Detection by 125I-cationized cytochrome c of proteoglycans and glycosaminoglycans immobilized on unmodified and on positively charged nylon 66

We have examined the detection by a 125I-labeled basic protein, cationized cytochrome c, of selected proteoglycans (PGs) and standard preparations of glycosaminoglycans (GAGs) immobilized on Nylon 66 and also on positively charged Nylon 66. Immobilization on Nylon 66 appears to allow a relative freedom of interaction between PGs or GAGs and 125I-cationized cytochrome c, but a more restricted reaction was observed when PGs and GAGs were immobilized to positively charged Nylon 66. On this support PGs with large numbers of GAG side chains reacted well with 125I-cationized cytochrome c, but GAGs were minimally reactive. By taking advantage of some of the properties of large-pore agarose-acrylamide gels, rapid partial characterization of some PGs can be accomplished in the 10-ng range, and therefore at a sensitivity equal to PGs with internal biosynthetic labels.     

Kinetics of electron transfer between cytochrome c and laccase.

Rate constants have been determined for the electron-transfer reactions between reduced horse heart cytochrome c and resting Rhus vernicifera laccase as a function of pH, ionic strength, and temperature. The second-order rate constant for the oxidation of reduced cytochrome c was determined to be k = 125 M-1 s-1 at 25 degrees C in 0.2 M phosphate buffer at pH 6.0 with the activation parameters delta H++ = 16.2 kJ mol-1 and delta S++ = 28.9 J mol-1 K-1. The rate constants increased with decreasing buffer concentration, indicating that electron transfer from cytochrome c to laccase is favored by the local electrostatic interaction (ZAZB = -0.9 at pH 6 and -1.3 at pH 4.8) between the basic proteins with positive net charges. From the increase of the rate of electron transfer with decreasing pH, one of the driving forces of the reaction was suggested to be the difference in the redox potentials between the type 1 copper in laccase and the central iron in cytochrome c. Further, on addition of one hexametaphosphate anion per cytochrome c molecule, the rate of the electron transfer was increased, probably because the association of both proteins became more favorable.     

Influence of buffer composition, membrane lipids and proteases on the kinetics of reconstituted cytochrome-c oxidase from bovine liver and heart

Isolated cytochrome-c oxidases from bovine heart and liver were reconstituted in liposomes with asolectin and the kinetics of cytochrome c oxidation were measured under various uncoupled conditions. With 40 mM KCl, 10 mM Hepes, pH 7.4, the liver enzyme showed a higher Vmax in the polarographic but a lower Vmax in the photometric assay. With 125 mM phosphate buffer at pH 6.0 both enzymes revealed identical kinetics. Reconstitution with pure phosphatidylcholine leads to a low activity, which is specifically stimulated for the heart enzyme by inclusion of 10% cardiolipin. Proteoliposomes of both enzymes prepared with asolectin have a high activity, which is unaffected by cardiolipin. Exchanging the intraliposomal buffer, Hepes, for phosphate causes an opposite change of the Vmax and a similar change of the Km for both enzymes suggesting a conformational change of the extraliposomal binding domain for cytochrome c through the membrane. Proteases change the kinetics of both enzymes, but to a different degree. The data indicate a complex and tissue-specific influence of nucleus-coded subunits on the catalytic activity of cytochrome-c-oxidase.     

Cytochrome c oxidase from bakers' yeast. Photolabeling of subunits exposed to the lipid bilayer.

Yeast mitochondria and purified yeast cytochrome c oxidase incorporated into micelles of the nonionic detergent Tween 80 were equilibrated with the hydrophobic aryl azides 5-[125I]iodonaphthyl-1-azide or S-(4-azido-2-nitrophenyl)-[35S]thiophenol. The azides were then converted to highly reactive nitrenes by flash photolysis or by illumination for 2 min and the derivatized cytochrome c oxidase subunits were identified by gel electrophoresis and radioactivity measurements. 5-[125I]Iodonaphthyl-1-azide labeled mainly the three mitochondrially made Subunits I to III and the cytoplasmically made Subunit VII. Subunits IV to VI or cytochrome c bound to the purified enzyme were labeled 9- to 90-fold less. Essentially the same result was obtained with S-(4-azido-2-nitrophenyl)-[35S]thiophenol except that Subunit V was labeled as well. In contrast, all seven subunits as well as cytochrome c were heavily labeled when the enzyme was dissociated with dodecyl sulfate prior to photolabeling with either of the two probes. These data indicate that all subunits of yeast cytochrome c oxidase except Subunits IV and VI are at least partly embedded in the lipid bilayer of the mitochondrial inner membrane.     

A simple and rapid assay for heme attachment to apocytochrome c

A method for assaying the covalent attachment of heme to apoprotein of cytochrome c was developed. 125I-labeled apoprotein was chemically prepared from 125I-labeled yeast cytochrome c (iso-1-cytochrome c). After incubation of 125I-apocytochrome c with yeast mitochondria, the product was extracted with Triton X-100, digested with trypsin in the presence or absence of a reducing agent, and then precipitated in trichloroacetic acid. The resulting precipitates were collected on nitrocellulose membranes and counted for radioactivity. The radioactivity correlated well with the appearance of a heme-containing peptide in the trypsin digested peptide fragments of cytochrome c. This procedure is simpler and faster than the previously reported methods.     

The primary structure of cytochrome c from the rust fungus Ustilago sphaerogena

1. The complete amino acid sequence of cytochrome c from the basidiomycete Ustilago sphaerogena was determined from the amino acid compositions and sequences of either tryptic or chymotryptic peptides, and in homology with at least thirty other established sequences of cytochrome c. 2. The primary structure of the molecule bears all of the characteristics of a mammalian-type cytochrome c, showing the typical clustered distribution of hydrophobic and basic residues with a single polypeptide chain of 107 residues. 3. Like all other fungal cytochromes c, it possesses a free N-terminus, and one less residue at the C-terminus than vertebrate cytochromes c. The region of residues 70-80 is strictly conserved, as is histidine at position 18. Position 26 is occupied by an asparagine residue, in contrast to histidine which occurs at this location in most of the known sequences of mammalian-type cytochromes c. 4. In contrast to some other fungal and plant cytochromes c of known primary structures, the Ustilago cytochrome c molecule does not contain trimethyl-lysine. 5. The sequence of Ustilago cytochrome c differs from the sequences of human, horse, chicken, tuna, wheat, and baker's yeast proteins at loci 47, 43, 44, 44 and 38 respectively.     

A new metal chelate affinity adsorbent for cytochrome C

We have prepared a novel metal-chelate adsorbent utilizing N-methacryloyl-L-histidine methyl ester (MAH) as a metal-chelating ligand. MAH was synthesized by using methacryloyl chloride and l-histidine methyl ester dihydrochloride. Spherical beads with an average diameter of 75-125 microm were produced by suspension polymerization of 2-hydroxyethyl methacrylate (HEMA) and MAH carried out in an aqueous dispersion medium. Then, Cu(2+) ions were chelated directly on the chelating beads. Cu(2+)-chelated beads were used in the adsorption of cytochrome c (cyt c) from aqueous solutions. The maximum cyt c adsorption capacity of the Cu(2+)-chelated beads (658.2 micromol/g Cu(2+) loading) was found to be 31.7 mg/g at pH 10 in phosphate buffer. The nonspecific cyt c adsorption on the naked PHEMA beads was 0.2 mg/g. Cyt c adsorption increased with increasing Cu(2+) loading. Cyt c adsorption capacity was demonstrated for the buffer types with the effects in the order phosphate > HEPES > MOPS > MES > Tris-HCl. Cyt c molecules could be adsorbed and desorbed five times with these adsorbents without noticeable loss in their cyt c adsorption capacity.     

Complex-formation between cytochrome c and cytochrome c peroxidase. Kinetic studies

1. The kinetics of ferrocytochrome c peroxidation by yeast peroxidase are described. Kinetic differences between the older and more recent preparations of the enzyme most probably arise from differences in intrinsic turnover rates. 2. The time-courses of cytochrome c peroxidation by the enzyme follow essentially first-order kinetics in phosphate buffer. Deviations from first-order kinetics occur in acetate buffer, and are due to a higher enzymic turnover rate in this medium accompanied by a greater tendency to autocatalytic peroxidation of cytochrome c. 3. The kinetics of ferrocytochrome c peroxidation by yeast peroxidase are interpreted in terms of a mechanism postulating formation of reversible complexes between the peroxidase and both reduced and oxidized cytochrome c. Formation of these complexes is inhibited at high ionic strengths and by polycations. 4. Oxidized cytochrome c can act as a competitive inhibitor of ferrocytochrome c peroxidation by peroxidase. The K(i) for ferricytochrome c is approximately equal to the K(m) for ferrocytochrome c and thus probably accounts for the observed apparent first-order kinetics even at saturating concentrations of ferrocytochrome c. 5. The results are discussed in terms of a possible analogy between the oxidations of cytochrome c catalysed by yeast peroxidase and by mammalian cytochrome oxidase.     

Characterization of two high molecular weight proteins immunoprecipitated with an antibody against rat liver cytochrome c oxidase

Isolated rat hepatocytes were labelled with [35S]methionine, dissolved in Triton X-100-containing buffer, and incubated with antibodies against rat liver cytochrome c oxidase. After separation by dodecyl sulfate-gel electrophoresis the fluorogram of immunoprecipitated proteins showed two labelled bands with apparent molecular weights of 52000 and 182000. The immunological relationship of the two proteins to cytochrome c oxidase was demonstrated by immunocompetition with the isolated enzyme and with purified subunits IV-VIII. Although the precursor nature of the two described proteins for cytoplasmically synthesized subunits of cytochrome c oxidase cannot be excluded, the following observations do not support this assumption: 1) The amount of incorporated radioactivity is too high; 2) they are exclusively located with the microsomal fraction; 3) the turnover is rather slow, compared to that of known precursor proteins.     

Dissociation of cytochrome c from the inner mitochondrial membrane during cardiac ischemia

Mitochondria isolated from ischemic cardiac tissue exhibit diminished rates of respiration and ATP synthesis. The present study was undertaken to determine whether cytochrome c release was responsible for ischemia-induced loss in mitochondrial function. Rat hearts were perfused in Langendorff fashion for 60 min (control) or for 30 min followed by 30 min of no flow ischemia. Mitochondria isolated from ischemic hearts in a buffer containing KCl exhibited depressed rates of maximum respiration and a lower cytochrome c content relative to control mitochondria. The addition of cytochrome c restored maximum rates of respiration, indicating that the release of cytochrome c is responsible for observed declines in function. However, mitochondria isolated in a mannitol/sucrose buffer exhibited no ischemia-induced loss in cytochrome c content, indicating that ischemia does not on its own cause the release of cytochrome c. Nevertheless, state 3 respiratory rates remained depressed, and cytochrome c release was enhanced when mitochondria from ischemic relative to perfused tissue were subsequently placed in a high ionic strength buffer, hypotonic solution, or detergent. Thus, events that occur during ischemia favor detachment of cytochrome c from the inner membrane increasing the pool of cytochrome c available for release. These results provide insight into the sequence of events that leads to release of cytochrome c and loss of mitochondrial respiratory activity during cardiac ischemia/reperfusion.     

Rhodobacter capsulatus CycH: a bipartite gene product with pleiotropic effects on the biogenesis of structurally different c-type cytochromes.

While searching for components of the soluble electron carrier (cytochrome c2)-independent photosynthetic (Ps) growth pathway in Rhodobacter capsulatus, a Ps- mutant (FJM13) was isolated from a Ps+ cytochrome c2-strain. This mutant could be complemented to Ps+ growth by cycA encoding the soluble cytochrome c2 but was unable to produce several c-type cytochromes. Only cytochrome c1 of the cytochrome bc1 complex was present in FJM13 cells grown on enriched medium, while cells grown on minimal medium contained at various levels all c-type cytochromes, including the membrane-bound electron carrier cytochrome cy. Complementation of FJM13 by a chromosomal library lacking cycA yielded a DNA fragment which also complemented a previously described Ps- mutant, MT113, known to lack all c-type cytochromes. Deletion and DNA sequence analyses revealed an open reading frame homologous to cycH, involved in cytochrome c biogenesis. The cycH gene product (CycH) is predicted to be a bipartite protein with membrane-associated amino-terminal (CycH1) and periplasmic carboxyl-terminal (CycH2) subdomains. Mutations eliminating CyCH drastically decrease the production or all known c-type cytochromes. However, mutations truncating only its CycH2 subdomain always produce cytochrome c1 and affect the presence of other cytochromes to different degrees in a growth medium-dependent manner. Thus, the subdomain CycH1 is sufficient for the proper maturation of cytochrome c1 which is the only known c-type cytochrome anchored to the cytoplasmic membrane by its carboxyl terminus, while CycH2 is required for efficient biogenesis of other c-type cytochromes. These findings demonstrate that the two subdomains of CycH play different roles in the biogenesis of topologically distinct c-type cytochromes and reconcile the apparently conflicting data previously obtained for other species.     

Electrocatalytic four-electron reduction of oxygen at the cytochrome c3-adsorbed electrode

The electrocatalytic activity of cytochrome c3 for the reduction of molecular oxygen was characterized from the studies of the adsorption of cytochrome c3 and the co-adsorption of cytochrome cs with cytochrome c on the mercury electrode by the a.c. polarographic technique. The adsorption of cytochrome c3 on the mercury electrode is irreversible and is diffusion-controlled. The maximum amount of cytochrome c3 absorbed was 0.92 . 10(-11) mol . cm-2 at -0.90 V. The amount of cytochrome c3 in the mixed adsorbed layer with cytochrome c was determined from the differential capacitance measurement. It was shown that the fractional coverage of cytochrome c3 can be estimated from its bulk concentration and the diffusion coefficient (1.05 . 10(-6) cm2 . s-1). Cytochrome c3 catalyzes the electrochemical reduction of molecular oxygen from the two-electron pathways via hydrogen peroxide to the four-electron pathway at the mercury electrode in neutral phosphate buffer solution. The catalytic activity varies with the bulk concentration of cytochrome c3. The highest catalytic activity for the oxygen reduction (no hydrogen peroxide formation) is attained when one-half of the mercury electrode surface is covered by cytochrome c3. The addition of cytochrome c or bovine serum albumin to the cytochrome c3 solution inhibits the catalytic activity of cytochrome c3. The reversible polarographic behavior of cytochrome c3 through the mixed adsorbed layer of cytochrome c3 and cytochrome c was also investigated.     

Formation of a cytochrome c-like species from horse apoprotein and hemin catalyzed by yeast mitochondrial cytochrome c synthetase

Cytochrome c synthetase in yeast mitochondria catalyzes the formation of a yeast cytochrome c-like species from the apoprotein and hemin (Basile, G., DiBello, C., and Taniuchi, H. (1980) J. Biol. Chem. 255, 7181-7191). To test the specificity of this enzyme, 125I-labeled horse apocytochrome c was incubated with the yeast mitochondrial fraction in the presence of hemin, NADPH, and an ethanol extract of the postmitochondrial fraction. A radioactive 125I-labeled cytochrome c-like species was formed in yields of up to 26%. This 125I-labeled species is indistinguishable from horse cytochrome c by ion exchange chromatography (under the conditions which allow separation of horse and yeast cytochrome c), resistance in its reduced form to digestion by trypsin, resistance against autoxidation, reduction by cytochrome b2, and generation of the apoprotein after treatment with silver sulfate and dithiothreitol. With unlabeled horse apoprotein and [59Fe]hemin, the yield of a [59Fe-labeled horse cytochrome c-like species was up to 7% with respect to the apoprotein incubated. The yield of the 59Fe-labeled species was not altered by the addition of unlabeled FeCl3. Conversely, synthesis of the 59Fe-labeled species was not detectable after incubation of yeast mitochondria with unlabeled horse apoprotein, unlabeled hemin, and 59FeCl3. The formation of both 125I- and 59Fe-labeled cytochrome c-like species was sensitive to heat. Thus, we conclude that cytochrome c synthetase catalyzes direct bonding of heme (or hemin) to the apoprotein. Since the amino acid sequences of horse and yeast cytochromes c differ considerably, cytochrome c synthetase may recognize only a limited region(s) of the apoprotein.     

Ultraviolet Micrography of Penetration of Exogenous Cytochrome c into the Yeast Cell

Candida utilis and Saccharomyces cerevisiae in water suspension were found to be very sensitive to exogenous cytochrome c. The protein was taken up by the cells, and the viable count was reduced to a few per cent of the initial value. Micrography at 405 nm revealed penetration of cytochrome c into the interior of the cell. The cytoplasmic membrane lost its capacity to retain intracellular constituents, and ultraviolet-absorbing compounds were released into the medium. When budding cells were subjected to treatment with cytochrome c, the mother cells were found to be more susceptible than the buds. Phosphate buffer protected the cells and spheroplasts against cytochrome c.     

Fluorescence and circular dichroism spectroscopy of cytochrome c in alkylammonium formate ionic liquids

The structural stability of cytochrome c has been studied in alkylammonium formate (AAF) ionic liquids such as methylammonium formate (MAF) and ethylammonium formate (EAF) by fluorescence and circular dichroism (CD) spectroscopy. At room temperature, the native structure of cytochrome c is maintained in relatively high ionic liquid concentrations (50-70% AAF/water or AAF/phosphate buffer pH 7.0) in contrast with denaturation of cytochrome c in similar solutions of methanol or acetonitrile with water or buffer cosolvents. Fluorescence and CD spectra indicate that the conformation of cytochrome c is maintained in 20% AAF-80% water from 30 to 50 °C. No such temperature stability is found in 80% AAF-20% water. About one-third of the enzyme activity of cytochrome c in 80% AAF-20% water can be maintained as compared with phosphate buffer, and this is greater than the activities measured in corresponding methanol and acetonitrile aqueous solutions. This biophysical study shows that AAFs have potential application as organic solvent replacements at moderate temperature in the mobile phase for the separation of proteins in their native form by reversed phase liquid chromatography.     

Sedimentation equilibrium studies on the interaction between cytochrome c and cytochrome c peroxidase

The interaction between cytochrome c and cytochrome c peroxidase was investigated using sedimentation equilibrium at pH 6,20 degrees C, in a number of buffer systems varying in ionic strength between 1 and 100 mM. Between 10 and 100 mM ionic strengths, the sedimentation of the individual proteins was essentially ideal, and sedimentation equilibrium experiments on mixtures of the two proteins were analyzed assuming ideal solution behavior. Analysis of the distribution of mixtures of cytochrome c and cytochrome c peroxidase in the ultracentrifuge cell based on a model involving the formation of a 1:1 cytochrome c-cytochrome c peroxidase complex gave values of the equilibrium dissociation constant ranging from 2.3 +/- 2.7 microM at 10 mM ionic strength to infinity (no detectable interaction) at 100 mM ionic strength. Attempts to determine the presence of complexes involving two cytochrome c molecules bound to cytochrome c peroxidase were inconclusive.     

The cytochrome c peroxidase-catalyzed oxidation of ferrocytochrome c by hydrogen peroxide. Steady state kinetic mechanism

Initial velocities for the cytochrome c peroxidase-catalyzed oxidation of ferrocytochrome c by hydrogen peroxide have been measured as functions of both the ferrocytochrome c (0.27-104 microM) and hydrogen peroxide (0.25-200 microM) concentrations at 25 degrees C, 0.01 M ionic strength, and pH 7 in a cacodylate/KNO3 buffer system Eadie-Hofstee plots of the initial velocity as a function of ferrocytochrome c concentration at constant hydrogen peroxide are nonlinear. A mechanism is proposed which includes random addition of the two substrates to the enzyme and a single catalytically active cytochrome c binding site. The mechanism is consistent with prior studies on cytochrome c peroxidase and fits the steady state kinetic data well.     

Effects of the medium on the rate of electron transfer in a reconstituted system of mitochondrial hydroxylation]

Effects of ionic strength, pH, viscosity, concentrations of components and nature of acceptor on the rate of NADPH oxidation and acceptor reduction were studied in a hydroxylation system containing adrenodoxin reductase, adrenodoxin and cytochrome P450 or cytochrome c. The maximal rate was observed with 0.05--0.10 M phosphate buffer, pH 6.0--6.5 and at the adrenoxin/flavoprotein/cytochrome ratio of 1 : 1 : 1. The electron transfer rate was decreased with an increase in viscosity. Cytochrome P450 is more efficient as a terminal acceptor as compared to cytochrome c or indigodisulphonate.     

Affinity chromatography purification of cytochrome c oxidase and b-c1 complex from beef heart mitochondria. Use of thiol-sepharose-bound Saccharomyces cerevisiae cytochrome c

A method for simultaneous purification of cytochrome c reductase and cytochrome c oxidase using a cytochrome c affinity column is presented. Cytochrome c from Saccharomyces cerevisiae was linked to an activated thiol-Sepharose gel via its Cys-102 residue located far from the lysine residues on the front side of the molecule, responsible for the interaction with the reductase and oxidase. In previously reported affinity chromatography techniques these lysine residues most probably reacted with the column. Cytochrome c oxidase and reductase from bovine heart mitochondria bind specifically to the affinity column and can be recovered separately at different ionic strength in the elution buffer. The enzymes are highly pure and active.     

Electron transfer between liposomal cytochrome c1 and cytochrome c: catalytic implications of electrostatic potentials

Kinetics measurements of the electron transfer between ferricytochrome c and liposomal ferrocytochrome c1 (with and without the hinge protein) were performed. The observed rate constants(kobs) of electron transfer between liposomal ferrocytochrome c1 and ferricytochrome c at different ionic strengths were measured in cacodylate buffer, pH 7.4, at 2 C. The effect of ionic strength on the rate constant(kobs) of electron transfer between liposomal cytochrome c1 and cytochrome c is far greater than that in the solution kinetics (Kim, C.H., Balny, C. and King, T.E. (1987) J. Biol. Chem. 262, 8103-8108). The result demonstrates that the membrane bound cytochrome c1 creates a polyelectrolytic microenvironment which appears to be involved in the control of electron transfer and can be modulated by the ionic strength. The involvement of electrostatic potentials in the electron transfer between the membrane bound cytochrome c1 and cytochrome c is discussed in accord with the experimental results and a polyelectrolyte theory.