Your search keyword '"active site"' showing total 6 results

1. Bioinspired Non-Heme Iron Complexes: The Evolution of Facial N, N, O Ligand Design

Author

Monkcom, Emily C., Ghosh, Pradip, Folkertsma, Emma, Negenman, Hidde A., Lutz, Martin, Klein Gebbink, Robertus J. M., Sub Organic Chemistry and Catalysis, Sub Crystal and Structural Chemistry, Organic Chemistry and Catalysis, Crystal and Structural Chemistry, Sub Organic Chemistry and Catalysis, Sub Crystal and Structural Chemistry, Organic Chemistry and Catalysis, and Crystal and Structural Chemistry

Subjects

BIOINSPIRED METAL COMPLEXES, Denticity, O LIGANDS, N,N,O LIGANDS, Homogeneous catalysis, Catalysis, 2-his-1-carboxylate facial triad, lcsh:Chemistry, 2-HIS-1-CARBOXYLATE FACIAL TRIADBIOINSPIRED METAL COMPLEXES, NON-HEME IRON, medicine, Reactivity (chemistry), biology, Chemistry, Ligand, Active site, Triad (anatomy), General Medicine, General Chemistry, Combinatorial chemistry, nno ligands, medicine.anatomical_structure, non-heme iron, lcsh:QD1-999, bioinspired metal complexes, biology.protein, N, Selectivity, Non-heme iron

Abstract

Iron-containing metalloenzymes that contain the 2-His-1-Carboxylate facial triad at their active site are well known for their ability to activate molecular oxygen and catalyse a broad range of oxidative transformations. Many of these reactions are synthetically challenging, and developing small molecular iron-based catalysts that can achieve similar reactivity and selectivity remains a long-standing goal in homogeneous catalysis. This review focuses on the development of bioinspired facial N,N,O ligands that model the 2-His-1-Carboxylate facial triad to a greater degree of structural accuracy than many of the polydentate N-donor ligands commonly used in this field. By developing robust, well-defined N,N,O facial ligands, an increased understanding could be gained of the factors governing enzymatic reactivity and selectivity.

Published

2020

2. Loops und Tunnel : unterschätzte Elemente in Enzymen

Author

Peter M. Heinemann, Lea R. Rapp, and Bernhard Hauer

Subjects

chemistry.chemical_classification, 0303 health sciences, biology, 030306 microbiology, Pharmacology toxicology, Active site, 03 medical and health sciences, Enzyme, chemistry, Biochemistry, biology.protein, Substrate specificity, Molecular Biology, 030304 developmental biology, Biotechnology

Abstract

In enzymes, the active site is the location where substrates are chemically converted. If this site is deeply buried within the protein, substrates must pass not only through the body of the protein via a tunnel, but also flexible, site decorating loops to access the active site. These elements can act as filters that influence on both substrate specificity and activity. Identifying and understanding how they exert such control has been of growing interest over the past several years., BMBF, Projekt DEAL

Published

2020

3. The Role of Proton Transfer in Heterogeneous Transformations of Hydrocarbons

Author

Deven P. Estes and Christophe Copéret

Subjects

Heterogeneous catalysis, Proton, biology, Chemistry, Metal ions in aqueous solution, Inorganic chemistry, Oxide, Active site, General Medicine, General Chemistry, Proton transfer, Catalysis, Metal, chemistry.chemical_compound, Chemical engineering, visual_art, visual_art.visual_art_medium, biology.protein, QD1-999, Organometallic chemistry

Abstract

Heterogeneous catalysis is essential for the transformation of light hydrocarbons into chemical feedstocks. Many of the catalysts that mediate these transformations consist of isolated metal ions on the surface of a metal oxide support, such as silica or alumina. Due to the complexity of these catalysts, studying the active site and mechanism of these reactions is difficult. Surface organometallic chemistry (SOMC) could offer a solution to this problem by allowing the synthesis of well-defined surface organometallic species. This approach has been used to study the reactions of light hydrocarbons with isolated metal species on silica and alumina surfaces. These studies showed that proton transfers play a key role in the reactions of many hydrocarbons. The mechanisms of these reactions and their role in some common catalytic cycles are discussed.

Published

2015

4. Die Analyse der Sauerstofftoleranz und biotechnologische Anwendung der NAD+-reduzierenden Hydrogenase aus Ralstonia eutropha H16

Author

Lauterbach, Lars, Friedrich, B., Hildebrandt, P., and Dobbek, H.

Subjects

Ralstonia eutropha, Diaphorase, oxygen tolerance, Elektrochemie, water, 32 Biologie, hydrogen peroxide, Hydrogenase, ddc:570, Complex I, 570 Biowissenschaften, Biologie, Wasser, FMN, NADH-Regeneration, Wasserstoffperoxid, Eisen-Schwefel-Cluster, Sauerstofftoleranz, active site, flavin mononucleotide, Komplex I, FTIR, electrochemistry, WD 5050, NADH regeneration, Fe-S Cluster, Aktives Zentrum, Flavinmononukleotid

Abstract

Die NAD+-reduzierende Hydrogenase aus Ralstonia eutropha (SH) katalysiert die reversible H2-Oxidation in Verbindung mit der Reduktion von NAD+ in Gegenwart von Sauerstoff. Die bemerkenswerte O2-Toleranz des Enzyms wurde zuvor auf eine für [NiFe]-Hydrogenasen ungewöhnliche Struktur des Wasserstoff-spaltenden Zentrums zurückgeführt. Diese Hypothese wurde in dieser Arbeit mittels in situ-Spektroskopie an SH-haltigen Zellen widerlegt. Um die folgende Untersuchung der aus sechs Untereinheiten und mindestens acht Kofaktoren bestehenden SH zu erleichtern, wurde das Enzym mittels genetischer Methoden in seine beiden Module aufgeteilt. Das die H2-Oxidation katalysierende Hydrogenase-Modul beinhaltete ein FMN-Molekül, welches für die reduktive Reaktivierung des oxidativ modifizierten Zentrums benötigt wird. Das Diaphorase-Modul besaß ebenfalls ein FMN, und die Reduktion von NAD+ wurde von der Anwesenheit von O2 nicht beeinträchtigt. Neben Wasserstoff reagierte das [NiFe]-Zentrum der SH auch mit Sauerstoff. Dabei wurde sowohl Wasserstoffperoxid- als auch Wasser im Hydrogenase-Modul freigesetzt. Die Sauerstofftoleranz der SH basiert auf einer kontinuierlichen Reaktivierung des durch Sauerstoff oxidierten [NiFe]-Zentrums. Aufgrund der außergewöhnlichen Sauerstofftoleranz stellt die SH ein vielversprechendes System für die wasserstoffgetriebene Regeneration von NADH in gekoppelten enzymatischen Reaktionen dar. In dieser Arbeit wurde ein SH-Derivat durch rationale Mutagenese konstruiert, das in der Lage war, ebenso den Kofaktor NADP+ wasserstoffabhängig zu reduzieren. Durch Ganzzellansätze kann die zeitaufwändige und kostenintensive Proteinreinigung vermieden werden. Um die wasserstoffabhängige in-vivo-Kofaktorregeneration zu ermöglichen, wurde die SH in Pseudomonas putida heterolog produziert. Die in dieser Arbeit erzielten Ergebnisse sind sowohl für das molekulare Verständnis der H2-abhängigen Katalyse als auch für die biotechnologische Anwendung der O2-toleranten SH relevant. The NAD+ reducing hydrogenase from Ralstonia eutropha (SH) catalyzes the reversible oxidation of hydrogen in connection with the reduction of NAD+ in the presence of oxygen. The remarkable oxygen tolerance was previously related to an unusual [NiFe] active site with four instead of two cyanide ligands. This hypothesis was rejected in this study by using in situ spectroscopy on SH containing cells. To simplify the investigation of the six-subunit and at least eight cofactors containing SH, the enzyme was separated into its two modules by genetic methods. The hydrogen oxidizing hydrogenase module contained one FMN molecule, which was required for the reductive reactivation of the oxidatively modified active site. The diaphorase module carried a second FMN. The reduction of NAD+ was not affected by the presence of oxygen. In addition to hydrogen, the [NiFe] center of the SH reacted with oxygen. Both hydrogen peroxide and water were released by the hydrogenase module. The oxygen tolerance of the SH is based on a continuous reactivation of the oxidized [NiFe] center. Due to the oxygen tolerance, the SH is a promising system for hydrogen based NADH regeneration in coupled enzymatic reactions. In this study a SH derivative was constructed by means of rational mutagenesis. The SH derivative was able to reduce the cofactor NADP+ by hydrogen oxidation. The time consuming and costly protein purification can be avoided by using whole cell approaches. In order to allow the hydrogen dependent in vivo cofactor regeneration, SH was heterologously produced in Pseudomonas putida. The results obtained in this study are relevant for the molecular understanding of hydrogen dependent catalysis and for the biotechnological application of the oxygen tolerant SH.

Published

2014

5. Die pleiotrope Maturation der sauerstofftoleranten [NiFe]-Hydrogenasen aus Ralstonia eutropha

Author

Bürstel, Ingmar, Friedrich, B., Sawers, R. G., and Dobbek, H.

Subjects

Ralstonia eutropha, oxygen tolerance, formic acid, 32 Biologie, Carbonylligand, carbonyl ligand, carbon monoxide, Hydrogenase, ddc:570, Maturation, HypX, Kohlenmonoxid, 570 Biowissenschaften, Biologie, C1-Metabolismus, Ameisensäure, diatomic ligands, Sauerstofftoleranz, active site, one-carbon metabolism, tetrahydrofolate, CO-ligand, WD 5055, Diatomare Liganden, Tetrahydrofolat, HypC, HypD, Aktives Zentrum

Abstract

Hydrogenasen sind komplexe Enzyme, die die reversible Oxidation von molekularem Wasserstoff zu Protonen und Elektronen katalysieren. Diese Enzyme erlauben ihrem Wirtsorganismus das Wachstum unter chemolithoautotrophen Bedingungen. Der Modellorganismus Ralstonia eutropha besitzt drei gut charakterisierte Hydrogenasen der [NiFe]-Klasse, die sich durch ihre Sauerstofftoleranz auszeichnen. Ihr aktives Zentrum besteht aus einer komplexen prosthetischen Gruppe, welche aus einem Nickel- und einem Eisenatom besteht. Letzteres koordiniert drei diatomare Liganden, zwei Cyanide und ein CO. Die Synthese der gesamten Ni(SR)2(µ-SR)2Fe(CN)2(CO)-Gruppe ist ein komplexer Prozess. Die sogenannte Maturation benötigt wenigstens sechs akzessorische Proteine, die sogenannten Hyp-Proteine. Das umfassende Verständnis dieser Maturationsprozesse ermöglicht eine Vielzahl von biotechnologischen Anwendungen. Die vorliegende Arbeit untersucht die Maturation unter verschiedenen Gesichtspunkten. Zentrale, offene Fragen sind die Herkunft des Carbonylliganden sowie die Prozesse, die zur Ligandierung des katalytischen Eisens führen. Dazu wurden molekularbiologische, biochemische und spektroskopische Methoden in Verbindung mit Isotopenmarkierung eingesetzt. Unter anderem konnte dabei gezeigt werden, dass das katalytische Eisen alle seine Liganden bereits im HypCD-Komplex, dem zentralen Element der Maturation, erhält. Ferner konnte in dieser Arbeit, erstmalig für [NiFe]-Hydrogenasen, eine konkrete Biosynthese des seltenen und toxischen diatomaren CO-Liganden beschrieben werden. Ausgehend vom Alpha-Kohlenstoff von Glycin wird der Tetrahydrofolat (THF)-abhängige C1-Metabolismus mit C1-Einheiten versorgt. Durch die enzymatische Aktivität von HypX wird die Formylgruppe von N10-Formyl-THF zu CO umgesetzt. Hydrogenases are complex enzymes that catalyze the reversible oxidation of molecular hydrogen into protons and electrons. These enzymes allow their host organism to grow under chemolithoautotrophic conditions. The model organism Ralstonia eutropha has three well-characterized [NiFe]-hydrogenases, which exhibit an extraordinary high oxygen tolerance. Its active center is a complex prosthetic group which consists of a nickel and iron atom. The latter coordinates three diatomic ligands, two cyanides and one CO. The biosynthesis of the whole Ni(SR)2(μ-SR)2Fe(CN)2(CO)-group is a complex process. This so-called maturation process needs the activity of at least six accessory proteins, the Hyp-proteins. Understanding the maturation allows a variety of biotechnological applications. The present study examines the maturation of [NiFe]-hydrogenases under different aspects. The major questions concern the origin of the carbonyl ligand as well as the processes that lead to ligandation of the designated catalytic iron. To adress these tasks, molecular biological, biochemical and spectroscopic methods in combination with isotopic labeling were employed. Inter alia, it could be shown that the catalytic iron in the HypCD-complex, the central element of the maturation process, contains all three diatomic ligands. Furthermore, this study describes, for the first time in [NiFe]-hydrogenases, a specific biosynthetic route of the rare and toxic diatomic CO-ligand. Starting from the alpha-carbon of glycine the tetrahydrofolate (THF)-dependent one-carbon metabolism is replenished with one-carbon units. Subsequently the formyl group from N10-formyl-THF is hydrolyzed by the enzymatic activity from HypX and further converted to carbon monoxide as determined by isotopic labeling and infrared spectroscopy.

Published

2013

6. Expanding the Catalytic Repertoire of DNAzymes by Modified Nucleosides

Author

Marcel Hollenstein

Subjects

Aptamer, Molecular Sequence Data, Oligonucleotides, Deoxyribozyme, Dnazymes, Base-modified dna, Ligands, Biochemistry, Modified nucleosides, Catalysis, Enzyme-mimetic, Catalytic Domain, Nucleic Acids, QD1-999, Base Sequence, Phenol, biology, Chemistry, Oligonucleotide, Active site, Nucleosides, DNA, Catalytic, Mercury, General Medicine, General Chemistry, Selex, Combinatorial chemistry, Kinetics, Models, Chemical, Organocatalysis, biology.protein, Nucleic acid, RNA, Nucleoside triphosphates, Dinucleoside Phosphates

Abstract

Modified nucleoside triphosphates (dNTPs) are a versatile platform for the generation of high-density functionalized nucleic acids. The enzymatic polymerization of dNTPs allows the introduction of sensible functionalities that might not be compatible with the standard automated synthesis of oligonucleotides. Their application to in vitro selections, an elegant chemical approach to Darwinian evolution, delivers modified aptamers and catalytic nucleic acids with potentially enhanced properties. This review article highlights some recent synthetic examples of dNTPs bearing functionalities that are either found in the active site of protein enzymes or have been employed in organocatalysis and further underscores their usefulness in the development of some modified catalytic nucleic acids with special emphasis on M2+-independent RNA-cleaving DNAzymes.

Published

2011