The pathway of electrons through OH2:cytochrome c oxidoreductase studied by pre-steady -state kinetics

A robust genetic system for producing heterodimeric native and mutant cytochrome bc(1)

The ubihydroquinone:cytochrome c oxidoreductase, or cytochrome bc1, is central to the production of ATP by oxidative phosphorylation and photophosphorylation in many organisms. Its three-dimensional structure depicts it as a homodimer with each monomer composed of the Fe-S protein, cytochrome b, and cytochrome c1 subunits. Recent genetic approaches successfully produced heterodimeric variants of this enzyme, providing insights into its mechanism of function. However, these experimental setups are inherently prone to genetic rearrangements as they carry repeated copies of cytochrome bc1 structural genes. Duplications present on a single replicon (one-plasmid system) or a double replicon (two-plasmid system) could yield heterogeneous populations via homologous recombination or other genetic events at different frequencies, especially under selective growth conditions. In this work, we assessed the origins and frequencies of genetic variations encountered in these systems and describe an improved variant of the two-plasmid system. We found that use of a recombination-deficient background (recA) minimizes spontaneous formation of co-integrant plasmids and renders the homologous recombination within the cytochrome b gene copies inconsequential. On the basis of the data, we conclude that both the newly improved RecA-deficient and the previously used RecA-proficient two-plasmid systems reliably produce native and mutant heterodimeric cytochrome bc1 variants. The two-plasmid system developed here might contribute to the study of "mitochondrial heteroplasmy"-like heterogeneous states in model bacteria (e.g., Rhodobacter species) suitable for bioenergetics studies. In the following paper (DOI 10.1021/bi400561e), we describe the use of the two-plasmid system to produce and characterize, in membranes and in purified states, an active heterodimeric cytochrome bc1 variant with unusual intermonomer electron transfer properties.

Intermonomer electron transfer between the b hemes of heterodimeric cytochrome bc(1)

The ubihydroquinone:cytochrome c oxidoreductase, or cytochrome bc1, is a central component of respiratory and photosynthetic energy transduction pathways in many organisms. It contributes to the generation of membrane potential and proton gradient used for cellular energy (ATP) production. The three-dimensional structures of cytochrome bc1 show a homodimeric organization of its three catalytic subunits. The unusual architecture revived the issue of whether the monomers operate independently or function cooperatively during the catalytic cycle of the enzyme. In recent years, different genetic approaches allowed the successful production of heterodimeric cytochrome bc1 variants and evidenced the occurrence of intermonomer electron transfer between the monomers of this enzyme. Here we used a version of the "two-plasmid" genetic system, also described in the preceding paper (DOI: 10.1021/bi400560p), to study a new heterodimeric mutant variant of cytochrome bc1. The strain producing this heterodimeric variant sustained photosynthetic growth of Rhodobacter capsulatus and yielded an active heterodimer. Interestingly, kinetic data showed equilibration of electrons among the four b heme cofactors of the heterodimer, via "reverse" intermonomer electron transfer between the bL hemes. Both inactive homodimeric and active heterodimeric cytochrome bc1 variants were purified to homogeneity from the same cells, and purified samples were subjected to mass spectrometry analyses. The data unequivocally supported the idea that the cytochrome b subunits carried the expected mutations and their associated epitope tags. Implications of these findings on our interpretation of light-activated transient cytochrome b and c redox kinetics and the mechanism of function of a dimeric cytochrome bc1 are discussed with respect to the previously proposed heterodimeric Q cycle model.

Design and use of photoactive ruthenium complexes to study electron transfer within cytochrome bc1 and from cytochrome bc1 to cytochrome c

The cytochrome bc1 complex (ubiquinone:cytochrome c oxidoreductase) is the central integral membrane protein in the mitochondrial respiratory chain as well as the electron-transfer chains of many respiratory and photosynthetic prokaryotes. Based on X-ray crystallographic studies of cytochrome bc1, a mechanism has been proposed in which the extrinsic domain of the iron-sulfur protein first binds to cytochrome b where it accepts an electron from ubiquinol in the Qo site, and then rotates by 57° to a position close to cytochrome c1 where it transfers an electron to cytochrome c1. This review describes the development of a ruthenium photooxidation technique to measure key electron transfer steps in cytochrome bc1, including rapid electron transfer from the iron-sulfur protein to cytochrome c1. It was discovered that this reaction is rate-limited by the rotational dynamics of the iron-sulfur protein rather than true electron transfer. A conformational linkage between the occupant of the Qo ubiquinol binding site and the rotational dynamics of the iron-sulfur protein was discovered which could play a role in the bifurcated oxidation of ubiquinol. A ruthenium photoexcitation method is also described for the measurement of electron transfer from cytochrome c1 to cytochrome c. This article is part of a Special Issue entitled: Respiratory Complex III and related bc complexes.

The mechanism of superoxide production by the antimycin-inhibited mitochondrial Q-cycle

Superoxide production from antimycin-inhibited complex III in isolated mitochondria first increased to a maximum then decreased as substrate supply was modulated in three different ways. In each case, superoxide production had a similar bell-shaped relationship to the reduction state of cytochrome b(566), suggesting that superoxide production peaks at intermediate Q-reduction state because it comes from a semiquinone in the outer quinone-binding site in complex III (Q(o)). Imposition of a membrane potential changed the relationships between superoxide production and b(566) reduction and between b(562) and b(566) redox states, suggesting that b(562) reduction also affects semiquinone concentration and superoxide production. To assess whether this behavior was consistent with the Q-cycle mechanism of complex III, we generated a kinetic model of the antimycin-inhibited Q(o) site. Using published rate constants (determined without antimycin), with unknown rate constants allowed to vary, the model failed to fit the data. However, when we allowed the rate constant for quinol oxidation to decrease 1000-fold and the rate constant for semiquinone oxidation by b(566) to depend on the b(562) redox state, the model fit the energized and de-energized data well. In such fits, quinol oxidation was much slower than literature values and slowed further when b(566) was reduced, and reduction of b(562) stabilized the semiquinone when b(566) was oxidized. Thus, superoxide production at Q(o) depends on the reduction states of b(566) and b(562) and fits the Q-cycle only if particular rate constants are altered when b oxidation is prevented by antimycin. These mechanisms limit superoxide production and short circuiting of the Q-cycle when electron transfer slows.

Metallomic EPR spectroscopy

Based on explicit definitions of biomolecular EPR spectroscopy and of the metallome, this tutorial review positions EPR in the field of metallomics as a unique method to study native, integrated systems of metallobiomolecular coordination complexes subject to external stimuli. The specific techniques of whole-system bioEPR spectroscopy are described and their historic, recent, and anticipated applications are discussed.

Regulatory interactions in the dimeric cytochrome bc(1) complex: the advantages of being a twin

The dimeric cytochrome bc(1) complex catalyzes the oxidation-reduction of quinol and quinone at sites located in opposite sides of the membrane in which it resides. We review the kinetics of electron transfer and inhibitor binding that reveal functional interactions between the quinol oxidation site at center P and quinone reduction site at center N in opposite monomers in conjunction with electron equilibration between the cytochrome b subunits of the dimer. A model for the mechanism of the bc(1) complex has emerged from these studies in which binding of ligands that mimic semiquinone at center N regulates half-of-the-sites reactivity at center P and binding of ligands that mimic catalytically competent binding of ubiquinol at center P regulates half-of-the-sites reactivity at center N. An additional feature of this model is that inhibition of quinol oxidation at the quinone reduction site is avoided by allowing catalysis in only one monomer at a time, which maximizes the number of redox acceptor centers available in cytochrome b for electrons coming from quinol oxidation reactions at center P and minimizes the leakage of electrons that would result in the generation of damaging oxygen radicals.

On the mechanism of quinol oxidation at the QP site in the cytochrome bc1 complex: studied using mutants lacking cytochrome bL or bH

To elucidate the mechanism of bifurcated oxidation of quinol in the cytochrome bc1 complex, Rhodobacter sphaeroides mutants, H198N and H111N, lacking heme bL and heme bH, respectively, were constructed and characterized. Purified mutant complexes have the same subunit composition as that of the wild-type complex, but have only 9-11% of the electron transfer activity, which is sensitive to stigmatellin or myxothiazol. The Em values for hemes bL and bH in the H111N and H198N complexes are -95 and -35 mV, respectively. The pseudo first-order reduction rate constants for hemes bL and bH in H111N and H198N, by ubiquiniol, are 16.3 and 12.4 s(-1), respectively. These indicate that the Qp site in the H111N mutant complex is similar to that in the wild-type complex. Pre-steady state reduction rates of heme c1 by these two mutant complexes decrease to a similar extent of their activity, suggesting that the decrease in electron transfer activity is due to impairment of movement of the head domain of reduced iron-sulfur protein, caused by disruption of electron transfer from heme bL to heme bH. Both mutant complexes produce as much superoxide as does antimycin A-treated wild-type complex. Ascorbate eliminates all superoxide generating activity in the intact or antimycin inhibited wild-type or mutant complexes.

The dimeric structure of the cytochrome bc(1) complex prevents center P inhibition by reverse reactions at center N

Energy transduction in the cytochrome bc(1) complex is achieved by catalyzing opposite oxido-reduction reactions at two different quinone binding sites. We have determined the pre-steady state kinetics of cytochrome b and c(1) reduction at varying quinol/quinone ratios in the isolated yeast bc(1) complex to investigate the mechanisms that minimize inhibition of quinol oxidation at center P by reduction of the b(H) heme through center N. The faster rate of initial cytochrome b reduction as well as its lower sensitivity to quinone concentrations with respect to cytochrome c(1) reduction indicated that the b(H) hemes equilibrated with the quinone pool through center N before significant catalysis at center P occurred. The extent of this initial cytochrome b reduction corresponded to a level of b(H) heme reduction of 33%-55% depending on the quinol/quinone ratio. The extent of initial cytochrome c(1) reduction remained constant as long as the fast electron equilibration through center N reduced no more than 50% of the b(H) hemes. Using kinetic modeling, the resilience of center P catalysis to inhibition caused by partial pre-reduction of the b(H) hemes was explained using kinetics in terms of the dimeric structure of the bc(1) complex which allows electrons to equilibrate between monomers.

Proton translocation by the cytochromebc1complexes of phototrophic bacteria: introducing the activated Q-cycle

The cytochrome bc1 complexes are proton-translocating, dimeric membrane ubiquinol:cytochrome c oxidoreductases that serve as "hubs" in the vast majority of electron transfer chains. After each ubiquinol molecule is oxidized in the catalytic center P at the positively charged membrane side, the two liberated electrons head out, according to the Mitchell's Q-cycle mechanism, to different acceptors. One is taken by the [2Fe-2S] iron-sulfur Rieske protein to be passed further to cytochrome c1. The other electron goes across the membrane, via the low- and high-potential hemes of cytochrome b, to another ubiquinone-binding site N at the opposite membrane side. It has been assumed that two ubiquinol molecules have to be oxidized by center P to yield first a semiquinone in center N and then to reduce this semiquinone to ubiquinol. This review is focused on the operation of cytochrome bc1 complexes in phototrophic purple bacteria. Their membranes provide a unique system where the generation of membrane voltage by light-driven, energy-converting enzymes can be traced via spectral shifts of native carotenoids and correlated with the electron and proton transfer reactions. An "activated Q-cycle" is proposed as a novel mechanism that is consistent with the available experimental data on the electron/proton coupling. Under physiological conditions, the dimeric cytochrome bc1 complex is suggested to be continually primed by prompt oxidation of membrane ubiquinol via center N yielding a bound semiquinone in this center and a reduced, high-potential heme b in the other monomer of the enzyme. Then the oxidation of each ubiquinol molecule in center P is followed by ubiquinol formation in center N, proton translocation and generation of membrane voltage.

Ubiquinol oxidation in the cytochrome bc1 complex: Reaction mechanism and prevention of short-circuiting

This review is focused on the mechanism of ubiquinol oxidation by the cytochrome bc1 complex (bc1). This integral membrane complex serves as a "hub" in the vast majority of electron transfer chains. The bc1 oxidizes a ubiquinol molecule to ubiquinone by a unique "bifurcated" reaction where the two released electrons go to different acceptors: one is accepted by the mobile redox active domain of the [2Fe-2S] iron-sulfur Rieske protein (FeS protein) and the other goes to cytochrome b. The nature of intermediates in this reaction remains unclear. It is also debatable how the enzyme prevents short-circuiting that could happen if both electrons escape to the FeS protein. Here, I consider a reaction mechanism that (i) agrees with the available experimental data, (ii) entails three traits preventing the short-circuiting in bc1, and (iii) exploits the evident structural similarity of the ubiquinone binding sites in the bc1 and the bacterial photosynthetic reaction center (RC). Based on the latter congruence, it is suggested that the reaction route of ubiquinol oxidation by bc1 is a reversal of that leading to the ubiquinol formation in the RC. The rate-limiting step of ubiquinol oxidation is then the re-location of a ubiquinol molecule from its stand-by site within cytochrome b into a catalytic site, which is formed only transiently, after docking of the mobile redox domain of the FeS protein to cytochrome b. In the catalytic site, the quinone ring is stabilized by Glu-272 of cytochrome b and His-161 of the FeS protein. The short circuiting is prevented as long as: (i) the formed semiquinone anion remains bound to the reduced FeS domain and impedes its undocking, so that the second electron is forced to go to cytochrome b; (ii) even after ubiquinol is fully oxidized, the reduced FeS domain remains docked to cytochrome b until electron(s) pass through cytochrome b; (iii) if cytochrome b becomes (over)reduced, the binding and oxidation of further ubiquinol molecules is hampered; the reason is that the Glu-272 residue is turned towards the reduced hemes of cytochrome b and is protonated to stabilize the surplus negative charge; in this state, this residue cannot participate in the binding/stabilization of a ubiquinol molecule.

Rapid Electron Transfer between Monomers when the Cytochrome bc1 Complex Dimer Is Reduced through Center N

We have obtained evidence for electron transfer between cytochrome b subunits of the yeast bc(1) complex dimer by analyzing pre-steady state reduction of cytochrome b in the presence of center P inhibitors. The kinetics and extent of cytochrome b reduced by quinol in the presence of variable concentrations of antimycin decreased non-linearly and could only be fitted to a model in which electrons entering through one center N can equilibrate between the two cytochrome b subunits of the bc(1) complex dimer. The b(H) heme absorbance in a bc(1) complex inhibited at center P and preincubated with substoichiometric concentrations of antimycin showed a red shift upon the addition of substrate, which indicates that electrons from the uninhibited center N in one monomer are able to reach the b(H) heme at the antimycin-blocked site in the other. The extent of cytochrome b reduction by variable concentrations of menaquinol could only be fitted to a kinetic model that assumes electron equilibration between center N sites in the dimer. Kinetic simulations showed that non-rate-limiting electron equilibration between the two b(H) hemes in the dimer through the two b(L) hemes is possible upon reduction through one center N despite the thermodynamically unfavorable b(H) to b(L) electron transfer step. We propose that electron transfer between cytochrome b subunits minimizes the formation of semiquinone-ferrocytochrome b(H) complexes at center N and favors ubiquinol oxidation at center P by increasing the amount of oxidized cytochrome b.

Microsecond freeze-hyperquenching: development of a new ultrafast micro-mixing and sampling technology and application to enzyme catalysis

A novel freeze-quench instrument with a characteristic <<dead-time>> of 137 +/- 18 micros is reported. The prototype has several key features that distinguish it from conventional freeze-quench devices and provide a significant improvement in time resolution: (a) high operating pressures (up to 400 bar) result in a sample flow with high linear rates (up to 200 m s(-1)); (b) tangential micro-mixer with an operating volume of approximately 1 nl yields short mixing times (up to 20 micros); (c) fast transport between the mixer and the cryomedium results in short reaction times: the ageing solution exits the mixer as a free-flowing jet, and the chemical reaction occurs "in-flight" on the way to the cryomedium; (d) a small jet diameter (approximately 20 microm) and a high jet velocity (approximately 200 m s(-1)) provide high sample-cooling rates, resulting in a short cryofixation time (up to 30 micros). The dynamic range of the freeze-quench device is between 130 micros and 15 ms. The novel tangential micro-mixer efficiently mixes viscous aqueous solutions, showing more than 95% mixing at eta < or = 4 (equivalent to protein concentrations up to 250 mg ml(-1)), which makes it an excellent tool for the preparation of pre-steady state samples of concentrated protein solutions for spectroscopic structure analysis. The novel freeze-quench device is characterized using the reaction of binding of azide to metmyoglobin from horse heart. Reaction samples are analyzed using 77 K optical absorbance spectroscopy, and X-band EPR spectroscopy. A simple procedure of spectral analysis is reported that allows (a) to perform a quantitative analysis of the reaction kinetics and (b) to identify and characterize novel reaction intermediates. The reduction of dioxygen by the bo3-type quinol oxidase from Escherichia coli is assayed using the MHQ technique. In these pilot experiments, low-temperature optical absorbance measurements show the rapid oxidation of heme o3 in the first 137 micros of the reaction, accompanied by the formation of an oxo-ferryl species. X-band EPR spectroscopy shows that a short-living radical intermediate is formed during the oxidation of heme o3. The radical decays within approximately 1 ms concomitant with the oxidation of heme b, and can be attributed to the PM reaction intermediate converting to the oxoferryl intermediate F. The general field of application of the freeze-quench methodology is discussed.

Occurrence of a bound ubiquinone and its function in Escherichia coli membrane-bound quinoprotein glucose dehydrogenase

The membrane-bound pyrroloquinoline quinone (PQQ)-containing quinoprotein glucose dehydrogenase (mGDH) in Escherichia coli functions by catalyzing glucose oxidation in the periplasm and by transferring electrons directly to ubiquinone (UQ) in the respiratory chain. To clarify the intramolecular electron transfer of mGDH, quantitation and identification of UQ were performed, indicating that purified mGDH contains a tightly bound UQ(8) in its molecule. A significant increase in the EPR signal was observed following glucose addition in mGDH reconstituted with PQQ and Mg(2+), suggesting that bound UQ(8) accepts a single electron from PQQH(2) to generate semiquinone radicals. No such increase in the EPR signal was observed in UQ(8)-free mGDH under the same conditions. Moreover, a UQ(2) reductase assay with a UQ-related inhibitor (C49) revealed different inhibition kinetics between the wild-type mGDH and UQ(8)-free mGDH. From these findings, we propose that the native mGDH bears two ubiquinone-binding sites, one (Q(I)) for bound UQ(8) in its molecule and the other (Q(II)) for UQ(8) in the ubiquinone pool, and that the bound UQ(8) in the Q(I) site acts as a single electron mediator in the intramolecular electron transfer in mGDH.

The modified Q-cycle explains the apparent mismatch between the kinetics of reduction of cytochromes c1 and bH in the bc1 complex

Crystallographic structures of the bc1 complex from different sources have provided evidence that a movement of the Rieske iron-sulfur protein (ISP) extrinsic domain is essential for catalysis. This dynamic feature has opened up the question of what limits electron transfer, and several authors have suggested that movement of the ISP head, or gating of such movement, is rate-limiting. Measurements of the kinetics of cytochromes and of the electrochromic shift of carotenoids, following flash activation through the reaction center in chromatophore membranes from Rhodobacter sphaeroides, have allowed us to demonstrate that: (i) ubiquinol oxidation at the Qo-site of the bc1 complex has the same rate in the absence or presence of antimycin bound at the Qi-site, and is the reaction limiting turnover. (ii) Activation energies for transient processes to which movement of the ISP must contribute are much lower than that of the rate-limiting step. (iii) Comparison of experimental data with a simple mathematical model demonstrates that the kinetics of reduction of cytochromes c1 and bH are fully explained by the modified Q-cycle. (iv) All rates for processes associated with movement of the ISP are more rapid by at least an order of magnitude than the rate of ubiquinol oxidation. (v) Movement of the ISP head does not introduce a significant delay in reduction of the high potential chain by quinol, and it is not necessary to invoke such a delay to explain the kinetic disparity between the kinetics of reduction of cytochromes c1 and bH.

Interactions of quinone with the iron-sulfur protein of the bc(1) complex: is the mechanism spring-loaded?

Since available structures of native bc(1) complexes show a vacant Q(o)-site, occupancy by substrate and product must be investigated by kinetic and spectroscopic approaches. In this brief review, we discuss recent advances using these approaches that throw new light on the mechanism. The rate-limiting reaction is the first electron transfer after formation of the enzyme-substrate complex at the Q(o)-site. This is formed by binding of both ubiquinol (QH(2)) and the dissociated oxidized iron-sulfur protein (ISP(ox)). A binding constant of approximately 14 can be estimated from the displacement of E(m) or pK for quinone or ISP(ox), respectively. The binding likely involves a hydrogen bond, through which a proton-coupled electron transfer occurs. An enzyme-product complex is also formed at the Q(o)-site, in which ubiquinone (Q) hydrogen bonds with the reduced ISP (ISPH). The complex has been characterized in ESEEM experiments, which detect a histidine ligand, likely His-161 of ISP (in mitochondrial numbering), with a configuration similar to that in the complex of ISPH with stigmatellin. This special configuration is lost on binding of myxothiazol. Formation of the H-bond has been explored through the redox dependence of cytochrome c oxidation. We confirm previous reports of a decrease in E(m) of ISP on addition of myxothiazol, and show that this change can be detected kinetically. We suggest that the myxothiazol-induced change reflects loss of the interaction of ISPH with Q, and that the change in E(m) reflects a binding constant of approximately 4. We discuss previous data in the light of this new hypothesis, and suggest that the native structure might involve a less than optimal configuration that lowers the binding energy of complexes formed at the Q(o)-site so as to favor dissociation. We also discuss recent results from studies of the bypass reactions at the site, which lead to superoxide (SO) production under aerobic conditions, and provide additional information about intermediate states.

The interaction of the Rieske iron-sulfur protein with occupants of the Qo-site of the bc1 complex, probed by electron spin echo envelope modulation

The bifurcated reaction at the Q(o)-site of the bc(1) complex provides the mechanistic basis of the proton pumping activity through which the complex conserves redox energy in the proton gradient. Structural information about the binding of quinone at the site is lacking, because the site is vacant in crystals of the native complexes. We now report the first structural characterization of the interaction of the native quinone occupant with the Rieske iron-sulfur protein in the bc(1) complex of Rhodobacter sphaeroides, using high resolution EPR. We have compared the binding configuration in the presence of quinone with the known structures for the complex with stigmatellin and myxothiazol. We have shown by using EPR and orientation-selective electron spin echo envelope modulation (ESEEM) measurements of the iron-sulfur protein that when quinone is present in the site, the isotropic hyperfine constant of one of the N(delta) atoms of a liganding histidine of the [2Fe-2S] cluster is similar to that observed when stigmatellin is present and different from the configuration in the presence of myxothiazol. The spectra also show complementary differences in nitrogen quadrupole splittings in some orientations. We suggest that the EPR characteristics, the ESEEM spectra, and the hyperfine couplings reflect a similar interaction between the iron-sulfur protein and the quinone or stigmatellin and that the N(delta) involved is that of a histidine (equivalent to His-161 in the chicken mitochondrial complex) that forms both a ligand to the cluster and a hydrogen bond with a carbonyl oxygen atom of the Q(o)-site occupant.

The [2Fe-2S] cluster E(m) as an indicator of the iron-sulfur subunit position in the ubihydroquinone oxidation site of the cytochrome bc1 complex

Recent crystallographic and kinetic data have revealed the crucial role of the large scale domain movement of the iron-sulfur subunit [2Fe-2S] cluster domain during the ubihydroquinone oxidation reaction catalyzed by the cytochrome bc(1) complex. Previously, the electron paramagnetic resonance signature of the [2Fe-2S] cluster and its redox midpoint potential (E(m)) value have been used extensively to characterize the interactions of the [2Fe-2S] cluster with the occupants of the ubihydroquinone oxidation (Q(o)) catalytic site. In this work we analyze these interactions in various iron-sulfur subunit mutants that carry mutations in its flexible hinge region. We show that the E(m) increases of the iron-sulfur subunit [2Fe-2S] cluster induced either by these mutations or by the addition of stigmatellin do not act synergistically. Moreover, the E(m) increases disappear in the presence of class I inhibitors like myxothiazol. Because various inhibitors are known to affect the location of the iron-sulfur subunit cluster domain, the measured E(m) value of the [2Fe-2S] cluster therefore reflects its equilibrium position in the Q(o) site. We also demonstrate the existence in this site of a location where the E(m) of the cluster is increased by about 150 mV and discuss its possible implications in term of Q(o) site catalysis and energetics.

Structures and proton-pumping strategies of mitochondrial respiratory enzymes

Enzymes of the mitochondrial respiratory chain serve as proton pumps, using the energy made available from electron transfer reactions to transport protons across the inner mitochondrial membrane and create an electrochemical gradient used for the production of ATP. The ATP synthase enzyme is reversible and can also serve as a proton pump by coupling ATP hydrolysis to proton translocation. Each of the respiratory enzymes uses a different strategy for performing proton pumping. In this work, the strategies are described and the structural bases for the action of these proteins are discussed in light of recent crystal structures of several respiratory enzymes. The mechanisms and efficiency of proton translocation are also analyzed in terms of the thermodynamics of the substrate transformations catalyzed by these enzymes.

Structure and function of cytochrome bc complexes

The cytochrome bc complexes represent a phylogenetically diverse group of complexes of electron-transferring membrane proteins, most familiarly represented by the mitochondrial and bacterial bc1 complexes and the chloroplast and cyanobacterial b6f complex. All these complexes couple electron transfer to proton translocation across a closed lipid bilayer membrane, conserving the free energy released by the oxidation-reduction process in the form of an electrochemical proton gradient across the membrane. Recent exciting developments include the application of site-directed mutagenesis to define the role of conserved residues, and the emergence over the past five years of X-ray structures for several mitochondrial complexes, and for two important domains of the b6f complex.

Reaction of Escherichia coli cytochrome bo(3) and mitochondrial cytochrome bc(1) with a photoreleasable decylubiquinol

In order to probe the reaction chemistry of respiratory quinol-oxidizing enzymes on a rapid time scale, a photoreleasable quinol substrate was synthesized by coupling decylubiquinol with the water-soluble protecting group 3',5'-bis(carboxymethoxy)benzoin (BCMB) through a carbonate linkage. The resulting compound, DQ-BCMB, was highly soluble in aqueous detergent solution, and showed no reactivity with quinol-oxidizing enzymes prior to photolysis. Upon photolysis in acetonitrile, 5, 7-bis(carboxymethoxy)-2-phenylbenzofuran, carbon dioxide, and decylubiquinol were formed. In aqueous media, free 3', 5'-bis(carboxymethoxy)benzoin was also produced. Photolysis of DQ-BCMB with a 308 nm excimer laser led to the release of the BCMB group in less than 10(-6) s. Decylubiquinol was released in the form of a carbonate monoester, which decarboxylated with an observed first-order rate constant of 195-990 s(-1), depending on the reaction medium. Yields of decylubiquinol as high as 35 microM per laser pulse were attained readily. In the presence of Escherichia coli cytochrome bo(3), photolysis of DQ-BCMB led to the oxidation of quinol by the enzyme with a rate that was limited by the rate of the decylubiquinol release. Mitochondrial cytochrome bc(1) reacted with photoreleased decylubiquinol with distinct kinetic phases corresponding to rapid b heme reduction and somewhat slower c heme reduction. Oxidation of photoreleased ubiquinol by this enzyme showed saturation kinetics with a K(m) of 3.6 microM and a k(cat) of 210 s(-1). The saturation behavior was a result of decylubiquinol being released as a carbonate monoester during the photolysis of DQ-BCMB and interacting with cytochrome bc(1) before decarboxylation of this intermediate yielded free decylubiquinol. The reaction of cytochrome bc(1) and photoreleased decylubiquinol in the presence of antimycin A led to monophasic b heme reduction, but also yielded slower quinol oxidation kinetics. The discrimination of kinetic phases in the reaction of cytochrome bc(1) with ubiquinol substrates has provided a means of exploring the bifurcation of electron transfer that is central to the operation of the Q-cycle in this enzyme.

Ubiquinone at center N is responsible for triphasic reduction of cytochrome b in the cytochrome bc(1) complex

We have examined the pre-steady state reduction kinetics of the Saccharomyces cerevisiae cytochrome bc(1) complex by menaquinol in the presence and absence of endogenous ubiquinone to elucidate the mechanism of triphasic cytochrome b reduction. With cytochrome bc(1) complex from wild type yeast, cytochrome b reduction was triphasic, consisting of a rapid partial reduction phase, an apparent partial reoxidation phase, and a slow rereduction phase. Absorbance spectra taken by rapid scanning spectroscopy at 1-ms intervals before, during, and after the apparent reoxidation phase showed that this was caused by a bona fide reoxidation of cytochrome b and not by any negative spectral contribution from cytochrome c(1). With cytochrome bc(1) complex from a yeast mutant that cannot synthesize ubiquinone, cytochrome b reduction by either menaquinol or ubiquinol was rapid and monophasic. Addition of ubiquinone restored triphasic cytochrome b reduction, and the duration of the reoxidation phase increased as the ubiquinone concentration increased. When reduction of the cytochrome bc(1) complex through center P was blocked, cytochrome b reduction through center N was biphasic and was slowed by the addition of exogenous ubiquinone. These results show that ubiquinone residing at center N in the oxidized cytochrome bc(1) complex is responsible for the triphasic reduction of cytochrome b.

Pre-steady-state kinetics of the reactions of [NiFe]-hydrogenase from Chromatium vinosum with H2 and CO

Results are presented of the first rapid-mixing/rapid-freezing studies with a [NiFe]-hydrogenase. The enzyme from Chromatium vinosum was used. In particular the reactions of active enzyme with H2 and CO were monitored. The conversion from fully reduced, active hydrogenase (Nia-SR state) to the Nia-C* state was completed in less than 8 ms, a rate consistent with the H2-evolution activity of the enzyme. The reaction of CO with fully reduced enzyme was followed from 8 to 200 ms. The Nia-SR state did not react with CO. It was discovered, contrary to expectations, that the Nia-C* state did not react with CO when reactions were performed in the dark. When H2 was replaced by CO, a Nia-C* EPR signal appeared within 11 ms; this was also the case when H2 was replaced by Ar. With CO, however, the Nia-C* state decayed within 40 ms, due to the generation of the Nia-S.CO state (the EPR-silent state of the enzyme with bound CO). The Nia-C* state, induced after 11 ms by replacing H2 by CO in the dark, could be converted, in the frozen enzyme, into the EPR-detectable state with CO bound to nickel (Nia*.CO) by illumination at 30 K (evoking the Nia-L* state), followed by dark adaptation at 200 K. This can be explained by assuming that the Nia-C* state represents a formally trivalent state of nickel, which is unable to bind CO, whereas nickel in the Nia-L* and the Nia*.CO states is formally monovalent.

Structure and function of the cytochrome bc1 complex of mitochondria and photosynthetic bacteria

Progress has recently been made in the understanding of the function of the cytochrome bc1 complex and related proteins in the context of recent structural information. The structures support many features that were predicted from sequence analysis and biophysical studies, but contain some surprises. Most dramatically, it is apparent that the iron-sulfur protein can take up different positions in different crystals, suggesting a novel mechanism for electron transfer through domain movement. Evidence from studies of mutant strains, in which the function of the sites or the binding of inhibitors is perturbed, has provided clues about the mechanism.

Inhibitor binding changes domain mobility in the iron-sulfur protein of the mitochondrial bc1 complex from bovine heart

We have analyzed crystal structures of cytochrome bc1 complexes with electron transfer inhibitors bound to the ubiquinone binding pockets Qi and/or Qo in the cytochrome b subunit. The presence or absence of the Qi inhibitor antimycin A did not affect the binding of the Qo inhibitors. Different subtypes of Qo inhibitors had dramatically different effects on the mobility of the extramembrane domain of the iron-sulfur protein (ISP): Binding of 5-undecyl-6-hydroxy-4, 7-dioxobenzothiazol and stigmatellin (subtype Qo-II and Qo-III, respectively) led to a fixation of the ISP domain on the surface of cytochrome b, whereas binding of myxothiazol and methoxyacrylate-stilbene (subtype Qo-I) favored release of this domain. The native structure has an empty Qo pocket and is intermediate between these extremes. On the basis of these observations we propose a model of quinone oxidation in the bc1 complex, which incorporates fixed and loose states of the ISP as features important for electron transfer and, possibly, also proton transport.

The amino-terminal portion of the Rieske iron-sulfur protein contributes to the ubihydroquinone oxidation site catalysis of the Rhodobacter capsulatus bc1 complex

The Rieske iron-sulfur (Fe-S) protein subunit of bc1 complexes contains in its carboxyl-terminal part two highly conserved hexapeptide motifs (box I and box II) that include the four amino acid ligands of its [2Fe-2S] cluster. In the preceding paper [Liebl, U., Sled, V., Brasseur, G., Ohnishi, T., & Daldal, F. (1997) Biochemistry 36, 11675-11684], the effects of mutations at two of the nonliganding residues [threonine (T) 134 and leucine (L) 136 in the Rhodobactercapsulatus Rieske Fe-S protein] of box I have been described. In this work, interactions between the occupants of the Qo site of the bc1 complex (UQ/UQH2 and the inhibitors stigmatellin and myxothiazol) and the [2Fe-2S] cluster of the Rieske Fe-S protein were probed by isolating photosynthesis-proficient (Ps+) revertants of the Ps- mutants L136R, -H, -D and -G. These revertants contained either a single substitution at the original position 136 or an additional mutation located in the amino-terminal part of the Fe-S protein at either position 44 or 46. The same-site revertants L136A and -Y grew well under photosynthetic conditions and contained highly active bc1 complexes but exhibited modified EPR spectra both in the presence and in the absence of stigmatellin. Unexpectedly, they were highly resistant to stigmatellin (StiR) and hypersensitive to myxothiazol (MyxHS) in vivo, demonstrating for the first time that mutations located in the Fe-S subunit confer resistance to stigmatellin. The [2Fe-2S] cluster of the same-site revertants responded weakly to the Qpool redox state and had redox midpoint potential (Em7) values (around 265 mV) lower than those of their wild type counterpart (about 310 mV). On the other hand, the second-site revertants L136H/V44L, L136G/V44F, and L136G/A46T, -V, or -P supported photosynthetic growth poorly, were StiR and MyxHS, and contained barely active bc1 complexes. Like the same-site revertants, they exhibited modified EPR spectra both in the presence and in the absence of stigmatellin and had perturbed Qo site occupancy. In addition, they contained substoichiometric amounts of the Fe-S protein with respect to the other subunits of the bc1 complex. The Em7 values of the [2Fe-2S] cluster of these double mutants were lower (around 245 mV) than that of the wild type strain but appreciably higher than those of their Ps- parents (about 200 mV for L136G). In order to define the molecular nature of the suppression mediated by the second-site mutations, the single mutants V44L and -F and A46T and -V were constructed in the absence of the original mutations at position 136. These mutants behaved like a wild type strain with respect to their Ps+ growth ability, inhibitor sensitivity, EPR spectra of their [2Fe-2S] cluster, and response to stigmatellin or to the Qpool redox state. But surprisingly, the Em7 values of their [2Fe-2S] cluster were much higher (about 385 mV) than that of a wild type strain. These findings demonstrated for the first time that the amino-terminal part of the Rieske Fe-S protein encompassing residues 44 and 46 is important not only for the structure and function of the Qo site of the bc1 complex but also for the properties of its [2Fe-2S] cluster.

The involvement of threonine 160 of cytochrome b of Rhodobacter sphaeroides cytochrome bc1 complex in quinone binding and interaction with subunit IV

The cytochrome b subunit (subunit I) of the ubiquinolcytochrome c reductase (bc1 complex) is thought to participate in the formation of two quinone/quinol reaction centers, an oxidizing center (Qo) and a reducing center, in accordance with the quinone cycle mechanism. Threonine 160 is a highly conserved residue in a segment of subunit I that was shown to bind quinone and is placed near the putative Qo site in current models of the bc1 complex. Rhodobacter sphaeroides cells expressing bc1 complexes with Ser or Tyr substituted for Thr160 grow photosynthetically at a reduced rate, and cells expressing the mutated complexes produce an "elevated" level of the bc1 complex. The Ser substitution also affects the interaction of subunit IV with subunit I. Replacement of Thr160 by Ser results in about a 70% loss of the activity in the purified complex, whereas substitution by Tyr lowers the activity by more than 80%. Both replacements lower the apparent Km for ubiquinol. Electron paramagnetic resonance (EPR) spectroscopy shows that in the Ser substituted complex, the environments of the Rieske iron-sulfur cluster in subunit III and the high potential cytochrome b (b562) in subunit I have been modified. The spectra of the Ser160 and Tyr160 iron-sulfur clusters have become redox-insensitive, with a line shape resembling that of the native complex in the fully reduced state. The EPR signal of b562 in the Ser160 complex is shifted from g = 3.50 to g = 3.52, but otherwise the line shape is very similar to the spectrum of the native complex. Most of these results are consistent with current ideas regarding the structure and function of Qo in the bc1 complex, except for the alteration of the b562 EPR feature, because this heme is not thought to be located in proximity to Qo. Immunoblotting analysis showed that the Ser or Tyr substituted complex contained significantly less than a stoichiometric amount of subunit IV. The enzymatic activity of mutated bc1 complex was found to be activable by the addition of purified subunit IV. These results indicate that Thr160 plays an important role in the structure and/or function of the bc1 complex.

Studies on a stabilisation of ubisemiquinone by Escherichia coli quinol oxidase, cytochrome bo

The Escherichia coli quinol oxidase, cytochrome bo, is closely related to the cytochrome c oxidase, cytochrome aa3 in all aspects of its structure and function except for the replacement of the cytochrome-c-binding site and its attendant CuA prosthetic group with a quinone-binding site. The putative oxidation of quinol by ferrihaem (cytochrome b) at this site in sequential one-electron steps requires the stabilisation of semiquinone. We have observed, by electron paramagnetic resonance, the properties of a ubisemiquinone radical in appropriately poised samples of purified enzyme reconstituted with excess ubiquinone. The ubisemiquinone is highly stabilised with respect to free ubisemiquinone; significant free radical can be observed even at pH 7.0, while at pH 9.0 the stability constant is 5-10. The pH dependence of the stability constant indicates that the anionic form of the semiquinone predominates above pH 7.5. The two-electron couple has an Em7 of approximately 70 mV. Below pH 9, the pH dependence of the two-electron couple is -60mV/pH, indicative of a 2H+/2e- reaction. The line width of the EPR spectrum is approximately 0.9 mT, which is consistent with a ubisemiquinone anion. In comparison with other respiratory chain Q.- species that have been described, the relaxation rate in the presence of reduced haems appears comparable to magnetically isolated Q.- radicals. Partially resolved splittings of approximately 0.4 mT can be observed in the spectrum of Q.-bo (QH.bo).

Functional activities of monomeric and dimeric forms of the chloroplast cytochrome b6f complex

A monomeric form of the isolated cytochrome b6f complex from spinach chloroplast membranes has been isolated after treatment of the dimeric complex with varying concentrations of Triton X-100. The two forms of the complex are similar as regards electron transfer components and subunit composition. In contrast to a previous report (Huang et al. (1994) Biochemistry 33: 4401-4409) both the monomer and dimer are enzymatically active. However, after incorporation of the respective complexes into phospholipid vesicles, only the dimeric form of the cytochrome complex shows uncoupler sensitive electron transport, an indication of coupling of electron transport to proton translocation. The absence of this activity with the monomeric form of the cytochrome complex may be related to an inhibition by added lipids.

Energy-induced structural changes in NADH:Q oxidoreductase of the mitochondrial respiratory chain

The reaction of coupled submitochondrial particles (SMP) with NADH was studied in the absence and presence of the uncoupler gramicidin, both in pre-steady-state and steady-state experiments. It was shown that the formation of ubisemiquinones associated with NADH:Q oxidoreductase is insensitive to uncouplers. It was found, however, that in the absence of gramicidin the ubisemiquinone showed a noticeably faster relaxation than in the presence of this uncoupler. During steady-state oxidation of NADH by coupled submitochondrial particles, the EPR signal of iron-sulphur cluster 2 of complex I, the cluster that is generally believed to be the electron donor for ubiquinone, showed some remarkable changes. Its gz line seemed to disappear from the spectrum, although the gxy line remained clearly present. Detailed EPR analysis indicated that (a component of) the gz line shifted to higher field. The temperature dependence of the EPR signal of cluster 2 was affected as well. In the presence of uncoupler the EPR properties of cluster 2 were indistinguishable from those in particles that showed no intrinsic coupling. These experiments strongly indicate that the coordination of cluster 2 is different in energized and non-energized SMP. The pre-steady-state reaction between these submitochondrial particles and NADH showed that the uncoupler-sensitive changes in both the ubisemiquinone and cluster 2 became effective between 9 ms and 30 ms. Similar changes were observed during succinate-driven reverse electron transfer. This report shows, for the first time, energy-induced structural changes in NADH:Q oxidoreductase.

Ubisemiquinones as obligatory intermediates in the electron transfer from NADH to ubiquinone

Until now ubisemiquinones associated with NADH:ubiquinone oxidoreductase (complex I) have been reported to occur in isolated enzyme and in tightly coupled submitochondrial particles. In this report it is shown that ubisemiquinones are always detectable during steady-state electron transfer from NADH to ubiquinone, independent of the type of inner-membrane preparation used. The EPR signal of the rotenone-sensitive ubisemiquinones could be detected not only in coupled MgATP submitochondrial particles, but also in routine preparations of uncoupled submitochondrial particles and in mitochondria. The ubisemiquinone formation in coupled preparations was completely insensitive to uncouplers. The maximal radical concentration during steady-state electron transfer from NADH to quinone was equal to that of iron-sulphur cluster 2. Experiments with antimycin, myxothiazol and 2-thenoyltrifluoroacetone demonstrated that about half of this radical was associated with complex I, giving a ubisemiquinone concentration of about 0.5 mol semiquinone/mol cluster 2. Uncoupled submitochondrial particles, prepared by extensive sonification, never showed radical signals within 100 ms after mixing with NADH. This was due to the reversible inactivation of the enzyme, caused by elevated temperatures during sonification. In preparations with deliberately heat-inactivated complex I, no radical signals were detected within 200 ms after mixing with NADH; at 1 s, however, radical formation was maximal. Yet, depending on the procedure of reactivation of the complex, in preparations previously treated to inactivate them ubisemiquinone concentrations were always less than in untreated particles. When complex I was in the active state the ubisemiquinone signal was maximal within 40 ms. The results described in this report lead to the conclusion that ubisemiquinones form obligatory intermediates in the reaction of NADH dehydrogenase with ubiquinone.

The protonmotive Q cycle in mitochondria and bacteria

The cytochrome bc1 complex is an oligomeric electron transfer enzyme located in the inner membrane of mitochondria and the plasma membrane of bacteria. The cytochrome bc1 complex participates in respiration in eukaryotic cells and also participates in respiration, cyclic photosynthetic electron transfer, denitrification, and nitrogen fixation in a phylogenetically diverse collection of bacteria. In all of these organisms, the cytochrome bc1 complex transfers electrons from ubiquinol to cytochrome c and links this electron transfer to translocation of protons across the membrane in which it resides, thus converting the available free energy of the oxidation-reduction reaction into an electrochemical proton gradient. The mechanism by which the cytochrome bc1 complex achieves this energy transduction is the protonmotive Q cycle. The Q cycle mechanism has been documented by extensive experimentation, and recent investigations have focused on structural features of the three redox subunits of the bc1 complex essential to the protonmotive and electrogenic activities of this membranous enzyme.

Abundance, subunit composition, redox properties, and catalytic activity of the cytochrome bc1 complex from alkaliphilic and halophilic, photosynthetic members of the family Ectothiorhodospiraceae

Ubiquinol-cytochrome c oxidoreductase (cytochrome bc1) complexes were demonstrated to be present in the membranes of the alkaliphilic and halophilic purple sulfur bacteria Ectothiorhodospira halophila, Ectothiorhodospira mobilis, and Ectothiorhodospira shaposhnikovii by protoheme extraction, immunoblotting, and electron paramagnetic resonance spectroscopy. The gy values of the Rieske [2Fe-2S] clusters observed in membranes of E. mobilis and E. halophila were 1.895 and 1.910, respectively. In E. mobilis membranes, the cytochrome bc1 complex was present in a stoichiometry of approximately 0.2 per reaction center. This complex was isolated and characterized. It contained four prosthetic groups: low-potential cytochrome b (cytochrome bL; Em = -142 mV), high-potential cytochrome b (cytochrome bH; Em = 116 mV), cytochrome c1 (Em = 341 mV), and a Rieske iron-sulfur cluster. The absorbance spectrum of cytochrome bL displayed an asymmetric alpha-band with a maximum at 564 nm and a shoulder at 559 nm. The alpha bands of cytochrome bH and cytochrome c1 peaked at 559.5 and 553 nm, respectively. These prosthetic groups were associated with three different polypeptides: cytochrome b, cytochrome c1, and the Rieske iron-sulfur protein, with apparent molecular masses of 43, 30, and 21 kDa, respectively. No evidence for the presence of a fourth subunit was obtained. Maximal ubiquinol-cytochrome c oxidoreductase activity of the purified complex was observed at pH 8; the turnover rate was 57 mol of cytochrome c reduced.(mol of cytochrome c1)-1.s-1. The complex showed a strikingly low sensitivity towards typical inhibitors of cytochrome bc1 complexes.

Non-linear inhibition curves for tight-binding inhibitors of dimeric ubiquinol-cytochrome c oxidoreductases. Evidence for rapid inhibitor mobility

Steady-state electron flow through and electron delivery into isolated dimeric bc1 complex (ubiquinol--cytochrome c oxidoreductase) from Neurospora crassa and beef heart mitochondria were studied in the presence of increasing concentrations of antimycin A, funiculosin and/or myxothiazol. Parabolic or linear inhibition curves were obtained, depending upon the different quinols and inhibitors that were used. Linear curves occur when the inhibitor directly affects the rate-determining step. The most reasonable explanation for the parabolic curves is given by a fast intradimeric exchange of the hydrophobic inhibitors antimycin A, funiculosin (rate less than 500 s-1) and of myxothiazol (rate greater than 1 s-1). Using mitochondria from beef heart, the shape of the inhibition curve with antimycin A is parabolic if the quinol--O2 oxidoreductase turns over at about 300 s-1, but hyperbolic if the rate is 5 times less. The hyperbolic titration curve may be the result of both intradimeric and an additional interdimeric redistribution (rate approximately 100 s-1) of inhibitors between enzymes incorporated in a continuous phospholipid membrane. This explanation is supported by experiments with chromatophores obtained from Rhodobacter capsulatus. As recently described [Fernandez-Velasco, J. & Crofts, A. R. (1992) Biophys. J. 2, A153], cytochrome b becomes fully reoxidized within 1 s after a flash at substoichiometric concentrations of antimycin A. This kinetic of the slow reoxidation can be expressed in terms of the intradimeric and interdimeric redistribution with rate constants of about 10 s-1 and 2 x 10(6) M-1 s-1, respectively. It seems that rapid inhibitor redistribution may be a widespread phenomenon for hydrophobic inhibitors of enzymes incorporated in lipid membranes.

The chloroplast cytochrome b 6 f complex can exist in monomeric and dimeric states

The cytochrome b 6 f complex isolated from spinach chloroplast membranes can be resolved into two forms, a monomeric and a dimeric form, by centrifugation on sucrose gradients. The conversion of the dimeric form of the complex into the monomeric form could be prevented by cross-linking with the homobifunctional reagent, dithiobis(succinimidylpropionate) but not by cross-linking with disuccinimidyltartrate or glutaraldehyde. SDS-PAGE analyses of the monomeric and dimeric forms of the cytochrome complex showed the presence of specific cross-linked products in each respective form of the complex. For example, the monomeric form contained a cross-linked product of cytochrome f, cytochrome b 6 f and subunit IV while the dimeric form contained a cross-linked dimer of cytochrome b 6 f. The presence of the former in the isolated cytochrome b 6 f complex prepared by the method of Hurt and Hauska (Eur J Biochem 117: 591-599, 1981) indicates the presence of the monomer in his preparation.

Interaction of Zn2+ with the bovine-heart mitochondrial bc1 complex

A study is presented of the effect of Zn2+ on the enzymatic properties of the bovine-heart cytochrome-bc1 complex. Micromolar concentrations of Zn2+ reversibly inhibit the cytochrome-c reductase activity of either the cholate-solubilized or liposome-reconstituted complex. Kinetic analysis of the redox reactions of the cytochromes indicate that Zn2+ affects the activity of the complex at the quinol oxidation site. The following have been determined: (a) Zn2+ inhibits the pre-steady-state reduction of cytochrome c1 by duroquinol either in the absence or in the presence of antimycin, (b) it does not inhibit the reduction of b cytochromes in the absence of antimycin or in the presence of myxothiazol, (c) it inhibits cytochrome-b reduction in the presence of antimycin. Furthermore Zn2+ inhibits the antimycin-promoted oxidant-induced extrareduction of b cytochromes. Addition of Zn2+ to reduced bc1 complex causes a red shift in the absorption spectrum of cytochrome b566 and a substantial decrease in the signal intensity of the EPR spectrum of the Fe-S protein. This is interpreted as an interaction of Zn2+ with the 2Fe-2S-cluster region of the Fe-S protein, thus giving rise to inhibition of the reductase activity and of the antimycin-insensitive reduction route of b cytochromes. A Scatchard-plot of 65Zn2+ binding to the native isolated complex gave a straight line from which a value of three binding sites and a single dissociation constant of 3 x 10(-6) M can be calculated, which is practically equal to the concentration causing 50% inhibition of electron flow.

Reduction of the Q-pool by duroquinol via the two quinone-binding sites of the QH2: cytochrome c oxidoreductase. A model for the equilibrium between cytochrome b-562 and the Q-pool

The steady-state reduction of exogenous ubiquinone-2 by duroquinol as catalysed by the ubiquinol: cytochrome c oxidoreductase was studied in bovine heart mitoplasts. The reduction of ubiquinone-2 by duroquinol proceeds both in the absence of inhibitors of the enzyme, in the presence of outside inhibitors, e.g., myxothiazol, and in the presence of inside inhibitors, e.g., antimycin, but not in the presence of both inside and outside inhibitors. It is concluded that both the Qin-binding domain and the Qout-binding domain may independently catalyse this reaction. The rate of the reduction of ubiquinone-2 by duroquinol via the Qin-binding domain is dependent on the type of outside inhibitor used. The maximal rate obtained for the reduction of ubiquinone-2 by DQH2 via the Qout-binding domain, measured in the presence of antimycin, is similar to that catalysed by the Qin-binding domain of the non-inhibited enzyme and depends on the redox state of the high-potential electron carriers of the respiratory chain. The reduction of ubiquinone-2 by DQH2 via the Qin-binding domain can be described by a mechanism in which duroquinol reduces the enzyme, upon which the reduced enzyme is rapidly oxidized by ubiquinone-2 yielding ubiquinol-2. By determination of the initial rate under various conditions and simulation of the time course of reduction of ubiquinone-2 using the integrated form of the steady-state rate equation the values of the various kinetic constants were calculated. During the course of reduction of ubiquinone-2 by duroquinol in the presence of outside inhibitors only cytochrome b-562 becomes reduced. At all stages during the reaction, cytochrome b-562 is in equilibrium with the redox potential of the ubiquinone-2/ubiquinol-2 couple but not with that of the duroquinone/duroquinol couple. At low pH values, cytochrome b-562 is reduced in a single phase; at high pH separate reduction phases are observed. In the absence of inhibitors three reduction phases of cytochrome b-562 are discernible at low pH values and two at high pH values. In the presence of antimyin cytochrome b becomes reduced in two phases. Cytochrome b-562 is reduced in the first phase and cytochrome b-566 in the second phase after substantial reduction of ubiquinone-2 to ubiquinol-2 has occurred. In ubiquinone-10 depleted preparations, titration of cytochrome b-562, in the presence of myxothiazol, with the duroquinone/duroquinol redox couple yields a value of napp = 2, both at low and high pH.(ABSTRACT TRUNCATED AT 400 WORDS)

EPR characterization of the cytochrome b-c1 complex from Rhodobacter sphaeroides

EPR characteristics of cytochrome c1, cytochromes b-565 and b-562, the iron-sulfur cluster, and an antimycin-sensitive ubisemiquinone radical of purified cytochrome b-c1 complex of Rhodobacter sphaeroides have been studied. The EPR specra of cytochrome c1 shows a signal at g = 3.36 flanked with shoulders. The oxidized form of cytochrome b-562 shows a broad EPR signal at g = 3.49, while oxidized cytochrome b-565 shows a signal at g = 3.76, similar to those of two b cytochromes in the mitochondrial complex. The distribution of cytochromes b-565 and b-562 in the isolated complex is 44 and 56%, respectively. Antimycin and 2,5-dibromo-3-methyl-6-isopropyl-1,4-benzoquinone (DBMIB) have little effect on the g = 3.76 signal, but they cause a slight downfield and upfield shifts of the g = 3.49 signal, respectively. 5-Undecyl-6-hydroxyl-4,7-dioxobenzothiazole (UHDBT) shifts the g = 3.49 signal downfield to g = 3.56 and sharpens the g = 3.76 signal slightly. Myxothiazol causes an upfield shift of both g = 3.49 and g = 3.76 signals. EPR characteristics of the reduced iron-sulfur cluster in bacterial cytochrome b-c1 complex are: gx = 1.8 with a small shoulder at g = 1.76, gy = 1.89 and gz = 2.02, similar to those observed with the mitochondrial enzyme. The gx = 1.8 signal decreased and the shoulder increased concurrently as the redox potential decreased, indicating that the environment of the iron-sulfur cluster is sensitive to the redox state of the complex. UHDBT sharpens the gz and and shifts it downfield from g = 2.02 to 2.03, and shifts gx upfield from g = 1.80 to 1.78. UHDBT also causes an upfield shift of gy but to a much lesser extent compared to the other two signals. Addition of DBMIB causes a downfield shift of the gy from 1.89 to 1.94 and broadens the gx signal with an upfield to g = 1.75. Myxothiazol and antimycin show little effect on the gy and gz signals, but they broaden and shift the gx signal upfield to g = 1.74. However, the myxothiazol effect is partially reversed by UHDBT. An antimycin-sensitive ubisemiquinone radical was detected in the cytochrome b-c1 complex. At pH 8.4, the antimycin-sensitive ubisemiquinone radical has a maximal concentration of 0.66 mol per mol complex at 100 mV.(ABSTRACT TRUNCATED AT 400 WORDS)

Inhibitor effects on redox-linked protonations of the b haems of the mitochondrial bc1 complex

The effects of pH and inhibitors on the spectra and redox properties of the haems b of the bc1 complex of beef heart submitochondrial particles were investigated. The major findings were: (1) both haems have a weakly redox-linked protonatable group with pKox and pKred of around 6 and 8; (2) at pH values above 7, haem bH becomes heterogeneous in its redox behaviour. This heterogeneity is removed by the Qi site inhibitors antimycin A, funiculosin and HQNO, but not by the Qo site inhibitors myxothiazol or stigmatellin; (3) of all inhibitors tested only funiculosin had a large effect on the Em/pH profile of either haem b. In all cases where definite effects were found, the haem most affected was that thought to be closest to the site of inhibitor binding; (4) spectral shifts of haem groups caused by inhibitor binding were usually, but not always, of the haem group closest to the binding site; (5) titrations with succinate/fumarate were in reasonable agreement with redox-mediated data provided that strict anaerobiosis was maintained. Apparent large shifts of haem midpoint potentials with antimycin A and myxothiazol could be produced in aerobic succinate/fumarate titrations in the presence of cyanide, as already reported in the literature, but these were artefactual; (6) the heterogeneous haem bH titration behaviour can be simulated with a model similar to that proposed by Salerno et al. (J. Biol. Chem. (1989) 264, 15398-15403) in which there is redox interaction between haem bH and ubiquinone species bound at the Qi site. Simulations closely fit both the haem bH data and known semiquinone data only if it is assumed that semiquinone bound to oxidised haem bH is EPR-silent.

Mitochondrial mutations may increase oxidative stress: implications for carcinogenesis and aging?

The sensitivity of mitochondrial DNA to damage by mutagens predisposes mitochondria to injury on exposure of cells to genotoxins or oxidative stress. Damage to the mitochondrial genome causing mutations or loss of mitochondrial gene products, or to some nuclear genes encoding mitochondrial membrane proteins, may accelerate release of reactive species of oxygen. Such aberrant mitochondria may contribute to cellular aging and promotion of cancer.

Triphasic reduction of bH and the absence of equilibration at the i-site of bc1 complex

The concept of a stabilized semiquinone radical forming the basis of a two-electron gate has long been familiar in the context of the quinone-reducing site in photosynthetic systems and has already been suggested to play a role at the i-site of the bc1-type complexes. It is here pointed out that this concept is sufficient to explain the so-called triphasic reduction kinetics of cytochrome bH, in which cytochrome bH goes partially reduced, is reoxidized and then goes fully reduced. The rate constants for binding and unbinding of quinone, quinol and semiquinone at the i-site are discussed, and a kinetic model featuring slow release of the i-site semiquinone is shown to display many features of the kinetics of electron transfer at the i-site.

The pathway of electron transfer in NADH:Q oxidoreductase

The pre-steady-state reduction by NADPH of NADH:Q oxidoreductase, as present in submitochondrial particles, has been further investigated with the rapid-mixing, rapid-freezing technique. It was found that trypsin treatment, that had previously been used to inactivate the transhydrogenase activity (Bakker, P.T.A. and Albracht, S.P.J. (1986) Biochim. Biophys. Acta 850, 413-422), considerably affected the stability at pH 6.2 of the NAD(P)H oxidation activity of submitochondrial particles. Use of the inhibitor butadione circumvented this problem, thus allowing a more careful investigation of the kinetics at pH 6.2. In the presence of the inhibitor rotenone it was found that 50% of the Fe-S clusters 3 and all of the Fe-S clusters 2 and 4 could be reduced by NADPH within 30 ms at pH 6.2. The remainder of the Fe-S clusters 3 and all of the Fe-S clusters 1 were reduced slowly (complete reduction only after more than 60 s). It was concluded that these latter Fe-S clusters play no role in the NADPH oxidation activity. In the absence of rotenone at pH 6.2 only 50% of the Fe-S clusters 2-4 could be reduced within 30 ms, while Fe-S cluster 1 was again not reduced. This difference was attributed to the fast reoxidation of part of the Fe-S clusters 2 and 4 by ubiquinone. At pH 8.0, where the NADPH oxidation activity is almost zero, 50% of the Fe-S clusters 2-4 could still be reduced by NADPH within 30 ms, while Fe-S cluster 1 was not reduced. The presence of rotenone had no effect on this reduction. From these observations it is concluded that the Fe-S clusters 2 and 4, which were rapidly reduced by NADPH and reoxidised by ubiquinone at pH 6.2, could not be reduced by NADPH at 8.0. This provides an explanation why NADH:Q oxidoreductase was not able to oxidise NADPH at pH 8.0, while part of the Fe-S clusters were still rapidly reduced. As a working hypothesis a dimeric structure for NADH:Q oxidoreductase is proposed. One protomer (B) contains FMN and Fe-S clusters 1-4 in equal amounts; the other protomer (A) is identical except for the absence of Fe-S cluster 1. NADH is able to react with both protomers, while NADPH only reacts with protomer A. A pH-dependent electron transfer from protomer A to protomer B is proposed, which would allow the reduction of Fe-S clusters 2 and 4 of protomer B by NADPH at pH 6.2, which is required for NADPH:Q oxidoreductase activity.

Effect of papain digestion on polypeptide subunits and electron-transfer pathways in mitochondrial b-c1 complex

Papain digestion of subunits of mitochondrial b-c1 complex (ubiquinol-cytochrome-c reductase) isolated from bovine heart and its impact on redox and proton-motive activity of the whole complex were investigated. A 5-min incubation of the oxidized enzyme with papain resulted in digestion of core protein II and the 14-kDa subunit, and limited digestion of the iron-sulfur protein. This was accompanied by a small inhibition of the rate of electron flow and a marked inhibition of proton translocation with decrease of the H+/e- ratio for proton pumping. When papain treatment was performed on the b-c1 complex pre-reduced with ascorbate, partial proteolysis of the iron-sulfur protein and the 14-kDa subunit was greatly accelerated and the electron transfer activity was more markedly inhibited. In all the conditions tested, digestion of the Rieske iron-sulfur protein paralleled the inhibition of reductase activity. Under ascorbate-reduced conditions, papain digestion of the complex gave rise to an alteration of the EPR line shape of the iron-sulfur cluster, namely a broadening and shift of the gx negative peak and destabilization of the protein-bound antimycin-sensitive semiquinone. The latter paralleled the decrease in electron transfer activity and inhibition of antimycin-sensitive cytochrome-b reduction. The results obtained indicate the following. 1. Core protein II and the 14-kDa protein may contribute to the proton-conducting pathway(s) from the matrix aqueous phase to the primary protolytic redox center (protein-bound semiquinone/quinone couple). 2. The iron-sulfur protein contributes, together with other protein(s) (the 14-kDa subunit), to the stabilization of the protein-bound antimycin-sensitive semiquinone species in a protein pocket in the complex. 3. Reduction of the high-potential redox centers induces a change in the quaternary structure of the complex which results in an enhanced surface exposure of segments of the 14-kDa protein and the iron-sulfur protein.