An enzymological approach to mitochondrial energy transduction

An approach to the problem of mitochondrial energy transduction is outlined. The approach is based on the fundamental assumption that there is an intimate relation between the mechanisms of enzyme catalysis and energy transduction. The implications of this assumption for the coupling of two chemical reactions and the coupling of a chemical reaction to an ion flux are discussed.     

Failure of atractyloside to inhibit synaptosomal mitochondrial energy transduction

Studies on synaptosome mitochondrial respiration are complicated by “free” mitochondria. Veratridine stimulation of synaptosomal respiration was due to increased Na⁺ cycling at the synaptosome membrane associated with increased oxidative phosphorylation of intraterminal ADP and was inhibited by oligomycin, ouabain or Na⁺ free medium. Atractylate or carboxyatractyloside failed to block veratridine-stimulated respiration but inhibited exogenous-ADP-stimulated respiration. Protein synthesis in the synaptosome fraction was inhibited by oligomycin, valinomycin or 2,4-dinitrophenol but was unaffected by excess atractylate. No change in synaptosomal adenine nucleotide content was found in the presence of atractylate, although a significant decrease in the [ATP]/[ADP] was found with oligomycin, veratridine or valinomycin. These findings show that atractylate does not modify intraterminal mitochondrial energy transduction and indirectly suggest an impermeability of the synaptosome membrane to atractylate.     

The effect of tetraphenylborate on mitochondrial energy transduction.

In phosphorylating submitochondrial particles, tetraphenylborate binds to the specific uncoupler binding site and inhibits oxidative phosphorylation, ATP-P_i exchange and ATP-driven reverse electron transport. In contrast, intact mitochondria are unaffected in uncoupler binding and energy transfer at the concentrations used in submitochondrial particles. The proton permeability of submitochondrial particles is only slightly increased (10–20%) at concentrations of tetraphenylborate which cause 50% uncoupling (4–8 μM). These results, and those obtained earlier with picrate, are consistent with a three-step mechanism of uncoupling which involves binding of uncoupler anions, protonation and dissociation of the resulting neutral uncoupler molecule.     

The mechanism of energy conservation and transduction by mitochondrial cytochrome c oxidase.

Oxidation of ferrocytochrome c by molecular oxygen catalysed by cytochrome c oxidase (cytochrome aa3) is coupled to translocation of H+ ions across the mitochondrial membrane. The proton pump is an intrinsic property of the cytochrome c oxidase complex as revealed by studies with phospholipid vesicles inlayed with the purified enzyme. As the conformation of cytochrome aa3 is specifically sensitive to the electrochemical proton gradient across the mitochondrial membrane, it is likely that redox energy is primarily conserved as a conformational "strain" in the cytochrome aa3 complex, followed by relaxation linked to proton translocation. Similar principles of energy conservation and transduction may apply on other respiratory chain complexes and on mitochondrial ATP synthase.     

The mitochondrial energy transduction system and the aging process

Aged mammalian tissues show a decreased capacity to produce ATP by oxidative phosphorylation due to dysfunctional mitochondria. The mitochondrial content of rat brain and liver is not reduced in aging and the impairment of mitochondrial function is due to decreased rates of electron transfer by the selectively diminished activities of complexes I and IV. Inner membrane H⁺ impermeability and F₁-ATP synthase activity are only slightly affected by aging. Dysfunctional mitochondria in aged rodents are characterized, besides decreased electron transfer and O₂ uptake, by an increased content of oxidation products of phospholipids, proteins and DNA, a decreased membrane potential, and increased size and fragility. Free radical-mediated oxidations are determining factors of mitochondrial dysfunction and turnover, cell apoptosis, tissue function, and lifespan. Inner membrane enzyme activities, such as those of complexes I and IV and mitochondrial nitric oxide synthase, decrease upon aging and afford aging markers. The activities of these three enzymes in mice brain are linearly correlated with neurological performance, as determined by the tightrope and the T-maze tests. The same enzymatic activities correlated positively with mice survival and negatively with the mitochondrial content of lipid and protein oxidation products. Conditions that increase survival, as vitamin E dietary supplementation, caloric restriction, high spontaneous neurological activity, and moderate physical exercise, ameliorate mitochondrial dysfunction in aged brain and liver. The pleiotropic signaling of mitochondrial H₂O₂ and nitric oxide diffusion to the cytosol seems modified in aged animals and to contribute to the decreased mitochondrial biogenesis in old animals. oxidative damage; survival; complexes I and IV; nitric oxide synthase     

Signal transduction by mitochondrial oxidants

The production of mitochondrial reactive oxygen species occurs as a consequence of aerobic metabolism. Mitochondrial oxidants are increasingly viewed less as byproducts of metabolism and more as important signaling molecules. Here, I review several notable examples, including the cellular response to hypoxia, aspects of innate immunity, the regulation of autophagy, and stem cell self-renewal capacity, where evidence suggests an important regulatory role for mitochondrial oxidants.     

The mechanism of energy conservation and transduction by mitochondrial cytochrome c oxidase

Oxidation of ferrocytochrome c by molecular oxygen catalysed by cytochrome c oxidase (cytochrome aa₃) is coupled to translocation of H⁺ ions across the mitochondrial membrane. The proton pump is an intrinsic property of the cytochrome c oxidase complex as revealed by studies with phospholipid vesicles inlayed with the purified enzyme. As the conformation of cytochrome aa₃ is specifically sensitive to the electrochemical proton gradient across the mitochondrial membrane, it is likely that redox energy is primarily conserved as a conformational “strain” in the cytochrome aa₃ complex, followed by relaxation linked to proton translocation. Similar principles of energy conservation and transduction may apply on other respiratory chain complexes and on mitochondrial ATP synthase.     

A mathematical model to study short-term regulation of mitochondrial energy transduction

A mathematical model is presented which includes the following elementary process of mitochondrial energy transduction: hydrogen supply, proton translocation by the respiratory chain, proton-driven ATP synthesis by the F0F1-ATPase, passive back-flow of protons (leak) and carrier-mediated exchange of adenine nucleotides and phosphate. For these processes empirical rate laws are used. The model is applied to calculate time-dependent states of energy transduction in isolated rat liver mitochondria. From the general agreement of the computational results with experimental data (Ogawa, S. and Lee, T.M. (1984) J. Biol. Chem. 259, 10004-10011) the following conclusions can be drawn. (1) The length of the time interval during which mitochondria are able to maintain a relatively high and constant delta pH in the absence of oxygen (anaerobiosis) is limited by the availability of intramitochondrial ATP. (2) The overshoot kinetics of delta pH which appear when reoxigenating mitochondria after a preceeding anaerobiosis might be due to a lag phase kinetics of the F0F1-ATPase. (3) In phosphorylating mitochondria the homeostasis of delta pH is brought about by a high sensitivity of the respiration rate and the rate of the F0F1-ATPase as to changes of delta pH. (4) Analysis of the mean transient times shows that the rate of ATP synthesis in State 3 is controlled to almost the same extent by the hydrogen supply, the respiratory chain, the adenine nucleotide translocator and the proton leak.     

Sidedness of inhibition of energy transduction in oxidative phosphorylation in rat liver mitochondria by ethidium bromide.

Ethidium bromide, a new type of inhibitor of energy transduction in oxidative phosphorylation, inhibited ATP synthesis in intact mitochondria but not in submitochondrial particles, the latter being inside-out relative to the membranes of intact mitochondria. Ethidium bromide incorporated inside the submitochondrial particles inhibited ATP synthesis in the particles. The decrease of the membrane potential by valinomycin (plus KCl) inhibited only slightly the energy-dependent binding of ethidium bromide to the mitochondria. The present results show clearly that ethidium bromide inhibited energy transduction in oxidative phosphorylation by acting on the outer side (C-side) of the inner mitochondrial membrane, perhaps by neutralizing negative charges created on the surface of the C-side, and that it had no inhibitory activity on the inner side (M-side) of the membrane. Th present results show also that the energy-dependent binding of ethidium is not due to electrophoretic transport down the membrane potential; ethidium may bind to negative charges on the surface of the C-side. The present study suggest that an anisotropic distribution of electric charge in the inner mitochondrial membrane is an intermediary high energy state of oxidatvie phosphorylation.     

Displacement of palmitate from albumin by chlorophenoxyisobutyrate.

The effect of chlorophenoxyisobutyrate, a hypolipidemic drug that decreases plasma free fatty acids, triglycerides, and cholesterol, on the partitioning of [¹⁴C]-palmitate between hexane and bovine serum albumin was studied at 37°. In this system, hexane served as a hydrophobic trap for free fatty acids displaced from BSA by chlorophenoxyisobutyrate, allowing less than 0.3% to remain in the aqueous phase. As the concentration of chlorophenoxy isobutyrate was raised from 0.4 to 3.2 mM, there was a progressive displacement of palmitate from the [¹⁴C]-palmitate-BSA complex into hexane, the magnitude being dependent on the initial $\text{V}$ value (moles palmitate bound/mole BSA). Beginning with [¹⁴C]-palmitate in hexane, chlorophenoxyisobutyrate (2 mM) decreased the moles palmitate bound/mole of BSA by 16% at $\text{V}$ = 0.2, and 34% at $\text{V}$ = 3.0.     

Conformational changes in cytochromeaa 3 and ATP synthetase of the mitochondrial membrane and their role in mitochondrial energy transduction

1. The thermodynamics and molecular basis of energy-linked conformational changes in the cytochrome aa3 and ATP synthetase complexes of the mitochondrial membrane have been studied with spectrophotometrical and fluorometrical techniques. 2. Ferric cytochrome aa3 exists in two conformations, high spin and low spin, the equilibrium between these states being controlled by the electrical potential difference across the mitochondrial membrane. The conformational change is brought about by an electrical field-driven binding of one proton per aa3 to the complex. At pH 7.2 the concentration of the two conformations is equal at a membrane potential of 170 mV corresponding to about 4 kcal/mole. 3. The high to low spin transition in ferric aa3 is also induced by hydrolysis of ATP in which case two molecules of aa3 are shifted per ATP molecule hydrolyzed. This is in accordance with translocation of two protons across the mitochondrial membrane coupled to hydrolysis of ATP as proposed in the chemiosmotic theory of oxidative phosphorylation. 4. The conformational transition in cytochrome aa3 is not an expression of the formation of a 'high-energy' intermediate or reversal of the energy-transducing pathway of oxidative phosphorylation, but is presumably the basis of allosteric control of the activity of cytochrome oxidase by the energy state of the mitochondrion. This control is exerted by a regulatory mechanism in which the electrical potential difference controls the conformation and redox properties of the heme centres and thereby the rate of oxygen consumption. 5. The synthesis of one molecule of ATP by oxidative phosphorylation is energetically equivalent to the work done in carrying two electrical charges across the entire mitochondrial membrane. 6. Fluorescence changes of aurovertin bound to ATP synthetase reveal that the electrical membrane potential induces a conformational change in the F1 portion of the enzyme which is probably associated with dissociation of the natural F1 inhibitor protein. This conformational change is energetically equivalent to the work done in carrying one electrical charge across the mitochondrial membrane. 7. A model is proposed for the mechanism of the electrical field-induced conformational changes in the cytochrome aa3 and ATP synthetase complexes, and the significance of these changes in the mechanism and control of mitochondrial energy conservation is discussed.     

Changes of expression of mitochondrial proteins involved in energy transduction in rat brain during aging

Dantrolene – an inhibitor of ryanodine receptors and calcium stabilizer – prevents ischemia- and excitotoxicity-evoked neurodegeneration. To elucidate the mechanisms of this phenomenon, we investigated effects of dantrolene on the NMDA- and glutamate-induced lesion and stimulation of ⁴⁵Ca uptake in primary cultures of rat cerebellar granule neurons. Neurodegeneration was evaluated after 24 h with the propidium iodide staining. Bcl-2 immunoreactivity in cell homogenates was measured by immunoblotting. The results demonstrated that dantrolene applied at micromolar concentrations inhibits in a dose-dependent manner NMDA- and glutamate-evoked ⁴⁵Ca uptake in neurones and induces neuroprotection. This effect was additive to known effects of DMSO, a vehicle to dantrolene. Dantrolene failed to induce changes in Bcl-2 immunoreactivity. Thus, dantrolene-induced neuroprotection against excitotoxicity may be at least partially mediated by its inhibitory effect on the NMDA receptors.     

Nitric oxide inhibits cardiac energy production via inhibition of mitochondrial creatine kinase

Nitric oxide biosynthesis in cardiac muscle leads to a decreased oxygen consumption and lower ATP synthesis. It is suggested that this effect of nitric oxide is mainly due to the inhibition of the mitochondrial respiratory chain enzyme, cytochrome c oxidase. However, this work demonstrates that nitric oxide is able to inhibit soluble mitochondrial creatine kinase (CK), mitochondrial CK bound in purified mitochondria, CK in situ in skinned fibres as well as the functional activity of mitochondrial CK in situ in skinned fibres. Since mitochondrial isoenzyme is functionally coupled to oxidative phosphorylation, its inhibition also leads to decreased sensitivity of mitochondrial respiration to ADP and thus decreases ATP synthesis and oxygen consumption under physiological ADP concentrations.     

Mode of action of miconazole on yeasts: inhibition of the mitochondrial ATPase

Miconazole [( 1-[2-(2,4 dichlorophenyl)-2-(2,4 dichlorophenyl)methoxy]ethyl]-1 H-imidazole) completely inhibited growth of Saccharomyces cerevisiae and Candida albicans on glycerol at 10 microM . 50 microM was needed to achieve the same effect during growth on glucose. Miconazole inhibited competitively the mitochondrial ATPase of S. cerevisiae with a Ki of 1 microM. F1 activity of the enzyme was not affected. Mutants resistant to miconazole were isolated. The ATPase of these mutants was resistant to 10 microM miconazole. Higher concentrations of miconazole inhibited the ATPase of the plasma membrane. The inhibition of the S. cerevisiae enzyme was competitive with a Ki of 50 microM. The results point to the mitochondrial ATPase as the primary target of miconazole action at least during growth on non-fermentable carbon sources.