Hochfeld- und Puls-EPR-Untersuchungen an den Kofaktoren von -Hydrogenasen Beiträge zur Klärung des Mechanismusses der biologischen Wasserstoffspaltung /

Brecht, Marc Torsten Jörg.

Unknown Date

Universiẗat, Diss., 2001--Berlin.

EPR spectroscopic investigation of the active site of -hydrogenase a contribution to the elucidation of the reaction mechanism /

Foerster, Stefanie Anette Erica.

Unknown Date

Techn. University, Diss., 2003--Berlin.

Spektroskopische und elektrochemische Untersuchung der -Hydrogenase aus Desulfovibrio vulgaris Miyazaki F

Fichtner, Caroline.

Unknown Date

Universiẗat, Diss., 2005--Düsseldorf.

Bioinspired Electrocatalytic Hydrogen Production: Synthetic and Biological Approaches

January 2017

abstract: Development of efficient and renewable electrocatalytic systems is foundational to creation of effective means to produce solar fuels. Many redox enzymes are functional electrocatalysts when immobilized on an electrode, but long-term stability of isolated proteins limits use in applications. Thus there is interest in developing bio-inspired functional catalysts or electrocatalytic systems based on living organisms. This dissertation describes efforts to create both synthetic and biological electrochemical systems for electrocatalytic hydrogen production. The first part of this dissertation describes the preparation of three different types of proton reduction catalysts. First, four bioinspired diiron complexes of the form (μ-SRS)Fe(CO)3[Fe(CO)(N-N)] for SRS = 1,2-benzenedithiolate (bdt) and 1,3-propanedithiolate (pdt) and N-N = 2,2’-bipyridine (bpy) and 2,2’-bypyrimidine (bpym), are described. Electrocatatlytic experiments show that although the byprimidinal complexes are not catalysts, the bipyridyl complexes produce hydrogen from acetic acid under reducing conditions. Second, three new mononuclear FeII carbonyl complexes of the form [Fe(CO)(bdt)(PPh2)2] in which P2 = bis-phosphine: 4,5-Bis(diphenylphosphino)- 9,9-dimethylxanthene (Xantphos), 1,2-Bis(diphenylphosphino)benzene (dppb), or cis- 1,2-Bis(diphenylphosphino)ethylene (dppv) are described. All are functional bio-inspired models of the distal Fe site of [FeFe]-hydrogenases. Of these, the Xanthphos complex is the most stable to redox reactions and active as an electrocatalyst. Third, a molybdenum catalyst based on the redox non-innocent PDI ligand framework is also shown to produce hydrogen in the presence of acid. The second part of this dissertation describes creating functional interfaces between chemical and biological models at electrode surfaces to create electroactive systems. First, covalent tethering of the redox probe ferrocene to thiol-functionalized reduced graphene oxide is demonstrated. I demonstrate that this attachment is via the thiol functional groups. Second, I demonstrate the ability to use electricity in combination with light to drive production of hydrogen by the anaerobic, phototrophic microorganism Heliobacterium modesticaldum. / Dissertation/Thesis / Doctoral Dissertation Biochemistry 2017

Biochemistry

Bio-inspired

Biomimicry

Catalysis

Electrochemistry

Hydrogenase

Photochemistry

Les foldamères comme mimes de la seconde sphère de coordination des hydrogénases [Fe-Fe] / Foldamers as second coordination sphere mimics of [Fe-Fe] hydrogenase

Meunier, Antoine

07 December 2017

La possibilité de reproduire une activité enzymatique de manière artificielle est l’un des objectifs de la chimie moderne mais reste un grand défi, même dans le cas de l’activation de petites molécules. Dans le cas du dihydrogène, certaines bactéries s’en servent comme vecteur d’énergie par l’intermédiaire d’enzymes appelées hydrogénases qui peuvent former ou consommer le dihydrogène grâce à des complexes à base de métaux non nobles. Le dihydrogène pouvant être également utilisé comme vecteur d’énergie dans nos sociétés, les hydrogénases font l’objet de nombreuses recherches. Jusqu’à présent, la plupart des complexes modèles d’hydrogénases se sont employés à modifier la première sphère de coordination pour reproduire au mieux ses propriétés électroniques. Néanmoins, l’étude de mutations ciblées des hydrogénases indique que plusieurs résidus d’acides aminés présents dans le site actif sont indispensables à la stabilité du complexe et à son efficacité catalytique, montrant ainsi comment le mime d’une deuxième sphère de coordination pourrait améliorer les propriétés des catalyseurs artificiels. Notre approche a consisté en l’utilisation de foldamères de type oligoamide aromatique, formant un cône autour d’un complexe modèle d’hydrogénase. La synthèse convergente du composé final, son étude structurale à l’état solide (diffraction des rayons X), en solution (RMN, IR) ainsi que sa dynamique ont été étudiées. La modification de la première sphère de coordination du complexe modèle en présence du foldamère est également décrite et montrant notamment leur interaction. / The ability to replicate enzymatic activity with a synthetic molecule is a highly sought after goal in modern chemistry. However, it remains a big challenge even in case of activation of small molecules. In the case of hydrogen, some bacteria can use it as energy carrier by means of enzymes called hydrogenases that can reversely make or break the bond of hydrogen molecules and are made of earth abundant metals. As hydrogen could be used for the same purpose of energy storage in our society, hydrogenases caught interest of scientific community. To date, most biomimetic hydrogenase models mainly focus on first coordination sphere modifications to fine-tune structure and physical properties. However, point mutation studies indicate that several of the amino acid residues surrounding the enzyme active site are required for structural stability or high turnover frequencies. It shows how mimicking second coordination sphere could improve the capabilities of synthetic catalysts. Our approach used aromatic oligoamide foldamers as helical scaffolds around an inspired 2Fe2S4cluster. Convergent synthesis of the final molecule and structural studies in the solid state (x-ray) and in solution (NMR, IR) as well as the dynamic behaviour are reported. Modifications of the first coordination sphere of the model complex in presence of the foldamer are also described, showing interactions between them.

Hydrogénase

Foldamère

Cavité

Biomimétisme

Hydrogenase

Foldamer

Cavity

Biomimetism

Structural studies on the [NiFe] hydrogenase maturation mechanism / [NiFe]ヒドロゲナーゼの成熟化機構に関する構造研究

Kwon, Sunghark

26 March 2018

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第20932号 / 理博第4384号 / 新制||理||1630(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授 三木 邦夫, 教授 杉山 弘, 教授 秋山 芳展 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

hydrogenase maturation

Ni insertion

HyhL

HypA

HybD

400

Syngas Fermentation: Quantification of Assay Techniques, Reaction Kinetics, and Pressure Dependencies of the Clostridial P11 Hydrogenase

Skidmore, Bradley E.

18 March 2010

Ethanol usage as a transportation fuel is rapidly increasing in the United States. Production of ethanol from cellulose feedstocks via gasification followed by syngas fermentation offers an environmentally friendly approach that mitigates many of the adverse effects associated with production from corn. In the syngas fermentation process, the hydrogenase enzyme of the fermentation bacterium, Clostridium P11 for this work, supplies electrons to the metabolic pathway, facilitating ethanol production. In this thesis, an assay for P11 hydrogenase activity was developed. It was determined that 1) less than 4 minutes of sparging with 50 sccm H2 is needed to reduce O2 levels to below 1 ppm in a 3 mL aqueous solution, while less than 1 minute of purging at the same rate is needed to fill an air-filled 3.5 mL cuvette to 99.9999% H2, 2) 12.5 mM DTT included in the reaction mixture at pH 6 helps scavenge O2, 3) H2 diffusion is slow compared to enzymatic reaction rates, 4) CO2 lowers media pH, 5) 0.084 atm CO causes 90% inhibition of P11 hydrogenase, 6) prolonged Triton X-100 exposure diminishes hydrogenase activity, and 7) variations in H2 pressure and electron acceptor identity and concentration affect measured hydrogenase activities. The assay developed for P11 hydrogenase activity was used to perform kinetic studies. The Okura rapid-equilibrium rate law best described this activity. A constant that regulates the effect of H2 pressure on hydrogenase activity, KH2, was determined to be independent of electron acceptor and to have a value of 0.31 atm, implying that H2 must be supplied to the syngas fermentation at ~3 atm to maximize hydrogenase activity. KBV and KMV, constants that regulate the effect of benzyl viologen and methyl viologen on hydrogenase activity, were determined to be 1.7-2.4 mM and 10.6 mM, respectively. Additionally, hydrogenase activity was temporally correlated with ethanol production in batch cultures of P11 and strongly dependent on pH. The intracellular pH of P11 was determined to be approximately 5.5.

ethanol

hydrogenase

syngas

fermentation

Clostridium

P11

assay

Chemical Engineering

Syngas Impurity Effects on Cell Growth, Enzymatic Activities and Ethanol Production via Fermentation

Xu, Deshun

26 October 2012

A syngas compositional database with focus on trace impurities was established. For this work, ammonia (NH3) and benzene (C6H6) effects on cell growth, enzymatic activities of hydrogenase and alcohol dehydrogenase (ADH), and product formation were studied. NH3, after entering media, will be converted rapidly to NH4+, which will raise the total osmolarity of the media. NH3, as a common nutrient for the cell growth, is not the real culprit for cell growth inhibition. In essence, it is the high osmolarity resulting from the accumulation of NH4+ in the media which disrupts the normal regulation of the cells. It was concluded that at NH4+ concentration above 250 mM, the cell growth was substantially inhibited. However, P11 cells used in this study can likely adapt to an elevated osmolarity (up to 500 mM) although the mechanism is unknown. It was also found that higher osmolarity will eventually lead to higher ethanol per cell density. In conclusion, NH3 needs to be cleaned out of syngas feeding system. The realistic C6H6 concentration in the media coming from a gasifier was simulated in bioreactors and was measured by a GC/MS. The most realistic C6H6 concentration in the media was around 0.41 mM (upper limit 0.83 mM). However, five elevated concentrations of 0.64, 1.18, 1.72, 2.33, and 3.44 mM were doped into the media. It was found that at 3.44 mM cell growth and ethanol production were significantly affected. However, there was only negligible adverse effect on cell growth and ethanol production at 0.41 mM, which is the expected concentration in bioreactors exposed to syngas. Therefore, it is unnecessary to remove C6H6 from the gas feeding stream. A kinetic model for hydrogenase activity that included inhibition effects of NH4+ and C6H6 was developed. Experimental results showed that NH4+ is a non-competitive inhibitor for hydrogenase activity with KNH4+ of (649 ± 35) mM and KH2 of (0.19 ± 0.1) mM. This KH2 value is consistent with those reported in literature. C6H6 is also a non-competitive inhibitor but a more potent one compared to NH4+ (KC6H6=11.4 ± 1.32 mM). A KH2 value of (0.196 ± 0.022) mM is also comparable with literature and also with the NH4+ study. At a realistic C6H6 concentration of 0.41 mM expected in bioreactors exposed to syngas, hydrogenase activity is expected to be reduced by less than 5%. Forward ADH activity was not adversely affected up to 200 mM [NH4+].From the current work, NH3 should be targeted for removal but it is not necessary to remove C6H6 when designing an efficient gas cleanup system.

syngas impurity

hydrogenase activity

ethanol formation

inhibition

fermentation

Chemical Engineering

A Theoretical Study for the Reactivation of O₂ Inhibited [Fe-Fe]-hydrogenase

Motiu, Stefan

January 2008

No description available.

Chemistry

Hydrogenase

Reactivation

H-cluster

DFT

ONIOM

Residues

Chemolithotrophic nitrate dependent growth of Rhizobium japonicum on carbon monoxide and its relationship to hydrogenase activity

Gunatilaka, Malkanthi Kumari

January 1983

M.S.

LD5655.V855 1983.G852

Hydrogenase

Nitrifying bacteria

Rhizobium