The binding domain on horse cytochrome c and Rhodobacter sphaeroides cytochrome c2 for the Rhodobacter sphaeroides cytochrome bc1 complex

The interaction of the Rhodobacter sphaeroides cytochrome bc1 complex with Rb. sphaeroides cytochrome c2 and horse cytochrome c was studied by using specific lysine modification and ionic strength dependence methods. The rate of the reactions with both cytochrome c and cytochrome c2 decreased rapidly with increasing ionic strength above 0.2 M NaCl. The ionic strength dependence suggested that electrostatic interactions were equally important to the reactions of the two cytochromes, even though they have opposite net charges at pH 7.0. In order to define the interaction domain on horse cytochrome c, the reaction rates of derivatives modified at single lysine amino groups with trifluoroacetyl or trifluoromethylphenylcarbamoyl were measured. Modification of lysine-8, -13, -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 result indicates that lysines surrounding the heme crevice of horse cytochrome c are involved in electrostatic interactions with carboxylate groups at the binding site on the cytochrome bc1 complex. In order to define the reaction domain on cytochrome c2, a fraction consisting of a mixture of singly labeled 4-carboxy-2,6-dinitrophenylcytochrome c2 derivatives modified at lysine-35, -88, -95, -97, and -105 and several unidentified lysines was prepared. Although it was not possible to resolve these derivatives, all of the identified lysines are located on the front surface of cytochrome c2 near the heme crevice. The rate of reaction of this fraction was significantly smaller than that of native cytochrome c2, suggesting that the binding domain on cytochrome c2 is also located at the heme crevice.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

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.     

A proton NMR study of the non-covalent complex of horse cytochrome c and yeast cytochrome-c peroxidase and its comparison with other interacting protein complexes

Cytochrome-c peroxidase (ferrocytochrome-c:hydrogen-peroxide oxidoreductase, EC 1.11.1.5) forms a noncovalent 1:1 complex with horse cytochrome c in low ionic strength solution that is detectable by proton NMR spectroscopy. When the entire proton hyperfine-shifted spectrum is considered only five hyperfine resonances exhibit unambiguously detectable shifts: the heme 8-CH3 and 3-CH3 resonances, single proton resonances near 19 ppm and -4 ppm and the methionine-80 methyl group. These shifts are very similar to those observed for the covalently crosslinked complex of cytochrome-c peroxidase and horse cytochrome c, but different from those reported for cytochrome c complexes with flavodoxin and cytochrome b5. By comparison with the shifts reported for lysine-13-modified cytochrome c we conclude that the results reported here support the Poulos-Kraut proposed structure for the molecular redox complex between cytochrome-c peroxidase and cytochrome c. These results indicate that the principal site of interaction with cytochrome-c peroxidase is the exposed heme edge of horse cytochrome c, in proximity to lysine-13 and the heme pyrrole II. The noncovalent cytochrome-c peroxidase-cytochrome c complex exists in the rapid-exchange time limit even at 500 mHz proton frequency. Our data provide an improved estimate of the minimum off-rate for exchanging cytochrome c as 1133 (+/- 120) s-1 at 23 degrees C.     

Reaction of cytochromes c and c2 with the Rhodobacter sphaeroides reaction center involves the heme crevice domain

In order to define the interaction domain on Rhodobacter sphaeroides cytochrome c2 for the photosynthetic reaction center, positively charged lysine amino groups on cytochrome c2 were modified to form negatively charged (carboxydinitrophenyl)- (CDNP-) lysines. The reaction mixture was separated into several different fractions by ion-exchange chromatography on (carboxymethyl)cellulose. Tryptic digests of these fractions were analyzed by reverse-phase peptide mapping to determine the lysines that had been modified. Fraction A was found to consist of a mixture of singly labeled derivatives modified at lysine-35, -88, -95, -97, and -105 and several other unidentified lysines comprising 32% of the total. Although it was not possible to resolve these derivatives, all of the identified lysines are located on the front surface of cytochrome c2 near the heme crevice. The second-order rate constant for the reaction of native cytochrome c2 with reaction centers was 2.0 X 10(8) M-1 s-1, while that for fraction A was 20-fold less, 1.0 X 10(7) M-1 s-1. This suggests that lysines surrounding the heme crevice of cytochrome c2 are involved in electrostatic interactions with carboxylate groups at the binding site of the reaction center. The reaction rates of horse heart cytochrome c derivatives modified at single lysine amino groups with trifluoroacetyl or trifluoromethylphenylcarbamoyl were also measured. Modification of lysine-8, -13, -27, -72, -79, and -87 surrounding the heme crevice significantly lowered the rate of reaction, while modification of lysines in other regions had no effect. This indicates that the reaction of horse heart cytochrome c with the reaction center also involves the heme crevice domain.     

Redox properties of the photosystem II cytochromes b559 and c550 in the cyanobacterium Thermosynechococcus elongatus

Redox properties of cytochrome b559 (Cyt b559) and cytochrome c550 (Cyt c550) have been studied by using highly stable photosystem II (PSII) core complex preparations from a mutant strain of the thermophilic cyanobacterium Thermosynechococcus elongatus with a histidine tag on the CP43 protein of PSII. Two different redox potential forms for Cyt b559 are found in these preparations, with a midpoint redox potential ( E'(m)) of +390 mV in about half of the centers and +275 mV in the other half. The high-potential form, whose E'(m)is pH independent, can be converted into the lower potential form by Tris washing, mild heating or alkaline pH incubation. The E'(m) of the low-potential form is significantly higher than that found in other photosynthetic organisms and is not affected by pH. The possibility that the heme of Cyt b559 in T. elongatus is in a more hydrophobic environment is discussed. Cyt c550 has a higher E'(m)when bound to the PSII core (-80 mV at pH 6.0) than after its extraction from the complex (-240 mV at pH 6.0). The E'(m) of Cyt c550 bound to PSII is pH independent, while in the purified state an increase of about 58 mV/pH unit is observed when the pH decreases below pH 9.0. Thus, Cyt c550 seems to have a single protonateable group which influences the redox properties of the heme. From these electrochemical measurements and from EPR controls it is proposed that important changes in the solvent accessibility to the heme and in the acid-base properties of that protonateable group could occur upon the release of Cyt c550 from PSII.     

Redox protein electron-transfer mechanisms: electrostatic interactions as a determinant of reaction site in c-type cytochromes

The effect of ionic strength on the rate constant for electron transfer has been used to determine the magnitude and charge sign of the net electrostatic potential which exists in close proximity to the sites of electron transfer on various c-type cytochromes. The negatively charged ferricyanide ion preferentially reacts at the positively charged exposed heme edge region on the front side of horse cytochrome c and Paracoccus cytochrome c2. In contrast, at low ionic strength, the positively charged cobalt phenanthroline ion interacts with the negatively charged back side of cytochrome c2, and at high ionic strength at a positively charged site on the front side of the cytochrome. With horse cytochrome c, over the ionic strength range studied, cobalt phenanthroline reacts only at a positively charged site which is probably not at the heme edge. These inorganic oxidants do not react at the relatively uncharged exposed heme edge sites on Azotobacter cytochrome c5 and Pseudomonas cytochrome c-551, but rather at a negatively charged site which is away from the heme edge. The results demonstrate that at least two electron-transferring sites on a single cytochrome can be functional, depending on the redox reactant used and the ionic strength. Electrostatic interactions between charge distributions on the cytochrome surface and the other reactant, or interactions involving uncharged regions on the protein(s), are critical in determining the preferred sites of electron transfer and reaction rate constants. When unfavorable electrostatic effects occur at a site near the redox center, less optimal sites at a greater distance can become kinetically important.     

Electron transport and cytochromes in aerobically grown Proteus mirabilis

The function of the cytochromes in electron transport from NADH to oxygen in aerobically grown Proteus mirabilis has been determined. 77K-Spectra of cytoplasmic membrane suspensions, frozen while catalyzing electron transport from NADH to oxygen, in the presence as well as in the absence of 2-n-heptyl-4-hydroxyquinoline-N-oxide, have been recorded. Analysis of these 77K-spectra revealed that cytochrome b-563 (E'0 = +140 mV), cytochrome b-556 (E'0 = +140 mV) [or alternatively cytochrome b-563/556 (E'0 = +140 mV)] and cytochrome b-557 (E'0 = +50 mV) may function in a Q or b-cycle. The function of cytochrome c-549 (E'0 = +75 mV), which seems to be present only in a very low concentration, and cytochrome b-556 (E'0 = -105 mV), which reacts very slowly to the addition of NADH and oxygen, remains unclear. Cytochrome o, the main oxidase of aerobically grown P. mirabilis cells, can not be detected by the methods described above. Only when the reduced form of cytochrome o is liganded with carbon monoxide a specific alpha-band can be detected at 569 nm at 25 degrees C and 565 nm at 77K.     

Electrostatic and steric control of electron self-exchange in cytochromes c, c551, and b5.

The ionic strength dependence of the electron self-exchange rate constants of cytochromes c, c551, and b5 has been analyzed in terms of a monopole-dipole formalism (van Leeuwen, J.W. 1983. Biochim. Biophys. Acta. 743:408-421). The dipole moments of the reduced and oxidized forms of Ps. aeruginosa cytochrome c551 are 190 and 210 D, respectively (calculated from the crystal structure). The projections of these on the vector from the center of mass through the exposed heme edge are 120 and 150 D. For cytochrome b5, the dipole moments calculated from the crystal structure are 500 and 460 D for the reduced and oxidized protein; the projections of these dipole moments through the exposed heme edge are -330 and -280 D. A fit of the ionic strength dependence of the electron self-exchange rate constants gives -280 (reduced) and -250 (oxidized) D for the center of mass to heme edge vector. The self-exchange rate constants extrapolated to infinite ionic strength of cytochrome c, c551, and b5 are 5.1 x 10(5), 2 x 10(7), and 3.7 x 10(5) M-1 s-1, respectively. The extension of the monopole-dipole approach to other cytochrome-cytochrome electron transfer reactions is discussed. The control of electron transfer by the size and shape of the protein is investigated using a model which accounts for the distance of the heme from each of the surface atoms of the protein. These calculations indicate that the difference between the electrostatically corrected self-exchange rate constants of cytochromes c and c551 is due only in part to the different sizes and heme exposures of the two proteins.     

Partitioning of electrostatic and conformational contributions in the redox reactions of modified cytochromes c.

The reduction of acetylated, fully succinylated and dicarboxymethyl horse cytochromes c by the radicals CH3CH(OH), CO2.-, O2.-, and e-aq' and the oxidation of the reduced cytochrome c derivatives by Fe(CN)3-6 were studied using the pulse radiolysis technique. Many of the reactions were also examined as a function of ionic strength. By obtaining rate constants for the reactions of differently charged small molecules redox agents with the differently charged cytochrome c derivatives at both zero ionic strength and infinite ionic strength, electrostatic and conformational contributions to the electron transfer mechanism were effectively partioned from each other in some cases. In regard to cytochrome c electron transfer mechanism, the results, especially those for which conformational influences predominate, are supportive of the electron being transferred in the heme edge region.     

Cytochrome c3 from the sulfate-reducing anaerobe Desulfovibrio africanus Benghazi: purification and properties.

Cytochrome c3 was purified from Desulfovibrio africanus Benghazi by extraction with alkaline deoxyribonuclease, fractionation with ammonium sulfate, batch elution from carboxymethyl Sephadex followed by chromatography on the same resin, and gel filtration on Sephadex G-75. The preparation was judge homogeneous by a variety of criteria. The molecular weight was determined in an analytical ultracentrifuge, and values between 14,400 and 15,490 were obtained, depending upon the presumed value of partial specific volume. Gel filtration on a calibrated column of Sephadex G-75 gave a value of 14,900 daltons. The amino acid composition was very similar to that observed for the cytochrome from other species of Desulfovibrio, with the exception of increased levels of ThR and PhE. S-Carboxymethylation of the protein before and after heme removal by HgCl2 demonstrated eight Cys molecules involved in heme binding or four heme sites per molecule. Titration with sodium dithionite under N2 gave an electrochemical potential (E' 0) of -276 mV relative to the normal hydrogen electrode. Electrochemical titration of the cytochrome gave a Nernst plot with two linear regions with E' 0 values of -0.376 and -0.534 V. The spectra produced at various potentials exhibited shifts in isosbestic points upon reduction, suggesting changes in conformation during the reaction.     

High-potential iron-sulfur proteins and their possible site of electron transfer

The electron-transfer mechanism of the Fe4S4 high-potential iron-sulfur proteins (HiPIP's) was explored via a stopped-flow spectrophotometric kinetic study of the reduction of Chromatium vinosum and Rhodopseudomonas gelatinosa HiPIP's by both native and trinitrophenyllysine-13 horse cytochrome c. The influence of electrostatic effects was also effectively partitioned from the redox process per se. The corrected rates were 12.3 X 10(4) and 3.8 X 10(4) M-1 s-1 for native with C. vinosum and R. gelatinosa HiPIP, respectively, and 17.5 X 10(4) and 5.46 X 10(4) M-1 s-1 for TNP-cytochrome c with the two HiPIP's, respectively. The faster rates of TNP-cytochrome c with the HiPIP's are unexpected in terms of possible steric interaction since lysine-13 is at the top of the heme crevice. In understanding the somewhat faster rates of the TNP-cytochrome c over native cytochrome c it is possible that (1) TNP-cytochrome c reacts more quickly since modification of the lysine-13 residue destabilizes somewhat the heme crevice or (2) in light of the hydrophobic nature of the trinitrophenyl group and the X-ray crystallographic structure of HiPIP, the TNP group facilitates electron transfer by interacting with a hydrophobic region on the HiPIP molecular surface. The region about the S4 sulfur atom is the most exposed and accessible hydrophobic region on the HiPIP surface, in addition to being the point of closest approach of the S4 to the external environment.     

Synthesis and characterization of singly modified (carboxyferrocenyl)cytochrome c derivatives.

Carbodiimide-activated coupling chemistry has been used to covalently attach 1,1'-dicarboxyferrocene (dcFc) to the epsilon-amine of surface lysine residues of horse heart cytochrome c. Conditions have been found that optimize the production of singly modified (dcFc)cytochrome c derivatives and the presence of one free carboxylate per modification site allows separation and purification of about 10 of these derivatives by cation-exchange chromatography. Reversed-phase HPLC tryptic peptide mapping techniques have been used to identify the attachment sites of eight pure (dcFc)cytochrome c derivatives (at lysines 7, 8, 13, 25, 60, 72, 73, and 100). Through-space distances from these lysines to the nearest heme edge span the 6-16 A range and these derivatives should prove useful in exploring the distance dependence of long-range intramolecular electron transfer in cytochrome c.     

Energy tranduction in photosynthetic bacteria. XI. Further resolution of cytochromes of b type and the nature of the co-sensitive oxidase present in the respiratory chain of Rhodopseudomonas capsulata.

1. In membranes prepared from dark grown cells of Rhodopseudomonas capsulata, five cytochromes of b type (E'0 at pH 7.0 +413+/-5, +270+/-5, +148+/-5, +56+/-5 and -32+/-5 mV) can be detected by redox titrations at different pH values. The midpoint potentials of only three of these cytochromes (b148, b56, and b-32) vary as a function of pH with a slope of 30 mV per pH unit. 2. In the presence of a CO/N2 mixture, the apparent E'0 of cytochrome b270 shifts markedly towards higher potentials (+355mV); a similar but less pronounced shift is apparent also for cytochrome b150. The effect of CO on the midpoint potential of cytochrome b270 is absent in the respiration deficient mutant M6 which possesses a specific lesion in the CO-sensitive segment of the branched respiratory chain present in the wild type strain. 3. Preparations of spheroplasts with lysozyme digestion lead to the release of a large amount of cytochrome c2 and of virtually all cytochrome cc'. These preparations show a respiratory chain impaired in the electron pathway sensitive to low KCN concentration, in agreement with the proposed role of cytochrome c2 in this branch; on the contrary, the activity of the CO-sensitive branch remains unaffected, indicating that neither cytochrome c2 nor the CO-binding cytochrome cc' are involved in this pathway. 4. Membranes prepared from spheroplasts still possess a CO-binding pigment characterized by maxima at 420.5, 543 and 574 nm and minima at 431, 560 nm in C0-difference spectra and with an alpha band at 562.5 nm in reduced minus oxidized difference spectra. This membrane-bound cytochrome, which is coincident with cytochrome b270, can be classified as a typical cytochrome "0" and considered the alternative CO-sensitive oxidase.     

Involvement of lysines-72 and -79 in the alkaline isomerization of horse heart ferricytochrome c

Spectrophotometric titrations of five singly modified horse heart ferricytochromes c, specifically (trifluoromethyl)phenylcarbamylated (CF3PhNHCO-) or trifluoroacetylated (CF3CO-) at lysines-13, -72, and -79, were carried out. The CF3PhNHCO-Lys-13, Lys-79, and CF3CO-Lys-79 derivatives all underwent alkaline isomerization with loss of the 695-nm band to low-spin species with an apparent pK of about 8.9, as did the unmodified cytochrome. However, modification of lysine-72 appeared to alter the reaction pathway since the CF3PhNHCO-Lys-72 derivative isomerized to a high-spin form with an apparent pK of 9.3, while the CF3CO-Lys-72 derivative isomerized to a low-spin species with an apparent pK of 9.6, indicating that lysine-72 may be the normal sixth iron ligand in the native protein alkaline isomer. These results, together with those of other workers, suggest a model for the alkaline transition in which replacement of the methionine iron ligand is dependent on a number of factors, including the local availability and relative affinities of possible ligands for the heme iron and the effects of ionic and hydrophobic interactions on the tertiary structure of the molecule.     

Redox and acid-base characterization of cytochrome b-559 in photosystem II particles

The redox and acid/base states and midpoint potentials of cytochrome b-559 have been determined in oxygen-evolving photosystem II (PS II) particles at room temperature in the pH range from 6.5 to 8.5. At pH 7.5 the fresh PS II particles present about 2/3 of their cytochrome b-559 in its reduced and protonated (non-auto-oxidizable) high-potential form and about 1/3 in its oxidized and non-protonated low-potential form. Potentiometric reductive titration shows that the protonated high-potential couple is pH-independent (E'0, + 380 mV), whereas the low-potential couple is non-protonated and pH-independent above pH 7.6 (E'0, pH greater than 7.6, + 140 mV), but becomes pH-dependent below this pH, with a slope of -72 mV/pH unit. Moreover, evidence is presented that in PS II particles cytochrome b-559 can cycle, according to its established redox and acid/base properties, as an energy transducer at two alternate midpoint potentials and at two alternate pKa values. Red light absorbed by PS II induces reduction of cytochrome b-559 in these particles at room temperature, the reaction being completely blocked by dichlorophenyldimethylurea.     

Spectroelectrochemical investigations of stoichiometry and oxidation-reduction potentials of cytochrome c oxidase components in the presence of carbon monoxide: the "invisible" copper.

Spectroelectrochemical studies are presented for the carbon monoxide complex of isolated, purified cytochrome c oxidase (EC 1.9.3.1) in solutions saturated with carbon monoxide. The results indicate a stoichiometry of three equivalents per oxidase-carbon monoxide complex molecule. Formal reduction potentials (Eo) of the two copper and one heme component at pH 7.0 were obtained by means of quantitative absorbance-charge titrations in the absence and presence of cytochrome c, and by means of a Nernstian "Minnaert" plot in the presence of cytochrome c. Analysis of the absorbance-charge curves from these titrations gave an indirect determination of the high potential, "invisible" copper component. The copper potentials in the carbon monoxide complex were found to be relatively unchanged with respect to those of the native enzyme. The Eo values obtained were: high potential ("invisible") copper (340 +/- 20 mV (NHE)), low potential copper (190 +/- 20 mV), and low potential heme (250 +/- 10 mV).     

Topological studies of monomeric and dimeric cytochrome c oxidase and identification of the copper A site using a fluorescence probe

Beef heart cytochrome c oxidase was labeled at a single sulfhydryl group by treatment with 5 mM N-iodoacetylamidoethyl-1-aminonaphthalene-5-sulfonate (1,5-I-AEDANS) at pH 8.0 for 4 h. Sodium dodecyl sulfate gel electrophoresis revealed that the enzyme was exclusively labeled at subunit III, presumably at Cys-115. The high affinity phase of the electron transfer reaction with horse cytochrome c was not affected by acetylamidoethyl-1-aminonaphthalene-5-sulfonate (AEDANS) labeling. Addition of horse cytochrome c to dimeric AEDANS-cytochrome c oxidase resulted in a 55% decrease in the AEDANS fluorescence due to the formation of a 1:1 complex between the two proteins. Forster energy transfer calculations indicated that the distance from the AEDANS label on subunit III to the heme group of cytochrome c was in the range 26-40 A. In contrast to the results with the dimeric enzyme, the fluorescence of monomeric AEDANS-cytochrome c oxidase was not quenched at all by binding horse heart cytochrome c, indicating that the AEDANS label on subunit III was at least 54 A from the heme group of cytochrome c. These results support a model in which the lysines surrounding the heme crevice of cytochrome c interact with carboxylates on subunit II of one monomer of the cytochrome c oxidase dimer and the back of the molecule is close to subunit III on the other monomer. In order to identify the cysteine residues that ligand copper A, a new procedure was developed to specifically remove copper A from cytochrome c oxidase by incubation with 2-mercaptoethanol followed by gel chromatography. Treatment of the copper A-depleted cytochrome c oxidase preparation with 1,5-I-AEDANS resulted in labeling sulfhydryl groups on subunit II as well as on subunit III. No additional subunits were labeled. This result indicates that the copper A binding site is located at cysteines 196 and/or 200 of subunit II and that removal of copper A exposes these residues for labeling by 1,5-I-AEDANS. Alternative copper A depletion methods involving incubation with bathocuproine sulfonate (Weintraub, S.T., and Wharton, D.C. (1981) J. Biol. Chem. 256, 1669-1676) or p-(hydroxymercuri)benzoate (Li, P.M., Gelles, J., Chan, S.I., Sullivan, R.J., and Scott, R.A. (1987) Biochemistry 26, 2091-2095) were also investigated. Treatment of these preparations with 1,5-I-AEDANS resulted in labeling cysteine residues on subunits II and III. However, additional sulfhydryl residues on other subunits were also labeled, preventing a definitive assignment of the location of copper A using these depletion procedures.     

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.