The Rieske/cytochrome b complex of Heliobacteria

Heliobacteria have a Rieske/cytochrome b complex composed of a Rieske protein, a cytochrome b_6, a subunit IV and a di-heme cytochrome c. The overall structure of the complex seems close to the b₆f complex from cyanobacteria and chloroplasts to the exception of the di-heme cytochrome. We show here by biochemical and biophysical studies that a heme c_i is covalently attached to the Rieske/cytochrome b complex from Heliobacteria. We studied the EPR signature of this heme in two different species, Heliobacterium modesticaldum and Heliobacillus mobilis. In contrast to the case of b₆f complex, a strong axial ligand to the heme is present, most probably a protonatable amino acid residue.     

Contents to volume 164

Cytochrome b₆ from spinach chloroplasts (either within the purified cytochrome b₆f complex, or in its isolated form) exhibits two spectral species, which correspond to two midpoint potentials. This can be demonstrated by low temperature difference spectroscopy at fixed redox potentials. The high potential form of cytochrome b₆ has a split α-peak at 557.5 and 561.5 nm, the low potential form has a symmetrical α-peak at 560.5 nm. Similar results were obtained with cytochrome b₆ in the isolated cytochrome b₆f complex from the cyanobacterium Anabaena variabilis.     

Superoxide anion generation by the cytochrome bc1 complex

We have measured the rates of superoxide anion generation by cytochrome bc₁ complexes isolated from bovine heart and yeast mitochondria and by cytochrome bc₁ complexes from yeast mutants in which the midpoint potentials of the cytochrome b hemes and the Rieske iron-sulfur cluster were altered by mutations in those proteins. With all of the bc₁ complexes the rate of superoxide anion production was greatest in the absence of bc₁ inhibitor and ranged from 3% to 5% of the rate of cytochrome c reduction. Stigmatellin, an inhibitor that binds to the ubiquinol oxidation site in the bc₁ complex, eliminated superoxide anion formation, while myxothiazol, another inhibitor of ubiquinol oxidation, allowed superoxide anion formation at a low rate. Antimycin, an inhibitor that binds to the ubiquinone reduction site in the bc₁ complex, also allowed superoxide anion formation and at a slightly greater rate than myxothiazol. Changes in the midpoint potentials of the cytochrome b hemes had no significant effect on the rate of cytochrome c reduction and only a small effect on the rate of superoxide anion formation. A mutation in the Rieske iron-sulfur protein that lowers its midpoint potential from +285 to +220 mV caused the rate of superoxide anion to decline in parallel with a decline in cytochrome c reductase activity. These results indicate that superoxide anion is formed by similar mechanisms in mammalian and yeast bc₁ complexes. The results also show that changes in the midpoint potentials of the redox components that accept electrons during ubiquinol oxidation have only small effects on the formation of superoxide anion, except to the extent that they affect the activity of the enzyme.     

Mitochondrial cytochrome b-c complex: its oxidation-reduction components and their stoichiometry.

A cytochrome b-c₁ complex was isolated from pigeon breast muscle mitochondria and purified to a content of 3 nmol of cytochrome c₁ per milligram of protein. Anaerobic suspensions of the preparation were titrated with reducing equivalents (NADH) and oxidizing equivalents (ferricyanide). The oxidation-reduction components of the complex were measured by the number of reducing equivalents accepted or donated per cytochrome c₁ and compared with the stoichiometries of the known redox components as measured by independent methods. The preparation accepts or donates 5.2 ± 0.3 equivalents per cytochrome c₁, while the measured content of cytochrome c₁, cytochrome b₅₆₁, cytochrome b₅₆₅, Rieske iron-sulfur protein, ubiquinone, and succinate dehydrogenase accounts for 5.0 ± 0.2 equivalents per cytochrome c₁. It is concluded that there are no unknown redox components in the cytochrome b-c₁ complex. The cytochrome b-c₁ complex (energy transduction site 2) appears to be a structural unit containing equal amounts of cytochrome c₁, cytochrome b₅₆₁, cytochrome b₅₆₆, and the Rieske iron-sulfur protein.     

Role of the Rieske Iron–Sulfur Protein Midpoint Potential in the Protonmotive Q-Cycle Mechanism of the Cytochrome bc 1 Complex

The midpoint potential of the [2Fe–2S] cluster of the Rieske iron–sulfurprotein (E _{m 7} = +280mV) is the primary determinant of the rate of electron transfer from ubiquinol to cytochromec catalyzed by the cytochrome bc ₁ complex. As the midpoint potential of the Rieske clusteris lowered by altering the electronic environment surrounding the cluster, theubiquinol-cytochrome c reductase activity of the bc ₁ complex decreases; between 220 and 280 mV therate changes 2.5-fold. The midpoint potential of the Rieske cluster also affects thepresteady-state kinetics of cytochrome b and c ₁ reduction. When the midpoint potential of the Rieskecluster is more positive than that of the heme of cytochrome c ₁, reduction of cytochrome bis biphasic. The fast phase of b reduction is linked to the optically invisible reduction of theRieske center, while the rate of the second, slow phase matches that of c ₁ reduction. The ratesof b and c ₁ reduction become slower as the potential of the Rieske cluster decreases andchange from biphasic to monophasic as the Rieske potential approaches that of theubiquinone/ubiquinol couple. Reduction of b and c ₁ remain kinetically linked as the midpoint potentialof the Rieske cluster is varied by 180 mV and under conditions where the presteady statereduction is biphasic or monophasic. The persistent linkage of the rates of b and c ₁ reduction isaccounted for by the bifurcated oxidation of ubiquinol that is unique to the Q-cycle mechanism.     

Generation of semiquinone-[2Fe-2S]+ spin-coupled center at the Qo site of cytochrome bc1 in redox-poised,illuminated photosynthetic membranes from Rhodobacter capsulatus

One of the less understood parts of the catalytic cycle of cytochrome bc₁/b₆f complexes is the mechanism of electronic bifurcation occurring within the hydroquinone oxidation site (Q_o site). Several models describing this mechanism invoke a phenomenon of formation of an unstable semiquinone. Recent studies with isolated cytochrome bc₁ or b₆f revealed that a relatively stable semiquinone spin-coupled to the reduced Rieske cluster (SQ-FeS) is generated at the Q_o site during the oxidation of ubi- or plastohydroquinone analogs under conditions of continuous turnover. Here, we identified the EPR transition of SQ-FeS formed upon oxidation of ubihydroquinone in native photosynthetic membranes from purple bacterium Rhodobacter capsulatus. We observed a significant amount of SQ-FeS generated when the antimycin-inhibited enzyme experiences conditions of non-equilibrium caused by the continuous light activation of the reaction center. We also noted that SQ-FeS cannot be detected under equilibrium redox titrations in dark. The non-equilibrium redox titrations of SQ-FeS indicate that this center has a higher apparent redox midpoint potential when compared to the redox midpoint potential of the quinone pool. This suggests that SQ-FeS is stabilized, which corroborates a recently proposed mechanism in which the SQ-FeS state is metastable and functions to safely hold electrons at the local energy minimum during the oxidation of ubihydroquinone and limits superoxide formation. Our results open new possibilities to study the formation and properties of this state in cytochromes bc under close to physiological conditions in which non-equilibrium is attained by the light activation of bacterial reaction centers or photosystems.     

Photoreactions of cytochrome b6 in systems using resolved chloroplast electron-transfer complexes

Photoreactions of cytochrome b₆ have been studied using resolved chloroplast electron-transfer complexes. In the presence of Photosystem (PS) II and the cytochrome b₆-f complex, photoreduction of the cytochrome can be observed. No soluble components are required for this reaction. Cytochrome b₆ photoreduction was found to be inhibited by quinone analogs, which inhibit at the Rieske iron-sulfur center of the cytochrome complex, by the addition of ascorbate and by depletion of the Rieske center and bound plastoquinone from the cytochrome complex. Photoreduction of cytochrome b₆ can also be demonstrated in the presence of the cytochrome complex and PS I. This photoreduction requires plastocyanin and a low-potential electron donor, such as durohydroquinone. Cytochrome b₆ photoreduction in the presence of PS I is inhibited by quinone analogs which interact with the Rieske iron-sulfur center. These results are discussed in terms of a Q-cycle mechanism in which plastosemiquinone serves as the reductant for cytochrome b₆ via an oxidant-induced reductive pathway.     

Cytochrome c6B of Synechococcus sp. WH 8102 – Crystal structure and basic properties of novel c6-like family representative

Cytochromes c are soluble electron carriers of relatively low molecular weight, containing single heme moiety. In cyanobacteria cytochrome c₆ participates in electron transfer from cytochrome b₆f complex to photosystem I. Recent phylogenetic analysis revealed the existence of a few families of proteins homologous to the previously mentioned. Cytochrome c_6A from Arabidopsis thaliana was identified as a protein responsible for disulfide bond formation in response to intracellular redox state changes and c₅₅₀ is well known element of photosystem II. However, function of cytochromes marked as c_6B, c_6C and c_M as well as the physiological process in which they take a part still remain unidentified. Here we present the first structural and biophysical analysis of cytochrome from the c_6B family from mesophilic cyanobacteria Synechococcus sp. WH 8102. Purified protein was crystallized and its structure was refined at 1.4 Å resolution. Overall architecture of this polypeptide resembles typical I-class cytochromes c. The main features, that distinguish described protein from cytochrome c₆, are slightly red-shifted α band of UV–Vis spectrum as well as relatively low midpoint potential (113.2 ± 2.2 mV). Although, physiological function of cytochrome c_6B has yet to be determined its properties probably exclude the participation of this protein in electron trafficking between b₆f complex and photosystem I.     

Biosynthesis of P700-Chlorophyll a Protein Complex, Plastocyanin, and Cytochrome b(6)/f Complex

Changes in the amount of P700-chlorophyll a protein complex, plastocyanin, and cytochrome b₆/f complex during greening of pea (Pisum sativum L.), wheat (Triticum aestivum L.), and barley (Hordeum vulgare L.) leaves were analyzed by an immunochemical quantification method. Neither subunit I nor II of P700-chlorophyll a protein complex could be detected in the etiolated seedlings of all three plants and the accumulation of these subunits was shown to be light dependent. On the other hand, a small amount of plastocyanin was present in the etiolated seedlings of all three plants and its level increased about 30-fold during the subsequent 72-hour greening period. Furthermore, cytochrome f, cytochrome b₆, and Rieske Fe-S center protein in cytochrome b₆/f complex were also present in the etiolated seedings of all three plants. The level of each subunit component increased differently during greening and their induction pattern differed from species to species. The accumulation of cytochrome b₆/f complex was most profoundly affected by light in pea leaves, and the levels of cytochrome f, cytochrome b₆, and Rieske Fe-S center protein increased during greening about 10-, 20-, and more than 30-fold, respectively. In comparison to the case of pea seedlings, in wheat and barley leaves the level of each subunit component increased much less markedly. The results suggest that light regulates the accumulation of not only the chlorophyll protein complex but also the components of the electron transport systems.     

Cytochrome c interaction with membranes. Interaction of cytochrome c with isolated membrane fragments and purified enzymes

The midpoint redox potential of cytochrome c and the electron paramagnetic resonance spectra of nitroxide labeled cytochromes c were measured as a function of binding to purified cytochrome c oxidase, cytochrome c peroxidase, cytochrome b₅ and succinate—cytochrome c reductase. The midpoint redox potential of horse heart cytochrome c is lowered in the presence of cytochrome c oxidase and succinate-cytochrome c reductase, but is unchanged in the presence of cytochrome c peroxidase or cytochrome b₅. Further evidence of binding is afforded by an increase in correlation time, T_c, of the spin-labeled cytochrome c at methionine 65 upon binding to cytochrome c peroxidase, cytochrome c oxidase and succinate—cytochrome c reductase. The changes in midpoint redox potential and electron paramagnetic resonance spectrum of the spin-labeled derivative upon binding can either be the consequence of specific interaction leading to formation of ES complexes, or it can be due to nonspecific electrostatic interaction between positively charged groups on cytochrome c and negatively charged groups on the isolated cytochrome preparations.     

Effect of phospholipid on the redox potential and enzymic properties of cytochromes b.

The effects of phospholipid on the redox behavior of b cytochromes in succinate-cytochrome c reductase, the cytochrome b-c₁ complex, and an isolated cytochrome b preparation were investigated by the oxidative and reductive titrations. Three E_m values of cytochrome b were observed in the phospholipid-sufftcient and -depleted succinate-cytochrome c reductase. Their midpoint potentials at pH 7.4 are 75, 75, and ?100 mV for the sufficient and 10, ?30, and ?160 mV for the depleted reductase. The molar distribution of the b cytochromes of these E_m values correspond to 30, 30, and 40%, respectively. The E_m values of the isolated cytochrome b preparations were not affected by addition of phospholipids. The isolated b preparation contained two components of equal concentration with E_m values of ?85 and ?200 mV. No direct correlation between enzymic activity and the amount of high potential b cytochromes present in the systems was demonstrated. Very little difference was observed in redox behavior of b cytochromes between the aged inactive preparations of phospholipid-depleted reductase and that of freshly prepared reconstitutively active enzyme.     

Thermodynamic and EPR characterization of mitochondrial succinate-cytochrome c reductase-phospholipid complexes

Succinate-cytochrome c reductase can be easily solubilized in a phospholipid mixture (1:1, lysolecithin:lecithin) in the absence of detergents. The resulting solution contains two b cytochromes with half-reduction potentials of 95 ± 10 mV (b₅₆₁), and 0 ± 10 mV (b₅₆₆) and cytochrome c₁ (E_{m 7.2} = +280±5 mV). The oxidation-reduction midpoint potentials obtained by optical potentiometric titrations are identical to those determined by the EPR titrations and are 40–60 mV higher than the corresponding midpoint potentials of these cytochromes in intact mitochondria. In contrast to detergent-suspended preparations, no CO-sensitive cytochrome b can be detected in the phospholipid-solubilized preparation or intact mitochondria. The half-reduction potential of cytochrome b₅₆₆ is pH-dependent above pH 7.0 (?60 mV/pH unit) while that of b₅₆₁ is essentially pH-independent from pH 6.7–8.5, in contrast to its pH dependence in intact mitochondria. EPR characterizations show the presence of three oxidized low-spin heme-iron signals with g values of 3.78, 3.41 and 3.37. The identification of these signals with cytochromes b₅₆₆ (b_T), b₅₆₁ (b_K) and c₁ respectively is made on the basis of redox midpoint potentials. No significant amounts of oxidized high-spin heme-iron are detectable. In addition, the preparation contains four distinct types of iron-sulfur centers: S₁ and S₂ (E_{m 7.4} = ?260 mV and 0 mV), and two iron-sulfur proteins which are associated with the cytochrome b-c₁ complex: Rieske's iron-sulfur protein (E_{m 7.4} = +280 mV) and Ohnishi's Center 5 (E_{m 7.4} = +35 mV).     

Localization of cytochrome b6f complexes implies an incomplete respiratory chain in cytoplasmic membranes of the cyanobacterium Synechocystis sp. PCC 6803

The cytochrome b₆f complex is an integral part of the photosynthetic and respiratory electron transfer chain of oxygenic photosynthetic bacteria. The core of this complex is composed of four subunits, cytochrome b, cytochrome f, subunit IV and the Rieske protein (PetC). In this study deletion mutants of all three petC genes of Synechocystis sp. PCC 6803 were constructed to investigate their localization, involvement in electron transfer, respiration and photohydrogen evolution. Immunoblots revealed that PetC1, PetC2, and all other core subunits were exclusively localized in the thylakoids, while the third Rieske protein (PetC3) was the only subunit found in the cytoplasmic membrane. Deletion of petC3 and both of the quinol oxidases failed to elicit a change in respiration rate, when compared to the respective oxidase mutant. This supports a different function of PetC3 other than respiratory electron transfer. We conclude that the cytoplasmic membrane of Synechocystis lacks both a cytochrome c oxidase and the cytochrome b₆f complex and present a model for the major electron transfer pathways in the two membranes of Synechocystis. In this model there is no proton pumping electron transfer complex in the cytoplasmic membrane.Cyclic electron transfer was impaired in all petC1 mutants. Nonetheless, hydrogenase activity and photohydrogen evolution of all mutants were similar to wild type cells. A reduced linear electron transfer and an increased quinol oxidase activity seem to counteract an increased hydrogen evolution in this case. This adds further support to the close interplay between the cytochrome bd oxidase and the bidirectional hydrogenase.     

The Qo-site inhibitor DBMIB favours the proximal position of the chloroplast Rieske protein and induces a pK-shift of the redox-linked proton

The interaction of the inhibitor 2,5-dibromo-3-methyl-6-isopropylbenzoquinone (DBMIB) with the Rieske protein of the chloroplast b₆f complex has been studied by EPR. All three redox states of DBMIB were found to interact with the iron-sulphur cluster. The presence of the oxidised form of DBMIB altered the equilibrium distribution of the Rieske protein’s conformational substates, strongly favouring the proximal position close to heme b_L. In addition to this conformational effect, DBMIB shifted the pK-value of the redox-linked proton involved in the iron-sulphur cluster’s redox transition by about 1.5 pH units towards more acidic values. The implications of these results with respect to the interaction of the native quinone substrate and the Rieske cluster in cytochrome bc complexes are discussed.     

The dynamic complex of cytochrome c6 and cytochrome f studied with paramagnetic NMR spectroscopy

The rapid transfer of electrons in the photosynthetic redox chain is achieved by the formation of short-lived complexes of cytochrome b₆f with the electron transfer proteins plastocyanin and cytochrome c₆. A balance must exist between fast intermolecular electron transfer and rapid dissociation, which requires the formation of a complex that has limited specificity. The interaction of the soluble fragment of cytochrome f and cytochrome c₆ from the cyanobacterium Nostoc sp. PCC 7119 was studied using NMR spectroscopy and X-ray diffraction. The crystal structures of wild type, M58H and M58C cytochrome c₆ were determined. The M58C variant is an excellent low potential mimic of the wild type protein and was used in chemical shift perturbation and paramagnetic relaxation NMR experiments to characterize the complex with cytochrome f. The interaction is highly dynamic and can be described as a pure encounter complex, with no dominant stereospecific complex. Ensemble docking calculations and Monte-Carlo simulations suggest a model in which charge–charge interactions pre-orient cytochrome c₆ with its haem edge toward cytochrome f to form an ensemble of orientations with extensive contacts between the hydrophobic patches on both cytochromes, bringing the two haem groups sufficiently close to allow for rapid electron transfer. This model of complex formation allows for a gradual increase and decrease of the hydrophobic interactions during association and dissociation, thus avoiding a high transition state barrier that would slow down the dissociation process.     

The photosynthetic apparatus and photoinduced electron transfer in the aerobic phototrophic bacteria <Emphasis Type="Italic">Roseicyclus mahoneyensis</Emphasis> and <Emphasis Type="Italic">Porphyrobacter meromictius</Emphasis>

Photosynthetic electron transfer has been examined in whole cells, isolated membranes and in partially purified reaction centers (RCs) of Roseicyclus mahoneyensis, strain ML6 and Porphyrobacter meromictius, strain ML31, two species of obligate aerobic anoxygenic phototrophic bacteria. Photochemical activity in strain ML31 was observed aerobically, but the photosynthetic apparatus was not functional under anaerobic conditions. In strain ML6 low levels of photochemistry were measured anaerobically, possibly due to incomplete reduction of the primary electron acceptor (Q_A) prior to light excitation, however, electron transfer occurred optimally under low oxygen conditions. Photoinduced electron transfer involves a soluble cytochrome c in both strains, and an additional reaction center (RC)-bound cytochrome c in ML6. The redox properties of the primary electron donor (P) and Q_A of ML31 are similar to those previously determined for other aerobic phototrophs, with midpoint redox potentials of +463 mV and −25 mV, respectively. Strain ML6 showed a very narrow range of ambient redox potentials appropriate for photosynthesis, with midpoint redox potentials of +415 mV for P and +94 mV for Q_A. Cytoplasm soluble and photosynthetic complex bound cytochromes were characterized in terms of apparent molecular mass. Fluorescence excitation spectra revealed that abundant carotenoids not intimately associated with the RC are not involved in photosynthetic energy conservation.     

Analysis of the Kinetics and Bistability of Ubiquinol:Cytochrome c Oxidoreductase

Ubiquinol:cytochrome c oxidoreductase, bc₁ complex, is the enzyme in the respiratory chain of mitochondria responsible for the transfer reducing potential from ubiquinol to cytochrome c coupled to the movement of charge against the electrostatic potential across the mitochondrial inner membrane. The complex is also implicated in the generation of reactive oxygen species under certain conditions and is thus a contributor to cellular oxidative stress. Here, a biophysically detailed, thermodynamically consistent model of the bc₁ complex for mammalian mitochondria is developed. The model incorporates the major redox centers near the Q_o- and Q_i-site of the enzyme, includes the pH-dependent redox reactions, accounts for the effect of the proton-motive force of the reaction rate, and simulates superoxide production at the Q_o-site. The model consists of six distinct states characterized by the mobile electron distribution in the enzyme. Within each state, substates that correspond to various electron localizations exist in a rapid equilibrium distribution. The steady-state equation for the six-state system is parameterized using five independent data sets and validated in comparison to additional experimental data. Model analysis suggests that the pH-dependence on turnover is primarily due to the pKa values of cytochrome b_H and Rieske iron sulfur protein. A previously proposed kinetic scheme at the Q_i-site where ubiquinone binds to only the reduced enzyme and ubiquinol binds to only the oxidized enzyme is shown to be thermodynamically infeasible. Moreover, the model is able to reproduce the bistability phenomenon where at a given overall flux through the enzyme, different rates of superoxide production are attained when the enzyme is differentially reduced.     

Characterization of cytochrome b in the isolated ubiquinol-cytochrome c2 oxidoreductase from Rhodopseudomonas sphaeroides GA

Extinction coefficients for cytochrome b and c₁ in the isolated cytochrome bc₁ complex from Rhodopseudomonas sphaeroides GA have been determined. They are 25 mM^?1.cm^?1 at 561 nm for cytochrome b and 17.4 mM^?1.cm^?1 at 553 nM for cytochrome c₁ for the difference between the reduced and the oxidized state. Cytochrome b is present in two forms in the complex. One form has an E_m7 of 50 mV, an α-peak of 557 nm at liquid N₂ temperature and of 561 nm at RT, which is red-shifted by antimycin A. The other form has an E_m7 of ?90 mV, a double α-peak of 555 and 561 nm at liquid N₂ temperature corresponding to 559 and 566 nm at RT. The absorption at 566 nm is red-shifted by myxothiazol. The two shifts are independent of each other. Both midpoint potentials of cytochromes b are pH-dependent. The redox center compositions of the cytochrome bc₁ complexes from Rhodopseudomonas sphaeroides and from mitochondria are identical.     

Redox-linked protonation state changes in cytochrome bc1 identified by Poisson-Boltzmann electrostatics calculations

Cytochrome bc₁ is a major component of biological energy conversion that exploits an energetically favourable redox reaction to generate a transmembrane proton gradient. Since the mechanistic details of the coupling of redox and protonation reactions in the active sites are largely unresolved, we have identified residues that undergo redox-linked protonation state changes. Structure-based Poisson-Boltzmann/Monte Carlo titration calculations have been performed for completely reduced and completely oxidised cytochrome bc₁. Different crystallographically observed conformations of Glu272 and surrounding residues of the cytochrome b subunit in cytochrome bc₁ from Saccharomyces cerevisiae have been considered in the calculations. Coenzyme Q (CoQ) has been modelled into the CoQ oxidation site (Q_o-site). Our results indicate that both conformational and protonation state changes of Glu272 of cytochrome b may contribute to the postulated gating of CoQ oxidation. The Rieske iron-sulphur cluster could be shown to undergo redox-linked protonation state changes of its histidine ligands in the structural context of the CoQ-bound Q_o-site. The proton acceptor role of the CoQ ligands in the CoQ reduction site (Q_i-site) is supported by our results. A modified path for proton uptake towards the Q_i-site features a cluster of conserved lysine residues in the cytochrome b (Lys228) and cytochrome c₁ subunits (Lys288, Lys289, Lys296). The cardiolipin molecule bound close to the Q_i-site stabilises protons in this cluster of lysine residues.