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Attenuation of Doxorubicin-Induced Cardiac Injury by Mitochondrial Glutaredoxin 2Diotte, Nicole M., Xiong, Ye, Gao, Jinping, Chua, Balvin H., Ho, Ye S. 01 February 2009 (has links)
While the cardiotoxicity of doxorubicin (DOX) is known to be partly mediated through the generation of reactive oxygen species (ROS), the biochemical mechanisms by which ROS damage cardiomyocytes remain to be determined. This study investigates whether S-glutathionylation of mitochondrial proteins plays a role in DOX-induced myocardial injury using a line of transgenic mice expressing the human mitochondrial glutaredoxin 2 (Glrx2), a thiotransferase catalyzing the reduction as well as formation of protein-glutathione mixed disulfides, in cardiomyocytes. The total glutaredoxin (Glrx) activity was increased by 76% and 53 fold in homogenates of whole heart and isolated heart mitochondria of Glrx2 transgenic mice, respectively, compared to those of nontransgenic mice. The expression of other antioxidant enzymes, with the exception of glutaredoxin 1, was unaltered. Overexpression of Glrx2 completely prevents DOX-induced decreases in NAD- and FAD-linked state 3 respiration and respiratory control ratio (RCR) in heart mitochondria at days 1 and 5 of treatment. The extent of DOX-induced decline in left ventricular function and release of creatine kinase into circulation at day 5 of treatment was also greatly attenuated in Glrx2 transgenic mice. Further studies revealed that heart mitochondria overexpressing Glrx2 released less cytochrome c than did controls in response to treatment with tBid or a peptide encompassing the BH3 domain of Bid. Development of tolerance to DOX toxicity in transgenic mice is also associated with an increase in protein S-glutathionylation in heart mitochondria. Taken together, these results imply that S-glutathionylation of heart mitochondrial proteins plays a role in preventing DOX-induced cardiac injury.
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Correlation between cytochrome levels and the ATP:ADP ratio in S. CerevisiaeBell, Douglas Eugene January 1978 (has links)
This document only includes an excerpt of the corresponding thesis or dissertation. To request a digital scan of the full text, please contact the Ruth Lilly Medical Library's Interlibrary Loan Department (rlmlill@iu.edu).
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Investigation of Fe(III) Reduction in Geobacter Sulfurreducens Characterization of Outer Surface Associated Electron Transfer ComponentsQian, Xenlei 01 September 2009 (has links)
Outer membrane cytochromes OmcB and OmcS of Geobacter sulfurreducens are two important components of the respiratory chain for extracellular Fe(III) reduction. OmcS is a loosely bound cell surface protein involved in the reduction of insoluble Fe(III). OmcB is an outer membrane protein and required for insoluble and soluble Fe(III) reduction. The objective of this study was to understand better the mechanism of dissimilatory Fe(III) reduction, focusing on the cell surface proteins by further localization, identification of protein-protein interactions, and biochemical characterization of OmcB and OmcS. OmcB was found to be surface-exposed but embedded in the outer membrane because mild protease treatment of cells resulted in partial degradation of OmcB. Removal of surface-exposed proteins inhibited Fe(III) reduction, which is at least partially due to the degradation of OmcB. Co-immunoprecipitation studies with outer surface proteins using an antibody against OmcS revealed that OmcS interacts with several proteins, of which some are implicated in Fe(III) reduction, such as PilA, OmpJ, and OmpB, and in electricity production, such as OmcZ. Other OmcS-associated proteins, which have not been studied, include a cytochrome (GSU2887), a hypothetical and a conserved hypothetical protein, and a putative protease with a PDZ domain. The results suggest that co-immunoprecipitation with other antibodies would help to identify more elements of electron transport pathways related to extracellular Fe(III) reduction. OmcB was purified via preparative sodium dodecylsulfate polyacrylamide gel electrophoresis (SDSPAGE) and anion-exchange chromatography. The molecular mass was determined as 82 kDa, and 11.5 hemes per molecule were found. OmcB was able to transfer electrons to either soluble or insoluble Fe(III). OmcS was purified by detergent extraction. The molecular mass was 47 kDa and it contains 6 heme groups. UV-visible, EPR, and NMR spectroscopies determined that all hemes are bis-histidyl hexacoordinated and low-spin in both oxidized and reduced forms. OmcS has a –212 mV midpoint redox potential, and donates electrons to soluble and insoluble metals and quinones. Transient state kinetics showed that OmcS reduces anthroquinone-2, 6-disulfonate 10 times faster than it reduces Fe(III) citrate. This study revealed valuable further details about the mechanism of Fe(III) reduction by G. sulfurreducens by identifying the localization, protein-protein interactions and biochemical characteristics of the components of extracellular electron transport.
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Ultrafast Protein Conformation DynamicsLink, Justin J. January 2008 (has links)
No description available.
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A Disulfide-Reducing Pathway Required For Plastid Cytochrome c AssemblyGabilly, Stephane T. 26 June 2012 (has links)
No description available.
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Cytochrome c Oxidase from Rhodobacter sphaeroides: Oligomeric Structure in the Phospholipid Bilayer and the Structural and Functional Effects of a C-Terminal Truncation in Subunit IIICvetkov, Teresa L. 13 July 2010 (has links)
No description available.
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Mitochondrial copper homeostasis in mammalian cells / Mitochondrialer Kupfermetabolismus in SäugerzellenOswald, Corina 05 October 2010 (has links) (PDF)
Assembly of cytochrome c oxidase (COX), the terminal enzyme of the mitochondrial respiratory chain, requires a concerted activity of a number of chaperones and factors for the correct insertion of subunits, accessory proteins, cofactors and prosthetic groups. Most of the fundamental biological knowledge concerning mitochondrial copper homeostasis and insertion of copper into COX derives from investigations in the yeast Saccharomyces cerevisiae. In this organism, Cox17 was the first identified factor involved in this pathway. It is a low molecular weight protein containing highly conserved twin Cx9C motifs and is localized in the cytoplasm as well as in the mitochondrial intermembrane space. It was shown that copper-binding is essential for its function.
So far, the role of Cox17 in the mammalian mitochondrial copper metabolism has not been well elucidated. Homozygous disruption of the mouse COX17 gene leads to COX deficiency followed by embryonic death, which implies an indispensable role for Cox17 in cell survival.
In this thesis, the role of COX17 in the biogenesis of the respiratory chain in HeLa cells was explored by use of siRNA. The knockdown of COX17 results in a reduced steady-state concentration of the copper-bearing subunits of COX and affects growth of HeLa cells accompagnied by an accumulation of ROS and apoptotic cells. Furthermore, in accordance with its predicted function as a copper chaperone and its role in formation of the binuclear copper center of COX, COX17 siRNA knockdown affects COX-activity and -assembly. It is now well accepted that the multienzyme complexes of the respiratory chain are organized in vivo as supramolecular functional structures, so called supercomplexes. While the abundance of COX dimers seems to be unaffected, blue native gel electrophoresis reveals the disappearance of COX-containing supercomplexes as an early response. Accumulation of a novel ~150 kDa complex containing Cox1, but not Cox2 could be observed. This observation may indicate that the absence of Cox17 interferes with copper delivery to Cox2, but not to Cox1. Data presented here suggest that supercomplex formation is not simply due to assembly of completely assembled complexes. Instead an interdependent assembly scenario for the formation of supercomplexes is proposed that requires the coordinated synthesis and association of individual complexes.
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Dysfonctions mitochondriales associées à l’acidose lactique du Saguenay-Lac-Saint-Jean révélées par l’étude d’un nouveau modèle murin de la maladieCuillerier, Alexanne 01 1900 (has links)
No description available.
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Assembly and maturation of cbb3-type cytochrome c oxidase in Rhodobacter capsulatus / Assemblage et maturation de la cytochrome oxydase de type cbb3 chez Rhodobacter capsulatusPawlik, Grzegorz 11 June 2012 (has links)
Dans cette thèse, le processus d'assemblage ainsi que la maturation du cytochrome c oxydase de type cbb3 (cbb3-Cox) ont été étudiés dans la proteobactérie phototrophique pourpe non soufrée Rhodobacter capsulatus. R. capsulatus contient une chaîne de transfert d'électrons très ramifiée et represente un modèle d’organisme très utilisé dans l'étude des processus respiratoires et photosynthétiques.Les cbb3-Coxs spécifiques des bactéries représentent la deuxième catégorie la plus abondante des cytochromes c oxydases après le type Cox-aa3, mais n'ont jusqu'à présent pas été étudiées en détail. Récemment, la première structure cristalline cbb3-Cox de P. stutzeri a été obtenue, fournissant ainsi une avancée majeure invitant à des etudes plus détaillées sur le mécanisme catalytique et le processus d'assemblage. Les études sur les procédés d'assemblage et de maturation sont d'une très grande importance en raison du fait que de nombreux agents pathogènes humains tels que Helicobacter pylori, Neisseria meningitidis ou Campylobacter jejuni utilisent ce type de Cox, ce qui par conséquent pourrait amener a développer une interessante cible thérapeutique.Cbb3-Cox dans R. capsulatus est encodé par le gène opéron ccoNOQP codant quatre protéines membranaires constitutives de cbb3-Cox. CcoP et CcoO sont des cytochromes de type c, contenant des motifs périplasmiques fixés à l’hème. CcoN est la sous-unité centrale catalytique contenant deux molécules d’hèmes de type b et un ion cuivre. L’étude de la distribution de l’ion Cu à la sous-unité CcoN et l'assemblage des quatre sous-unités dans le complexe actif cbb3-Cox complexe sont les thèmes principaux de ce travail.Ici, le rôle du facteur d'assemblage putatif CcoH, sa structure et son interaction avec cbb3-Cox ont été étudiés en détail. CcoH est une petite protéine membranaire codé dans le groupe de gènes ccoGHIS situé à proximité des gènes codant cbb3-Cox. L'analyse in vivo de la formation de cbb3-Cox dans une souche ne contenant pas le facteur CcoH a montré une absence totale de cbb3-Cox. De même, la stabilité du facteur CcoH a été considérablement altérée dans une souche avec deletion du gene ccoNOQP. La dépendance mutuelle des deux protéines suggère leur interaction directe, ce qui a été confirmé par la photoréticulation directe de CcoH à la sous-unité CcoN, l’immunodétection de CcoH dans les cbb3-Cox complexes sur gels Blue Native, la co-purification par marquage CcoH-cbb3-Cox et le marquage radioactive in vitro des complexes cbb3-Cox avec CcoH.[...] / In this thesis, the assembly and maturation process of the cbb3-type cytochrome c oxidase (cbb3-Cox) was studied in the purple-non-sulphur phototrophic α-proteobacterium Rhodobacter capsulatus. R. capsulatus contains a highly branched electron-transfer chain and is a well studied model organism for investigating respiratory and photosynthetic processes.The bacteria-specific cbb3-Coxs represent the second most abundant class of cytochrome c oxidases after the aa3-type Cox, but have so far not been investigated in much detail. Recently, the first crystal structure of cbb3-Cox from P. stutzeri was obtained, providing a major breakthrough and inviting detailed studies on the catalytic mechanism and the assembly process. Studies on the assembly and maturation processes are of wide significance due to the fact that many human pathogens like Helicobacter pylori, Neisseria meningitides or Campylobacter jejuni use this type of Cox and it therefore might develop into an attractive drug-target. cbb3-Cox in R. capsulatus is encoded by the ccoNOQP gene operon which codes for four membrane proteins constituting cbb3-Cox. CcoP and CcoO are c-type cytochromes, containing periplasmic heme-binding motifs. CcoN is the central catalytic subunit which contains two b-type hemes and a copper ion. Investigating the delivery of Cu to the CcoN subunit and the assembly of all four subunits into the active cbb3-Cox complex were the main topics of this work. Here the role of the putative assembly factor CcoH, its structure and interaction with cbb3-Cox was investigated in detail. CcoH is a small membrane protein encoded in the ccoGHIS gene cluster located adjacent to the genes coding for cbb3-Cox. In vivo analysis of cbb3-Cox formation in a strain lacking ccoH showed the total absence of cbb3-Cox. Likewise, the stability of CcoH was drastically impaired in a ccoNOQP deletion strain. The mutual dependency of both proteins suggested their direct interaction, which was confirmed by site-directed photocrosslinking of CcoH to the CcoN subunit, by immunodetection of CcoH in cbb3-Cox complexes on Blue Native gels, by CcoH-cbb3-Cox co-purification and by in vitro labelling of cbb3-Cox complexes with radioactively labelled CcoH.[...]
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Variations autour d'une porphyrine à anse phénanthroline : un site distal dynamique / Variations on a phenanthroline strapped-porphyrin : evidence of a dynamic distal siteVorburger, Pauline 16 March 2012 (has links)
L’objectif de ce travail est l’obtention de mimes efficaces d’hémoprotéines telles le cytochrome P450, la myoglobine ou la cytochrome c oxydase, grâce à des variations synthétiques autour d’une porphyrine à anse phénanthroline (Porphen). Un nouveau modèle de cytochrome c oxydase a plus particulièrement été analysé ici. Il est préparé par substitution des deux positions meso d’une Zn-Porphen. Des phénomènes dynamiques ont été observés et étudiés par RMN 1H, mettant en évidence la présence d’atropoisomères et la coordination-décoordination de la pyridine proximale sur le zinc. Le remplacement du zinc par du fer a ensuite permis l’étude de la coordination d’un sixième ligand exogène dans un site distal dynamique. L’évolution de la géométrie du complexe a été suivie par spectrophotométrie UV-Visible et RPE. En présence de ligands azotés de type midazoles, il se forme dans tous les cas des complexes [1 récepteur/ 1 substrat]. La forte affinité de notre modèle pour le dioxygène a été montrée à la fois par spectrophotométrie UV-Visible, RMN 1H et par résonance Raman. Que ce soit en UV-Visible ou en RMN, la réversibilité du dioxygène a été montré par son remplacement par du CO. La souplesse de cette nouvelle architecture a été mise en évidence, par l’observation d’une relative flexibilité lors des études par spectroscopie IR de la fixation de CO dans le site distal. Cette adaptabilité est également à l’origine d’un comportement assez surprenant en électrochimie, où la réduction du fer(III) et l’oxydation du cuivre(I) en présence de O2 sont facilitées. En électrocatalyse, la réduction de O2 par ce nouveau modèle de cytochrome c oxydase n’est pas facilitée en terme de potentiel, mais efficace quant à la contribution d’un mécanisme à 4 électrons. / The purpose of this work was to prepare efficient models of cytochrome P450, hemoglobin and cytochrome c oxidase, by various synthetic modifications on a phenanthroline-strapped porphyrin (Porphen). In particular, a new model of cytochrome c oxidase was analyzed here. This compound was obtained by substitution of both meso positions of a Zn-Porphen. Dynamics phenoma were observed and analyzed by 1H NMR, showing the presence of atropoisomers and coordination-decoordination of the proximal pyridine on zinc. Zinc was then replaced by iron, which allows the coordination of a sixth exogenous ligand in the dynamic distal site. The evolution of the complexes’ geometry was monitored by UV-Visible spectrophotometry and EPR. In the presence of imidazolesligands, complexes [1 receptor/ 1 substrate] were observed in all cases. Our model’s high affinity for dioxygen was shown by UV-Visible and 1H NMR spectroscopy and Raman resonance. In UV-Visible and NMR studies, the reversibility of dioxygen binding was demonstrated by replacement with CO.The versatility of this new architecture was demonstrated during IR studies by the relative flexibility of the CO binding in the distal site. This versatility also led to surprisingly behavior in electrochemistry, where the reduction of iron(III) and the oxidation of copper(I) were easier in the presence of O2. In electrocatalysis, the reduction of O2 by this new cytochrome c oxidase model was not easier in terms of potentiel, but was efficient in a 4-electrons mechanism.
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