Polarographic studies in presence of Triton X-100 on oxidation-reduction components bound with chromatophores from Rhodospirillum rubrum.

Polarographic studies on oxidation-reduction components bound with chromatophores from Rhodospirillum rubrum were carried out at 24 degrees. 1. Using a carbon-paste electrode as the working electrode, polarographic waves characteristic of oxidation-reduction components were observed in the presence, but not in the absence of Triton X-100; these waves were therefore measured in the presence of the detergent. 2. At least two kinds of oxidation-reduction components were detectable, having different half-wave potentials (E1/2); at pH 7, one had an E1/2 value of +275 mV (POC+275) and the other had a value of +60 mV (POC+60). 3. POC+275 was reduced by succinate and by NADH. Both reductions were almost completely inhibited by antimycin A, which hardly affected the reductions of ubiquinone-10 by succinate and by NADH. Most POC+275 molecules were not reduced by the substrates when quinones were extracted from the chromatophores, and the reductions were mostly restored when ubiquinone-10 was re-added. This indicates that POC+275 is functional between ubiquinone-10 and cytochrome c2 in the electron transport system. 4. POC+60 was reduced by succinate, but hardly at all by NADH. The reduction of POC+60 was not influenced either by the addition of antimycin A or by the extraction of quinones. This suggests that POC+60 is functional in the process from succinate dehydrogenase [EC 1.3.99.1] to ubiquinone-10 in the electron transport system. 5. Of the POC+275 reducible by dithionite, approximately 70% could be reduced in the absence of Triton X-100, provided that the potential of the working electrode immersed in chromatophore suspensions was set at potentials of 0 mV or lower and that the electrochemical reaction was carried out at pH 7.5. When the potential of the electrode was set at +50 mV (the same as the E1/2 value of ubiquinone-10 bound with chromatophores), and the suspension was allowed to stand for various lengths in the presence of the detergent, it was found that approximately half of the electrochemically reducible POC+275 was rapidly reduced, followed by a slow reduction. The discrepancy in the oxidation-reduction equilibrium on the basis of the E1/2 values of ubiquinone-10 and POC+275 is discussed.     

The indispensability of phospholipid and ubiquinone in mitochondrial electron transfer from succinate to cytochrome c.

The indispensability of phospholipid and ubiquinone (Q) in mitochondrial electron transfer was studied by depleting phospholipid and Q in succinate-cytochrome c reductase and then replenishing the depleted enzyme. More than 90% of phospholipid and Q was removed by repeated ammonium sulfate-cholate fractionation. The depleted succinate-cytochrome c reductase showed no enzymatic activity for succinate leads to c or QH2 leads to c and yet retained most of the succinate leads to Q activity. All enzymatic activity was restored upon the addition of Q and phospholipid. Restoration required the addition of Q prior to the addition of phospholipid. Reversing the addition sequence or addition of a mixture of phospholipid and Q resulted only in a small restoration of activities. The conditions for restoration are given in detail. Removal of phospholipid from succinate-cytochrome c reductase resulted in reduction of cytochrome c1 in the absence of exogenous electron donor. Replenishing the preparation with phospholipid brought about the reoxidation of cytochrome c1 in the absence of electron acceptor or oxygen.     

Rapid reduction of cytochrome c1 in the presence of antimycin and its implication for the mechanism of electron transfer in the cytochrome b-c1 segment of the mitochondrial respiratory chain

Antimycin, a specific and highly potent inhibitor of electron transfer in the cytochrome b-c1 segment of the mitochondrial respiratory chain, does not inhibit reduction of cytochrome c1 by succinate in isolated succinate-cytochrome c reductase complex under conditions where the respiratory chain complex undergoes one oxidation-reduction turnover. If a slight molar excess of cytochrome c is added to the isolated reductase complex in the presence of antimycin, there is rapid reduction of one equivalent of c type cytochrome by succinate, after which reduction of the remaining c type cytochrome is inhibited. Antimycin fully inhibits succinate-cytochrome c reductase activity of isolated succinate-cytochrome c reductase complex in which the b-c1 complex undergoes multiple turnovers in a catalytic fashion. In addition, when antimycin is added to isolated reductase complex in the presence of cytochrome c plus cytochrome c oxidase, the inhibitor causes a "crossover" in the steady state level of reduction of the cytochromes b and c1 comparable to this classical effect in mitochondria. On the basis of these results, it is suggested that linear schemes of electron transfer are not adequate to account for the site of antimycin inhibition and the mechanism of electron transfer in the cytochrome b-c1 segment of the respiratory chain. The effects of antimycin are consistent with cyclic electron transfer mechanisms such as the protonmotive Q cycle.     

Inhibitory effect of α-tocopherol and its derivatives on bovine heart succinate-cytochrome c reductase

α-Tocopherol and its derivatives inhibit succinate-cytochrome c reductase activity at a concentration of 0.5 μmol/mg protein in 50 mM phosphate buffer, pH 7.4, containing 0.4 % sodium cholate when α-tocopherol is predispersed in sodium cholate solution. The inhibitory site is located at the cytochrome b-c₁ region. Succinate-ubiquinone reductase activity of succinate-cytochrome c reductase was not impaired by treatment with α-tocopherol. The α-tocopherol-inhibited succinate-cytochrome c reductase activity can be reversed by the addition of ubiquinone and its analogs. When ubiquinone- and phospholipid-depleted succinate-cytochrome c reductase was treated with α-tocopherol followed by reaction with a fixed amount of 2,3-dimethoxy-6-methyl-5-(10-bromodecyl)-1,4-benzoquinone and phospholipid, the amount of α-tocopherol needed to express the maximal inhibition was only 0.3 μmol/mg protein. When ubiquinone- and phospholipid-depleted enzyme was treated with a given amount of α-tocopherol and followed by titration with 2,3-dimethoxy-6-methyl-5-(10-bromodecyl)-1,4-benzoquinone, restoration of activity was enhanced at low concentrations of ubiquinone analog, indicating that α-tocopherol can serve as an effector for ubiquinone. The maximal binding capacity of α-[¹⁴C]tocopherol, dispersed in 50 mM phosphate buffer containing 0.25% sodium cholate, pH 7.4, to succinate-cytochrome c reductase was shown to be 0.68 μmol/mg protein. A similar binding capacity, based on cytochrome b content, was observed in submitochondrial particles. Binding of α-tocopherol to succinate-cytochrome c reductase not only caused an inhibition of enzymatic activity but also caused a reduction of cytochrome c₁ in the absence of substrate, a phenomenon analogous to the removal of phospholipids from the enzyme preparation. Furthermore, binding of α-tocopherol to succinate-cytochrome c reductase decreased the rate of reduction of cytochrome b by succinate. Since electron transfer from succinate to ubiquinone was not affected by α-tocopherol treatment, the decrease in reduction rate of cytochrome b by succinate must be due to a change in environment around cytochrome b. These results as well as the fact that reactivation of α-tocopherol-inhibited enzyme requires only low concentrations of ubiquinone were used to explain the inhibitory effect as a result of a change in protein conformation and protein-phospholipid interaction rather than the direct displacement of ubiquinone by α-tocopherol. This deduction was further supported by the fact that no ubiquinone was released from succinate-cytochrome c reductase upon treatment with α-tocopherol.     

An antimycin-insensitive succinate-cytochrome c reductase activity in pure reconstitutively active succinate dehydrogenase

Antimycin-insensitive succinate-cytochrome c reductase activity has been detected in pure, reconstitutively active succinate dehydrogenase. The enzyme catalyzes electron transfer from succinate to cytochrome c at a rate of 0.7 mumole succinate oxidized per min per mg protein, in the presence of 100 microM cytochrome c. This activity, which is about 2% of that of reconstitutive (the ability of succinate dehydrogenase to reconstitute with coenzyme ubiquinone-binding proteins (QPs) to form succinate-ubiquinone reductase) or succinate-phenazine methosulfate activity in the preparation, differs from antimycin-insensitive succinate-cytochrome c reductase activity detected in submitochondrial particles or isolated succinate-cytochrome c reductase. The Km for cytochrome c for the former is too high to be measured. The Km for the latter is about 4.4 microM, similar to that of antimycin-sensitive succinate-cytochrome c activity in isolated succinate-cytochrome c reductase, suggesting that antimycin-insensitive succinate-cytochrome c activity of succinate-cytochrome c reductase probably results from incomplete inhibition by antimycin. Like reconstitutive activity of succinate dehydrogenase, the antimycin-insensitive succinate-cytochrome c activity of succinate dehydrogenase is sensitive to oxygen; the half-life is about 20 min at 0 degrees C at a protein concentration of 23 mg/ml. In the presence of QPs, the antimycin-insensitive succinate-cytochrome c activity of succinate dehydrogenase disappears and at the same time a thenoyltrifluoroacetone-sensitive succinate-ubiquinone reductase activity appears. This suggests that antimycin-insensitive succinate-cytochrome c reductase activity of succinate dehydrogenase appears when succinate dehydrogenase is detached from the membrane or from QPs. Reconstitutively active succinate dehydrogenase oxidizes succinate using succinylated cytochrome c as electron acceptor, suggesting that a low potential intermediate (radical) may be involved. This suggestion is confirmed by the detection of an unknown radical by spin trapping techniques. When a spin trap, alpha-phenyl-N-tert-butylnitrone (PBN), is added to a succinate oxidizing system containing reconstitutively active succinate dehydrogenase, a PBN spin adduct is generated. Although this PBN spin adduct is identical to that generated by xanthine oxidase, indicating that a perhydroxy radical might be involved, the insensitivity of this antimycin-insensitive succinate-cytochrome c reductase activity to superoxide dismutase and oxygen questions the nature of this observed radical.     

Resolution and reconstitution of succinate-cytochrome c reductase: preparations and properties of high purity succinate dehydrogenase and ubiquinol-cytochrome c reductase

An improved method was developed to sequentially fractionate succinate-cytochrome c reductase into three reconstitutive active enzyme systems with good yield: pure succinate dehydrogenase, ubiquinone-binding protein fraction and a highly purified ubiquinol-cytochrome c reductase (cytochrome b-c1 III complex). An extensively dialyzed succinate-cytochrome c reductase was first separated into a succinae dehydrogenase fraction and the cytochrome b-c1 complex by alkali treatment. The resulting succinate dehydrogenase fraction was further purified to homogeneity by the treatment of butanol, calcium phosphate gel adsorption and ammonium sulfate fractionation under anaerobic condition in the presence of succinate and dithiothreitol. The cytochrome b-c1 complex was separated into chtochrome b-c1 III complex and ubiquinone-binding protein fractions by careful ammonium acetate fractionation in the presence of deoxycholate. The purified succinate dehydrogenase contained only two polypeptides with molecular weights of 70 000 anbd 27 000 as revealed by the sodium dodecyl sulfate polyacrylamide gel electrophoretic pattern. The enzyme has the reconstitutive activity and a low Km ferricyanide reductase activity of 85 mumol succinate oxidized per min per mg protein at 38 degrees C. Chemical composition analysis of cytochrome b-c1 III complex showed that the preparation was completely free of contamination of succinate dehydrogenase and ubiquinone-binding protein and was 30% more pure than the available preparation. When these three components were mixed in a proper ratio, a thenoyltrifluoroacetone- and antimycin A-sensitive succinate-cytochrome c reductase was reconstituted.     

Reconstitution of photosynthetic electron transport and photophosphorylation in cytochrome-c2-deficient membrane preparation of Rhodopseudomonas capsulata.

Cytochrome c₂ was removed by washing from heavy chromatophores prepared from Rhodopseudomonas capsulata cells. The easy removal of the cytochrome could indicate that it was attached on the outside of the membrane. Therefore, the membrane was probably oriented inside out in relation to the membrane of regular chromatophores, from which cytochrome c₂ could not be removed. Washing of the heavy chromatophores caused loss of photphosphorylation activity. The activity was restored to the resolved heavy chromatophores by the supernatant obtained during the washing or by the native cytochrome c₂, which was found to be the active component in this supernatant. The activity could not be restored by other c-type cytochromes. Ascorbate, which enhanced photophosphorylation activity in the heavy chromatophores at the optimal concentration of 8 mm, restored this activity to the washed heavy chromatophores, but at an optimum concentration of 50 mm. Cytochrome c₂ and dichlorophenol indophenol reduced the optimum of the ascorbate concentration to 7 mm. This might indicate that the effect of ascorbate is mediated through cytochrome c₂. Washing the heavy chromatophores caused 70% loss of the light-induced electron transport from ascorbate and from ascorbate-reduced dichlorophenol indophenol to O₂. However, this effect was only observed with the lower concentrations of ascorbate and the dye. The activity was restored either by the supernatant obtained from the washing or by various c-type cytochromes, reduced by ascorbate. Washing the heavy chromatophores did not affect succinate oxidation in the dark. It is suggested that cytochrome c₂ is one of the cytochromes catalyzing the photosynthetic cyclic electron transport, as has been seen from its high specificity in the reconstitution experiments. Light can induce oxidation of various c-type cytochromes and other redox reagents. However, reduction was specific for cytochrome c₂ from Rps. capuslata, since it was the only one which could be both reduced and oxidized as required from a component which is part of a cyclic electron transport chain. It is also suggested that cytochrome c₂ was not part of the succinate oxidase system.     

Lateral diffusion of ubiquinone during electron transfer in phospholipid- and ubiquinone-enriched mitochondrial membranes

After fusion of small unilamellar phospholipid liposomes with mitochondrial inner membranes, the rate of electron transfer between membrane dehydrogenases and cytochrome c decreases as the average distance between integral membrane proteins increases, suggesting that electron transfer is mediated through a diffusional process in the membrane plane (Schneider, H., Lemasters, J. J., H?chli, M., and Hackenbrock, C. R. (1980)., J. Biol. Chem. 255, 3748-3756). The role of ubiquinone in this process was evaluated by fusing liposomes containing ubiquinone-10 or ubiquinone-6, with inner membranes. In control membranes enriched with phospholipid only, ubiquinol-cytochrome c reductase and NADH- and succinate-cytochrome c reductase activities decreased proportionally to the increase in bilayer lipid. These decreases were restored substantially in phospholipid plus ubiquinone-supplemented membranes. The degree to which restoration occurred was dependent upon the length of the isoprenoid side chain of the ubiquinone with the shorter chain length ubiquinone-6, always giving greater restoration than ubiquinone-10. It is concluded that electron transfer between flavin-linked dehydrogenases (Complexes I and II) and cytochrome bc1 (Complex III) occurs by independent, lateral diffusion of ubiquinone as well as independent, lateral diffusion of ubiquinone as well as the protein complexes within the plane of the membrane.     

Biochemical effects of PR toxin on rat liver mitochondrial respiration and oxidative phosphorylation

The in vitro effects of PR toxin, a toxic secondary metabolite produced by certain strains of Penicillium roqueforti, on the membrane structure and function of rat liver mitochondria were investigated. It was found that the respiratory control and oxidative phosphorylation of the isolated mitochondria decreased concomitantly when the toxin was added to the assay system. The respiratory control ratio decreased about 60% and the ADP/O ratio decreased about 40% upon addition of 3.1 X 10(-5) M PR toxin to the highly coupled mitochondria. These findings suggest that PR toxin impairs the structural integrity of mitochondrial membranes. On the other hand, the toxin inhibited mitochondrial respiratory functions. It exhibited noncompetitive inhibitions to succinate oxidase, succinate-cytochrome c reductase, and succinate dehydrogenase activities of the mitochondrial respiratory chain. The inhibitory constants of PR toxin to these three enzyme systems were estimated to be 5.1 X 10(-6), 2.4 X 10(-5), and 5.2 X 10(-5) M, respectively. Moreover, PR toxin was found to change the spectral features of succinate-reduced cytochrome b and cytochrome c1 in succinate-cytochrome c reductase and inhibited the electron transfer between the two cytochromes. These observations indicate that the electron transfer function of succinate-cytochrome c reductase was perturbed by the toxin. However, PR toxin did not show significant inhibition of either cytochrome oxidase or NADH dehydrogenase activity of the mitochondria. It is thus concluded that PR toxin exerts its effect on the mitochondrial respiration and oxidative phosphorylation through action on the membrane and the succinate-cytochrome c reductase complex of the mitochondria.     

The operation of the alternative electron-leak pathways mediated by cytochrome c in mitochondria

Low (1 x 10(-9)M) concentrations of cytochrome c inhibit H2O2 production in cytochrome c-depleted mitochondria, purified succinate-cytochrome c reductase (SCR) and antimycin A inhibited cytochrome c-depleted HMP. At higher concentration (2 x 10(-6)M), cytochrome c eliminates pre-existed H2O2 if feeding electrons to it by succinate. Cytochrome c also decreases the OH* produced by succinate-cytochrome c reductase oxidizing succinate. We conclude that the alternative electron-leak pathway mediated by cytochrome c operates very well. In the presence of antimycin A, ferrocytochrome c can suppress the generation of H2O2 in SCR system, but ferricytochrome c cannot. Similar results are obtained on the elimination of pre-existed H2O2 by cytochrome c. For hydroxyl radical, antimycin A abolishes the suppression caused by both ferrocytochrome c and ferricytochrome c. These results indicate that the reductive state of cytochrome c caused by electron-flow is necessary and sufficient for the operation of cytochrome c-mediated electron-leakage pathway.     

Interactions of cytochrome c with mitochondrial membranes. Binding to succinate-cytochrome c reductase

Methyl-4-azidobenzoimidate was reacted with horse heart cytochrome c to give a photoaffinity-labeled derivative of this heme protein. The modified cytochrome c bound to cytochrome c-depleted mitochondria with the same Kd as native cytochrome c and restored oxygen uptake to the same extent. Irradiation of cytochrome c-depleted mitochondrial membranes with 3- to 4-fold excess of photoaffinity-labeled cytochrome c over cytochrome c oxidase resulted in covalent binding of the derivative to the membranes. Fractionation of the irradiated mitochondria in the presence of detergents and salts followed by chromatography on an agarose Bio-Gel-A-5m showed that the labeled cytochrome c was bound covalently to succinate-cytochrome c reductase. The covalently bound cytochrome c was active in mediating electron transfer between its reductase and oxidase. Sodium dodecyl sulfate polyacrylamide gel electrophoresis of the succinate-cytochrome c reductase containing photoaffinity-labeled 125I-cytochrome c showed that the reductase contained a protein binding site for cytochrome c. It is suggested that cytochrome c1 is the most likely site for the cytochrome c binding in mitochondria in situ.     

Studies with a reconstituted muscle glycolytic system. The rate and extent of glycolysis in simulated post-mortem conditions

The stimulation of succinate-cytochrome c reductase in Jerusalem artichoke mitochondria by lowering osmolarity was found to be associated with conformational changes in the inner membrane rather than with rupture of the outer membrane. This conclusion is based on the following evidence. (1) When the activation of succinate dehydrogenase was measured by using either K(3)Fe(CN)(6) or exogenous cytochrome c as an electron acceptor, electron flow to cytochrome c was always 7% of that to K(3)Fe(CN)(6) throughout the activation process. (2) The rate of exogenous cytochrome c reduction by succinate and NADH was directly related to the maximum rate of electron flow as determined by oxygen utilization. These two observations are not consistent with the low rate of succinate-cytochrome c reductase being limited by a permeability barrier at the outer membrane. (3) In addition to stimulating the succinate-cytochrome c reductase, lowering the osmolarity caused simultaneous changes in the permeability of the inner membrane to ferricyanide and NADH. The data show that lowering the osmolarity results in progressive changes in the permeability of the inner membrane. The first change detected was an increased permeability to K(3)Fe(CN)(6), then a simultaneous increase in accessibility of the respiratory chain to exogenous cytochrome c and an increased permeability to NADH, followed finally by rupture as measured by the release of malate dehydrogenase.     

Myeloperoxidase-mediated damage to the succinate oxidase system of Escherichia coli. Evidence for selective inactivation of the dehydrogenase component

Myeloperoxidase, a granule-associated enzyme of neutrophils and monocytes, combines with H2O2 and chloride to form a potent microbicidal system that contributes to phagocyte antimicrobial activity. The nature of the lesion or lesions induced by the myeloperoxidase system which are responsible for the loss of microbial replicative activity (viability) remains unknown. Using Escherichia coli grown to late log or stationary phase under conditions of low aeration with succinate as the sole carbon source, we found that myeloperoxidase-induced loss of microbial viability could be correlated with a decrease in succinate-dependent respiration (succinate oxidase activity). Succinate dehydrogenase activity fell rapidly to undetectable levels during incubation with the myeloperoxidase system, suggesting that damage to the dehydrogenase was a major factor in the loss of oxidase activity. Other components of the succinate oxidase system were resistant to the actions of myeloperoxidase. The ubiquinone-8 and cytochrome components of the respiratory chain remained nearly constant in amount despite reduction of respiration to undetectable levels. However, as expected from the loss of succinate dehydrogenase activity, succinate-ubiquinone reductase and succinate-cytochrome reductase activities were markedly impaired. We propose that the loss of E. coli viability induced by the myeloperoxidase-H2O2-chloride system is due in part to the loss of electron transport function consequent to the oxidation of critical catalytic centers in susceptible dehydrogenases.     

Photosynthetic membrane development in Rhodopseudomonas sphaeroides. Spectral and kinetic characterization of redox components of light-driven electron flow in apparent photosynthetic membrane growth initiation sites

The kinetics of light-driven electron flow and the nature of redox centers at apparent photosynthetic membrane growth initiation sites in Rhodopseudomans sphaeroides were compared to those of intracytoplasmic photosynthetic membranes. In sucrose gradients, these membrane growth sites sediment more slowly than intracytoplasmic membrane-derived chromatophores and form an upper pigmented band. Cytochromes c1, c2, b561, and b566 were demonstrated in the upper fraction by redox potentiometry; c-type cytochromes were also detected electrophoretically. Signals characteristic of light-induced reaction center bacteriochlorophyll triplet and photooxidized reaction center bacteriochlorophyll dimer states were observed by EPR spectroscopy but the Rieske iron-sulfur signal of the ubiquinol-cytochrome c2 oxidoreductase was present at a 3-fold reduced level on a reaction center basis in comparison to chromatophores. Flash-induced absorbance measurements of the upper pigmented fraction demonstrated reaction center primary and secondary semiquinone anion acceptor signals, but cytochrome b561 photoreduction and cytochrome c1/c2 reactions occurred at slow rates. This fraction was enriched approximately 2- and 4-fold in total b- and c-type cytochromes, respectively, per reaction center over chromatophores, but photoreducible b-type cytochrome was lower. Measurements of respiratory activity indicated a 1.6-fold higher level of succinate-cytochrome c oxidoreductase/reaction center than in chromatophores, but the apparent turnover rates in both preparations were low. Overall, the results suggest that complete cycles of rapid, light-driven electron flow do not occur merely by introduction of newly synthesized reaction centers into respiratory membrane, but that subsequent synthesis and assembly of appropriate components of the ubiquinol-cytochrome c2 oxidoreductase is required.     

Disintegration of Rhodospirillum rubrum chromatophore membrane into photoreaction units, reaction centers, and ubiquinone-10 protein with mixture of cholate and deoxycholate.

1. The membrane of Rhodospirillum rubrum chromatophores was disintegrated with mild detergents (cholate and deoxycholate) in order to study the spatial arrangement of the functional proteins in the photochemical apparatus and the electron transport system in the membrane. 2. The components solubilized from the membrane by a mixture of cholate and deoxycholate (C-DOC) were separated into four fractions by molecular-sieve chromatography in the presence of C-DOC; they were designated as F1, F2, F3, and F4 in the order of elution. The fractions were further purified by repeated molecular-sieve chromatography in the presence of C-DOC until each fraction was chromatographically homogeneous. 3. F1 appeared to be conjugated forms of F2. 4. The purified F2 was composed of a rigid complex having a weight of 7 X 10(5) daltons, containing approximately 10 different kinds of protein species with molecular weights of 3.8 X 10(4), 3.6 X 10(4), 3.5 X 10(4), 2.8 X 10(4), 2.7 X 10(4), 2.6 X 10(4), 1.3 X 10(4), 1.2 X 10(4), 1.1 X 10(4), and 1.0 X 10(4). The complex contained 33 bacteriochlorophylls, 4 iron atoms, and 90 phosphates, but no cytochrome, ubiquinone, or phospholipid. It showed the same reaction center activity as chromatophores, indicating that the complex was a unit of the photochemical apparatus (photoreaction unit). Each chromatophore of average size was estimated to possess about 24 photoreaction units. 5. The purified F3 showed an absorbance spectrum characteristic of reaction centers, and contained 3.4 bacteriochlorophylls, 2.0 bacteriopheophytins, and 1.9 acid-labile iron atoms, but no cytochrome or ubiquinone (C-DOC reaction center). It had a weight of 1.2 X 10(5) daltons, and the main components were 4 protein species with molecular weights of 2.8 X 10(4), 2.7 X 10(4), 2.6 X 10(4), and 1.0 X 10(4). 6. The purified F4 showed a molecular weight of about 11,000, and contained one mole of ubiquinone-10 per mole (ubiquinone-10 protein). 7. The reaction center activity of C-DOC reaction centers was stimulated by ubiquinone-10 protein. In addition, the reaction center oxidized reduced cytochrome c2 in the light, provided that ubiquinone-10 protein was present (photo-oxidase activity).     

Identification of ubiquinone-binding proteins in yeast mitochondrial ubiquinol-cytochrome c reductase using an azido-ubiquinone derivative

An azido-ubiquinone derivative, 3-azido-2-methyl-5-methoxy-6-(3,7-dimethyloctyl)-1,4-benzoquinone, was used to study the ubiquinone-protein interaction and to identify the ubiquinone-binding proteins in yeast mitochondrial ubiquinone-cytochrome c reductase. The phospholipids and Q6 in purified reductase were removed by repeated ammonium sulfate precipitation in the presence of 0.5% sodium cholate. The resulting phospholipid- and ubiquinone-depleted reductase shows no enzymatic activity; activity can be completely restored by the addition of phospholipids and Q6 or Q2. The ubiquinone- and phospholipid-replenished ubiquinonol-cytochrome c reductase is also fully active upon reconstituting with bovine succinate-ubiquinone reductase to form succinate-cytochrome c reductase. When an azido-ubiquinone derivative was added to the ubiquinone and phospholipid-depleted reductase in the dark, followed by the addition of phospholipids, partial reconstitutive activity was restored, while full ubiquinol-cytochrome c reductase activity was observed when Q2H2 was used as substrate in the assay mixture. Apparently, the large amount of Q2H2 present in the assay mixture displaces the azido-ubiquinone in the system. Photolysis of the azido-Q-treated reductase with long-wavelength ultraviolet light abolishes about 70% of both the restored reconstitutive activity and Q2H2-cytochrome c reductase activity. The activity loss is directly proportional to the covalent binding of [3H]azido-ubiquinone to the reductase protein. When the photolyzed, [3H]azido-ubiquinone-treated sample was subjected to SDS-polyacrylamide gel electrophoresis followed by analysis of the distribution of radioactivity among the subunits, the cytochrome b protein and a protein with an apparent molecular weight of 14 000 were heavily labeled. The amount of radioactive labeling in both these proteins was affected by the presence of phospholipids.     

The location and function of cytochrome c2 in Rhodopseudomonas capsulate membranes.

Two fractions of membrane preparations, a heavy and a light one were isolated from mildly broken Rhodopseudomonas capsulata cells. The light fraction which contained vesicles similar to the regular chromatophores obtained by sonication and a heavy fraction which appeared in electron micrographs to consist of cell fragments which were designated as heavy chromatophores and were composed of broken cell envelopes containing closely packed vesicles enclosed within the cytoplasmic membrane. Both types of chromatophores catalyzed photophosphorylation. However, cytochrome c2 could be washed out only from the heavy chromatophores. Photophosphorylation activity which was lost by the removal of the cytochrome could be restored by addition of either cytochrome c2 or phenazine methosulphate. Light induced proton efflux in heavy chromatophores in contrast to proton influx in regular chromatophores. The washed heavy chromatophores did not lose the light induced proton movement. Light induced quenching of 9-aminoacridine and atebrin fluorescence in chromatophores, while the fluorescence was enhanced in the heavy chromatophores. The washing did not affect the fluorescence changes of the heavy chromatophores but caused a reduction of the steady state of the carotenoid absorbance shift. It is suggested that the membrane in the heavy chromatophores is oriented inside out with respect to the membrane in regular chromatophores. Cytochrome c2 which is attached to that side of the membrane facing the outside medium could be removed from the heavy chromatophors and reconstituted to them. The role of cytochrome c2 in photophosphorylation is discussed.     

Activity of reduced ubiquinone: Cytochrome c oxidoreductase with various ubiquinol-isoprenologues as substrate and corresponding inhibitory effect of antimycin in yeast

1. Reduced ubiquinones-1, -2, -3, -4 and -6 were used as substrates for ubiquinol: cytochrome c oxidoreductase.2. The portion of antimycin-sensitive activity depends on the concentration of ubiquinol and on the pH. Only reduced ubiquinone-2 and reduced ubiquinone-3 show high activities the main part of which is sensitive to antimycin.3. The antimycin effect curve of ubiquinol: cytochrome c oxidoreductase is linear in shape with reduced ubiquinone-2 as substrate but sigmoidal with reduced ubiquinone-3 and succinate. Ubiquinol-3: cytochrome c oxidoreductase activity contains a portion scarcely affected by antimycin. About 300 pmoles of antimycin per mg protein, enough to inhibit succinate, NADH- and reduced ubiquinone-2:cytochrome c oxidoreductase almost totally, affect ubiquinol-3: cytochrome c oxidoreductase to only about 80% and another 300 pmoles of antimycin are needed for the next 10% of inhibition.4. The activities of succinate- and NADH: cytochrome c oxidoreductase are stimulated by ubiquinones-2 and -3. The shapes of the inhibition curves by antimycin of the stimulated activities are sigmoidal. About twice the amount of antimycin is necessary to inhibit stimulated activities to the same value as the unstimulated.5. The non-ionic detergent Lubrol WX is not effective in stimulating enzymatic activities. However, in the presence of 0.6 M sorbitol, it converts the linear antimycin effect curve with reduced ubiquinone-2 as substrate, into sigmoidal.6. NADH- and succinate: cytochrome c oxidoreductase activities and reduced ubiquinone-2 and reduced ubiquinone-3: cytochrome c oxidoreductase activities become deactivated with increasing concentrations of the non-ionic detergent Lubrol WX. The activity with reduced ubiquinone-2 as substrate is less resistant to the action of the detergent than with reduced ubiquinone-3. The b-cytochromes do not become CO-reactive by this treatment.7. Deoxycholate in low concentrations does not stimulate ubiquinol: cytochrome c oxidoreductase activity. It converts the inhibition curve by antimycin from sigmoidal to linear with increasing concentrations of the detergent with all substrates tested. The amount of antimycin needed for 90% inhibition of reduced ubiquinone activities is about the same under these conditions as with succinate, NADH or reduced ubiquinol in untreated particles.8. The results are discussed with respect to the theories of the electron transport mechanism and of the inhibition by antimycin of the electron flow through the bc₁-segment of the respiratory chain in beef heart.     

Freezing injury in the yeast respiratory system

The effect of freeze-thawing on the yeast respiratory system was studied at rapid rates of cooling. Freezing of whole cells with liquid nitrogen induced decrease of respiratory activity to under 20% of that of original cells. Mitochondria harvested from freeze-thawed cells have markedly decreased succinate oxidizing activity. Activity of succinate cytochrome c reductase was reduced significantly after freeze-thawing of whole cells while activities of succinate dehydrogenase and cytochrome c oxidase were reduced slightly. By spectrophotometric analysis it was found that about one-half the amount of cytochrome c + c1 was eluted from mitochondria to cytosol after freeze-thawing of cells. The activities of succinate oxidation in mitochondria from freeze-thawed cells were restored to normal levels by the addition of cytochrome c. Freeze-thawing of isolated mitochondria did not induce deactivation of succinate oxidizing activities and succinate cytochrome c reductase, and no elution of cytochrome c was observed. It was concluded that the decreased respiratory activities of yeast cells by freezing of cells with liquid nitrogen can be attributed primarily to the elution of cytochrome c from mitochondria.     

Catalytic activity of cytochromes c and c1 in mitochondria and submitochondrial particles.

1. Beef heart mitochondria have a cytochrome c1:c:aa3 ratio of 0.65:1.0:1.0 as isolated; Keilin-Hartree submitochondrial particles ahve a ratio of 0.65:0.4:1.0. More than 50% of the submitochondrial particle membrane is in the 'inverted' configuration, shielding the catalytically active cytochrome c. The 'endogenous' cytochrome c of particles turns over at a maximal rate between 450 and 550 s-1 during the oxidation of succinate or ascorbate plus TMPD; the maximal turnover rate for cytochrome c in mitochondria is 300-400 s-1, at 28 degrees-30 degrees C, pH 7.4. 2. Ascorbate plus N,N,N',N'-tetramethyl-p-phenylene diamine added to antimycin-treated particles induces anomalous absorption increases between 555 and 565 nm during the aerobic steady state, which disappear upon anaerobiosis; succinate addition abolishes this cycle and permits the partial resolution of cytochrome c1 and cytochrome c steady states at 552.5-547 nm and 550-556.5 nm, respectively. 3. Cytochrome c1 is rather more reduced than cytochrome c during the oxidation of succinate and of ascorbate + N,N,N',N'-tetramethyl-p-phenylene diamine in both mitochondria and submitochondrial particles; a near equilibrium condition exists between cytochromes c1 and c in the aerobic steady state, with a rate constant for the c1 leads to c reduction step greater than 10(3) s-1. 4. The greater apparent response of the c/aa3 electron transfer step to salts, the hyperbolic inhibition of succinate oxidation by azide and cyanide, and the kinetic behaviour of the succinate-cytochrome c reductase system, are all explicable in terms of a near-equilibrium condition prevailing at the c1/c step. Endogenous cytochrome c of mitochondria and submitochondrial particles is apparently largely bound to cytochrome aa3 units in situ. Cytochrome c1 can either reduce the cytochrome c-cytochrome aa3 complex directly, or requires only a small extra amount of cytochrome c to carry the full electron transfer flux.