type architecture, which consists only of the H-domain that interacts directly with photosynthetic ferredoxin PetF as an electron donor. To date, only a few algal species are known to contain bacterial-type [FeFe]-hydrogenases, and no M1-type enzymes have been identified in these species. Here, we show that the chlorophycean alga Uronema belkae possesses both bacterial-type and algal-type [FeFe]-hydrogenases. Both hydrogenase genes are transcribed, and the cells produce H 2 under hypoxic conditions. The biochemical analyses show that the two enzymes show features typical for each of the two [FeFe]-hydrogenase types. Most notable in the physiological context is that the bacterial-type hydrogenase does not interact with PetF proteins, suggesting that the two enzymes are integrated differently into the alga's metabolism.

Published

2023

6. The [4Fe-4S]-Cluster of HydF is not Required for the Binding and Transfer of the Diiron Site of [FeFe]-Hydrogenases.

Author

Haas R, Engelbrecht V, Lampret O, Yadav S, Apfel UP, Leimkühler S, and Happe T

Subjects

Proteins metabolism, Binding Sites, Catalytic Domain, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry

Abstract

The active site of [FeFe]-hydrogenases contains a cubane [4Fe-4S]-cluster and a unique diiron cluster with biologically unusual CO and CN - ligands. The biogenesis of this diiron site, termed [2Fe H ], requires the maturation proteins HydE, HydF and HydG. During the maturation process HydF serves as a scaffold protein for the final assembly steps and the subsequent transfer of the [2Fe H ] precursor, termed [2Fe P ], to the [FeFe]-hydrogenase. The binding site of [2Fe P ] in HydF has not been elucidated, however, the [4Fe-4S]-cluster of HydF was considered as a possible binding partner of [2Fe P ]. By targeting individual amino acids in HydF from Thermosipho melanesiensis using site directed mutagenesis, we examined the postulated binding mechanism as well as the importance and putative involvement of the [4Fe-4S]-cluster for binding and transferring [2Fe P ]. Surprisingly, our results suggest that binding or transfer of [2Fe P ] does not involve the proposed binding mechanism or the presence of a [4Fe-4S]-cluster at all., (© 2023 The Authors. ChemBioChem published by Wiley-VCH GmbH.)

Published

2023

7. Cyanide Binding to [FeFe]-Hydrogenase Stabilizes the Alternative Configuration of the Proton Transfer Pathway.

Author

Duan J, Hemschemeier A, Burr DJ, Stripp ST, Hofmann E, and Happe T

Subjects

Protons, Hydrogen chemistry, Cyanides metabolism, Catalysis, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry

Abstract

Hydrogenases are H 2 converting enzymes that harbor catalytic cofactors in which iron (Fe) ions are coordinated by biologically unusual carbon monoxide (CO) and cyanide (CN - ) ligands. Extrinsic CO and CN - , however, inhibit hydrogenases. The mechanism by which CN - binds to [FeFe]-hydrogenases is not known. Here, we obtained crystal structures of the CN - -treated [FeFe]-hydrogenase CpI from Clostridium pasteurianum. The high resolution of 1.39 Å allowed us to distinguish intrinsic CN - and CO ligands and to show that extrinsic CN - binds to the open coordination site of the cofactor where CO is known to bind. In contrast to other inhibitors, CN - treated crystals show conformational changes of conserved residues within the proton transfer pathway which could allow a direct proton transfer between E279 and S319. This configuration has been proposed to be vital for efficient proton transfer, but has never been observed structurally., (© 2022 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2023

8. Changing the tracks: screening for electron transfer proteins to support hydrogen production.

Author

Günzel A, Engelbrecht V, and Happe T

Subjects

Electron Transport, Electrons, Hydrogen metabolism, NADP metabolism, Ferredoxins chemistry, Hydrogenase chemistry

Abstract

Ferredoxins are essential electron transferring proteins in organisms. Twelve plant-type ferredoxins in the green alga Chlamydomonas reinhardtii determine the fate of electrons, generated in multiple metabolic processes. The two hydrogenases HydA1 and HydA2 of. C. reinhardtii compete for electrons from the photosynthetic ferredoxin PetF, which is the first stromal mediator of the high-energy electrons derived from the absorption of light energy at the photosystems. While being involved in many chloroplast-located metabolic pathways, PetF shows the highest affinity for ferredoxin-NADP + oxidoreductase (FNR), not for the hydrogenases. Aiming to identify other potential electron donors for the hydrogenases, we screened as yet uncharacterized ferredoxins Fdx7, 8, 10 and 11 for their capability to reduce the hydrogenases. Comparing the performance of the Fdx in presence and absence of competitor FNR, we show that Fdx7 has a higher affinity for HydA1 than for FNR. Additionally, we show that synthetic FeS-cluster-binding maquettes, which can be reduced by NADPH alone, can also be used to reduce the hydrogenases. Our findings pave the way for the creation of tailored electron donors to redirect electrons to enzymes of interest., (© 2022. The Author(s).)

Published

2022

9. Site-selective protonation of the one-electron reduced cofactor in [FeFe]-hydrogenase.

Author

Laun K, Baranova I, Duan J, Kertess L, Wittkamp F, Apfel UP, Happe T, Senger M, and Stripp ST

Subjects

Chlamydomonas reinhardtii enzymology, Electrons, Hydrogen-Ion Concentration, Hydrogenase analysis, Iron-Sulfur Proteins analysis, Oxidation-Reduction, Protons, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism

Abstract

Hydrogenases are bidirectional redox enzymes that catalyze hydrogen turnover in archaea, bacteria, and algae. While all types of hydrogenase show H2 oxidation activity, [FeFe]-hydrogenases are excellent H2 evolution catalysts as well. Their active site cofactor comprises a [4Fe-4S] cluster covalently linked to a diiron site equipped with carbon monoxide and cyanide ligands. The active site niche is connected with the solvent by two distinct proton transfer pathways. To analyze the catalytic mechanism of [FeFe]-hydrogenase, we employ operando infrared spectroscopy and infrared spectro-electrochemistry. Titrating the pH under H2 oxidation or H2 evolution conditions reveals the influence of site-selective protonation on the equilibrium of reduced cofactor states. Governed by pKa differences across the active site niche and proton transfer pathways, we find that individual electrons are stabilized either at the [4Fe-4S] cluster (alkaline pH values) or at the diiron site (acidic pH values). This observation is discussed in the context of the complex interdependence of hydrogen turnover and bulk pH.

Published

2021

10. The roles of long-range proton-coupled electron transfer in the directionality and efficiency of [FeFe]-hydrogenases.

Author

Lampret O, Duan J, Hofmann E, Winkler M, Armstrong FA, and Happe T

Subjects

Chlamydomonas reinhardtii, Clostridium, Electron Transport, Hydrogenase genetics, Iron-Sulfur Proteins genetics, Mutagenesis, Site-Directed, Protons, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism

Abstract

As paradigms for proton-coupled electron transfer in enzymes and benchmarks for a fully renewable H 2 technology, [FeFe]-hydrogenases behave as highly reversible electrocatalysts when immobilized on an electrode, operating in both catalytic directions with minimal overpotential requirement. Using the [FeFe]-hydrogenases from Clostridium pasteurianum (CpI) and Chlamydomonas reinhardtii (CrHydA1) we have conducted site-directed mutagenesis and protein film electrochemistry to determine how efficient catalysis depends on the long-range coupling of electron and proton transfer steps. Importantly, the electron and proton transfer pathways in [FeFe]-hydrogenases are well separated from each other in space. Variants with conservative substitutions (glutamate to aspartate) in either of two positions in the proton-transfer pathway retain significant activity and reveal the consequences of slowing down proton transfer for both catalytic directions over a wide range of pH and potential values. Proton reduction in the variants is impaired mainly by limiting the turnover rate, which drops sharply as the pH is raised, showing that proton capture from bulk solvent becomes critical. In contrast, hydrogen oxidation is affected in two ways: by limiting the turnover rate and by a large overpotential requirement that increases as the pH is raised, consistent with the accumulation of a reduced and protonated intermediate. A unique observation having fundamental significance is made under conditions where the variants still retain sufficient catalytic activity in both directions: An inflection appears as the catalytic current switches direction at the 2H + /H 2 thermodynamic potential, clearly signaling a departure from electrocatalytic reversibility as electron and proton transfers begin to be decoupled., Competing Interests: The authors declare no competing interest.

Published

2020

11. How [FeFe]-Hydrogenase Facilitates Bidirectional Proton Transfer.

Author

Senger M, Eichmann V, Laun K, Duan J, Wittkamp F, Knör G, Apfel UP, Happe T, Winkler M, Heberle J, and Stripp ST

Subjects

Catalytic Domain, Chlamydomonas reinhardtii enzymology, Glutamic Acid chemistry, Hydrogen Bonding, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Protons, Serine chemistry, Spectroscopy, Fourier Transform Infrared, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry

Abstract

Hydrogenases are metalloenzymes that catalyze the conversion of protons and molecular hydrogen, H 2 . [FeFe]-hydrogenases show particularly high rates of hydrogen turnover and have inspired numerous compounds for biomimetic H 2 production. Two decades of research on the active site cofactor of [FeFe]-hydrogenases have put forward multiple models of the catalytic proceedings. In comparison, our understanding of proton transfer is poor. Previously, residues were identified forming a hydrogen-bonding network between active site cofactor and bulk solvent; however, the exact mechanism of catalytic proton transfer remained inconclusive. Here, we employ in situ infrared difference spectroscopy on the [FeFe]-hydrogenase from Chlamydomonas reinhardtii evaluating dynamic changes in the hydrogen-bonding network upon photoreduction. While proton transfer appears to be impaired in the oxidized state ( Hox ), the presented data support continuous proton transfer in the reduced state ( Hred ). Our analysis allows for a direct, molecular unique assignment to individual amino acid residues. We found that transient protonation changes of glutamic acid residue E141 and, most notably, arginine R148 facilitate bidirectional proton transfer in [FeFe]-hydrogenases.

Published

2019

12. The final steps of [FeFe]-hydrogenase maturation.

Author

Lampret O, Esselborn J, Haas R, Rutz A, Booth RL, Kertess L, Wittkamp F, Megarity CF, Armstrong FA, Winkler M, and Happe T

Subjects

Apoproteins chemistry, Apoproteins metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Clostridium enzymology, Electrochemistry, Holoenzymes chemistry, Holoenzymes metabolism, Hydrogen metabolism, Hydrogenase chemistry, Models, Molecular, Spectroscopy, Fourier Transform Infrared, Hydrogenase metabolism, Iron metabolism

Abstract

The active site (H-cluster) of [FeFe]-hydrogenases is a blueprint for the design of a biologically inspired H 2 -producing catalyst. The maturation process describes the preassembly and uptake of the unique [2Fe H ] cluster into apo-hydrogenase, which is to date not fully understood. In this study, we targeted individual amino acids by site-directed mutagenesis in the [FeFe]-hydrogenase CpI of Clostridium pasteurianum to reveal the final steps of H-cluster maturation occurring within apo-hydrogenase. We identified putative key positions for cofactor uptake and the subsequent structural reorganization that stabilizes the [2Fe H ] cofactor in its functional coordination sphere. Our results suggest that functional integration of the negatively charged [2Fe H ] precursor requires the positive charges and individual structural features of the 2 basic residues of arginine 449 and lysine 358, which mark the entrance and terminus of the maturation channel, respectively. The results obtained for 5 glycine-to-histidine exchange variants within a flexible loop region provide compelling evidence that the glycine residues function as hinge positions in the refolding process, which closes the secondary ligand sphere of the [2Fe H ] cofactor and the maturation channel. The conserved structural motifs investigated here shed light on the interplay between the secondary ligand sphere and catalytic cofactor., Competing Interests: The authors declare no conflict of interest.

Published

2019

13. His-Ligation to the [4Fe-4S] Subcluster Tunes the Catalytic Bias of [FeFe] Hydrogenase.

Author

Rodríguez-Maciá P, Kertess L, Burnik J, Birrell JA, Hofmann E, Lubitz W, Happe T, and Rüdiger O

Subjects

Catalytic Domain, Chlamydomonas reinhardtii enzymology, Hydrogenase genetics, Ligands, Models, Molecular, Mutagenesis, Site-Directed, Oxidation-Reduction, Biocatalysis, Hydrogenase chemistry, Hydrogenase metabolism, Iron metabolism, Sulfur metabolism

Abstract

[FeFe] hydrogenases interconvert H 2 into protons and electrons reversibly and efficiently. The active site H-cluster is composed of two sites: a unique [2Fe] subcluster ([2Fe] H ) covalently linked via cysteine to a canonical [4Fe-4S] cluster ([4Fe-4S] H ). Both sites are redox active and electron transfer is proton-coupled, such that the potential of the H-cluster lies very close to the H 2 thermodynamic potential, which confers the enzyme with the ability to operate quickly in both directions without energy losses. Here, one of the cysteines coordinating [4Fe-4S] H (Cys362) in the [FeFe] hydrogenase from the green algae Chlamydomonas reinhardtii ( CrHydA1) was exchanged with histidine and the resulting C362H variant was shown to contain a [4Fe-4S] cluster with a more positive redox potential than the wild-type. The change in the [4Fe-4S] cluster potential resulted in a shift of the catalytic bias, diminishing the H 2 production activity but giving significantly higher H 2 oxidation activity, albeit with a 200 mV overpotential requirement. These results highlight the importance of the [4Fe-4S] cluster as an electron injection site, modulating the redox potential and the catalytic properties of the H-cluster.

Published

2019

14. Crystallographic and spectroscopic assignment of the proton transfer pathway in [FeFe]-hydrogenases.

Author

Duan J, Senger M, Esselborn J, Engelbrecht V, Wittkamp F, Apfel UP, Hofmann E, Stripp ST, Happe T, and Winkler M

Subjects

Crystallography, X-Ray, Hydrogen metabolism, Hydrogen Bonding, Hydrogen-Ion Concentration, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Mutagenesis, Site-Directed, Mutant Proteins chemistry, Mutant Proteins metabolism, Spectrophotometry, Infrared, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Protons

Abstract

The unmatched catalytic turnover rates of [FeFe]-hydrogenases require an exceptionally efficient proton-transfer (PT) pathway to shuttle protons as substrates or products between bulk water and catalytic center. For clostridial [FeFe]-hydrogenase CpI such a pathway has been proposed and analyzed, but mainly on a theoretical basis. Here, eleven enzyme variants of two different [FeFe]-hydrogenases (CpI and HydA1) with substitutions in the presumptive PT-pathway are examined kinetically, spectroscopically, and crystallographically to provide solid experimental proof for its role in hydrogen-turnover. Targeting key residues of the PT-pathway by site directed mutagenesis significantly alters the pH-activity profile of these variants and in presence of H 2 their cofactor is trapped in an intermediate state indicative of precluded proton-transfer. Furthermore, crystal structures coherently explain the individual levels of residual activity, demonstrating e.g. how trapped H 2 O molecules rescue the interrupted PT-pathway. These features provide conclusive evidence that the targeted positions are indeed vital for catalytic proton-transfer.

Published

2018

15. Spectroscopical Investigations on the Redox Chemistry of [FeFe]-Hydrogenases in the Presence of Carbon Monoxide.

Author

Laun K, Mebs S, Duan J, Wittkamp F, Apfel UP, Happe T, Winkler M, Haumann M, and Stripp ST

Subjects

Catalysis, Crystallography, X-Ray, Hydrogen chemistry, Models, Molecular, Oxidation-Reduction, Spectroscopy, Fourier Transform Infrared, Carbon Monoxide chemistry, Hydrogenase chemistry, Iron chemistry

Abstract

[FeFe]-hydrogenases efficiently catalyzes hydrogen conversion at a unique [4Fe⁻4S]-[FeFe] cofactor, the so-called H-cluster. The catalytic reaction occurs at the diiron site, while the [4Fe⁻4S] cluster functions as a redox shuttle. In the oxidized resting state (Hox), the iron ions of the diiron site bind one cyanide (CN−) and carbon monoxide (CO) ligand each and a third carbonyl can be found in the Fe⁻Fe bridging position (µCO). In the presence of exogenous CO, A fourth CO ligand binds at the diiron site to form the oxidized, CO-inhibited H-cluster (Hox-CO). We investigated the reduced, CO-inhibited H-cluster (Hred´-CO) in this work. The stretching vibrations of the diatomic ligands were monitored by attenuated total reflection Fourier-transform infrared spectroscopy (ATR FTIR). Density functional theory (DFT) at the TPSSh/TZVP level was employed to analyze the cofactor geometry, as well as the redox and protonation state of the H-cluster. Selective 13CO isotope editing, spectro-electrochemistry, and correlation analysis of IR data identified a one-electron reduced, protonated [4Fe⁻4S] cluster and an apical CN− ligand at the diiron site in Hred´-CO. The reduced, CO-inhibited H-cluster forms independently of the sequence of CO binding and cofactor reduction, which implies that the ligand rearrangement at the diiron site upon CO inhibition is independent of the redox and protonation state of the [4Fe⁻4S] cluster. The relation of coordination dynamics to cofactor redox and protonation changes in hydrogen conversion catalysis and inhibition is discussed.

Published

2018

16. Rational redesign of the ferredoxin-NADP + -oxido-reductase/ferredoxin-interaction for photosynthesis-dependent H 2 -production.

Author

Wiegand K, Winkler M, Rumpel S, Kannchen D, Rexroth S, Hase T, Farès C, Happe T, Lubitz W, and Rögner M

Subjects

Binding Sites, Cloning, Molecular, Electron Transport, Escherichia coli genetics, Escherichia coli metabolism, Ferredoxin-NADP Reductase genetics, Ferredoxin-NADP Reductase metabolism, Ferredoxins genetics, Ferredoxins metabolism, Gene Expression, Hydrogenase genetics, Hydrogenase metabolism, Kinetics, Models, Molecular, Mutagenesis, Site-Directed, Oxidation-Reduction, Photosynthesis genetics, Photosystem I Protein Complex genetics, Photosystem I Protein Complex metabolism, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Synechocystis enzymology, Thermodynamics, Electrons, Ferredoxin-NADP Reductase chemistry, Ferredoxins chemistry, Hydrogen metabolism, Hydrogenase chemistry, Metabolic Engineering methods, Synechocystis genetics

Abstract

Utilization of electrons from the photosynthetic water splitting reaction for the generation of biofuels, commodities as well as application in biotransformations requires a partial rerouting of the photosynthetic electron transport chain. Due to its rather negative redox potential and its bifurcational function, ferredoxin at the acceptor side of Photosystem 1 is one of the focal points for such an engineering. With hydrogen production as model system, we show here the impact and potential of redox partner design involving ferredoxin (Fd), ferredoxin-oxido-reductase (FNR) and [FeFe]‑hydrogenase HydA1 on electron transport in a future cyanobacterial design cell of Synechocystis PCC 6803. X-ray-structure-based rational design and the allocation of specific interaction residues by NMR-analysis led to the construction of Fd- and FNR-mutants, which in appropriate combination enabled an about 18-fold enhanced electron flow from Fd to HydA1 (in competition with equimolar amounts of FNR) in in vitro assays. The negative impact of these mutations on the Fd-FNR electron transport which indirectly facilitates H 2 production (with a contribution of ≤42% by FNR variants and ≤23% by Fd-variants) and the direct positive impact on the Fd-HydA1 electron transport (≤23% by Fd-mutants) provide an excellent basis for the construction of a hydrogen-producing design cell and the study of photosynthetic efficiency-optimization with cyanobacteria., (Copyright © 2018. Published by Elsevier B.V.)

Published

2018

17. Protonation/reduction dynamics at the [4Fe-4S] cluster of the hydrogen-forming cofactor in [FeFe]-hydrogenases.

Author

Senger M, Mebs S, Duan J, Shulenina O, Laun K, Kertess L, Wittkamp F, Apfel UP, Happe T, Winkler M, Haumann M, and Stripp ST

Subjects

Biocatalysis, Carbon Monoxide chemistry, Carbon Monoxide metabolism, Catalytic Domain, Chlamydomonas reinhardtii enzymology, Coenzymes chemistry, Coenzymes metabolism, Cyanides chemistry, Cyanides metabolism, Electron Transport, Hydrogen chemistry, Hydrogen-Ion Concentration, Hydrogenase chemistry, Hydrogenase genetics, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins genetics, Ligands, Oxidation-Reduction, Protein Binding, Protons, Quantum Theory, Recombinant Proteins biosynthesis, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Spectroscopy, Fourier Transform Infrared, Hydrogen metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism

Abstract

The [FeFe]-hydrogenases of bacteria and algae are the most efficient hydrogen conversion catalysts in nature. Their active-site cofactor (H-cluster) comprises a [4Fe-4S] cluster linked to a unique diiron site that binds three carbon monoxide (CO) and two cyanide (CN - ) ligands. Understanding microbial hydrogen conversion requires elucidation of the interplay of proton and electron transfer events at the H-cluster. We performed real-time spectroscopy on [FeFe]-hydrogenase protein films under controlled variation of atmospheric gas composition, sample pH, and reductant concentration. Attenuated total reflection Fourier-transform infrared spectroscopy was used to monitor shifts of the CO/CN - vibrational bands in response to redox and protonation changes. Three different [FeFe]-hydrogenases and several protein and cofactor variants were compared, including element and isotopic exchange studies. A protonated equivalent (HoxH) of the oxidized state (Hox) was found, which preferentially accumulated at acidic pH and under reducing conditions. We show that the one-electron reduced state Hred' represents an intrinsically protonated species. Interestingly, the formation of HoxH and Hred' was independent of the established proton pathway to the diiron site. Quantum chemical calculations of the respective CO/CN - infrared band patterns favored a cysteine ligand of the [4Fe-4S] cluster as the protonation site in HoxH and Hred'. We propose that proton-coupled electron transfer facilitates reduction of the [4Fe-4S] cluster and prevents premature formation of a hydride at the catalytic diiron site. Our findings imply that protonation events both at the [4Fe-4S] cluster and at the diiron site of the H-cluster are important in the hydrogen conversion reaction of [FeFe]-hydrogenases.

Published

2018

18. Hydrogen and oxygen trapping at the H-cluster of [FeFe]-hydrogenase revealed by site-selective spectroscopy and QM/MM calculations.

Author

Mebs S, Kositzki R, Duan J, Kertess L, Senger M, Wittkamp F, Apfel UP, Happe T, Stripp ST, Winkler M, and Haumann M

Subjects

Catalytic Domain, Chlamydomonas reinhardtii enzymology, Hydrogen chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Oxygen chemistry, Plant Proteins chemistry

Abstract

[FeFe]-hydrogenases are superior hydrogen conversion catalysts. They bind a cofactor (H-cluster) comprising a four-iron and a diiron unit with three carbon monoxide (CO) and two cyanide (CN - ) ligands. Hydrogen (H 2 ) and oxygen (O 2 ) binding at the H-cluster was studied in the C169A variant of [FeFe]-hydrogenase HYDA1, in comparison to the active oxidized (Hox) and CO-inhibited (Hox-CO) species in wildtype enzyme. 57 Fe labeling of the diiron site was achieved by in vitro maturation with a synthetic cofactor analogue. Site-selective X-ray absorption, emission, and nuclear inelastic/forward scattering methods and infrared spectroscopy were combined with quantum chemical calculations to determine the molecular and electronic structure and vibrational dynamics of detected cofactor species. Hox reveals an apical vacancy at Fe d in a [4Fe4S-2Fe] 3- complex with the net spin on Fe d whereas Hox-CO shows an apical CN - at Fe d in a [4Fe4S-2Fe(CO)] 3- complex with net spin sharing among Fe p and Fe d (proximal or distal iron ions in [2Fe]). At ambient O 2 pressure, a novel H-cluster species (Hox-O 2 ) accumulated in C169A, assigned to a [4Fe4S-2Fe(O 2 )] 3- complex with an apical superoxide (O 2 - ) carrying the net spin bound at Fe d . H 2 exposure populated the two-electron reduced Hhyd species in C169A, assigned as a [(H)4Fe4S-2Fe(H)] 3- complex with the net spin on the reduced cubane, an apical hydride at Fe d , and a proton at a cysteine ligand. Hox-O 2 and Hhyd are stabilized by impaired O 2 - protonation or proton release after H 2 cleavage due to interruption of the proton path towards and out of the active site., (Copyright © 2017. Published by Elsevier B.V.)

Published

2018

19. [FeFe]-hydrogenases from green algae.

Author

Engelbrecht V and Happe T

Subjects

Hydrogen metabolism, Hydrogenase chemistry, Chlorophyta enzymology, Hydrogenase isolation & purification, Hydrogenase metabolism

Abstract

Algal hydrogenases are among to the most efficient hydrogen (H 2 ) generating biocatalysts and use low-potential electrons from the photosynthetic light reactions. Thereby, photobiological H 2 evolution by eukaryotic microalgae represents a sustainable alternative to the energy intensive industrial production of H 2 based on fossil fuels. Novel algal hydrogenases are still being discovered and their biochemical and biophysical characterization has revealed unique features beneficial to overcome bottlenecks in photobiological H 2 production. Highly advanced techniques are available to study hydrogenases to atomic level accuracy. Yet, to benefit from these methods, one has to overcome the first and most fundamental obstacle, namely, obtaining sufficient amounts of active hydrogenase enzyme. The recombinant production of hydrogenases can be very challenging, so this chapter provides information and useful advice for the discovery, heterologous production, and analyses of hydrogenases from microalgae., (© 2018 Elsevier Inc. All rights reserved.)

Published

2018

20. Interplay between CN - Ligands and the Secondary Coordination Sphere of the H-Cluster in [FeFe]-Hydrogenases.

Author

Lampret O, Adamska-Venkatesh A, Konegger H, Wittkamp F, Apfel UP, Reijerse EJ, Lubitz W, Rüdiger O, Happe T, and Winkler M

Subjects

Genomic Structural Variation, Iron-Sulfur Proteins genetics, Ligands, Models, Molecular, Spectroscopy, Fourier Transform Infrared, Hydrogen chemistry, Hydrogenase chemistry, Iron chemistry, Iron-Sulfur Proteins chemistry, Nitrogen chemistry

Abstract

The catalytic cofactor of [FeFe]-hydrogenses (H-cluster) is composed of a generic cubane [4Fe-4S]-cluster (4Fe H ) linked to a binuclear iron-sulfur cluster (2Fe H ) that has an open coordination site at which the reversible conversion of protons to molecular hydrogen occurs. The (2Fe H ) subsite features a diatomic coordination sphere composed of three CO and two CN - ligands affecting its redox properties and providing excellent probes for FTIR spectroscopy. The CO stretch vibrations are very sensitive to the redox changes within the H-cluster occurring during the catalytic cycle, whereas the CN - signals seem to be relatively inert to these effects. This could be due to the more structural role of the CN - ligands tightly anchoring the (2Fe H ) unit to the protein environment through hydrogen bonding. In this work we explore the effects of structural changes within the secondary ligand sphere affecting the CN - ligands on FTIR spectroscopy and catalysis. By comparing the FTIR spectra of wild-type enzyme and two mutagenesis variants, we are able to assign the IR signals of the individual CN - ligands of the (2Fe H ) site for different redox states of the H-cluster. Moreover, protein film electrochemistry reveals that targeted manipulation of the secondary coordination sphere of the proximal CN - ligand (i.e., closest to the (4Fe H ) site) can affect the catalytic bias. These findings highlight the importance of the protein environment for re-adjusting the catalytic features of the H-cluster in individual enzymes and provide valuable information for the design of artificial hydrogenase mimics.

Published

2017

21. Chalcogenide substitution in the [2Fe] cluster of [FeFe]-hydrogenases conserves high enzymatic activity.

Author

Kertess L, Wittkamp F, Sommer C, Esselborn J, Rüdiger O, Reijerse EJ, Hofmann E, Lubitz W, Winkler M, Happe T, and Apfel UP

Subjects

Catalytic Domain, Clostridium enzymology, Electrochemistry, Electrons, Models, Molecular, Oxygen metabolism, Hydrogenase chemistry, Hydrogenase metabolism, Iron, Selenium chemistry

Abstract

[FeFe]-Hydrogenases efficiently catalyze the uptake and evolution of H 2 due to the presence of an inorganic [6Fe-6S]-cofactor (H-cluster). This cofactor is comprised of a [4Fe-4S] cluster coupled to a unique [2Fe] cluster where the catalytic turnover of H 2 /H + takes place. We herein report on the synthesis of a selenium substituted [2Fe] cluster [Fe 2 {μ(SeCH 2 ) 2 NH}(CO) 4 (CN) 2 ] 2- (ADSe) and its successful in vitro integration into the native protein scaffold of [FeFe]-hydrogenases HydA1 from Chlamydomonas reinhardtii and CpI from Clostridium pasteurianum yielding fully active enzymes (HydA1-ADSe and CpI-ADSe). FT-IR spectroscopy and X-ray structure analysis confirmed the presence of structurally intact ADSe at the active site. Electrochemical assays reveal that the selenium containing enzymes are more biased towards hydrogen production than their native counterparts. In contrast to previous chalcogenide exchange studies, the S to Se exchange herein is not based on a simple reconstitution approach using ionic cluster constituents but on the in vitro maturation with a pre-synthesized selenium-containing [2Fe] mimic. The combination of biological and chemical methods allowed for the creation of a novel [FeFe]-hydrogenase with a [2Fe2Se]-active site which confers individual catalytic features.

Published

2017

22. Bridging Hydride at Reduced H-Cluster Species in [FeFe]-Hydrogenases Revealed by Infrared Spectroscopy, Isotope Editing, and Quantum Chemistry.

Author

Mebs S, Senger M, Duan J, Wittkamp F, Apfel UP, Happe T, Winkler M, Stripp ST, and Haumann M

Subjects

Hydrogen chemistry, Molecular Structure, Hydrogenase chemistry, Iron chemistry, Isotopes chemistry, Quantum Theory, Spectrophotometry, Infrared methods

Abstract

[FeFe]-Hydrogenases contain a H 2 -converting cofactor (H-cluster) in which a canonical [4Fe-4S] cluster is linked to a unique diiron site with three carbon monoxide (CO) and two cyanide (CN - ) ligands (e.g., in the oxidized state, Hox). There has been much debate whether reduction and hydrogen binding may result in alternative rotamer structures of the diiron site in a single (Hred) or double (Hsred) reduced H-cluster species. We employed infrared spectro-electrochemistry and site-selective isotope editing to monitor the CO/CN - stretching vibrations in [FeFe]-hydrogenase HYDA1 from Chlamydomonas reinhardtii. Density functional theory calculations yielded vibrational modes of the diatomic ligands for conceivable H-cluster structures. Correlation analysis of experimental and computational IR spectra has facilitated an assignment of Hred and Hsred to structures with a bridging hydride at the diiron site. Pronounced ligand rotation during μH binding seems to exclude Hred and Hsred as catalytic intermediates. Only states with a conservative H-cluster geometry featuring a μCO ligand are likely involved in rapid H 2 turnover.

Published

2017

23. The structurally unique photosynthetic Chlorella variabilis NC64A hydrogenase does not interact with plant-type ferredoxins.

Author

Engelbrecht V, Rodríguez-Maciá P, Esselborn J, Sawyer A, Hemschemeier A, Rüdiger O, Lubitz W, Winkler M, and Happe T

Subjects

Algal Proteins chemistry, Algal Proteins isolation & purification, Amino Acid Sequence, Carbon Monoxide pharmacology, Chlamydomonas reinhardtii chemistry, Chlorella radiation effects, Electrochemical Techniques, Electron Transport, Hydrogen metabolism, Hydrogenase antagonists & inhibitors, Hydrogenase chemistry, Hydrogenase isolation & purification, Iron-Sulfur Proteins antagonists & inhibitors, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins isolation & purification, Light, Models, Molecular, Oxidation-Reduction, Oxygen pharmacology, Photosynthesis, Protein Conformation, Recombinant Proteins metabolism, Sequence Alignment, Sequence Homology, Amino Acid, Sulfur metabolism, Algal Proteins metabolism, Chlorella enzymology, Ferredoxins metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Plant Proteins metabolism

Abstract

Hydrogenases from green algae are linked to the photosynthetic electron transfer chain via the plant-type ferredoxin PetF. In this work the [FeFe]-hydrogenase from the Trebouxiophycean alga Chlorella variabilis NC64A (CvHydA1), which in contrast to other green algal hydrogenases contains additional FeS-cluster binding domains, was purified and specific enzyme activities for both hydrogen (H 2 ) production and H 2 oxidation were determined. Interestingly, although C. variabilis NC64A, like many Chlorophycean algal strains, exhibited light-dependent H 2 production activity upon sulfur deprivation, CvHydA1 did not interact in vitro with several plant-type [2Fe-2S]-ferredoxins, but only with a bacterial2[4Fe4S]-ferredoxin. In an electrochemical characterization, the enzyme exhibited features typical of bacterial [FeFe]-hydrogenases (e.g. minor anaerobic oxidative inactivation), as well as of algal enzymes (very high oxygen sensitivity)., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2017

24. Accumulating the hydride state in the catalytic cycle of [FeFe]-hydrogenases.

Author

Winkler M, Senger M, Duan J, Esselborn J, Wittkamp F, Hofmann E, Apfel UP, Stripp ST, and Happe T

Subjects

Catalysis, Escherichia coli, Spectroscopy, Fourier Transform Infrared, Hydrogen metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism

Abstract

H 2 turnover at the [FeFe]-hydrogenase cofactor (H-cluster) is assumed to follow a reversible heterolytic mechanism, first yielding a proton and a hydrido-species which again is double-oxidized to release another proton. Three of the four presumed catalytic intermediates (H ox , H red /H red and H sred ) were characterized, using various spectroscopic techniques. However, in catalytically active enzyme, the state containing the hydrido-species, which is eponymous for the proposed heterolytic mechanism, has yet only been speculated about. We use different strategies to trap and spectroscopically characterize this transient hydride state (H hyd ) for three wild-type [FeFe]-hydrogenases. Applying a novel set-up for real-time attenuated total-reflection Fourier-transform infrared spectroscopy, we monitor compositional changes in the state-specific infrared signatures of [FeFe]-hydrogenases, varying buffer pH and gas composition. We selectively enrich the equilibrium concentration of H hyd , applying Le Chatelier's principle by simultaneously increasing substrate and product concentrations (H 2 /H + ). Site-directed manipulation, targeting either the proton-transfer pathway or the adt ligand, significantly enhances H hyd accumulation independent of pH.

Published

2017

25. Compartmentalisation of [FeFe]-hydrogenase maturation in Chlamydomonas reinhardtii.

Author

Sawyer A, Bai Y, Lu Y, Hemschemeier A, and Happe T

Subjects

Chlamydomonas reinhardtii genetics, Chloroplasts metabolism, Hydrogenase genetics, Iron-Sulfur Proteins genetics, Plant Proteins genetics, Chlamydomonas reinhardtii enzymology, Chlamydomonas reinhardtii metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Plant Proteins metabolism

Abstract

Molecular hydrogen (H 2 ) can be produced in green microalgae by [FeFe]-hydrogenases as a direct product of photosynthesis. The Chlamydomonas reinhardtii hydrogenase HYDA1 contains a catalytic site comprising a classic [4Fe4S] cluster linked to a unique 2Fe sub-cluster. From in vitro studies it appears that the [4Fe4S] cluster is incorporated first by the housekeeping FeS cluster assembly machinery, followed by the 2Fe sub-cluster, whose biosynthesis requires the specific maturases HYDEF and HYDG. To investigate the maturation process in vivo, we expressed HYDA1 from the C. reinhardtii chloroplast and nuclear genomes (with and without a chloroplast transit peptide) in a hydrogenase-deficient mutant strain, and examined the cellular enzymatic hydrogenase activity, as well as in vivo H 2 production. The transformants expressing HYDA1 from the chloroplast genome displayed levels of H 2 production comparable to the wild type, as did the transformants expressing full-length HYDA1 from the nuclear genome. In contrast, cells equipped with cytoplasm-targeted HYDA1 produced inactive enzyme, which could only be activated in vitro after reconstitution of the [4Fe4S] cluster. This indicates that the HYDA1 FeS cluster can only be built by the chloroplastic FeS cluster assembly machinery. Further, the expression of a bacterial hydrogenase gene, CPI, from the C. reinhardtii chloroplast genome resulted in H 2 -producing strains, demonstrating that a hydrogenase with a very different structure can fulfil the role of HYDA1 in vivo and that overexpression of foreign hydrogenases in C. reinhardtii is possible. All chloroplast transformants were stable and no toxic effects were seen from HYDA1 or CPI expression., (© 2017 The Authors The Plant Journal © 2017 John Wiley & Sons Ltd.)

Published

2017

26. Frequency and potential dependence of reversible electrocatalytic hydrogen interconversion by [FeFe]-hydrogenases.

Author

Pandey K, Islam ST, Happe T, and Armstrong FA

Subjects

Catalysis, Catalytic Domain, Chlamydomonas reinhardtii enzymology, Clostridium enzymology, Electron Spin Resonance Spectroscopy, Electron Transport, Kinetics, Models, Molecular, Protein Conformation, Hydrogen chemistry, Hydrogenase metabolism

Abstract

The kinetics of hydrogen oxidation and evolution by [FeFe]-hydrogenases have been investigated by electrochemical impedance spectroscopy-resolving factors that determine the exceptional activity of these enzymes, and introducing an unusual and powerful way of analyzing their catalytic electron transport properties. Attached to an electrode, hydrogenases display reversible electrocatalytic behavior close to the 2H + /H 2 potential, making them paradigms for efficiency: the electrocatalytic "exchange" rate (measured around zero driving force) is therefore an unusual parameter with theoretical and practical significance. Experiments were carried out on two [FeFe]-hydrogenases, Cr HydA1 from the green alga Chlamydomonas reinhardtii , which contains only the active-site "H cluster," and Cp I from the fermentative anaerobe Clostridium pasteurianum , which contains four low-potential FeS clusters that serve as an electron relay in addition to the H cluster. Data analysis yields catalytic exchange rates (at the formal 2H + /H 2 potential, at 0 °C) of 157 electrons (78 molecules H 2 ) per second for Cp I and 25 electrons (12 molecules H 2 ) per second for Cr HydA1. The experiments show how the potential dependence of catalytic electron flow comprises frequency-dependent and frequency-independent terms that reflect the proficiencies of the catalytic site and the electron transfer pathway in each enzyme. The results highlight the "wire-like" behavior of the Fe-S electron relay in Cp I and a low reorganization energy for electron transfer on/off the H cluster.

Published

2017

27. Sunlight-Dependent Hydrogen Production by Photosensitizer/Hydrogenase Systems.

Author

Adam D, Bösche L, Castañeda-Losada L, Winkler M, Apfel UP, and Happe T

Subjects

Chlamydomonas reinhardtii enzymology, Electron Transport, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Kinetics, Models, Molecular, Protein Conformation, Hydrogen metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Photosensitizing Agents metabolism, Sunlight

Abstract

We report a sustainable in vitro system for enzyme-based photohydrogen production. The [FeFe]-hydrogenase HydA1 from Chlamydomonas reinhardtii was tested for photohydrogen production as a proton-reducing catalyst in combination with eight different photosensitizers. Using the organic dye 5-carboxyeosin as a photosensitizer and plant-type ferredoxin PetF as an electron mediator, HydA1 achieves the highest light-driven turnover number (TON HydA1 ) yet reported for an enzyme-based in vitro system (2.9×10 6  mol(H 2 ) mol(cat) -1 ) and a maximum turnover frequency (TOF HydA1 ) of 550 mol(H 2 ) mol(HydA1) -1  s -1 . The system is fueled very effectively by ambient daylight and can be further simplified by using 5-carboxyeosin and HydA1 as a two-component photosensitizer/biocatalyst system without an additional redox mediator., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017

28. Electrochemical Investigations of the Mechanism of Assembly of the Active-Site H-Cluster of [FeFe]-Hydrogenases.

Author

Megarity CF, Esselborn J, Hexter SV, Wittkamp F, Apfel UP, Happe T, and Armstrong FA

Subjects

Catalytic Domain, Chlamydomonas reinhardtii enzymology, Electrochemical Techniques, Hydrogenase chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism

Abstract

Protein film electrochemistry (PFE) has been used to study the assembly of the complex 6Fe active site of [FeFe]-hydrogenases (known as the H-cluster) from its precursors-the [4Fe-4S] domain that is already coordinated within the host, and the 2Fe domain that is presented as a synthetic water-soluble complex stabilized by an additional CO. Not only does PFE allow control of redox states via the electrode potential but also the immobilized state of the enzyme facilitates control of extremely low concentrations of the 2Fe complex. Results for two enzymes, CrHydA1 from Chlamydomonas reinhardtii and CpI from Clostridium pasteurianum, are very similar, despite large differences in size and structure. Assembly begins with very tight binding of the 34-valence electron 2Fe complex to the apo-[4Fe-4S] enzyme, well before the rate-determining step. The precursor is trapped under highly reducing conditions (<-0.5 V vs SHE) that prevent fusion of the [4Fe-4S] and 2Fe domains (via cysteine-S) since the immediate product would be too electron-rich. Relaxing this condition allows conversion to the active H-cluster. The intramolecular steps are relevant to the final stage of biological H-cluster maturation.

Published

2016

29. A redox hydrogel protects the O2 -sensitive [FeFe]-hydrogenase from Chlamydomonas reinhardtii from oxidative damage.

Author

Oughli AA, Conzuelo F, Winkler M, Happe T, Lubitz W, Schuhmann W, Rüdiger O, and Plumeré N

Subjects

Hydrogel, Polyethylene Glycol Dimethacrylate chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Models, Molecular, Molecular Structure, Oxidation-Reduction, Oxygen chemistry, Chlamydomonas reinhardtii enzymology, Hydrogel, Polyethylene Glycol Dimethacrylate metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Oxygen metabolism

Abstract

The integration of sensitive catalysts in redox matrices opens up the possibility for their protection from deactivating molecules such as O2 . [FeFe]-hydrogenases are enzymes catalyzing H2 oxidation/production which are irreversibly deactivated by O2 . Therefore, their use under aerobic conditions has never been achieved. Integration of such hydrogenases in viologen-modified hydrogel films allows the enzyme to maintain catalytic current for H2 oxidation in the presence of O2 , demonstrating a protection mechanism independent of reactivation processes. Within the hydrogel, electrons from the hydrogenase-catalyzed H2 oxidation are shuttled to the hydrogel-solution interface for O2 reduction. Hence, the harmful O2 molecules do not reach the hydrogenase. We illustrate the potential applications of this protection concept with a biofuel cell under H2 /O2 mixed feed., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

30. Lyophilization protects [FeFe]-hydrogenases against O2-induced H-cluster degradation.

Author

Noth J, Kositzki R, Klein K, Winkler M, Haumann M, and Happe T

Subjects

Catalytic Domain, Clostridium enzymology, Freeze Drying, Hydrogen metabolism, Hydrogenase chemistry, Hydrogenase genetics, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins genetics, Recombinant Proteins biosynthesis, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Solutions chemistry, X-Ray Absorption Spectroscopy, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Oxygen chemistry

Abstract

Nature has developed an impressive repertoire of metal-based enzymes that perform complex chemical reactions under moderate conditions. Catalysts that produce molecular hydrogen (H2) are particularly promising for renewable energy applications. Unfortunately, natural and chemical H2-catalysts are often irreversibly degraded by molecular oxygen (O2). Here we present a straightforward procedure based on freeze-drying (lyophilization), that turns [FeFe]-hydrogenases, which are excellent H2-producers, but typically extremely O2-sensitive in solution, into enzymes that are fully resistant against O2. Complete dryness protects and conserves both, the [FeFe]-hydrogenase proteins and their inorganic active-site cofactor (H-cluster), when exposed to 100% O2 for days. The full H2-formation capacity is restored after solvation of the lyophilized enzymes. However, even minimal moisturizing re-establishes O2-sensitivity. The dry [FeFe]-hydrogenase material is superior also for advanced spectroscopic investigations on the H-cluster reaction mechanism. Our method provides a convenient way for long-term storage and impacts on potential biotechnological hydrogen production applications of hydrogenase enzymes.

Published

2015

31. How Formaldehyde Inhibits Hydrogen Evolution by [FeFe]-Hydrogenases: Determination by ¹³C ENDOR of Direct Fe-C Coordination and Order of Electron and Proton Transfers.

Author

Bachmeier A, Esselborn J, Hexter SV, Krämer T, Klein K, Happe T, McGrady JE, Myers WK, and Armstrong FA

Subjects

Chlamydomonas reinhardtii chemistry, Chlamydomonas reinhardtii metabolism, Electron Spin Resonance Spectroscopy, Hydrogenase chemistry, Hydrogenase metabolism, Models, Molecular, Protons, Quantum Theory, Chlamydomonas reinhardtii enzymology, Enzyme Inhibitors pharmacology, Formaldehyde pharmacology, Hydrogen metabolism, Hydrogenase antagonists & inhibitors

Abstract

Formaldehyde (HCHO), a strong electrophile and a rapid and reversible inhibitor of hydrogen production by [FeFe]-hydrogenases, is used to identify the point in the catalytic cycle at which a highly reactive metal-hydrido species is formed. Investigations of the reaction of Chlamydomonas reinhardtii [FeFe]-hydrogenase with formaldehyde using pulsed-EPR techniques including electron-nuclear double resonance spectroscopy establish that formaldehyde binds close to the active site. Density functional theory calculations support an inhibited super-reduced state having a short Fe-(13)C bond in the 2Fe subsite. The adduct forms when HCHO is available to compete with H(+) transfer to a vacant, nucleophilic Fe site: had H(+) transfer already occurred, the reaction of HCHO with the Fe-hydrido species would lead to methanol, release of which is not detected. Instead, Fe-bound formaldehyde is a metal-hydrido mimic, a locked, inhibited form analogous to that in which two electrons and only one proton have transferred to the H-cluster. The results provide strong support for a mechanism in which the fastest pathway for H2 evolution involves two consecutive proton transfer steps to the H-cluster following transfer of a second electron to the active site.

Published

2015

32. Hydride binding to the active site of [FeFe]-hydrogenase.

Author

Chernev P, Lambertz C, Brünje A, Leidel N, Sigfridsson KG, Kositzki R, Hsieh CH, Yao S, Schiwon R, Driess M, Limberg C, Happe T, and Haumann M

Subjects

Binding Sites, Carbon Monoxide chemistry, Catalytic Domain, Cyanides chemistry, Hydrogenase genetics, Iron-Sulfur Proteins genetics, Models, Molecular, Oxidation-Reduction, Protein Binding, X-Ray Absorption Spectroscopy, Chlamydomonas reinhardtii enzymology, Ferrous Compounds chemistry, Hydrogen chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry

Abstract

[FeFe]-hydrogenase from green algae (HydA1) is the most efficient hydrogen (H2) producing enzyme in nature and of prime interest for (bio)technology. Its active site is a unique six-iron center (H-cluster) composed of a cubane cluster, [4Fe4S]H, cysteine-linked to a diiron unit, [2Fe]H, which carries unusual carbon monoxide (CO) and cyanide ligands and a bridging azadithiolate group. We have probed the molecular and electronic configurations of the H-cluster in functional oxidized, reduced, and super-reduced or CO-inhibited HydA1 protein, in particular searching for intermediates with iron-hydride bonds. Site-selective X-ray absorption and emission spectroscopy were used to distinguish between low- and high-spin iron sites in the two subcomplexes of the H-cluster. The experimental methods and spectral simulations were calibrated using synthetic model complexes with ligand variations and bound hydride species. Distinct X-ray spectroscopic signatures of electronic excitation or decay transitions in [4Fe4S]H and [2Fe]H were obtained, which were quantitatively reproduced by density functional theory calculations, thereby leading to specific H-cluster model structures. We show that iron-hydride bonds are absent in the reduced state, whereas only in the super-reduced state, ligand rotation facilitates hydride binding presumably to the Fe-Fe bridging position at [2Fe]H. These results are in agreement with a catalytic cycle involving three main intermediates and at least two protonation and electron transfer steps prior to the H2 formation chemistry in [FeFe]-hydrogenases.

Published

2014

33. New redox states observed in [FeFe] hydrogenases reveal redox coupling within the H-cluster.

Author

Adamska-Venkatesh A, Krawietz D, Siebel J, Weber K, Happe T, Reijerse E, and Lubitz W

Subjects

Amines chemistry, Catalysis, Catalytic Domain, Chlamydomonas reinhardtii enzymology, Cluster Analysis, Cysteine chemistry, Electrochemistry, Electron Spin Resonance Spectroscopy, Escherichia coli enzymology, Ligands, Protons, Spectroscopy, Fourier Transform Infrared, Hydrogen chemistry, Hydrogenase chemistry, Iron chemistry, Oxidation-Reduction

Abstract

Active [FeFe] hydrogenases can be obtained by expressing the unmaturated enzyme in Escherichia coli followed by incubation with a synthetic precursor of the binuclear [2Fe] subcluster, namely: [NEt4]2[Fe2(adt)(CO)4(CN)2] (adt = [S-CH2-NH-CH2-S](2-)). The binuclear subsite Fe2(adt)(CO)3(CN)2 is attached through a bridging cysteine side chain to a [4Fe-4S] subcluster already present in the unmaturated enzyme thus yielding the intact native "H-cluster". We present FTIR electrochemical studies of the [FeFe] hydrogenase from Chlamydomonas reinhardtii, CrHydA1, maturated with the precursor of the native cofactor [Fe2(adt)(CO)4(CN)2](2-) as well as a non-natural variant [Fe2(pdt)(CO)4(CN)2](2-) in which the bridging amine functionality is replaced by CH2. The obtained active enzyme CrHydA1(adt) shows the same redox states in the respective potential range as observed for the native system (E(ox/red) = -400 mV, E(red/sred) = -470 mV). For the Hox → Hred transition the reducing equivalent is stored on the binuclear part, ([4Fe-4S](2+)Fe(II)Fe(I) → [4Fe-4S](2+)Fe(I)Fe(I)), while the Hred → Hsred transition is characterized by a reduction of the [4Fe-4S] part of the H-cluster ([4Fe-4S](2+)Fe(I)Fe(I) → [4Fe-4S](+)Fe(I)Fe(I)). A similar transition is reported here for the CO inhibited state of the H-cluster: ([4Fe-4S](2+)Fe(I)Fe(II)CO → [4Fe-4S](+)Fe(I)Fe(II)CO). An FTIR electrochemical study of the inactive variant with the pdt ligand, CrHydA1(pdt), identified two redox states H(pdt)-ox and H(pdt)-"red". Both EPR and FTIR spectra of H(pdt)-ox are virtually identical to those of the H(adt)-ox and the native Hox state. The H(pdt)-"red" state is also characterized by a reduced [4Fe-4S] subcluster. In contrast to CrHydA1(adt), the H(pdt)-ox state of CrHydA1(pdt) is stable up to rather high potentials (+200 mV). This study demonstrates the distinct redox coupling between the two parts of the H-cluster and confirms that the [4Fe-4S]H subsite is also redox active and as such an integral part of the H-cluster taking part in the catalytic cycle.

Published

2014

34. Spontaneous activation of [FeFe]-hydrogenases by an inorganic [2Fe] active site mimic.

Author

Esselborn J, Lambertz C, Adamska-Venkates A, Simmons T, Berggren G, Noth J, Siebel J, Hemschemeier A, Artero V, Reijerse E, Fontecave M, Lubitz W, and Happe T

Subjects

Apoenzymes agonists, Apoenzymes chemistry, Apoenzymes metabolism, Biocatalysis drug effects, Catalytic Domain drug effects, Coenzymes metabolism, Enzyme Activation drug effects, Hydrogen chemistry, Iron chemistry, Iron-Sulfur Proteins agonists, Models, Molecular, Coenzymes pharmacology, Hydrogen metabolism, Hydrogenase metabolism, Iron metabolism, Iron-Sulfur Proteins metabolism

Abstract

Hydrogenases catalyze the formation of hydrogen. The cofactor ('H-cluster') of [FeFe]-hydrogenases consists of a [4Fe-4S] cluster bridged to a unique [2Fe] subcluster whose biosynthesis in vivo requires hydrogenase-specific maturases. Here we show that a chemical mimic of the [2Fe] subcluster can reconstitute apo-hydrogenase to full activity, independent of helper proteins. The assembled H-cluster is virtually indistinguishable from the native cofactor. This procedure will be a powerful tool for developing new artificial H₂-producing catalysts.

Published

2013

35. Molecular basis of [FeFe]-hydrogenase function: an insight into the complex interplay between protein and catalytic cofactor.

Author

Winkler M, Esselborn J, and Happe T

Subjects

Amino Acid Sequence, Biocatalysis, Electron Transport, Hydrogenase chemistry, Hydrogenase genetics, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins genetics, Models, Molecular, Molecular Sequence Data, Phylogeny, Sequence Homology, Amino Acid, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism

Abstract

The precise electrochemical features of metal cofactors that convey the functions of redox enzymes are essentially determined by the specific interaction pattern between cofactor and enclosing protein environment. However, while biophysical techniques allow a detailed understanding of the features characterizing the cofactor itself, knowledge about the contribution of the protein part is much harder to obtain. [FeFe]-hydrogenases are an interesting class of enzymes that catalyze both, H2 oxidation and the reduction of protons to molecular hydrogen with significant efficiency. The active site of these proteins consists of an unusual prosthetic group (H-cluster) with six iron and six sulfur atoms. While H-cluster architecture and catalytic states during the different steps of H2 turnover have been thoroughly investigated during the last 20 years, possible functional contributions from the polypeptide framework were only assumed according to the level of conservancy and X-ray structure analyses. Due to the recent development of simpler and more efficient expression systems the role of single amino acids can now be experimentally investigated. This article summarizes, compares and categorizes the results of recent investigations based on site directed and random mutagenesis according to their informative value about structure function relationships in [FeFe]-hydrogenases. This article is part of a Special Issue entitled: Metals in Bioenergetics and Biomimetics Systems., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published

2013

36. Biomimetic assembly and activation of [FeFe]-hydrogenases.

Author

Berggren G, Adamska A, Lambertz C, Simmons TR, Esselborn J, Atta M, Gambarelli S, Mouesca JM, Reijerse E, Lubitz W, Happe T, Artero V, and Fontecave M

Subjects

Apoproteins chemistry, Apoproteins metabolism, Biocatalysis, Biomimetics, Catalytic Domain, Clostridium acetobutylicum genetics, Clostridium acetobutylicum metabolism, Electron Spin Resonance Spectroscopy, Enzyme Activation, Ligands, Spectroscopy, Fourier Transform Infrared, Biomimetic Materials chemical synthesis, Biomimetic Materials metabolism, Chlamydomonas reinhardtii enzymology, Hydrogenase metabolism, Thermotoga maritima enzymology

Abstract

Hydrogenases are the most active molecular catalysts for hydrogen production and uptake, and could therefore facilitate the development of new types of fuel cell. In [FeFe]-hydrogenases, catalysis takes place at a unique di-iron centre (the [2Fe] subsite), which contains a bridging dithiolate ligand, three CO ligands and two CN(-) ligands. Through a complex multienzymatic biosynthetic process, this [2Fe] subsite is first assembled on a maturation enzyme, HydF, and then delivered to the apo-hydrogenase for activation. Synthetic chemistry has been used to prepare remarkably similar mimics of that subsite, but it has failed to reproduce the natural enzymatic activities thus far. Here we show that three synthetic mimics (containing different bridging dithiolate ligands) can be loaded onto bacterial Thermotoga maritima HydF and then transferred to apo-HydA1, one of the hydrogenases of Chlamydomonas reinhardtii algae. Full activation of HydA1 was achieved only when using the HydF hybrid protein containing the mimic with an azadithiolate bridge, confirming the presence of this ligand in the active site of native [FeFe]-hydrogenases. This is an example of controlled metalloenzyme activation using the combination of a specific protein scaffold and active-site synthetic analogues. This simple methodology provides both new mechanistic and structural insight into hydrogenase maturation and a unique tool for producing recombinant wild-type and variant [FeFe]-hydrogenases, with no requirement for the complete maturation machinery.

Published

2013

37. Identification and characterization of the "super-reduced" state of the H-cluster in [FeFe] hydrogenase: a new building block for the catalytic cycle?

Author

Adamska A, Silakov A, Lambertz C, Rüdiger O, Happe T, Reijerse E, and Lubitz W

Subjects

Catalytic Domain, Clostridium acetobutylicum chemistry, Clostridium acetobutylicum metabolism, Electron Spin Resonance Spectroscopy, Enzyme Activation, Oxidation-Reduction, Spectroscopy, Fourier Transform Infrared, Clostridium acetobutylicum enzymology, Hydrogen metabolism, Hydrogenase chemistry, Hydrogenase metabolism

Published

2012

38. Differential expression of the Chlamydomonas [FeFe]-hydrogenase-encoding HYDA1 gene is regulated by the copper response regulator1.

Author

Pape M, Lambertz C, Happe T, and Hemschemeier A

Subjects

Base Sequence, Chlamydomonas reinhardtii drug effects, Electrophoretic Mobility Shift Assay, Gene Deletion, Genetic Complementation Test, Hydrogenase metabolism, Ions, Iron-Sulfur Proteins metabolism, Luciferases metabolism, Mercury toxicity, Molecular Sequence Data, Mutation genetics, Nucleotide Motifs genetics, Plant Proteins genetics, Promoter Regions, Genetic genetics, Protein Binding drug effects, Protein Structure, Tertiary, RNA, Messenger genetics, RNA, Messenger metabolism, Transformation, Genetic drug effects, Chlamydomonas reinhardtii enzymology, Chlamydomonas reinhardtii genetics, Gene Expression Regulation, Plant drug effects, Genes, Plant genetics, Hydrogenase genetics, Iron-Sulfur Proteins genetics, Plant Proteins metabolism

Abstract

The unicellular green alga Chlamydomonas reinhardtii adapts to anaerobic or hypoxic conditions by developing a complex fermentative metabolism including the production of molecular hydrogen by [FeFe]-hydrogenase isoform1 (HYDA1). HYDA1 transcript and hydrogenase protein accumulate in the absence of oxygen or copper (Cu). Factors regulating this differential gene expression have been unknown so far. In this study, we report on the isolation of a Chlamydomonas mutant strain impaired in HYDA1 gene expression by screening an insertional mutagenesis library for HYDA1 promoter activity using the arylsulfatase-encoding ARYLSULFATASE2 gene as a selection marker. The mutant strain has a deletion of the COPPER RESPONSE REGULATOR1 (CRR1) gene encoding for CRR1, indicating that this SQUAMOSA-PROMOTER BINDING PROTEIN (SBP) domain transcription factor is involved in the regulation of HYDA1 transcription. Treating the C. reinhardtii wild type with mercuric ions, which were shown to inhibit the binding of the SBP domain to DNA, prevented or deactivated HYDA1 gene expression. Reporter gene analyses of the HYDA1 promoter revealed that two GTAC motifs, which are known to be the cores of CRR1 binding sites, are necessary for full promoter activity in hypoxic conditions or upon Cu starvation. However, mutations of the GTAC sites had a much stronger impact on reporter gene expression in Cu-deficient cells. Electrophoretic mobility shift assays showed that the CRR1 SBP domain binds to one of the GTAC cores in vitro. These combined results prove that CRR1 is involved in HYDA1 promoter activation.

Published

2012

39. Inhibition of [FeFe]-hydrogenases by formaldehyde and wider mechanistic implications for biohydrogen activation.

Author

Foster CE, Krämer T, Wait AF, Parkin A, Jennings DP, Happe T, McGrady JE, and Armstrong FA

Subjects

Carbon Monoxide metabolism, Clostridium acetobutylicum chemistry, Hydrogenase chemistry, Hydrogenase metabolism, Iron chemistry, Metalloproteins chemistry, Metalloproteins metabolism, Clostridium acetobutylicum enzymology, Enzyme Inhibitors pharmacology, Formaldehyde pharmacology, Hydrogen metabolism, Hydrogenase antagonists & inhibitors, Metalloproteins antagonists & inhibitors

Abstract

Formaldehyde-a rapid and reversible inhibitor of hydrogen evolution by [FeFe]-hydrogenases-binds with a strong potential dependence that is almost complementary to that of CO. Whereas exogenous CO binds tightly to the oxidized state known as H(ox) but very weakly to a state two electrons more reduced, formaldehyde interacts most strongly with the latter. Formaldehyde thus intercepts increasingly reduced states of the catalytic cycle, and density functional theory calculations support the proposal that it reacts with the H-cluster directly, most likely targeting an otherwise elusive and highly reactive Fe-hydrido (Fe-H) intermediate., (© 2012 American Chemical Society)

Published

2012

40. Importance of the protein framework for catalytic activity of [FeFe]-hydrogenases.

Author

Knörzer P, Silakov A, Foster CE, Armstrong FA, Lubitz W, and Happe T

Subjects

Bacterial Proteins genetics, Catalysis, Chlamydomonas reinhardtii genetics, Clostridium genetics, Desulfovibrio desulfuricans genetics, Electron Spin Resonance Spectroscopy, Hydrogenase genetics, Kinetics, Mutagenesis, Site-Directed, Plant Proteins genetics, Spectroscopy, Fourier Transform Infrared, Bacterial Proteins chemistry, Chlamydomonas reinhardtii enzymology, Clostridium enzymology, Desulfovibrio desulfuricans enzymology, Hydrogenase chemistry, Plant Proteins chemistry

Abstract

The active center (H-cluster) of [FeFe]-hydrogenases is embedded into a hydrophobic pocket within the protein. We analyzed several amino acids, located in the vicinity of this niche, by site-directed mutagenesis of the [FeFe]-hydrogenases from Clostridium pasteurianum (CpI) and Chlamydomonas reinhardtii (CrHydA1). These amino acids are highly conserved and predicted to be involved in H-cluster coordination. Characterization of two hydrogenase variants confirmed this hypothesis. The exchange of residues CrHydA1Met(415) and CrHydA1Lys(228) resulted in inactive proteins, which, according to EPR and FTIR analyses, contain no intact H-cluster. However, [FeFe]-hydrogenases in which CpIMet(353) (CrHydA1Met(223)) and CpICys(299) (CrHydA1Cys(169)) were exchanged to leucine and serine, respectively, showed a structurally intact H-cluster with catalytic activity either absent (CpIC299S) or strongly diminished (CpIM353L). In the case of CrHydA1C169S, the H-cluster was trapped in an inactive state exhibiting g values and vibrational frequencies that resembled the H(trans) state of DdH from Desulfovibrio desulfuricans. This cysteine residue, interacting with the bridge head nitrogen of the di(methyl)amine ligand, seems therefore to represent an essential contribution of the immediate protein environment to the reaction mechanism. Exchanging methionine CpIM(353) (CrHydA1M(223)) to leucine led to a strong decrease in turnover without affecting the K(m) value of the electron donor. We suggest that this methionine constitutes a "fine-tuning" element of hydrogenase activity.

Published

2012

41. O2 reactions at the six-iron active site (H-cluster) in [FeFe]-hydrogenase.

Author

Lambertz C, Leidel N, Havelius KG, Noth J, Chernev P, Winkler M, Happe T, and Haumann M

Subjects

Chlamydomonas reinhardtii enzymology, Enzyme Activation drug effects, Kinetics, Protein Binding, Reactive Oxygen Species metabolism, X-Ray Absorption Spectroscopy, Catalytic Domain drug effects, Hydrogenase chemistry, Hydrogenase metabolism, Iron metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, Oxygen metabolism, Oxygen pharmacology

Abstract

Irreversible inhibition by molecular oxygen (O(2)) complicates the use of [FeFe]-hydrogenases (HydA) for biotechnological hydrogen (H(2)) production. Modification by O(2) of the active site six-iron complex denoted as the H-cluster ([4Fe4S]-2Fe(H)) of HydA1 from the green alga Chlamydomonas reinhardtii was characterized by x-ray absorption spectroscopy at the iron K-edge. In a time-resolved approach, HydA1 protein samples were prepared after increasing O(2) exposure periods at 0 °C. A kinetic analysis of changes in their x-ray absorption near edge structure and extended X-ray absorption fine structure spectra revealed three phases of O(2) reactions. The first phase (τ(1) ≤ 4 s) is characterized by the formation of an increased number of Fe-O,C bonds, elongation of the Fe-Fe distance in the binuclear unit (2Fe(H)), and oxidation of one iron ion. The second phase (τ(2) ≈ 15 s) causes a ∼50% decrease of the number of ∼2.7-Å Fe-Fe distances in the [4Fe4S] subcluster and the oxidation of one more iron ion. The final phase (τ(3) ≤ 1000 s) leads to the disappearance of most Fe-Fe and Fe-S interactions and further iron oxidation. These results favor a reaction sequence, which involves 1) oxygenation at 2Fe(H(+)) leading to the formation of a reactive oxygen species-like superoxide (O(2)(-)), followed by 2) H-cluster inactivation and destabilization due to ROS attack on the [4Fe4S] cluster to convert it into an apparent [3Fe4S](+) unit, leading to 3) complete O(2)-induced degradation of the remainders of the H-cluster. This mechanism suggests that blocking of ROS diffusion paths and/or altering the redox potential of the [4Fe4S] cubane by genetic engineering may yield improved O(2) tolerance in [FeFe]-hydrogenase.

Published

2011

42. Formaldehyde--a rapid and reversible inhibitor of hydrogen production by [FeFe]-hydrogenases.

Author

Wait AF, Brandmayr C, Stripp ST, Cavazza C, Fontecilla-Camps JC, Happe T, and Armstrong FA

Subjects

Chlamydomonas reinhardtii enzymology, Clostridium acetobutylicum enzymology, Desulfovibrio desulfuricans enzymology, Kinetics, Oxidation-Reduction drug effects, Protons, Substrate Specificity, Enzyme Inhibitors pharmacology, Formaldehyde pharmacology, Hydrogen metabolism, Hydrogenase antagonists & inhibitors, Hydrogenase metabolism, Iron-Sulfur Proteins antagonists & inhibitors, Iron-Sulfur Proteins metabolism

Abstract

Dihydrogen (H(2)) production by [FeFe]-hydrogenases is strongly inhibited by formaldehyde (methanal) in a reaction that is rapid, reversible, and specific to this type of hydrogenase. This discovery, using three [FeFe]-hydrogenases that are homologous about the active site but otherwise structurally distinct, was made by protein film electrochemistry, which measures the activity (as electrical current) of enzymes immobilized on an electrode; importantly, the inhibitor can be removed after addition. Formaldehyde causes rapid loss of proton reduction activity which is restored when the solution is exchanged. Inhibition is confirmed by conventional solution assays. The effect depends strongly on the direction of catalysis: inhibition of H(2) oxidation is much weaker than for H(2) production, and formaldehyde also protects against CO and O(2) inactivation. By contrast, inhibition of [NiFe]-hydrogenases is weak. The results strongly suggest that formaldehyde binds at, or close to, the active site of [FeFe]-hydrogenases at a site unique to this class of enzyme--highly conserved lysine and cysteine residues, the bridgehead atom of the dithiolate ligand, or the reduced Fe(d) that is the focal center of catalysis.

Published

2011

43. The [FeFe]-hydrogenase maturation protein HydF contains a H-cluster like [4Fe4S]-2Fe site.

Author

Czech I, Stripp S, Sanganas O, Leidel N, Happe T, and Haumann M

Subjects

Bacterial Proteins chemistry, Binding Sites, Hydrogen chemistry, Hydrogen metabolism, Hydrogenase chemistry, Iron chemistry, Iron metabolism, Iron-Sulfur Proteins chemistry, Protein Binding, X-Ray Absorption Spectroscopy methods, Bacterial Proteins metabolism, Chlamydomonas reinhardtii enzymology, Clostridium acetobutylicum enzymology, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism

Abstract

Formation of the catalytic six-iron complex (H-cluster) of [FeFe]-hydrogenase (HydA) requires its interaction with a specific maturation protein, HydF. Comparison by X-ray absorption spectroscopy at the Fe K-edge of HydF from Clostridium acetobutylicum and HydA1 from Chlamydomonas reinhardtii revealed that the overall structure of the iron site in both proteins is highly similar, comprising a [4Fe4S] cluster (Fe-Fe distances of ∼2.7Å) and a di-iron unit (Fe-Fe distance of ∼2.5Å). Thus, a precursor of the whole H-cluster is assembled on HydF. Formation of the core structures of both the 4Fe and 2Fe units may require only the housekeeping [FeS] cluster assembly machinery of the cell. Presumably, only the 2Fe cluster is transferred from HydF to HydA1, thereby forming the active site., (Copyright © 2010 Federation of European Biochemical Societies. Published by Elsevier B.V. All rights reserved.)

Published

2011

44. Wiring an [FeFe]-hydrogenase with photosystem I for light-induced hydrogen production.

Author

Lubner CE, Knörzer P, Silva PJ, Vincent KA, Happe T, Bryant DA, and Golbeck JH

Subjects

Clostridium acetobutylicum enzymology, Electron Transport radiation effects, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Models, Molecular, Photosystem I Protein Complex chemistry, Protein Conformation, Hydrogen metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Light, Nanotechnology methods, Nanowires chemistry, Photosystem I Protein Complex metabolism

Abstract

A molecular wire is used to connect two proteins through their physiologically relevant redox cofactors to facilitate direct electron transfer. Photosystem I (PS I) and an [FeFe]-hydrogenase (H(2)ase) serve as the test bed for this new technology. By tethering a photosensitizer with a hydrogen-evolving catalyst, attached by Fe-S coordination bonds between the F(B) iron-sulfur cluster of PS I and the distal iron-sulfur cluster of H(2)ase, we assayed electron transfer between the two components via light-induced hydrogen generation. These hydrogen-producing nanoconstructs self-assemble when the PS I variant, the H(2)ase variant, and the molecular wire are combined.

Published

2010

45. The surprising diversity of clostridial hydrogenases: a comparative genomic perspective.

Author

Calusinska M, Happe T, Joris B, and Wilmotte A

Subjects

Base Sequence, Catalysis, Clostridium genetics, Clostridium metabolism, Genome, Bacterial, Hydrogen metabolism, Hydrogenase chemistry, Hydrogenase genetics, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins genetics, Iron-Sulfur Proteins metabolism, Operon, Clostridium enzymology, Hydrogenase metabolism

Abstract

Among the large variety of micro-organisms capable of fermentative hydrogen production, strict anaerobes such as members of the genus Clostridium are the most widely studied. They can produce hydrogen by a reversible reduction of protons accumulated during fermentation to dihydrogen, a reaction which is catalysed by hydrogenases. Sequenced genomes provide completely new insights into the diversity of clostridial hydrogenases. Building on previous reports, we found that [FeFe] hydrogenases are not a homogeneous group of enzymes, but exist in multiple forms with different modular structures and are especially abundant in members of the genus Clostridium. This unusual diversity seems to support the central role of hydrogenases in cell metabolism. In particular, the presence of multiple putative operons encoding multisubunit [FeFe] hydrogenases highlights the fact that hydrogen metabolism is very complex in this genus. In contrast with [FeFe] hydrogenases, their [NiFe] hydrogenase counterparts, widely represented in other bacteria and archaea, are found in only a few clostridial species. Surprisingly, a heteromultimeric Ech hydrogenase, known to be an energy-converting [NiFe] hydrogenase and previously described only in methanogenic archaea and some sulfur-reducing bacteria, was found to be encoded by the genomes of four cellulolytic strains: Clostridum cellulolyticum, Clostridum papyrosolvens, Clostridum thermocellum and Clostridum phytofermentans.

Published

2010

46. The [FeFe]-hydrogenase maturase HydF from Clostridium acetobutylicum contains a CO and CN- ligated iron cofactor.

Author

Czech I, Silakov A, Lubitz W, and Happe T

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Clostridium acetobutylicum genetics, Electrophoresis, Polyacrylamide Gel, Hydrogen metabolism, Hydrogenase genetics, Iron-Sulfur Proteins genetics, Spectroscopy, Fourier Transform Infrared, Carbon Monoxide chemistry, Clostridium acetobutylicum enzymology, Hydrogenase chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism

Abstract

Biosynthesis of the [FeFe] hydrogenases active site (H-cluster) requires three maturation factors whose respective roles are not understood yet. The clostridial maturation enzymes (CaHydE, CaHydF and CaHydG) were homologously overexpressed in their native host Clostridium acetobutylicum. CaHydF was able to activate Chlamydomonas reinhardtii [FeFe] hydrogenase apoprotein (CrHydA1(apo)) to almost 100% compared to the native specific hydrogen evolution activity. Based on electron paramagnetic resonance spectroscopy and Fourier-transform infrared spectroscopy data the existence of a [4Fe4S] cluster and a CO and CN(-) ligand coordinated di-iron cluster is suggested. This study contains the first experimental evidence that the bi-nuclear part of the H-cluster is assembled in HydF., (2009 Federation of European Biochemical Societies. Published by Elsevier B.V. All rights reserved.)

Published

2010

47. Characterization of the key step for light-driven hydrogen evolution in green algae.

Author

Winkler M, Kuhlgert S, Hippler M, and Happe T

Subjects

Algal Proteins genetics, Anaerobiosis physiology, Animals, Chlamydomonas reinhardtii genetics, Electron Transport physiology, Ferredoxins genetics, Ferredoxins metabolism, Hydrogenase genetics, Light, Peptide Mapping, Protozoan Proteins genetics, Algal Proteins metabolism, Chlamydomonas reinhardtii enzymology, Hydrogen metabolism, Hydrogenase metabolism, Photosynthesis physiology, Protozoan Proteins metabolism

Abstract

Under anaerobic conditions, several species of green algae perform a light-dependent hydrogen production catalyzed by a special group of [FeFe] hydrogenases termed HydA. Although highly interesting for biotechnological applications, the direct connection between photosynthetic electron transport and hydrogenase activity is still a matter of speculation. By establishing an in vitro reconstitution system, we demonstrate that the photosynthetic ferredoxin (PetF) is essential for efficient electron transfer between photosystem I and HydA1. To investigate the electrostatic interaction process and electron transfer between PetF and HydA1, we performed site-directed mutagenesis. Kinetic analyses with several site-directed mutagenesis variants of HydA1 and PetF enabled us to localize the respective contact sites. These experiments in combination with in silico docking analyses indicate that electrostatic interactions between the conserved HydA1 residue Lys(396) and the C terminus of PetF as well as between the PetF residue Glu(122) and the N-terminal amino group of HydA1 play a major role in complex formation and electron transfer. Mapping of relevant HydA1 and PetF residues constitutes an important basis for manipulating the physiological photosynthetic electron flow in favor of light-driven H(2) production.

Published

2009

48. How algae produce hydrogen--news from the photosynthetic hydrogenase.

Author

Stripp ST and Happe T

Subjects

Hydrogenase metabolism, Photosynthesis, Chlorophyta enzymology, Hydrogen metabolism, Hydrogenase chemistry, Light

Abstract

Green algae are the only known eukaryotes capable of oxygenic photosynthesis which are equipped with a hydrogen metabolism. Hydrogen production is light-dependent, since the [FeFe] hydrogenases are coupled to the photosynthetic electron transport chain via ferredoxin. Algal [FeFe] hydrogenases are one of the most active biocatalysts for the evolution of hydrogen. Therefore, special interest exists in the biophysical characterization and biotechnological usage of these [Fe-S] enzymes. This review traces the discovery of this interesting class of proteins. Recent findings allow insight into the electronic structure and configuration of the [FeFe] hydrogenase active site (H-cluster). Emphasis is placed on novel discoveries of the hydrogenase interaction with its natural electron donor ferredoxin and the mechanism of enzyme inactivation through oxygen.

Published

2009

49. Electrochemical kinetic investigations of the reactions of [FeFe]-hydrogenases with carbon monoxide and oxygen: comparing the importance of gas tunnels and active-site electronic/redox effects.

Author

Goldet G, Brandmayr C, Stripp ST, Happe T, Cavazza C, Fontecilla-Camps JC, and Armstrong FA

Subjects

Bacteria enzymology, Electrochemistry, Enzyme Activation, Hydrogen metabolism, Kinetics, Models, Molecular, Oxidation-Reduction, Carbon Monoxide metabolism, Catalytic Domain, Electrons, Gases metabolism, Hydrogenase chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, Oxygen metabolism

Abstract

A major obstacle for future biohydrogen production is the oxygen sensitivity of [FeFe]-hydrogenases, the highly active catalysts produced by bacteria and green algae. The reactions of three representative [FeFe]-hydrogenases with O(2) have been studied by protein film electrochemistry under conditions of both H(2) oxidation and H(2) production, using CO as a complementary probe. The hydrogenases are DdHydAB and CaHydA from the bacteria Desulfovibrio desulfuricans and Clostridium acetobutylicum , and CrHydA1 from the green alga Chlamydomonas reinhardtii . Rates of inactivation depend on the redox state of the active site 'H-cluster' and on transport through the protein to reach the pocket in which the H-cluster is housed. In all cases CO reacts much faster than O(2). In the model proposed, CaHydA shows the most sluggish gas transport and hence little dependence of inactivation rate on H-cluster state, whereas DdHydAB shows a large dependence on H-cluster state and the least effective barrier to gas transport. All three enzymes show a similar rate of reactivation from CO inhibition, which increases upon illumination: the rate-determining step is thus assigned to cleavage of the labile Fe-CO bond, a reaction likely to be intrinsic to the atomic and electronic state of the H-cluster and less sensitive to the surrounding protein.

Published

2009

50. How oxygen attacks [FeFe] hydrogenases from photosynthetic organisms.

Author

Stripp ST, Goldet G, Brandmayr C, Sanganas O, Vincent KA, Haumann M, Armstrong FA, and Happe T

Subjects

Animals, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Catalysis, Clostridium metabolism, Electrochemistry methods, Hydrogenase antagonists & inhibitors, Hydrogenase chemistry, Iron metabolism, Iron-Sulfur Proteins metabolism, Kinetics, Photosynthesis, Chlamydomonas reinhardtii metabolism, Hydrogenase metabolism, Oxygen metabolism

Abstract

Green algae such as Chlamydomonas reinhardtii synthesize an [FeFe] hydrogenase that is highly active in hydrogen evolution. However, the extreme sensitivity of [FeFe] hydrogenases to oxygen presents a major challenge for exploiting these organisms to achieve sustainable photosynthetic hydrogen production. In this study, the mechanism of oxygen inactivation of the [FeFe] hydrogenase CrHydA1 from C. reinhardtii has been investigated. X-ray absorption spectroscopy shows that reaction with oxygen results in destruction of the [4Fe-4S] domain of the active site H-cluster while leaving the di-iron domain (2Fe(H)) essentially intact. By protein film electrochemistry we were able to determine the order of events leading up to this destruction. Carbon monoxide, a competitive inhibitor of CrHydA1 which binds to an Fe atom of the 2Fe(H) domain and is otherwise not known to attack FeS clusters in proteins, reacts nearly two orders of magnitude faster than oxygen and protects the enzyme against oxygen damage. These results therefore show that destruction of the [4Fe-4S] cluster is initiated by binding and reduction of oxygen at the di-iron domain-a key step that is blocked by carbon monoxide. The relatively slow attack by oxygen compared to carbon monoxide suggests that a very high level of discrimination can be achieved by subtle factors such as electronic effects (specific orbital overlap requirements) and steric constraints at the active site.

Published

2009