On the mechanism of action of alkylguanidines on oxidative phosphorylation in mitochondria.

The effect of octylguanidine and oligomycin on the oxygen uptake of rat liver mitochondria and on the ATPase activity of "sonic" submitochondrial particles has been studied. 1. Octylguanidine inhibits state 3 respiration with glutamate-malate and succinate as substrates, but much lower concentrations are required to inhibit oxygen uptake with the former substrates. State 4 respiration is unaffected by octylguanidine. 2. The titration-curve for the octylguanidine inhibition of glutamate-malate oxidation is hyperbolic and apparently biphasic, half-maximal inhibition is obtained at 30 muM octylguanidine. The octylguanidine-curve for inhibition of succinate oxidation is sigmoid with half-maximal inhibition at about 250 muM. 3. Octylguanidine and oligomycin show additive inhibitory action on state 3 respiration with both glutamate plus malage and succinate as respiratory substrates. 4. Concentrations of oligomycin or octylguanidine, which added separately are ineffective on state 3 respiration, become inhibitory when the two inhibitors are added together. 5. Octylguanidine inhibits the ATPase activity of sonic submitochondrial particles with a hyperbolic titration-curve analogous to that obtained for oligomycin inhibition. The inhibitory actions of octylguanidine and oligomycin on the ATPase activity are additive. 6. It is concluded that octylguanidine acts directly on the ATPase complex and that its binding at the action site is mutually exclusive with the binding of oligomycin. A kinetic explanation is given for the reported higher sensitivity of site I phosphorylation to octylguanidine.     

The kinetic mechanism of action of an uncoupler of oxidative phosphorylation.

The chemiosmotic hypothesis predicts that the mechanism by which weak acids uncouple oxidative phosphorylation in mitochondria is identical to the mechanism by which they transport hydrogen ions across artificial bilayer membranes. We report here the results of a kinetic study of uncoupler-mediated hydrogen ion transport across bilayer membranes. We made electrical relaxation measurements on black lipid membranes exposed to the substituted benzimidazole 5,6-dichloro-2-trifluoromethylbenzimidazole. The simplest model consistent with our experimental data allowed us to deduce values for adsorption coefficients and rate constants. Our major conclusions are that the back diffusion of the neutral species is the rate limiting step for the steady state transport of hydrogen ions, that both the neutral and charged forms of the uncoupler adsorb strongly to the interfaces, and that the reactions at the membrane-solution interfaces occur sufficiently rapidly for equilibrium to be maintained. Independent measurements of the adsorption coefficients of both the neutral and anionic forms of the weak acid and also of the permeability of the membrane to the neutral form agreed well with the values deduced from the kinetic study.     

On the mechanism of ATP synthesis in oxidative phosphorylation: A review

It is shown that the presently available evidence supports the existence of two entry points for water oxygen in the mitochondrial oxygen exchanges. This in turn provides support for the pseudorotation reaction mechanism of ATP synthesis which is the only mechanism of ATP synthesis proposed to date allowing for two entry points of water oxygen. It is also shown that the pseudorotation mechanism can resolve the apparent paradox of a P₁ ? H₂O exchange·separate from the reversal of phosphorylation yet dependent on the mechanism of P₁ activation. In addition an interpretation consistent with the experimental observations concerning As_i-induced stimulation of respiration and effects associated with oligomycin and aurovertin is shown to follow from the analysis of the oxygen exchanges. Implications of the pseudorotation mechanism for the mechanism of energy coupling in oxidative phosphorylation are discussed.     

Studies on the mechanism of oxidative phosphorylation. ADP promotion of GDP phosphorylation

The process of ATP or GTP synthesis by bovine heart submitochondrial particles involves the binding of ADP or GDP to 3 exchangeable sites I, II, and III, and only upon substrate occupation of site III does rapid ATP or GTP synthesis take place. The dissociation constants determined for ADP were KADPI less than or equal to 10(-8) M, KADPII approximately 10(-7) M, and KADPIII (equivalent to apparent KADPm), approximately 3 x 10(-6) M in the low Km mode and KADPIII approximately 150 x 10(-6) M in the high Km mode. For GDP, these constants were KGDPI approximately 10(-6)-10(-5) M, KGDPII approximately 10(-4) M, and KGDPIII approximately 10(-3) M when NADH was the respiratory substrate (Matsuno-Yagi, A., and Hatefi, Y. (1990) J. Biol. Chem. 265, 82-88). Because of its low affinity for the above binding sites, GDP at micromolar concentrations does not lead to GTP synthesis. However, as shown in this paper, micromolar [GDP] undergoes phosphorylation in the presence of micromolar concentrations of ADP. Under these conditions, both ATP and GTP are synthesized. GDP inhibits ATP synthesis with KGDPi congruent to 7 microM, while ADP promotes GTP synthesis in a reaction that requires inorganic phosphate (apparent KPim = 2-3 mM) and is inhibited by uncouplers and inhibitors of the ATP synthase complex. The ADP-promoted GTP synthesis exhibited an "apparent" KGDPm = 4 microM and an "apparent" Vmax = 11 nmol of GTP (min.mg of protein)-1. These results were interpreted to mean that (a) micromolar [ADP] occupies sites I and II, allowing site III to bind and phosphorylate GDP, and (b) the KGDPm and Vmax calculated under these conditions represent values for the low Km-low Vmax mode of GTP synthesis, which in the absence of ADP is not detectable because of the positive cooperativity phase of GTP synthesis with the high KGDPII approximately 10(-4) M.     

The kinetic mechanism of action of an uncoupler of oxidative phosphorylation

Summary The chemiosmotic hypothesis predicts that the mechanism by which weak acids uncouple oxidative phosphorylation in mitochondria is identical to the mechanism by which they transport hydrogen ions across artificial bilayer membranes. We report here the results of a kinetic study of uncoupler-mediated hydrogen ion transport across bilayer membranes. We made electrical relaxation measurements on black lipid membranes exposed to the substituted benzimidazole 5,6-dichloro-2-trifluoromethylbenzimidazole. The simplest model consistent with our experimental data allowed us to deduce values for adsorption coefficients and rate constants. Our major conclusions are that the back diffusion of the neutral species is the rate limiting step for the steady state transport of hydrogen ions, that both the neutral and charged forms of the uncoupler adsorb strongly to the interfaces, and that the reactions at the membrane-solution interfaces occur sufficiently rapidly for equilibrium to be maintained. Independent measurements of the adsorption coefficients of both the neutral and anionic forms of the weak acid and also of the permeability of the membrane to the neutral form agreed well with the values deduced from the kinetic study.     

Uncoupling of oxidative phosphorylation by curcumin: Implication of its cellular mechanism of action

Curcumin is a phytochemical isolated from the rhizome of turmeric. Recent reports have shown curcumin to have antioxidant, anti-inflammatory and anti-tumor properties as well as affecting the 5′-AMP activated protein kinase (AMPK), mTOR and STAT-3 signaling pathways. We provide evidence that curcumin acts as an uncoupler. Well-established biochemical techniques were performed on isolated rat liver mitochondria in measuring oxygen consumption, F₀F₁-ATPase activity and ATP biosynthesis. Curcumin displays all the characteristics typical of classical uncouplers like fccP and 2,4-dinitrophenol. In addition, at concentrations higher than 50 μM, curcumin was found to inhibit mitochondrial respiration which is a characteristic feature of inhibitory uncouplers. As a protonophoric uncoupler and as an activator of F₀F₁-ATPase, curcumin causes a decrease in ATP biosynthesis in rat liver mitochondria. The resulting change in ATP:AMP could disrupt the phosphorylation status of the cell; this provides a possible mechanism for its activation of AMPK and its downstream mTOR and STAT-3 signaling.     

Studies on the mechanism of oxidative phosphorylation. Positive cooperativity in ATP synthesis

Kinetic and nucleotide binding studies have shown that submitochondrial particles from bovine heart possess three exchangeable binding sites for ADP or GDP. In order of decreasing affinity at neutral pH, these sites will be referred to as sites I, II, and III, and their respective dissociation constants as KI, KII, and KIII. In oxidative phosphorylation experiments in the presence of saturating amounts of inorganic phosphate, rapid ATP (or GTP) synthesis occurred only upon ADP (or GDP) binding to site III. The Eadie-Hofstee plots (v/[S] on the ordinate versus v on the abscissa) of the kinetics of ATP (or GTP) synthesis at variable ADP (or GDP) were, therefore, composed of an initial upward phase, indicating positive cooperativity with respect to substrate concentration, followed by a downward phase where rapid product formation took place. These data allowed calculation of KII from the upward phase and KIII (equivalent to apparent Km) from the downward phase. KI was estimated from Scatchard plots of binding data with radiolabeled ADP or GDP. Thus, together with our previous results, these findings have allowed characterization of the process of ATP or GTP synthesis by bovine-heart submitochondrial particles in terms of KI, KII, KIII, and kcat.     

Studies on the mechanism of oxidative phosphorylation. Catalytic site cooperativity in ATP synthesis

Oxidative phosphorylation catalyzed by bovine heart submitochondrial particles appears to exhibit negative cooperativity with respect to [ADP] and positive cooperativity in catalysis. Eadie-Hofstee plots (v/[S]versus v) of the kinetics of oxidative phosphorylation at the variable ADP concentration range of 1-1200 microM were curvilinear and could be analyzed for two apparent KmADP values differing by one order of magnitude, and two apparent Vmax values. The KmADP values with either NADH or succinate as the respiratory substrate were in the ranges of 10 and 100 microM, and the Vmax values in nmol of ATP formed X min-1 (mg of protein)-1 were, respectively, 500 and 1840 when NADH was the oxidizable substrate, and 550 and 100 when succinate was the energy source. Site-site cooperativity of the ATP synthase, which is a central feature of current theories for the mechanism of oxidative phosphorylation, has been well-documented for ATP hydrolysis by isolated F1-ATPase, but never before demonstrated for mitochondrial ATP synthesis.     

On the mechanism of a calcium-associated defect of oxidative phosphorylation in progessive muscular dystrophy

Partially purified elongation factor 1 preparations from calf brain, sheep brain, calf liver, and rabbit reticulocytes have been compared in their ability to interact with GTP and Phe-tRNA. A nitrocellulose filter assay has been used to study these interactions, and with all the EF1 preparations studied, evidence has been obtained for the formation of a Phe-tRNA·-EF1·-GTP complex. The ternary complex reacts with calf brain ribosomes in the presence of poly(U) resulting in a rapid hydrolysis of GTP and the binding of Phe-tRNA to the ribosome. Indirect evidence indicates that EF1·GDP is a product of this reaction. In the absence of poly(U) the intact complex reacts with the ribosomes without hydrolysis of GTP. The stability of the ternary complex was different with the various EF1 preparations, but the most stable complexes were prepared with calf brain EF1. Sephadex chromatography of the ternary complex shows that it contains a low molecular-weight species of the enzyme.