Cytochrome c interaction with membranes. Formylated cytochrome c.

A single species of tryptophan-59 formylated cytochrome c with a half-reduction potential of 0.085 ± 0.01 V at pH 7.0 was used to study its catalytic and functional properties. The spectral properties of the modified cytochrome show that the 6th ligand position is open to reaction with azide, cyanide, and carbon monoxide. Formylated cytochrome c binds to cytochrome c depleted rat liver and pigeon heart mitochondria with the precise stoichiometry of two modified cytochrome c molecules per molecule of cytochrome a (K_D of approx 0.1 μm). Formylated cytochrome c was reducible by ascorbate and was readily oxidized by cytochrome c oxidase. The apparent K_m value of the oxidase for the formylated cytochrome c was six times higher than for the native cytochrome and the apparent V was smaller. Formylated cytochrome c does not restore the oxygen uptake in C-depleted mitochondria but inhibits, in a competitive manner, the oxygen uptake induced by the addition of native cytochrome c. Formylated cytochrome c was inactive in the reaction with mitochondrial NADH-cytochrome c reductase but was able to accept electrons through the microsomal NADPH-cytochrome c reductase.     

Interaction of cytochrome c with cytochrome c oxidase. Photoaffinity labeling of beef heart cytochrome c oxidase with arylazido-cytochrome c.

Cytochrome c derivatives labeled with a 3-nitrophenylazido group at lysine 13, at lysine 22, or at both residues have been prepared. The interaction of the cytochrome c derivatives with beef heart cytochrome c oxidase (ferrocytochrome c:oxygen oxidoreductase, EC 1.9.3.1) in the presence of ultrviolet light results in formation of a covalent complex between cytochrome c and the oxidase. Using the lysine 22 derivative, the polypeptide composition of the oxidase is not modified, nor is its catalytic activity, whereas with the lysine 13 derivative, the gel electrophoretic pattern is altered and the catalytic activity of the complex diminished. The data are consisten with a specfic covalent interaction of the lysine 13 derivative of cytochrome c with the polypeptide of molecular weight 23,700 (Subunit II) of cytochrome c oxidase.     

Cytochrome c interactions with membranes. A photoaffinity-labeled cytochrome c.

The aryl azide, 2,4-dinitro-5-fluorophenylazide, was reacted with horse heart cytochrome c to give a photoaffinity-labeled derivative of this heme protein. The modified cytochrome c, with one to two dinitroazidophenyl groups per mole of the enzyme, has a half-reduction potential the same (± 10 mV) as native cytochrome c. The dissociation constant for the modified cytochrome c from cytochrome c-depleted mitochondrial membranes and the apparent K_m for the reaction with cytochrome c oxidase were each five to six times greater than the values for native cytochrome c. Irradiation of cytochrome c-depleted mitochondrial membranes supplemented with an excess of photoaffinity-labeled cytochrome c resulted in covalent binding of the derivative to the mitochondrial membranes. Fractionation of the irradiated mitochondria in the presence of detergents and salts followed by chromatography on agarose, Bio-Gel A, showed that labeled cytochrome c was bound covalently to cytochrome c oxidase in a 1:1 molar complex. The covalently linked cytochrome c-cytochrome c oxidase complex was active in mediating the electron transfer between N,N,N′,N′-tetramethyl-p-phenylenediamine/ascorbate and the oxidase.     

Ferricytochrome c oxidation of cobaltocytochrome c. Comparison of experiments with electron-transfer theories.

Electron transfer from cobaltocytochrome c to ferricytochrome c has been studied by stopped-flow kinetics. The second-order rate constant at pH 7.0, 0.1 ionic strenght, 0.2 M phosphate, and 25 degrees C is 8.3 x 103 M-1 s-1. The activation parameters obtained from measurements made between 20 and 50 degrees C are deltaHnot equal to = 2.3 kcal mol-1 and deltaSnot equal to = -33 eu. The rate constant is not significantly dependent on ionic strength; it is also relatively independent of pH between the pK values for conformation transitions. The rate diminishes at pH greater than 12. The self-exchange reaction of cobalt cytochrome c was investigated with pulsed Fourier transform 1H NMR. The rate is too slow on the 1H NMR scale; it is estimated to be less than 133 M-1 s-1. These results together with the self-exchange rates of iron cytochrome c [Gupta, R.K., Koenig, S. H., and Redfield, A. G. (1972), J. Magn. Reson. 7, 66] were analyzed by theories of Jortner and Hopfield. The theories predict the self-exchange of Cocyt c to be too slow for 1H NMR determination. The rate constant calculated by the nonadiabatic multiphonon electron-tunneling theory for the Fecyt c-Fecyt c+ and Cocyt c-Fecyt c+ electron transfers are in good agreement with experiments.     

Orientation ofFucus egg polarity by electric a. c. and d. c. fields

Summary Zygotes of the marine brown alga,Fucus serratus, have been subjected to the different modes of electric fields. 1) The result of a former study with conductive d.c. fields has been confirmed using electrostatic d.c. fields of 0.5 to 4 V/cm: the zygotes develop the cell polarity axis parallel to the imposed field with the rhizoid pole toward the cathode. 2) The frequency response to both, conductive and electrostatic, a.c. fields represents an optimum curve. The response,i.e. rhizoid formation at either or, in rare cases, both cell poles, peaks at square pulse durations,t _E, of 70 to 120 ms. 3) The same frequency response appears if the pulse number is kept constant at 8s^–1 by variation of the interval between the pulses,t _o. Only fort _oo > 200 ms,i.e. a pulse number of 3s^–1 the response declines markedly. The data support our hypothesis that imposed electric fields induce cell polarityvia differential shift of the membrane potential rather than transcellular current flow. Furthermore, the given dose-response curves strikingly resemble those due to the other morphogenetically active signals: percent response consistently approximates the per cent signal intensity gradient which evokes it.     

Import of cytochrome c into mitochondria. Cytochrome c heme lyase

The import of cytochrome c into mitochondria can be resolved into a number of discrete steps. Here we report on the covalent attachment of heme to apocytochrome c by the enzyme cytochrome c heme lyase in mitochondria from Neurospora crassa. A new method was developed to measure directly the linkage of heme to apocytochrome c. This method is independent of conformational changes in the protein accompanying heme attachment. Tryptic peptides of [35S]cysteine-labelled apocytochrome c, and of enzymatically formed holocytochrome c, were resolved by reverse-phase HPLC. The cysteine-containing peptide to which heme was attached eluted later than the corresponding peptide from apocytochrome c and could be quantified by counting 35S radioactivity as a measure of holocytochrome c formation. Using this procedure, the covalent attachment of heme to apocytochrome c, which is dependent on the enzyme cytochrome c heme lyase, could be measured. Activity required heme (as hemin) and could be reversibly inhibited by the analogue deuterohemin. Holocytochrome c formation was stimulated 5--10-fold by NADH greater than NADPH greater than glutathione and was independent of a potential across the inner mitochondrial membrane. NADH was not required for the binding of apocytochrome c to mitochondria and was not involved in the reduction of the cysteine thiols prior to heme attachment. Holocytochrome c formation was also dependent on a cytosolic factor that was necessary for the heme attaching step of cytochrome c import. The factor was a heat-stable, protease-insensitive, low-molecular-mass component of unknown function. Cytochrome c heme lyase appeared to be a soluble protein located in the mitochondrial intermembrane space and was distinct from the previously identified apocytochrome c binding protein having a similar location. A model is presented in which the covalent attachment of heme by cytochrome c heme lyase also plays an essential role in the import pathway of cytochrome c.     

Cytochrome c interaction with membranes. The enthalpy of oxidation of cytochromes c, c2, and a1,2.

The enthalpy of oxidation of horse-heart cytochrome c bound to phospholipid vesicles was found to be 14.6 ± 0.3 kcal/mole at 25 °C, pH 7.0, equal to the value for oxidation of the free form of the cytochrome. The affinity constants for binding of the reduced and oxidized forms of cytochrome c were the same at 4 °C and 30 °C, indicating that ΔH ° of binding contributes negligibly to the overall enthalpy of oxidation of the bound cytochrome c. The free energy (ΔG °′) of oxidation of the bound cytochrome c was 1.3 kcal/mole smaller than that for the free form, the difference being due to the change in entropy favoring the oxidized state of the cytochrome in the bound state. Measurement of the ΔH °′ for the oxidation of cytochrome a relative to the ferri/ferrocyanide couple shows it to be the same, within the limits of experimental error to that for the oxidation of cytochrome c.     

A complex of cardiac cytochrome c1 and cytochrome c.

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