Tissue-specific differences between heart and liver cytochrome c oxidase

Bovine liver cytochrome c oxidase has been isolated and the subunit structure of this preparation compared with that of the bovine heart enzyme. Of the 10 nuclear-coded subunits, 3 were different in the 2 tissue forms, having different migrations in sodium dodecyl sulfate-polyacrylamide gel electrophoresis, different antigenicities to antibodies made against the heart subunits, and different N-terminal amino acid sequences. Subunit ASA of heart begins with the N-terminal sequence of SSG in liver and is different in 17 of the first 33 residues including a deletion of 2 residues in the liver isoform of this subunit. Subunit CVII of liver differs from its heart counterpart in 6 of the first 37 residues while subunit CIX from liver differs from the heart isoform in 15 of the first 25 residues. No differences between tissue types were observed in partial sequencing of the remaining nuclear-coded subunits. Recently, the major portion of the sequence of subunit CIX from rat liver has been obtained by cloning and sequencing of the cDNA for this polypeptide [Suske, G., Mengel, T., Cordingley, M., & Kadenbach, B. (1987) Eur. J. Biochem. 168, 233-237]. There is a greater sequence homology of the rat and bovine liver forms of CIX than there is between the bovine heart and liver isoforms.     

Kinetic mechanism of beef heart ubiquinol:cytochrome c oxidoreductase.

The electron transfer from ubiquinol-2 to ferricytochrome c mediated by ubiquinol:cytochrome c oxidoreductase [E.C. 1.10.2.2] purified from beef heart mitochondria, which contained one equivalent of ubiquinone-10 (Q10), was investigated under initial steady-state conditions. The Q10-depleted enzyme was as active as the Q10-containing one. Double reciprocal plots for the initial steady-state rate versus one of the two substrates at various fixed levels of the other substrate gave parallel straight lines in the absence of any product. Intersecting straight lines were obtained in the presence of a constant level of one of the products, ferrocytochrome c. The other product, ubiquinone-2, did not show any significant effect on the enzymic reaction. Ferrocytochrome c non-competitively inhibited the enzymic reaction against either ubiquinol-2 or ferricytochrome c. These results indicate a Hexa-Uni ping-pong mechanism with one ubiquinol-2 and two ferricytochrome c molecules as the substrates, which involves the irreversible release of ubiquinone-2 as the first product and the irreversible isomerization between the release of the first ferrocytochrome c and the binding of the second ferricytochrome c. Considering the cyclic electron transfer reaction mechanism, this scheme suggests that the binding of quinone or quinol to the enzyme and electron transfer between the iron-sulfur center and cytochrome c1 are rigorously controlled by the electron distribution within the enzyme.     

Sequence homologies and structural similarities between the polypeptides of yeast and beef heart cytochrome c oxidase

The homologous polypeptides in yeast and beef heart cytochrome c oxidase have been identified by sequence comparisons and structural similarities. The properties of individual polypeptides have been used to specify which components are extrinsic, and which intrinsic and bilayer spanning, in the cytochrome c oxidase complex.     

Properties of protease-treated cytochrome c oxidase from beef heart

Summary About 45% of the protein can be removed from oxidized cytochrome c oxidase by treatment with proteolytic enzymes under a variety of conditions, leading to an increased heme to protein ratio.The principal spectroscopic parameters of cytochrome c oxidase are retained in the protease-treated enzyme.Of the overall catalytic activity 20% remained after digestion; the electron-transfer reactions were impaired but the affinity for cytochrome c appeared unchanged.Proteolysis resulted in removal of the hydrophobic subunit III and most of the smaller hydrophilic subunits, leaving a core, which basically consists of the two largest subunits I and II.The subunits I and/or II carry the prosthetic groups of the enzyme and at least one of the cytochrome c binding sites. The smaller subunits, however, are essential for optimal electron transfer and possibly have other functions as well.     

Complex-formation between cytochrome c and cytochrome c peroxidase. Kinetic studies

1. The kinetics of ferrocytochrome c peroxidation by yeast peroxidase are described. Kinetic differences between the older and more recent preparations of the enzyme most probably arise from differences in intrinsic turnover rates. 2. The time-courses of cytochrome c peroxidation by the enzyme follow essentially first-order kinetics in phosphate buffer. Deviations from first-order kinetics occur in acetate buffer, and are due to a higher enzymic turnover rate in this medium accompanied by a greater tendency to autocatalytic peroxidation of cytochrome c. 3. The kinetics of ferrocytochrome c peroxidation by yeast peroxidase are interpreted in terms of a mechanism postulating formation of reversible complexes between the peroxidase and both reduced and oxidized cytochrome c. Formation of these complexes is inhibited at high ionic strengths and by polycations. 4. Oxidized cytochrome c can act as a competitive inhibitor of ferrocytochrome c peroxidation by peroxidase. The K(i) for ferricytochrome c is approximately equal to the K(m) for ferrocytochrome c and thus probably accounts for the observed apparent first-order kinetics even at saturating concentrations of ferrocytochrome c. 5. The results are discussed in terms of a possible analogy between the oxidations of cytochrome c catalysed by yeast peroxidase and by mammalian cytochrome oxidase.     

Electrophoretically monodisperse cytochrome c oxidases

A discontinuous gradient polyacrylamide gel electrophoresis under nondenaturing conditions has been used to demonstrate monodispersity of procaryotic and eucaryotic cytochrome c oxidase preparations. Alkaline treated bovine enzyme which contains nine subunits as analysed by subsequent discontinuous SDS-polyacrylamide gel electrophoresis is a monodisperse dimer in 0.1% Triton X-100 and a monomer in 0.1% dodecyl maltoside. The Mr-values corrected for bound detergent are 286,000 in Triton X-100 and 152,000 in dodecyl maltoside respectively. The two-subunit bacterial cytochrome c oxidase of Paracoccus denitrificans is proved to be a monomer with a corrected Mr of 76,000 in both nonionic detergents Triton X-100 and dodecyl maltoside.     

Topology of beef heart cytochrome c oxidase from studies on reconstituted membranes

The orientation of purified beef heart cytochrome c oxidase, incorporated into vesicles by the cholate dialysis procedure [Carroll, R.C., & Racker, E. (1977) J. Biol. Chem. 252, 6981], has been investigated by functional and structural approaches. The level of heme reduction obtained by using cytochrome c along with the membrane-impermeant electron donor ascorbate was 78 +/- 2% of that obtained with cytochrome c and the membrane-permeant reagent N,N,N',N'-tetramethyl-p-phenylenediamine. Electron transfer from cytochrome c is known to occur exclusively from the outer surface of the mitochondrial inner membrane (C side), implying that at least 78% of the oxidase molecules are oriented in the same way in these vesicles as in the intact mitochondria. Trypsin, which cleaves subunit IV near its N terminus, modifies only 5-7% of this subunit in intact vesicles. This removal of the N-terminal residues has been shown to occur only in mitochondrial membranes with their inner side (M side) exposed. Diazobenzene [35S]sulfonate [( 35S]DABS) likewise modifies subunit IV only in submitochondrial particles. Labeling of intact membranes with [35S]DABS resulted in incorporation of only 4-8% of the total counts that could be incorporated into this subunit in membranes made leaky to the reagent by addition of 2% Triton X-100. Therefore, both the functional and structural data show that at least 80% and probably more of the cytochrome c oxidase molecules are oriented with their C domain outermost and M domains in the lumen of vesicles prepared by the cholate dialysis method.(ABSTRACT TRUNCATED AT 250 WORDS)     

The absorbance coefficient of beef heart cytochrome c1

Isolated cytochrome c1 contains endogenous reducing equivalents. They can be removed by treating the protein with sodium dithionite followed by chromatography. This treatment has no effect on the reaction with cytochrome c, nor does it alter the optical spectrum, or the polypeptide or amino acid composition of the protein. Both the titration of dithionite-treated ferrocytochrome c1 with potassium ferricyanide and the anaerobic titration of dithionite-treated ferricytochrome c1 with NADH in the presence of phenazine methosulphate lead to the same value for the absorbance coefficient of cytochrome c1: 19.2 mM-1 . cm-1 at 552.4 nm for the reduced-minus-oxidised form. This value was also obtained when the haem content was determined by comparing the spectra of the reduced pyridine haemochromes of cytochrome c and cytochrome c1. Comparison of the optical spectra of cytochrome c and cytochrome c1 by integration shows equal transition moments for the transitions in the porphyrin systems of both proteins. A set of equations with which the concentration of the cytochromes aa3, b, c and c1 can be calculated from one reduced-minus-oxidised difference spectrum of a mixture of these proteins.     

The protein formula of beef heart cytochrome c oxidase

Beef heart cytochrome c oxidase consist of 12 different polypeptides stoichiometrically arranged in respiratory complex IV. The functional 2 heme a, 2 copper monomer of this complex consist of 1793 amino acids; the exact Mr is 202,787 Da. From 17 cysteine residues, six are involved in the formation of three disulphide bonds. The theoretical heme a content of the enzyme is 9.86 nmol/mg protein. The theoretical iron and copper contents are 0.55 and 0.63 microgram/mg protein, respectively.     

Kinetic characterization of the interaction between cytochrome oxidase and cytochrome c

The mechanism of electron transfer catalyzed by cytochrome oxidase was investigated by monitoring the reaction of cytochrome oxidase with cytochrome c under carefully controlled anaerobic conditions. The kinetics of the reaction were examined by varying conditions of ionic strength, inhibitor binding, and oxidation-reduction potential. An analogue of cytochrome c in which the iron atom was replaced with cobalt was used to probe the effect of redox potential on the reaction. Under conditions of low ionic strength, there is very rapid oxidation of cytochrome c and reduction of oxidase which occurs at a rate of 3 X 10(7) M-1 s-1. The number of electrons transferred exhibit a hyperbolic dependence on the concentration of cytochrome c reaching a maximum of 2 electrons transferred at the highest concentration of reduced cytochrome c employed. The total number of electrons transferred was always observed to be distributed equally between cytochrome a and a second acceptor which appears to be the associated copper center; electron transfer to cytochrome a3 did not occur in the absence of oxygen. Substitution of cytochrome c by the cobalt analogue (which represents a decrease in oxidation-reduction potential of about 400 mV) yielded identical results indicating that the origin of the lack of reactivity of cytochrome a3 is of a kinetic nature. The effect of increasing the ionic strength on the reaction was 2-fold: a marked decrease in reaction rate and the appearance of biphasic kinetics with the amplitude of the very fast absorbance changes at 605 nm decreasing from 80% to 40% of the total anticipated from static absorbance measurements. Each of the two phases accounted for a maximum of 1 electron at the highest ionic strength employed. These results are simulated in terms of a sample kinetic reaction scheme involving a two-step electron transfer at one binding site.     

Interaction of cytochrome c with cytochrome c oxidase. Photoaffinity labeling of beef heart cytochrome c oxidase with arylazido-cytochrome c.

Cytochrome c derivatives labeled with a 3-nitrophenylazido group at lysine 13, at lysine 22, or at both residues have been prepared. The interaction of the cytochrome c derivatives with beef heart cytochrome c oxidase (ferrocytochrome c:oxygen oxidoreductase, EC 1.9.3.1) in the presence of ultrviolet light results in formation of a covalent complex between cytochrome c and the oxidase. Using the lysine 22 derivative, the polypeptide composition of the oxidase is not modified, nor is its catalytic activity, whereas with the lysine 13 derivative, the gel electrophoretic pattern is altered and the catalytic activity of the complex diminished. The data are consisten with a specfic covalent interaction of the lysine 13 derivative of cytochrome c with the polypeptide of molecular weight 23,700 (Subunit II) of cytochrome c oxidase.     

Characterization of a seventh different subunit of beef heart cytochrome c oxidase. Similarities between the beef heart enzyme and that from other species.

Beef heart cytochrome c oxidase has been resolved into seven subunits by electrophoresis in highly cross-linked gels containing urea and sodium dodecyl sulfate. The molecular weights of the polypeptides are estimated to be I, 35 400; II, 24 100; III, 21 000; IV, 16 800; V, 12 400; VI, 8200; and VII, 4400. It has been shown that subunits II and III can coelectrophorese on standard sodium dodecyl sulfate-polyacrylamide gels and appear as a single component with an apparent molecular weight of 22 500. This accounts for previous reports that the beef heart enzyme contains only six subunits. Amino acid analysis of the isolated subunits I, II, and III revealed that they have polarities of 35.5, 44.7, and 39.9%, respectively. All three subunits have an extremely high leucine content and a low percentage of basic amino acids relative to subunits IV-VII. The size, number, and properties of subunits in the beef heart cytochrome c oxidase complex suggest that it has essentially the same subunit structure as the complexes isolated from Saccharomyces cerevisiae and Neurospora crassa.     

A structural model for the adduct between cytochrome c and cytochrome c oxidase

An ensemble of structural models of the adduct between cytochrome c and cytochrome c oxidase from Paracoccus denitrificans has been calculated based on the experimental data from site-directed mutagenesis and NMR experiments that have accumulated over the last years of research on this system. The residues from each protein that are at the protein–protein interface have been identified by the above experimental work, and this information has been converted in a series of restraints explicitly used in calculations. It is found that a single static structural model cannot satisfy all experimental data simultaneously. Therefore, it is proposed that the adduct exists as a dynamic ensemble of different orientations in equilibrium, and may be represented by a combination or average of the various limiting conformations calculated here. The equilibrium involves both conformations that are competent for electron transfer and conformations that are not. Long-range recognition of the partners is driven by non-specific electrostatic interactions, while at shorter distances hydrophobic contacts tune the reciprocal orientation. Electron transfer from cytochrome bc ₁ to cytochrome c oxidase is mediated through cytochrome c experiencing multiple encounters with both of its partners, only part of which are productive. The number of encounters, and thus the electron transfer rate, may be increased by the formation of a cytochrome bc ₁–cytochrome c oxidase supercomplex and/or (in human) by increasing the concentration of the two enzymes in the membrane space. Protein Data Bank Accession numbers The coordinates of the five best structural models for each of the four clusters have been deposited in the Protein Data Bank (PDB ID 1ZYY).     

Bovine cytochrome c oxidases,purified from heart,skeletal muscle,liver and kidney,differ in the small subunits but show the same reaction kinetics with cytochrome c

(1) Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate of purified cytochrome c oxidase preparations revealed that bovine kidney, skeletal muscle and heart contain different cytochrome c oxidase isoenzymes, which show differences in mobility of the subunits encoded by the nuclear genome. No differences in subunit pattern were observed between the oxidase preparations isolated from kidney and liver. (2) The kinetics of the steady-state reactions between bovine ferrocytochrome c and the four types of bovine cytochrome c oxidase preparation were compared under conditions of both high- and low-ionic strength. Also the pre-steady-state kinetics were studied. Only minor differences were observed in the electron-transfer activity of the isoenzymes. Thus, our experiments do not support the notion that the subunits encoded by the nuclear genome act as modulators conferring different activities to the isoenzymes of cytochrome c oxidase. (3) The cytochrome c oxidase preparation from bovine skeletal muscle was found to consist mainly of dimers, whereas the enzymes isolated from bovine kidney, liver and heart were monomeric.