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.     

The soluble cytochromes c of methanol-grown Hyphomicrobium X. Evidence against the involvement of autoreduction in electron-acceptor functioning of cytochrome cL.

Hyphomicrobium X, grown on methanol with O2 or nitrate as electron acceptor, contains two major soluble cytochromes c. These were isolated in electrophoretically homogeneous form. They are related to cytochromes c already described for other methylotrophic bacteria and designated cytochromes cH and cL (properties indicated in that order) in view of the following characteristics: absorption maxima of the reduced forms (414, 520 and 551 nm and 414, 520 and 550 nm); molar absorption coefficients of the alpha-bands (23,700 M-1.cm-1 and 21,600 M-1.cm-1); maxima of the alpha-bands (no splitting) at 77 K (547.6 nm and 548.5 nm); Mr values of the native proteins (15,000 and 19,500); pI values (7.4 and 7.5, and 4.3); midpoint potentials at pH 7.0 (+292 mV and +270 mV). Both were monomers containing 1 haem c group per protein molecule, the oxidized forms binding cyanide at high pH. Autoreduction also occurred at high pH but at a rate significantly lower than that reported for other ferricytochromes c. On the other hand, the reverse situation applies to the reduction of ferricytochrome cL by reduced methanol dehydrogenase, the reduction occurring instantaneously at pH 7 but much more slowly at pH 9 (ferricytochrome cH was reduced at a 7-fold lower rate, but the rates at pH 7 and 9 were similar). Insignificant reduction was observed with cyclopropanol-inactivated enzyme or with enzyme in the presence of EDTA. In view of the dissimilarities, it is concluded that different mechanisms operate in the autoreduction of ferricytochrome cL and in its reduction by reduced methanol dehydrogenase.     

Assignments of 15N and 1H NMR resonances and a neutral pH ionization in Rhodospirillum rubrum cytochrome c2

The phi NH proton and 15N resonances of the ligand histidine of Rhodospirillum rubrum fericytochrome c2 are found at 14.7 and 184 ppm, respectively, contradicting the proposal that this proton is absent in the R. rubrum ferricytochrome. Substitution of the deuterium atom for this proton causes small upfield shifts of the phi nitrogen in both oxidation states, indicating that the phi NH-peptide carboxyl hydrogen bond is not substantially weakened by the substitution. The proton and 15N resonances of the indolic NH group of the invariant tryptophan-62 and numerous proton resonances of the heme and extraheme ligands in the spectrum of the ferricytochrome are also assigned. An ionization in the ferrocytochrome occurring at neutral pH is assigned to the single nonligand histidine. This attribution is supported by the direct measurement of the ionization by NOE difference spectroscopy and by comparative structural arguments involving closely related cytochromes and chemically modified cytochromes.     

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.     

Evolutionary change of the heme c electronic structure: ferricytochrome c-551 from Pseudomonas aeruginosa and horse heart ferricytochrome c.

Individual assignments of the ¹H n.m.r. lines of heme c in reduced and oxidized cytochrome c-551 from $\text{Pseudomonas aeruginosa}$ were obtained by nuclear Overhauser enhancement and saturation transfer experiments. Comparison with the corresponding data on horse heart cytochrome c showed that the locations of high spin density on the heme c periphery as well as the in-plane principal axes x and y of the electronic g-tensor are rotated by approximately 90° in ferricytochrome c-551 relative to horse ferricytochrome c. High spin density in ferricytochrome c-551 is thus localized on the pyrrole ring III. While this pyrrole ring is well shielded in the interior of mammalian-type cytochromes c, it is more easily accessible in cytochrome c-551. It is suggested that this evolutionary change of the heme c electronic structure would be compatible with the hypothesis that the electron transfer in both species is via solvent exposed peripheral ring carbon atoms.     

Structure of rice ferricytochrome c at 2.0 A resolution

The crystal structure of ferricytochrome c from rice embryos has been solved by X-ray diffraction to a resolution of 2.0 A, applying a single isomorphous replacement method with anomalous scattering effects. The initial molecular model was built on a graphics display system and was refined by the Hendrickson and Konnert method. The R factor was reduced to 0.25. Rice cytochrome c consists of III amino acid residues. In comparison with animal cytochromes c, the peptide chain extends for eight residues at the N-terminal end, which is characteristic for plant cytochromes c. These additional residues display a collagen-like conformation and an irregular reverse turn, and are located around the C-terminal alpha-helix on the surface or the rear side of the molecule. Two hydrogen bonds between the carbonyl oxygen of the N-terminal acetyl group and O eta of Tyr65, and between the peptide carbonyl oxygen of Pro-1 and O epsilon 1 of Gln89, are involved in holding these eight residues on the molecular surface, where Tyr65 and Gln89 are invariant in plant cytochromes c. Except for the extra eight residues, the main-chain conformations of both rice and tuna cytochromes c are essentially identical, though small local conformational differences are found at residues 24, 25, 56 and 57.     

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.     

N.m.r. and e.p.r. characterization of [4-carboxy-2,6-dinitrophenyl-lysine]cytochromes c.

Monosubstituted [4-carboxy-2,6-dinitrophenyl-lysine]cytochromes c were investigated by n.m.r. and e.p.r. Modification of Lys-13 or Lys-72 in ferricytochrome c by 4-chloro-3,5-dinitrobenzoate yields either of two different conformers that are rapidly exchanging in the native form. The equilibrium involves small local changes in the conformation of Met-80 (the sixth ligand) and Phe-82, as a result of whether Lys-13 is the 'on' or 'off' position in the Lys-13--Glu-90 salt bridge.     

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.     

Haem ligands of the ferricytochrome c of Ustilago sphaerogena

The mammalian-type cytochrome c of the basidiomycete Ustilago sphaerogena contains in a single polypeptide chain of 107 residues, two histidine residues located at positions 18 and 33, and one methionine residue situated at position 80 (Bitar et al., 1972). The reaction of Ustilago ferricytochrome c with bromoacetate at neutral pH resulted in the modification of histidine-33, but not of histidine-18 or of the invariant methionine residue. The activities of Ustilago cytochrome c with mitochondrial cytochrome c oxidase and with NADH-cytochrome c reductase were unaltered by the modification. The equilibrium constants for the formation of low-spin complexes of the ferrihaem octapeptide of horse cytochrome c (residues 14-21, including the haem bound covalently to cysteines 14 and 17) with imidazole, N(2)-acetylhistidine and monocarboxymethyl derivatives of N(2)-acetylhistidine were determined spectrophotometrically. Alkylation of the imidazole side-chain group of N(2)-acetylhistidine resulted in a marked decrease in its ability to form low-spin ferrihaem complexes. These results indicate that in Ustilago ferricytochrome c in solution histidine-33 is not involved in the central co-ordination complex. Since side-chain groups of residues other than histidine and methionine do not appear to be involved in the central complexes of other mammalian-type cytochromes c (Hettinger & Harbury, 1964, 1965; Myer & Harbury, 1965) it is likely that in Ustilago ferricytochrome c in solution at neutral pH, the side-chain groups of histidine-18 and methionine-80 are involved in the central co-ordination complex. The latter is stable over the pH range 2.6-8.4.     

A new spatial structure for the axial methionine observed in cytochrome c5 from Pseudomonas mendocina. Correlations with the electronic structure of heme c

Cytochrome c5 from Pseudomonas mendocina has been isolated and the coordination geometry at the heme iron was investigated by 1H nuclear magnetic resonance and circular dichroism spectroscopy. Individual assignments were obtained for heme c and the axial ligands. From studies of nuclear Overhauser enhancements the axial histidine imidazole ring orientation relative to the heme group was found to coincide with that of other c-type cytochromes. In contrast, a new structure was observed for the axial methionine. This includes S chirality at the iron-bound sulfur atom, but compared to cytochromes c-551 from Pseudomonads and Rhodopseudomonas gelatinosa, which also contain S-chiral methionine, the spatial arrangement of the gamma- and beta-methylene groups and the alpha carbon of methionine is markedly different. Analysis of the electron spin density distribution in ferricytochrome c5 in the light of this new coordination geometry provides additional support for the hypothesis that the electronic structure of heme c is primarily governed by the orientation of the sp3 lone-pair orbital of the axial sulfur atom with respect to the heme plane.     

1H NMR studies of the heme iron coordination in cytochrome c-552 from Euglena gracilis.

The coordination of the heme iron in cytochrome c-552 from Euglena gracilis was investigated by 1H NMR studies at 360 MHz. The data imply that the axial heme ligands are His-14 and Met-56 in both the oxidized and the reduced protein. Studies of mixed solutions of ferro- and ferricytochrome c-552, which provided much of the information on the heme structure, also showed that the intermolecular electron exchange is characterized by a bimolecular rate constant of 5-10(6) mol-1-s-1 at 29 degrees C, which is three orders of magnitude faster than the corresponding reaction in solutions of mammalian cytochromes c.     

Cytochrome c reductase purified from Crithidia fasciculata contains an atypical cytochrome c1.

Cytochrome c reductase purified from the trypanosomatid Crithidia fasciculata retained antimycin A sensitivity and catalyzed the reduction of horse heart ferricytochrome c in the presence of reduced coenzyme Q10. The complex contained heme b and heme c1 in a ratio of 2:1. Nine major protein bands ranging in size from 55.3 to approximately 12.8 kDa were resolved by SDS-polyacrylamide gel electrophoresis. A 31.6-kDa protein was identified as cytochrome c1 by the presence of a covalently attached heme. A red shift in the alpha-absorbance band of the cytochrome c1 absolute absorbance spectrum, difference absorbance spectrum, and pyridine ferrohemochrome absorbance spectrum suggested that the heme prosthetic group of C. fasciculata cytochrome c1 is bound to the apoprotein through only one thioether bond. A fragment of the cytochrome c1 gene was amplified from C. fasciculata, Trypanosoma brucei, Leishmania tarentolae, and Bodo caudatus. The deduced heme binding site sequence of each of these kinetoplastid species, Phe-Ala-Pro-Cys-His, contains a phenylalanine rather that a cysteine at the first position so that only one thioether bond can be formed between heme and apoprotein. This phenylalanine substitution and the presence of a conserved proline in the sequence may represent compensatory changes that are necessary for optimal interaction of the cytochromes c1 with the atypical cytochromes c of these species.     

Ion binding to lysine-modified derivatives of cytochrome c.

The effect of Cl- and K+ ions on the apparent equilibrium constant of the reaction between horse ferricytochrome c and potassium ferrocyanide was studied. Unmodified cytochrome was compared with two lysine-modified derivatives. One, guanidinated, had all lysyl groups converted to homoarginine (but retained the same positive charge); the other was trinitrophenylated at one lysine (measured spectrophotometrically). Both modified derivatives had a somewhat larger equilibrium constant in the reaction of the reduced protein with ferricyanide, but, unlike trifluoroacetylated cytochrome c (which has a negative charge), the redox properties were not dramatically different. The native protein and the lysine-modified cytochromes showed differential K+ binding in Tris-cacodylate buffer at constant ionic strength (0.003-0.005 M). More K+ was bound to ferrocytochrome c. This redox-linked binding, however, was unaffected by modification of lysine. All three derivatives also showed redox-linked differential Cl- ion binding (more Cl- ion was bount to ferricytochrome); however, in this case, the binding was reduced in the lysine-modified molecules. This was interpreted as loss of a single anion site. This anion site critically depends on one or a few lysines which are more reactive with trinitrobenzene sulfonate.     

Denaturant dependence of equilibrium unfolding intermediates and denatured state structure of horse ferricytochrome c

Nuclear magnetic resonance spectroscopy is employed to characterize unfolding intermediates and the denatured state of horse ferricytochrome c in guanidine hydrochloride. Unfolded and partially unfolded species with non-native heme ligation are detected by analysis of hyperfine-shifted (1)H resonances. Two equilibrium unfolding intermediates with His-Lys heme axial ligation are detected, as are two unfolded species with bis-His heme ligation. These results are contrasted with previous results on horse ferricytochrome c denaturation by urea, for which only one unfolding intermediate and one unfolded species were detected by NMR spectroscopy. Urea and guanidine hydrochloride are often used interchangeably in protein denaturation studies, but these results and those of others indicate that unfolded and intermediate states in these two denaturants may have substantially different properties. Implications of these results for folding studies and the biological function of mitochondrial cytochromes c are discussed.     

Isolation of a multiprotein complex containing cytochrome b and c1 from Neurospora crassa mitochondria by affinity chromatography on immobilized cytochrome c. Difference in the binding between ferricytochrome c and ferrocytochrome c to the multiprotein complex.

A multiprotein complex which contains in equimolar amounts two cytochromes b (Mr each about 27,000), one cytochrome c1 (Mr 31,000) and six subunits without known prosthetic groups (Mr 8000, 12,000, 14,000, 45,000, 45,000, and 50,000) has been isolated from the mitochondrial membranes of Neurospora crassa by affinity chromatography on immobilized cytochrome c. The chromatographic separation was based upon the specific binding of the complex to ferricytochrome c coupled to Sepharose and its specific release upon conversion of the coupled ferricytochrome c into ferrocytochrome c using ascorbate as a reductant. The chromatography was performed in the presence of the nonionic detergent Triton X-100 at low ionic strengths. A monodisperse preparation of the multiprotein complex was obtained which was used for binding studies with cytochrome c from Neurospora crassa, horse heart and Saccaromyces cerevisiae. At low ionic strength (20 mM Trisacetate) and slightly alkaline pH (pH 7 to 8), more than one molecule of ferricytochrome c were bound to the isolated multiprotein complex with dissociation constants below 1 x 10(-7) M. One of these bindings appeared different from the others, since its high affinity was preserved at an ionic strength at which the affinities of the other bindings decreased. Furthermore, the affinity of only this binding decreased upon reduction of cytochrome c. It is suggested that this binding is at or near the functionally active site(s) of the mulipprotein complex.     

Reaction of c-Type Cytochromes with the Iron Hexacyanides: Mechanistic Implications

The reaction of c-cytochromes with iron hexacyanides is similar in mechanism to the interaction of cytochromes with their physiological oxidants and reductants in that the formation of complexes precedes electron transfer. Analysis of the kinetics of oxidation and reduction of a number of c-cytochromes by solving the simultaneous differential equations defining the mechanism is possible, and allows assignment of all six rate constants describing a minimum three-step mechanism [cyto(Fe(+3)) + Fe(+2) right harpoon over left harpoon cyto (Fe(+3)) - Fe(+2) right harpoon over left harpoon cyto(Fe(+2)) - Fe(+3) right harpoon over left harpoon cyto(Fe(+2)) + Fe(+3)]. We find that the usual steady-state approximations are not valid. Furthermore, the ratio of first-order rate constants for electron transfer was approximately 1.0, and no correlation was found between any of the six rate constants and the differences in oxidation-reduction potential of the iron-hexacyanides and different cytochromes c. However, it was found that the ratio of the rate constants for complex formation between ferricytochrome c and potassium ferrocyanide and ferrocytochrome c and potassium ferricyanide was proportional to the difference in oxidation-reduction potentials. Thus the minimum three-step mechanism given above accurately describes the observed kinetic data. However, this mechanism leads to a number of conceptual difficulties. Specifically, the mechanism requires that the collision complexes formed [cyto(Fe(+3)) - Fe(CN)(6) (-4) and cyto(Fe(+2)) - Fe(CN)(6) (-3)] have very different equilibrium constants, and further requires that formation of the collision complexes be accompanied by "chemistry" to make the intermediates isoenergetic. A more complex five-step mechanism which requires that the reactants [Fe(CN)(6) (-4) and ferricytochrome c or Fe(CN)(6) (-3) and ferrocytochrome c] form a collision complex followed by a first-order process before electron transfer, was found to yield results similar to those of the three-step mechanism. However, describing the formation of the collision complex in terms of a rapid equilibrium circumvents conceptual difficulties and leads to a physically reasonable mechanism. In this mechanism the reactants are in rapid equilibrium with the collision complexes and the rate constants for complex formation are controlled by diffusion and accessibility. The collision complexes then rearrange, possibly through conformational changes and/or solvent reorganization, to yield isoenergetic intermediates that can undergo rapid reversible electron transfer. The five-step mechanism can be described by the same rate constants obtained from the three-step mechanism with the appropriate adjustments to account for rapid equilibrium. This more complex analysis associates the oxidation-reduction potential of a particular cytochrome with the relative magnitude of the first-order conversion of the oxidant and reductant collision complexes to their respective intermediates. Thus the cytochromes c control their oxidation-reduction potential by chemical and/or structural alterations. This mechanism appears to be general in that it is consistent with the observed kinetics of 11 different cytochromes c from a wide variety of sources with a range of oxidation-reduction potentials.     

Kinetics and mechanism of the reduction of ferricytochrome c by the superoxide anion

The temperature and pH dependence of the reaction of the superoxide radical anion with ferricytochrome c have been measured using the pulse-radiolysis technique. The temperature dependence of the reaction at low ionic strength yields an activation energy of 31 +/- 5 kJ/mol as compared to 14 +/- 3 kJ/mol for the reaction of CO2.(-) under the same conditions. The pH dependence fits the single pK'a of ferricytochrome c of 9.1. The bimolecular rate constant for the reaction of the superoxide anion with ferricytochrome c at pH 7.8, 21 +/- 2 degrees C, in the presence of 50 mM phosphate and 0.1 mM EDTA is (2.6 +/- 0.1) X 10(5) M-1 s-1. Using this value, 1 unit of superoxide dismutase activity (McCord, J. M., and Fridovich, I. (1969) J. Biol. Chem. 244, 6049-6055) is calculated to be 3.6 +/- 0.3 pmol of enzyme if the assay is performed in a total volume of 3.0 ml. Copper ions reduce the yield of the reaction of ferricytochrome c with CO2.(-). The reactivities of native and singly modified 4-carboxy-2,4-dinitrophenyllysine cytochromes c towards the superoxide anion radical are in the order native greater than 4-carboxy-2,4-dinitrophenyllysine 60 greater than lysine 13 greater than lysine 87 greater than lysine 27 greater than lysine 86 greater than lysine 72, indicating that electron transfer takes place at or close to the solvent accessible heme edge. The mechanism of the reaction is discussed in terms of the approach of superoxide anion radicals to the heme edge and the available molecular orbitals of both heme and free radicals.