Global ETD Search

271	Funktionelle Bedeutung von Hämoxygenase-1 und Kohlenmonoxid für circadiane Oszillatoren Klemz, Roman 15 October 2009 (has links) Hämoxygenasen (HO) katalysieren unter der Aufnahme von molekularen Sauerstoﬀ und der Freisetzung von Kohlenmonoxid (CO) und Eisen (Fe2+) die Oxidation von Häm zu Biliverdin. HO-1, eine induzierbare Isoform der HO, wird durch ihre Aktivität mit zellschützenden, antiinﬂammatorischen und antiapoptotischen Eigenschaften in Verbindung gebracht. Dabei gilt insbesondere das CO als Mediator dieser Eigenschaften. Die molekularen Wechselwirkungen und genregulatorischen Funktionen von CO sind allerdings noch weitgehend unbekannt. In dieser Arbeit wurden mittels cDNA Microarray-Technologie Gene identiﬁziert, die in der murinen Leber nach Inhalation von CO oder nach pharmakologischer Induktion von mHO-1 eine diﬀerentielle Expression der mRNA aufwiesen. Diese Gene konnten in einen Zusammenhang mit der circadianen Uhr gebracht werden und führten zu der Hypothese, dass CO einen direkten Einﬂuss auf den molekularen Oszillator der Inneren Uhr hat. Dies konnte in primären Hepatozyten durch eine veränderte circadiane Expression der essentiellen Uhrgene mPer2 und mRev-erba nach CO-Behandlung bestätigt werden. Weiterhin wurde für mHo-1 eine, bisher unbekannte, circadian regulierte Genexpression in primären Hepatozyten und der murinen Leber gezeigt. Es konnte die Funktionalität einer speziesübergreifend, konservierten E-Box im Promotor von mHo-1 nachgewiesen werden, die diese Regulation initiieren kann. Bezüglich der circadianen Oszillation von essentiellen Komponenten der circadianen Uhr zeigten mHo-1 Knockout-Fibroblasten eine veränderte Genexpression. Die Ergebnisse dieser Arbeit demonstrieren eine enge Kopplung des Häm-Metabolismus mit der circadianen Uhr. HO-1 scheint dabei in diesem regulativen Netzwerk eine funktionale Rolle zu spielen. Einerseits könnte diese Verbindung eine weitere Kommunikation der circadianen Uhr mit metabolischen Prozessen darstellen und bietet andererseits eine neue Sichtweise bezüglich der Aufklärung der zellschützenden Eigenschaften von HO-1. / Heme oxygenases (HO) catalyze the oxidation of heme and generate the bile pigment biliverdin, ferric iron and carbon monoxide (CO). Endogenous produced CO, especially due to the activity of the inducible isoform HO-1, has been associated with cytoprotective, anti-inflammatory and –apoptotic functions. CO is a signalling molecule, but the molecular interactions and gene regulatory functions are still unknown. In the present thesis a cDNA microarray identified genes in murine liver which were expressed differentially after inhalation of CO and pharmacological induction of HO-1. Interestingly, the expression of the candidate genes is directly controlled by the molecular circadian clockwork, and led to the hypothesis that CO has an influence on the molecular oscillator of the circadian clock. It was shown, that CO influences the gene expression of essential clock genes in primary hepatocytes. Furthermore, it was demonstrated that the gene expression and activity of mHO-1 is circadian regulated in primary hepatocytes and liver, and is reasonably based on a functional E-box in the promoter of the mHO-1 gene. The deficiency of HO-1 in HO-1 knockout mice displayed differential gene expression profiles in magnitude and amplitude of the circadian oscillations of essential clock and output genes. In this work it was shown, that the heme metabolism is coupled very close to the molecular circadian oscillator. HO-1 plays a functional role in the regulation of this regulatory network, which could provide insights into the understanding of cytoprotective properties of HO-1. Hämoxygenase Kohlenmonoxid circadiane Uhr Hepatozyten heme oxygenase carbon monoxide circadian clock hepatocytes 570 Biologie 32 Biologie WD 8050 ddc:570
272	A Mass Spectrometry Approach to Ligand Identification for Orphan Fly and Human Nuclear Receptors Pardee, Keith Ian 01 September 2010 (has links) The nuclear receptor superfamily is responsible for regulating the expression of genes involved in development, reproduction and metabolism. These transcription factors control the expression of their target genes through the binding of small molecule regulators to their ligand binding domains. Classical nuclear receptors include the steroid receptors, which bind endocrine hormones and have been important targets of pharmaceutical intervention. However, approximately one half of the human nuclear receptors remain orphans and are without known cognate ligands. Focusing on the Drosophila orthologues of these orphan receptors, this project used mass spectrometry to identify the chemical diversity associated with the receptors following expression in recombinant systems. In a genome-wide screen of Drosophila nuclear receptors, this approach identified co-purifying molecules with a number of receptors. The physiological relevance of these putative ligand/receptor pairs was determined through biochemical analysis, in vivo characterization and structure determination. Ligand(s) or the ligand state was identified for the Drosophila receptors: DHR3, DHR96, E75, Ftz-f1 and USP. Of these, three were validated through the efforts of this project, and independent groups confirmed the remaining two. The most significant findings were the discoveries that the fly nuclear receptor E75 is regulated by heme, gas and redox, and that there is a similar regulatory scheme in the human orthologues, Reverbα and β. Furthermore, crystallization of the heme-bound Rev-erbβ ligand binding domain was also achieved, and this provided key insights into the mechanism of ligand regulation for the Rev-erbs. This project highlighted the role of nuclear receptors in metabolic surveillance. The ligands/signals identified in association with these receptors include: cholesterol, dehydrocholesterol, heme, NO, CO, redox and phospholipids. Unlike the classical steroid hormones, these are not dedicated signaling molecules, but instead are key substrates or products of metabolism. In the context of nuclear receptor signaling, I hypothesize that these metabolites serve as metabolic indicators/signals in the regulation of development and metabolism. Furthermore, four of these Drosophila receptors comprise the ecdysone-response pathway in the developing fly. Taken together, this suggests that both the metabolic state of the organism and steroid hormones drive nuclear receptor regulation of development. nuclear receptor orphan E75 Rev-erb heme nitric oxide crystal structure DHR3 DHR96 cholesterol metabolism ligand Drosophila human mass spectrometry 0307 0760
273	Vrozené poruchy metabolismu bilirubinu / Inherited Disorders of Bilirubin Metabolism Šlachtová, Lenka January 2013 (has links) Inherited disorders of bilirubin metabolism - hereditary hyperbilirubinemias - are metabolic disorders manifested in early childhood. Unconjugated hyperbilirubinemias result from the defect of the enzyme uridine diphosphoglucuronosyltransferase (UGT1A1). UGT1A1 mediates the conjugation of bilirubin with glucuronid acid in hepatocytes and its elimination to water soluble compound. In the next step of bilirubin degradation the transport of conjugated bilirubin from hepatocyte into the bile occure. It is caused by the ATP dependent transporters ABCC2, ATP1B1 and OATP1B3. Mutations in the genes coding the bilirubin transporters results in conjugated hyperbilirubinemia Dubin-Johnson or Rotor syndrome. This study is focused on unconjugated hyperbilirubinemia in adolescents including the non-typical manifestations and the defects of ABCC2 transporter and their phenotype in humans.
274	Possível envolvimento do monóxido de carbono na modulação do comportamento emocional em ratos: o papel do locus coeruleus / Involvement of carbono monoxide in the emotional behavior in rats: role of the locus coeruleus. Cazuza, Rafael Alves 03 March 2017 (has links) O gás monóxido de carbono (CO) possui diversas funções no sistema nervoso central (SNC) funcionando como neuromodulador, como por exemplo da regulação da temperatura corporal, da nocicepção e mais recentemente, do comportamento emocional. Este neuromodulador gasoso é produzido pela ação da enzima heme oxigenase (HO), a qual é encontrada em diferentes áreas do SNC. Com destaque, esta enzima tem alta expressão no locus coeruleus (LC), o que sugere o envolvimento do CO na modulação de funções desempenhadas por esta estrutura. O LC localiza-se na ponte, sendo a maior origem da inervação noradrenérgica do SNC. Esta estrutura tem participação ativa na modulação das respostas relacionadas ao estresse, em particular, na modulação do comportamento emocional, desde que integra o Sistema de Inibição Comportamental (SIC), o qual inclui ainda o sistema septo-hipocampal e os núcleos da rafe. O SIC é responsável por comandar respostas defensivas de avaliação de risco, alerta e atenção, as quais podem ser eliciadas pela ansiedade. Dentro desta perspectiva, o presente estudo teve como objetivo avaliar se a ativação sistêmica da via HO-CO pode modular o comportamento emocional de ratos, e se há participação do LC. Assim, este trabalho avaliou se o tratamento sistêmico via intraperitoneal (i.p.) agudo (3 h antes) ou crônico (10 dias/2 vezes ao dia) com um liberador de monóxido de carbono (CORM-2), ou com indutor da enzima HO (CoPP), altera as respostas comportamentais no teste do labirinto em cruz elevado (LCE) e no teste claro-escuro (TCE) em ratos, bem como a expressão da enzima HO no LC. Em uma segunda etapa foi avaliado se a administração aguda de CORM-2 ou CoPP altera o comportamento avaliado no LCE e no TCE de ratos submetidos ao estresse crônico variado (ECV) por 10 dias. Os resultados mostraram que o CO induzido pela administração aguda ou crônica de CORM-2 ou CoPP possui efeito ansiolítico. Ainda, o tratamento com CORM-2 ou CoPP aumentou a expressão da enzima HO-1 em células localizadas no LC, sem alterar a imunorreatividade à enzima HO-2. Considerando os grupos submetidos ao estresse ECV, nem a ativação da via HO-CO ou o ECV apresentaram efeitos significativos nos comportamentos avaliados nos testes LCE e TCE. Os resultados do presente estudo sugerem que o tratamento sistêmico com drogas que modulam a liberação de CO possui claro efeito ansiolítico. Assim, é possível que o CO possa ser uma droga com potencial terapêutico para o tratamento de desordens neuropsiquiátricas. / The carbon monoxide gas (CO) has several functions in the central nervous system acting as a neuromodulator, such as in the body temperature regulation, nociception and more recently, in the emotional behavior modulation. This gas is produced by the action of the heme oxigenase enzyme (HO), which is found in different areas of the central nervous system (CNS). It is important to note that this enzyme has high expression in the locus coeruleus (LC), suggesting the involvement of CO in the modulation functions performed by this midbrain structure. LC is located in the pons, being the source of majority of the noradrenergic innervation of the CNS. This structure is intimately involved in the stress modulation responses, particularly in the emotional behavior regulation, since it integrates the Behavioral Inhibition System (BIS), which also includes septum-hippocampal system and raphe nucleus. The BIS is responsible for defensive responses like the risk assessment and alertness trigged by anxiety. Within this perspective, the present study was designed to evaluate whether the systemic HO-CO pathway can modulate emotional behavior of rats, and if the HO enzyme of the neurons located into LC is involved in this response. Thus, this study evaluated whether the acute systemic i.p. treatment (3 hours before) or chronic (10 days / 2 times a day) with a carbon monoxide releaser (CORM-2) or inducer of heme enzyme oxygenase (CoPP), is able to alter the behavioral responses in the elevated plus maze (EPM) and in the light-dark box test (LDB) in rats, and the HO enzyme expression in the LC. Furthermore, the effect of the acute administration of CORM-2 or CoPP was evaluated in the emotional behavior assessed in the EPM and LDB by rats submitted to unpredictable chronic stress (during 10 days). The results showed that the CO induced by acute or chronic administration of CORM-2 or CoPP has an anxiolytic-like effect. Furthermore, treatment with CORM-2 or CoPP promoted an increase of HO-1 enzyme expression in cells located in the LC without altering the immunoreactivity of HO-2 enzyme. Still, considering the rats subjected to stress UCS neither the activation of HO-CO pathway nor the UCS protocol altered the emotional behavior evaluated in the EPM and LDB tests. The results of this study suggest that systemic treatment with drugs that modulate the CO release has anxiolytic effect. Thus, it is possible that CO can be a potential drug therapeutic target for neuropsychiatric disorders. Acute stress Ansiedade Comportamento emocional Elevated plus maze Heme oxygenase HO-1 HO-2 Light-dark box test Locus coeruleus Monóxido de carbono Unpredictable chronic stress
275	Effets des immunoglobulines intraveineuses sur les cellules de l'immunité innée / Effects of intravenous immunoglobulin on innate immune cells Galeotti, Caroline 12 March 2018 (has links) Les IgIV, une préparation thérapeutique d'IgG normales, sont utilisées dans le traitement de diverses maladies auto-immunes et inflammatoires. Les mécanismes par lesquels les IgIV exercent une activité anti-inflammatoire ne sont pas complètement compris. Elles interagissent avec de nombreux composants du système immunitaire et modulent leurs fonctions. Des études récentes ont rapporté que l'hème oxygénase-1 (HO-1) joue un rôle important dans la régulation de la réponse inflammatoire dans un certain nombre de pathologies. Plusieurs agents thérapeutiques exercent des effets anti-inflammatoires grâce à l'induction de l'HO-1. Etant donné le rôle commun anti-inflammatoire de l'HO-1 et des IgIV, j'ai étudié l'implication de l'HO-1 dans les mécanismes d'action des IgIV. J'ai montré que les effets des IgIV ne sont pas associés à l'induction de l'HO-1, que ce soit dans des cellules de l'immunité innée comme les monocytes, cellules dendritiques ou macrophages, ou dans les reins et foie de souris avec une encéphalomyélite auto-immune expérimentale traitées par les IgIV. Des données récentes dans des modèles expérimentaux suggèrent que les IgIV induisent la sécrétion d’IL-4 des basophiles en augmentant l’IL-33 des cellules innées SIGN-R1+. J’ai rapporté que les IgIV induisent directement l’activation de basophiles pré-stimulés avec l’IL-3 alors que contrairement au modèle murin, l’IL-33 n’est pas indispensable. L’activation des basophiles par les IgIV est associée à l’expression augmentée de CD69 et la sécrétion d’IL-4, d’IL-6 et d’IL-8. Ces fonctions sont médiées par les fragments F(ab’)2 qui se lient à des IgE membranaires et activent la voie Syk. / Intravenous immunoglobulin (IVIG), a therapeutic normal immunoglobulin G preparation, is used in the therapy of various autoimmune and inflammatory conditions. The mechanisms by which IVIG exerts anti-inflammatory effects are not completely understood. It interacts with numerous components of the immune system including dendritic cells, macrophages, T and B cells and modulates their functions. Recent studies have reported that heme oxygenase-1 (HO-1) pathway plays an important role in the regulation of inflammatory response in several pathologies. Several therapeutic agents exert anti-inflammatory effects via induction of HO-1. Therefore, in view of common anti-inflammatory role exerted by both HO-1 and IVIG, I investigated if mechanisms of IVIG implicate HO-1. I show that anti-inflammatory effects of IVIG were not associated with an induction of HO-1 either in innate cells such as monocytes, dendritic cells and macrophages or in the kidneys or liver of experimental autoimmune encephalomyelitis. Recent data in experimental models suggest that IVIG induces IL-4 in basophils by enhancing IL-33 in SIGN-R1+ innate cells. I reported that IVIG directly induces activation of IL-3-primed basophils while unlike mice IL-33 was dispensable. The activation of basophils by IVIG was associated with enhanced expression of CD69 and secretion of IL-4, IL-6 and IL-8. These functions of IVIG are mediated via F(ab’)2 fragments that bind to basophil surface IgE and activate Syk pathway. Immunoglobulines intraveineuses Hème oxygénase-1 Basophile Interleukine-3 Cellule de l'immunité innée Intravenous immunoglobulin Innate immune cells Basophil Heme-oxygenase 1 Interleukin-3 615.37
276	Experimental studies of proton translocation reactions in biological systems : Electrogenic events in heme-copper oxidases Lepp, Håkan January 2008 (has links) <p>Terminal heme-copper oxidases (HCuOs) are transmembrane proteins that catalyze the final step in the respiratory chain - the reduction of O<sub>2</sub> to H<sub>2</sub>O, coupled to energy conservation by generation of an electrochemical proton gradient. The most extensively investigated of the HCuOs are the <i>aa</i><sub>3</sub>-type oxidases, to which cytochrome <i>c</i> oxidase (Cyt<i>c</i>O) belongs, which uses energy released in the O<sub>2</sub>-reduction for proton pumping. The bacterial nitric oxide reductases (NORs) have been identified as divergent members of the HCuO-superfamily and are involved in the denitrification pathway where they catalyze the reduction of NO to NO<sub>2</sub>. Although as exergonic as O<sub>2</sub>-reduction, this reaction is completely non-electrogenic. Among the traditional HCuOs, the <i>cbb</i><sub>3</sub>-type oxidases are the closest relatives to the NORs and as such provide a link between the <i>aa</i><sub>3</sub> oxidases and the NORs. The <i>cbb</i><sub>3</sub> oxidases have been shown to pump protons with nearly the same efficiency as the <i>aa</i><sub>3</sub> oxidases, despite low sequence similarity.</p><p>This thesis is focused on measurements of membrane potential generating reactions during catalysis in the Cyt<i>c</i>O and the <i>cbb</i><sub>3</sub> oxidase from <i>Rhodobacter sphaeroides</i>, and the NOR from <i>Paracoccus</i> <i>denitrificans</i>, using a time resolved electrometric technique. The pH dependence of the membrane potential generation in Cyt<i>c</i>O showed that only one proton is taken up and that no protons are pumped, at high pH. An additional kinetic phase was also detected at high pH that presumably originates to from charge-transfer within the K-pathway. Possible reasons for uncoupling, and the extent of charge-transfer, were studied using structural variants of Cyt<i>c</i>O. The measurements established that electrons and protons are taken up from the same side of the membrane in NOR. In addition, the directionality for proton uptake in <i>cbb</i><sub>3</sub> oxidase appeared to be dependent on the choice of substrate while proton pumping was indicated to occur only during O<sub>2</sub>-reduction.</p> heme-copper oxidase cytochrome c oxidase nitric oxide reductase cbb3-type oxidase proton pumping uncoupling charge-transfer electrogenic event flow-flash Biophysics Biofysik
277	Nitric Oxide Reductase from<i> Paracoccus denitrificans</i> : A Proton Transfer Pathway from the “Wrong” Side Flock, Ulrika January 2008 (has links) <p>Denitrification is an anaerobic process performed by several soil bacteria as an alternative to aerobic respiration. A key-step in denitrification (the N-N-bond is made) is catalyzed by nitric oxide reductase (NOR); 2NO + 2e<sup>-</sup> + 2H<sup>+</sup> → N<sub>2</sub>O + H<sub>2</sub>O. NOR from <i>Paracoccus denitrificans</i> is a member of the heme copper oxidase superfamily (HCuOs), where the mitochondrial cytochrome c oxidase is the classical example. NOR is situated in the cytoplasmic membrane and can, as a side reaction, catalyze the reduction of oxygen to water.</p><p>NORs have properties that make them divergent members of the HCuOs; the reactions they catalyze are not electrogenic and they do not pump protons. They also have five strictly conserved glutamates in their catalytic subunit (NorB) that are not conserved in the ‘classical’ HCuOs. It has been asked whether the protons used in the reaction really come from the periplasm and if so how do the protons proceed through the protein into the catalytic site?</p><p>In order to find out whether the protons are taken from the periplasm or the cytoplasm and in order to pinpoint the proton-route in NorB, we studied electron- and proton transfer during a single- as well as multiple turnovers, using time resolved optical spectroscopy. Wild type NOR and several variants of the five conserved glutamates were investigated in their solubilised form or/and reconstituted into vesicles.</p><p>The results demonstrate that protons needed for the reaction indeed are taken from the periplasm and that all but one of the conserved glutamates are crucial for the oxidative phase of the reaction that is limited by proton uptake to the active site.</p><p>In this thesis it is proposed, using a model of NorB, that two of the glutamates are located at the entrance of the proton pathway which also contains two of the other glutamates close to the active site.</p> denitrification nitric oxide reductase heme copper oxidase superfamily divergent member proton transfer electron transfer single turnover spectroscopy periplasm glutamate proton pathway Biochemistry Biokemi
278	The Physiological Cost of Antibiotic Resistance Macvanin, Mirjana January 2003 (has links) <p>Becoming antibiotic resistant is often associated with fitness costs for the resistant bacteria. This is seen as a loss of competitiveness against the antibiotic-sensitive wild-type in an antibiotic-free environment. In this study, the physiological alterations associated with fitness cost of antibiotic resistance <i>in vitro</i> (in the laboratory medium), and <i>in vivo</i> (in a mouse infection model), are identified in the model system of fusidic acid resistant (Fus<sup>R</sup>) <i>Salmonella</i> <i>enterica</i> serovar Typhimurium.</p><p>Fus<sup>R</sup> mutants have mutations in <i>fusA</i>, the gene that encodes translation elongation factor G (EF-G). Fus<sup>R</sup> EF-G has a slow rate of regeneration of active EF-G·GTP off the ribosome, resulting in a slow rate of protein synthesis. The low fitness of Fus<sup>R</sup> mutants <i>in vitro</i>, and <i>in vivo</i>, can be explained in part by a slow rate of protein synthesis and resulting slow growth. However, some Fus<sup>R</sup> mutants with normal rates of protein synthesis still suffer from reduced fitness <i>in vivo</i>. We observed that Fus<sup>R</sup> mutants have perturbed levels of the global regulatory molecule ppGpp. One consequence of this is an inefficient induction of RpoS, a regulator of general stress reponse and an important virulence factor for <i>Salmonella</i>. In addition, we found that Fus<sup>R</sup> mutants have reduced amounts of heme, a co-factor of catalases and cytochromes. As a consequence of the heme defect, Fus<sup>R</sup> mutants have a reduced ability to withstand oxidative stress and a low rate of aerobic respiration.</p><p>The pleiotropic phenotypes of Fus<sup>R</sup> mutants suggest that antibiotic resistance can be associated with broad changes in bacterial physiology. Knowledge of physiological alterations that reduce the fitness of antibiotic-resistant mutants can be useful in identifying novel targets for antimicrobial agents. Drugs that alter the levels of global transcriptional regulators such as ppGpp or RpoS deserve attention as potential antimicrobial agents. Finally, the observation that Fus<sup>R</sup> mutants have increased sensitivity to several unrelated classes of antibiotics suggests that the identification of physiological cost of resistance can help in optimizing treatment of resistant bacterial populations.</p> Microbiology fusidic acid fitness cost protein synthesis EF-G ppGpp RpoS oxidative stress heme Mikrobiologi
279	The Physiological Cost of Antibiotic Resistance Macvanin, Mirjana January 2003 (has links) Becoming antibiotic resistant is often associated with fitness costs for the resistant bacteria. This is seen as a loss of competitiveness against the antibiotic-sensitive wild-type in an antibiotic-free environment. In this study, the physiological alterations associated with fitness cost of antibiotic resistance in vitro (in the laboratory medium), and in vivo (in a mouse infection model), are identified in the model system of fusidic acid resistant (FusR) Salmonella enterica serovar Typhimurium. FusR mutants have mutations in fusA, the gene that encodes translation elongation factor G (EF-G). FusR EF-G has a slow rate of regeneration of active EF-G·GTP off the ribosome, resulting in a slow rate of protein synthesis. The low fitness of FusR mutants in vitro, and in vivo, can be explained in part by a slow rate of protein synthesis and resulting slow growth. However, some FusR mutants with normal rates of protein synthesis still suffer from reduced fitness in vivo. We observed that FusR mutants have perturbed levels of the global regulatory molecule ppGpp. One consequence of this is an inefficient induction of RpoS, a regulator of general stress reponse and an important virulence factor for Salmonella. In addition, we found that FusR mutants have reduced amounts of heme, a co-factor of catalases and cytochromes. As a consequence of the heme defect, FusR mutants have a reduced ability to withstand oxidative stress and a low rate of aerobic respiration. The pleiotropic phenotypes of FusR mutants suggest that antibiotic resistance can be associated with broad changes in bacterial physiology. Knowledge of physiological alterations that reduce the fitness of antibiotic-resistant mutants can be useful in identifying novel targets for antimicrobial agents. Drugs that alter the levels of global transcriptional regulators such as ppGpp or RpoS deserve attention as potential antimicrobial agents. Finally, the observation that FusR mutants have increased sensitivity to several unrelated classes of antibiotics suggests that the identification of physiological cost of resistance can help in optimizing treatment of resistant bacterial populations. Microbiology fusidic acid fitness cost protein synthesis EF-G ppGpp RpoS oxidative stress heme Mikrobiologi
280	Experimental studies of proton translocation reactions in biological systems : Electrogenic events in heme-copper oxidases Lepp, Håkan January 2008 (has links) Terminal heme-copper oxidases (HCuOs) are transmembrane proteins that catalyze the final step in the respiratory chain - the reduction of O2 to H2O, coupled to energy conservation by generation of an electrochemical proton gradient. The most extensively investigated of the HCuOs are the aa3-type oxidases, to which cytochrome c oxidase (CytcO) belongs, which uses energy released in the O2-reduction for proton pumping. The bacterial nitric oxide reductases (NORs) have been identified as divergent members of the HCuO-superfamily and are involved in the denitrification pathway where they catalyze the reduction of NO to NO2. Although as exergonic as O2-reduction, this reaction is completely non-electrogenic. Among the traditional HCuOs, the cbb3-type oxidases are the closest relatives to the NORs and as such provide a link between the aa3 oxidases and the NORs. The cbb3 oxidases have been shown to pump protons with nearly the same efficiency as the aa3 oxidases, despite low sequence similarity. This thesis is focused on measurements of membrane potential generating reactions during catalysis in the CytcO and the cbb3 oxidase from Rhodobacter sphaeroides, and the NOR from Paracoccus denitrificans, using a time resolved electrometric technique. The pH dependence of the membrane potential generation in CytcO showed that only one proton is taken up and that no protons are pumped, at high pH. An additional kinetic phase was also detected at high pH that presumably originates to from charge-transfer within the K-pathway. Possible reasons for uncoupling, and the extent of charge-transfer, were studied using structural variants of CytcO. The measurements established that electrons and protons are taken up from the same side of the membrane in NOR. In addition, the directionality for proton uptake in cbb3 oxidase appeared to be dependent on the choice of substrate while proton pumping was indicated to occur only during O2-reduction. heme-copper oxidase cytochrome c oxidase nitric oxide reductase cbb3-type oxidase proton pumping uncoupling charge-transfer electrogenic event flow-flash Biophysics Biofysik

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