Arrangement of the subunits in solubilized and membrane-bound cytochrome c oxidase from bovine heart.

The arrangement of the six cytochrome c oxidase subunits in the inner membrane of bovine heart mitochondria was investigated. The experiments were carried out in three steps. In the first step, exposed subunits were coupled to the membrane-impermeant reagent p-diazonium benzene [32S]sulfonate. In the second step, the membranes were lysed with cholate anc cytochrome c oxidase was isolated by immunoprecipitation. In the third step, the six cytochrome c oxidase subunits were separated from each other by dodecyl sulfate-acrylamide gel electrophoresis and scanned for radioactivity. Exposed subunits on the outer side of the mitochondrial inner membrane were identified by labeling intact mitochondria. Exposed subunits on the matrix side of the inner membrane were identified by labeling sonically prepared submitochondrial particles in which the matrix side of the inner membrane is exposed to the suspending medium. Since sonic irradiation leads to a rearrangement of cytochrome c oxidase in a large fraction of the resulting submitochondrial particles, an immunochemical procedure was developed for isolating particles with a low content of displaced cytochrome c oxidase. With mitochondria, subunits II, V, and VI were labeled, whereas in purified submitochondrial particles most of the label was in subunit III. The arrangement of cytochrome c oxidase in the mitochondrial inner membrane is thus transmembraneous and asymmetric; subunits II, V, and VI are situated on the outer side, subunit III is situated on the matrix side, and subunits I and IV are buried in the interior of the membrane. In a study of purified cytochrome c oxidase labeled with p-diazonium benzene [32S]sulfonate, the results were similar to those obtained with the membrane-bound enzyme. Subunits I and IV were inaccessible to the reagent, whereas the other four subunits were accessible. In contrast, all six subunits became labeled if the enzyme was dissociated with dodecyl sulfate before being exposed to the labeling reagent.     

Identification of cytochrome c oxidase subunits in nuclear yeast mutants lacking the functional enzyme.

Yeast mutants specifically lacking cytochrome c oxidase activity were screened for cytochrome c oxidase subunits by one- and two-dimensional electrophoresis, electrophoresis in exponential gradient gels, and immunoprecipitation with antisera against one or more of the cytoplasmically made subunits of the enzyme. Two cytochrome c oxidase-less nuclear mutants previously described from this laboratory each lack one or more mitochondrially synthesized cytochrome c oxidase subunits while possessing all four cytoplasmically synthesized subunits of that enzyme. The subunits remaining in these mutants were not assembled with each other; the cytoplasmically made subunits IV and VI could be released from the mitochondria by sonic oscillation, in contrast to the situation in wild type cells. No electrophoretically detectable alterations were found in any of the cytochrome c oxidase subunits present in the mutants. Nuclear mutations may thus cause both a loss as well as a defective assembly of mitochondrially made cytochrome c oxidase subunits.     

Cytochrome c oxidase from bakers' yeast. V. Arrangement of the subunits in the isolated and membrane-bound enzyme.

Cytochrome c oxidase from baker's yeast contains three mitochondrially made subunits (I to III) which are relatively hydrophobic and four cytoplasmically made subunits (IV to VII) which are relatively hydrophilic (Mason, T. L., Poyton, R. O., Wharton, D.C., and Schatz, G. (1973) J. Biol. Chem. 248, 1346-1354 and Poyton, R. O., and Schatz, G. (1975) J. Biol. Chem. 250, 752-761). In order to explore the arrangement of these subunits in the holoenzyme, the reactivity of each subunit with a variety of "surface probes" was tested with isolated cytochrome c oxidase, with cytochrome c oxidase incorporated into liposomes, and with mitochondrially bound cytochrome c oxidase. The surface probes included iodination with lactoperoxidase and coupling with p-diazonium benzenesulfonate. In addition, external subunits were identified by linking them to bovine serum albumin carrying a covalently bound isocyanate group. In the membrane-bound enzyme, Subunit I was almost completely inaccessible and Subunit II was partly inaccessible to all surface probes. All of the other subunits were accessible. Similar results were obtained with the solubilized enzyme, except that the differences in reactivity between the individual subunits were less clear-cut. The results obtained with liposome-bound cytochrome c oxidase resembled those obtained with the mitochondrially bound enzyme. These data suggest that the two largest mitochondrially made subunits are localized in the interior of the enzyme and that they are genuine components of cytochrome c oxidase.     

Near-neighbor relationships of the subunits of cytochrome c oxidase.

Cytochrome c oxidase in detergent dispersion has been cross-linked with two reversible cross-linking agents, dithiobissuccinimidylpropionate (DSP) and dimethyl-3,3'-dithiobispropionimidate (DTBP), and the cross-linked products formed have been analyzed by two-dimensional gel electrophoresis. Under mild reaction conditions, several subunit pairs were seen including II and V, V and VII, IV and VI. With higher levels of DSP, larger aggregates were seen until a cross-linked product with an apparent molecular weight of 140 000 was the predominant band on gels. This is the smallest molecular weight aggregate to contain all seven subunits of the enzyme and most likely represents the "unit" or two heme and two copper containing complex of cytochrome c oxidase.     

Studies on cytochrome oxidase. Interactions of the cytochrome oxidase protein with phospholipids and cytochrome c.

1. By the application of the principle of the sequential fragmentation of the respiratory chain, a simple-method has been developed for the isolation of phospholipid-depleted and phospholipid-rich cytochrome oxidase preparations. 2. The phospholip-rich oxidase contains about 20% lipid, including mainly phosphatidylethanolamine, phosphatidylcholine, and cardiolipin. Its enzymic activity is not stimulated by an external lipid such as asolectin. 3. The phospholipid-depleted oxidase contains less than 0.1% lipid. It is enzymically inactive in catalyzing the oxidation of reduced cytochrome c by molecular oxygen. This activity can be fully restored by asolectin; and partially restored (approximately 75%) by purified phospholipids individually or in combination. The activity can be partially restored also by phospholipid mixtures isolated from mitochondria, from the oxidase itself, and from related preparations. Among the detergents tested only Emasol-1130 and Tween 80 show some stimulatory activity. 4. The phospholipid-depleted oxidase binds with cytochrome c evidently by "protein-protein" interactions as does the phospholipid-rich or the phospholipid-replenished oxidase to form a complex with the ratio of cytochrome c to heme a of unity. The complex prepared from phospholipid-depleted cytochrome oxidase exhibits a characteristic Soret absorption maximum at 415 nm in the difference spectrum of the carbon monoxide-reacted reduced form minus the reduced form. This 415-nm maximum is abolished by the replenishment of the complex with a phospholipid or by the dissociation of the complex in cholate or in a medium of high ionic strength. When ascorbate is used as an electron donor, the complex prepared from phospholipid-depleted cytochrome oxidase does not cause the reduction of cytochrome a3 which is in dramatic contrast to the complex from the phospholipid-rich or the phospholipid-replenished oxidase. However, dithionite reduces cytochrome a3 in all of the preparations of the cytochrome c-cytochrome oxidase complex. These facts suggest that the action of phospholipid on the electron transfer in cytochrome oxidase may be at the step between cytochromes a and a3. This conclusion is substantiated by preliminary kinetic results that the electron transfer from cytochrome a to a3 is much slower in the phospholipid-depleted than in phospholipid-rich or phospholipid-replenished oxidase. On the basis of the cytochrome c content, the enzymic activity has been found to be about 10 times higher in the system with the complex (in the presence of the replenishedhe external medium unless energy is provided, and that     

Structure of the copper sites in membrane-bound cytochrome c oxidase

The structures of membrane proteins are difficult to obtain by crystallography and may be altered by the detergents used in their extraction. X-ray absorption spectroscopy has been used to identify the structures of the copper atoms of the membrane-bound enzyme in mitochondria and in submitochondrial particles at respective concentrations of 100 and 200 micron of molar copper. To within the experimental error, the x-ray absorption spectra of the copper atoms of the membrane-bound and the Yonetani (Yonetani, T. (1961) J. Biol. Chem. 236, 1680-1688) purified oxidase are identical; all detectable shells of the active site indicate no alteration of structural parameters. Significant differences are found when compared to the Hartzell-Beinert (Hartzell, R. C., and Beinert, H. (1974) Biochim. Biophys. Acta 368, 318-338) preparation. Extended x-ray absorption fine structure technology is now adequate for the direct studies of membrane proteins in situ in their natural environment.     

Models of protein lateral arrangements in lipid bilayer membranes. Application to electron spin resonance studies of cytochrome c oxidase

We consider the situation of integral membrane proteins in a lipid bilayer matrix where the size of the polar group of the protein is important in determining the lateral packing of the proteins. We represent the cross-section of the protein hydrophobic core as a hexagon moving on a lattice, and represent the projection of the polar group onto the plane of the bilayer as a shape, parts of which overlap the hexagon. Lattice sites represent lipid molecules. We calculate the fraction of lipid molecules which are adjacent to the hydrophobic core of at least one protein. We use this data to consider the "motion restricted" spectrum observed in electron spin resonance (ESR) probe studies, and compute the dependence of the "motion restricted" fraction upon protein concentration. The resulting curves can be used to analyse ESR data in order to deduce the size and shape of the proteins' polar segment. We have used the range of models examined to study the dependence upon protein concentration of the particular case of the "motion restricted" spectrum of a spin-labelled lipid freely diffusing or, alternatively, covalently bound to cytochrome c oxidase. We find that our calculations are in accord with a model where approximately 60 lipid molecules can fit around an isolated such protein in both halves of the bilayer, and where the polar segment is substantially anisotropic and extends laterally beyond the limits of the hydrophobic core. The latter is in accord with what is known about the structure of cytochrome c oxidase. We indicate further measurements that should be performed in order to establish more definitively the dependence of the "motion restricted" component upon protein concentration, giving the lipid protein ratios at which they should be performed, and we make predictions concerning the results. Finally we argue for a particular unified way of plotting experimental data.     

Topology of subunits of the mammalian cytochrome c oxidase: relationship to the assembly of the enzyme complex.

The arrangement of three subunits of beef heart cytochrome c oxidase, subunits Va, VIa, and VIII, has been explored by chemical labeling and protease digestion studies. Subunit Va is an extrinsic protein located on the C side of the mitochondrial inner membrane. This subunit was found to label with N-(4-azido-2-nitrophenyl)-2-aminoethane[35S]sulfonate and sodium methyl 4-[3H]formylphenyl phosphate in reconstituted vesicles in which 90% of cytochrome c oxidase complexes were oriented with the C domain outermost. Subunit VIa was cleaved by trypsin both in these reconstituted vesicles and in submitochondrial particles, indicating a transmembrane orientation. The epitope for a monoclonal antibody (mAb) to subunit VIa was lost or destroyed when cleavage occurred in reconstituted vesicles. This epitope was localized to the C-terminal part of the subunit by antibody binding to a fusion protein consisting of glutathione S-transferase (G-ST) and the C-terminal amino acids 55-85 of subunit VIa. No antibody binding was obtained with a fusion protein containing G-ST and the N-terminal amino acids 1-55. The mAb reaction orients subunit VIa with its C-terminus in the C domain. Subunit VIII was cleaved by trypsin in submitochondrial particles but not in reconstituted vesicles. N-Terminal sequencing of the subunit VIII cleavage product from submitochondrial particles gave the same sequence as the untreated subunit, i.e., ITA, indicating that it is the C-terminus which is cleaved from the M side. Subunits Va and VIII each contain N-terminal extensions or leader sequences in the precursor polypeptides; subunit VIa is made without an N-terminal extension.     

Studies of the kinetics of oxidation of cytochrome c by cytochrome c oxidase: comparison of the reactions of purified and membrane-bound oxidase

l-Asparaginase (EC 3.5.1.1.) activity has been detected in crude extracts of Lupinus arboreus young leaves, root tips, flower buds, and developing seeds. The enzyme was also present in Lupinus angustifolius root tips, developing nodules, and developing seeds. The asparaginase from each of these tissues had the same electrophoretic mobility on polyacrylamide gels and a K_m of 6–8 mm for asparagine. In extracts other than those of the developing seeds, asparaginase activity was dependent upon the inclusion of K⁺ ion and a sulfhydryl protectant in the extraction buffer. No asparaginase activity was detected in mature leaves, in the plant fraction of nodules that were fixing nitrogen, nor in root tissue further than 1.5 cm from the root tip. Asparaginase has been purified 326- and 230-fold from L. arboreus and L. angustifolius developing seeds, respectively. A molecular weight of 75,000 was obtained by gel filtration. An apparent K_m of 6.6 and 7.0 mm for asparagine was determined for the purified L. arboreus and L. angustifolius asparaginases, respectively. Of the amides, nitriles, and hydroxamates examined, the L. arboreus enzyme hydrolyzed only l-asparagine and dl-aspartyl hydroxamate. This same enzyme was inhibited by d-asparagine, 5-diazo-4-oxo-l-norvaline, dl-aspartyl hydroxamate, d-and l-aspartate, 3-cyano-l-alanine, glycine, and cysteine. Glutamine, glutamine analogs, and a number of other amino acids, amides and amines did not inhibit the L. arboreus asparaginase.     

Reversible redox titrations of cytochrome c and cytochrome c oxidase using detergent solubilized electrochemically generated mediator-titrants

The repetitive, $\text{reversible}$ equilibrium redox cycling of cytochrome $\text{c}$, cytochrome $\text{c}$ oxidase, or mixtures thereof has been made possible by the use of the oxidant, ferricinium ion. This ion is electrochemically generated by the use of non-ionic detergent solubilized ferrocene which is apparently incorporated as micelles and readily electron transfers with an electrode. The $\text{ferricinium-ferrocene}$ couple equilibrates rapidly with these heme proteins. Electrochemically generated benzylviologen radical cations are used as the reductant. The E^O′ values for cytochrome $\text{c}$ oxidase at pH 7.0 are 209 ± 15 mv (2e^?) and 340 ± 15 mv (2e^?).     

Kinetic studies on the reaction between cytochrome c oxidase and ferrocytochrome c.

In stopped-flow experiments in which oxidized cytochrome c oxidase was mixed with ferrocytochrome c in the presence of a range of oxygen concentrations and in the absence and presence of cyanide, a fast phase, reflecting a rapid approach to an equilibrium, was observed. Within this phase, one or two molecules of ferrocytochrome were oxidized per haem group of cytochrome a, depending on the concentration of ferrocytochrome c used. The reasons for this are discussed in terms of a mechanism in which all electrons enter through cytochrome a, which, in turn, is in rapid equilibrium with a second site, identified with 'visible' copper (830 nm-absorbing) Cud (Beinert et al., 1971). The value of the bimolecular rate constant for the reaction between cytochromes c2+ and a3+ was between 10(6) and 10(7) M(-1)-S(-1); some variability from preparation to preparation was observed. At high ferrocytochrome c concentrations, the initial reaction of cytochrome c2+ with cytochrome a3+ could be isolated from the reaction involving the 'visible' copper and the stoicheiometry was found to approach one molecule of cytochrome c2+ oxidized for each molecule of cytochrome a3+ reduced. At low ferrocytochrome c concentrations, however, both sites (i.e. cytochrome a and Cud) were reduced simultaneously and the stoicheiometry of the initial reaction was closer to two molecules of cytochrome c2+ oxidized per molecule of cytochrome a reduced. The bleaching of the 830 nm band lagged behind or was simultaneous with the formation of the 605 nm band and does not depend on the cytochrome c concentration, whereas the extinction at the steady-state does. The time-course of the return of the 830 nm-absorbing species is much faster than the bleaching of the 605 nm-absorbing component, and parallels that of the turnover phase of cytochrome c2+ oxidation. Additions of cyanide to the oxidase preparations had no effect on the observed stoicheiometry or kinetics of the reduction of cytochrome a and 'visible' copper, but inhibited electron transfer to the other two sites, cytochrome a3 and the undetectable copper, Cuu.     

Evolutionary analysis of the nucleus-encoded subunits of mammalian cytochrome c oxidase.

The cytochrome c oxidase enzyme complex of eukaryotes is made up of three mitochondrial-coded subunits and a variable number of nuclear-coded subunits. Some nuclear-coded subunits are present in multiple forms and probably perform a tissue- or development-specific function. A detailed evolutionary analysis of the cytochrome c oxidase subunits that have been sequenced to date is reported here. We have found that gene duplication events from which the liver and heart isoforms of rat subunits VIa and subunit VIII originated can both be dated at about 240 +/- 90 million years ago, long before the radiation of mammalian lineages. Sequence divergence between the processed-type pseudogenes for the subunits IV, VIc and VIII have been estimated. Our results indicate that they arose fairly recently, thus suggesting that retroposition is a continuing process. We show that the rate of silent substitution in mitochondrial-coded subunits is 5-10 times higher than in nuclear-coded subunits; on the other hand replacement rates, although differing from gene to gene, are roughly of the same order of magnitude in both nuclear and mitochondrial genes. In the case of most of the nuclear-coded proteins we observed a slightly greater similarity between rats and cow, which agrees with the data obtained for mitochondrial-coded subunits.     

The effect of oxygen concentration on the steady-state kinetics of the solubilized cytochrome c oxidase.

1. The steady-state kinetics of ascorbate oxidation as a function of oxygen concentration was measured with a solubilized cytochrome c oxidase (ferrocytochrome c:oxygen oxidoreductase, EC 1.9.3.1) preparation. 2. Linear double reciprocal plots were obtained at various fixed concentrations of ascrobate, cytochrome c and cytochrome aa3. 3. The results are interpreted in terms of an oxidase model similar to that put forward by Minnaert in 1961 (Minnaert, K. (1961) Biochim. Biophys. Acta 50, 23-34). 4. The Km for oxygen at infinite cytochrome c concentration is 0.95 muM and the intramolecular rate constant for the transfer of electrons from cytochrome c to cytochome aa3 is 400 s(-1). According to the model, this implies that the second order rate constant for the reaction between oxygen and the oxidase is 9.5 X 10(7)M(-1)-s(-1).