Control of respiration in proteoliposomes containing cytochrome aa3. I. Stimulation by valinomycin and uncoupler

1. Both valinomycin and p-trifluoromethoxy carbonyl cyanide phenylhydrazone (FCCP) are required for full release of respiration by cytochrome c oxidase-containing proteoliposomes (prepared by sonicating beef heart cytochrome aa₃ in salt solution with 4 parts phosphatidylcholine, 4 parts phosphatidylethanolamine and 2 parts cardiolipin) in the presence of external ascorbate and cytochrome c. In the absence of valinomycin the response to FCCP is rather sluggish, as reported by Wrigglesworth et al. (1976) (Abstracts, 10th Int. Congr. Biochem., No. 06-6-230).2. The K_m for cytochrome c in 67 mM, pH 7.4, phosphate buffer with ascorbate as substrate, was 9 μM in both absence and presence of valinomycin and FCCP. Energization thus acts non-competitively towards cytochrome c oxidation.3. The apparent K_m for oxygen is greater in the energized than in the deenergized state; double reciprocal plots of respiration rate versus oxygen concentration are concave downward in the absence of uncouplers, as found with intact mitochondria. Energization thus acts “competitively” towards oxygen.4. Despite the lack of a functional ATPase system, all the kinetic features of energization found in intact mitochondria can be mimicked in the reconstituted liposomes. This supports the chemiosmotic idea that electrical and perhaps H⁺ gradients modify the oxidase activity in reconstituted vesicles.     

Oxidation of NADH by plant mitochondria: Kinetics and effects of calcium ions

The kinetics of NADH oxidation by the outer membrane electron transport system of intact beetroot (Beta vulgaris L.) mitochondria were investigated. Very different values for V_max and the K_m for NADH were obtained when either antimycin A-insensitive NADH-cytochrome c activity (V_max= 31 ± 2.5 nmol cytochrome c (mg protein)^?1 min^?1; K_m= 3.1 ± 0.8 μM) or antimycin A-insensitive NADH-ferricyanide activity (V_max= 1.7 ± 0.7 μmol ferricyanide (mg protein)^?1 min^?1; K_m= 83 ± 20 μM) were measured. As ferricyanide is believed to accept electrons closer to the NADH binding site than cytochrome c, it was concluded that 83 ± 20 μM NADH represented a more accurate estimate of the binding affinity of the outer membrane dehydrogenase for NADH. The low K_m determined with NADH-cytochrome c activity may be due to a limitation in electron flow through the components of the outer membrane electron transport chain. The K_m for NADH of the externally-facing inner membrane NADH dehydrogenase of pea leaf (Pisum sativum L. cv. Massey Gem) mitochondria was 26.7 ± 4.3 μM when oxygen was the electron acceptor. At an NADH concentration at which the inner membrane dehydrogenase should predominate, the Ca²⁺ chelator, ethyleneglycol-(β-aminoethylether)-N,N,-tetraacetic acid (EGTA), inhibited the oxidation of NADH through to oxygen and to the ubiquinone-10 analogues, duroquinone and ubiquinone-1, but had no effect on the antimycin A-insensitive ferricyanide reduction. It is concluded that the site of action of Ca²⁺ involves the interaction of the enzyme with ubiquinone and not with NADH.     

A study of the current-voltage relationships of electrogenetic active and passive membrane elements in riccia fluitans

Potassium- and proton-dependent membrane potential, conductance, and current-voltage characteristics (I–V curves) have been measured on rhizoid cells of the liverwort Riccia fluitans. The potential difference (E_m) measured with microelectrodes across plasmalemma and tonoplast is depolarized to the potassium-sensitive diffusion potential (E_D) in the presence of 1 mM NaCN, 1 mM NaN₃, or at temperatures below 6°C. Whereas the temperature change from 25°C to 5°C decreases the membrane conductance (g_m) from 0.71 to 0.43 S ? m^?2, 1 mM NaCN increases g_m by about 25%. The membrane displays potassium-controlled rectification which gradually disappears at temperatures below 5°C. The potassium pathway can be described by an equivalent circuit of a diode and an ohmic resistor in parallel. In the potential interval of E_D ± 100 mV the measured I-V curves roughly fit the theoretical curves obtained from a modified diode equation. ⁸⁶Rb⁺(K⁺)-influx is voltage sensitive: In the presence of 1 mM NaCN, ⁸⁶Rb⁺-influx follows a hyperbolic function corresponding to a low conductance at low [K⁺]_o and high conductance at high [K⁺]_o. On the contrary ⁸⁶Rb⁺-influx is linear with [K⁺]_o when pump activity is normal. It is believed that there are two K⁺-transport pathways in the Riccia membrane, one of which is assigned to the low conductance (0.2 S · m^?2), the other to a temperature-dependent facilitated diffusion system with a higher conductance (7.7 S · m^?2). The electrogenic pump essentially acts as a current source and consumes about 39% of the cellular ATP-turnover. In the presence of 30 μM CCCP the saturation current of 0.1 A · m^?2 is doubled to about 0.2 A · m^?2, and the electromotive force of ?360 mV switches to ?250 mV. It is suggested that this may be due to a change in stoichiometry from one to two transported charges per ATP hydrolyzed.     

Regulation of pyruvate oxidation in blowfly flight muscle mitochondria: Requirement for ADP

Blowfly (Phormia regina) flight muscle mitochondria oxidized pyruvate (+ proline) in the presence of either ADP (coupled respiration) or carbonylcyanide-p-trifluoromethoxyphenylhydrazone (FCCP-uncoupled respiration). There was an absolute requirement for ADP (K_m = 8.0 μm) when pyruvate oxidation was stimulated by FCCP in the presence of oligomycin. This requirement for ADP was limited to the oxidation of pyruvate; uncoupled α-glycerolphosphate oxidation proceeded maximally even in the absence of added ADP. Atractylate inhibited uncoupled pyruvate oxidation whether added before (>99%) or after (95%) initiation of respiration with FCCP. In the presence of FCCP, oligomycin, and limiting concentrations of ADP (less than 110 μm), there was a shutoff in the uptake of oxygen. This inhibition of respiration was completely reversed by the addition of more ADP. Plots of net oxygen uptake as a function of the limiting ADP concentration were linear; the observed ADP/O ratio was 0.22 ± 0.025. An ADP/O ratio of 0.2 was predicted if phosphorylation occurred only at the succinyl-CoA synthetase step of the tricarboxylate cycle. Experiments performed in the presence of limiting concentrations of ADP, and designed to monitor changes in the mitochondrial content of ADP and ATP, demonstrated that the shutoff in oxygen uptake was not due to the presence of a high intramitochondrial concentration of ATP. Indeed, ATP, added to the medium prior to the addition of FCCP, inhibited uncoupled pyruvate oxidation; the apparent K_I was 0.8 mm. These results are consistent with the hypothesis that it is the intramitochondrial ATP/ADP ratio that is one of the controlling factors in determining the rate of flux through the tricarboxylate cycle. Changes in the mitochondrial content of citrate, isocitrate, α-ketoglutarate, and malate during uncoupled pyruvate oxidation in the presence of a limiting concentration of ADP were consistent with the hypothesis that the mitochondrial NAD⁺-linked isocitric dehydrogenase is a major site for such control through the tricarboxylate cycle.     

The membrane potential of intact Rhodospirillum rubrum cells in the absence of light-dependent and oxygen-linked electron transfer

In the absence of oxygen-linked and light-dependent electron transfer, the steady-state membrane potential of intact Rhodospirillum rubrum cells was usually between 65 and 75% of that of dark aerated cells, as indicated by the relative extent of the bacteriochlorophyll electrochromic changes that were induced by oxygen and by uncouplers. That potential was not due to residual levels of oxygen or light, because its value was not significantly altered by the presence of oxygen-trapping systems or by exhaustive gassing with Ar, and because it was also exhibited by a reaction-center-less mutant. The dark anaerobic potential was unaffected by 0.11 M K⁺; that seemed to exclude a diffusion potential generated by dissipation of a previously built K⁺ gradient. In contrast, it was largely abolished by 0.5 mM N,N′-dicyclohexylcarbodiimide, suggesting its dependence on ATP hydrolysis by the proton-translocating ATPase of the bacterial membrane. That was not expected because R. rubrum did not grow fermentatively under the conditions used. Low concentrations of protonophores were more effective in dissipating the anaerobic than the aerobic membrane potential. That observation indicated a lower activity of the electrogenic system responsible for the anaerobic potential. In consequence, the addition of uncouplers at low levels resulted in a marked enhancement of the membrane potential decrease which followed the transition between the aerobic and the anaerobic steady states.     

Anandamide inhibits oxidative phosphorylation in isolated liver mitochondria

A study on the effect of anandamide (AEA) in energy coupling of rat liver mitochondria is presented. Micromolar concentrations of AEA, while almost ineffective on substrate supported oxygen consumption rate and on uncoupler stimulated respiration, strongly inhibited the respiratory state III. AEA did not change the rate and the extent of substrate generated membrane potential, but markedly delayed rebuilding by respiration of the potential collapsed by ADP addition. Overall, these data suggest that anandamide inhibits the oxidative phosphorylation process. Direct measurement of the F_oF₁ ATP synthase activity showed that the oligomycin sensitive ATP synthesis was inhibited by AEA, (IC₅₀, 2.5 μM), while the ATP hydrolase activity was unaffected. Consistently, AEA did not change the membrane potential generated by ATP hydrolysis.     

Tolbutamide-sensitive potassium conductance in the basolateral membrane of A6 cells

K⁺ channels sensitive to intracellular ATP (K_ATP channels) have been described in a number of cell types and are selectively inhibited by sulfonylurea drugs. To look for the presence of this type of K⁺ channel in the basolateral membrane of tight epithelia, we have used an amphibian renal cell line, the A6 cells, grown on filters. After the selective permeabilization of the apical membrane with amphotericin B, the basolateral conductance was studied under voltage-clamp conditions. Tolbutamide inhibited 65.8 ± 6.3% of the barium-sensitive current. The tolbutamide-sensitive conductance had an equilibrium potential of ?83 ± 1 mV and was inward rectifying in spite of the outwardly directed K⁺ gradient. Similar results were obtained with glibenclamide. The half-inhibition constants were 25.7 ± 3.0 μm and 0.114 ± 0.018 μm for tolbutamide and glibenclamide respectively. To study the relation between cellular ATP and the activity of this conductance, A6 cells were treated with glucose (5 mm) and insulin (250 μU/ml). This maneuver significantly increased the cellular ATP and abolished the tolbutamide-sensitive conductance. A sulfonylurea-sensitive K⁺ conductance is present and active in the basolateral membrane of A6 cells. This conductance appears to be modulated by physiological changes of intracellular ATP.     

Short-and long-term effects of cadmium on transmembrane electric potential (E m) in maize roots

In this study, the effects of Cd on root growth, respiration, and transmembrane electric potential (E _m) of the outer cortical cells in maize roots treated with various Cd concentrations (from 1 μM to 1 mM) for several hours to one week were studied. The E _m values of root cells ranged between −120 and −140 mV and after addition of Cd they were depolarized immediately. The depolarization was concentration-dependent reaching the value of diffusion potential (E _D) when the Cd concentration exceeded 100 μM. The values of E _D ranged between −65 to −68 mV (−66 ± 1.42 mV). The maximum depolarization of E _m was registered approx. 2.5 h after addition of Cd to the perfusion solution and in some cases, partial (Cd > 100 μM) or complete repolarization (Cd < 100 μM) was observed within 8–10 h of Cd treatment. In the time-dependent experiments (0 to 168 h) shortly after the maximum repolarization of E _m a continuous concentration-dependent decrease of E _m followed at all Cd concentrations. Depolarization of E _m was accompanied by both increased electrolyte leakage and inhibition of respiration, especially in the range of 50 μM to 1 mM Cd, with the exception of root cells treated with 1 and 10 μM Cd for 24 and 48 h. Time course analysis of Cd impact on root respiration revealed that at higher Cd concentrations (> 50 μM) the respiration gradually declined (∼ 6 h) and then remained at this lowest level for up to 24 h. All the Cd concentrations used in this experiment induced significant inhibition of root elongation and concentrations higher than 100 μM stopped the root growth within the first day of Cd treatment. Our results suggest that Cd does not cause irreversible changes in the electrogenic plasma membrane H⁺ ATPase because fusicoccin, an H⁺ ATPase activator diminished the depolarizing effect of Cd on the E _m. The depolarization of E _m in the outer cortical cells of maize roots was the result of a cumulative effect of Cd on ATP supply, plasmalemma permeability, and activity of H⁺ ATPase.     

Relation between the reaction cytochrome oxidase-oxygen and oxygen uptake in cells in vivo. The role of diffusion

Before reaching the oxidase located inside the cell on the mitochondrial membrane, oxygen may be slowed down by diffusion within the cytoplasm. Diffusion or enzymic activity may predominate and this is related to the size and morphology of the organism, the intracellular diffusion coefficient, and the K_m of the oxidizing terminal enzyme. This K_m may be apparently diminished by inhibitors. Different experimental situations can arise in some plants (where oxygen diffusion in bulk tissue is not important in comparison to that in cell): either oxygen diffusion is limiting, or diffusion and an enzymic reaction compete, or diffusion does not slow down the respiratory rate. A mathematical model relates the oxygen concentration in the external medium, to the rate of oxygen uptake at the oxygen cytochrome-oxidase reaction level.     

The high affinity of Paracoccus denitrificans cells for nitrate as an electron acceptor. Analysis of possible mechanisms of nitrate and nitrite movement across the plasma membrane and the basis for inhibition by added nitrite of oxidase activity in permeabilised cells

(1) The apparent K_m for nitrate of the electron-transport system in intact cells of Paracoccus denitrificans was less than 5 μM. In contrast the apparent K_m for nitrate of inverted membrane vesicles oxidising NADH was greater than 50 μM. When azide, a competitive inhibitor, was present, the apparent K_m observed with the vesicles was raised to 0.64 mM, consistent with values previously reported for purified preparations of the reductase. In membrane vesicles the nitrate reductase is probably not rate-limiting for NADH-nitrate oxido-reductase activity, and thus a lower limit for K_m (NO₃⁻) is obtained. It is suggested that the very low K_m (NO₃⁻) in intact cells must arise from either a transport process or a nitrate-specific pore that allows access of nitrate directly to the active site of its reductase from the periplasm. (2) The swelling of spheroplasts has been studied under both aerobic and anaerobic conditions to probe possible mechanisms of nitrate and nitrite transport across the plasma membrane of P. denitrificans. Nitrate reductase was inhibited by azide to prevent reduction of internal nitrate. No evidence for operation of either nitrate-nitrite antiport or proton-nitrate symport was obtained. (3) Measurements from the fluorescence intensity of 8-anilino-naphthalene-1-sulphonate of the rates of decay of diffusion potentials generated by addition of potassium salts to valinomycin-treated plasma membrane vesicles from P. denitrificans showed that the permeability of the membrane to anions is SCN⁻ > NO₃⁻, NO₂⁻, pyruvate, acetate > CI⁻ > SO₄²⁻. In the presence of a protonophore the rate of decay of the diffusion potential was considerably enhanced with potassium acetate or potassium nitrite, but not with potassium salts of nitrate, chloride or pyruvate. This result indicates that HNO₂ and CH₃COOH can rapidly and passively diffuse across the cell membrane. This finding suggests that transport systems for nitrite are in general probably not required in bacteria. The failure of a protonophore to enhance the dissipation of the diffusion potential generated by potassium nitrate is evidence against the operation of a proton-nitrate symporter. (4) Low concentrations of added nitrite very strongly inhibit electron flow to oxygen in anaerobically grown cells, provided that they have been treated with Triton X-100 or an uncoupler. This inhibition is not observed with aerobically grown cells. It is concluded that the inhibitory species is a reaction product or an intermediate of the nitrite reductase reaction. The requirement for collapse of protonomotive force by uncoupler or permeabilising the plasma membrane suggests that any such species could be negatively charged. Nitroxyl anion (NO⁻) can be considered, as its conjugate acid is a postulated intermediate between nitrite and nitrous oxide; nitroxyl anion can bind to heme centres to give nitrosyl derivatives. (5) The basis for the ability of permeabilised, but not intact, cells of P. denitrificans to reduce oxygen and nitrate simultaneously is discussed.     

Measurements of membrane potentials in plant mitochondria with the safranine method

The positively charged dye, safranine, has been used as an indicator of membrane potentials in mung bean (Phaseolus aureus) and Voodoo lily (Sauromatum guttatum) mitochondria under a variety of metabolic conditions. The spectral response of safranine has been calibrated with respect to a K⁺ diffusion potential and was found to be linearly related to the developed potential within the range of 50 to 160 millivolts. Both respiration and ATP hydrolysis gave rise to a membrane potential of approximately 135 millivolts. Respiratory inhibitors such as cyanide and antimycin depolarized the potential, whereas rotenone has little effect. No potentials were developed during NADH supported cyanide insensitive respiration. It is concluded that safranine may be a useful spectrophotometric probe of the mitochondrial membrane potential.     

Investigation of the subcellular distribution of cyclic-AMP phosphodiesterase in rat hepatocytes,using a rapid immunological procedure for the isolation of plasma membrane

The distribution of cyclic-AMP phosphodiesterase was investigated in subcellular fractions prepared from homogenates of rat liver or isolated hepatocytes. When measured at 1 mM or 1 μM substrate concentration, approx. 35% or 50%, respectively, of enzyme activity was particulate. The soluble activity appeared to be predominantly a ‘high K_m’ form, whereas the particulate activity had both ‘high K_m’ and ‘low K_m’ components. The recovery of cyclic-AMP phosphodiesterase was measured using 1 μM substrate concentration, in plasma membrane-containing fractions prepared either by centrifugation or by the use of specific immunoadsorbents. The recovery of phosphodiesterase was lower than that of marker enzymes for plasma membrane, and comparable with the recovery of markers for intracellular membranes. It was concluded that regulation of both ‘high K_m’ and ‘low K_m’ phosphodiesterase could potentially make a significant contribution to the control of cyclic AMP concentration, even at μM levels, in the liver. The ‘low K_m’ enzyme, for which activation by hormones has been previously described, appears to be located predominantly in intracellylar membranes in hepatocytes.The immunological procedure for membrane isolation allowed the rapid preparation of plasma membranes in high yield. Liver cells were incubated with rabbit anti-(rat erythrocyte) serum and homogenized. The antibody-coated membrane fragments were then extracted onto an immunoadsorbent consisiting of sheep anti-(rabbit IgG) immunoglobulin covalently bound to aminocellulose. Plasma membrane was obtained in approx. 40% yield within 50 min of homogenizing cells.     

Mitochondrial respiration and membrane potential are regulated by the allosteric ATP-inhibition of cytochrome c oxidase

This paper describes the problems of measuring the allosteric ATP-inhibition of cytochrome c oxidase (CcO) in isolated mitochondria. Only by using the ATP-regenerating system phosphoenolpyruvate and pyruvate kinase full ATP-inhibition of CcO could be demonstrated by kinetic measurements. The mechanism was proposed to keep the mitochondrial membrane potential (?Ψ_m) in living cells and tissues at low values (100-140 mV), when the matrix ATP/ADP ratios are high. In contrast, high ?Ψ_m values (180-220 mV) are generally measured in isolated mitochondria. By using a tetraphenyl phosphonium electrode we observed in isolated rat liver mitochondria with glutamate plus malate as substrates a reversible decrease of ?Ψ_m from 233 to 123 mV after addition of phosphoenolpyruvate and pyruvate kinase. The decrease of ?Ψ_m is explained by reversal of the gluconeogenetic enzymes pyruvate carboxylase and phosphoenolpyruvate carboxykinase yielding ATP and GTP, thus increasing the matrix ATP/ADP ratio. With rat heart mitochondria, which lack these enzymes, no decrease of ?Ψ_m was found. From the data we conclude that high matrix ATP/ADP ratios keep ?Ψ_m at low values by the allosteric ATP-inhibition of CcO, thus preventing the generation of reactive oxygen species which could generate degenerative diseases. It is proposed that respiration in living eukaryotic organisms is normally controlled by the ?Ψ_m-independent “allosteric ATP-inhibition of CcO.” Only when the allosteric ATP-inhibition is switched off under stress, respiration is regulated by “respiratory control,” based on ?Ψ_m according to the Mitchell Theory.     

Changes in membrane potential during calcium ion influx and efflux across the mitochondrial membrane

1. A depolarisation of the membrane of rat liver mitochondria, as measured with the safranine method, is seen during Ca²⁺ uptake. The depolarisation is followed by a slow repolarisation, the rate of which can be increased by the addition of EGTA or phosphate.2. Plots relating the initial rate of calcium ion (Ca²⁺) uptake and the decrease in membrane potential (Δψ) to the Ca²⁺ concentration show a half-maximal change at less than 10 μM Ca²⁺ and a saturation above 20 μM Ca²⁺.3. Plots relating the initial rate of Ca²⁺ uptake to Δψ are linear.4. Addition of Ca²⁺ chelators, nitriloacetate or EGTA, to deenergized mitochondria equilibrated with Ca²⁺ causes a polarisation of the mitochondrial membrane due to a diffusion potential created by electrogenic Ca²⁺ efflux.5. If the extent of the response induced by different nitriloacetate concentrations is plotted against the expected membrane potential a linear plot is obtained up to 70 mV with a slope corresponding to two-times the extent of the response induced by valinomycin in the presence of different potassium ion gradients. This suggests that the Ca²⁺ ion is transferred across the membrane with one net positive charge in present conditions.     

Relationship between membrane potential and external potassium in human glioblastoma cells in tissue culture

Cells from a human glioblastoma (TC 526) maintained in tissue culture for ten years had a mean membrane potential of 27 ± 0.9 mV at an external potassium concentration [K₀] of 5.3 mM. When [K₀] was varied between 2.5 and 5.3 mM, membrane potential changes were close to those predicted by the Nernst equation. At higher [K₀], the Nernstian slope was approached only in the presence of 10^?5 M ouabain, which did not affect membrane potential at a [K₀] of 5.3 mM. An electrogenic sodium pump activated by high [K₀] could explain these findings; such a mechanism has been demonstrated in other tissues.     

High efficiency versus maximal performance — The cause of oxidative stress in eukaryotes: A hypothesis

Degenerative diseases are in part based on elevated production of ROS (reactive oxygen species) in mitochondria, mainly during stress and excessive work under stress (strenuous exercise). The production of ROS increases with increasing mitochondrial membrane potential (ΔΨ_m). A mechanism is described which is suggested to keep ΔΨ_m at low values under normal conditions thus preventing ROS formation, but is switched off under stress and excessive work to maximize the rate of ATP synthesis, accompanied by decreased efficiency. Low ΔΨ_m and low ROS production are suggested to occur by inhibition of respiration at high [ATP]/[ADP] ratios. The nucleotides interact with phosphorylated cytochrome c oxidase (COX), representing the step with the highest flux-control coefficient of mitochondrial respiration. At stress and excessive work neural signals are suggested to dephosphorylate the enzyme and abolish the control of COX activity (respiration) by the [ATP]/[ADP] ratio with consequent increase of ΔΨ_m and ROS production. The control of COX by the [ATP]/[ADP] ratio, in addition, is proposed to increase the efficiency of ATP production via a third proton pumping pathway, identified in eukaryotic but not in prokaryotic COX. We conclude that ‘oxidative stress’ occurs when the control of COX activity by the [ATP]/[ADP] ratio is switched off via neural signals.     

Properties and regulation of a trans-plasma membrane redox system of perfused rat heart

Ferricyanide was reduced to ferrocyanide by the perfused rat heart at a linear rate of 78 nmol/min per g of heart (non-recirculating mode). Ferricyanide was not taken up by the heart and ferrocyanide oxidation was minimal (3 nmol/min per g of heart). Perfusate samples from hearts perfused without ferricyanide did not reduce ferricyanide. A single high-affinity site (apparent K_m=22 μM) appeared to be responsible for the reduction. Perfusion of the heart with physiological medium containing 0.5 mM ferricyanide did not alter contractility, biochemical parameters or energy status of the heart. Perfusate flow rate and perfusate oxygen concentration exerted opposing effects on the rate of ferricyanide reduction. A net decreased reduction rate resulted from a decreased perfusion flow rate. Thus, the rate of supply of ferricyanide dominated over the stimulatory effect of oxygen restriction; the latter effect only becoming apparent when the oxygen concentration was lowered at a high perfusate flow rate. Whereas glucose (5 mM) increased the rate of ferricyanide reduction, pyruvate (2 mM), acetate (2 mM), lactate (2 mM) and 3-hydroxybutyrate (2 mM) each had no effect. Insulin (3 nM), glucagon (0.5 μM), dibutyryl cyclic AMP (0.1 mM) and the β-adrenergic agonist ritodrine (10 μM) also had no effect, however the α₁-adrenergic agonist, methoxamine (10 μM), produced a net increase in the rate of ferricyanide reduction. It is concluded that a trans-plasma membrane electron efflux occurs in perfused rat heart that is sensitive to oxygen supply, glucose, perfusion flow rate, and the α-adrenergic agonist methoxamine.     

Reaction of oxygen with the respiratory chain in cells and tissues

This paper considers the way in which the oxygen reaction described by Dr. Nicholls and the ADP control reactions described by Dr. Racker could cooperate to establish a purposeful metabolic control phenomenon in vivo. This has required an examination of the kinetic properties of the respiratory chain with particular reference to methods for determinations of oxygen affinity (K_m). The constant parameter for tissue respiration is k ₁, the velocity constant for the reaction of oxygen with cytochrome oxidase. Not only is this quantity a constant for a particular tissue or mitochondria; it appears to vary little over a wide range of biological material, and for practical purposes a value of 5 x 10⁷ at 25° close to our original value (20) is found to apply with adequate accuracy for calculation of K_m for mammalia. The quantity which will depend upon the tissue and its metabolic state is the value of K_m itself, and K_m may be as large as 0.5 µM and may fall to 0.05 µM or less in resting, controlled, or inhibited states. The control characteristic for ADP may depend upon the electron flux due to the cytochrome chain (40); less ADP is required to activate the slower electron transport at lower temperatures than at higher temperatures. The affinity constants for ADP control appear to be less dependent upon substrate supplied to the system. The balance of ADP and oxygen control in vivo is amply demonstrated experimentally and is dependent on the oxygen concentration as follows. In the presence of excess oxygen, control may be due to the ADP or phosphate (or substrate), and the kinetics of oxygen utilization will be independent of the oxygen concentration. As the oxygen concentration is diminished, hemoglobin becomes disoxygenated, deep gradients of oxygen concentration develop in the tissue, and eventually cytochrome oxidase becomes partially and then completely reduced. DPN at this point will become reduced and the electron flow diminished. The rate of ATP production falls and energy conservation previously under the control of the ADP concentration will now be controlled by the diffusion of oxygen to the respiratory enzymes in the mitochondria. Under these conditions the rate of reaction of cytochrome oxidase with oxygen and the reaction of cytochromes with one another become of key importance. The rise of ADP and the depletion of energy reserves evoke glycolytic activity, and failure of biological function may result.     

Inhibition of oxygen consumption in skeletal muscle-derived mitochondria by pinacidil,diazoxide, and glibenclamide,but not by 5-hydroxydecanoate

Cell intermediary metabolism and energy production succeeds by means of mitochondria, whose activity is in relation to transmembrane potential and/or free radical production. Adenosine triphosphate (ATP)-dependent potassium channels (K_ATP) in several cell types have shown to couple cell metabolism to membrane potential and ATP production. In this study, we explore whether oxygen consumption in isolated skeletal-muscle mitochondria differs in the presence of distinct respiration substrates and whether these changes are affected by K_ATP-channel inhibitors such as glibenclamide, 5-Hydroxydecanoate (5-HD), and K_ATP channel activators (pinacidil and diazoxide). Results demonstrate a concentration-dependent diminution of respiration rate by glibenclamide (0.5–20 μM), pinacidil (1–50 μM), and diazoxide (50–200 μM), but no significant differences were found when the selective mitochondrial K_ATP-channel inhibitor (5-HD, 10–500 μM) was used. These results suggest that these K_ATP-channel agonists and antagonists exert an effect on mitochondrial respiration and that they could be acting on mito-K_ATP or other respiratory-chain components.     

Kinetics of ubiquinol-1-cytochrome c reductase in bovine heart mitochondria and submitochondrial particles

A kinetic study on ubiquinol-cytochrome f reductase (EC 1.10.2.2) has been undertaken either in situ in KCN-inhibited mitochondria and submitochondrial particles, or in the isolated cytochrome b-c₁ complex using ubiquinol-1 and exogenous cytochrome c as substrates. The steady-state two-substrate kinetics of the reductase appears to follow a general sequential mechanism, allowing calculation of a K_m for ubiquinol-1 of 13.4 μM in mitochondria and of 24.6 μM in the isolated cytochrome b-c₁ complex. At low concentrations of cytochrome c, however, the titrations as a function of quinol concentration appear biphasic both in mitochondria and in submitochondrial particles containing trapped cytochrome c inside the vesicle space, fitting two apparent K_m values for ubiquinol-1. Relatively high antimycin-sensitive rates of ubiquinol-1-cytochrome c reductase have been found in submitochondrial particles: both the V_max and the K_m for ubiquinol-1 are, however, affected by the overall orientation of the particle preparation, i.e., by the reactivity of cytochrome c with its proper site. The turnover numbers corrected for particle orientation with respect to cytochrome c interaction are at least 2-fold higher in submitochondrial particles than in mitochondria. This is particularly evident using inside-out particles containing trapped cytochrome c in the vesicle space (and therefore reacting with its physiological site). A diffusion step for the quinol substrate appears to be rate limiting in mitochondria and can be removed by addition of deoxycholate, suggesting that the oxidation site of ubiquinol may be more exposed to the matrix side of the inner mitochondrial membrane.