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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Charakterizace železo-sirných flavoproteinů z hydrogenosomu Trichomonas vaginalis / Characterization of hydrogenosomal iron-sulfur flavoproteins from Trichomonas vaginalis

Pilařová, Kateřina January 2012 (has links)
Trichomonas vaginalis is flagelated microaerophilic protozoan parasite from Excavata group, which causes trichomoniasis, the most common nonviral sexually transmitted disease in the world. It causes vaginitis in women and uretritis in man and it can also cause problems for example during pregnancy. This thesis is aimed on the characterisation of hydrogenosomal iron-sulfur flavoproteins (ISF) from Trichomonas vaginalis, proteins, which were only recently discovered in the proteome of hydrogenosome of T. vaginalis. Specifically, we have focused on characterisation of ISF3 which is, according to our data, active homodimer and binds flavin mononucleotide (FMN) and iron-sulphur centre in its active site. The iron- sulphur centre is not characterised yet. ISF3 is able to reduce oxygen, hydrogen peroxide, sodium nitrate and metronidazole also in the enzymatic system with PFO and ferredoxin. Next, I tried to reduce ammonium sulphate with ISF3, but unsuccessfully. These results correspond with the activities obtained for ISF from Methanosarcina thermophila, where ISF reduces oxygen and hydrogen peroxide to water. In addition, ISF3 is able to reduce nitrogen compounds. It is important according to the fact, that metronidazole is a drug from the group of 5−nitroimidazoles. The other results show the decrease...
2

Kinetic behavior of the NAD(P)H:Quinone oxidoreductase WrbA from Escherichia coli. / Kinetic behavior of the NAD(P)H:Quinone oxidoreductase WrbA from Escherichia coli.

KISHKO, Iryna January 2012 (has links)
This Ph.D. thesis addresses the structure-function relationship of the multimeric oxidoreductase WrbA with the principal aim being the explanation of the unusual kinetics of this enzyme in molecular terms, and thus getting an insight about its physiological role in bacteria. WrbA is a multimeric enzyme with FMN as a co-factor, catalyzing the oxidation of NADH by a two electrons transfer. Structure and function analysis of WrbA places this enzyme between bacterial flavodoxins and eukaryotic oxidoreductases in terms of its evolutionary relationship. The kinetic activity of WrbA was studied under varying conditions such as temperature, pH etc, and its kinetic mechanism was evaluated from parameters KM and Vmax and confirmed by product inhibition pattern experiments. Crystallization and proteolytic experiments also underpin the functional importance of the multimeric nature of WrbA and aid the understanding of the physiological role of this enzyme in molecular terms.
3

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

Lauterbach, Lars 30 May 2014 (has links)
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.

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