Your search keyword '"Rauchfuss, Thomas B."' showing total 140 results

1. The H-cluster of [FeFe] Hydrogenases: Its Enzymatic Synthesis and Parallel Inorganic Semisynthesis.

Author

Britt RD, Rauchfuss TB, and Rao G

Subjects

Catalytic Domain, Hydrogen chemistry, Hydrogen metabolism, Hydrogenase metabolism, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism

Abstract

ConspectusNature's prototypical hydrogen-forming catalysts─hydrogenases─have attracted much attention because they catalyze hydrogen evolution at near zero overpotential and ambient conditions. Beyond any possible applications in the energy sphere, the hydrogenases feature complicated active sites, which implies novel biosynthetic pathways. In terms of the variety of cofactors, the [FeFe]-hydrogenase is among the most complex.For more than a decade, we have worked on the biosynthesis of the active site of [FeFe] hydrogenases. This site, the H-cluster, is a six-iron ensemble consisting of a [4Fe-4S] H cluster linked to a [2Fe] H cluster that is coordinated to CO, cyanide, and a unique organic azadithiolate ligand. Many years ago, three enzymes, namely, HydG, HydE, and HydF, were shown to be required for the biosynthesis and the in vitro maturation of [FeFe] hydrogenases. The structures of the maturases were determined crystallographically, but still little progress was made on the biosynthetic pathway. As described in this Account, the elucidation of the biosynthetic pathway began in earnest with the identification of a molecular iron-cysteinate complex produced within HydG.In this Account, we present our most recent progress toward the molecular mechanism of [2Fe] H biosynthesis using a collaborative approach involving cell-free biosynthesis, isotope and element-sensitive spectroscopies, as well as inorganic synthesis of purported biosynthetic intermediates. Our study starts from the radical SAM enzyme HydG that lyses tyrosine into CO and cyanide and forms an Fe(CO) 2 (CN)-containing species. Crystallographic identification of a unique auxiliary 5Fe-4S cluster in HydG leads to a proposed catalytic cycle in which a free cysteine-chelated "dangler" Fe serves as the platform for the stepwise formation of a [4Fe-4S][Fe(CO)(CN)(cysteinate)] intermediate, which releases the [Fe(CO) 2 (CN)(cysteinate)] product, Complex B. Since Complex B is unstable, we applied synthetic organometallic chemistry to make an analogue, syn-B, and showed that it fully replaces HydG in the in vitro maturation of the H-cluster. Syn-B serves as the substrate for the next radical SAM enzyme HydE, where the low-spin Fe(II) center is activated by 5'-dAdo • to form an adenosylated Fe(I) intermediate. We propose that this Fe(I) species strips the carbon backbone and dimerizes in HydE to form a [Fe 2 (SH) 2 (CO) 4 (CN) 2 ] 2- product. This mechanistic scenario is supported by the use of a synthetic version of this dimer complex, syn-dimer, which allows for the formation of active hydrogenase with only the HydF maturase. Further application of this semisynthesis strategy shows that an [Fe 2 (SCH 2 NH 2 ) 2 (CO) 4 (CN) 2 ] 2- complex can activate the apo hydrogenase, marking it as the last biosynthetic intermediate en route to the H-cluster. This combined enzymatic and semisynthetic approach greatly accelerates our understanding of H-cluster biosynthesis. We anticipate additional mechanistic details regarding H-cluster biosynthesis to be gleaned, and this methodology may be further applied in the study of other complex metallocofactors.

Published

2024

2. Final Stages in the Biosynthesis of the [FeFe]-Hydrogenase Active Site.

Author

Yu X, Rao G, Britt RD, and Rauchfuss TB

Subjects

Molecular Structure, Hydrogenase metabolism, Hydrogenase chemistry, Catalytic Domain, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism

Abstract

The paper aims to elucidate the final stages in the biosynthesis of the [2Fe] H active site of the [FeFe]-hydrogenases. The recently hypothesized intermediate [Fe 2 (SCH 2 NH 2 ) 2 (CN) 2 (CO) 4 ] 2- ([1] 2- ) was prepared by a multistep route from [Fe 2 (S 2 )(CN)(CO) 5 ] - . The following synthetic intermediates were characterized in order: [Fe 2 (SCH 2 NHFmoc) 2 (CNBEt 3 )(CO) 5 ] - , [Fe 2 (SCH 2 NHFmoc) 2 (CN)-(CO) 5 ] - , and [Fe 2 (SCH 2 NHFmoc) 2 (CN) 2 (CO) 4 ] 2- , where Fmoc is fluorenylmethoxycarbonyl). Derivatives of these anions include [K(18-crown-6)] + , PPh 4 + and PPN + salts as well as the 13 CD 2 -isotopologues. These Fe 2 species exist as a mixture of two isomers attributed to diequatorial (ee) and axial-equatorial (ae) stereochemistry at sulfur. In vitro experiments demonstrate that [1] 2- maturates HydA1 in the presence of HydF and a cocktail of reagents. HydA1 can also be maturated using a highly simplified cocktail, omitting HydF and other proteins. This result is consistent with HydA1 participating in the maturation process and refines the roles of HydF., (© 2024 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2024

3. Characterizing the Biosynthesis of the [Fe(II)(CN)(CO) 2 (cysteinate)] - Organometallic Product of the Radical-SAM Enzyme HydG by EPR and Mössbauer Spectroscopy.

Author

Villarreal DG, Rao G, Tao L, Liu L, Rauchfuss TB, and Britt RD

Subjects

Spectroscopy, Mossbauer, Methionine, Catalysis, Oxidation-Reduction, Ferrous Compounds, Electron Spin Resonance Spectroscopy, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry

Abstract

[FeFe]-hydrogenases employ a catalytic H-cluster, consisting of a [4Fe-4S] H cluster linked to a [2Fe] H subcluster with CO, CN - ligands, and an azadithiolate bridge, which mediates the rapid redox interconversion of H + and H 2 . In the biosynthesis of this H-cluster active site, the radical S -adenosyl-l-methionine (radical SAM, RS) enzyme HydG plays the crucial role of generating an organometallic [Fe(II)(CN)(CO) 2 (cysteinate)] - product that is en route to forming the H-cluster. Here, we report direct observation of this diamagnetic organometallic Fe(II) complex through Mössbauer spectroscopy, revealing an isomer shift of δ = 0.10 mm s -1 and quadrupole splitting of Δ E Q = 0.66 mm s -1 . These Mössbauer values are a change from the starting values of δ = 1.15 mm s -1 and Δ E for the ferrous "dangler" Fe in HydG. These values of the observed product complex B are in good agreement with Mössbauer parameters for the low-spin Fe Q = 3.23 mm s -1 Fe Syn-B, which we report here. These results highlight the essential role that HydG plays in converting a resting-state high-spin Fe(II) to a low-spin organometallic Fe(II) product that can be transferred to the downstream maturase enzymes.2+ ions in synthetic analogues, such as 57 Fe Syn-B, which we report here. These results highlight the essential role that HydG plays in converting a resting-state high-spin Fe(II) to a low-spin organometallic Fe(II) product that can be transferred to the downstream maturase enzymes.

Published

2023

4. Fully Refined Semisynthesis of the [FeFe] Hydrogenase H-Cluster.

Author

Rao G, Yu X, Zhang Y, Rauchfuss TB, and Britt RD

Subjects

Protons, Spectrum Analysis, Catalytic Domain, Escherichia coli metabolism, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry

Abstract

[FeFe] hydrogenases contain a 6-Fe cofactor that serves as the active site for efficient redox interconversion between H 2 and protons. The biosynthesis of the so-called H-cluster involves unusual enzymatic reactions that synthesize organometallic Fe complexes containing azadithiolate, CO, and CN - ligands. We have previously demonstrated that specific synthetic [Fe(CO) x (CN) y ] complexes can be used to functionally replace proposed Fe intermediates in the maturation reaction. Here, we report the results from performing such cluster semisynthesis in the context of a recent fully defined cluster maturation procedure, which eliminates unknown components previously employed from Escherichia coli cell lysate and demonstrate this provides a concise route to H-cluster synthesis. We show that formaldehyde can be used as a simple reagent as the carbon source of the bridging adt ligand of H-cluster in lieu of serine/serine hydroxymethyltransferase. In addition to the actual H-cluster, we observe the formation of several H-cluster-like species, the identities of which are probed by cryogenic photolysis combined with EPR/ENDOR spectroscopy.

Published

2023

5. Organometallic Fe 2 (μ-SH) 2 (CO) 4 (CN) 2 Cluster Allows the Biosynthesis of the [FeFe]-Hydrogenase with Only the HydF Maturase.

Author

Zhang Y, Tao L, Woods TJ, Britt RD, and Rauchfuss TB

Subjects

Catalysis, Catalytic Domain, Electron Spin Resonance Spectroscopy, Hydrogen chemistry, Hydrogen metabolism, Hydrogenase metabolism, Molecular Conformation, Organometallic Compounds chemistry, Organometallic Compounds metabolism, Oxidation-Reduction, Bacterial Proteins metabolism, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Trans-Activators metabolism

Abstract

The biosynthesis of the active site of the [FeFe]-hydrogenases (HydA1), the H-cluster, is of interest because these enzymes are highly efficient catalysts for the oxidation and production of H 2 . The biosynthesis of the [2Fe] H subcluster of the H-cluster proceeds from simple precursors, which are processed by three maturases: HydG, HydE, and HydF. Previous studies established that HydG produces an Fe(CO) 2 (CN) adduct of cysteine, which is the substrate for HydE. In this work, we show that by using the synthetic cluster [Fe 2 (μ-SH) 2 (CN) 2 (CO) 4 ] 2- active HydA1 can be biosynthesized without maturases HydG and HydE.

Published

2022

6. Surprising Condensation Reactions of the Azadithiolate Cofactor.

Author

Zhang F, Richers CP, Woods TJ, and Rauchfuss TB

Subjects

Aza Compounds chemistry, Coordination Complexes chemistry, Models, Molecular, Molecular Structure, Rubidium chemistry, Toluene chemistry, Toluene metabolism, Aza Compounds metabolism, Coordination Complexes metabolism, Hydrogenase metabolism, Rubidium metabolism, Toluene analogs & derivatives

Abstract

Azadithiolate, a cofactor found in all [FeFe]-hydrogenases, is shown to undergo acid-catalyzed rearrangement. Fe 2 [(SCH 2 ) 2 NH](CO) 6 self-condenses to give Fe 6 [(SCH 2 ) 3 N] 2 (CO) 17 . The reaction, which is driven by loss of NH 4 + , illustrates the exchange of the amine group. X-ray crystallography reveals that three Fe 2 (SR) 2 (CO) x butterfly subunits interconnected by the aminotrithiolate [N(CH 2 S) 3 ] 3- . Mechanistic studies reveal that Fe 2 [(SCH 2 ) 2 NR](CO) 6 participate in a range of amine exchange reactions, enabling new methodologies for modifying the adt cofactor. Ru 2 [(SCH 2 ) 2 NH](CO) 6 also rearranges, but proceeds further to give derivatives with Ru-alkyl bonds Ru 6 [(SCH 2 ) 3 N][(SCH 2 ) 2 NCH 2 ]S(CO) 17 and [Ru 2 [(SCH 2 ) 2 NCH 2 ](CO) 5 ] 2 S., (© 2021 Wiley-VCH GmbH.)

Published

2021

7. Vibrational Perturbation of the [FeFe] Hydrogenase H-Cluster Revealed by 13 C 2 H-ADT Labeling.

Author

Pelmenschikov V, Birrell JA, Gee LB, Richers CP, Reijerse EJ, Wang H, Arragain S, Mishra N, Yoda Y, Matsuura H, Li L, Tamasaku K, Rauchfuss TB, Lubitz W, and Cramer SP

Subjects

Carbon Isotopes, Density Functional Theory, Deuterium, Hydrogen chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Isotope Labeling, Molecular Conformation, Vibration, Hydrogen metabolism, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry

Abstract

[FeFe] hydrogenases are highly active catalysts for the interconversion of molecular hydrogen with protons and electrons. Here, we use a combination of isotopic labeling, 57 Fe nuclear resonance vibrational spectroscopy (NRVS), and density functional theory (DFT) calculations to observe and characterize the vibrational modes involving motion of the 2-azapropane-1,3-dithiolate (ADT) ligand bridging the two iron sites in the [2Fe] H subcluster. A - 13 C 2 H 2 - ADT labeling in the synthetic diiron precursor of [2Fe] H produced isotope effects observed throughout the NRVS spectrum. The two precursor isotopologues were then used to reconstitute the H-cluster of [FeFe] hydrogenase from Chlamydomonas reinhardtii ( Cr HydA1), and NRVS was measured on samples poised in the catalytically crucial H hyd state containing a terminal hydride at the distal Fe site. The 13 C 2 H isotope effects were observed also in the H hyd spectrum. DFT simulations of the spectra allowed identification of the 57 Fe normal modes coupled to the ADT ligand motions. Particularly, a variety of normal modes involve shortening of the distance between the distal Fe-H hydride and ADT N-H bridgehead hydrogen, which may be relevant to the formation of a transition state on the way to H 2 formation.

Published

2021

8. Crystal Structure of the [FeFe]-Hydrogenase Maturase HydE Bound to Complex-B.

Author

Rohac R, Martin L, Liu L, Basu D, Tao L, Britt RD, Rauchfuss TB, and Nicolet Y

Subjects

Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Models, Molecular, Protein Conformation, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry

Abstract

[FeFe]-hydrogenases use a unique organometallic complex, termed the H cluster, to reversibly convert H 2 into protons and low-potential electrons. It can be best described as a [Fe 4 S 4 ] cluster coupled to a unique [2Fe] H center where the reaction actually takes place. The latter corresponds to two iron atoms, each of which is bound by one CN - ligand and one CO ligand. The two iron atoms are connected by a unique azadithiolate molecule ( - S-CH 2 -NH-CH 2 -S - ) and an additional bridging CO. This [2Fe] H center is built stepwise thanks to the well-orchestrated action of maturating enzymes that belong to the Hyd machinery. Among them, HydG converts l-tyrosine into CO and CN - to produce a unique l-cysteine-Fe(CO) 2 CN species termed complex-B. Very recently, HydE was shown to perform radical-based chemistry using synthetic complex-B as a substrate. Here we report the high-resolution crystal structure that establishes the identity of the complex-B-bound HydE. By triggering the reaction prior to crystallization, we trapped a new five-coordinate Fe species, supporting the proposal that HydE performs complex modifications of complex-B to produce a monomeric "SFe(CO) 2 CN" precursor to the [2Fe] H center. Substrate access, product release, and intermediate transfer are also discussed.

Published

2021

9. Radical SAM Enzyme HydE Generates Adenosylated Fe(I) Intermediates En Route to the [FeFe]-Hydrogenase Catalytic H-Cluster.

Author

Tao L, Pattenaude SA, Joshi S, Begley TP, Rauchfuss TB, and Britt RD

Subjects

Biocatalysis, Hydrogenase chemistry, Iron Compounds chemistry, Molecular Conformation, S-Adenosylmethionine chemistry, Hydrogenase metabolism, Iron Compounds metabolism, S-Adenosylmethionine metabolism, Thermotoga maritima enzymology

Abstract

The H-cluster of [FeFe]-hydrogenase consists of a [4Fe-4S] H -subcluster linked by a cysteinyl bridge to a unique organometallic [2Fe] H -subcluster assigned as the site of interconversion between protons and molecular hydrogen. This [2Fe] H -subcluster is assembled by a set of Fe-S maturase enzymes HydG, HydE and HydF. Here we show that the HydG product [Fe II (Cys)(CO) 2 (CN)] synthon is the substrate of the radical SAM enzyme HydE, with the generated 5'-deoxyadenosyl radical attacking the cysteine S to form a C5'-S bond concomitant with reduction of the central low-spin Fe(II) to the Fe(I) oxidation state. This leads to the cleavage of the cysteine C3-S bond, producing a mononuclear [Fe I (CO) 2 (CN)S] species that serves as the precursor to the dinuclear Fe(I)Fe(I) center of the [2Fe] H -subcluster. This work unveils the role played by HydE in the enzymatic assembly of the H-cluster and expands the scope of radical SAM enzyme chemistry.

Published

2020

10. Spectroscopic and Computational Evidence that [FeFe] Hydrogenases Operate Exclusively with CO-Bridged Intermediates.

Author

Birrell JA, Pelmenschikov V, Mishra N, Wang H, Yoda Y, Tamasaku K, Rauchfuss TB, Cramer SP, Lubitz W, and DeBeer S

Subjects

Chlamydomonas reinhardtii metabolism, Density Functional Theory, Desulfovibrio desulfuricans metabolism, Electron Transport, Nuclear Magnetic Resonance, Biomolecular methods, Carbon Monoxide chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Spectroscopy, Fourier Transform Infrared methods

Abstract

[FeFe] hydrogenases are extremely active H 2 -converting enzymes. Their mechanism remains highly controversial, in particular, the nature of the one-electron and two-electron reduced intermediates called H red H + and H sred H + . In one model, the H red H + and H sred H + states contain a semibridging CO, while in the other model, the bridging CO is replaced by a bridging hydride. Using low-temperature IR spectroscopy and nuclear resonance vibrational spectroscopy, together with density functional theory calculations, we show that the bridging CO is retained in the H sred H + and H red H + states in the [FeFe] hydrogenases from Chlamydomonas reinhardtii and Desulfovibrio desulfuricans , respectively. Furthermore, there is no evidence for a bridging hydride in either state. These results agree with a model of the catalytic cycle in which the H red H + and H sred H + states are integral, catalytically competent components. We conclude that proton-coupled electron transfer between the two subclusters is crucial to catalysis and allows these enzymes to operate in a highly efficient and reversible manner.

Published

2020

11. The binuclear cluster of [FeFe] hydrogenase is formed with sulfur donated by cysteine of an [Fe(Cys)(CO) 2 (CN)] organometallic precursor.

Author

Rao G, Pattenaude SA, Alwan K, Blackburn NJ, Britt RD, and Rauchfuss TB

Subjects

Bacterial Proteins metabolism, Catalysis, Catalytic Domain, Cysteine metabolism, Electron Spin Resonance Spectroscopy, Iron metabolism, Organometallic Compounds metabolism, Sulfur metabolism, Bacterial Proteins chemistry, Cysteine chemistry, Hydrogenase chemistry, Iron chemistry, Organometallic Compounds chemistry, Sulfur chemistry

Abstract

The enzyme [FeFe]-hydrogenase (HydA1) contains a unique 6-iron cofactor, the H-cluster, that has unusual ligands to an Fe-Fe binuclear subcluster: CN - , CO, and an azadithiolate (adt) ligand that provides 2 S bridges between the 2 Fe atoms. In cells, the H-cluster is assembled by a collection of 3 maturases: HydE and HydF, whose roles aren't fully understood, and HydG, which has been shown to construct a [Fe(Cys)(CO) 2 (CN)] organometallic precursor to the binuclear cluster. Here, we report the in vitro assembly of the H-cluster in the absence of HydG, which is functionally replaced by adding a synthetic [Fe(Cys)(CO) 2 (CN)] carrier in the maturation reaction. The synthetic carrier and the HydG-generated analog exhibit similar infrared spectra. The carrier allows HydG-free maturation to HydA1, whose activity matches that of the native enzyme. Maturation with 13 CN-containing carrier affords 13 CN-labeled enzyme as verified by electron paramagnetic resonance (EPR)/electron nuclear double-resonance spectra. This synthetic surrogate approach complements existing biochemical strategies and greatly facilitates the understanding of pathways involved in the assembly of the H-cluster. As an immediate demonstration, we clarify that Cys is not the source of the carbon and nitrogen atoms in the adt ligand using pulse EPR to target the magnetic couplings introduced via a 13 C 3 , 15 N-Cys-labeled synthetic carrier. Parallel mass-spectrometry experiments show that the Cys backbone is converted to pyruvate, consistent with a cysteine role in donating S in forming the adt bridge. This mechanistic scenario is confirmed via maturation with a seleno-Cys carrier to form HydA1-Se, where the incorporation of Se was characterized by extended X-ray absorption fine structure spectroscopy., Competing Interests: The authors declare no competing interest.

Published

2019

12. A [RuRu] Analogue of an [FeFe]-Hydrogenase Traps the Key Hydride Intermediate of the Catalytic Cycle.

Author

Sommer C, Richers CP, Lubitz W, Rauchfuss TB, and Reijerse EJ

Subjects

Biocatalysis, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Molecular Structure, Ruthenium chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Ruthenium metabolism

Abstract

The active site of the [FeFe]-hydrogenases features a binuclear [2Fe] H sub-cluster that contains a unique bridging amine moiety close to an exposed iron center. Heterolytic splitting of H 2 results in the formation of a transient terminal hydride at this iron site, which, however is difficult to stabilize. We show that the hydride intermediate forms immediately when [2Fe] H is replaced with [2Ru] H analogues through artificial maturation. Outside the protein, the [2Ru] H analogues form bridging hydrides, which rearrange to terminal hydrides after insertion into the apo-protein. H/D exchange of the hydride only occurs for [2Ru] H analogues containing the bridging amine moiety., (© 2018 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2018

13. Reaction Coordinate Leading to H 2 Production in [FeFe]-Hydrogenase Identified by Nuclear Resonance Vibrational Spectroscopy and Density Functional Theory.

Author

Pelmenschikov V, Birrell JA, Pham CC, Mishra N, Wang H, Sommer C, Reijerse E, Richers CP, Tamasaku K, Yoda Y, Rauchfuss TB, Lubitz W, and Cramer SP

Subjects

Biocatalysis, Catalytic Domain, Chlamydomonas reinhardtii enzymology, Desulfovibrio desulfuricans enzymology, Models, Molecular, Spectrum Analysis, Vibration, Hydrogen metabolism, Hydrogenase metabolism, Iron metabolism, Quantum Theory

Abstract

[FeFe]-hydrogenases are metalloenzymes that reversibly reduce protons to molecular hydrogen at exceptionally high rates. We have characterized the catalytically competent hydride state (H hyd ) in the [FeFe]-hydrogenases from both Chlamydomonas reinhardtii and Desulfovibrio desulfuricans using 57 Fe nuclear resonance vibrational spectroscopy (NRVS) and density functional theory (DFT). H/D exchange identified two Fe-H bending modes originating from the binuclear iron cofactor. DFT calculations show that these spectral features result from an iron-bound terminal hydride, and the Fe-H vibrational frequencies being highly dependent on interactions between the amine base of the catalytic cofactor with both hydride and the conserved cysteine terminating the proton transfer chain to the active site. The results indicate that H hyd is the catalytic state one step prior to H 2 formation. The observed vibrational spectrum, therefore, provides mechanistic insight into the reaction coordinate for H 2 bond formation by [FeFe]-hydrogenases.

Published

2017

14. Direct Observation of an Iron-Bound Terminal Hydride in [FeFe]-Hydrogenase by Nuclear Resonance Vibrational Spectroscopy.

Author

Reijerse EJ, Pham CC, Pelmenschikov V, Gilbert-Wilson R, Adamska-Venkatesh A, Siebel JF, Gee LB, Yoda Y, Tamasaku K, Lubitz W, Rauchfuss TB, and Cramer SP

Subjects

Hydrogenase metabolism, Iron metabolism, Iron-Sulfur Proteins metabolism, Magnetic Resonance Spectroscopy, Molecular Conformation, Quantum Theory, Spectroscopy, Fourier Transform Infrared, Water chemistry, Water metabolism, Hydrogenase chemistry, Iron chemistry, Iron-Sulfur Proteins chemistry

Abstract

[FeFe]-hydrogenases catalyze the reversible reduction of protons to molecular hydrogen with extremely high efficiency. The active site ("H-cluster") consists of a [4Fe-4S] H cluster linked through a bridging cysteine to a [2Fe] H subsite coordinated by CN - and CO ligands featuring a dithiol-amine moiety that serves as proton shuttle between the protein proton channel and the catalytic distal iron site (Fe d ). Although there is broad consensus that an iron-bound terminal hydride species must occur in the catalytic mechanism, such a species has never been directly observed experimentally. Here, we present FTIR and nuclear resonance vibrational spectroscopy (NRVS) experiments in conjunction with density functional theory (DFT) calculations on an [FeFe]-hydrogenase variant lacking the amine proton shuttle which is stabilizing a putative hydride state. The NRVS spectra unequivocally show the bending modes of the terminal Fe-H species fully consistent with widely accepted models of the catalytic cycle.

Published

2017

15. Hydrogenase Enzymes and Their Synthetic Models: The Role of Metal Hydrides.

Author

Schilter D, Camara JM, Huynh MT, Hammes-Schiffer S, and Rauchfuss TB

Subjects

Crystallography, X-Ray, Magnetic Resonance Spectroscopy, Models, Chemical, Molecular Mimicry, Coordination Complexes chemistry, Hydrogen chemistry, Hydrogenase chemistry

Abstract

Hydrogenase enzymes efficiently process H2 and protons at organometallic FeFe, NiFe, or Fe active sites. Synthetic modeling of the many H2ase states has provided insight into H2ase structure and mechanism, as well as afforded catalysts for the H2 energy vector. Particularly important are hydride-bearing states, with synthetic hydride analogues now known for each hydrogenase class. These hydrides are typically prepared by protonation of low-valent cores. Examples of FeFe and NiFe hydrides derived from H2 have also been prepared. Such chemistry is more developed than mimicry of the redox-inactive monoFe enzyme, although functional models of the latter are now emerging. Advances in physical and theoretical characterization of H2ase enzymes and synthetic models have proven key to the study of hydrides in particular, and will guide modeling efforts toward more robust and active species optimized for practical applications., Competing Interests: Notes The authors declare no competing financial interest.

Published

2016

16. Mechanism of H2 Production by Models for the [NiFe]-Hydrogenases: Role of Reduced Hydrides.

Author

Ulloa OA, Huynh MT, Richers CP, Bertke JA, Nilges MJ, Hammes-Schiffer S, and Rauchfuss TB

Subjects

Catalytic Domain, Hydrogenase chemistry, Models, Molecular, Oxidation-Reduction, Protons, Quantum Theory, Hydrogen metabolism, Hydrogenase metabolism

Abstract

The intermediacy of a reduced nickel-iron hydride in hydrogen evolution catalyzed by Ni-Fe complexes was verified experimentally and computationally. In addition to catalyzing hydrogen evolution, the highly basic and bulky (dppv)Ni(μ-pdt)Fe(CO)(dppv) ([1](0); dppv = cis-C2H2(PPh2)2) and its hydride derivatives have yielded to detailed characterization in terms of spectroscopy, bonding, and reactivity. The protonation of [1](0) initially produces unsym-[H1](+), which converts by a first-order pathway to sym-[H1](+). These species have C1 (unsym) and Cs (sym) symmetries, respectively, depending on the stereochemistry of the octahedral Fe site. Both experimental and computational studies show that [H1](+) protonates at sulfur. The S = 1/2 hydride [H1](0) was generated by reduction of [H1](+) with Cp*2Co. Density functional theory (DFT) calculations indicate that [H1](0) is best described as a Ni(I)-Fe(II) derivative with significant spin density on Ni and some delocalization on S and Fe. EPR spectroscopy reveals both kinetic and thermodynamic isomers of [H1](0). Whereas [H1](+) does not evolve H2 upon protonation, treatment of [H1](0) with acids gives H2. The redox state of the "remote" metal (Ni) modulates the hydridic character of the Fe(II)-H center. As supported by DFT calculations, H2 evolution proceeds either directly from [H1](0) and external acid or from protonation of the Fe-H bond in [H1](0) to give a labile dihydrogen complex. Stoichiometric tests indicate that protonation-induced hydrogen evolution from [H1](0) initially produces [1](+), which is reduced by [H1](0). Our results reconcile the required reductive activation of a metal hydride and the resistance of metal hydrides toward reduction. This dichotomy is resolved by reduction of the remote (non-hydride) metal of the bimetallic unit., Competing Interests: Notes The authors declare no competing financial interest.

Published

2016

17. Models of the Ni-L and Ni-SIa States of the [NiFe]-Hydrogenase Active Site.

Author

Chambers GM, Huynh MT, Li Y, Hammes-Schiffer S, Rauchfuss TB, Reijerse E, and Lubitz W

Subjects

Catalysis, Catalytic Domain, Electron Spin Resonance Spectroscopy, Spectroscopy, Mossbauer, Thermodynamics, Hydrogenase chemistry, Nickel chemistry

Abstract

A new class of synthetic models for the active site of [NiFe]-hydrogenases are described. The Ni(I/II)(SCys)2 and Fe(II)(CN)2CO sites are represented with (RC5H4)Ni(I/II) and Fe(II)(diphos)(CO) modules, where diphos = 1,2-C2H4(PPh2)2(dppe) or cis-1,2-C2H2(PPh2)2(dppv). The two bridging thiolate ligands are represented by CH2(CH2S)2(2-) (pdt(2-)), Me2C(CH2S)2(2-) (Me2pdt(2-)), and (C6H5S)2(2-). The reaction of Fe(pdt)(CO)2(dppe) and [(C5H5)3Ni2]BF4 affords [(C5H5)Ni(pdt)Fe(dppe)(CO)]BF4 ([1a]BF4). Monocarbonyl [1a]BF4 features an S = 0 Ni(II)Fe(II) center with five-coordinated iron, as proposed for the Ni-SIa state of the enzyme. One-electron reduction of [1a](+) affords the S = 1/2 derivative [1a](0), which, according to density functional theory (DFT) calculations and electron paramagnetic resonance and Mössbauer spectroscopies, is best described as a Ni(I)Fe(II) compound. The Ni(I)Fe(II) assignment matches that for the Ni-L state in [NiFe]-hydrogenase, unlike recently reported Ni(II)Fe(I)-based models. Compound [1a](0) reacts with strong acids to liberate 0.5 equiv of H2 and regenerate [1a](+), indicating that H2 evolution is catalyzed by [1a](0). DFT calculations were used to investigate the pathway for H2 evolution and revealed that the mechanism can proceed through two isomers of [1a](0) that differ in the stereochemistry of the Fe(dppe)CO center. Calculations suggest that protonation of [1a](0) (both isomers) affords Ni(III)-H-Fe(II) intermediates, which represent mimics of the Ni-C state of the enzyme.

Published

2016

18. Hydride bridge in [NiFe]-hydrogenase observed by nuclear resonance vibrational spectroscopy.

Author

Ogata H, Krämer T, Wang H, Schilter D, Pelmenschikov V, van Gastel M, Neese F, Rauchfuss TB, Gee LB, Scott AD, Yoda Y, Tanaka Y, Lubitz W, and Cramer SP

Subjects

Magnetic Resonance Spectroscopy, Desulfovibrio vulgaris enzymology, Hydrogenase chemistry

Abstract

The metabolism of many anaerobes relies on [NiFe]-hydrogenases, whose characterization when bound to substrates has proven non-trivial. Presented here is direct evidence for a hydride bridge in the active site of the (57)Fe-labelled fully reduced Ni-R form of Desulfovibrio vulgaris Miyazaki F [NiFe]-hydrogenase. A unique 'wagging' mode involving H(-) motion perpendicular to the Ni(μ-H)(57)Fe plane was studied using (57)Fe-specific nuclear resonance vibrational spectroscopy and density functional theory (DFT) calculations. On Ni(μ-D)(57)Fe deuteride substitution, this wagging causes a characteristic perturbation of Fe-CO/CN bands. Spectra have been interpreted by comparison with Ni(μ-H/D)(57)Fe enzyme mimics [(dppe)Ni(μ-pdt)(μ-H/D)(57)Fe(CO)3](+) and DFT calculations, which collectively indicate a low-spin Ni(II)(μ-H)Fe(II) core for Ni-R, with H(-) binding Ni more tightly than Fe. The present methodology is also relevant to characterizing Fe-H moieties in other important natural and synthetic catalysts.

Published

2015

19. Spectroscopic Investigations of [FeFe] Hydrogenase Maturated with [(57)Fe2(adt)(CN)2(CO)4](2-).

Author

Gilbert-Wilson R, Siebel JF, Adamska-Venkatesh A, Pham CC, Reijerse E, Wang H, Cramer SP, Lubitz W, and Rauchfuss TB

Subjects

Carbon Monoxide metabolism, Catalytic Domain, Chlamydomonas reinhardtii chemistry, Chlamydomonas reinhardtii metabolism, Hydrogenase antagonists & inhibitors, Hydrogenase metabolism, Iron Isotopes chemistry, Iron-Sulfur Proteins antagonists & inhibitors, Iron-Sulfur Proteins metabolism, Models, Molecular, Chlamydomonas reinhardtii enzymology, Electron Spin Resonance Spectroscopy, Hydrogenase chemistry, Iron Compounds chemistry, Iron-Sulfur Proteins chemistry, Spectroscopy, Mossbauer

Abstract

The preparation and spectroscopic characterization of a CO-inhibited [FeFe] hydrogenase with a selectively (57)Fe-labeled binuclear subsite is described. The precursor [(57)Fe2(adt)(CN)2(CO)4](2-) was synthesized from the (57)Fe metal, S8, CO, (NEt4)CN, NH4Cl, and CH2O. (Et4N)2[(57)Fe2(adt)(CN)2(CO)4] was then used for the maturation of the [FeFe] hydrogenase HydA1 from Chlamydomonas reinhardtii, to yield the enzyme selectively labeled at the [2Fe]H subcluster. Complementary (57)Fe enrichment of the [4Fe-4S]H cluster was realized by reconstitution with (57)FeCl3 and Na2S. The Hox-CO state of [2(57)Fe]H and [4(57)Fe-4S]H HydA1 was characterized by Mössbauer, HYSCORE, ENDOR, and nuclear resonance vibrational spectroscopy.

Published

2015

20. Diiron azadithiolates as models for the [FeFe]-hydrogenase active site and paradigm for the role of the second coordination sphere.

Author

Rauchfuss TB

Subjects

Aza Compounds metabolism, Catalytic Domain, Hydrogenase metabolism, Iron Compounds metabolism, Iron-Sulfur Proteins metabolism, Models, Molecular, Molecular Conformation, Stereoisomerism, Sulfhydryl Compounds metabolism, Aza Compounds chemistry, Hydrogenase chemistry, Iron Compounds chemistry, Iron-Sulfur Proteins chemistry, Sulfhydryl Compounds chemistry

Abstract

The [FeFe] hydrogenases (H2ases) catalyze the redox reaction that interconverts protons and H2. This area of biocatalysis has attracted attention because the metal-based chemistry is unusual, and the reactions have practical implications. The active site consists of a [4Fe-4S] cluster bridged to a [Fe2(μ-dithiolate)(CN)2(CO)3](z) center (z = 1- and 2-). The dithiolate cofactor is [HN(CH2S)2](2-), called the azadithiolate ([adt(H)](2-)). Although many derivatives of Fe2(SR)2(CO)6-xLx are electrocatalysts for the hydrogen evolution reaction (HER), most operate by slow nonbiomimetic pathways. Biomimetic hydrogenogenesis is thought to involve intermediates, wherein the hydride substrate is adjacent to the amine of the adt(H), being bonded to only one Fe center. Formation of terminal hydride complexes is favored when the diiron carbonyl models contain azadithiolate. Although unstable in the free state, the adt cofactor is stable once it is affixed to the Fe2 center. It can be prepared by alkylation of Fe2(SH)2(CO)6 with formaldehyde in the presence of ammonia (to give adt(H) derivatives) or amines (to give adt(R) derivatives). Weak acids protonate Fe2(adt(R))(CO)2(PR3)4 to give terminal hydrido (term-H) complexes. In contrast, protonation of the related 1,3-propanedithiolate (pdt(2-)) complexes Fe2(pdt)(CO)2(PR3)4 requires strong acids. The amine in the azadithiolate is a kinetically fast base, relaying protons to and from the iron, which is a kinetically slow base. The crystal structure of the doubly protonated model [(term-H)Fe2(Hadt(H))(CO)2(dppv)2](2+) confirms the presence of both ammonium and terminal hydrido centers, which interact through a dihydrogen bond (dppv = cis-C2H2(PPh2)2). DFT calculations indicate that this H---H interaction is sensitive to the counterions and is strengthened upon reduction of the diiron center. For the monoprotonated models, the hydride [(term-H)Fe2(adt(H))(CO)2(dppv)2](+) exists in equilibrium with the ammonium tautomer [Fe2(Hadt(H))(CO)2(dppv)2](+). Both [(term-H)Fe2(Hadt(H))(CO)2(dppv)2](2+) and [(term-H)Fe2(adt(H))(CO)2(dppv)2](+) are highly active electrocatalysts for HER. Catalysis is initiated by reduction of the diferrous center, which induces coupling of the protic ammonium center and the hydride ligand. In contrast, the propanedithiolate [(term-H)Fe2(pdt)(CO)2(dppv)2](+) is a poor electrocatalyst for HER. Oxidation of H2 has been demonstrated, starting with models for the oxidized state ("Hox"), for example, [Fe2(adt(H))(CO)3(dppv)(PMe3)](+). Featuring a distorted Fe(II)Fe(I) center, this Hox model reacts slowly with high pressures of H2 to give [(μ-H)Fe2(adt(H))(CO)3(dppv)(PMe3)](+). Highlighting the role of the proton relay, the propanedithiolate [Fe2(pdt)(CO)3(dppv)(PMe3)](+) is unreactive toward H2. The Hox-model + H2 reaction is accelerated in the presence of ferrocenium salts, which simulate the role of the attached [4Fe-4S] cluster. The redox-complemented complex [Fe2(adt(Bn))(CO)3(dppv)(FcP*)](n+) catalyzes both proton reduction and hydrogen oxidation (FcP* = (C5Me5)Fe(C5Me4CH2PEt2)).

Published

2015

21. N-Substituted Derivatives of the Azadithiolate Cofactor from the [FeFe] Hydrogenases: Stability and Complexation.

Author

Angamuthu R, Chen CS, Cochrane TR, Gray DL, Schilter D, Ulloa OA, and Rauchfuss TB

Subjects

Catalysis, Chemistry Techniques, Synthetic, Coenzymes chemical synthesis, Crystallography, X-Ray, Hydrolysis, Magnetic Resonance Spectroscopy, Molecular Structure, Nickel chemistry, Sulfhydryl Compounds chemistry, Coenzymes chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Organometallic Compounds chemistry

Abstract

Experiments are described that probe the stability of N-substituted derivatives of the azadithiolate cofactor recently confirmed in the [FeFe] hydrogenases (Berggren, G., et al. Nature 2013, 499, 66). Acid-catalyzed hydrolysis of bis(thioester) BnN(CH2SAc)2 gives [BnNCH2SCH2]2 rather than azadithiol BnN(CH2SH)2. Treatment of BnN(CH2SAc)2 with NaO(t)Bu generates BnN(CH2SNa)2, which was trapped with NiCl2(diphos) (diphos = 1,2-C2H4(PR2)2; R = Ph (dppe) and Cy (dcpe)) to give fully characterized complexes Ni[(SCH2)2NBn](diphos). The related N-aryl derivative Ni[(SCH2)2NC6H4Cl](diphos) was prepared analogously from 4-ClC6H4N(CH2SAc)2, NaO(t)Bu, and NiCl2(dppe). Crystallographic analysis confirmed that these rare nonbridging [adt(R)](2-) complexes feature distorted square planar Ni centers. The analogue Pd[(SCH2)2NBn](dppe) was also prepared. (31)P NMR analysis indicates that Ni[(SCH2)2NBn](dppe) has basicity comparable to typical amines. As shown by cyclic voltammetry, the couple [M[(SCH2)2NBn](dppe)](+/0) is reversible near -2.0 V versus Fc(+/0). The wave shifts to -1.78 V upon N-protonation. In the presence of CF3CO2H, Ni[(SCH2)2NBn](dppe) catalyzes hydrogen evolution at rate of 22 s(-1) in the acid-independent regime, at room temperature in CH2Cl2 solution. In contrast to the instability of RN(CH2SH)2 (R = alkyl, aryl), the dithiol of tosylamide TsN(CH2SH)2 proved sufficiently stable to allow full characterization. This dithiol reacts with Fe3(CO)12 and, in the presence of base, NiCl2(dppe) to give Fe2[(SCH2)2NTs](CO)6 and Ni[(SCH2)2NTs](dppe), respectively.

Published

2015

22. Synthesis and vibrational spectroscopy of (57)Fe-labeled models of [NiFe] hydrogenase: first direct observation of a nickel-iron interaction.

Author

Schilter D, Pelmenschikov V, Wang H, Meier F, Gee LB, Yoda Y, Kaupp M, Rauchfuss TB, and Cramer SP

Subjects

Coordination Complexes chemistry, Coordination Complexes metabolism, Electron Spin Resonance Spectroscopy, Hydrogenase metabolism, Iron Compounds chemistry, Iron Isotopes chemistry, Magnetic Resonance Spectroscopy, Coordination Complexes chemical synthesis, Hydrogenase chemistry, Iron chemistry, Models, Molecular, Nickel chemistry

Abstract

A new route to iron carbonyls has enabled synthesis of (57)Fe-labeled [NiFe] hydrogenase mimic (OC)3(57)Fe(pdt)Ni(dppe). Its study by nuclear resonance vibrational spectroscopy revealed Ni-(57)Fe vibrations, as confirmed by calculations. The modes are absent for [(OC)3(57)Fe(pdt)Ni(dppe)](+), which lacks Ni-(57)Fe bonding, underscoring the utility of the analyses in identifying metal-metal interactions.

Published

2014

23. Computational investigation of [FeFe]-hydrogenase models: characterization of singly and doubly protonated intermediates and mechanistic insights.

Author

Huynh MT, Wang W, Rauchfuss TB, and Hammes-Schiffer S

Subjects

Biocatalysis, Ferrous Compounds chemical synthesis, Ferrous Compounds chemistry, Ferrous Compounds metabolism, Hydrogen chemistry, Hydrogen metabolism, Hydrogen Bonding, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Models, Molecular, Protons, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Quantum Theory

Abstract

The [FeFe]-hydrogenase enzymes catalyze hydrogen oxidation and production efficiently with binuclear Fe metal centers. Recently the bioinspired H2-producing model system Fe2(adt)(CO)2(dppv)2 (adt=azadithiolate and dppv=diphosphine) was synthesized and studied experimentally. In this system, the azadithiolate bridge facilitates the formation of a doubly protonated ammonium-hydride species through a proton relay. Herein computational methods are utilized to examine this system in the various oxidation states and protonation states along proposed mechanistic pathways for H2 production. The calculated results agree well with the experimental data for the geometries, CO vibrational stretching frequencies, and reduction potentials. The calculations illustrate that the NH···HFe dihydrogen bonding distance in the doubly protonated species is highly sensitive to the effects of ion-pairing between the ammonium and BF4(-) counterions, which are present in the crystal structure, in that the inclusion of BF4(-) counterions leads to a significantly longer dihydrogen bond. The non-hydride Fe center was found to be the site of reduction for terminal hydride species and unsymmetric bridging hydride species, whereas the reduced symmetric bridging hydride species exhibited spin delocalization between the Fe centers. According to both experimental measurements and theoretical calculations of the relative pKa values, the Fed center of the neutral species is more basic than the amine, and the bridging hydride species is more thermodynamically stable than the terminal hydride species. The calculations implicate a possible pathway for H2 evolution that involves an intermediate with H2 weakly bonded to one Fe, a short H2 distance similar to the molecular bond length, the spin density delocalized over the two Fe centers, and a nearly symmetrically bridged CO ligand. Overall, this study illustrates the mechanistic roles of the ammonium-hydride interaction, flexibility of the bridging CO ligand, and intramolecular electron transfer between the Fe centers in the catalytic cycle. Such insights will assist in the design of more effective bioinspired catalysts for H2 production.

Published

2014

24. Protonation of nickel-iron hydrogenase models proceeds after isomerization at nickel.

Author

Huynh MT, Schilter D, Hammes-Schiffer S, and Rauchfuss TB

Subjects

Crystallography, X-Ray, Isomerism, Models, Molecular, Palladium chemistry, Platinum chemistry, Coordination Complexes chemistry, Hydrogenase chemistry, Iron chemistry, Nickel chemistry, Protons

Abstract

Theory and experiment indicate that the protonation of reduced NiFe dithiolates proceeds via a previously undetected isomer with enhanced basicity. In particular, it is proposed that protonation of (OC)3Fe(pdt)Ni(dppe) (1; pdt(2-) = (-)S(CH2)3S(-); dppe = Ph2P(CH2)2PPh2) occurs at the Fe site of the two-electron mixed-valence Fe(0)Ni(II) species, not the Fe(I)-Ni(I) bond for the homovalence isomer of 1. The new pathway, which may have implications for protonation of other complexes and clusters, was uncovered through studies on the homologous series L(OC)2Fe(pdt)M(dppe), where M = Ni, Pd (2), and Pt (3) and L = CO, PCy3. Similar to 1, complexes 2 and 3 undergo both protonation and 1e(-) oxidation to afford well-characterized hydrides ([2H](+) and [3H](+)) and mixed-valence derivatives ([2](+) and [3](+)), respectively. Whereas the Pd site is tetrahedral in 2, the Pt site is square-planar in 3, indicating that this complex is best described as Fe(0)Pt(II). In view of the results on 2 and 3, the potential energy surface of 1 was reinvestigated with density functional theory. These calculations revealed the existence of an energetically accessible and more basic Fe(0)Ni(II) isomer with a square-planar Ni site.

Published

2014

25. Borane-protected cyanides as surrogates of H-bonded cyanides in [FeFe]-hydrogenase active site models.

Author

Manor BC, Ringenberg MR, and Rauchfuss TB

Subjects

Catalytic Domain, Hydrogen Bonding, Models, Molecular, Spectrophotometry, Infrared, Boranes chemistry, Cyanides chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry

Abstract

Triarylborane Lewis acids bind [Fe2(pdt)(CO)4(CN)2](2-) [1](2-) (pdt(2-) = 1,3-propanedithiolate) and [Fe2(adt)(CO)4(CN)2](2-) [3](2-) (adt(2-) = 1,3-azadithiolate, HN(CH2S(-))2) to give the 2:1 adducts [Fe2(xdt)(CO)4(CNBAr3)2](2-). Attempts to prepare the 1:1 adducts [1(BAr3)](2-) (Ar = Ph, C6F5) were unsuccessful, but related 1:1 adducts were obtained using the bulky borane B(C6F4-o-C6F5)3 (BAr(F)*3). By virtue of the N-protection by the borane, salts of [Fe2(pdt)(CO)4(CNBAr3)2](2-) sustain protonation to give hydrides that are stable (in contrast to [H1](-)). The hydrides [H1(BAr3)2](-) are 2.5-5 pKa units more acidic than the parent [H1](-). The adducts [1(BAr3)2](2-) oxidize quasi-reversibly around -0.3 V versus Fc(0/+) in contrast to ca. -0.8 V observed for the [1](2-/-) couple. A simplified synthesis of [1](2-), [3](2-), and [Fe2(pdt)(CO)5(CN)](-) ([2](-)) was developed, entailing reaction of the diiron hexacarbonyl complexes with KCN in MeCN.

Published

2014

26. Crystallographic characterization of a fully rotated, basic diiron dithiolate: model for the H(red) state?

Author

Wang W, Rauchfuss TB, Moore CE, Rheingold AL, De Gioia L, and Zampella G

Subjects

Catalytic Domain, Crystallography, X-Ray, Ligands, Hydrogenase chemistry, Iron chemistry, Sulfhydryl Compounds chemistry

Abstract

A lucky break: A combination of steric pressure and electron asymmetry has provided the first example of a diiron dithiolate that is both rotated and basic. The present work establishes the feasibility of a hydride free rotated structure for the Hred state of the enzyme., (Copyright © 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2013

27. Hydrogen activation by biomimetic [NiFe]-hydrogenase model containing protected cyanide cofactors.

Author

Manor BC and Rauchfuss TB

Subjects

Biomimetic Materials metabolism, Boranes metabolism, Catalytic Domain, Cyanides metabolism, Desulfovibrio chemistry, Desulfovibrio metabolism, Hydrogen chemistry, Hydrogenase metabolism, Models, Molecular, Biomimetic Materials chemistry, Boranes chemistry, Cyanides chemistry, Desulfovibrio enzymology, Hydrogen metabolism, Hydrogenase chemistry

Abstract

Described are experiments demonstrating incorporation of cyanide cofactors and hydride substrate into [NiFe]-hydrogenase (H2ase) active site models. Complexes of the type (CO)2(CN)2Fe(pdt)Ni(dxpe) (dxpe = dppe, 1; dxpe = dcpe, 2) bind the Lewis acid B(C6F5)3 (BAr(F)3) to give the adducts (CO)2(CNBAr(F)3)2Fe(pdt)Ni(dxpe), (1(BAr(F)3)2, 2(BAr(F)3)2). Upon decarbonylation using amine oxides, these adducts react with H2 to give hydrido derivatives [(CO)(CNBAr(F)3)2Fe(H)(pdt)Ni(dxpe)](-) (dxpe = dppe, [H3(BAr(F)3)2](-); dxpe = dcpe, [H4(BAr(F)3)2](-)). Crystallographic analysis shows that Et4N[H3(BAr(F)3)2] generally resembles the active site of the enzyme in the reduced, hydride-containing states (Ni-C/R). The Fe-H···Ni center is unsymmetrical with r(Fe-H) = 1.51(3) Å and r(Ni-H) = 1.71(3) Å. Both crystallographic and (19)F NMR analyses show that the CNBAr(F)3(-) ligands occupy basal and apical sites. Unlike cationic Ni-Fe hydrides, [H3(BAr(F)3)2](-) and [H4(BAr(F)3)2](-) oxidize at mild potentials, near the Fc(+/0) couple. Electrochemical measurements indicate that in the presence of base, [H3(BAr(F)3)2](-) catalyzes the oxidation of H2. NMR evidence indicates dihydrogen bonding between these anionic hydrides and R3NH(+) salts, which is relevant to the mechanism of hydrogenogenesis. In the case of Et4N[H3(BAr(F)3)2], strong acids such as HCl induce H2 release to give the chloride Et4N[(CO)(CNBAr(F)3)2Fe(Cl)(pdt)Ni(dppe)].

Published

2013

28. Observation of the Fe-CN and Fe-CO vibrations in the active site of [NiFe] hydrogenase by nuclear resonance vibrational spectroscopy.

Author

Kamali S, Wang H, Mitra D, Ogata H, Lubitz W, Manor BC, Rauchfuss TB, Byrne D, Bonnefoy V, Jenney FE Jr, Adams MW, Yoda Y, Alp E, Zhao J, and Cramer SP

Subjects

Catalytic Domain, Electron Spin Resonance Spectroscopy, Hydrogenase metabolism, Iron Compounds chemistry, Models, Molecular, Oxidation-Reduction, Spectroscopy, Fourier Transform Infrared, Vibration, Hydrogenase chemistry

Abstract

Nuclear inelastic scattering of (57)Fe labeled [NiFe] hydrogenase is shown to give information on different states of the enzyme. It was thus possible to detect and assign Fe-CO and Fe-CN bending and stretching vibrations of the active site outside the spectral range of the Fe-S cluster normal modes., (Copyright © 2013 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2013

29. Nickel-iron dithiolates related to the deactivated [NiFe]-hydrogenases.

Author

Schilter D and Rauchfuss TB

Subjects

Bridged-Ring Compounds chemistry, Coordination Complexes chemical synthesis, Coordination Complexes chemistry, Crystallography, X-Ray, Hydrogenase chemistry, Molecular Conformation, Ferrous Compounds chemistry, Hydrogenase metabolism, Nickel chemistry, Sulfhydryl Compounds chemistry

Abstract

Described herein are preparations of synthetic models for the deactivated Ni(II)Fe(II) states of the [NiFe]-hydrogenases. Iodination of the S = ½ species [(dppe)Ni(pdt)Fe(CO)(3)](+) afforded the diamagnetic iodo complex [(dppe)Ni(pdt)IFe(CO)(3)](+). Crystallographic analysis of this species confirmed the presence of square-pyramidal Ni linked to an octahedral Fe centre. The NiFe separation of 3.018 Å indicated the absence of metal-metal bonding. This complex could be reduced to give (dppe)Ni(pdt)Fe(CO)(3) and, in the presence of iodide, decarbonylated to afford (dppe)Ni(pdt)FeI(2). Derivatives of the type [(diphosphine)Ni(dithiolate)XFe(CO)(2)L](+) (X = Cl, Br, I) were prepared by halogenation of mixed-valence precursors [(diphosphine)Ni(dithiolate)Fe(CO)(2)L](+) (diphosphine = dppe, dcpe; L = tertiary phosphine or CO). The Fe(CO)(2)(PR(3))-containing derivatives are more robust than the related tricarbonyl derivatives. Exploiting this greater stability, we characterised examples of chloride and bromide derivatives. Related fluorides could be prepared by F(-) abstraction from BF(4)(-). Spectroscopic evidence is presented for the hydroperoxide [(dppe)Ni(pdt)(OOH)Fe(CO)(2)L](+), which represents a model for the Ni-SU state.

Published

2012

30. Synthetic models for the active site of the [FeFe]-hydrogenase: catalytic proton reduction and the structure of the doubly protonated intermediate.

Author

Carroll ME, Barton BE, Rauchfuss TB, and Carroll PJ

Subjects

Biocatalysis, Catalytic Domain, Ferrous Compounds chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Models, Molecular, Molecular Conformation, Oxidation-Reduction, Ferrous Compounds metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Protons

Abstract

This report compares biomimetic hydrogen evolution reaction catalysts with and without the amine cofactor (adt(NH)): Fe(2)(adt(NH))(CO)(2)(dppv)(2) (1(NH)) and Fe(2)(pdt)(CO)(2)(dppv)(2) (2) [(adt(NH))(2-) = HN(CH(2)S)(2)(2-), pdt(2-) = 1,3-(CH(2))(3)S(2)(2-), and dppv = cis-C(2)H(2)(PPh(2))(2)]. These compounds are spectroscopically, structurally, and stereodynamically very similar but exhibit very different catalytic properties. Protonation of 1(NH) and 2 gives three isomeric hydrides each, beginning with the kinetically favored terminal hydride, which converts sequentially to sym and unsym isomers of the bridging hydrides. In the case of 1(NH), the corresponding ammonium hydrides are also observed. In the case of the terminal amine hydride [t-H1(NH)]BF(4), the ammonium/amine hydride equilibrium is sensitive to counteranions and solvent. The species [t-H1(NH(2))](BF(4))(2) represents the first example of a crystallographically characterized terminal hydride produced by protonation. The NH---HFe distance of 1.88(7) Å indicates dihydrogen-bonding. The bridging hydrides [μ-H1(NH)](+) and [μ-H2](+) reduce near -1.8 V, about 150 mV more negative than the reductions of the terminal hydride [t-H1(NH)](+) and [t-H2](+) at -1.65 V. Reductions of the amine hydrides [t-H1(NH)](+) and [t-H1(NH(2))](2+) are irreversible. For the pdt analogue, the [t-H2](+/0) couple is unaffected by weak acids (pK(a)(MeCN) = 15.3) but exhibits catalysis with HBF(4)·Et(2)O, albeit with a turnover frequency (TOF) around 4 s(-1) and an overpotential greater than 1 V. The voltammetry of [t-H1(NH)](+) is strongly affected by relatively weak acids and proceeds at 5000 s(-1) with an overpotential of 0.7 V. The ammonium hydride [t-H1(NH(2))](2+) is a faster catalyst, with an estimated TOF of 58 000 s(-1) and an overpotential of 0.5 V.

Published

2012

31. EPR/ENDOR, Mössbauer, and quantum-chemical investigations of diiron complexes mimicking the active oxidized state of [FeFe]hydrogenase.

Author

Silakov A, Olsen MT, Sproules S, Reijerse EJ, Rauchfuss TB, and Lubitz W

Subjects

Binding Sites, Catalysis, Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Ferrous Compounds chemistry, Hydrogen, Iron-Sulfur Proteins chemistry, Models, Molecular, Oxidation-Reduction, Quantum Theory, Spectroscopy, Mossbauer, Stereoisomerism, Biomimetic Materials chemical synthesis, Electrons, Hydrogenase chemistry, Organometallic Compounds chemical synthesis, Sulfhydryl Compounds chemistry

Abstract

Understanding the catalytic process of the heterolytic splitting and formation of molecular hydrogen is one of the key topics for the development of a future hydrogen economy. With an interest in elucidating the enzymatic mechanism of the [Fe(2)(S(2)C(2)H(4)NH)(CN)(2)(CO)(2)(μ-CO)] active center uniquely found in [FeFe]hydrogenases, we present a detailed spectroscopic and theoretical analysis of its inorganic model [Fe(2)(S(2)X)(CO)(3)(dppv)(PMe(3))](+) [dppv = cis-1,2-bis(diphenylphosphino)ethylene] in two forms with S(2)X = ethanedithiolate (1edt) and azadithiolate (1adt). These complexes represent models for the oxidized mixed-valent Fe(I)Fe(II) state analogous to the active oxidized "H(ox)" state of the native H-cluster. For both complexes, the (31)P hyperfine interactions were determined by pulse electron paramagnetic resonance and electron nuclear double resonance (ENDOR) methods. For 1edt, the (57)Fe parameters were measured by electron spin-echo envelope modulation and Mössbauer spectroscopy, while for 1adt, (14)N and selected (1)H couplings could be obtained by ENDOR and hyperfine sublevel correlation spectroscopy. The spin density was found to be predominantly localized on the Fe(dppv) site. This spin distribution is different from that of the H-cluster, where both the spin and charge densities are delocalized over the two Fe centers. This difference is attributed to the influence of the "native" cubane subcluster that is lacking in the inorganic models. The degree and character of the unpaired spin delocalization was found to vary from 1edt, with an abiological dithiolate, to 1adt, which features the authentic cofactor. For 1adt, we find two (14)N signals, which are indicative for two possible isomers of the azadithiolate, demonstrating its high flexibility. All interaction parameters were also evaluated through density functional theory calculations at various levels.

Published

2012

32. Mixed-valence nickel-iron dithiolate models of the [NiFe]-hydrogenase active site.

Author

Schilter D, Nilges MJ, Chakrabarti M, Lindahl PA, Rauchfuss TB, and Stein M

Subjects

Catalytic Domain, Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Models, Molecular, Phosphines chemistry, Spectroscopy, Mossbauer, Biomimetic Materials chemistry, Hydrogenase chemistry, Iron chemistry, Nickel chemistry, Sulfhydryl Compounds chemistry

Abstract

A series of mixed-valence nickel-iron dithiolates is described. Oxidation of (diphosphine)Ni(dithiolate)Fe(CO)(3) complexes 1, 2, and 3 with ferrocenium salts affords the corresponding tricarbonyl cations [(dppe)Ni(pdt)Fe(CO)(3)](+) ([1](+)), [(dppe)Ni(edt)Fe(CO)(3)](+) ([2](+)) and [(dcpe)Ni(pdt)Fe(CO)(3)](+) ([3](+)), respectively, where dppe = Ph(2)PCH(2)CH(2)PPh(2), dcpe = Cy(2)PCH(2)CH(2)PCy(2), (Cy = cyclohexyl), pdtH(2) = HSCH(2)CH(2)CH(2)SH, and edtH(2) = HSCH(2)CH(2)SH. The cation [2](+) proved unstable, but the propanedithiolates are robust. IR and EPR spectroscopic measurements indicate that these species exist as C(s)-symmetric species. Crystallographic characterization of [3]BF(4) shows that Ni is square planar. Interaction of [1]BF(4) with P-donor ligands (L) afforded a series of substituted derivatives of type [(dppe)Ni(pdt)Fe(CO)(2)L]BF(4) for L = P(OPh)(3) ([4a]BF(4)), P(p-C(6)H(4)Cl)(3) ([4b]BF(4)), PPh(2)(2-py) ([4c]BF(4)), PPh(2)(OEt) ([4d]BF(4)), PPh(3) ([4e]BF(4)), PPh(2)(o-C(6)H(4)OMe) ([4f]BF(4)), PPh(2)(o-C(6)H(4)OCH(2)OMe) ([4g]BF(4)), P(p-tol)(3) ([4h]BF(4)), P(p-C(6)H(4)OMe)(3) ([4i]BF(4)), and PMePh(2) ([4j]BF(4)). EPR analysis indicates that ethanedithiolate [2](+) exists as a single species at 110 K, whereas the propanedithiolate cations exist as a mixture of two conformers, which are proposed to be related through a flip of the chelate ring. Mössbauer spectra of 1 and oxidized S = 1/2 [4e]BF(4) are both consistent with a low-spin Fe(I) state. The hyperfine coupling tensor of [4e]BF(4) has a small isotropic component and significant anisotropy. DFT calculations using the BP86, B3LYP, and PBE0 exchange-correlation functionals agree with the structural and spectroscopic data, suggesting that the SOMOs in complexes of the present type are localized in an Fe(I)-centered d(z(2)) orbital. The DFT calculations allow an assignment of oxidation states of the metals and rationalization of the conformers detected by EPR spectroscopy. Treatment of [1](+) with CN(-) and compact basic phosphines results in complex reactions. With dppe, [1](+) undergoes quasi-disproportionation to give 1 and the diamagnetic complex [(dppe)Ni(pdt)Fe(CO)(2)(dppe)](2+) ([5](2+)), which features square-planar Ni linked to an octahedral Fe center.

Published

2012

33. Combining acid-base, redox and substrate binding functionalities to give a complete model for the [FeFe]-hydrogenase.

Author

Camara JM and Rauchfuss TB

Subjects

Binding Sites, Catalytic Domain, Oxidation-Reduction, Substrate Specificity, Ferredoxins chemistry, Hydrogenase chemistry, Models, Biological

Abstract

Some enzymes function by coupling substrate turnover with electron transfer from a redox cofactor such as ferredoxin. In the [FeFe]-hydrogenases, nature's fastest catalysts for the production and oxidation of H(2), the one-electron redox by a ferredoxin complements the one-electron redox by the diiron active site. In this Article, we replicate the function of the ferredoxins with the redox-active ligand Cp*Fe(C(5)Me(4)CH(2)PEt(2)) (FcP*). FcP* oxidizes at mild potentials, in contrast to most ferrocene-based ligands, which suggests that it might be a useful mimic of ferredoxin cofactors. The specific model is Fe(2)[(SCH(2))(2)NBn](CO)(3)(FcP*)(dppv) (1), which contains the three functional components of the active site: a reactive diiron centre, an amine as a proton relay and, for the first time, a one-electron redox module. By virtue of the synthetic redox cofactor, [1](2+) exhibits unique reactivity towards hydrogen and CO. In the presence of excess oxidant and base, H(2) oxidation by [1](2+) is catalytic.

Published

2011

34. Active-site models for the nickel-iron hydrogenases: effects of ligands on reactivity and catalytic properties.

Author

Carroll ME, Barton BE, Gray DL, Mack AE, and Rauchfuss TB

Subjects

Catalytic Domain, Crystallography, X-Ray, Magnetic Resonance Spectroscopy, Models, Molecular, Phosphines chemical synthesis, Spectrometry, Mass, Electrospray Ionization, Spectroscopy, Fourier Transform Infrared, Sulfhydryl Compounds chemical synthesis, Hydrogenase chemistry, Phosphines chemistry, Sulfhydryl Compounds chemistry

Abstract

Described are new derivatives of the type [HNiFe(SR)(2)(diphosphine)(CO)(3)](+), which feature a Ni(diphosphine) group linked to a Fe(CO)(3) group by two bridging thiolate ligands. Previous work had described [HNiFe(pdt)(dppe)(CO)(3)](+) ([1H](+)) and its activity as a catalyst for the reduction of protons (J. Am. Chem. Soc. 2010, 132, 14877). Work described in this paper focuses on the effects on properties of NiFe model complexes of the diphosphine attached to nickel as well as the dithiolate bridge, 1,3-propanedithiolate (pdt) vs 1,2-ethanedithiolate (edt). A new synthetic route to these Ni-Fe dithiolates is described, involving reaction of Ni(SR)(2)(diphosphine) with FeI(2)(CO)(4) followed by in situ reduction with cobaltocene. Evidence is presented that this route proceeds via a metastable μ-iodo derivative. Attempted isolation of such species led to the crystallization of NiFe(Me(2)pdt)(dppe)I(2), which features tetrahedral Fe(II) and square planar Ni(II) centers (H(2)Me(2)pdt = 2,2-dimethylpropanedithiol). The new tricarbonyls prepared in this work are NiFe(pdt)(dcpe)(CO)(3) (2, dcpe = 1,2-bis(dicyclohexylphosphino)ethane), NiFe(edt)(dppe)(CO)(3) (3), and NiFe(edt)(dcpe)(CO)(3) (4). Attempted preparation of a phenylthiolate-bridged complex via the FeI(2)(CO)(4) + Ni(SPh)(2)(dppe) route gave the tetrametallic species [(CO)(2)Fe(SPh)(2)Ni(CO)](2)(μ-dppe)(2). Crystallographic analysis of the edt-dcpe compund [2H]BF(4) and the edt-dppe compound [3H]BF(4) verified their close resemblance. Each features pseudo-octahedral Fe and square pyramidal Ni centers. Starting from [3H]BF(4) we prepared the PPh(3) derivative [HNiFe(edt)(dppe)(PPh(3))(CO)(2)]BF(4) ([5H]BF(4)), which was obtained as a ∼2:1 mixture of unsymmetrical and symmetrical isomers. Acid-base measurements indicate that changing from Ni(dppe) (dppe = Ph(2)PCH(2)CH(2)PPh(2)) to Ni(dcpe) decreases the acidity of the cationic hydride complexes by 2.5 pK(a)(PhCN) units, from ∼11 to ∼13.5 (previous work showed that substitution at Fe leads to more dramatic effects). The redox potentials are more strongly affected by the change from dppe to dcpe, for example the [2](0/+) couple occurs at E(1/2) = -820 for [2](0/+) vs -574 mV (vs Fc(+/0)) for [1](0/+). Changes in the dithiolate do not affect the acidity or the reduction potentials of the hydrides. The acid-independent rate of reduction of CH(2)ClCO(2)H by [2H](+) is about 50 s(-1) (25 °C), twice that of [1H](+). The edt-dppe complex [2H](+) proved to be the most active catalyst, with an acid-independent rate of 300 s(-1).

Published

2011

35. Mild redox complementation enables H2 activation by [FeFe]-hydrogenase models.

Author

Camara JM and Rauchfuss TB

Subjects

Deuterium, Electron Spin Resonance Spectroscopy, Kinetics, Oxidation-Reduction, Hydrogen chemistry, Hydrogenase chemistry, Protons

Abstract

Mild oxidants such as [Fe(C(5)Me(5))(2)](+) accelerate the activation of H(2) by [Fe(2)[(SCH(2))(2)NBn](CO)(3)(dppv)(PMe(3))](+) ([1](+)), despite the fact that the ferrocenium cation is incapable of oxidizing [1](+). The reaction is first-order in [1](+) and [H(2)] but independent of the E(1/2) and concentration of the oxidant. The analogous reaction occurs with D(2) and proceeds with an inverse kinetic isotope effect of 0.75(8). The activation of H(2) is further enhanced with the tetracarbonyl [Fe(2)[(SCH(2))(2)NBn](CO)(4)(dppn)](+) ([2](+)), the first crystallographically characterized model for the H(ox) state of the active site containing an amine cofactor. These studies point to rate-determining binding of H(2) followed by proton-coupled electron transfer. Relative to that by [1](+), the rate of H(2) activation by [2](+)/Fc(+) is enhanced by a factor of 10(4) at 25 °C., (© 2011 American Chemical Society)

Published

2011

36. Role of the azadithiolate cofactor in models for [FeFe]-hydrogenase: novel structures and catalytic implications.

Author

Olsen MT, Rauchfuss TB, and Wilson SR

Subjects

Catalysis, Catalytic Domain, Molecular Structure, Oxidation-Reduction, Stereoisomerism, Thermodynamics, Aza Compounds chemistry, Coenzymes chemistry, Coenzymes physiology, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Models, Molecular

Abstract

This paper summarizes studies on the redox behavior of synthetic models for the [FeFe]-hydrogenases, consisting of diiron dithiolato carbonyl complexes bearing the amine cofactor and its N-benzyl derivative. Of specific interest are the causes of the low reactivity of oxidized models toward H(2), which contrasts with the high activity of these enzymes for H(2) oxidation. The redox and acid-base properties of the model complexes [Fe(2)[(SCH(2))(2)NR](CO)(3)(dppv)(PMe(3))](+) ([2](+) for R = H and [2'](+) for R = CH(2)C(6)H(5), dppv = cis-1,2-bis(diphenylphosphino)ethylene)) indicate that addition of H(2) followed by deprotonation are (i) endothermic for the mixed valence (Fe(II)Fe(I)) state and (ii) exothermic for the diferrous (Fe(II)Fe(II)) state. The diferrous state is shown to be unstable with respect to coordination of the amine to Fe, a derivative of which was characterized crystallographically. The redox and acid-base properties for the mixed valence models differ strongly for those containing the amine cofactor versus those derived from propanedithiolate. Protonation of [2'](+) induces disproportionation to a 1:1 mixture of the ammonium [H2'](+) (Fe(I)Fe(I)) and the dication [2'](2+) (Fe(II)Fe(II)). This effect is consistent with substantial enhancement of the basicity of the amine in the Fe(I)Fe(I) state vs the Fe(II)Fe(I) state. The Fe(I)Fe(I) ammonium compounds are rapid and efficient H-atom donors toward the nitroxyl compound TEMPO. The atom transfer is proposed to proceed via the hydride. Collectively, the results suggest that proton-coupled electron-transfer pathways should be considered for H(2) activation by the [FeFe]-hydrogenases.

Published

2010

37. Iron acyl thiolato carbonyls: structural models for the active site of the [Fe]-hydrogenase (Hmd).

Author

Royer AM, Salomone-Stagni M, Rauchfuss TB, and Meyer-Klaucke W

Subjects

Cyanides chemistry, Heterocyclic Compounds chemistry, Methanococcus enzymology, Phosphines chemistry, Protons, Catalytic Domain, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Models, Molecular, Organometallic Compounds chemistry

Abstract

Phosphine-modified thioester derivatives are shown to serve as efficient precursors to phosphine-stabilized ferrous acyl thiolato carbonyls, which replicate key structural features of the active site of the hydrogenase Hmd. The reaction of Ph(2)PC(6)H(4)C(O)SPh and sources of Fe(0) generates both Fe(SPh)(Ph(2)PC(6)H(4)CO)(CO)(3) (1) and the diferrous diacyl Fe(2)(SPh)(2)(CO)(3)(Ph(2)PC(6)H(4)CO)(2), which carbonylates to give 1. For the extremely bulky arylthioester Ph(2)PC(6)H(4)C(O)SC(6)H(3)-2,6-(2,4,6-trimethylphenyl)(2), oxidative addition is arrested and the Fe(0) adduct of the phosphine is obtained. Complex 1 reacts with cyanide to give Et(4)N[Fe(SPh)(Ph(2)PC(6)H(4)CO)(CN)(CO)(2)] (Et(4)N[2]). (13)C and (31)P NMR spectra indicate that substitution is stereospecific and cis to P. The IR spectrum of [2](-) in ν(CN) and ν(CO) regions very closely matches that for Hmd(CN). XANES and EXAFS measurements also indicate close structural and electronic similarity of Et(4)N[2] to the active site of wild-type Hmd. Complex 1 also stereospecifically forms a derivative with TsCH(2)NC, but the adduct is more labile than Et(4)N[2]. Tricarbonyl 1 was found to reversibly protonate to give a thermally labile derivative, IR measurements of which indicate that the acyl and thiolate ligands are probably not protonated in Hmd.

Published

2010

38. Hydride-containing models for the active site of the nickel-iron hydrogenases.

Author

Barton BE and Rauchfuss TB

Subjects

Catalysis, Catalytic Domain, Crystallography, X-Ray, Hydrogenase chemistry, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Spectroscopy, Fourier Transform Infrared, Hydrogen chemistry, Hydrogenase metabolism, Models, Chemical

Abstract

The [NiFe]-hydrogenase model complex NiFe(pdt)(dppe)(CO)(3) (1) (pdt = 1,3-propanedithiolate) has been efficiently synthesized and found to be robust. This neutral complex sustains protonation to give the first nickel-iron hydride [1H]BF(4). One CO ligand in [1H]BF(4) is readily substituted by organophosphorus ligands to afford the substituted derivatives [HNiFe(pdt)(dppe)(PR(3))(CO)(2)]BF(4), where PR(3) = P(OPh)(3) ([2H]BF(4)); PPh(3) ([3H]BF(4)); PPh(2)Py ([4H]BF(4), where Py = 2-pyridyl). Variable temperature NMR measurements show that the neutral and protonated derivatives are dynamic on the NMR time scale, which partially symmetrizes the phosphine complex. The proposed stereodynamics involve twisting of the Ni(dppe) center, not rotation at the Fe(CO)(2)(PR(3)) center. In MeCN solution, 3, which can be prepared by deprotonation of [3H]BF(4) with NaOMe, is about 10(4) stronger base than is 1. X-ray crystallographic analysis of [3H]BF(4) revealed a highly unsymmetrical bridging hydride, the Fe-H bond being 0.40 Å shorter than the Ni-H distance. Complexes [2H]BF(4), [3H]BF(4), and [4H]BF(4) undergo reductions near -1.46 V vs Fc(0/+). For [2H]BF(4), this reduction process is reversible, and we assign it as a one-electron process. In the presence of trifluoroacetic acid, proton reduction catalysis coincides with this reductive event. The dependence of i(c)/i(p) on the concentration of the acid indicates that H(2) evolution entails protonation of a reduced hydride. For [2H](+), [3H](+), and [4H](+), the acid-independent rate constants are 50-75 s(-1). For [2H](+) and [3H](+), the overpotentials for H(2) evolution are estimated to be 430 mV, whereas the overpotential for the N-protonated pyridinium complex [4H(2)](2+) is estimated to be 260 mV. The mechanism of H(2) evolution is proposed to follow an ECEC sequence, where E and C correspond to one-electron reductions and protonations, respectively. On the basis of their values for its pK(a) and redox potentials, the room temperature values of ΔG(H•) and ΔG(H-) are estimated as respectively as 57 and 79 kcal/mol for [1H](+).

Published

2010

39. Unraveling the biosynthesis of nature's fastest hydrogenase.

Author

Rauchfuss TB

Subjects

Cyanides chemical synthesis, Glycine chemistry, Ligands, Molecular Structure, Hydrogenase biosynthesis

Published

2010

40. Artificial hydrogenases.

Author

Barton BE, Olsen MT, and Rauchfuss TB

Subjects

Biomimetics, Hydrogen metabolism, Iron metabolism, Iron-Sulfur Proteins metabolism, Hydrogenase metabolism

Abstract

Decades of biophysical study on the hydrogenase (H(2)ase) enzymes have yielded sufficient information to guide the synthesis of analogs of their active sites. Three families of enzymes serve as inspiration for this work: the [FeFe]-H(2)ases, [NiFe]-H(2)ases, and [Fe]-H(2)ases, all of which feature iron centers bound to both CO and thiolate. Artificial H(2)ases affect the oxidation of H(2) and the reverse reaction, the reduction of protons. These reactions occur via the intermediacy of metal hydrides. The inclusion of amine bases within the catalysts is an important design feature that is emulated in related bioinspired catalysts. Continuing challenges are the low reactivity of H(2) toward biomimetic H(2)ases., (Copyright 2010 Elsevier Ltd. All rights reserved.)

Published

2010

41. The iron-site structure of [Fe]-hydrogenase and model systems: an X-ray absorption near edge spectroscopy study.

Author

Salomone-Stagni M, Stellato F, Whaley CM, Vogt S, Morante S, Shima S, Rauchfuss TB, and Meyer-Klaucke W

Subjects

Bacterial Proteins chemistry, Carbon chemistry, Hydrogen chemistry, Molecular Structure, Oxidation-Reduction, X-Ray Absorption Spectroscopy, Hydrogenase chemistry, Iron chemistry, Iron-Sulfur Proteins chemistry, Models, Molecular

Abstract

The [Fe]-hydrogenase is an ideal system for studying the electronic properties of the low spin iron site that is common to the catalytic centres of all hydrogenases. Because they have no auxiliary iron-sulfur clusters and possess a cofactor containing a single iron centre, the [Fe]-hydrogenases are well suited for spectroscopic analysis of those factors required for the activation of molecular hydrogen. Specifically, in this study we shed light on the electronic and molecular structure of the iron centre by XAS analysis of [Fe]-hydrogenase from Methanocaldococcus jannashii and five model complexes (Fe(ethanedithiolate)(CO)(2)(PMe(3))(2), [K(18-crown-6)](2)[Fe(CN)(2)(CO)(3)], K[Fe(CN)(CO)(4)], K(3)[Fe(III)(CN)(6)], K(4)[Fe(II)(CN)(6)]). The different electron donors have a strong influence on the iron absorption K-edge energy position, which is frequently used to determine the metal oxidation state. Our results demonstrate that the K-edges of Fe(II) complexes, achieved with low-spin ferrous thiolates, are consistent with a ferrous centre in the [Fe]-hydrogenase from Methanocaldococcus jannashii. The metal geometry also strongly influences the XANES and thus the electronic structure. Using in silico simulation, we were able to reproduce the main features of the XANES spectra and describe the effects of individual donor contributions on the spectra. Thereby, we reveal the essential role of an unusual carbon donor coming from an acyl group of the cofactor in the determination of the electronic structure required for the activity of the enzyme.

Published

2010

42. Isomerization of the hydride complexes [HFe2(SR)2(PR3)(x)(CO)(6-x)]+ (x = 2, 3, 4) relevant to the active site models for the [FeFe]-hydrogenases.

Author

Barton BE, Zampella G, Justice AK, De Gioia L, Rauchfuss TB, and Wilson SR

Subjects

Hydrogenase metabolism, Isomerism, Models, Molecular, Molecular Conformation, Protein Structure, Tertiary, Protons, Sulfhydryl Compounds chemistry, Hydrogen chemistry, Hydrogenase chemistry, Iron chemistry

Abstract

The stepwise formation of bridging (mu-) hydrides of diiron dithiolates is discussed with attention on the pathway for protonation and subsequent isomerizations. Our evidence is consistent with protonations occurring at a single Fe center, followed by isomerization to a series of mu-hydrides. Protonation of Fe(2)(edt)(CO)(4)(dppv) (1) gave a single mu-hydride with dppv spanning apical and basal sites, which isomerized at higher temperatures to place the dppv into a dibasal position. Protonation of Fe(2)(pdt)(CO)(4)(dppv) (2) followed an isomerization pathway similar to that for [1H](+), except that a pair of isomeric terminal hydrides were observed initially, resulting from protonation at the Fe(CO)(3) or Fe(CO)(dppv) site. The first observable product from low temperature protonation of the tris-phosphine Fe(2)(edt)(CO)(3)(PMe(3))(dppv) (3) was a single mu-hydride wherein PMe(3) is apical and the dppv ligand spans apical and basal sites. Upon warming, this isomer converted fully but in a stepwise manner to a mixture of three other isomeric hydrides. Protonation of Fe(2)(pdt)(CO)(3)(PMe(3))(dppv) (4) proceeded similarly to the edt analogue 3, however a terminal hydride was observed, albeit only briefly and at very low temperatures (-90 degrees C). Low-temperature protonation of the bis-chelates Fe(2)(xdt)(CO)(2)(dppv)(2) produced exclusively the terminal hydrides [HFe(2)(xdt)(mu-CO)(CO)(dppv)(2)](+) (xdt = edt and pdt), which subsequently isomerized to a pair of mu-hydrides. At room temperature these (dppv)(2) derivatives convert to an equilibrium of two isomers, one C(2)-symmetric and the other C(s)-symmetric. The stability of the terminal hydrides correlates with the (C(2)-isomer)/(C(s)-isomer) equilibrium ratio, which reflects the size of the dithiolate. The isomerization was found to be unaffected by the presence of excess acid, by solvent polarity, and the presence of D(2)O. This isomerization mechanism is proposed to be intramolecular, involving a 120 degrees rotation of the HFeL(3) subunit to an unobserved terminal basal hydride as the rate-determining step. The observed stability of the hydrides was supported by DFT calculations, which also highlight the instability of the basal terminal hydrides. Isomerization of the mu-hydride isomers occurs on alternating FeL(3) via 120 degree rotations without generating D(2)O-exchangeable intermediates.

Published

2010

43. Nickel-iron dithiolato hydrides relevant to the [NiFe]-hydrogenase active site.

Author

Barton BE, Whaley CM, Rauchfuss TB, and Gray DL

Subjects

Catalytic Domain, Hydrogenase metabolism, Iron Compounds chemical synthesis, Models, Molecular, Organometallic Compounds chemical synthesis, Sulfhydryl Compounds chemical synthesis, Hydrogenase chemistry, Iron Compounds chemistry, Nickel chemistry, Organometallic Compounds chemistry, Organophosphorus Compounds chemistry, Sulfhydryl Compounds chemistry

Abstract

The ferrous dithiolato carbonyl Fe(S(2)C(3)H(6))(CO)(2)(dppe) (1) condenses with NiCl(2)(dppe) to give [FeNi(pdt)(mu-Cl)(CO)(dppe)(2)]BF(4) ([2Cl](+)). The corresponding reaction of the ditosylate Ni(OTs)(2)(dppe) gave the dication [(CO)(2)(dppe)Fe(pdt)Ni(dppe)](OTs)(2) ([2(CO)](OTs)(2)) (pdt = 1,3-propanedithiolate; dppe = 1,2-C(2)H(4)(PPh(2))(2); OTs(-) = CH(3)C(6)H(4)-4-SO(3)(-)). Reduction of the bimetallic dicarbonyl with borohydride salts afforded impure, thermally stable hydride, [(CO)(dppe)Fe(pdt)(mu-H)Ni(dppe)](+) ([2H](+)). A reliable route to NiFe(SR)(2)H species entailed protonation of (CO)(3)Fe(pdt)Ni(dppe) to give [(CO)(3)Fe(pdt)(mu-H)Ni(dppe)](+) ([3H](+)). The iron-nickel dithiolato hydride, [3H]BF(4), was characterized crystallographically: as anticipated by biophysical studies, the hydride ligand is bridging, the Fe center is octahedral, and the Ni center is pentacoordinate. Solutions of [3H]BF(4) undergo substitution by dppe to give [2H](+). The hydride undergoes rapid deprotonation and is an electrocatalyst for hydrogen evolution from trifluoroacetic acid. Oxidation of 3 gives a mixed valence species [3](+), a potential model for the Ni-L state.

Published

2009

44. Coordination chemistry of [HFe(CN)(2)(CO)(3)](-) and its derivatives: toward a model for the iron subsite of the [NiFe]-hydrogenases.

Author

Whaley CM, Rauchfuss TB, and Wilson SR

Subjects

Binding Sites, Catalysis, Chemical Phenomena, Crystallography, X-Ray, Molecular Structure, Organometallic Compounds chemistry, Thermodynamics, Biomimetic Materials chemistry, Hydrogenase chemistry, Iron chemistry, Models, Molecular

Abstract

The photoreaction of Fe(CO)(5) and cyanide salts in MeCN solution affords the dianion [Fe(CN)(2)(CO)(3)](2-), conveniently isolated as [K(18-crown-6)](2)[Fe(CN)(2)(CO)(3)]. Solutions of [Fe(CN)(2)(CO)(3)](2-) oxidize irreversibly at -600 mV (vs Ag/AgCl) to give primarily [Fe(CN)(3)(CO)(3)](-). Protonation of the dianion affords the hydride [K(18-crown-6)][HFe(CN)(2)(CO)(3)] with a pK(a) approximately 17 (MeCN). The ferrous hydride exhibits enhanced electrophilicity vs its dianionic precursor, which resists substitution. Treatment of [K(18-crown-6)][Fe(CN)(2)(CO)(3)] with tertiary phosphines and phosphites gives isomeric mixtures of [HFe(CN)(2)(CO)(2)L](-) (L = P(OPh)(3) and PPh(3)). Carbonyl substitution on [1H(CO)(2)](-) by P(OPh)(3) is first-order in both the phosphite and iron (k = 0.18 M(-1) s(-1) at 22 degrees C) with DeltaH(double dagger) = 51.6 kJ mol(-1) and DeltaS(double dagger) = -83.0 J K(-1) mol(-1). These ligands are displaced under an atmosphere of CO. With cis-Ph(2)PCH=CHPPh(2) (dppv), we obtained the monocarbonyl, [HFe(CN)(2)(CO)(dppv)](-), a highly basic hydride (pK(a) > 23.3) that rearranges in solution to a single isomer. Treatment of [K(18-crown-6)][HFe(CN)(2)(CO)(3)] with Et(4)NCN resulted in rapid deprotonation to give [Fe(CN)(2)(CO)(3)](2-) and HCN. The tricyano hydride [HFe(CN)(3)(CO)(2)](2-) is prepared by the reaction of [HFe(CN)(2)(CO)(2)(PPh(3))](-) and [K(18-crown-6)]CN. Similar to the phosphine and phosphite derivatives, [HFe(CN)(3)(CO)(2)](2-) exists as a mixture of all three possible isomers. Protonation of the hydrides [HFe(CN)(2)(CO)(dppv)](-) and [HFe(CN)(3)(CO)(2)](-) in acetonitrile solutions releases H(2) and gives the corresponding acetonitrile complexes [K(18-crown-6)][Fe(CN)(3)(NCMe)(CO)(2)] and Fe(CN)(2)(NCMe)(CO)(dppv). Alkylation of [K(18-crown-6)](2)[Fe(CN)(2)(CO)(3)] with MeOTf gives the thermally unstable [MeFe(CN)(2)(CO)(3)](-), which was characterized spectroscopically at -40 degrees C. Reaction of dppv with [MeFe(CN)(2)(CO)(3)](-) gives the acetyl complex, [Fe(CN)(2)(COMe)(CO)(dppv)](-). Whereas [Fe(CN)(2)(CO)(3)](2-) undergoes protonation and methylation at Fe, acid chlorides give the iron(0) N-acylisocyanides [Fe(CN)(CO)(3)(CNCOR)](-) (R = Ph, CH(3)). The solid state structures of [K(18-crown-6)][HFe(CN)(2)(CO)(dppv)], Fe(CN)(2)(NCMe)(CO)(dppv), and [K(18-crown-6)](2)[HFe(CN)(3)(CO)(2)] were confirmed crystallographically. In all three cases, the cyanide ligands are cis to the hydride or acetonitrile ligands.

Published

2009

45. Small molecule mimics of hydrogenases: hydrides and redox.

Author

Gloaguen F and Rauchfuss TB

Subjects

Bacterial Proteins metabolism, Biocatalysis, Catalytic Domain, Clostridium enzymology, Desulfovibrio desulfuricans enzymology, Ferric Compounds metabolism, Hydrogenase metabolism, Iron chemistry, Iron metabolism, Oxidation-Reduction, Small Molecule Libraries, Sulfhydryl Compounds metabolism, Bacterial Proteins chemistry, Biomimetics trends, Ferric Compounds chemistry, Hydrogen metabolism, Hydrogenase chemistry, Sulfhydryl Compounds chemistry

Abstract

This tutorial review is aimed at chemical scientists interested in understanding and exploiting the remarkable catalytic behavior of the hydrogenases. The key structural features are analyzed for the active sites of the two most important hydrogenases. Reactivity is emphasized, focusing on mechanism and catalysis. Through this analysis, gaps are identified in the synthesis of functional replicas of these fascinating and potentially useful enzymes.

Published

2009

46. Aza- and oxadithiolates are probable proton relays in functional models for the [FeFe]-hydrogenases.

Author

Barton BE, Olsen MT, and Rauchfuss TB

Subjects

Calcitriol chemistry, Catalytic Domain, Molecular Structure, Aza Compounds chemistry, Calcitriol analogs & derivatives, Hydrogenase chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, Models, Biological, Protons, Sulfhydryl Compounds chemistry

Abstract

The dithiolate cofactor for the [FeFe]-hydrogenase models, Fe(2)(xdt)(CO)(2)(dppv)(2) (where xdt = 1,3-propanedithiolate (pdt), azadithiolate (adt), (SCH(2))(2)NH, and oxadithiolate (odt), (SCH(2))(2)O; dppv = cis-1,2-bis(diphenylphosphino)ethylene) have been probed for their functionality as proton relays enabling formation and deprotonation of terminal hydrides. Compared to the propanedithiolate derivative, the azadithiolate and oxaditiholate show enhanced rates of proton transfer between solution and the terminal site on one Fe center. The results are consistent with the heteroatom of the dithiolate serving a gating role for both protonation and deprotonation. The pK(a) of the transiently formed ammonium (pK(CD(2))(Cl(2)) 5.7-8.2) or oxonium (pK(CD(2))(Cl(2)) -4.7-1.6) regulates the proton transfer. As a consequence, only the azadithiolate is capable of yielding the terminal hydride from weak acids. The aza- and oxadithiolates manifested the advantages of proton relays: the odt derivative proved to be a faster catalyst for hydrogen evolution than the pdt derivative as indicated from cyclic voltammetry plots of i(c)/i(p) vs [H(+)]. The adt derivative was capable of proton reduction from the weak acid [HPMe(2)Ph]BF(4) (pK(CD(2))(Cl(2)) = 5.7). The proton relay function does not apply to the isomeric bridged-hydrides [Fe(2)(xdt)(mu-H)(CO)(2)(dppv)(2)](+), where the hydride is too distant and too basic to interact to be affected by the heteroatomic relay site. None of these mu-H species can be deprotonated.

Published

2008

47. New nitrosyl derivatives of diiron dithiolates related to the active site of the [FeFe]-hydrogenases.

Author

Olsen MT, Justice AK, Gloaguen F, Rauchfuss TB, and Wilson SR

Subjects

Catalysis, Catalytic Domain, Crystallography, X-Ray, Cyanides, Electrochemistry, Kinetics, Ligands, Magnetic Resonance Spectroscopy, Models, Molecular, Spectrophotometry, Infrared, Thermodynamics, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Nitrogen Oxides chemistry, Sulfhydryl Compounds chemistry

Abstract

Nitrosyl derivatives of diiron dithiolato carbonyls have been prepared starting from the precursor Fe(2)(S(2)C(n)H(2n))(dppv)(CO)(4) (dppv = cis-1,2-bis(diphenylphosphinoethylene). These studies expand the range of substituted diiron(I) dithiolato carbonyl complexes. From [Fe(2)(S(2)C(2)H(4))(CO)(3)(dppv)(NO)]BF(4) ([1(CO)(3)]BF(4)), the following compounds were prepared: [1(CO)(2)(PMe(3))]BF(4), [1(CO)(dppv)]BF(4), NEt(4)[1(CO)(CN)(2)], and 1(CO)(CN)(PMe(3)). Some of these substitution reactions occur via the addition of 2 equiv of the nucleophile followed by the dissociation of one nucleophile and decarbonylation. Such a double adduct was characterized crystallographically in the case of [Fe(2)(S(2)C(2)H(4))(CO)(3)(dppv)(NO)(PMe(3))(2)]BF(4). This result shows that the addition of two ligands causes scission of the Fe-Fe bond and one Fe-S bond. When cyanide is the nucleophile, nitrosyl migrates away from the Fe(dppv) site, yielding a Fe(CN)(2)(NO) derivative. Compounds [1(CO)(3)]BF(4), [1(CO)(2)(PMe(3))]BF(4), and [1(CO)(dppv)]BF(4) were also prepared by the addition of NO(+) to the di-, tri-, and tetrasubstituted precursors. In these cases, the NO(+) appears to form an initial 36e(-) adduct containing terminal Fe-NO, followed by decarbonylation. Several complexes were prepared by the addition of NO to the mixed-valence Fe(I)Fe(II) derivatives. The diiron nitrosyl complexes reduce at mild potentials and in certain cases form weak adducts with CO. IR and EPR spectra of 1(CO)(dppv), generated by low-temperature reduction of [1(CO)(dppv)]BF(4) with Co(C(5)Me(5))(2), indicates that the SOMO is located on the FeNO subunit.

Published

2008

48. Nitrosyl derivatives of diiron(I) dithiolates mimic the structure and Lewis acidity of the [FeFe]-hydrogenase active site.

Author

Olsen MT, Bruschi M, De Gioia L, Rauchfuss TB, and Wilson SR

Subjects

Binding Sites, Biomimetic Materials chemistry, Biomimetic Materials metabolism, Crystallography, X-Ray, Electrochemistry, Ferric Compounds metabolism, Hydrogenase metabolism, Iron-Sulfur Proteins metabolism, Models, Molecular, Nuclear Magnetic Resonance, Biomolecular, Sulfhydryl Compounds metabolism, Ferric Compounds chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Nitrogen Oxides chemistry, Sulfhydryl Compounds chemistry

Abstract

This study probes the impact of electronic asymmetry of diiron(I) dithiolato carbonyls. Treatment of Fe2(S2C(n)H(2n))(CO)(6-x)(PMe3)x compounds (n = 2, 3; x = 1, 2, 3) with NOBF4 gave the derivatives [Fe2(S2C(n)H(2n))(CO)(5-x)(PMe3)x(NO)]BF4, which are electronically unsymmetrical because of the presence of a single NO(+) ligand. Whereas the monophosphine derivative is largely undistorted, the bis(PMe3) derivatives are distorted such that the CO ligand on the Fe(CO)(PMe3)(NO)(+) subunit is semibridging. Two isomers of [Fe2(S2C3H6)(CO)3(PMe3)2(NO)]BF4 were characterized spectroscopically and crystallographically. Each isomer features electron-rich Fe(CO)2PMe3 and electrophilic Fe(CO)(PMe3)(NO)(+) subunits. These species are in equilibrium with an unobserved isomer that reversibly binds CO (DeltaH = -35 kJ/mol, DeltaS = -139 J mol(-1) K(-1)) to give the symmetrical adduct [Fe2(S2C3H6)(mu-NO)(CO)4(PMe3)2]BF4. In contrast to Fe2(S2C3H6)(CO)4(PMe3)2, the bis(PMe3) nitrosyl complexes readily undergo CO substitution to give the (PMe3)3 derivatives. The nitrosyl complexes reduce at potentials that are approximately 1 V milder than their carbonyl counterparts. Results of density functional theory calculations, specifically natural bond orbital analysis, reinforce the electronic resemblance of the nitrosyl complexes to the corresponding mixed-valence diiron complexes. Unlike other diiron dithiolato carbonyls, these species undergo reversible reductions at mild potentials. The results show that the novel structural and chemical features associated with mixed-valence diiron dithiolates (the so-called H(ox) models) can be replicated in the absence of mixed-valency by the introduction of electronic asymmetry.

Published

2008

49. Redox and structural properties of mixed-valence models for the active site of the [FeFe]-hydrogenase: progress and challenges.

Author

Justice AK, De Gioia L, Nilges MJ, Rauchfuss TB, Wilson SR, and Zampella G

Subjects

Binding Sites, Crystallography, X-Ray, Cyanides chemistry, Electron Spin Resonance Spectroscopy, Electrons, Ligands, Oxidation-Reduction, Propane analogs & derivatives, Propane chemistry, Propane metabolism, Quantum Theory, Sulfhydryl Compounds chemistry, Sulfhydryl Compounds metabolism, Hydrogenase chemistry, Hydrogenase metabolism, Iron-Sulfur Proteins chemistry, Iron-Sulfur Proteins metabolism, Models, Molecular

Abstract

The one-electron oxidations of a series of diiron(I) dithiolato carbonyls were examined to evaluate the factors that affect the oxidation state assignments, structures, and reactivity of these low-molecular weight models for the H ox state of the [FeFe]-hydrogenases. The propanedithiolates Fe 2(S 2C 3H 6)(CO) 3(L)(dppv) (L = CO, PMe 3, P i-Pr 3) oxidize at potentials approximately 180 mV milder than the related ethanedithiolates ( Angew. Chem., Int. Ed. 2007, 46, 6152). The steric clash between the central methylene of the propanedithiolate and the phosphine favors the rotated structure, which forms upon oxidation. Electron Paramagnetic Resonance (EPR) spectra for the mixed-valence cations indicate that the unpaired electron is localized on the Fe(CO)(dppv) center in both [Fe 2(S 2C 3H 6)(CO) 4(dppv)]BF 4 and [Fe 2(S 2C 3H 6)(CO) 3(PMe 3)(dppv)]BF 4, as seen previously for the ethanedithiolate [Fe 2(S 2C 2H 4)(CO) 3(PMe 3)(dppv)]BF 4. For [Fe 2(S 2C n H 2 n )(CO) 3(P i-Pr 3)(dppv)]BF 4; however, the spin is localized on the Fe(CO) 2(P i-Pr 3) center, although the Fe(CO)(dppv) site is rotated in the crystalline state. IR and EPR spectra, as well as redox potentials and density-functional theory (DFT) calculations, suggest that the Fe(CO) 2(P i-Pr 3) site is rotated in solution, driven by steric factors. Analysis of the DFT-computed partial atomic charges for the mixed-valence species shows that the Fe atom featuring a vacant apical coordination position is an electrophilic Fe(I) center. One-electron oxidation of [Fe 2(S 2C 2H 4)(CN)(CO) 3(dppv)] (-) resulted in 2e oxidation of 0.5 equiv to give the mu-cyano derivative [Fe (I) 2(S 2C 2H 4)(CO) 3(dppv)](mu-CN)[Fe (II) 2(S 2C 2H 4)(mu-CO)(CO) 2(CN)(dppv)], which was characterized spectroscopically.

Published

2008

50. Precursors to [FeFe]-hydrogenase models: syntheses of Fe2(SR)2(CO)6 from CO-free iron sources.

Author

Volkers PI, Boyke CA, Chen J, Rauchfuss TB, Whaley CM, Wilson SR, and Yao H

Subjects

Binding Sites, Crystallography, X-Ray, Ferrous Compounds chemistry, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Carbon chemistry, Ferric Compounds chemistry, Hydrogenase metabolism, Iron chemistry, Iron-Sulfur Proteins metabolism, Oxygen chemistry

Abstract

This report describes routes to iron dithiolato carbonyls that do not require preformed iron carbonyls. The reaction of FeCl 2, Zn, and Q 2S 2C n H 2 n (Q (+) = Na (+), Et 3NH (+)) under an atmosphere of CO affords Fe 2(S 2C n H 2 n )(CO) 6 ( n = 2, 3) in yields >70%. The method was employed to prepare Fe 2(S 2C 2H 4)( (13)CO) 6. Treatment of these carbonylated mixtures with tertiary phosphines, instead of Zn, gave the ferrous species Fe 3(S 2C 3H 6) 3(CO) 4(PR 3) 2, for R = Et, Bu, and Ph. Like the related complex Fe 3(SPh) 6(CO) 6, these compounds consist of a linear arrangement of three conjoined face-shared octahedral centers. Omitting the phosphine but with an excess of dithiolate, we obtained the related mixed-valence triiron species [Fe 3(S 2C n H 2 n ) 4(CO) 4] (-). The highly reducing all-ferrous species [Fe 3(S 2C n H 2 n ) 4(CO) 4] (2-) is implicated as an intermediate in this transformation. Reactive forms of iron, prepared by the method of Rieke, also combined with dithiols under a CO atmosphere to give Fe 2(S 2C n H 2 n )(CO) 6 in modest yields under mild conditions. Studies on the order of addition indicate that ferrous thiolates are formed prior to the onset of carbonylation. Crystallographic characterization demonstrated that the complexes Fe 3(S 2C 3H 6) 3(CO) 4(PEt 3) 2 and PBnPh 3[Fe 3(S 2C 3H 6) 4(CO) 4] feature high-spin ferrous and low-spin ferric as the central metal, respectively.

Published

2008