The multiple functions of coenzyme Q

The coenzyme function of ubiquinone was subject of extensive studies in mitochondria since more than 40 years. The catalytic activity of ubiquinone (UQ) in electron transfer and proton translocation in cooperation with mitochondrial dehydrogenases and cytochromes contributes essentially to the bioenergetic activity of ATP synthesis. In the past two decades UQ was recognized to exert activities which differ from coenzyme functions in mitochondria. From extraction/reincorporation experiments B. Chance has drawn the conclusion that redox-cycling of mitochondrial ubiquinone supplies electrons for univalent reduction of dioxygen. The likelihood of O2(.-) release as normal byproduct of respiration was based on the existence of mitochondrial SOD and the fact that mitochondrial oxygen turnover accounts for more than 90% of total cellular oxygen consumption. Arguments disproving this concept are based on results obtained from a novel noninvasive, more sensitive detection method of activated oxygen species and novel experimental approaches, which threw light into the underlying mechanism of UQ-mediated oxygen activation. Single electrons for O2(.-) formation are exclusively provided by deprotonated ubisemiquinones. Impediment of redox-interaction with the bc1 complex in mitochondria or the lack of stabilizing interactions with redox-partners are promotors of autoxidation. The latter accounts for autoxidation of antioxidant-derived ubisemiquinones in biomembranes, which do not recycle oxidized ubiquinols. Also O2(.-)-derived H2O2 was found to interact with ubisemiquinones both in mitochondria and nonrecycling biomembranes when ubiquinol was active as antioxidant. The catalysis of reductive homolytic cleavage of H2O2, which contributes to HO. formation in biological systems was confirmed under defined chemical conditions in a homogenous reduction system. Apart from dioxygen and hydrogen peroxide we will provide evidence that also nitrite may chemically interact with the ubiquinol/bc1 redox couple in mitochondria. The reaction product NO was reported elsewhere to be a significant bioregulator of the mitochondrial respiration and O2 activation. Another novel finding documents the bioenergetic role of UQ in lysosomal proton intransport. A lysosomal chain of redox couples will be presented, which includes UQ and which requires oxygen as the terminal electron acceptor.     

Antioxidant action of ubiquinol homologues with different isoprenoid chain length in biomembranes

Ubiquinones (CoQn) are intrinsic lipid components of many membranes. Besides their role in electron-transfer reactions they may act as free radical scavengers, yet their antioxidant function has received relatively little study. The efficiency of ubiquinols of varying isoprenoid chain length (from Q0 to Q10) in preventing (Fe2+ + ascorbate)-dependent or (Fe2+ + NADPH)-dependent lipid peroxidation was investigated in rat liver microsomes and brain synaptosomes and mitochondria. Ubiquinols, the reduced forms of CoQn, possess much greater antioxidant activity than the oxidized ubiquinone forms. In homogenous solution the radical scavenging activity of ubiquinol homologues does not depend on the length of their isoprenoid chain. However in membranes ubiquinols with short isoprenoid chains (Q1-Q4) are much more potent inhibitors of lipid peroxidation than the longer chain homologues (Q5-Q10). It is found that: i) the inhibitory action, that is, antioxidant efficiency of short-chain ubiquinols decreases in order Q1 greater than Q2 greater than Q3 greater than Q4; ii) the antioxidant efficiency of long-chain ubiquinols is only slightly dependent on their concentrations in the order Q5 greater than Q6 greater than Q7 greater than Q8 greater than Q9 greater than Q10 and iii) the antioxidant efficiency of Q0 is markedly less than that of other homologues. Interaction of ubiquinols with oxygen radicals was followed by their effects on luminol-activated chemiluminescence. Ubiquinols Q1-Q4 at 0.1 mM completely inhibit the luminol-activated NADPH-dependent chemiluminescent response of microsomes, while homologues Q6-Q10 exert no effect. In contrast to ubiquinol Q10 (ubiquinone Q10) ubiquinone Q1 synergistically enhances NADPH-dependent regeneration of endogenous vitamin E in microsomes thus providing for higher antioxidant protection against lipid peroxidation. The differences in the antioxidant potency of ubiquinols in membranes are suggested to result from differences in partitioning into membranes, intramembrane mobility and non-uniform distribution of ubiquinols resulting in differing efficiency of interaction with oxygen and lipid radicals as well as different efficiency of ubiquinols in regeneration of endogenous vitamin E.     

Investigation of ubiquinol formation in isolated photosynthetic reaction centers by rapid-scan Fourier transform IR spectroscopy

Light-induced formation of ubiquinol-10 in Rhodobacter sphaeroides reaction centers was followed by rapid-scan Fourier transform IR difference spectroscopy, a technique that allows the course of the reaction to be monitored, providing simultaneously information on the redox states of cofactors and on protein response. The spectrum recorded between 4 and 29 ms after the second flash showed bands at 1,470 and 1,707 cm(-1), possibly due to a QH(-) intermediate state. Spectra recorded at longer delay times showed a different shape, with bands at 1,388 (+) and 1,433 (+) cm(-1) characteristic of ubiquinol. These spectra reflect the location of the ubiquinol molecule outside the Q(B) binding site. This was confirmed by Fourier transform IR difference spectra recorded during and after continuous illumination in the presence of an excess of exogenous ubiquinone molecules, which revealed the process of ubiquinol formation, of ubiquinone/ubiquinol exchange at the Q(B) site and between detergent micelles, and of Q(B)(-) and QH(2) reoxidation by external redox mediators. Kinetics analysis of the IR bands allowed us to estimate the ubiquinone/ubiquinol exchange rate between detergent micelles to approximately 1 s. The reoxidation rate of Q(B)(-) by external donors was found to be much lower than that of QH(2), most probably reflecting a stabilizing/protecting effect of the protein for the semiquinone form. A transient band at 1,707 cm(-1) observed in the first scan (4-29 ms) after both the first and the second flash possibly reflects transient protonation of the side chain of a carboxylic amino acid involved in proton transfer from the cytoplasm towards the Q(B) site.     

On the sidedness of the ubiquinone redox cycle. Kinetic studies in mitochondrial membranes

The inhibition of NADH oxidation but not of succinate oxidation by the low ubiquinone homologs UQ-2 and UQ-3 is not due to a lower rate of reduction of ubiquinone by NADH dehydrogenase: experiments in submitochondrial particles and in pentane-extracted mitochondria show that UQ-3 is reduced at similar rates using either NADH or succinate as substrates. The fact that reduced UQ-3 cannot be reoxidized when reduced by NADH but can be reoxidized when reduced by succinate may be explained by a compartmentation of ubiquinone.Using reduced ubiquinones as substrates of ubiquinol oxidase activity in intact mitochondria and in submitochondrial particles we found that ubiquinol-3 is oxidized at higher rates in submitochondrial particles than in mitochondria. The initial rates of ubiquinol oxidation increased with increasing lengths of isoprenoid side chains in mitochondria, but decreased in submitochondrial particles. These findings suggest that the site of oxidation of reduced ubiquinone is on the matrix side of the membrane; reduced ubiquinones may reach their oxidation site in mitochondria only crossing the lipid bilayer: the rate of diffusion of ubiquinol-3 is presumably lower than that of ubiquinol-7 due to the differences in hydrophobicity of the two quinones.     

Effect of ubiquinone extraction on ubiquinol-1 oxidase activity in beef heart mitochondria

Extraction of endogenous ubiquinone with different methods does not influence ubiquinol oxidase activity in lyophilized mitochondria in terms ofK _M, although a decrease ofV _max is sometimes observed. Experiments with submitochondrial particles from a UQ-deficient mutant ofS. cerevisiae confirm the results with UQ-depleted mitochondria and support the idea that endogenous ubiquinone is not required for the oxidation of exogenous ubiquinols by complex III.     

Role of a bound ubiquinone on reactions of the Escherichia coli cytochrome bo with ubiquinol and dioxygen.

To probe the functional role of a bound ubiquinone-8 in cytochrome bo-type ubiquinol oxidase from Escherichia coli, we examined reactions with ubiquinol-1 and dioxygen. Stopped-flow studies showed that anaerobic reduction of the wild-type and the bound ubiquinone-free (DeltaUbiA) enzymes with ubiquinol-1 immediately takes place with four kinetic phases. Replacement of the bound ubiquinone with 2,6-dibromo-4-cyanophenol (PC32) suppressed the anaerobic reduction of the hemes with ubiquinol-1 by eliminating the fast phase. Flow-flash studies in the reaction of the fully reduced enzyme with dioxygen showed that the heme b-to-heme o electron transfer occurs with a rate constant of approximately 1x10(4) s(-1) in all three preparations. These results support our previous proposal that the bound ubiquinone is involved in facile oxidation of substrates in subunit II and subsequent intramolecular electron transfer to low-spin heme b in subunit I.     

Kinetic mechanism of quinol oxidation by cytochrome bd studied with ubiquinone-2 analogs

Cytochrome bd is a heterodimeric terminal ubiquinol oxidase of Escherichia coli under microaerophilic growth conditions. The oxidase activity shows sigmoidal concentration-dependence with low concentrations of ubiquinols, and a marked substrate inhibition with high concentrations of ubiquinol-2 analogs [Sakamoto, K., Miyoshi, H., Takegami, K., Mogi, T., Anraku, Y., and Iwamura H. (1996) J. Biol. Chem. 271, 29897-29902]. Kinetic analysis of the oxidation of the ubiquinol-2 analogs, where the 2- or 3-methoxy group has been substituted with an azido or ethoxy group, suggested that its peculiar enzyme kinetics can be explained by a modified ping-pong bi-bi mechanism with the formation of inactive binary complex FS in the one-electron reduced oxygenated state and inactive ternary complex (E2S)S(n) on the oxidation of the second quinol molecule. Structure-function studies on the ubiquinol-2 analogs suggested that the 6-diprenyl group and the 3-methoxy group on the quinone ring are involved in the substrate inhibition. We also found that oxidized forms of ubiquinone-2 analogs served as weak noncompetitive inhibitors. These results indicate that the mechanism for the substrate oxidation by cytochrome bd is different from that of the heme-copper terminal quinol oxidase and is tightly coupled to dioxygen reduction chemistry.     

Diffusional effects in the steady state kinetics of ubiquinol cytochrome c reductase in bovine heart submitochondrial particles

The steady-state kinetics of ubiquinol cytochrome c reductase was investigated in submitochondrial particles using ubiquinol-1 as electron donor in media of increasing viscosities obtained by water-polyethylene glycol mixtures. The minimum association rate constant, kmin = kcat/km, for cytochrome c was strongly viscosity dependent, whereas kmin for ubiquinol-1 was only weakly affected by viscosity. It is concluded that the interaction of cytochrome c with the membranous reductase is largely under diffusion control, whereas the oxidation of ubiquinol by the enzyme is not significantly controlled by diffusion in either the aqueous medium or the membrane. The results are compatible with the presence of a diffusion limited step in cytochrome c but not in ubiquinone in mitochondrial electron transfer.     

Direct and indirect roles of cytochrome b in the mediation of superoxide generation and NO catabolism by mitochondrial succinate-cytochrome c reductase

Mitochondrial superoxide (O2*-) production is an important mediator of oxidative cellular injury. Succinate-cytochrome c reductase (SCR) of the electron transport chain has been implicated as an essential part of the mediation of O2*- generation and an alternative target of nitric oxide (NO) in the regulation of mitochondrial respiration. The Q cycle mechanism plays a central role in controlling both events. In the present work, O2*- generation by SCR was measured with the EPR spin-trapping technique using DEPMPO (5-diethoxylphosphoryl-5-methyl-1-pyrroline N-oxide) as the spin trap. In the presence of succinate, O2*- generation from SCR was detected as the spin adduct DEPMPO/*OOH. Inhibitors of the Q(o*-) site only marginally reduced (20-30%) this O2*- production, suggesting a secondary role of Q(o*-) in the mediation of O2*- generation. Addition of cyanide significantly decreased (approximately 70%) O2*- production, indicating the involvement of the heme component. UV-visible spectral analysis revealed that oxidation of ferrocytochrome b was accompanied by cytochrome c(1) reduction, and the reaction was mediated by the formation of an O2*- intermediate, indicating a direct role for cytochrome b in O2*- generation. In the presence of NO, DEPMPO/*OOH production was progressively diminished, implying that NO interacted with SCR or trapped the O2*-. The consumption of NO by SCR was investigated by electrochemical detection using an NO electrode. In the presence of succinate, SCR-mediated NO consumption was observed and inhibited by the addition of superoxide dismutase, suggesting the involvement of O2*-. Under the conditions of argon saturation, the NO consumption rate was not enhanced by succinate, suggesting a direct role for O2*- in the mediation of NO consumption. In the presence of succinate, oxidation of the ferrocytochrome b moiety of SCR was accelerated by the addition of NO, and was inhibited by argon saturation, indicating an indirect role for cytochrome b in the mediation of NO consumption.     

The reaction of nitric oxide with 6-hydroxydopamine: implications for Parkinson's disease.

Oxidation of catecholamines is suggested to contribute to oxidative stress in Parkinson's disease. Nitric oxide (*NO) is able to oxidize cyclic compounds like ubiquinol; moreover, recent lines of evidence proposed a direct role of *NO and its by-product peroxynitrite in the pathophysiology of Parkinson's disease. The aim of this study was to analyze the potential reaction between 6-hydroxydopamine, a classic inducer of Parkinson's disease, and *NO. The results showed that *NO reacts with the deprotonated form of 6-hydroxydopamine at pH 7 and 37 degrees C with a second-order rate constant of 1.5 x 10(3) M(-1) x s(-1) as calculated by the rate of *NO decay measured with an amperometric sensor. Accordingly, the rates of formation of 6-hydroxy-dopamine quinone were dependent on *NO concentration. The coincubation of *NO and 6-hydroxydopamine with either bovine serum albumin or alpha-synuclein led to tyrosine nitration of the protein, in a concentration dependent-manner and sensitive to superoxide dismutase. These findings suggest the formation of peroxynitrite during the redox reactions following the interaction of 6-hydroxydopamine with *NO. The implications of this reaction for in vivo models are discussed in terms of the generation of reactive nitrogen and oxygen species within a propagation process that may play a significant role in neurodegenerative diseases.     

Reactions of peroxynitrite in the mitochondrial matrix

Superoxide radical (O2-) and nitric oxide (NO) produced at the mitochondrial inner membrane react to form peroxynitrite (ONOO-) in the mitochondrial matrix. Intramitochondrial ONOO- effectively reacts with a few biomolecules according to reaction constants and intramitochondrial concentrations. The second-order reaction constants (in M(-1) s(-1)) of ONOO- with NADH (233 +/- 27), ubiquinol-0 (485 +/- 54) and GSH (183 +/- 12) were determined fluorometrically by a simple competition assay of product formation. The oxidation of the components of the mitochondrial matrix by ONOO- was also followed in the presence of CO2, to assess the reactivity of the nitrosoperoxocarboxylate adduct (ONOOCO2-) towards the same reductants. The ratio of product formation was about similar both in the presence of 2.5 mM CO2 and in air-equilibrated conditions. Liver submitochondrial particles supplemented with 0.25-2 microM ONOO- showed a O2- production that indicated ubisemiquinone formation and autooxidation. The nitration of mitochondrial proteins produced after addition of 200 microM ONOO- was observed by Western blot analysis. Protein nitration was prevented by the addition of 50-200 microM ubiquinol-0 or GSH. An intramitochondrial steady state concentration of about 2 nM ONOO- was calculated, taking into account the rate constants and concentrations of ONOO- coreactants.     

The regulation of mitochondrial oxygen uptake by redox reactions involving nitric oxide and ubiquinol

The reversible inhibitory effects of nitric oxide (.NO) on mitochondrial cytochrome oxidase and O(2) uptake are dependent on intramitochondrial.NO utilization. This study was aimed at establishing the mitochondrial pathways for.NO utilization that regulate O-(2) generation via reductive and oxidative reactions involving ubiquinol oxidation and peroxynitrite (ONOO(-)) formation. For this purpose, experimental models consisting of intact mitochondria, ubiquinone-depleted/reconstituted submitochondrial particles, and ONOO(-)-supplemented mitochondrial membranes were used. The results obtained from these experimental approaches strongly suggest the occurrence of independent pathways for.NO utilization in mitochondria, which effectively compete with the binding of.NO to cytochrome oxidase, thereby releasing this inhibition and restoring O(2) uptake. The pathways for.NO utilization are discussed in terms of the steady-state levels of.NO and O-(2) and estimated as a function of O(2) tension. These calculations indicate that mitochondrial.NO decays primarily by pathways involving ONOO(-) formation and ubiquinol oxidation and, secondarily, by reversible binding to cytochrome oxidase.     

THE ROLE OF THE QUINONE POOL IN THE CYCLIC ELECTRON-TRANSFER CHAIN OF RHODOPSEUDOMONAS SPHAEROIDES: A MODIFIED Q-CYCLE MECHANISM

(1) The role of the ubiquinone pool in the reactions of the cyclic electron-transfer chain has been investigated by observing the effects of reduction of the ubiquinone pool on the kinetics and extent of the cytochrome and electrochromic carotenoid absorbance changes following flash illumination. (2) In the presence of antimycin, flash-induced reduction of cytochrome b-561 is dependent on a coupled oxidation of ubiquinol. The ubiquinol oxidase site of the ubiquinol:cytochrome c(2) oxidoreductase catalyses a concerted reaction in which one electron is transferred to a high-potential chain containing cytochromes c(1) and c(2), the Rieske-type iron-sulfur center, and the reaction center primary donor, and a second electron is transferred to a low-potential chain containing cytochromes b-566 and b-561. (3) The rate of reduction of cytochrome b-561 in the presence of antimycin has been shown to reflect the rate of turnover of the ubiquinol oxidase site. This diagnostic feature has been used to measure the dependence of the kinetics of the site on the ubiquinol concentration. Over a limited range of concentration (0-3 mol ubiquinol/mol cytochrome b-561), the kinetics showed a second-order process, first order with respect to ubiquinol from the pool. At higher ubiquinol concentrations, other processes became rate determining, so that above approx. 25 mol ubiquinol/mol cytochrome b-561, no further increase in rate was seen. (4) The kinetics and extents of cytochrome b-561 reduction following a flash in the presence of antimycin, and of the antimycin-sensitive reduction of cytochrome c(1) and c(2), and the slow phase of the carotenoid change, have been measured as a function of redox potential over a wide range. The initial rate for all these processes increased on reduction of the suspension over the range between 180 and 100 mV (pH 7). The increase in rate occurred as the concentration of ubiquinol in the pool increased on reduction, and could be accounted for in terms of the increased rate of ubiquinol oxidation. It is not necessary to postulate the presence of a tightly bound quinone at this site with altered redox properties, as has been previously assumed. (5) The antimycin-sensitive reactions reflect the turnover of a second catalytic site of the complex, at which cytochrome b-561 is oxidized in an electrogenic reaction. We propose that ubiquinone is reduced at this site with a mechanism similar to that of the two-electron gate of the reaction center. We suggest that antimycin binds at this site, and displaces the quinone species so that all reactions at the site are inhibited. (6) In coupled chromatophores, the turnover of the ubiquinone reductase site can be measured by the antimycin-sensitive slow phase of the electrochromic carotenoid change. At redox potentials higher than 180 mV, where the pool is completely oxidized, the maximal extent of the slow phase is half that at 140 mV, where the pool contains approx. 1 mol ubiquinone/mol cytochrome b-561 before the flash. At both potentials, cytochrome b-561 became completely reduced following one flash in the presence of antimycin. The results are interpreted as showing that at potentials higher than 180 mV, ubiquinol stoichiometric with cytochrome b-561 reaches the complex from the reaction center. The increased extent of the carotenoid change, when one extra ubiquinol is available in the pool, is interpreted as showing that the ubiquinol oxidase site turns over twice, and the ubiquinone reductase sites turns over once, for a complete turnover of the ubiquinol:cytochrome c(2) oxidoreductase complex, and the net oxidation of one ubiquinol/complex. (7) The antimycin-sensitive reduction of cytochrome c(1) and c(2) is shown to reflect the second turnover of the ubiquinol oxidase site. (8) We suggest that, in the presence of antimycin, the ubiquinol oxidase site reaches a quasi equilibrium with ubiquinol from the pool and the high- and low-potential chains, and that the equilibrium constant of the reaction catalysed constrains the site to the single turnover under most conditions. (9) The results are discussed in the context of a detailed mechanism. The modified Q-cycle proposed is described by physicochemical parameters which account well for the results reported.     

Nature of the activation of succinate dehydrogenase by various effectors and in hypobaria and hypoxia

1. Hepatic mitochondrial succinate dehydrogenase (succinate:(acceptor)oxidoreductase, EC 1.3.99.1) was activated by preincubation of mitochondria with four diverse classes of compounds, the dicarboxylic acids, nitrophenols, quinols (and ubiquinols) and pyrophosphates. Of the various compounds tested malonate, oxaloacetate and pyrophosphate, well-known competitive inhibitors of the enzyme, and also hydroquinone and ubiquinols were effective even at low concentrations and showed maximal stimulation in 2 min.2. Activation of succinate dehydrogenase by ubiquinol-9 and ubiquinol-10 was comparable to succinate activation in fresh mitochondria, and was much higher in the aged samples.3. Preincubation of mitochondria with succinate, 2,4-dinitrophenol, pyrophosphate and ATP also stimulated the succinate-2,2′,5,5′-tetraphenyl-3,3′-(4,4′-biphenylene) ditetrazolium chloride (NT) reductase activity, whereas malonate, hydroquinone and ubiquinol-9 were ineffective. A differential activation of the flavoprotein by the oxidized and reduced forms of ubiquinone-9 was observed, the former stimulating the reduction of NT and the latter of phenazine methosulphate-2,6-dichlorophenolindophenol.4. Repeated washing of the activated mitochondrial samples with the sucrose homogenizing medium, partially reversed the activation by effectors other than succinate. Further washing of the activated preparations after a second preincubation with succinate reverted the enzyme activity to the basal level in the case of malonate, ATP and pyrophosphate but not that of hydroquinone and ubiquinol-9.5. Increase in the activity of hepatic mitochondrial succinate dehydrogenase, but not of succinate-NT reductase, known to occur in rats exposed to hypobaria was also observed in hypoxia indicating that it is an effect of lowered O₂ tension. The enzyme activity in these “partially activated” preparations was stable to washing with the sucrose homogenizing medium and could be fully activated to the same level as in the controls showing thereby the qualitative nature of the change. On washing these succinate-activated preparations further with the medium, the “hypobaric activation” was not reversed to the basal level, whereas the “hypoxic activation” was reversed. These results suggest that the effectors responsible for the activation of succinate dehydrogenase under hypobaric and hypoxic conditions are probably different; the former may be of the ubiquinol type and the latter of the malonate type.     

Antioxidant effects of ubiquinones in microsomes and mitochondria are mediated by tocopherol recycling

Ubiquinones and tocopherols (vitamin E) are intrinsic lipid components which have a stabilizing function in many membranes attributed to their antioxidant activity. The antioxidant effects of tocopherols are due to direct radical scavenging. Although ubiquinones also exert antioxidant properties the specific molecular mechanisms of their antioxidant activity may be due to: (i) direct reaction with lipid radicals or (ii) interaction with chromanoxyl radicals resulting in regeneration of vitamin E. Lipid peroxidation results have now shown that tocopherols are much stronger membrane antioxidants than naturally occurring ubiquinols (ubiquinones). Thus direct radical scavenging effects of ubiquinols (ubiquinones) might be negligible in the presence of comparable or higher concentrations of tocopherols. In support of this our ESR findings show that ubiquinones synergistically enhance enzymic NADH- and NADPH-dependent recycling of tocopherols by electron transport in mitochondria and microsomes. If ubiquinols were direct radical scavengers their consumption would be expected. Further proving our conclusion HPLC measurements demonstrated that ubiquinone-dependent sparing of tocopherols was not accompanied by ubiquinone consumption.     

The oxidation of ubiquinol by the isolated Rieske iron-sulfur protein in solution

The pre-steady-state redox reactions of the Rieske iron-sulfur protein isolated from beef heart mitochondria have been characterized. The rates of oxidation by c-type cytochromes is much faster than the rate of reduction by ubiquinols. This enables the monitoring of the oxidation of ubiquinols by the Rieske protein through the steady-state electron transfer to cytochrome c in solution. The pH and ionic strength dependence of this reaction indicate that the ubiquinol anion is the direct reductant of the oxidized cluster of the iron-sulfur protein. The second electron from ubiquinol is diverted to oxygen by the isolated Rieske protein, and forms oxygen radicals that contribute to the steady-state reduction of cytochrome c. Under anaerobic conditions, however, the reduction of cytochrome c catalyzed by the protein becomes mechanicistically identical to the chemical reduction by ubiquinols. The present kinetic work outlines that: (i) the electron transfer between the ubiquinol anion and the Rieske cluster has a comparable rate when the protein is isolated or inserted into the parent cytochrome c reductase enzyme; (ii) the Rieske protein may be a relevant generator of oxygen radicals during mitochondrial respiration.     

The mechanism of mitochondrial superoxide production by the cytochrome bc1 complex

Production of reactive oxygen species (ROS) by the mitochondrial respiratory chain is considered to be one of the major causes of degenerative processes associated with oxidative stress. Mitochondrial ROS has also been shown to be involved in cellular signaling. It is generally assumed that ubisemiquinone formed at the ubiquinol oxidation center of the cytochrome bc(1) complex is one of two sources of electrons for superoxide formation in mitochondria. Here we show that superoxide formation at the ubiquinol oxidation center of the membrane-bound or purified cytochrome bc(1) complex is stimulated by the presence of oxidized ubiquinone indicating that in a reverse reaction the electron is transferred onto oxygen from reduced cytochrome b(L) via ubiquinone rather than during the forward ubiquinone cycle reaction. In fact, from mechanistic studies it seems unlikely that during normal catalysis the ubisemiquinone intermediate reaches significant occupancies at the ubiquinol oxidation site. We conclude that cytochrome bc(1) complex-linked ROS production is primarily promoted by a partially oxidized rather than by a fully reduced ubiquinone pool. The resulting mechanism of ROS production offers a straightforward explanation of how the redox state of the ubiquinone pool could play a central role in mitochondrial redox signaling.     

Use of an azido-ubiquinone derivative to identify subunit I as the ubiquinol binding site of the cytochrome d terminal oxidase complex of Escherichia coli

The radiolabeled, photoreactive azido-ubiquinone derivative (azido-Q), 3-azido-2-methyl-5-methoxy-6-(3,7-dimethyl-[3H]octyl)- 1,4-benzoquinone, was used to investigate the active site of ubiquinol oxidase activity of the cytochrome d complex, a two-subunit terminal oxidase of Escherichia coli. The azido-Q, when reduced by dithioerythritol, was shown to support enzymatic oxygen consumption by the cytochrome d complex that was 8% of the rate observed with ubiquinol-1. This observation provided the rationale behind further studies of the possible photoinactivation and labeling of the active site by this azido-Q. Ten min of photolysis of the purified cytochrome d complex in the presence of the azido-Q resulted in a 60% loss of the ubiquinol-1 oxidase activity. Uptake of the radiolabeled azido-Q by the cytochrome d complex was correlated to the photoinactivation of the ubiquinol-1 oxidase activity. Both increased linearly during the first 4 min of photolysis and reached 90% of the maximum within 10 min. Photolysis times longer than 10 min resulted in no increase in the maximum of 2 mol of azido-Q incorporated per mol of enzyme. The rate of azido-Q uptake by subunit I, but not subunit II, correlated well with the rate of loss of ubiquinol oxidase activity. Use of ubiquinol-0, which is not oxidized by the enzyme, to competitively inhibit radiolabeling of nonspecific binding sites, resulted in a significant decrease (42%) of azido-Q labeling of subunit II while it did not affect the labeling of subunit I. After photolysis for 4 min, the ratio of radiolabeled azido-Q in subunits I to II of the complex was 4.3 to 1.0. These observations support the conclusion that the ubiquinol substrate binding site is located on subunit I of the cytochrome d complex.     

硝基水杨酰胺抑制泛醌-细胞色素c还原酶的作用对氢醌的敏感性

泛醌－细胞色素ｃ还原酶（ＱＣＲ）是线粒体呼吸链的三个能量偶联部位之一,它起着将电子从还原型泛醌传递给细胞色素ｃ（Ｃｙｔ．ｃ）的作用,根据Ｋｉｎｇ和Ｙｕ提出的泛醌结合蛋白理论［１］,泛醌－细胞色素ｃ还原酶中含有泛醌结合蛋白ＱＰｃ．研究表明,泛醌－细胞色...     

Free radical chemistry in biological systems

Mitochondria are an active source of the free radical superoxide (O2-) and nitric oxide (NO), whose production accounts for about 2% and 0.5% respectively, of mitochondrial O2 uptake under physiological conditions. Superoxide is produced by the auto-oxidation of the semiquinones of ubiquinol and the NADH dehydrogenase flavin and NO by the enzymatic action of the nitric oxide synthase of the inner mitochondrial membrane (mtNOS). Nitric oxide reversibly inhibits cytochrome oxidase activity in competition with O2. The balance between NO production and its utilization results in a NO intramitochondrial steady-state concentration of 20-50 nM, which regulates mitochondrial O2 uptake and energy supply. The regulation of cellular respiration and energy production by NO and its ability to switch the pathway of cell death from apoptosis to necrosis in physiological and pathological conditions could take place primarily through the inhibition of mitochondrial ATP production. Nitric oxide reacts with O2- in a termination reaction in the mitochondrial matrix, yielding peroxynitrite (ONOO-), which is a strong oxidizing and nitrating species. This reaction accounts for approximately 85% of the rate of mitochondrial NO utilization in aerobic conditions. Mitochondrial aging by oxyradical- and peroxynitrite-induced damage would occur through selective mtDNA damage and protein inactivation, leading to dysfunctional mitochondria unable to keep membrane potential and ATP synthesis.