Reduction kinetics of bacterial cytochromes c2.

In a continuing effort to understand the mechanism of electron transfer by c-type cytochromes we have extended our investigations of the oxidation and reduction of Rhodospirillum rubrum cytochrome c₂. We have utilized the oxidant, oxidized azurin, and the reductants SO₂^?, S₂O₄^2?, sodium ascorbate, and reduced azurin. The results of these studies demonstrate that, as found previously with the iron hexacyanides, electron transfer apparently takes place at the exposed heme edge. Furthermore, we report studies on the reduction of ferricytochrome c₂ from Rhodopseudomonas sphaeroides, Rhodopseudomonas capsulata, Rhodomicrobium vannielii, and Rhodopseudomonas palustris by potassium ferrocyanide. Based on the amino acid sequence homology between the various cytochromes c₂ and presumed structural homology, the observed rates of electron transport are analyzed in terms of the structure in the region of the exposed heme edge.     

Picosecond kinetics of cytochromes b5 and c

Ligand photolysis and subsequent recombination in cytochromes b5 and c have been studied with picosecond resolution. In both proteins, an iron-histidine bond is broken after excitation with 314-nm light, and recombination occurs with a rate constant of about 1.4 x 10(11) s-1. Photolysis and reformation of the iron-histidine bond may be surprising as these hemoproteins do not reversibly bind ligands in nature. The findings are explained using results both from experiments on model hemes and from computer investigations with atomic resolution on the three-dimensional structure of the protein. After photolysis, the formation and recombination of the geminate contact pair are attributed to simple low amplitude ligand bond rotations, a result that can be applied to geminate processes in other hemoproteins and model heme compounds as well.     

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.     

Catalytic activity of cytochromes c and c1 in mitochondria and submitochondrial particles.

1. Beef heart mitochondria have a cytochrome c1:c:aa3 ratio of 0.65:1.0:1.0 as isolated; Keilin-Hartree submitochondrial particles ahve a ratio of 0.65:0.4:1.0. More than 50% of the submitochondrial particle membrane is in the 'inverted' configuration, shielding the catalytically active cytochrome c. The 'endogenous' cytochrome c of particles turns over at a maximal rate between 450 and 550 s-1 during the oxidation of succinate or ascorbate plus TMPD; the maximal turnover rate for cytochrome c in mitochondria is 300-400 s-1, at 28 degrees-30 degrees C, pH 7.4. 2. Ascorbate plus N,N,N',N'-tetramethyl-p-phenylene diamine added to antimycin-treated particles induces anomalous absorption increases between 555 and 565 nm during the aerobic steady state, which disappear upon anaerobiosis; succinate addition abolishes this cycle and permits the partial resolution of cytochrome c1 and cytochrome c steady states at 552.5-547 nm and 550-556.5 nm, respectively. 3. Cytochrome c1 is rather more reduced than cytochrome c during the oxidation of succinate and of ascorbate + N,N,N',N'-tetramethyl-p-phenylene diamine in both mitochondria and submitochondrial particles; a near equilibrium condition exists between cytochromes c1 and c in the aerobic steady state, with a rate constant for the c1 leads to c reduction step greater than 10(3) s-1. 4. The greater apparent response of the c/aa3 electron transfer step to salts, the hyperbolic inhibition of succinate oxidation by azide and cyanide, and the kinetic behaviour of the succinate-cytochrome c reductase system, are all explicable in terms of a near-equilibrium condition prevailing at the c1/c step. Endogenous cytochrome c of mitochondria and submitochondrial particles is apparently largely bound to cytochrome aa3 units in situ. Cytochrome c1 can either reduce the cytochrome c-cytochrome aa3 complex directly, or requires only a small extra amount of cytochrome c to carry the full electron transfer flux.     

The oxidation-reduction kinetics of cytochromes b, c1 and c in initially fully reduced mitochondrial membranes are in agreement with the Q-cycle hypothesis

Stopped-flow experiments were performed to distinguish between two hypotheses, the Q-cycle and the SQ-cycle, each describing the pathway of electron transfer in the QH2:cytochrome c oxidoreductases. It was observed that, when mitochondrial membranes from the yeast Saccharomyces cerevisiae were poised at a low redox potential with appropriate amounts of sodium dithionite to completely reduce cytochrome b, the kinetics of oxidation of cytochrome b showed a lag period of maximally 100 ms. Under the same experimental conditions, the oxidation-reduction kinetics of cytochromes c + c1 showed transient behaviour. These results do not support the presence of a mobile species of semiquinone in the QH2:cytochrome c oxidoreductases, as envisaged in the SQ-cycle, but are consistent with a Q-cycle mechanism in which the two quinone-binding domains do not exchange electrons directly on the timescale of turnover of the enzyme.     

Membrane-bound Bacillus cytochromes c and their phylogenetic position among bacterial class I cytochromes c

Abstract Gram-positive bacteria lack a periplasmic compartment and contain only membrane-bound cytochromes c . There are at least two types. One is found in subunit II of cytochrome oxidase, and the other is small cytochrome c which is also membrane-bound because of an unprocessed signal sequence or post-translational acylation at the N-terminal end of the protein. These Bacillus cytochromes c are compared with known class I cytochromes c , and a phylogenetic tree has been constructed by the neighbour-joining method.     

The modified Q-cycle explains the apparent mismatch between the kinetics of reduction of cytochromes c1 and bH in the bc1 complex

Crystallographic structures of the bc1 complex from different sources have provided evidence that a movement of the Rieske iron-sulfur protein (ISP) extrinsic domain is essential for catalysis. This dynamic feature has opened up the question of what limits electron transfer, and several authors have suggested that movement of the ISP head, or gating of such movement, is rate-limiting. Measurements of the kinetics of cytochromes and of the electrochromic shift of carotenoids, following flash activation through the reaction center in chromatophore membranes from Rhodobacter sphaeroides, have allowed us to demonstrate that: (i) ubiquinol oxidation at the Qo-site of the bc1 complex has the same rate in the absence or presence of antimycin bound at the Qi-site, and is the reaction limiting turnover. (ii) Activation energies for transient processes to which movement of the ISP must contribute are much lower than that of the rate-limiting step. (iii) Comparison of experimental data with a simple mathematical model demonstrates that the kinetics of reduction of cytochromes c1 and bH are fully explained by the modified Q-cycle. (iv) All rates for processes associated with movement of the ISP are more rapid by at least an order of magnitude than the rate of ubiquinol oxidation. (v) Movement of the ISP head does not introduce a significant delay in reduction of the high potential chain by quinol, and it is not necessary to invoke such a delay to explain the kinetic disparity between the kinetics of reduction of cytochromes c1 and bH.     

High-resolution refinement of yeast iso-1-cytochrome c and comparisons with other eukaryotic cytochromes c

The structure of yeast iso-1-cytochrome c has been refined against X-ray diffraction data to a nominal resolution of 1.23 A. The atomic model contains 893 protein atoms, as well as 116 water molecules and one sulfate anion. Also included in the refinement are 886 hydrogen atoms belonging to the protein molecule. The crystallographic R-factor is 0.192 for the 12,513 reflections with F greater than or equal to 3 sigma (F) in the resolution range 6.0 to 1.23 A. Co-ordinate accuracy is estimated to be better than 0.18 A. The iso-1-cytochrome c molecule has the typical cytochrome c fold, with the polypeptide chain organized into a series of alpha-helices and reverse turns that serve to envelop the heme prosthetic group in a hydrophobic pocket. Inspection of the conformations of helices in the molecule shows that the local environments of the helices, in particular the presence of intrahelical threonine residues, cause distortions from ideal alpha-helical geometry. Analysis of the internal mobility of iso-1-cytochrome c, based on refined crystallographic temperature factors, shows that the most rigid parts of the molecule are those that are closely associated with the heme group. The degree of saturation of hydrogen-bonding potential is high, with 90% of all polar atoms found to participate in hydrogen bonding. The geometry of intramolecular hydrogen bonds is typical of that observed in other high-resolution protein structures. The 116 water molecules present in the model represent about 41% of those expected to be present in the asymmetric unit. The majority of the water molecules are organized into a small number of hydrogen-bonding networks that are anchored to the protein surface. Comparison of the structure of yeast iso-1-cytochrome c with those of tuna and rice cytochromes c shows that these three molecules have very high structural similarity, with the atomic packing in the heme crevice region being particularly highly conserved. Large conformational differences that are observed between these cytochromes c can be explained by amino acid substitutions. Additional subtle differences in the positioning of the side-chains of several highly conserved residues are also observed and occur due to unique features in the local environments of each cytochrome c molecule.(ABSTRACT TRUNCATED AT 400 WORDS)     

Assembly of chloroplast cytochromes b and c

The synthesis of holocytochromes in plastids is a catalyzed process. Several proteins, including plastid CcsA, Ccs1, possibly CcdA and a thioredoxin, plus at least two additional Ccs factors, are required in sub-stoichiometric amounts for the conversion of apocytochromes f and c(6) to their respective holoforms. CcsA, proposed to be a heme delivery factor, and Ccs1, an apoprotein chaperone, are speculated to interact physically in vivo. The formation of holocytochrome b(6) is a multi-step pathway in which at least four, as yet unidentified, Ccb factors are required for association of the b(H) heme. The specific requirement of reduced heme for in vitro synthesis of a cytochrome b(559)-derived holo-beta(2) suggests that cytochrome b synthesis in PSII might also be catalyzed in vivo.     

Two cytochromes c of Methylomonas J

Two kinds of c-type cytochromes, cytochrome c-551 (I), and cytochrome c-551 (II), were highly purified and crystallized from cell-free extract of methanol-grown Methylomonas J (formerly Pseudomonas sp. J) and their physiochemical and biochemical properties were studied. Cytochrome c-551 (I) had an absorption peak at 409 nm in the oxidized form and peaks at 417, 523, 551 nm, and a shoulder at 532 nm in the reduced form. The millimolar extinction coefficient of the alpha-peak of the reduced form was 25.3. The isoelectric point was at pH 5.3 and its standard redox potential was 0.29 V at pH 7.0. The molecular weight was estimated to be 16,000. Cytochrome c-551 (II) had absorption maxima at 409 nm in the oxidized form, and at 416, 521, and 551 nm in the reduced form. The millimolar extinction coefficient of the alpha-peak of the reduced form was 22.4. The isoelectric point was at pH 4.3 and its standard redox form was 22.4. The isoelectric point was at pH 4.3 and its standard redox potential was 0.24 V at pH 7.0. The molecular weight was estimated to be 12,500. The two cytochromes were reduced by methanol dehydrogenase [EC 1.1.99.8] of this bacterium, and formaldehyde was detected as an oxidation product. Ammonium chloride was not essential for reduction of the cytochromes. No significant reduction of the cytochromes was observed by methylamine dehydrogenase isolated from methylamine-grown cells or by 2,6-dichlorophenol-indophenol (DCPIP)-dependent aldehyde dehydrogenase of the methanol-grown cells. The reduced forms of the cytochromes were oxidized by blue copper protein of the methanol-grown cells.     

Structural homology of cytochromes c.

Cytochromes c from many eukaryotic and diverse prokaryotic organisms have been investigated and compared using high-resolution nuclear magnetic resonance spectroscopy. Resonances have been assigned to a large number of specific groups, mostly in the immediate environment of the heme. This information, together with sequence data, has allowed a comparison of the heme environment and protein conformation for these cytochromes. All mitochondrial cytochromes c are found to be very similar to the cytochromes c2 from Rhodospirillaceae. In the smaller bacterial cytochromes, Pseudomonas aeruginosa cytochrome c551 and Euglena gracilis cytochrome c552, the orientation of groups near the heme is very similar, but the folding of the polypeptide chain is different. The heme environment of these two proteins is similar to that of the larger bacterial and mitochondrial cytochromes. Two low-potential cytochromes, Desulfovibrio vulgaris cytochrome c553 and cytochrome c554 from a halotolerant micrococcus have heme environments which are not very similar to those of the other proteins reported here.     

Oxidation of cytochromes c and c2 by bacterial photosynthetic reaction centers in phospholipid vesicles. 1. Studies with neutral membranes

The oxidation of cytochrome c2 by photosynthetic reaction center isolated from Rhodopseudomonas sphaeroides and incorporated into unilamellar phosphatidylcholine vesicles was found to be kinetically similar to that observed earlier for reaction centers in low detergent solution [Overfield, R.E., Wraight, C.A., & DeVault, D. (1979) FEBS Lett. 105, 137-142]. At low ionic strength the kinetics were biphasic. The fast phase indicated the formation of a cytochrome-reaction center complex with an apparent binding constant, KB, of about 10(5) M-1. However, KB decreased dramatically with increasing salt concentration, and no fast oxidation was detectable in 0.1 M NaCl. The slow cytochrome oxidation was first order in both cytochrome and reaction centers and, thus, second order overall. Deviations from theoretical second-order behavior were observed when the rate of the first-order back reaction of the primary photoproducts was significant compared to the cytochrome oxidation. This can cause serious overestimation of the second-order rate constant. The slow oxidation of cytochrome c2 by reaction centers in phosphatidylcholine vesicles exhibited a 40% lower encounter frequency than with the solubilized reaction center. This was attributed to the much lower diffusion coefficient of the reaction center in the vesicle membrane than in solution. No effects of diminished dimensionality were detected with neutral vesicles. An activation energy of 8.0 +/- 0.4 kcal x mol-1 was determined for the slow phase of cytochrome c2 oxidation by reaction centers in solution and in vesicles of several different phosphatidylcholines, including dimyristoylphosphatidylcholine above and below its phase transition temperature. Thus, the physical state of the lipid did not appear to affect any rate-limiting steps leading to cytochrome oxidation. The ionic strength dependence of the slow kinetics of oxidation of cytochromes c and c2 confirmed the electrostatic nature of the cytochrome-reaction center interaction, and the pH dependence indicated the titration of a group or groups, important to this interaction, at pH 9.5.     

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.     

The two cytochromes c in the facultative methylotroph Pseudomonas AM1

It was previously suggested that there is only one soluble cytochrome c in Pseudomonas AM1, having a molecular weight of 20000, a redox midpoint potential of about +260mV and a low isoelectric pint [Anthony (1975) Biochem. J. 146, 289–298; Widdowson & Anthony (1975) Biochem. J. 152, 349–356]. A more thorough examination of the soluble fraction of methanol-grown Pseudomonas AM1 has now revealed the presence of two different cytochromes c. These were both purified to homogeneity by acid treatment, ion-exchange chromatography, gel filtration, chromatography on hydroxyapatite and preparative isoelectric focusing. Molecular weights were determined by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis; midpoint redox potentials were determined directly by using platinum and calomel electrodes; isoelectric points were estimated by electrophoresis and by the behaviour of the two cytochromes on ion-exchange celluloses. The more abundant cytochrome c_H (λ_max. 550.5nm) had a low molecular weight (11000), a midpoint potential of about +294mV and a high isoelectric point, not being adsorbed on DEAE-cellulose in 20mm-Tris/HCl buffer, pH8.0. The less abundant cytochrome c_L (λ_max. 549nm) was about 30% of the total; it had a high molecular weight (20900), a midpoint potential of about +256mV and a low isoelectric point, binding strongly to DEAE-cellulose in 20mm-Tris/HCl buffer, pH8.0. The pH-dependence of the midpoint redox potentials of the two cytochromes c were very similar. There were four ionizations affecting the redox potentials in the pH range studied (pH4.0–9.5), two in the oxidized form (pK values about 3.5 and 5.5) and two in the reduced form (pK values about 4.5 and 6.5), suggesting that the ionizing groups involved may be the two propionate side chains of the haem. Neither of the cytochromes c was present in mutant PCT76, which was unable to oxidize or grow on C₁ compounds, although still able to grow well on multicarbon compounds such as succinate. Whether or not these two cytochromes c have separate physiological functions is not yet certain.     

Design and synthesis of de novo cytochromes c

Natural c-type cytochromes are characterized by the consensus Cys-X-X-Cys-His heme-binding motif (where X is any amino acid) by which the heme is covalently attached to protein by the addition of the sulfhydryl groups of two cysteine residues to the vinyl groups of the heme. In this work, the consensus sequence was used for the heme-binding site of a designed four-helix bundle, and the apoproteins with either a histidine residue or a methionine residue positioned at the sixth coordination site were synthesized and reacted with iron protoporphyrin IX (protoheme) under mild reducing conditions in vitro. These polypeptides bound one heme per helix-loop-helix monomer via a single thioether bond and formed four-helix bundle dimers in the holo forms as designed. They exhibited visible absorption spectra characteristic of c-type cytochromes, in which the absorption bands shifted to lower wavelengths in comparison with the b-type heme binding intermediates of the same proteins. Unexpectedly, the designed cytochromes c with bis-His-coordinated heme iron exhibited oxidation-reduction potentials similar to those of their b-type intermediates, which have no thioether bond. Furthermore, the cytochrome c with His and Met residues as the axial ligands exhibited redox potentials increased by only 15-30 mV in comparison with the cytochrome with the bis-His coordination. These results indicate that highly positive redox potentials of natural cytochromes c are not only due to the heme covalent structure, including the Met ligation, but also due to noncovalent and hydrophobic environments surrounding the heme. The covalent attachment of heme to the polypeptide in natural cytochromes c may contribute to their higher redox potentials by reducing the thermodynamic stability of the oxidized forms relatively against that of the reduced forms without the loss of heme.