Region of cytochrome c interacting with yeast cytochrome b2: determination with singly modified carboxydinitrophenyl cytochromes c

The association and reduction reactions of ten different 4-carboxy-2,6-dinitrophenyl (CDNP) horse heart cytochromes c, singly modified at lysines 8, 13, 27, 39, 60, 72, 73, 86, 87, and 99, with Saccharomyces cerevisiae cytochrome b2 were studied to determine the region of cytochrome c interacting with cytochrome b2. In the presence of higher ratios of free cytochrome c to cytochrome b2, native cytochrome c, and the CDNP-lysine 39, 60, and 99 derivatives associated with cytochrome b2 with a binding stoichiometry close to 2:1, while CDNP-cytochromes c modified at lysines 8, 13, 27, 72, 73, 86, and 87 formed only 1:1 complexes. In the presence of lower ratios of free cytochrome c, modifications of lysines 8, 27, 86, and 87 had more inhibitory effects on the association of cytochrome c with cytochrome b2 than modifications of lysines 13, 39, 60, 72, 73, and 99. This tendency was similar to that on removal of free cytochrome c, except in the case of CDNP-lysine 13 and 73 derivatives. The rate of reduction of cytochrome c by cytochrome b2 was decreased by carboxydinitrophenylation of lysines 8, 13, 27, 72, 73, 86, and 87. In contrast, the rate of reduction of cytochrome c was not affected by modifications of lysines 39, 60, and 99. Since lysines 8, 13, 27, 72, 73, 86, and 87 are located on the front surface and lysines 39, 60, and 99 on the back side, and since different effects of modifying lysine residues located on the front surface may be interpreted in terms of effects on the complementary interaction of cytochrome c and cytochrome b2, these results indicate that the region of cytochrome c interacting with cytochrome b2 is located on the front surface of the cytochrome c molecule containing the exposed heme edge.     

Membrane location of apocytochrome c and cytochrome c determined from lipid-protein spin exchange interactions by continuous wave saturation electron spin resonance.

Apocytochrome c derived from horse heart cytochrome c was spin-labeled on the cysteine residue at position 14 or 17 in the N-terminal region of the primary sequence, and cytochrome c from yeast was spin-labeled on the single cysteine residue at sequence position 102 in the C-terminal region. The spin-labeled apocytochrome c and cytochrome c were bound to fluid bilayers composed of different negatively charged phospholipids that also contained phospholipid probes that were spin-labeled either in the headgroup or at different positions in the sn-2 acyl chain. The location of the spin-labeled cysteine residues on the lipid-bound proteins was determined relative to the spin-label positions in the different spin-labeled phospholipids by the influence of spin-spin interactions on the microwave saturation properties of the spin-label electron spin resonance spectra. The enhanced spin relaxation observed in the doubly labeled systems arises from Heisenberg spin exchange, which is determined by the accessibility of the spin-label group on the protein to that on the lipid. It is found that the labeled cysteine groups in horse heart apocytochrome c are located closest to the 14-C atom of the lipid acyl chain when the protein is bound to dimyristoyl- or dioleoyl-phosphatidylglycerol, and to that of the 5-C atom when the protein is bound to a dimyristoylphosphatidylglycerol/dimyristoylphosphatidylcholine (15:85 mol/mol mixture. On binding to dioleoylphosphatidylglycerol, the labeled cysteine residue in yeast cytochrome c is located closest to the phospholipid headgroups but possibly between the polar group region and the 5-C atom of the acyl chains. These data determine the extent to which the different regions of the proteins are able to penetrate negatively charged phospholipid bilayers.     

Use of specific lysine modifications to identify the site of reaction between cytochrome c and ferricyanide

The site of the reaction between horse heart ferrocytochrome c and ferricyanide was investigated by measuring the reaction rate of cytochrome c derivatives specifically modified at single lysine residues to form trifluoroacetyl or trifluoromethylphenylcarbamyl amino groups. Cytochrome c derivatives singly modified at lysines 8, 13, 25, 27, 72, 79, and 87 surrounding the heme crevice had rate constants decreased from that of native cytochrome c by factors of 1.29, 2.03, 1.12, 1.35, 1.46, 1.29, and 1.19, respectively. Modification of a given lysine with the bulky trifluoromethylphenylcarbamyl group caused nearly the same decrease in reaction rate as modification with the trifluoroacetyl group, indicating that the effect was due to removal of an electrostatic interaction between the protonated lysine amino group and ferricyanide. Modification of lysines 22, 55, 99, and 100 at the right side, bottom, and back of cytochrome c had no effect on the reaction rate. These results indicate that the reaction site is located at the exposed edge of the heme and that the electrostatic interaction between ferricyanide and cytochrome c is dominated by the lysine amino groups surrounding the heme crevice, which include lysine 86, in addition to the ones listed above. We have used the specific lysine modification results to estimate the contribution of each lysine amino group to the electrostatic interaction and have developed a semiempirical relation for the total electrostatic interaction.     

Preferred sites for electron transfer between cytochrome c and iron and cobalt complexes

The kinetics of oxidation of eight different singly substituted 4-carboxy-2,6-dinitrophenyl (CDNP) horse ferrocytochromes c, modified at lysine 7, 13, 25, 27, 60, 72, 86, or 87, and of one trinitrophenyl horse ferrocytochrome c, modified at lysine 13, by the 3- and 3+ inorganic complexes hexacyanoferrate(III) (Fe(CN)6(3-) ) and tris(1,10-phenanthroline)cobalt(III) (Co(phen)3(3+) ) have been characterized. The influence of the modified residues on the bimolecular rate constants for these reactions define the protein molecular surface involved. The site of electron exchange for both oxidants appears to be the solvent accessible edge of the heme prosthetic group or a closely related structure on the "front" surface of the molecule. The reaction with Fe(CN)6(3-) is most strongly influenced by modification of lysine 72, a residue to the left of the exposed heme edge. (CDNP lysine 72 cytochrome c yields a 3.6-fold decrease in the bimolecular rate constant, as compared to that for the native protein.) However, it is the region around lysine 27, to the right of the heme edge, that is most influential in the reaction with Co(phen)3(3+). (CDNP-lysine 27 cytochrome c exhibits a 7.3-fold increase in the rate constant, as compared to that for the native protein.) The kinetics of reaction of the CDNP-lysine 13, 60, 72, and 87 modified cytochromes c with Fe(CN)5(4-aminopyridine)2- as oxidant and Fe(CN)5(4-aminopyridine)3- and Fe(CN)5-(imidazole)3- as reductants have also been determined and further illustrate the influence of electrostatics on the kinetics of such protein-small molecule electron exchanges.     

Modification by homocysteine thiolactone affects redox status of cytochrome C

Homocysteine (Hcy)-thiolactone mediates a post-translational incorporation of Hcy into protein in humans. Protein N-homocysteinylation is detrimental to protein structure and function and is linked to pathophysiology of hyperhomocysteinemia observed in humans and experimental animals. The modification by Hcy-thiolactone can be detrimental directly by affecting the function of an essential lysine residue or indirectly by interfering with the function of other essential residues or cofactors. Previous work has shown that cytochrome c is very sensitive to Hcy-thiolactone, which causes formation of N-Hcy-cytochrome c multimers. However, it was unclear what sites in cytochrome c were prone to Hcy attachment and whether N-linked Hcy can affect the structure and redox function of cytochrome c. Here we show that 4 lysine residues (Lys8 or -13, Lys86 or -87, Lys99, and Lys100) of cytochrome c are susceptible to N-homocysteinylation. We also show that N-homocysteinylation of 1 mol of lysine/mol of protein affects the redox state of the heme ligand of cytochrome c by rendering it reduced. The modification causes subtle structural changes, manifested as increased resistance of the N-Hcy-cytochrome c to proteolysis by trypsin, chymotrypsin, and Pronase. However, no major secondary structure perturbations were observed as shown by circular dichroism spectroscopy. Our data illustrate how N-homocysteinylation can interfere with the function of heme-containing proteins.     

The role of individual lysine residues of horse cytochrome <Emphasis Type="Italic">c</Emphasis> in the formation of reactive complexes with components of the respiratory chain

A number of mutant forms of horse cytochrome c with single or double substitutions of lysine residues near the heme cavity involved in interaction of mitochondrial cytochrome c with ubiquinol:cytochrome c reductase (EC 1.10.2.2) (complex III) and cytochrome c oxidase (EC 1.9.3.1) (complex IV) were prepared.. The succinate:cytochrome c reductase and cytochrome c oxidase activities of mitoplasts of rat liver were measured in the presence of mutant forms of cytochrome c. The lysine residues in positions 8, 27, 72, 86, and 87 were shown to be the main contribution to the formation of a reactive complex with ubiquinol:cytochrome c reductase of the respiratory chain, whereas the lysine residues in positions 13, 79, 86, and 87 were predominantly responsible for the formation of a complex with cytochrome c oxidase.     

Comparison of the binding sites on cytochrome c for cytochrome c oxidase, cytochrome bc1, and cytochrome c1. Differential acetylation of lysyl residues in free and complexed cytochrome c

The isolated complexes of ferricytochrome c with cytochrome c oxidase, cytochrome c reductase (cytochrome bc1 or complex III), and cytochrome c1 (a subunit of cytochrome c reductase) were investigated by the method of differential chemical modification (Bosshard, H.R. (1979) Methods Biochem. Anal. 25, 273-301). By this method the chemical reactivity of each of the 19 lysyl side chains of horse cytochrome c was compared in free and in complexed cytochrome c and binding sites were deduced from altered chemical reactivities of particular lysyl side chains in complexed cytochrome c. The most important findings follow. 1. The binding sites on cytochrome c for cytochrome c oxidase and cytochrome c reductase, defined in terms of the involvement of particular lysyl residues, are indistinguishable. The two oxidation-reduction partners of cytochrome c interact at the front (exposed heme edge) and top left part of the molecule, shielding mainly lysyl residues 8, 13, 72 + 73, 86, and 87. The chemical reactivity of lysyl residues 22, 39, 53, 55, 60, 99, and 100 is unaffected by complex formation while the remaining lysyl residues in positions 5, 7, 25, 27, 79, and 88 are somewhat less reactive in the complexed molecule. 2. When bound to cytochrome c reductase or to the isolated cytochrome c1 subunit of the reductase the same lysyl side chains of cytochrome c are shielded. This indicates that cytochrome c binds to the c1 subunit of the reductase during the electron transfer process.     

The reaction domain on Rhodospirillum rubrum cytochrome c2 and horse cytochrome c for the Rhodospirillum rubrum cytochrome bc1 complex

The interaction of the Rhodospirillum rubrum cytochrome bc1 complex with R. rubrum cytochrome c2 and horse cytochrome c was studied using specific lysine modification and ionic strength dependence methods. In order to define the reaction domain on cytochrome c2, several fractions consisting of mixtures of singly labeled carboxydintrophenyl-cytochrome c2 derivatives were employed. Fraction A consisted of a mixture of derivatives modified at lysines 58, 81, and 109 on the back of cytochrome c2, while fractions C1, C2, C3, and C4 were mixtures of singly labeled derivatives modified at lysines 9, 13, 75, 86, and 88 on the front of cytochrome c2 surrounding the heme crevice. The rate of the reaction of fraction A was found to be nearly the same as that of native cytochrome c2. However, the rate constants of fractions C1-C4 were found to be more than 20-fold smaller than that of native cytochrome c2. These results indicate that lysine residues surrounding the heme crevice of cytochrome c2 are involved in electrostatic interactions with carboxylate groups at the binding site on the cytochrome bc1 complex. Since the same domain is involved in the reaction with the photosynthetic reaction center, cytochrome c2 must undergo some type of rotational or translational diffusion during electron transport in R. rubrum. The reaction rates of horse heart cytochrome c derivatives modified at single lysine amino groups with trifluoroacetyl or trifluoromethylphenylcarbamoyl were also measured. Modification of lysines 8, 13, 25, 27, 72, 79, and 87 surrounding the heme crevice was found to significantly lower the rate of the reaction, while modification of lysines in other regions had no effect. This indicates that the reaction of horse cytochrome c also involves the heme crevice domain.     

The structural and functional role of lysine residues in the binding domain of cytochrome c in the electron transfer to cytochrome c oxidase.

The interactions of yeast iso-1 cytochrome c with bovine cytochrome c oxidase were studied using cytochrome c variants in which lysines of the binding domain were substituted by alanines. Resonance Raman spectra of the fully oxidized complexes of both proteins reveal structural changes of both the heme c and the hemes a and a3. The structural changes in cytochrome c are the same as those observed upon binding to phospholipid vesicles where the bound protein exists in two conformers, B1 and B2. Whereas the structure of B1 is the same as that of the unbound cytochrome c, the formation of B2 is associated with substantial alterations of the heme pocket. In cytochrome c oxidase, the structural changes in both hemes refer to more subtle perturbations of the immediate protein environment and may be a result of a conformational equilibrium involving two states. These changes are qualitatively different to those observed for cytochrome c oxidase upon poly-l-lysine binding. The resonance Raman spectra of the various cytochrome c/cytochrome c oxidase complexes were analyzed quantitatively. The spectroscopic studies were paralleled by steady-state kinetic measurements of the same protein combinations. The results of the spectra analysis and the kinetic studies were used to determine the stability of the complexes and the conformational equilibria B2/B1 for all cytochrome c variants. The complex stability decreases in the order: wild-type WT > J72K > K79A > K73A > K87A > J72A > K86A > K73A/K79A (where J is the natural trimethyl lysine). This order is not exhibited by the conformational equilibria. The electrostatic control of state B2 formation does not depend on individual intermolecular salt bridges, but on the charge distribution in a specific region of the front surface of cytochrome c that is defined by the lysyl residues at positions 72, 73 and 79. On the other hand, the conformational changes in cytochrome c oxidase were found to be independent of the identity of the bound cytochrome c variant. The maximum rate constants determined from steady-state kinetic measurements could be related to the conformational equilibria of the bound cytochrome c using a simple model that assumes that the conformational transitions are faster than product formation. Within this model, the data analysis leads to the conclusion that the interprotein electron transfer rate constant is around two times higher in state B2 than in B1. These results can be interpreted in terms of an increase of the driving force in state B2 as a result of the large negative shift of the reduction potential.     

Cytochrome c and cytochrome c oxidase interactions: the effects of ionic strength and hydrostatic pressure studied with site-specific modifications of cytochrome c.

Seven cytochromes c, in which individual lysines have been modified to the propylthiobimane derivatives, have been prepared. These derivatives were also converted to the porphyrin cytochromes c by treatment with HF. The properties of both types of modified proteins were studied in their reactions with cytochrome c oxidase. The results show that lysines 25, 27, 60, 72, and 87 do not contribute a full charge to the binding interaction with the oxidase. These five residues, with the exception of the lysine-60 derivative, on the front surface of the protein and contain the solvent-accessible edge of the heme prosthetic group. By contrast, lysines 8 and 13 at the top of the front surface do contribute a full charge to the binding interaction with the oxidase. The removal of the positive charge on any one lysine weakens the binding to cytochrome c oxidase by at least 1 kcal (1 cal = 4.1868 J). The presence of bimane at lysines 13 and 87 clearly forces the separation of the cytochrome c and oxidase, but this does not occur with the other complexes. The bimane-modified lysine-13 protein, and to a lesser extent that modified at lysine 8, show the interesting effect of enhanced complex formation with cytochrome c oxidase when subjected to pressure, possibly because of entrapment of water at the newly created interface of the complex. Our observations indicate that the two proteins of the cytochrome c - cytochrome oxidase complex have preferred, but not obligatory, spatial orientations and that interaction occurs without either protein losing significant portions of its hydration shell.     

Use of specific trifluoroacetylation of lysine residues in cytochrome c to study the reaction with cytochrome b5, cytochrome c1, and cytochrome oxidase

The preparation, purification, and characterization of four new derivatives of cytochrome c trifluoroacetylated at lysines 72, 79, 87, and 88 are reported. The redox reaction rates of these derivatives with cytochrome b5, cytochrome c1 and cytochrome oxidase indicated that the interaction domain on cytochrome c for all three proteins involves the lysines immediately surrounding the heme crevice. Modification of lysines 72, 79, 87 had a large effect on the rate of all three reactions, while modification of lysine 88 had a very small effect. Even though lysines 87 and 88 are adjacent to one another, lysine 87 is at the top left of the heme crevice oriented towards the front of cytochrome c, while lysine 88 is oriented more towards the back. Since the interaction sites for cytochrome c1 and cytochrome oxidase are essentially identical, cytochrome c probably undergoes some type of rotational diffusion during electron transport.     

Use of specific trifluoroacetylation of lysine residues in cytochrome c to study the reaction with cytochrome b5, cytochrome c1, and cytochrome oxidase

The preparation, purification, and characterization of four new derivatives of cytochrome c trifluoroacetylated at lysines 72, 79, 87, and 88 are reported. The redox reaction rates of these derivatives with cytochrome b₅, cytochrome c₁ and cytochrome oxidase indicated that the interaction domain on cytochrome c for all three proteins involves the lysines immediately surrounding the heme crevice. Modification of lysines 72, 79, and 87 had a large effect on the rate of all three reactions, while modification of lysine 88 had a very small effect. Even though lysines 87 and 88 are adjacent to one another, lysine 87 is at the top left of the heme crevice oriented towards the front of cytochrome c, while lysine 88 is oriented more towards the back. Since the interaction sites for cytochrome c₁ and cytochrome oxidase are essentially identical, cytochrome c probably undergoes some type of rotational diffusion during electron transport.     

Structural studies of bovine heart cytochrome c1

The complete primary structure of bovine heart cytochrome c1 was established by analyses of peptide fragments prepared by digestion using trypsin, staphylococcal protease, and chymotrypsin and by cyanogen bromide cleavage of cytochrome c1 and its derivatives. The total number of amino acid residues is 241, giving a molecular weight of 27,924 including the heme group. The NH2- and COOH-terminal residues are serine and lysine, respectively. One characteristic of the protein is that cytochrome c1 contains 43.6% hydrophobic residues and the polarity is estimated to be 41.1%. No clear homology was found between cytochrome c1 and other membranous proteins such as cytochrome b5 or the subunits of cytochrome oxidase for which sequences have been reported. Cytochrome c1 is predicted to have a high content of alpha-helix (46%). Partial sequence studies were also carried out on cytochrome c1 preparations obtained by different procedures and showed that there is no difference among the sequences of various preparations of cytochrome c1. The presence of a hydrophobic cluster near the COOH-terminal region indicates that the COOH-terminal region of cytochrome C1 associates with, or is buried in, the phospholipid bilayer of the mitochondrial membrane.     

Preparation and characterization of singly labeled ruthenium polypyridine cytochrome c derivatives

A novel two-step procedure has been developed to prepare cytochrome c derivatives labeled at specific lysine amino groups with ruthenium bis(bipyridine) dicarboxybipyridine [RuII(bpy)2(dcbpy)]. In the first step, cytochrome c was treated with the mono-N-hydroxysuccinimide ester of 4,4'-dicarboxy-2,2'-bipyridine (dcbpy) to convert positively charged lysine amino groups to negatively charged dcbpy-lysine groups. Singly labeled dcbpy-cytochrome c derivatives were then separated and purified by ion-exchange chromatography. In the second step, the individual dcbpy-cytochrome c derivatives were treated with RuII(bpy)2CO3 to form singly labeled RuII(bpy)2(dcbpy-cytochrome c) derivatives. The specific lysine labeled in each derivative was determined by reverse-phase chromatography of a tryptic digest. All of the derivatives had a strong luminescence emission centered at 662 nm, but the luminescence decay rates were increased relative to that of a non-heme protein control, RuII(bpy)2(dcbpy-lysozyme), which was 1.8 X 10(6) s-1. The luminescence decay rates were found to be 21, 16, 7.2, 5.7, 4.3, 4.3, and 3.5 X 10(6) s-1 for derivatives singly labeled at lysines 13, 72, 25, 7, 39, 86, and 87, respectively. There was an inverse relationship between the luminescence decay rates and the distances between the ruthenium labels and the heme group. The increased luminescence decay rates observed in the cytochrome c derivatives might be due to electron transfer from the excited triplet state of ruthenium to the ferric heme group. However, it is also possible that an energy-transfer mechanism might contribute to the luminescence quenching.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pyridoxal phosphate modified cytochromes c. Identification and electron transfer properties

The preparation, purification and characterization of the three singly, three doubly and one triply substituted derivatives of cytochrome c modified by pyridoxal phosphate (PLP) at lysine residues are reported. The PLP positions in PLP derivatives were determined by the amino acid analysis and sequence of PLP peptides. The results identified the lysine at position 86 in one of the singly substituted, lysine 79 in the other singly substituted and lysines 86 and 79 in the third doubly substituted cytochrome c derivatives. The area surrounding phenylalanine 82 forms the predominant PLP binding site on the cytochrome c molecule. The visible, CD and proton NMR spectra, the full intensity of the conformation-sensitive 695 nm band and the oxidation-reduction properties provide evidence to confirm the conclusion that singly and doubly substituted PLP cytochromes c retain the native conformation. The ability to restore both succinate and ascorbate/TMPD oxidation in cytochrome c-depleted mitochondria decreases in the order: native cytochrome c greater than PLP-Lys-79-cytochrome c greater than PLP-Lys-86-cytochrome c greater than PLP-Lys-79,86-cytochrome c greater than triply substituted derivative.     

Chemical modification of methionine residues of the phosphatidylcholine transfer protein from bovine liver. A spin-label study

The role of methionine residues in the interaction of the phosphatidylcholine transfer protein from bovine liver with phospholipid vesicles was investigated by specific modification of these residues with iodoacetamide. The modified protein was digested with cyanogen bromide in order to determine which methionine residues had become resistant to this cleavage. Automated Edman degradation on the digest indicated that after 72 h of reaction, Met-1 was modified for 80%, Met-73 for 50%, Met-109 for 20%, whilst Met-173 and Met-203 were found to be unmodified. This distinct modification did not result in any loss of phosphatidylcholine transfer activity. The interaction of the phosphatidylcholine transfer protein with phospholipid vesicles was investigated by making use of electron spin resonance spectroscopy. The interaction of unmodified protein with vesicles composed of phosphatidylcholine/phosphatidic acid/spin-labeled phosphatidylethanolamine (79:16:5, mol%) or composed of phosphatidylserine/spin-labeled phosphatidylethanolamine (95:5, mol%), gave an increase of about 50% in the rotation correlation time. A similar increase was observed with the modified protein. This interaction was further investigated by labeling Met-1 and Met-73 in the transfer protein with iodoacetamidoproxyl spin-label. Spin-labeling did not inactivate the transfer protein. In addition, the electron spin resonance spectra of the spin-labeled protein were not affected upon addition of vesicles composed of phosphatidylcholine/phosphatidic acid (80:20, mol%). These experiments strongly suggest that Met-1 and Met-73 are not part of the site that interacts with the membrane.     

Use of specific lysine modifications to locate the reaction site of cytochrome c with cytochrome oxidase.

The reaction of cytochrome c with trifluoromethylphenyl isocyanate was carried out under conditions which led to the modification of a small number of the 19 lysines. Extensive ion-exchange chromatography was used to separate and purify six different derivatives, each modified at a single lysine residue, lysines 8, 13, 27, 72, 79, and 100, respectively. The only modifications which affected the activity of cytochrome c with cytochrome oxidase (EC 1.9.3.1) were those of lysines immediately surrounding the heme crevice, lysines 13, 27, 72, and 79, and also lysine 8 at the top of the heme crevice. In each case, the modified cytochrome c had the same maximum velocity as that of native cytochrome c, but an increased Michaelis constant for high affinity phase of the reaction. This supports the hypothesis that the cytochrome oxidase reaction site is located in the heme crevice region, and the highly conserved lysine residues surrounding the heme crevice are important in the binding.     

A complex of cardiac cytochrome c1 and cytochrome c.

The interactions of cytochrome c1 and cytochrome c from bovine cardiac mitochondria were investigated. Cytochrome c1 and cytochrome c formed a 1:1 molecular complex in aqueous solutions of low ionic strength. The complex was stable to Sephadex G-75 chromatography. The formation and stability of the complex were independent of the oxidation state of the cytochrome components as far as those reactions studied were concerned. The complex was dissociated in solutions of ionic strength higher than 0.07 or pH exceeding 10 and only partially dissociated in 8 M urea. No complexation occurred when cytochrome c was acetylated on 64% of its lysine residues or photooxidized on its 2 methionine residues. Complexes with molecular ratios of less than 1:1 (i.e. more cytochrome c) were obtained when polymerized cytochrome c, or cytochrome c with all lysine residues guanidinated, or a "1-65 heme peptide" from cyanogen bromide cleavage of cytochrome c was used. These results were interpreted to imply that the complex was predominantly maintained by ionic interactions probably involving some of the lysine residues of cytochrome c but with major stabilization dependent on the native conformations of both cytochromes. The reduced complex was autooxidizable with biphasic kinetics with first order rate constants of 6 X 10(-5) and 5 X U0(-5) s-1 but did not react with carbon monoxide. The complex reacted with cyanide and was reduced by ascorbate at about 32% and 40% respectively, of the rates of reaction with cytochrome c alone. The complex was less photoreducible than cytochrome c1 alone. The complex exhibited remarkably different circular dichroic behavior from that of the summation of cytochrome c1 plus cytochrome c. We concluded that when cytochromes c1 and c interacted they underwent dramatic conformational changes resulting in weakening of their heme crevices. All results available would indicate that in the complex cytochrome c1 was bound at the entrance to the heme crevice of cytochrome c on the methionine-80 side of the heme crevice.     

Affinity chromatography purification of cytochrome c oxidase and b-c1 complex from beef heart mitochondria. Use of thiol-sepharose-bound Saccharomyces cerevisiae cytochrome c

A method for simultaneous purification of cytochrome c reductase and cytochrome c oxidase using a cytochrome c affinity column is presented. Cytochrome c from Saccharomyces cerevisiae was linked to an activated thiol-Sepharose gel via its Cys-102 residue located far from the lysine residues on the front side of the molecule, responsible for the interaction with the reductase and oxidase. In previously reported affinity chromatography techniques these lysine residues most probably reacted with the column. Cytochrome c oxidase and reductase from bovine heart mitochondria bind specifically to the affinity column and can be recovered separately at different ionic strength in the elution buffer. The enzymes are highly pure and active.