Structure of an electron transfer complex. II. Chemical modification of carboxyl groups of cytochrome c peroxidase in presence and absence of cytochrome c

Cytochrome c peroxidase forms an electron transfer complex with cytochrome c. The complex is governed by ionic bonds between side chain amino groups of cytochrome c and carboxyl groups of peroxidase. To localize the binding site for cytochrome c on the peroxidase, we have used the method of differential chemical modification. By this method the chemical reactivity of carboxyl groups (toward carbodiimide/aminoethane sulfonate) was compared in free and in complexed peroxidase. When ferricytochrome c was bound to cytochrome c peroxidase, acidic residues 33, 34, 35, 37, 221, 224, and 1 to 3 carboxyls at the C terminus became less reactive by a factor of approximately 4, relative to the remaining 39 carboxylates of peroxidase. Of the less reactive residues those in the 30-40 region and the 221/224 pair are on opposite sides of the surface area which contains the heme propionates. We, therefore, propose that the binding site for cytochrome c on cytochrome c peroxidase spans the area where one heme edge comes close to the molecular surface. The results are in very good agreement with chemical cross-linking studies (Waldmeyer, B., and Bosshard, H.R. (1985) J. Biol. Chem. 260, 5184-5190); they also support a hypothetical model predicted on the basis of the known crystal structures of cytochrome c and peroxidase (Poulos, T.L., and Kraut, J. (1980) J. Biol. Chem. 255, 10322-10330).     

Spectroscopic analysis of the interaction between cytochrome c and cytochrome c oxidase

Complex formation between cytochrome c oxidase and cytochrome c perturbs the optical absorption spectrum of heme c and heme a in the region of the alpha-, beta, and gamma-bands. The perturbations have been used to titrate cytochrome c oxidase with cytochrome c. A stoichiometry of one molecule of cytochrome c bound per molecule of cytochrome c oxidase is obtained (1 heme c per heme aa3). In contrast, a stoichiometry of 2:1 was found earlier using a gel-filtration method (Rieder, R., and Bosshard, H.R. (1978) J. Biol. Chem. 253, 6045-6053). From the result of the spectrophotometric titration and from the wavelength position of the perturbation signals it is concluded that cytochrome c oxidase contains only a single binding site for cytochrome c which is close enough to heme a to function as an electron transfer site. The second site detected earlier by the gel-filtration method must be remote from this electron transfer site. Scatchard plots of the titration data are curvilinear, possibly indicating interactions between cytochrome c-binding sites on adjacent monomers of dimeric cytochrome c oxidase. The relationship between cytochrome c binding and the reaction of cytochrome c oxidase with ferrocytochrome c is discussed.     

The mechanisms of inactivation of sulfite oxidase by periodate and arsenite.

The inactivation of sulfite oxidase, a molybdoenzyme containing the Mo cofactor, by arsenite and periodate was investigated. In contrast to ferricyanide (Gardlik, S., and Rajagopalan, K.V. (1991) J. Biol. Chem. 266, 4889-4895), neither of these reagents causes oxidation of the pterin ring of the Mo cofactor. Instead, inactivation by these reagents appears to involve attack on sulfhydryl groups at the active site of the enzyme. The inactivation of sulfite oxidase by arsenite was shown to be dependent on the presence of O2 and on the enzymatic oxidation of arsenite to arsenate. The inactivation was preventable by the presence of sulfite, or by the use of cytochrome c as the electron acceptor instead of O2. It is concluded that inactivation by arsenite is the result of arsenite displacement of Mo during enzymatic oxidation of arsenite to arsenate, when Mo transiently breaks its bond to protein or molybdopterin sulfhydryl(s) in order to provide a site for transfer of electrons to O2. Data indicate that arsenite is properly oriented to displace Mo only once every 20,800 turnovers, thus accounting for the slow rate of inactivation by this reagent. Inactivation of sulfite oxidase by periodate is believed to occur as the result of direct attack of periodate on the thiolate ligands of Mo, either those of the protein and/or molybdopterin, leading to Mo loss. Treatment of enzyme with even low levels of periodate resulted in loss of Mo and both sulfite:cytochrome c and sulfite:O2 activities. Molybdopterin of periodate-inactivated enzyme retained the ability to reconstitute nitrate reductase apoprotein in nit-1 extracts and the ability to reduce dichlorophenolindophenol, indicating that the pterin ring had not been oxidized.     

Proton NMR and electrophoretic studies of the covalent complex formed by cross-linking yeast cytochrome c peroxidase and horse cytochrome c with a water-soluble carbodiimide

The 1:1 covalently cross-linked complex between horse cytochrome c and yeast cytochrome c peroxidase (ccp) has been formed by a slight modification of the method of Waldmeyer and Bosshard [Waldmeyer, B., & Bosshard, H. R. (1985) J. Biol. Chem. 260, 5184-5190]. This earlier study has been extended to show that efficient cross-linking of the two proteins can occur in a variety of buffers over a broad ionic strength range. The substitution of ferrocytochrome c for ferricytochrome c in the cross-linking studies resulted in an increased yield of 1:1 complex (approximately 10-20%) under the conditions studied. An improved method for purifying the covalent complex in relatively large quantities is presented here as are the results of electrophoresis and proton NMR studies of the complex. Both electrophoresis and NMR studies indicate modification of some surface acidic amino acids in the covalent complex by the carbodiimide. The proton hyperfine-shifted resonances of cytochrome c are broadened in the covalent complex relative to free cytochrome c, and the resonances corresponding to the cytochrome c heme 3-CH3 and 8-CH3 groups are shifted closer together in the complex. Integration of NMR resonances confirms a 1:1 complex as the primary cross-linking reaction product. However, we also demonstrate that the covalent complex can be further coupled to ccp and to cytochrome c to form higher molecular weight aggregates.     

Binding of arylazidocytochrome c derivatives to beef heart cytochrome c oxidase: cross-linking in the high- and low-affinity binding sites

Two arylazidocytochrome c derivatives, one modified at lysine-13 and the second modified at lysine-22, were reacted with beef heart cytochrome c oxidase. The lysine-13 modified arylazidocytochrome c was found to cross-link both to the enzyme and with lipid bound to the cytochrome c oxidase complex. The lysine-22 derivative reacted only with lipids. Cross-linking to protein was through subunit II of the cytochrome c oxidase complex, as first reported by Bisson et al. [Bisson, R., Azzi, A., Gutweniger, H., Colonna, R., Monteccuco, C., & Zanotti, A. (1978) J. Biol. Chem. 253, 1874]. Binding studies show that the cytochrome c derivative covalently bound to subunit II was in the high-affinity binding site for the substrate. Evidence is also presented to suggest that cytochrome c bound to the lipid was in the low-affinity binding site [as defined by Ferguson-Miller et al. [Ferguson-Miller, S., Brautigan, D. L., & Margoliash, E. (1976) J. Biol. Chem. 251, 1104]]. Covalent binding of the cytochrome c derivative into the high-affinity binding site was found to inhibit electron transfer even when native cytochrome c was added as a substrate. Inhibition was almost complete when 1 mol of the Lys-13 modified arylazidocytochrome c was covalently bound to the enzyme per cytochrome c oxidase dimer (i.e., congruent to 280 000 daltons). Covalent binding of either derivative with lipid (low-affinity site) had very little effect on the overall electron transfer activity of cytochrome c oxidase. These results are discussed in terms of current theories of cytochrome c-cytochrome c oxidase interactions.     

Spectra of intermediates in oxidation and reduction of cytochrome c oxidase

Two kinetic components with distinct difference spectra occur during reduction of cytochrome c oxidase by ruthenium hexamine. They are attributed to reduction of heme a (fast phase) and heme a3 (slow phase) (Scott, R. A., and Gray, H. B. (1980) J. Am. Chem. Soc. 102, 3219-3774). Two spectra seen during oxidation of cytochrome c oxidase by molecular oxygen have also been attributed to oxidation of hemes a3 and a (Greenwood, C., and Gibson, Q. H. (1967) J. Biol. Chem. 242, 1782-1787). We now report that spectra for the reductive and oxidative reactions obtained with the same preparations and the same apparatus under similar conditions are significantly different. The reactions appear to populate different reaction intermediates. Reconstitution into phospholipid vesicles does not affect these two spectra significantly. During turnover, the chief intermediates are those of the reductive pathway (Scott and Gray type intermediates). Reduction of heme a3 occurs approximately 70 times faster after turnover than the reduction of the resting enzyme. This is probably a dramatic "pulsing" effect (Wilson, M. T., Peterson, J., Antonini, E., Brunori, M., Colosimo, A., and Wyman, J. (1981) Proc. Natl. Acad. Sci. U.S.A. 7115-7118).     

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.     

The oxygen reactions of reduced cytochrome c oxidase. Position of a form with an unusual EPR signal in the sequence of early intermediates.

The order of appearance of intermediates in the reoxidation of reduced cytochrome c oxidase by oxygen has been examined. Particular emphasis was placed on determining where the intermediate with the EPR signal at g = 5, 1.78, 1.69 (Shaw, R.W., Hansen, R.E. and Beinert, H. (1978) J. Biol. Chem. 253, 6637--6640) appears in the sequence of events during reoxidation. Flash photolysis of reduced, CO-complexed samples of cytochrome c oxidase in the presence of oxygen in a buffer containing 30% (v/v) ethylene glycol at 77 K and 195 K has been used to generate states of partial reoxidation. The intermediate with the EPR signal at g = 5, 1.78, and 1.69 can be detected as a product of the photolysis and subsequent oxidation but does not appear until the photolyzed sample is incubated at temperatures well above 196 K. In the course of the reoxidation, the intermediate characterized by the g = 5, 1.78, 1.69 signal occurs in the reaction sequence after the states referred to as 'Compound A' and 'Compound B' (Chance, B., Saronio, C., and Leigh, J.S. (1975) J. Biol. Chem. 250, 9226--9237). Its appearance is within the time range reported for the formation of 'oxygenated' cytochrome c oxidase (Orii, Y. (1979) in Cytochrome Oxidase (King, T.E., Orii, Y., Chance, B. and Okunuki, K., eds.), pp. 331--340, Elsevier/North-Holland Biomedical Press, Amsterdam).     

Oxidation of molybdopterin in sulfite oxidase by ferricyanide. Effect on electron transfer activities

The attenuation of the sulfite:cytochrome c activity of sulfite oxidase upon treatment with ferricyanide was demonstrated to be the result of oxidation of the pterin ring of the molybdenum cofactor in the enzyme. Oxidation of molybdopterin (MPT) was detected in several ways. Ferricyanide treatment not only abolished the ability of sulfite oxidase to serve as a source of MPT to reconstitute the aponitrate reductase in extracts of the Neurospora crassa mutant nit-1 but also eliminated the ability of sulfite oxidase to reduce dichlorobenzenoneindophenol after anaerobic denaturation. Additionally, the absorption spectrum of anaerobically denatured ferricyanide-treated molybdenum fragment of rat liver sulfite oxidase was typical of fully oxidized pterins. Ferricyanide treatment had no effect on the protein of sulfite oxidase or on the sulfhydryl-containing side chain of MPT. Quantitation of the ferricyanide reaction showed that 2 mol of ferricyanide were reduced per mol of MPT oxidized, yielding a fully oxidized pterin. These results corroborate the previously reported conclusion that the native state of reduction of MPT in sulfite oxidase is at the dihydro level (Gardlik, S., and Rajagopalan, K.V. (1990) J. Biol. Chem. 265, 13047-13054). As a result of oxidation of the pterin ring, the affinity of MPT for molybdenum is decreased, leading to eventual loss of molybdenum. Because the loss of molybdenum is slow, a population of sulfite oxidase molecules can exist in which molybdenum is complexed to oxidized MPT. These molecules retain sulfite:O2 activity, a function apparently dependent solely on the molybdenum-thiolate complex, yet have greatly decreased sulfite:cytochrome c activity, a function requiring heme as well as the molybdenum center of holoenzyme. These observations suggest that the pterin ring of MPT participates in enzyme function, possibly in electron transfer, directly in catalysis, or by controlling the oxidation/reduction potential of molybdenum.     

ATP induces conformational changes in mitochondrial cytochrome c oxidase. Effect on the cytochrome c binding site

ATP influences the kinetics of electron transfer from cytochrome c to mitochondrial oxidase both in the membrane-embedded and detergent-solubilized forms of the enzyme. The most relevant effect is on the so-called "high affinity" binding site for cytochrome c which can be converted to "low affinity" by millimolar concentrations of ATP (Ferguson-Miller, S., Brautigan, D. L., and Margoliash, E. (1976) J. Biol. Chem. 251, 1104-1115). This phenomenon is characterized at the molecular level by the following features. ATP triggers a conformational change on the water-exposed surface of cytochrome c oxidase; in this process, carboxyl groups forming the cluster of negative charges responsible for binding cytochrome c change their accessibility to water-soluble protein modifier reagents; as a consequence the electrostatic field that controls the enzyme-substrate interaction is altered and cytochrome c appears to bind differently to oxidase; photolabeling experiments with the enzyme from bovine heart and other eukaryotic sources show that ATP cross-links specifically to the cytoplasmic subunits IV and VIII. Taken together, these data indicate that ATP can, at physiological concentration, bind to cytochrome c oxidase and induce an allosteric conformational change, thus affecting the interaction of the enzyme with cytochrome c. These findings raise the possibility that the oxidase activity may be influenced by the cell environment via cytoplasmic subunit-mediated interactions.     

Orientation of cytochrome c oxidase molecules in the two populations of reconstituted vesicles resolved by column chromatography on DEAE-Sephacryl

Vesicles reconstituted with bovine heart cytochrome c oxidase and dioleoylphosphatidylcholine can be resolved into two populations by column chromatography in DEAE-Sephacryl (Madden, T.D. and Cullis, P.R. (1984) J. Biol. Chem. 259, 7655-7658). These two fractions (I and II) were treated with two proteases. These are trypsin, which has been found to cleave subunit IV in the M domain of the cytochrome c oxidase molecule, and chymotrypsin, which has been found to cleave subunit III in the C domain. These studies show that fraction I vesicles contain cytochrome c oxidase orientation with the M domain outside, i.e., in the same topology as in submitochondrial particles, while fraction II vesicles contain enzyme molecules with their C domain outside, and thus in the same orientation as in mitochondria.     

Existence of a new type of sulfite oxidase which utilizes ferric ions as an electron acceptor in Thiobacillus ferrooxidans

A new type of sulfite oxidase which utilizes ferric ion (Fe3+) as an electron acceptor was found in iron-grown Thiobacillus ferrooxidans. It was localized in the plasma membrane of the bacterium and had a pH optimum at 6.0. Under aerobic conditions, 1 mol of sulfite was oxidized by the enzyme to produce 1 mol of sulfate. Under anaerobic conditions in the presence of Fe3+, sulfite was oxidized by the enzyme as rapidly as it was under aerobic conditions. In the presence of o-phenanthroline or a chelator for Fe2+, the production of Fe2+ was observed during sulfite oxidation by this enzyme under not only anaerobic conditions but also aerobic conditions. No Fe2+ production was observed in the absence of o-phenanthroline, suggesting that the Fe2+ produced was rapidly reoxidized by molecular oxygen. Neither cytochrome c nor ferricyanide, both of which are electron acceptors for other sulfite oxidases, served as an electron acceptor for the sulfite oxidase of T. ferrooxidans. The enzyme was strongly inhibited by chelating agents for Fe3+. The physiological role of sulfite oxidase in sulfur oxidation of T. ferrooxidans is discussed.     

Existence of a new type of sulfite oxidase which utilizes ferric ions as an electron acceptor in Thiobacillus ferrooxidans.

A new type of sulfite oxidase which utilizes ferric ion (Fe3+) as an electron acceptor was found in iron-grown Thiobacillus ferrooxidans. It was localized in the plasma membrane of the bacterium and had a pH optimum at 6.0. Under aerobic conditions, 1 mol of sulfite was oxidized by the enzyme to produce 1 mol of sulfate. Under anaerobic conditions in the presence of Fe3+, sulfite was oxidized by the enzyme as rapidly as it was under aerobic conditions. In the presence of o-phenanthroline or a chelator for Fe2+, the production of Fe2+ was observed during sulfite oxidation by this enzyme under not only anaerobic conditions but also aerobic conditions. No Fe2+ production was observed in the absence of o-phenanthroline, suggesting that the Fe2+ produced was rapidly reoxidized by molecular oxygen. Neither cytochrome c nor ferricyanide, both of which are electron acceptors for other sulfite oxidases, served as an electron acceptor for the sulfite oxidase of T. ferrooxidans. The enzyme was strongly inhibited by chelating agents for Fe3+. The physiological role of sulfite oxidase in sulfur oxidation of T. ferrooxidans is discussed.     

Studies on cytochrome c oxidase activity of the cytochrome c1aa3 complex from Thermus thermophilus

Cytochrome oxidase from T. thermophilus is isolated as a noncovalent complex of cytochromes c1 and aa3 in which the four redox components of aa3 appear to be associated with a single approximately 55,000-D subunit while the heme C is associated with a approximately 33,000-D peptide (Yoshida, T., Lorence, R. M., Choc, M. G., Tarr, G. E., Findling, K. L., and Fee, J. A. (1983) J. Biol. Chem. 258, 112-123). We have examined the steady state transfer of electrons from ascorbate to oxygen by cytochrome c1aa3 as mediated by horse heart, Candida krusei, and T. thermophilus (c552) cytochromes c as well as tetramethylphenylenediamine (TMPD). These mediators exhibit simple Michaelis-Menten kinetic behavior yielding Vmax and KM values characteristic of the experimental conditions. Three classes of kinetic behavior were observed and are qualitatively discussed in terms of a reaction scheme. The data show that tetramethylphenyldiamine and cytochromes c react with the enzyme at independent sites; it is suggested that cytochrome c1 may efficiently transfer electrons to cytochrome aa3. When incorporated into phospholipid vesicles, the highly purified cytochrome c1aa3 was found to translocate one proton into the exterior medium for each molecule of cytochrome c552 oxidized. The combined results suggest that this bacterial enzyme functions in a manner generally identical with the more complex eucaryotic enzyme.     

Evidence for a three-iron center in a ferredoxin from Desulfovibrio gigas. M?ssbauer and EPR studies

The tetrameric form of a Desulfovibrio gigas ferredoxin, named Fd II, mediates electron transfer between cytochrome c3 and sulfite reductase. We have studied two stable oxidation states of this protein with M?ssbauer spectroscopy and electron paramagnetic resonance. We found 3 iron atoms/monomer and a spin concentration of 0.9 spins/monomer for the oxidized protein. Taken together, the EPR and M?ssbauer data demonstrate conclusively the presence of a spin-coupled structure containing 3 iron atoms and labile sulfur. The M?ssbauer data show also that this metal center is structurally similar, if not identical, with the low potential center of a ferredoxin from Azotobacter vinelandii, a novel cluster described recently (Emptage, M.H., Kent, T.A., Huynh, B.H., Rawlings, J., Orme-Johnson, W.H., and Münck, E. (1980) J. Biol. Chem. 255, 1793-1796).     

Cytochrome c binding affects the conformation of cytochrome a in cytochrome c oxidase.

Second derivative absorption spectroscopy has been used to assess the effects of complex formation between cytochrome c and cytochrome c oxidase on the conformation of the cytochrome a cofactor. When ferrocytochrome c is complexed to the cyanide-inhibited reduced or mixed valence enzyme, the conformation of ferrocytochrome a is affected. The second derivative spectrum of these enzyme forms displays two electronic transitions at 443 and 451 nm before complex formation, but only the 443-nm transition after cytochrome c is bound. This effect is not induced by poly-L-lysine, a homopolypeptide which is known to bind to the cytochrome c binding domain of cytochrome c oxidase. The effect is limited to cyanide-inhibited forms of the enzyme; no effect was observed for the fully reduced unliganded or fully reduced carbon monoxide-inhibited enzyme. The spectral signatures of these changes and the fact that they are exclusively associated with the cyanide-inhibited enzyme are both reminiscent of the effects of low pH on the conformation of cytochrome a (Ishibe, N., Lynch, S., and Copeland, R. A. (1991) J. Biol. Chem. 266, 23916-23920). These results are discussed in terms of possible mechanisms of communication between the cytochrome c binding site, cytochrome a, and the oxygen binding site within the cytochrome c oxidase molecule.     

Effect of the hinge protein on the heme iron site of cytochrome c1

X-ray absorption spectroscopic (XAS) studies on cytochrome C1 from beef heart mitochondria were conducted to identify the effect of the hinge protein [Kim, C.H., & King, T.E. (1983) J. Biol. Chem. 258, 13543-13551] on the structure of the heme site in cytochrome c1. A comparison of XAS data of highly purified "one-band" and "two-band" cytochrome c1 [Kim, C.H., & King, T.E. (1987) Biochemistry 26, 1955-1961] demonstrates that the hinge protein exerts a rather pronounced effect on the heme environment of the cytochrome c1: a conformational change occurs within a radius of approximately 5 A from the heme iron in cytochrome c1 when the hinge protein is bound to cytochrome c1. This result may be correlated with the previous observations that the structure and reactivity of cytochrome c1 are affected by the hinge protein [Kim, C.H., & King, T.E. (1987) Biochemistry 26, 1955-1961; Kim, C.H., Balny, C., & King, T.E. (1987) J. Biol. Chem. 262, 8103-8108].     

Oxygen influences the subunit structure of cytochrome c oxidase in the slime mold Dictyostelium discoideum

The conditions that promote the alternative expression of two nuclear-encoded subunits of cytochrome c oxidase in the slime mold Dictyostelium discoideum (Bisson, R., and Schiavo, G. (1986) J. Biol. Chem. 261, 4373-4376) have been investigated. Oxygen concentration seems to be the only factor able to cause the subunit switching. This result indicates that the polypeptide composition of the mitochondrial enzyme can be influenced by environmental conditions. The significance of this change is discussed.     

Plant sulfite oxidase as novel producer of H2O2: combination of enzyme catalysis with a subsequent non-enzymatic reaction step

Sulfite oxidase (EC 1.8.3.1) from the plant Arabidopsis thaliana is the smallest eukaryotic molybdenum enzyme consisting of a molybdenum cofactor-binding domain but lacking the heme domain that is known from vertebrate sulfite oxidase. While vertebrate sulfite oxidase is a mitochondrial enzyme with cytochrome c as the physiological electron acceptor, plant sulfite oxidase is localized in peroxisomes and does not react with cytochrome c. Here we describe results that identified oxygen as the terminal electron acceptor for plant sulfite oxidase and hydrogen peroxide as the product of this reaction in addition to sulfate. The latter finding might explain the peroxisomal localization of plant sulfite oxidase. 18O labeling experiments and the use of catalase provided evidence that plant sulfite oxidase combines its catalytic reaction with a subsequent non-enzymatic step where its reaction product hydrogen peroxide oxidizes another molecule of sulfite. In vitro, for each catalytic cycle plant SO will bring about the oxidation of two molecules of sulfite by one molecule of oxygen. In the plant, sulfite oxidase could be responsible for removing sulfite as a toxic metabolite, which might represent a means to protect the cell against excess of sulfite derived from SO2 gas in the atmosphere (acid rain) or during the decomposition of sulfur-containing amino acids. Finally we present a model for the metabolic interaction between sulfite and catalase in the peroxisome.     

Definition of the interaction domain for cytochrome c on cytochrome c oxidase. I. Biochemical, spectral, and kinetic characterization of surface mutants in subunit ii of Rhodobacter sphaeroides cytochrome aa(3)

To determine the interaction site for cytochrome c (Cc) on cytochrome c oxidase (CcO), a number of conserved carboxyl residues in subunit II of Rhodobacter sphaeroides CcO were mutated to neutral forms. A highly conserved tryptophan, Trp(143), was also mutated to phenylalanine and alanine. Spectroscopic and metal analyses of the surface carboxyl mutants revealed no overall structural changes. The double mutants D188Q/E189N and D151Q/E152N exhibit similar steady-state kinetic behavior as wild-type oxidase with horse Cc and R. sphaeroides Cc(2), showing that these residues are not involved in Cc binding. The single mutants E148Q, E157Q, D195N, and D214N have decreased activities and increased K(m) values, indicating they contribute to the Cc:CcO interface. However, their reactions with horse and R. sphaeroides Cc are different, as expected from the different distribution of surface lysines on these cytochromes c. Mutations at Trp(143) severely inhibit activity without changing the K(m) for Cc or disturbing the adjacent Cu(A) center. From these data, we identify a Cc binding area on CcO with Trp(143) and Asp(214) close to the site of electron transfer and Glu(148), Glu(157), and Asp(195) providing electrostatic guidance. The results are completely consistent with time-resolved kinetic measurements (Wang, K., Zhen, Y., Sadoski, R., Grinnell, S., Geren, L., Ferguson-Miller, S., Durham, B., and Millett, F. (1999) J. Biol. Chem. 274, 38042-38050) and computational docking analysis (Roberts, V. A., and Pique, M. E. (1999) J. Biol. Chem. 274, 38051-38060).