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The green alga Chlamydomonas reinhardtii: a new model system to unravel the biogenesis of respiratory complexesBarbieri, Maria del Rosario 30 July 2010 (has links)
No description available.
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Transformation of a membrane protein from the respiratory chain into a sensor for the analysis of its interaction with substrates, inhibitors and lipids / Transformation d'une protéine membranaire de la chaîne respiratoire en une sonde pour l'analyse de substrats, inhibiteurs et lipidesKriegel, Sébastien 11 December 2013 (has links)
Le domaine de la bioénérgétique traîte de la circulation et de la transformation de l’énergie dans et entre des organismes et leur environnement. Dans ce manuscrit de thèse, la respiration cellulaire et plus particulièrement la première enzyme de la chaîne respiratoire, la NADH:ubiquinone oxidoreductase (Complexe I) ont été étudiées, dans l’objectif de clarifier sa fonction et son implication dans certaines maladies. Dans une première partie, la création d’une sonde impliquant l’enzyme immobilisée de façon biomimétique est décrite. La caractérisation de ce système est effectuée via spectroscopie infrarouge par exaltation de surface (SEIRAS) couplée à de l’électrochimie. Sa réponse à l’ajout de substrats et d’inhibiteurs est ensuite présentée. Dans une seconde partie, l’interaction du Complexe I avec des lipides et des inhibiteurs (Zn2+ et NADH-OH) ainsi que le rôle d’une Tyrosine située au site de fixation du NADH ont été étudiés par spectroscopies IR et UV-Vis différentielles induites par électrochimie. L’exploration des résultats obtenus sous un angle structural a finalement permis de proposer un modèle pour le mécanisme de couplage entre la réduction d’ubiquinone et le pompage de protons par le Complexe I. / The field of bioenergetics deals with the flow and transformation of energy within and between living organisms and their environment. The work presented in this thesis report focuses on cellular respiration and more specifically on the first enzyme of the respiratory chain, NADH:ubiquinone oxidoreductase (Complex I). This was done to clarify details about its function and its implication in disease. First, the creation of a sensor involving the biomimetically immobilized enzyme is presented and probed through a combination of surface enhanced infrared absorption spectroscopy (SEIRAS) and electrochemistry. This sensor is then tested against different substrates and inhibitors. In a second part, the interaction of Complex I with lipids, inhibitors (Zn2+ and NADH-OH) and the role of a Tyrosine residue situated in the NADH binding pocket are investigated through electrochemically induced UV-Vis and FTIR difference spectroscopies. The results gathered through these experiments are then explored under a structural perspective and a coupling mechanism between quinone reduction and proton translocation by Complex I is proposed.
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Mitochondrial energy metabolism in \kur{Trypanosoma brucei} / Mitochondrial energy metabolism in \kur{Trypanosoma brucei}VERNER, Zdeněk January 2011 (has links)
The thesis summarizes data gathered on various components of respiratory chain of Trypanosoma brucei. Namely, NADH:ubiquinone oxidoreductase (complex I), alternative NADH:ubiquinone oxidoreductase (NDH2) and mitochondrial glycerol-3-phosphate dehydrogenase are discussed themselves and in broader context of energy metabolism. Also, a work done using RNA interference library is described.
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Transformation of a membrane protein from the respiratory chain into a sensor for the analysis of its interaction with substrates, inhibitors and lipidsKriegel, Sébastien 11 December 2013 (has links) (PDF)
The field of bioenergetics deals with the flow and transformation of energy within and between living organisms and their environment. The work presented in this thesis report focuses on cellular respiration and more specifically on the first enzyme of the respiratory chain, NADH:ubiquinone oxidoreductase (Complex I). This was done to clarify details about its function and its implication in disease. First, the creation of a sensor involving the biomimetically immobilized enzyme is presented and probed through a combination of surface enhanced infrared absorption spectroscopy (SEIRAS) and electrochemistry. This sensor is then tested against different substrates and inhibitors. In a second part, the interaction of Complex I with lipids, inhibitors (Zn2+ and NADH-OH) and the role of a Tyrosine residue situated in the NADH binding pocket are investigated through electrochemically induced UV-Vis and FTIR difference spectroscopies. The results gathered through these experiments are then explored under a structural perspective and a coupling mechanism between quinone reduction and proton translocation by Complex I is proposed.
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