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Electron and Proton Transfer in Nitric Oxide Reductase : NO Binding, NO Reduction and no PumpingLachmann, Peter January 2009 (has links)
Nitric oxide reductase (NOR) from Paracoccus denitrificans catalyzes the two electronreduction of NO to N2O (2NO + 2H+ + 2e- → N2O + H2O) as part of the process ofdenitrification, the step-wise reduction of nitrate to dinitogen. The NOR-catalyzedreaction is central in the nitrogen cycle, since in this step the N=N double bond isformed. NOR is a deviant heme copper oxidase, located in the cytoplasmic membrane,containing four redox active cofactors. Like cytochrome c oxidase (CcO), NOR canreduce oxygen to water as a side reaction, but in contrast to CcO it does not contributeto the proton motive force that drives the conversion of ADP to ATP by ATP synthase.The active site in the catalytic subunit NorB consists of a non-heme iron FeB and a hemeb3 that are anti-ferromagnetically coupled. Additionally a low-spin heme b in NorB isinvolved in accepting electrons from heme c of NorC, a membrane anchored cytochromec, which is the second subunit of the purified NorBC heterodimer.We have studied the terminal region of the proton entry channel and possible ligands tothe binuclear active site of NOR using the flow-flash technique and could demonstratethat the putative proton channel residues Glu(E)198 and E267 in NorB are essential forproton uptake. We propose that they define the terminal proton channel region close tothe binuclear site. An alanine variant of the fully conserved amino acid residue E202 ofNOR that, according to the model of NOR (47), is located in the vicinity to the active site,is neither essential for catalytic activity nor integrity of the active site.Furthermore, we were able to demonstrate the [NO] dependency of NOR in the reactionbetween fully reduced protein and NO using the flow-flash technique (21, 24). Thebinding of NO to the fully reduced enzyme is clearly concentration dependent,inconsistent with a previously proposed obligatory binding of NO first to FeB before itligates to heme b3, where it, in the first turnover, is reduced by the electrons from theactive site. Further oxidation involves electron transfer from the low-spin hemes, which isaccelerated at lower [NO]. This acceleration at lower substrate concentration is evenlarger at decreased pH. We could demonstrate that substrate inhibition, observed insteady-state measurements, occurs already on oxidizing the fully reduced enzyme,indicating that NO binds to its inhibitory site before electrons can redistribute to theactive site from the low-spin hemes.
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Kinetics of proton and electron transfer in heme-copper oxidasesLachmann, Peter January 2015 (has links)
Heme-copper oxidases are transmembrane proteins that are found in aerobic and anaerobic respiratory chains. During aerobic respiration, these enzymes reduce dioxygen to water. The energy released in the reaction is used to transport protons across a biological membrane. Stored as proton electrochemical gradient, the energy can be used to regenerate ATP. It is known that aa3 oxidases, which are the most common oxidases, transport pumped protons and protons used for the catalytic reaction using two proton pathways. However, the molecular mechanism of pumping is still being debated. When oxygen is available in very small quantities, oxygen reductases with high affinity for oxygen are expressed by organisms like Thermus thermophilus. The proton pumping mechanism in the ba3 oxidase is slightly different from that of aa3 oxidases as this enzyme only uses a single proton uptake pathway. Here we analyzed the reaction mechanism of ba3 oxidase and found evidence that the first proton taken up by the four-electron reduced ba3 oxidase is transferred to a site distant from the catalytic site, the pump site, and that only every second proton taken up from solution is pumped. Data obtained from studies using site-directed mutagenesis and flow-flash spectroscopy suggest a probable location of the pump site. Under anaerobic conditions, some organisms are able to generate a proton- motive force using nitrate and nitrite as electron acceptors. In this process, the cytotoxic reaction intermediate nitric oxide is produced. Nitric oxide reductase (NOR), a deviant heme-copper oxidase that reduces NO to the rather harmless N2O, does not pump any protons. The catalytic mechanism of nitric oxide reduction by NOR is very poorly understood. Here we demonstrate that substrate inhibition, which occurs in NOR from Paracoccus denitrificans above 5 μM NO, can already be observed before the electrons from the low-spin hemes re-distribute to the active site. Furthermore, we found that a single specific proton pathway is used for proton-transfer leading from the periplasm to the active site.
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Experimental studies of proton translocation reactions in biological systems : Electrogenic events in heme-copper oxidasesLepp, 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>
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Nitric Oxide Reductase from<i> Paracoccus denitrificans</i> : A Proton Transfer Pathway from the “Wrong” SideFlock, 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>
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Experimental studies of proton translocation reactions in biological systems : Electrogenic events in heme-copper oxidasesLepp, 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.
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Nitric Oxide Reductase from Paracoccus denitrificans : A Proton Transfer Pathway from the “Wrong” SideFlock, Ulrika January 2008 (has links)
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- + 2H+ → N2O + H2O. NOR from Paracoccus denitrificans 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. 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? 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. 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. 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.
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Proton pathways in energy conversion : K-pathway analogs in O2- and NO-reductasesGonska, Nathalie January 2017 (has links)
Oxygen and nitric oxide reductases are enzymes found in aerobic and anaerobic respiration, respectively. Both enzyme groups belong to the superfamily of Heme-Copper Oxidases, which is further divided into several subgroups: oxygen-reducing enzymes into A-, B- and C-type and nitric oxide reductases into qNORs and cNORs. Oxygen reducing enzymes use the energy released from oxygen reduction to take up electrons and protons from different sides of the membrane. Additionally, protons are pumped. These processes produce a membrane potential, which is used by the ATP-synthase to produce ATP, the universal energy currency of the cell. Nitric oxide reductases are not known to conserve the energy from nitric oxide reduction, although the reaction is highly exergonic. Here, the detailed mechanism of a B-type oxidase is studied with special interest in an element involved in proton pumping (proton loading site, PLS). The study supports the hypothesis that the PLS is protonated in one and deprotonated in the consecutive step of the oxidative catalytic cycle, and that a proton is pumped during the final oxidation phase. It further strengthens the previous suggestion that the PLS is a cluster instead of a single residue or heme propionate. Additionally, it is proposed that the residue Asp372, which is in vicinity of the heme a3 propionates previously suggested as PLS, is part of this cluster. In another study, we show that the Glu15II at the entry of the proton pathway in the B-type oxidase is the only crucial residue for proton uptake, while Tyr248 is or is close to the internal proton donor responsible for coupling proton pumping to oxygen reduction. The thesis also includes studies on the mechanism and electrogenicity of qNOR. We show that there is a difference in the proton-uptake reaction between qNOR and the non-electrogenic homolog cNOR, hinting at a different reaction mechanism. Further, studies on a qNOR from a different host showed that qNOR is indeed electrogenic. This surprising result opens up new discussions on the evolution of oxygen and nitric oxide reductases, and about how energy conservation can be achieved. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Manuscript.</p>
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