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 have 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° – 30°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 → c reduction step greater than 10³ s^?1.4. The greater apparent response of the $\text{c}\text{aa}{}_3$ 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 $\text{c}{}_1\text{c}$ 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.     

Properties of rat liver mitochondria with intermembrane Cytochrome c.

When rat liver mitochondria were suspended in 0.15 m KCl, the cytochrome c appeared to be solubilized from the binding site on the outside of the inner membrane and trapped in the intermembrane space. When the outer membrane of these mitochondria was disrupted with digitonin at a digitonin concentration of 0.15 mg/mg of protein, the solubilized cytochrome c could be released from mitochondria along with adenylate kinase. When mitochondria were suspended in 0.15 m KCl instead of 0.33 m sucrose, the $\text{ADP}\text{O}$ ratio observed with succinate, β-hydroxybutyrate, malate + pyruvate or glutamate as substrates was little affected. A number of cycles of State 4-State 3-State 4 with ADP was observed. The respiratory control ratios, however, were decreased, particularly when glutamate was used as the substrate. Cytochrome c oxidase activity was also decreased to 55% when assayed using ascorbate + N,N,N′,N′-tetramethyl-p-phenylene-diamine (TMPD) as substrates. Suspension of mitochondria in 0.15 m KCl resulted in an enhancement of the very low NADH oxidation by intact mitochondria and a twofold enhancement of sulfite oxidation. Trapped cytochrome c in outer membrane vesicles prepared from untreated and trypsin-treated intact mitochondria was found to be readily reduced by NADH and suggests that some cytochrome b₅ is located on the inner surface of the outer membrane. The enhanced NADH oxidase could therefore reflect the ability of cytochrome c to mediate intermembrane electron transport. The enhanced sulfite oxidase activity was sensitive to cyanide inhibition and coupled to oxidative phosphorylation ($\text{ADP}\text{O}\text{< 1}$) unlike the activity of mitochondria in sucrose medium. These results suggest that free cytochrome c in the intermembrane space can mediate electron transfer between the sulfite oxidase and the inner membrane.     

Impaired substrate utilization in mitochondria from strain 129 dystrophic mice

Mitochondria from skeletal muscle, heart and liver of strain 129/ReJ-dy dystrophic mice and their littermate controls were characterized with respect to their respiratory and phosphorylating activities. Skeletal muscle mitochondria from dystrophic mice showed significantly lower state 3 respiratory rates than controls with both pyruvate + malate and succinate as substrates (P < 0.01). ADP/O and Ca²⁺/O ratios were found to be normal. A decreased rate of NADH oxidation (0.01 <P < 0.05) by sonicated mitochondrial suspensions from dystrophic mice was also seen. High respiratory rates with ascorbate + phenazine methosulfate as substrates indicated that cytochrome oxidase was not rate limiting in the oxidation of either pyruvate + malate or succinate. Skeletal muscle mitochondria from dystrophic mice showed no deficiency in any of the cytochromes or coenzyme Q. Mg²⁺-stimulated ATPase activity was higher in dystrophic muscle mitochondria than in controls, but basal and oligomycin-insensitive activities were virtually identical to those of controls. A significant reduction in the intramitochondrial NAD⁺ content (0.01 <P < 0.02) was seen in dystrophic skeletal muscle as compared to controls. Heart mitochondria from dystrophic mice showed similar, though less extensive abnormalities while liver mitochondria were essentially normal. We concluded from these results that skeletal muscle mitochondria from strain 129 dystrophic mice possess impairments in substrate utilization which may result from (1) an abnormality in the transfer of electrons on the substrate side of coenzyme Q in the case of succinate oxidation; (2) a defect on the path of electron flow from NADH to cytochrome c, and (3) a deficiency of NAD⁺ in the case of NAD⁺-linked substrates.     

Properties of Ascaris muscle mitochondria. I. Cytochromes

1. The cytochrome system in Ascaris muscle mitochondria was further characterized using purer preparations.2. Difference spectra (at 22 °C and ?196 °C) of the mitochondrial preparations using succinate and ascorbate plus N,N,N′,N′-tetramethyl-p-phenylenediamine show that Ascaris muscle mitochondria contain cytochromes c₁, c and aa₃, and also at least three b-type cytochromes. The b-type cytochrome is the predominant component.3. Cytochrome c and Ascaris cytochrome b-560 can be extracted from the mitochondrial preparations with 150 mM KCl, leaving the membrane-bound cytochromes c₁, b and aa₃ in the KCl residue.     

Exogenous cytochrome c-dependent light-induced membrane potential generation in Rhodospirillum rubrum chromatophores

Rhodospirillum rubrum chromatophores associated with a planar phospholipid macromembrane by bivalent cations in the presence of quinone, N,N,N′,N′-tetramethyl-p-phenylenediamine (TMPD) and ascorbate generate a transmembrane electrical potential difference in the light. Photoelectrical activity is also observed if chromatophores are preincubated with cytochrome c; the maximum values of responses are reached upon subsequent addition of ascorbate and menadion in the absence of bivalent cations and TMPD. The cytochrome c-dependent responses of the illuminated chromatophores are inhibited by Ca²⁺ and prevented by quinones. The possibility of cytochrome c (c₂) translocation across the chromatophore membrane and the mechanism of charge transfer across the planar phospholipid membrane are discussed.     

Proton pump coupled to cytochrome c oxidase in Paracoccus denitrificans

The proton translocating properties of cytochrome c oxidase in whole cells of Paracoccus denitrificans have been studied with the oxidant pulse method.$\text{→}\text{H}{}^{\mathrm{+}}\text{2e}{}^{\mathrm{?}}$ quotients have been measured with endogenous substrates, added methanol and added ascorbate (+TMPD) as reductants, and oxygen and ferricyanide as oxidants. It was found that both the observed $\text{→}\text{H}{}^{\mathrm{+}}\text{O}$ with ascorbate (+TMPD) as reductant, and the differences in proton ejection between oxygenand ferricyanide pulses, with endogenous substrates or added methanol as a substrte, indicate that the P. denitrificans cytochrome c oxidase translocates protons with a stoichiometry of $\text{2}\text{H}{}^{\mathrm{+}}\text{2e}{}^{\mathrm{?}}$. The results presented in this and previous papers are in good agreement with recent findings concerning the mitochondrial cytochrome c oxidase, and suggest unequal charge separation by different coupling segments of the respiratory chain of P. denitrificans.     

The effect of diabetes on protein synthesis and the respiratory chain of rat skeletal muscle and kidney mitochondria

The effects of streptozotocin-induced diabetes mellitus upon mitochondria from rat skeletal muscle and kidney were examined. The rate of amino acid incorporation in vitro by isolated skeletal muscle mitochondria from diabetic animals was decreased by 50–60% from control values. Treatment of diabetic animals with insulin lowered blood glucose levels to control values and restored the rate of muscle mitochondrial protein synthesis in vitro to control levels. The rates of skeletal muscle mitochondrial protein synthesis were also decreased 23–27% by a 2-day fast. Comparison of the translation products synthesized by isolated muscle mitochondria from control and diabetic rats by dodecyl sulfate polyacrylamide-gel electrophoresis revealed a uniform decrease in the synthesis of all polypeptides. Aurintricarboxylic acid and pactamycin, inhibitors of chain initiation, blocked protein synthesis to a greater extent in muscle mitochondria from control as compared to diabetic animals suggesting that mitochondria from diabetics are unable to initiate protein synthesis at a rate comparable to control. Phenotypic changes observed in diabetic muscle mitochondria included a 36% decrease in the content of cytochromes aa₃ and a 27% decrease in cytochrome b, both established as containing mitochondrial translation products in lower eucaryotes. State 3 respiration with glutamate as substrate decreased by 27% and uncoupler-stimulated respiration decreased by 23% in the diabetic mitochondria. By contrast, the specific activities of NADH and succinate dehydrogenases, established as products of cytoplasmic protein synthesis in lower eucaryotes, were not decreased in skeletal muscle mitochondria from the diabetic animals. These results suggest that the considerable muscular atrophy observed in diabetics may involve decreases in both cytoplasmic and mitochondrial protein synthesis, the latter reflected in profound changes in the respiratory chain. By contrast, comparison of kidney mitochondria from control and diabetic rats revealed no differences in the rates of protein synthesis in vitro, nor in the mitochondrial translation products, which corresponded closely to liver and skeletal muscle translation products. Similarly, the mitochondrial content of cytochromes b, c + c₁, and aa₃, the specific activity of succinate dehydrogenase, the rate of state 3 respiration, and the recovery of mitochondria from kidney homogenates did not differ in control and diabetic animals. Kidney mitochondria are thus like liver mitochondria in being relatively unaffected by insulin deprivation.     

Funiculosin: An antibiotic with antimycin-like inhibitory properties

The antibiotic funiculosin mimics the action of antimycin in several ways. It inhibits the oxidation of NADH and succinate, but not TMPD+ascorbate. The titer for maximal inhibition in Mg²⁺-ATP particles (0.4–0.6 nmol/mg protein) is close to the concentrations of cytochromes b and cc₁. Funiculosin also induces the oxidation of cytochromes cc₁ and an extra reduction of cytochrome b in the aerobic steady state, and it inhibits duroquinol-cytochrome c reductase activity in isolated Complex III. The location of the funiculosin binding site is clearly similar to that of antimycin. In addition, funiculosin, like antimycin, prevents electron transport from duroquinol to cytochrome b in isolated Complex III if the complex is pre-reduced with ascorbate. Funiculosin and antimycin differ, however, in the manner in which they modulate the reduction of cytochrome b by ascorbate+TMPD.     

Effects of chronic ethanol treatment of mitochondrial functions damage to coupling site I

Chronic ethanol feeding to rats produces changes in hepatic mitochondria which persist in the absence of ethanol metabolism. The integrity of isolated mitochondria is well preserved, as evidenced by unchanged activities of latent, Mg²⁺- and dinitrophenol-stimulated ATPase activity, and unaltered permeability to NADH. With succinate or ascorbate as substrates, oxygen uptake by mitochondria from ethanol-fed rats was decreased compared to pair-fed controls. The decrease was comparable under state 4 or state 3 conditions, or in the presence of an uncoupler. However, with the NAD⁺-dependent substrates, ADP-stimulated oxygen consumption (state 3) was decreased to a greater extent than state 4 or uncoupler-stimulated oxygen consumption in mitochondria from ethanol-fed rats. This suggests that the decrease in energy-dependent oxygen consumption at site I may be superimposed upon damage to the respiratory chain. Using NAD⁺-dependent substrates (glutamate, α-ketoglutarate or β-hydroxybutyrate) the respiratory control ratio and the $\text{P}\text{O}$ ratio of oxidative phosphorylation were significantly decreased in mitochondria isolated from the livers of rats fed ethanol. By contrast, when succinate or ascorbate served as the electron donor these functions were unchanged. The rate of phosphorylation is decreased 70% with the NAD⁺-dependent substrates because of a decreased flux of electrons, as well as a lower efficiency of oxidative phosphorylation. With succinate and ascorbate as substrates, the rate of phosphorylation is decreased 20–30%, owing to a decreased flux of electrons. These data suggest the possibility that, in addition to effects on the respiratory chain, energy-coupling site I may be damaged by ethanol feeding. Energy-dependent Ca²⁺ uptake, supported by either substrate oxidation or ATP hydrolysis, was inhibited by chronic ethanol feeding.Concentrations of acetaldehyde (1–3 mm) which inhibited phosphorylation associated with the oxidation of NAD⁺-dependent substrates had no effect on that of succinate or ascorbate. Many of the effects of chronic ethanol feeding on mitochondrial functions are similar to those produced by acetaldehyde in vitro.     

Calcium uptake by two preparations of mitochondria from heart

Ca²⁺ transport and respiratory characteristics of two preparations of cardiac mitochondria (Palmer, J.W., Tandler, B. and Hoppel, C.L. (1977) J. Biol. Chem. 252, 8731–8739) isolated using polytron homogenization (subsarcolemmal mitochondria) and limited Nagarse exposure (intermyofibrillar mitochondria) are described.The Nagarse procedure yields mitochondria with 50% higher rates of oxidative phosphorylation than the polytron-prepared mitochondria in both rat and dog. Rat hear intermyofibrillar mitochondria contain 50% more cytochrome aa₃ than the polytron preparation, whereas in the dog, cytochrome aa₃ content is not significantly different. Cytochrome oxidase activities and cytochrome c, c₁ and b contents were comparable in both populations of rat and dog heart mitochondria.The V of succinate-supported Ca²⁺ accumulation for Nagarse-prepared mitochondria from rat heart was 1.8-fold higher than the polytron-prepared mitochondria. In dog heart, the Nagarse preparation showed a 3.0-fold higher V for Ca²⁺ uptake compared to the polytron preparation. A lower apparent affinity for Ca²⁺ was demonstrated in the intermyofibrillar mitochondria for both species (K_m is 2–2.5-fold higher). The Hill coefficient was 1 both mitochondrial types. Subsarcolemmal mitochondria from both species were treated with Nagarse to determine the role of this treatment on the observed differences. Nagarse did not alter any kinetic parameter of Ca²⁺ uptake.The properties of these mitochondria with reference to their presumed intracellular location may pertain to the role of mitochondria as an intracellular Ca²⁺ buffering mechanism in contractile tissue.     

Fuscin,an inhibitor of respiration and oxidative phosphorylation in ox-neck muscle mitochondria

1. The effect of fuscin on the mitochondrial oxidation of pyruvate plus malate, of succinate and of ascorbate plus tetramethyl-p-phenylenediamine (TMPD) and on the redox changes of succinate-reducible cytochromes b and c was investigated using tightly-coupled ox-neck muscle mitochondria.     

13th International Congress of Biochemistry

Cytochrome caa₃ (cytochrome oxidase) from the thermophilic bacterium PS3 can exhibit full catalytic activity in the presence of ascorbate and TMPD or other electron donors and in the absence of added soluble c-type cytochromes. It appears to possess only a low-affinity and not a high-affinity site for the soluble cytochromes. Proteoliposomal cytochrome caa₃ develops an effective membrane potential in the presence of ascorbate and TMPD or PMS, in the absence of added soluble cytochrome c. Reduction of the a₃ centre is blocked in the presence of cyanide. During reductive titrations of the cyanide-inhibited enzyme, electrons initially equilibrate among three centres, the c haem, the a haem and one of the associated Cu atoms. During steady-state turnover, electrons probably enter the complex via the bound c haem; the a haem and perhaps an associated Cu_A atom are reduced next. It is concluded that, despite its size and hydrophobic association with the aa₃ complex, the haem c-containing subunit can behave in an analogous way to that of mammalian cytochrome c, bound at the high-affinity site of the eucaryotic enzyme.     

Isolation of plasma membrane vesicles,derived from transverse tubules,by selective homogenization of subcellular fractions of frog skeletal muscle in isotonic media

A new technique for isolating fragmented plasma membranes from skeletal muscle has been developed that is based on gentle mechanical disruption of selected homogenate fractions. $\text{(Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}\text{)-stimulated}$, Mg²⁺-dependent ATPase was used as an enzymatic marker for the plasma membrane, Ca²⁺-stimulated, Mg²⁺-dependent ATPase as a marker for sarcoplasmic reticulum, and succinate dehydrogenase for mitochondria. Cell Cell segments in an amber low-speed ($\text{800 × g}$) pellet of a frog muscle homogenate were disrupted by repeated gentle shearing with a Polytron homogenizer. Sarcoplasmic reticulum was released into the low-speed supernatant, whereas most of the plasma membrane marker remained in a white, fluffy layer of the sediment, which contained sarcolemma and myofibrils. Additional gentle shearing of the white low-speed sediment extracted plasma membranes in a form that required centrifugation at $\text{100 000 × g}$ for pelleting. This pellet, the fragmented plasma membrane fraction, had a relatively high specific activity of $\text{(Na}{}^{\mathrm{+}}\text{+ K}{}^{\mathrm{+}}\text{)-stimulated}$ ATPase compared with the other fractions, but it had essentially no Ca²⁺-stimulated ATPase activity and only a small percentage of the succinate dehydrogenase activity of the homogenate.Experimental evidence suggests that the fragmented plasma membrane fraction is derived from delicate transverse tubules rather than from the thicker, basement membrane-coated sarcolemmal sheath of muscle cells. Electron microscopy showed small vesicles lined by a single thin membrane. Hydroxyproline, a characteristic constituent of collagen and basement membrane, could not be detected in this fraction.     

On the existence of two populations of mitochondria in a single organ. Respiration, calcium transport and enzyme activities.

Mitochondria isolated from rat heart and kidney cortex by Polytron treatment of the tissues exhibit lower state 3 rates of respiration than mitochondria isolated by Nagarse method. Addition of cytochrome $\text{c}$ to Polytron mitochondria isolated from heart, but not from kidney, increases oxygen uptake to values approaching those of Nagarse-treated preparations. Similar results were observed for Ca²⁺ uptake. Kidney Polytron mitochondria exhibited lower mitochondrial, but higher non-mitochondrial enzyme activities compared to kidney Nagarse mitochondria. Enzyme activities were the same in Polytron and Nagarse mitochondria from heart. The differences between Polytron and Nagarse mitochondria appear to be mainly due to lower cytochrome $\text{c}$ content of Polytron mitochondria from heart and higher contamination of Polytron mitochondria from kidney.     

The effect of inorganic phosphate on calcium influx into rat heart mitochondria

The effect of inorganic phosphate on the accumulation of Ca²⁺ by heart mitochondria has been reinvestigated. Inorganic phosphate has no effect on the initial rate of Ca²⁺ uptake supported by respiration on either ascorbate $\text{plus}$ tetramethylenephenylene diamine, pyruvate $\text{plus}$ malate, or glutamate $\text{plus}$ malate, although it does increase the final amount of Ca²⁺ accumulated; evidence suggests that the latter phenomenon requires phosphate influx via the phosphate carrier. It is concluded that the earlier reports that phosphate augments the initial rate of Ca²⁺ influx reflects an effect of phosphate on succinate oxidation, which was employed in the previous studies, rather than an Ca²⁺ transport itself.     

Trifluoperazine inhibition of electron transport and adenosine triphosphatase in plant mitochondria

Trifluoperazine inhibits ADP-stimulated respiration in mung bean (Phaseolus aureus) mitochondria when either NADH, malate, or succinate serve as substrates (IC50 values of 56, 59, and 55 microM, respectively). Succinate:ferricyanide oxidoreductase activity of these mitochondria was inhibited to a similar extent. The oxidation of ascorbate/TMPD was also sensitive to the phenothiazine (IC50 = 65 microM). Oxidation of exogenous NADH was inhibited by trifluoperazine even in the presence of excess EGTA [ethylene glycol bis(beta-aminoethyl ether)-N,N'-tetraacetic acid] (IC50 = 60 microM), indicating an interaction with the electron transport chain rather than with the dehydrogenase itself. In contrast, substrate oxidation in Voodoo lily (Sauromatum guttatum) mitochondria was relatively insensitive to the phenothiazine. The results suggest the bc1 complex to be a major site of inhibition. The membrane potential of energized mung bean mitochondria was depressed by micromolar concentrations of trifluoperazine, suggesting an effect on the proton-pumping capability of these mitochondria. Membrane-bound and soluble ATPases were equally sensitive to trifluoperazine (IC50 of 28 microM for both), implying the site of inhibition to be on the F1. Inhibition of the soluble ATPase was not affected by EGTA, CaCl2, or exogenous calmodulin. Trifluoperazine inhibition of electron transport and phosphorylation in plant mitochondria appears to be due to an interaction with a protein of the organelle that is not calmodulin.     

Multiple-site inhibition by colloidal elemental sulfur (S°) of respiration by mitochondria from young dormant α spores of Phomopsis viticola

Beffa, T., Pezet, R. and Turian, G. 1987. Multiple-site inhibition by colloidal elemental sulfur (S°) of respiration by mitochondria from young dormant α spores of Phomopsis viticola. Mitochondria from young dormant α spores of Phomopsis viticola Sacc. (ATCC 44940) were isolated by grinding and differential centrifugation. They presented a good integrity of their inner and outer membranes as measured by biochemical assays. Electron microscopic analysis revealed an homogenous population. The highest respiratory activities were observed with NADH and ascorbate + tetra-methyl-p-phenylenediamine (TMPD). Malate stimulated the oxidation of pyruvate, citrate or α-ketoglutarate. The coupling of respiration to oxidative phosphorylation appeared at the time of spore germination. The respiratory activities of mitochondria isolated from young dormant α spores of P. viticola were strongly inhibited by S°. The sensitivity of mitochondrial oxidation of different substrates (NADH, pyruvate + malate, succinate and ascorbate + TMPD) to S° was heterogenous and indicated multiple-site action. Thus preincubation of mitochondria with 30 μM S° before addition of substrates fully prevented NADH oxidation (>98%), and strongly inhibited oxidation of pyruvate + malate (85%), succinate (60%) and ascorbate + TMPD (74%). S° inhibited more rapidly the oxidation of succinate than that of other substrates. In the presence of dithiothreitol (DTT), S°-inhibited oxidation of all substrates (except ascorbate + TMPD) could only be transiently and weakly reestablished. The inhibitory action of S° on the oxidation of NADH, pyruvate + malate and succinate was higher than that observed with sulfhydryl group reagents such as mersalyl, Hg-acetate or p - chloromercuribenzoate. In contrast to S° these SH-group reagents could not inhibit oxidation of ascorbate + TMPD. S°, by its dual capacity to oxidize the SH-groups and to self-reduce, probably at the level of cytochrome c oxidase, could produce a modification of the oxidation state of the respiratory complexes thereby disturbing the electron flux.     

Anion and ionic strength effects upon the oxidation of cytochrome c by cytochrome c oxidase

Citrate and other polyanion binding to ferricytochrome c partially blocks reduction by ascorbate, but at constant ionic strength the citrate-cytochrome c complex remains reducible; reduction by TMPD is unaffected. At a constant high ionic strength citrate inhibits the cytochrome c oxidase reaction competitively with respect to cytochrome c, indicating that ferrocytochrome c also binds citrate, and that the citrateferrocytochrome c complex is rejected by the binding site at high ionic strength. At lower ionic strengths, citrate and other polyanions change the kinetic pattern of ferrocytochrome c oxidation from first-order towards zero-order, indicating preferential binding of the ferric species, followed by its exclusion from the binding site. The turnover at low cytochrome c concentrations is diminished by citrate but not the K_m (apparent non-competitive inhibition) or the rate of cytochrome a reduction by bound cytochrome c. Small effects of anions are seen in direct measurements of binding to the primary site on the enzyme, and larger effects upon secondary site binding. It is concluded that anion-cytochrome c complexes may be catalytically competent but that the redox potentials and/or intramolecular behaviour of such complexes may be affected when enzyme-bound. Increasing ionic strength diminishes cytochrome c binding not only by decreasing the ‘association’ rate but also by increasing the ‘dissociation’ rate for bound cytochrome c converting the ‘primary’ (T) site at high salt concentrations into a site similar kinetically to the ‘secondary’ (L) site at low ionic strength. A finite K_m of 170 μM at very high ionic strength indicates a ratio of $\text{K}{}^{\mathrm{\infty }}{}_{\mathrm{<mtext>M</mtext>}}\text{K}{}^0{}_{\mathrm{<mtext>M</mtext>}}$ of about 5000. It is proposed that anions either modify the E¹₀ of cytochrome c bound at the primary (T) site or that they perturb an equilibrium between two forms of bound c in favour of a less active form.     

Cytochrome c interaction with membranes. I. Use of a fluorescent chromophore in the study of cytochrome c interaction with artificial and mitochondrial membranes

Quenching of 12-(9-anthroyl) stearic acid (AS) fluorescence by cytochrome c occurs through an energy-transfer mechanism and can be used to measure the binding of the cytochrome to artificial and mitochondrial membranes. The quenching of AS³ fluorescence is biphasic ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}$ below 25 msec and above 500 msec) and its extent diminishes at high salt concentration or at high pH and increases in the presence of negatively charged lipids.Addition of cytochrome c to cytochrome c-depleted mitochondria results in binding of the cytochrome to the membrane and quenching of AS fluorescence. The affinity of oxidized cytochrome c for cytochrome c-depleted mitochondria is 1.8 × 10⁶m, while the affinity constant for reduced cytochrome c is 0.5 × 10⁶m. The lower affinity of the reduced cytochrome c for mitochondrial membranes is in accordance with midpoint potential differences between the bound and free forms.