Cytochrome c interaction with membranes. Formylated cytochrome c.

A single species of tryptophan-59 formylated cytochrome c with a half-reduction potential of 0.085 ± 0.01 V at pH 7.0 was used to study its catalytic and functional properties. The spectral properties of the modified cytochrome show that the 6th ligand position is open to reaction with azide, cyanide, and carbon monoxide. Formylated cytochrome c binds to cytochrome c depleted rat liver and pigeon heart mitochondria with the precise stoichiometry of two modified cytochrome c molecules per molecule of cytochrome a (K_D of approx 0.1 μm). Formylated cytochrome c was reducible by ascorbate and was readily oxidized by cytochrome c oxidase. The apparent K_m value of the oxidase for the formylated cytochrome c was six times higher than for the native cytochrome and the apparent V was smaller. Formylated cytochrome c does not restore the oxygen uptake in C-depleted mitochondria but inhibits, in a competitive manner, the oxygen uptake induced by the addition of native cytochrome c. Formylated cytochrome c was inactive in the reaction with mitochondrial NADH-cytochrome c reductase but was able to accept electrons through the microsomal NADPH-cytochrome c reductase.     

Ferrocyanide as electron donor to cytochrome aa3. Cytochrome c requirement for oxygen uptake

1. In the absence of cytochrome c, ferrocyanide or ferrous sulphate reduces cytochrome c oxidase (EC 1.9.3.1), but no continuous oxygen uptake ensues, as it does with N,N,N′,N′-Tetramethyl-p-phenylenediamine or reduced phenazine methosulphate as reductants, unless a substoichiometric amount of cytochrome c or an excess of clupein is present. Cytochrome c cannot be replaced by porphyrin cytochrome c.2. Cytochrome c, porphyrin cytochrome c and clupein all stimulate the reduction of cytochrome aa₃ by ferrocyanide.3. A model is proposed to explain these findings in which a high-affinity site for cytochrome c on the oxidase regulates the access of hydrophilic electron donors to a low-affinity site, and reduction via the high-affinity site is required for continuous oxygen uptake.4. Furthermore, it is shown that upon reaction of oxidase with ferrocyanide, cyano-oxidase is formed.     

Control of respiration in proteoliposomes containing cytochrome aa3. I. Stimulation by valinomycin and uncoupler

1. Both valinomycin and p-trifluoromethoxy carbonyl cyanide phenylhydrazone (FCCP) are required for full release of respiration by cytochrome c oxidase-containing proteoliposomes (prepared by sonicating beef heart cytochrome aa₃ in salt solution with 4 parts phosphatidylcholine, 4 parts phosphatidylethanolamine and 2 parts cardiolipin) in the presence of external ascorbate and cytochrome c. In the absence of valinomycin the response to FCCP is rather sluggish, as reported by Wrigglesworth et al. (1976) (Abstracts, 10th Int. Congr. Biochem., No. 06-6-230).2. The K_m for cytochrome c in 67 mM, pH 7.4, phosphate buffer with ascorbate as substrate, was 9 μM in both absence and presence of valinomycin and FCCP. Energization thus acts non-competitively towards cytochrome c oxidation.3. The apparent K_m for oxygen is greater in the energized than in the deenergized state; double reciprocal plots of respiration rate versus oxygen concentration are concave downward in the absence of uncouplers, as found with intact mitochondria. Energization thus acts “competitively” towards oxygen.4. Despite the lack of a functional ATPase system, all the kinetic features of energization found in intact mitochondria can be mimicked in the reconstituted liposomes. This supports the chemiosmotic idea that electrical and perhaps H⁺ gradients modify the oxidase activity in reconstituted vesicles.     

Reaction of cytochrome c in the electron-transport chain of Paracoccus denitrificans

The reaction of the cytochrome c oxidase (ferrocytochrome c:oxygen oxidoreductase, EC 1.9.3.1) of Paracoccus denitrificans cytoplasmic membranes with the endogenous cytochrome c of the membranes was studied, as well as its interaction with added exogenous cytochrome c from P. denitrificans or bovine heart. The polarographic method was employed, using N,N,N′,N′-tetramethyl-p-phenylenediamine plus ascorbate to reduce the cytochrome c. We found that overall electron transport can proceed maximally while the cytochrome c remains membrane bound; NADH or succinoxidase activities were not inhibited by the addition of substances which bind the P. denitrificans cytochrome c strongly. In contrast to our observations with the spectrophotometric method (Smith, L., Davies, H.C. and Nava, M.E. (1976) Biochemistry 15, 5827–5831), in the polarographic assays the membrane-bound oxidase reacts with about equal rapidity with exogenous bovine and P. denitrificans cytochromes c. The reaction of the oxidase with the endogenous cytochrome c proceeds at high rates and preferentially to that with exogenous cytochrome c; the reaction with the latter, but not the former is inhibited by positively charged poly(l-lysine). The cytochrome c and the oxidase appear to be very closely associated on the membrane.     

13th International Congress of Biochemistry

Cytochrome caa₃ (cytochrome oxidase) from the thermophilic bacterium PS3 can exhibit full catalytic activity in the presence of ascorbate and TMPD or other electron donors and in the absence of added soluble c-type cytochromes. It appears to possess only a low-affinity and not a high-affinity site for the soluble cytochromes. Proteoliposomal cytochrome caa₃ develops an effective membrane potential in the presence of ascorbate and TMPD or PMS, in the absence of added soluble cytochrome c. Reduction of the a₃ centre is blocked in the presence of cyanide. During reductive titrations of the cyanide-inhibited enzyme, electrons initially equilibrate among three centres, the c haem, the a haem and one of the associated Cu atoms. During steady-state turnover, electrons probably enter the complex via the bound c haem; the a haem and perhaps an associated Cu_A atom are reduced next. It is concluded that, despite its size and hydrophobic association with the aa₃ complex, the haem c-containing subunit can behave in an analogous way to that of mammalian cytochrome c, bound at the high-affinity site of the eucaryotic enzyme.     

Cytochrome c interactions with membranes. A photoaffinity-labeled cytochrome c.

The aryl azide, 2,4-dinitro-5-fluorophenylazide, was reacted with horse heart cytochrome c to give a photoaffinity-labeled derivative of this heme protein. The modified cytochrome c, with one to two dinitroazidophenyl groups per mole of the enzyme, has a half-reduction potential the same (± 10 mV) as native cytochrome c. The dissociation constant for the modified cytochrome c from cytochrome c-depleted mitochondrial membranes and the apparent K_m for the reaction with cytochrome c oxidase were each five to six times greater than the values for native cytochrome c. Irradiation of cytochrome c-depleted mitochondrial membranes supplemented with an excess of photoaffinity-labeled cytochrome c resulted in covalent binding of the derivative to the mitochondrial membranes. Fractionation of the irradiated mitochondria in the presence of detergents and salts followed by chromatography on agarose, Bio-Gel A, showed that labeled cytochrome c was bound covalently to cytochrome c oxidase in a 1:1 molar complex. The covalently linked cytochrome c-cytochrome c oxidase complex was active in mediating the electron transfer between N,N,N′,N′-tetramethyl-p-phenylenediamine/ascorbate and the oxidase.     

Cytochrome c reactivity in its complexes with mammalian cytochrome c oxidase and yeast peroxidase

1.

1. The ascorbate reducibility of cytochrome c (beef or horse heart) in its complexes with cytochrome c oxidase (beef heart) and cytochrome c peroxidase (yeast) has been studied.     

Effect of crosslinking cytochrome c oxidase

Bovine heart cytochrome c oxidase and rat liver mitochondria were crosslinked in the presence and absence of cytochrome c. Biimidate treatment of purified cytochrome oxidase, which results in the crosslinkage of all of the oxidase protomers except subunit I when ? 20% of the free amines are modified, inhibits ascorbate-N,N,N′,N′-tetramethyl-p-phenylene diamine oxidase activity. Intermolecular crosslinking of cytochrome oxidase molecules, which results in the formation of large enzyme aggregates displaying rotational correlation times ? 1 ms, does not affect oxidase activity. Crosslinking of mitochondria covalently binds the cytochrome bc₁ and aa₃ complexes to cytochrome c, and inhibits steady-state oxidase activity. Addition of cytochrome c to purified cytochrome oxidase or to cytochrome c-depleted mitoplasts increases this inhibition slightly. Cytochrome c oligomers act as competitive inhibitors of native cytochrome c; however, crosslinking of cytochrome c to cytochrome c-depleted mitoplasts or purified cytochrome oxidase results in a catalytically inactive complex. These experiments indicate that cytochrome c oxidase subunit interactions are required for activity, and that cytochrome c mobility may be essential for electron transport between cytochrome c reductase and oxidase.     

Energized transport of potassium ions in the absence of valinomycin by cytochrome c oxidase-reconstituted vesicles

Valinomycin-independent energized uptake of K⁺ was observed in cytochrome c oxidase reconstituted proteoliposome. The rate of K⁺ influx was proportoinal to the magnitude of electron flux. The energized uptake of K⁺ was abolished by p-trifluoromethoxycarbonylcyanide phenylhydrazone or by nigericin. Using the safranine fluorescence technique, it was demonstrated that even in the absence of valinomycin, liposomes and proteoliposomes reconstituted with cytochrome c oxidase are able to discriminate between Na⁺ and K⁺ and show a preference for K⁺ in the presence of excess Na⁺.     

Reduction of ascorbate free radical by the plasma membrane of synaptic terminals from rat brain

Synaptic plasma membranes (SPMV) decrease the steady state ascorbate free radical (AFR) concentration of 1 mM ascorbate in phosphate/EDTA buffer (pH 7), due to AFR recycling by redox coupling between ascorbate and the ubiquinone content of these membranes. In the presence of NADH, but not NADPH, SPMV catalyse a rapid recycling of AFR which further lower the AFR concentration below 0.05 μM. These results correlate with the nearly 10-fold higher NADH oxidase over NADPH oxidase activity of SPMV. SPMV has NADH-dependent coenzyme Q reductase activity. In the presence of ascorbate the stimulation of the NADH oxidase activity of SPMV by coenzyme Q₁ and cytochrome c can be accounted for by the increase of the AFR concentration generated by the redox pairs ascorbate/coenzyme Q₁ and ascorbate/cytochrome c. The NADH:AFR reductase activity makes a major contribution to the NADH oxidase activity of SPMV and decreases the steady-state AFR concentration well below the micromolar concentration range.     

The use of a water-soluble carbodiimide to cross-link cytochrome c to plastocyanin

A water-soluble carbodiimide, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide, has been used to cross-link horse heart cytochrome c to spinach chloroplast plastocyanin. The complex was formed in yields up to 90%, and was found to have a stoichiometry of 1 mol plastocyanin per mol cytochrome c. The cytochrome c in the complex was fully reducible by ascorbate and potassium ferrocyanide, and had a redox potential only 25 mV less than that of native cytochrome c. The complex was nearly completely inactive towards succinate-cytochrome c reductase and cytochrome c oxidase, suggesting that the heme crevice region of cytochrome c was blocked. We propose that the carbodiimide promoted the formation of amide cross-links between lysine amino groups surrounding the heme crevice of cytochrome c and complementary carboxyl groups on plastocyanin. It is of interest that the high-affinity site for cytochrome c binding on bovine heart cytochrome c oxidase has recently been found to involve a sequence of subunit II with some homology to the copper-binding sequence of plastocyanin.     

Turnover and vectorial properties of cytochrome c oxidase in reconstituted vesicles

1. Proteoliposomes containing cytochrome c oxidase and phospholipid have been made by sonication and by the cholate dialysis procedure. In both methods of preparation, only about 50% of the enzyme molecules are oriented in the membrane with their cytochrome c reaction sites exposed to the outside of the vesicle.2. The activity of cytochrome c oxidase in the reconstituted vesicles is not increased by incubation in 1% Tween 80. Experiments on reconstituted vesicles containing internal (entrapped) cytochrome c indicate that turnover of enzyme oxidising entrapped cytochrome c in the presence of N,N,N′,N′-tetramethyl-p-phenylenediamine or 2,3,5,6-tetramethyl-p-phenylenediamine is at a very much lower rate than enzyme oxidising external ferrocytochrome c.3. Oxidation of ascorbate by externally added cytochrome c results in an electrogenic production of OH^? inside the vesicles, which can be monitored using entrapped phenol red. Polylysine inhibits, but does not abolish, the internal alkalinity change in reconstituted vesicles oxidising internal (entrapped) cytochrome c using externally added ascorbate plus N,N,N′,N′-tetramethyl-p-phenylenediamine. When 2,3,5,6-tetramethyl-p-phenylenediamine is used as the permeable redox mediator, an increase in internal acidity can be monitored under the same conditions.     

Occurrence of cytochrome aa3 in Anacystis nidulans

The cytochrome content of membrane fragments prepared from the bluegreen alga (cyanobacterium) Anacystis nidulans was examined by difference spectrophotometry. Two b-type cytochromes and a hitherto unknown cytochrome a could be characterized. In the reduced-minus-oxidised difference spectra the a-type cytochrome showed an α-band at 605 nm and a γ-band at 445 nm. These bands shifted to 590 and 430 nm, respectively, in CO difference spectra. NADPH, NADH and ascorbate reduced the cytochrome through added horse heart cytochrome c as electron mediator. In presence of KCN the reduced-minus-oxidised spectrum showed a peak at 600 nm and a trough at 604 nm. Photoaction spectra of O₂ uptake and of horse heart cytochrome c oxidation by CO-inhibited membranes showed peaks at 590 and 430 nm. These findings are consistent with cytochrome aa₃ being the predominant respiratory cytochrome c oxidase in Anacystis nidulans.     

Biochemical and biophysical studies on cytochrome c oxidase XVI. Circular dichroic study of cytochrome c oxidase and its ligand complexes

1. CD spectra of cytochrome c oxidase have been determined both in the absence and presence of the extrinsic ligands CO, NO, cyanide and azide.2. CO and NO affect the CD spectrum of cytochrome c oxidase in a similar way.3. Cyanide and azide also affect the CD spectrum of cytochrome c oxidase in a similar way, but distinctly different from CO and NO.4. From the CD spectra of the oxidized and reduced enzyme, in the presence and absence of extrinsic ligands, CD difference spectra (reduced minus oxidized) are calculated for the so-called cytochrome a and cytochrome a₃ moieties of the enzyme.5. These spectra are largely dependent on the extrinsic ligand used. It is therefore concluded that these spectra do not represent independent cytochrome a and cytochrome a₃ difference spectra, but that heme-heme interactions occur within the cytochrome c oxidase molecule, in such a way that binding of a ligand to one of the heme a groups of cytochrome c oxidase affects the spectral properties of the other heme a group.6. As a consequence, ligand-binding studies cannot give information as to the pre-existence of separate cytochrome a and cytochrome a₃ moieties in the absence of extrinsic ligands.     

Cytochrome c-cytochrome oxidase interaction at subzero temperatures

Cytochrome oxidase forms two distinctive compounds with oxygen at ?105 and ?90°C, one appears to be oxycytochrome oxidase (Compound A) and the other peroxycytochrome oxidase (Compound B). The functional role of compound B in the oxidation of cytochrome c has been examined in a variety of mitochondrial preparations. The rate and the extent of the reaction have been found to be dependent upon the presence of a fluid phase in the vicinity of the site of the reaction of cytochrome c and cytochrome oxidase. The kinetics of cytochrome c oxidation and of the slowly reacting component of cytochrome oxidase are found to be linked to one another even in cytochrome c depleted preparations, but under appropriate conditions, especially low temperatures, the oxidation of cytochrome c precedes that of this component of cytochrome oxidase. Based upon the identification of the slowly reacting components of cytochrome oxidase with cytochrome c, various mechanisms are considered which allow cytochrome c to be oxidized without the intervention of cytochrome a at very low temperatures, and tunneling seems an appropriate mechanism.     

Methionine-oxidized horse heart cytochromes c. I. Reaction with Chloramine-T,products, and their oxidoreduction properties

Spectroscopically, the modification of horse heart ferricytochrome c with N-chloro-4-toluolsul-fonamide (Chloramine-T, CT) occurs through a two-step process, the disruption of the methionine-80 sulfur-iron linkage and a reagent-independent change, an intramolecular rearrangement. Chromatographic purification of the preparation at a 2.5:1 reagent-to-protein ratio, pH 8.0–8.5, yields two major products, the F^II and F^III CT-cytochromes c. Both products contain modification of only the methionines, 80 and 65, to sulfoxides; both are monomeric, reduced by ascorbate, and the ferrous forms are oxidized by molecular oxygen and bind carbon monoxide. The redox potentials of F^II and F^III are 135 and 175±15 mV. The F^III is indistinguishable from the native protein in its binding and the electron donor property toward mammalian cytochrome c oxidase. It also binds nearly as effectively as the native protein to yeast cytochrome c peroxidase, but is a less efficient donor. It is, however, a poor electron acceptor from both mammalian cytochrome c reductase and chicken liver sulfite oxidase. F^II lacks cytochrome c oxidase activity and is also a poorer substrate for the other three enzymes. Both the derivatives are consistently better electron donors than acceptors. It is concluded that the binding of cytochrome c to cytochrome c oxidase and to cytochrome c peroxidase does not require the integrity of the methionine-80 sulfur linkage and that the complexation process has a finite degree of freedom with regard to the state of the heme crevice opening. The alterations of the oxidoreduction function have been analyzed in light of both prevailing models of cytochrome c function, the two-site model (one site for oxidizing and the other for reducing enzymes) and the single-site model (the same site for the oxidizing and reducing enzymes). These observations can be accommodated by either model, given the latitude that the binding domains for the oxidizing and the reducing enzymes have finite overlapping and nonoverlapping regions.     

Formamide probes a role for water in the catalytic cycle of cytochrome c oxidase

Formamide is a slow-onset inhibitor of mitochondrial cytochrome c oxidase that is proposed to act by blocking water movement through the protein. In the presence of formamide the redox level of mitochondrial cytochrome c oxidase evolves over the steady state as the apparent electron transfer rate from cytochrome a to cytochrome a₃ slows. At maximal inhibition cytochrome a and cytochrome c are fully reduced, whereas cytochrome a₃ and Cu_B remain fully oxidized consistent with the idea that formamide interferes with electron transfer between cytochrome a and the oxygen reaction site. However, transient kinetic studies show that intrinsic rates of electron transfer are unchanged in the formamide-inhibited enzyme. Formamide inhibition is demonstrated for another member of the heme-oxidase family, cytochrome c oxidase from Bacillus subtilis, but the onset of inhibition is much quicker than for mitochondrial oxidase. If formamide inhibition arises from a steric blockade of water exchange during catalysis then water exchange in the smaller bacterial oxidase is more open. Subunit III removal from the mitochondrial oxidase hastens the onset of formamide inhibition suggesting a role for subunit III in controlling water exchange during the cytochrome c oxidase reaction.     

CYANIDE-SENSITIVE BACTERIAL RESPIRATORY SYSTEMS DIFFERENT FROM THE USUAL CYTOCHROME-CYTOCHROME OXIDASE SYSTEM

Aerobic respiration of Streptococcus pyogenes and pneumococcus Type 1 are strongly inhibited by KCN, NaN₃, and Na₂S. The anaerobic glycolysis of glucose by pneumococcus is also inhibited by KCN and NaN₃. Streptococcus pyogenes, E. coli, pneumococcus Type 1, B. subtilis, B. proteus, and Staphylococcus aureus did not catalyze the oxygen uptake by p-phenylenediamine in the presence of added cytochrome c or in its absence. Yeast cells, B. subtilis, and B. pyocyaneus oxidized p-phenylenediamine to a dark purple meriquinoid substance in contrast to the other bacteria mentioned above. Streptococcus pyogenes in contrast to pneumococcus Type 1 catalyzed the oxygen uptake by cysteine. Neither of these bacteria catalyzed the oxygen uptake by tyrosine, adrenaline, pyrocatechin, xanthine, and hypoxanthine. Streptococcus pyogenes, pneumococcus Type 1, and E. coli, boiled and not boiled, gave positive peroxidative tests with benzidine showing the presence of hematin compounds. The results discussed in the light of the interpretations offered by Keilin and Harpley show that Streptococcus pyogenes and pneumococcus Type 1 contain cyanide-sensitive respiratory systems which are different from the cytochrome c-cytochrome oxidase system.     

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.     

Different reactivity of carboxylic groups of cytochrome c oxidase polypeptides from pig liver and heart

Cytochrome c oxidase isolated from pig liver and heart was incubated with 1-ethyl-3-[3-(dimethylamino) propyl]carbodiimide and [¹⁴C]glycine ethyl ester in the presence and absence of cytochrome c. Labelling of individual subunits was determined after separation of the enzyme complexes into 13 polypeptides by SDS-gel electrophoresis. Polypeptide II and additional but different polypeptides were labelled in the liver and in the heart enzyme. Labelling of polypeptide II and of some other polypeptides could be partially or completely suppressed by cytochrome c. From the data two conclusions can be drawn: In addition to polypeptide II, other polypeptides take part in the binding of cytochrome c to cytochrome c oxidase; the binding domain for cytochrome c is different in pig liver and heart cytochrome c oxidase.Cytochrome c oxidase isozymeCytochrome c binding domain1-Ethyl-3-(3-dimethylaminopropyl)carbodiimideTissue specificity