Proton-NMR studies of the effects of ionic strength and pH on the hyperfine-shifted resonances and phenylalanine-82 environment of three species of mitochondrial ferricytochrome c.

Ferricytochromes c from three species (horse, tuna, yeast) display sensitivity to variations in solution ionic strength or pH that is manifested in significant changes in the proton NMR spectra of these proteins. Irradiation of the heme 3-CH3 resonances in the proton NMR spectra of tuna, horse and yeast iso-1 ferricytochromes c is shown to give NOE connectivities to the phenyl ring protons of Phe82 as well as to the beta-CH2 protons of this residue. This method was used to probe selectively the Phe82 spin systems of the three cytochromes c under a variety of solution conditions. This phenylalanine residue has previously been shown to be invariant in all mitochondrial cytochromes c, located near the exposed heme edge in proximity to the heme 3-CH3, and may function as a mediator in electron transfer reactions [Louie, G. V., Pielak, G. J., Smith, M. & Brayer, G. D. (1988) Biochemistry 27, 7870-7876]. Ferricytochromes c from all three species undergo a small but specific structural rearrangement in the environment around the heme 3-CH3 group upon changing the solution conditions from low to high ionic strength. This structural change involves a decrease in the distance between the Phe82 beta-CH2 group and the heme 3-CH3 substituent. In addition, studies of the effect of pH on the 1H-NMR spectrum of yeast iso-1 ferricytochrome c show that the heme 3-CH3 proton resonance exhibits a pH-dependent shift with an apparent pK in the range of 6.0-7.0. The chemical shift change of the yeast iso-1 ferricytochrome c heme 3-CH3 resonance is not accompanied by an increase in the linewidth as previously described for horse ferricytochrome c [Burns, P. D. & La Mar, G. N. (1981) J. Biol. Chem. 256, 4934-4939]. These spectral changes are interpreted as arising from an ionization of His33 near the C-terminus. In general, the larger spectral changes observed for the resonances in the vicinity of the heme 3-CH3 group in yeast iso-1 ferricytochrome c with changes in solution conditions, relative to the tuna and horse proteins, suggest that the region around Phe82 is more open and that movement of the Phe82 residue is less constrained in yeast ferricytochrome c. Finally, it is demonstrated here that both the heme 8-CH3 and the 7 alpha-CH resonances of yeast ferricytochrome c titrate with p2H and exhibit apparent pK values of approximately 7.0. The titrating group responsible for these spectral changes is proposed to be His39.     

Study of the biological significance of cytochrome methylation. I. Thermal, acid and guanidinium hydrochloride denaturations of baker's yeast ferricytochromes c.

The iso-cytochromes c from baker's yeast: iso-1 methylated and unmethylated forms and iso-2 have been purified and their stabilities towards denaturants compared to that of horse heart cytochrome c. Thermal, acid and guanidinium hydrochloride denaturations were followed using fluorescence emission of their tryptophan 59 and/or the absorbance in the Soret region as the physical parameters. Very few differences could be evidenced among the ferricytochromes investigated in this study insofar as the acid denaturations are concerned. This is to be contrasted with the conclusions of the thermal and guanidinium hydrochloride denaturations studies which clearly showed the ferricytochrome from horse heart to be much more stable than those from baker's yeast. No appreciable differences could be measured among the methylated and unmethylated forms of iso-1 cytochrome c nor among iso-1 and iso-2 cytochromes from baker's yeast. Our results suggest that a stabilizing effect of methylation on the tridimensional structure of ferricytochrome c must probably be discarded. Other possible physiological roles of methylation are suggested taking into account the relative instability of ascomycetes's cytochromes as compared to mammalian ones.     

Electron paramagnetic resonance studies of Pseudomonas cytochrome c peroxidase

The EPR spectrum at 15 K of Pseudomonas cytochrome c peroxidase, which contains two hemes per molecule, is in the totally ferric form characteristic of low-spin heme giving two sets of g-values with gz 3.26 and 2.94. These values indicate an imidazole-nitrogen : heme-iron : methionine-sulfur and an imidazole-nitrogen : heme-iron : imidazole-nitrogen hemochrome structure, respectively. The spectrum is essentially identical at pH 6.0 and 4.6 and shows only a very small amount of high-spin heme iron (g 5--6) also at 77 K. Interaction between the two hemes is shown to exist by experiments in which one heme is reduced. This induces a change of the EPR signal of the other (to gz 2.83, gy 2.35 and gx 1.54), indicative of the removal of a histidine proton from that heme, which is axially coordinated to two histidine residues. If hydrogen peroxide is added to the partially reduced protein, its EPR signal is replaced by still other signals (gz 3.5 and 3.15). Only a very small free radical peak could be observed consistent with earlier mechanistic proposals. Contrary to the EPR spectra recorded at low temperature, the optical absorption spectra of both totally oxidized and partially reduced enzyme reveal the presence of high-spin heme at room temperature. It seems that a transition of one of the heme c moieties from an essentially high-spin to a low-spin form takes place on cooling the enzyme from 298 to 15 K.     

Kinetic and equilibrium studies of alkaline isomerization of vertebrate cytochromes c

Equilibria and kinetics of alkaline isomerization of seven ferricytochromes c from vertebrates were studied by pH-titration and pH-jump methods in the pH region of 7-12. In the equilibrium behavior, no significant difference was detected among the cytochromes c, whereas marked differences in the kinetic behavior were observed. According to the kinetic behavior of the isomerization, the cytochromes c examined fall into three classes: Group I (horse, sheep, dog and pigeon cytochromes c), Group II (tuna and bonito cytochromes c) and Group III (rhesus monkey cytochrome c). The kinetic results are interpreted in terms of the sequential scheme: Neutral form in equilibrium with fast Transient form in equilibrium with slow Alkaline form where the neutral and alkaline forms are the species stable at neutral and alkaline pH, respectively, and the transient form is a kinetic intermediate. From comparison of the primary sequences of the seven cytochromes c and the classification of these cytochromes c, it is concluded that the amino acid substitution Phe/Tyr at the 46-th position has a major influence on the kinetic behavior. In Group II and III cytochromes c, the ionization of Tyr-46 is suggested to bring about loosening of the heme crevice and thus facilitate the ligand replacement involved in the isomerization.     

Physicochemical properties of two atypical cytochromes c, Crithidia cytochrome c-557 and Euglena cytochrome c-558.

Cytochrome c-557 from Crithidia oncopelti and cytochrome c-558 from Euglena gracilis are mitochondrial cytochromes c that have an atypical haem-binding site. It was of interest to know whether the loss of one thioether bond affected the physicochemical properties of these cytochromes. The thermodynamic parameters of the redox potential were measured. The reaction with imidazole, the kinetics and thermodynamics of the alkaline isomerization and the effect of heating on the visible spectrum are described for the ferricytochromes. The kinetics of the loss of cyanide, the spectral changes occurring on reduction with dithionite at alkaline pH values and the reactivity with CO are described for the ferrocytochromes. In many respects the cytochromes of the two protozoans are very similar to the cytochromes of horse and yeast. The ferricytochromes do, however, undergo a reversible transition to high-spin species on heating, which may be due to the more flexible attachment of the prosthetic group. Similarly the alkaline isomers of cytochromes c-557 and c-558 give rise to high-spin proteins above pH 11. The alkaline isomerization of cytochrome c-558, involves a pKobs. of 10 and kinetics which do not obey the model of Davis et al. [(1974) J. Biol. Chem. 249, 2624-2632] for horse cytochrome c. It is proposed that a model involving two ionizations, followed by a conformation change, may fit the data. Both cytochromes c-557 and c-558 combine slowly with CO at neutral pH values.     

1H NMR and ESR studies of oxidized cytochrome c551 from Pseudomonas aeruginosa.

Near neutral pH, Fe(III) cytochrome c551 exhibits an ESR absorption due primarily to a single species with g values of 3.24, 2.06, and 1.48. These g values are somewhat different from those of horse heart cytochrome c and can be interpreted by the generalizations of Brautigan et al. [(1977) J. Biol. Chem. 252, 574] to be due to Fe binding by the imidazole anion of histidine rather than by neutral imidazole. The NMR spectrum of Fe(III) cytochrome c551 exhibits a number of hyperfine-shifted peaks whose pattern shows similarities to but many differences from that of horse heart cytochrome c. Variation in shifts of some of the peaks in the pH range 5--9 is ascribed to ionization of a somewhat buried propionic acid side chain (pK = 5.8) and to ionization of the N-terminal NH3+ group (pK = 7.7). At alkaline pH greater than 9.4, as shown by a variety of optical and ESR spectral changes, the Met-61 S ligand is replaced by other ligands.     

Conservation of the free energy change of the alkaline isomerization in mitochondrial and bacterial cytochromes c

The thermodynamic parameters of the alkaline transition for oxidized native yeast iso-1 cytochrome c and Rhodopseudomonas palustris cytochrome c(2) (cytc(2)) have been determined through direct electrochemistry experiments carried out at variable pH and temperature and compared to those for horse and beef heart cytochromes c. We have found that both transition enthalpy and entropy are remarkably species dependent, following the order R. palustris cytc(2) > beef (horse) heart cytc>yeast iso-1 cytc. Considering the high homology at the heme-protein interface in the native species, this variability is likely to be mainly determined by differences in the structural and solvation properties and the relative abundance of the various alkaline conformers. Notably, changes in transition enthalpy and entropy among these cytochromes c are compensative and result in small variations in the free energy change of the process (which amounts approximately to +50 kJ mol(-1)) and consequently in the apparent pK(a) value. This compensation indicates that solvent reorganization effects play an important role in the thermodynamics of the transition. This mechanism is functional to ensure a relatively high pK(a) value for the alkaline transition, which is needed to preserve His,Met ligation to the heme iron in cytochrome c at physiological pH and temperature, hence the E(o) value required for the biological function.     

Proton hyperfine resonance assignments using the nuclear Overhauser effect for ferric forms of horse and tuna cytochrome c.

Proton hyperfine resonance assignments for cytochromes c from several species are currently being successfully pursued by several laboratories. These efforts focus mostly on the ferrous forms. In contrast to that work, we have pursued assignments of the proton hyperfine shifted resonances for horse and tuna ferricytochromes c. Our results indicate that assignments are nearly identical in those two proteins. Using the pre-steady state nuclear Overhauser effect, several additional assignments have been made for the tuna protein, whereas for the horse protein, the following protons have been assigned: heme 7, alpha CH2; heme 7, beta CH2; histidine 18, beta CH2 and alpha CH; and the methionine 80, beta CH2.     

pH-induced conformation changes and equilibrium unfolding in yeast iso-2 cytochrome c

The relationship between pH-induced conformational changes in iso-2 cytochrome c from Saccharomyces cerevisiae and the guanidine hydrochloride induced unfolding transition has been investigated. Comparison of equilibrium unfolding transitions at acid, neutral, and alkaline pH shows that stability toward guanidine hydrochloride denaturation is decreased at low pH but increased at high pH. In the acid range the decrease in stability of the folded protein is correlated with changes in the visible spectrum, which indicate conversion to a high-spin heme state--probably involving the loss of heme ligands. The increase in stability at high pH is correlated with a pH-induced conformational change with an apparent pK near 8. As in the case of homologous cytochromes c, this transition involves the loss of the 695-nm absorbance band with only minor changes in other optical parameters. For the unfolded protein, optical spectroscopy and 1H NMR spectroscopy are consistent with a random coil unfolded state in which amino acid side chains serve as (low-spin) heme ligands at both neutral and alkaline pH. However, the paramagnetic region of the proton NMR spectrum of unfolded iso-2 cytochrome c indicates a change in the (low-spin) heme-ligand complex at high pH. Apparently, the folded and unfolded states of the (inactive) alkaline form differ from the corresponding states of the less stable native protein.     

NMR comparison of prokaryotic and eukaryotic cytochromes c

1H NMR spectroscopy has been used to examine ferrocytochrome c-551 from Pseudomonas aeruginosa (ATCC 19429) over the pH range 3.5-10.6 and the temperature range 4-60 degrees C. Resonance assignments are proposed for main-chain and side-chain protons. Comparison of results for cytochrome c-551 to recently assigned spectra for horse cytochrome c (Wand et al. (1989) Biochemistry 28, 186-194) and mutants of yeast iso-1 cytochrome (Pielak et al. (1988) Eur. J. Biochem. 177, 167-177) reveals some unique resonances with unusual chemical shifts in all cytochromes that may serve as markers for the heme region. Results for cytochrome c-551 indicate that in the smaller prokaryotic cytochrome, all benzoid side chains are rapidly flipping on the NMR time scale. In contrast, in eukaryotic cytochromes there are some rings flipping slowly on the NMR time scale. The ferrocytochrome c-551 undergoes a transition linked to pH with a pK around 7. The pH behavior of assigned resonances provides evidence that the site of protonation is the inner or buried 17-propionic acid heme substituent (IUPAC-IUB porphyrin nomenclature). Conformational heterogeneity has been observed for segments near the inner heme propionate substituent.     

pH dependence of the oxidation-reduction potential of cytochrome c2.

The pH dependence of the spectra and of the oxidation-reduction potential of three cytochromes c2, from Rhodopseudomonas capsulata, Rhodopseudomonas sphaeroides and Rhodomicrobium vannielii, were studied. A single alkaline pK was observed for the spectral changes in all three ferricytochromes. In Rps. capsulata cytochrome c2 this spectroscopic pK corresponds to the pK observed in the dependence of oxidation-reduction potential on pH. For the other two cytochromes the oxidation-reduction potential showed a complex dependency on pH which can be fitted to theoretical curves involving three ionizations. The third ionization corresponds to the ionization observed in the spectroscopic studies but the first two occur without changes in the visible spectra. The possible structural bases for these ionizations are discussed.     

A spin label study of conformational changes in cytochrome c

Spin-labeled pig heart cytochromes c singly modified at Met-65, Tyr-74 and at one of the lysine residues, Lys-72 or Lys-73, were investigated by the ESR method under conditions of different ligand and redox states of the heme and at various pH values. Replacement of Met-80 by the external ligand, cyanide, was shown to produce a sharp increase in the mobility of all the three bound labels while reduction of the spin-labeled ferricytochromes c did not cause any marked changes in their ESR spectra. In the pH range 6-13, two conformational transitions in ferricytochrome c were observed which preceded its alkaline denaturation: the first with pK 9.3 registered by the spin label at the Met-65 position, and the second with pK 11.1 registered by the labels bound to Tyr-74 and Lys-72(73). The conformational changes in the 'left-hand part' of ferricytochrome c are most probably induced in both cases by the exchange of internal protein ligands at the sixth coordination site of the heme.     

Kinetics of electron transfer between mitochondrial cytochrome c and iron hexacyanides

The reduction of horse and Candida krusei cytochromes c by ferrocyanide has been studied by 1H NMR spectroscopy and the reaction found to involve a precursor complex of ferrocyanide bound to ferricytochrome c (pH* 7.4, 2H2O, I = 0.12, and 25 degrees C). The electron transfer rate constants for the reduction of the two ferricytochromes by associated ferrocyanide were found to be the same at 780 +/- 80 sec-1 but the association constants for binding of ferrocyanide to ferricytochrome c were significantly different: horse, 90 +/- 20 M-1 and Candida, 285 +/- 30 M-1. The different association constants partly accounts for the previously observed reactivity difference between horse and Candida cytochromes c. Comparison of the NMR data with data obtained by other kinetic methods has allowed the electron transfer rate constant for the oxidation of ferrocytochrome c by associated ferricyanide to be determined. This was found to be 4.6 +/- 1 X 10(4) sec-1.     

Spectral properties of Achromobacter xylosoxidans cytochromes c' and their NO complexes.

Cytochromes c' have been isolated from six strains of Achromobacter xylosoxidans: NCIB 11015 (formerly Alcaligenes sp. NCIB 11015), GIFU 543, 1048, 1051, 1055 and 1764. They are dimeric proteins with more positive redox potentials than those of cytochromes c' from phototrophic bacteria at neutral pH. The electronic absorption, EPR and MCD spectra on NO-ferrous cytochromes c' at physiological pH showed that the major part of the heme-iron of nitrosylheme was penta-coordinated. The EPR spectral results indicated that the ground state of the heme-iron of ferric cytochromes c' appears to be in an admixed spin states which consists of predominant high-spin with a slight intermediate-spin character at pH 7.2. These spectra were compared with those for cytochromes c' from phototrophic bacteria and the other hemoproteins.     

High-resolution three-dimensional structure of horse heart cytochrome c

The 1.94 A resolution three-dimensional structure of oxidized horse heart cytochrome c has been elucidated and refined to a final R-factor of 0.17. This has allowed for a detailed assessment of the structural features of this protein, including the presence of secondary structure, hydrogen-bonding patterns and heme geometry. A comprehensive analysis of the structural differences between horse heart cytochrome c and those other eukaryotic cytochromes c for which high-resolution structures are available (yeast iso-1, tuna, rice) has also been completed. Significant conformational differences between these proteins occur in three regions and primarily involve residues 22 to 27, 41 to 43 and 56 to 57. The first of these variable regions is part of a surface beta-loop, whilst the latter two are located together adjacent to the heme group. This study also demonstrates that, in horse cytochrome c, the side-chain of Phe82 is positioned in a co-planar fashion next to the heme in a conformation comparable to that found in other cytochromes c. The positioning of this residue does not therefore appear to be oxidation-state-dependent. In total, five water molecules occupy conserved positions in the structures of horse heart, yeast iso-1, tuna and rice cytochromes c. Three of these are on the surface of the protein, serving to stabilize local polypeptide chain conformations. The remaining two are internally located. One of these mediates a charged interaction between the invariant residue Arg38 and a nearby heme propionate. The other is more centrally buried near the heme iron atom and is hydrogen bonded to the conserved residues Asn52, Tyr67 and Thr78. It is shown that this latter water molecule shifts in a consistent manner upon change in oxidation state if cytochrome c structures from various sources are compared. The conservation of this structural feature and its close proximity to the heme iron atom strongly implicate this internal water molecule as having a functional role in the mechanism of action of cytochrome c.     

Steady state kinetics and binding of eukaryotic cytochromes c with yeast cytochrome c peroxidase.

1. The steady state kinetics for the oxidation of ferrocytochrome c by yeast cytochrome c peroxidase are biphasic under most conditions. The same biphasic kinetics were observed for yeast iso-1, yeast iso-2, horse, tuna, and cicada cytochromes c. On changing ionic strength, buffer anions, and pH, the apparent Km values for the initial phase (Km1) varied relatively little while the corresponding apparent maximal velocities varied over a much larger range. 2. The highest apparent Vmax1 for horse cytochrome c is attained at relatively low pH (congruent to 6.0) and low ionic strength (congruent to 0.05), while maximal activity for the yeast protein is at higher pH (congruent to 7.0) and higher ionic strength (congruent to 0.2), with some variations depending on the nature of the buffering ions. 3. Direct binding studies showed that cytochrome c binds to two sites on the peroxidase, under conditions that give biphasic kinetics. Under those ionic conditions that yield monophasic kinetics, binding occurred at only one site. At the optimal buffer concentrations for both yeast and horse cytochromes c, the KD1 and KD2 values approximate the Km1 and Km2 values. At ionic strengths below optimal, binding becomes too strong and above optimal, too weak. 4. Under ionic conditions that are optimal and give monophasic kinetics with horse cytochrome c but are suboptimal for the yeast protein, yeast cytochrome c strongly inhibits the reaction of horse cytochrome c with peroxidase, uncompetitively at one site and competitively at a second site. The appearance of the second site under monophasic conditions is interpreted as an allosteric effect of the inhibitor binding to the first site. 5. The simplest model accounting for these observations postulates two kinetically active sites on each molecule of peroxidase, a high affinity and a low affinity site, that may correspond to the free radical and the heme iron (IV) of the oxidized enzyme, respectively. Both oxidizing equivalents may be discharged at either site. Furthermore, the enzyme appears to exist as an equilibrium mixture of a high ionic strength form, EH and a low ionic strength form, EL, the former reacting optimally with yeast cytochrome c, and the latter with horse cytochrome c.     

Correlation of the kinetics of electron transfer activity of various eukaryotic cytochromes c with binding to mitochondrial cytochrome c oxidase.

1. A detailed study of cytochrome c oxidase activity with Keilin-Hartree particles and purified beef heart enzyme, at low ionic strength and low cytochrome c concentrations, showed biphasic kinetics with apparent Km1 = 5 x 10(-8) M, and apparent Km2 = 0.35 to 1.0 x 10(-6) M. Direct binding studies with purified oxidase, phospholipid-containing as well as phospholiptaining aid-depleted, demonstrated two sites of interaction of cytochrome c with the enzyme, with KD1 less than or equal to 10(-7) M, and KD2 = 10(-6) M. 2. The maximal velocities as low ionic strength increased with pH and were highest above ph 7.5. 3. The presence and properties of the low apparent Km phase of the kinetics were strongly dependent on the nature and concentration of the anions in the medium. The multivalent anions, phosphate, ADP, and ATP, greatly decreased the proportion of this phase and similarly decreased the amount of high affinity cytochrome c-cytochrome oxidase complex formed. The order of effectiveness was ATP greater than ADP greater than P1 and since phosphate binds to cytochrome c more strongly than the nucleotides, it is concluded that the inhibition resulted from anion interaction with the oxidase. 4mat low concentrations bakers' yeast iso-1, bakers' yeast iso-1, horse, and Euglena cytochromes c at high concentrations all attained the same maximal velocity. The different proportions of low apparent Km phase in the kinetic patterns of these cytochromes c correlated with the amounts of high affinity complex formed with purified cytochrome c oxidase. 5. The apparent Km for cytochrome c activity in the succinate-cytochrome c reductase system of Keilin-Hartree particles was identical with that obtained with the oxidase (5 x 10(-8) M), suggesting the same site serves both reactions. 6. It is concluded that the observed kinetics result from two catalytically active sites on the cytochrome c oxidase protein of different affinities for cytochrome c. The high affinity binding of cytochrome c to the mitochondrial membrane is provided by the oxidase and at this site cytochrome c can be reduced by cytochrome c1. Physiological concentrations of ATP decrease the affinity of this binding to the point that interaction of cytochrome c with numerous mitochondrial pholpholipid sites can competitively remove cytochrome c from the oxidase. It is suggested that this effect of ATP represents a possible mechanism for the control of electron flow to the oxidase.     

Proton NMR comparison of noncovalent and covalently cross-linked complexes of cytochrome c peroxidase with horse, tuna, and yeast ferricytochromes c.

Proton NMR spectroscopy at 500 and 361 MHz has been used to characterize the noncovalent or electrostatic complexes of yeast cytochrome c peroxidase (CcP) with horse, tuna, yeast isozyme-1, and yeast isozyme-2 ferricytochromes c and the covalently cross-linked complexes of cytochrome c peroxidase with horse and yeast isozyme-1 ferricytochromes c. Under the conditions employed in this work, the stoichiometry of the predominant complex formed in solution (which totaled greater than 90% of complex formed) was found to be 1:1 in all cases. These studies have elucidated significant differences in the proton NMR absorption spectra and the one-dimensional nuclear Overhauser effect difference spectra of the complexes, depending on the specific species of ferricytochrome c incorporated. In particular, the results indicate that the noncovalent complexes formed between CcP and physiological redox partners (yeast isozyme-1 or yeast isozyme-2 ferricytochromes c) are distinctly different from the noncovalent complexes formed between CcP and ferricytochromes c from horse and tuna. Parallel chemical cross-linking studies carried out using mixtures of cytochrome c peroxidase with horse ferricytochrome c, and cytochrome c peroxidase with yeast isozyme-1 ferricytochrome c further emphasize such cytochrome c-dependent differences, with only the covalently cross-linked complex of physiological redox partners (cytochrome c peroxidase/yeast isozyme-1) displaying NMR spectra characteristic of a heterogeneous mixture of different 1:1 complexes. Finally, one-dimensional nuclear Overhauser effect experiments have proven valuable in selectively and efficiently probing the protein-protein interface in these complexes, including the environment around the cytochrome c heme 3-methyl group and Phe-82.     

Kinetics of reduction by free flavin semiquinones of the components of the cytochrome c-cytochrome c peroxidase complex and intracomplex electron transfer

The kinetics of reduction by free flavin semiquinones of the individual components of 1:1 complexes of yeast ferric and ferryl cytochrome c peroxidase and the cytochromes c of horse, tuna, and yeast (iso-2) have been studied. Complex formation decreases the rate constant for reduction of ferric peroxidase by 44%. On the basis of a computer model of the complex structure [Poulos, T.L., & Finzel, B.C. (1984) Pept. Protein Rev. 4, 115-171], this decrease cannot be accounted for by steric effects and suggests a decrease in the dynamic motions of the peroxidase at the peroxide access channel caused by complexation. The orientations of the three cytochromes within the complex are not equivalent. This is shown by differential decreases in the rate constants for reduction by neutral flavin semiquinones upon complexation, which are in the order tuna much greater than horse greater than yeast iso-2. Further support for differences in orientation is provided by the observation that, with the negatively charged reductant FMNH., the electrostatic environments near the horse and tuna cytochrome c electron-transfer sites within their respective complexes with peroxidase are of opposite sign. For the horse and tuna cytochrome c complexes, we have also observed nonlinear concentration dependencies of the reduction rate constants with FMNH.. This is interpreted in terms of dynamic motion at the protein-protein interface. We have directly measured the physiologically significant intra-complex one electron transfer rate constants from the three ferrous cytochromes c to the peroxide-oxidized species of the peroxidase. At low ionic strength these rate constants are 920, 730, and 150 s-1 for tuna, horse, and yeast cytochromes c, respectively. These results are also consistent with the contention that the orientations of the three cytochromes within the complex with CcP are not the same. The effect on the intracomplex electron-transfer rate constant of the peroxidase amino acid side chain(s) that is (are) oxidized by the reduction of peroxide was determined to be relatively small. Thus, the rate constant for reduction by horse cytochrome c of the peroxidase species in which only the heme iron atom is oxidized was decreased by only 38%, indicating that this oxidized side-chain group is not tightly coupled to the ferryl peroxidase heme iron. Finally, it was found that, in the absence of cytochrome c, neither of the ferryl peroxidase species could be rapidly reduced by flavin semiquinones.(ABSTRACT TRUNCATED AT 400 WORDS)     

Protein dynamics: imidazole binding to class I C-type cytochromes.

The oxidized cytochrome c(2) from the purple phototrophic bacteria, Rhodobacter sphaeroides and Rhodobacter capsulatus, bind the neutral species of imidazole (K(a) = 1440 +/- 40 M(-1)) 50 times more strongly than does horse mitochondrial cytochrome c (K(a) = 30 +/- 1 M(-1)). The kinetics of imidazole binding are consistent with a change in rate-limiting step at high ligand concentrations for all three proteins. This is attributed to a conformational change leading to breakage of the iron-methionine bond which precedes imidazole binding. The three-dimensional structure of the Rb. sphaeroides cytochrome c(2) imidazole complex (Axelrod et al., Acta Crystalogr. D50, 596-602) supports the view that the conformational changes are essentially localized to approximately seven residues on either side of the ligated methionine and there is a hydrogen bond between the Phe 102 carbonyl, an internal water, and the bound imidazole. Insertions and deletions in this region of cytochrome c(2), the presence of a proline near the methionine, and the smaller size of the dynamic region of horse cytochrome c suggest that the stabilizing hydrogen bond is not present in horse cytochrome c, hence, the dramatic difference in affinity for imidazole. The kinetics of ligand binding do not correlate with either the strength of the iron-methionine bond as measured by the pK of the 695-nm absorption band or the overall stability of the cytochromes studied. However, the very similar imidazole binding properties of the two cytochromes c(2) indicate that the Rb. sphaeroides cytochrome c(2)-imidazole complex structure is an excellent model for the corresponding Rb. capsulatus cytochrome c(2) complex. It is notable that the movement of the peptide chain in the vicinity of the ligated methionine has been preserved throughout evolution and suggests a role in the function of c-type cytochromes.