Your search keyword '"Siebel, Judith F."' showing total 8 results

1. 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

2. Spectroscopic Characterization of the Bridging Amine in the Active Site of [FeFe] Hydrogenase Using Isotopologues of the H-Cluster.

Author

Adamska-Venkatesh A, Roy S, Siebel JF, Simmons TR, Fontecave M, Artero V, Reijerse E, and Lubitz W

Subjects

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

Abstract

The active site of [FeFe] hydrogenase contains a catalytic binuclear iron subsite coordinated by CN(-) and CO ligands as well as a unique azadithiolate (adt(2-)) bridging ligand. It has been established that this binuclear cofactor is synthesized and assembled by three maturation proteins HydE, -F, and -G. By means of in vitro maturation in the presence of (15)N- and (13)C-labeled tyrosine it has been shown that the CN(-) and CO ligands originate from tyrosine. The source of the bridging adt(2-) ligand, however, remains unknown. In order to identify the nitrogen of the bridging amine using HYSCORE spectroscopy and distinguish its spectroscopic signature from that of the CN(-) nitrogens, we studied three isotope-labeled variants of the H-cluster ((15)N-adt(2-)/C(14)N(-), (15)N-adt(2-)/C(15)N(-), and (14)N-adt(2-)/C(15)N(-)) and extracted accurate values of the hyperfine and quadrupole couplings of both CN(-) and adt(2-) nitrogens. This will allow an evaluation of isotopologues of the H-cluster generated by in vitro bioassembly in the presence of various (15)N-labeled potential precursors as possible sources of the bridging ligand.

Published

2015

3. Structural Insight into the Complex of Ferredoxin and [FeFe] Hydrogenase from Chlamydomonas reinhardtii.

Author

Rumpel S, Siebel JF, Diallo M, Farès C, Reijerse EJ, and Lubitz W

Subjects

Ferredoxins genetics, Gallium chemistry, Hydrogen metabolism, Hydrogenase genetics, Hydrophobic and Hydrophilic Interactions, Models, Molecular, Mutation, Oxidation-Reduction, Protein Binding, Protein Conformation, Chlamydomonas reinhardtii enzymology, Ferredoxins chemistry, Ferredoxins metabolism, Hydrogenase chemistry, Hydrogenase metabolism

Abstract

The transfer of photosynthetic electrons by the ferredoxin PetF to the [FeFe] hydrogenase HydA1 in the microalga Chlamydomonas reinhardtii is a key step in hydrogen production. Electron delivery requires a specific interaction between PetF and HydA1. However, because of the transient nature of the electron-transfer complex, a crystal structure remains elusive. Therefore, we performed protein-protein docking based on new experimental data from a solution NMR spectroscopy investigation of native and gallium-substituted PetF. This provides valuable information about residues crucial for complex formation and electron transfer. The derived complex model might help to pinpoint residue substitution targets for improved hydrogen production., (© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2015

4. 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

5. Hybrid [FeFe]-hydrogenases with modified active sites show remarkable residual enzymatic activity.

Author

Siebel JF, Adamska-Venkatesh A, Weber K, Rumpel S, Reijerse E, and Lubitz W

Subjects

Aza Compounds chemistry, Aza Compounds metabolism, Catalytic Domain, Chlamydomonas reinhardtii chemistry, Chlamydomonas reinhardtii metabolism, Hydrogen metabolism, Hydrogenase metabolism, Iron Compounds metabolism, Ligands, Methylation, Models, Molecular, Oxidation-Reduction, Propane chemistry, Propane metabolism, Sulfhydryl Compounds metabolism, Chlamydomonas reinhardtii enzymology, Hydrogenase chemistry, Iron Compounds chemistry, Propane analogs & derivatives, Sulfhydryl Compounds chemistry

Abstract

[FeFe]-hydrogenases are to date the only enzymes for which it has been demonstrated that the native inorganic binuclear cofactor of the active site Fe2(adt)(CO)3(CN)2 (adt = azadithiolate = [S-CH2-NH-CH2-S](2-)) can be synthesized on the laboratory bench and subsequently inserted into the unmaturated enzyme to yield fully functional holo-enzyme (Berggren, G. et al. (2013) Nature 499, 66-70; Esselborn, J. et al. (2013) Nat. Chem. Biol. 9, 607-610). In the current study, we exploit this procedure to introduce non-native cofactors into the enzyme. Mimics of the binuclear subcluster with a modified bridging dithiolate ligand (thiodithiolate, N-methylazadithiolate, dimethyl-azadithiolate) and three variants containing only one CN(-) ligand were inserted into the active site of the enzyme. We investigated the activity of these variants for hydrogen oxidation as well as proton reduction and their structural accommodation within the active site was analyzed using Fourier transform infrared spectroscopy. Interestingly, the monocyanide variant with the azadithiolate bridge showed ∼50% of the native enzyme activity. This would suggest that the CN(-) ligands are not essential for catalytic activity, but rather serve to anchor the binuclear subsite inside the protein pocket through hydrogen bonding. The inserted artificial cofactors with a propanedithiolate and an N-methylazadithiolate bridge as well as their monocyanide variants also showed residual activity. However, these activities were less than 1% of the native enzyme. Our findings indicate that even small changes in the dithiolate bridge of the binuclear subsite lead to a rather strong decrease of the catalytic activity. We conclude that both the Brønsted base function and the conformational flexibility of the native azadithiolate amine moiety are essential for the high catalytic activity of the native enzyme.

Published

2015

6. Artificially maturated [FeFe] hydrogenase from Chlamydomonas reinhardtii: a HYSCORE and ENDOR study of a non-natural H-cluster.

Author

Adamska-Venkatesh A, Simmons TR, Siebel JF, Artero V, Fontecave M, Reijerse E, and Lubitz W

Subjects

Catalytic Domain, Chlamydomonas reinhardtii chemistry, Electron Spin Resonance Spectroscopy, Ligands, Models, Molecular, Propane chemistry, Biomimetic Materials chemistry, Chlamydomonas reinhardtii enzymology, Hydrogenase chemistry, Iron-Sulfur Proteins chemistry, Propane analogs & derivatives, Sulfhydryl Compounds chemistry

Abstract

Hydrogenases are enzymes that catalyze the oxidation of H2 as well as the reduction of protons to form H2. The active site of [FeFe] hydrogenase is referred to as the "H-cluster" and consists of a "classical" [4Fe-4S] cluster connected via a bridging cysteine thiol group to a unique [2Fe]H sub-cluster, containing CN(-) and CO ligands as well as a bidentate azadithiolate ligand. It has been recently shown that the biomimetic [Fe2(adt)(CO)4(CN)2](2-) (adt(2-) = azadithiolate) complex resembling the diiron sub-cluster can be inserted in vitro into the apo-protein of [FeFe] hydrogenase, which contains only the [4Fe-4S] part of the H-cluster, resulting in a fully active enzyme. This synthetic tool allows convenient incorporation of a variety of diiron mimics, thus generating hydrogenases with artificial active sites. [FeFe] hydrogenase from Chlamydomonas reinhardtii maturated with the biomimetic complex [Fe2(pdt)(CO)4(CN)2](2-) (pdt(2-) = propanedithiolate), in which the bridging adt(2-) ligand is replaced by pdt(2-), can be stabilized in a state strongly resembling the active oxidized (Hox) state of the native protein. This state is EPR active and the signal originates from the mixed valence Fe(I)Fe(II) state of the diiron sub-cluster. Taking advantage of the variant with (15)N and (13)C isotope labeled CN(-) ligands we performed HYSCORE and ENDOR studies on this hybrid protein. The (13)C hyperfine couplings originating from both CN(-) ligands were determined and assigned. Only the (15)N coupling from the CN(-) ligand bound to the terminal iron was observed. Detailed orientation selective ENDOR and HYSCORE experiments at multiple field positions enabled the extraction of accurate data for the relative orientations of the nitrogen and carbon hyperfine tensors. These data are consistent with the crystal structure assuming a g-tensor orientation following the local symmetry of the binuclear sub-cluster.

Published

2015

7. Insertion of heme b into the structure of the Cys34-carbamidomethylated human lipocalin α(1)-microglobulin: formation of a [(heme)(2) (α(1)-Microglobulin)](3) complex.

Author

Siebel JF, Kosinsky RL, Åkerström B, and Knipp M

Subjects

Alpha-Globulins metabolism, Chromatography, Gel methods, Heme metabolism, Humans, Lipocalins metabolism, Protein Folding, Spectrophotometry, Alpha-Globulins chemistry, Heme chemistry, Lipocalins chemistry

Abstract

α(1)-Microglobulin (α(1)m) is a 26 kDa plasma and tissue protein belonging to the lipocalin protein family. Previous investigations indicate that the protein interacts with heme and suggest that it has a function in heme metabolism. However, detailed characterizations of the α(1)m-heme interactions are lacking. Here, we report for the first time the preparation and analysis of a stable α(1)m-heme complex upon carbamidomethylation of the reactive Cys34 by using recombinantly expressed human α(1)m. Analytical size-exclusion chromatography coupled with a diode-array absorbance spectrophotometry demonstrates that at first an α(1)m-heme monomer is formed. Subsequently, a second heme triggers oligomerization that leads to trimerization. The resulting (α(1)m[heme](2))(3) complex was characterized by resonance Raman and EPR spectroscopy, which support the presence of two ferrihemes, thus indicating an unusual spin-state admixed ground state with S=(3)/(2), (5)/(2)., (Copyright © 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2012

8. Metal selectivity of the Escherichia coli nickel metallochaperone, SlyD.

Author

Kaluarachchi H, Siebel JF, Kaluarachchi-Duffy S, Krecisz S, Sutherland DE, Stillman MJ, and Zamble DB

Subjects

Circular Dichroism, Cobalt metabolism, Copper metabolism, Escherichia coli genetics, Escherichia coli growth & development, Escherichia coli metabolism, Iron metabolism, Manganese metabolism, Mass Spectrometry, Nickel metabolism, Protein Structure, Tertiary, Zinc metabolism, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Metals metabolism, Peptidylprolyl Isomerase chemistry, Peptidylprolyl Isomerase metabolism

Abstract

SlyD is a Ni(II)-binding protein that contributes to nickel homeostasis in Escherichia coli. The C-terminal domain of SlyD contains a rich variety of metal-binding amino acids, suggesting broader metal binding capabilities, and previous work demonstrated that the protein can coordinate several types of first-row transition metals. However, the binding of SlyD to metals other than Ni(II) has not been previously characterized. To improve our understanding of the in vitro metal-binding activity of SlyD and how it correlates with the in vivo function of this protein, the interactions between SlyD and the series of biologically relevant transition metals [Mn(II), Fe(II), Co(II), Cu(I), and Zn(II)] were examined by using a combination of optical spectroscopy and mass spectrometry. Binding of SlyD to Mn(II) or Fe(II) ions was not detected, but the protein coordinates multiple ions of Co(II), Zn(II), and Cu(I) with appreciable affinity (K(D) values in or below the nanomolar range), highlighting the promiscuous nature of this protein. The order of affinities of SlyD for the metals examined is as follows: Mn(II) and Fe(II) < Co(II) < Ni(II) ~ Zn(II) ≪ Cu(I). Although the purified protein is unable to overcome the large thermodynamic preference for Cu(I) and exclude Zn(II) chelation in the presence of Ni(II), in vivo studies reveal a Ni(II)-specific function for the protein. Furthermore, these latter experiments support a specific role for SlyD as a [NiFe]-hydrogenase enzyme maturation factor. The implications of the divergence between the metal selectivity of SlyD in vitro and the specific activity in vivo are discussed.

Published

2011