Downmodulation of mitochondrial F0F1 ATP synthase by diazoxide in cardiac myoblasts: a dual effect of the drug

Similar to ischemic preconditioning, diazoxide was documented to elicit beneficial bioenergetic consequences linked to cardioprotection. Inhibition of ATPase activity of mitochondrial F(0)F(1) ATP synthase may have a role in such effect and may involve the natural inhibitor protein IF(1). We recently documented, using purified enzyme and isolated mitochondrial membranes from beef heart, that diazoxide interacts with the F(1) sector of F(0)F(1) ATP synthase by promoting IF(1) binding and reversibly inhibiting ATP hydrolysis. Here we investigated the effects of diazoxide on the enzyme in cultured myoblasts. Specifically, embryonic heart-derived H9c2 cells were exposed to diazoxide and mitochondrial ATPase was assayed in conditions maintaining steady-state IF(1) binding (basal ATPase activity) or detaching bound IF(1) at alkaline pH. Mitochondrial transmembrane potential and uncoupling were also investigated, as well as ATP synthesis flux and ATP content. Diazoxide at a cardioprotective concentration (40 muM cell-associated concentration) transiently downmodulated basal ATPase activity, concomitant with mild mitochondria uncoupling and depolarization, without affecting ATP synthesis and ATP content. Alkaline stripping of IF(1) from F(0)F(1) ATP synthase was less in diazoxide-treated than in untreated cells. Pretreatment with glibenclamide prevented, together with mitochondria depolarization, inhibition of ATPase activity under basal but not under IF(1)-stripping conditions, indicating that diazoxide alters alkaline IF(1) release. Diazoxide inhibition of ATPase activity in IF(1)-stripping conditions was observed even when mitochondrial transmembrane potential was reduced by FCCP. The results suggest that diazoxide in a model of normoxic intact cells directly promotes binding of inhibitor protein IF(1) to F(0)F(1) ATP synthase and enhances IF(1) binding indirectly by mildly uncoupling and depolarizing mitochondria.     

Thiols in oxidative phosphorylation: inhibition and energy-potentiated uncoupling by monothiol and dithiol modifiers

Three apparently different modifications of submitochondrial particles (SMP) or ATP synthase preparations (complex V) inhibit oxidative phosphorylation and ATP-32Pi exchange activities, all of which are reversible by addition of mono- or dithiols. (a) Triphenyltin chloride inhibits ATP synthesis and hydrolysis without uncoupling. The inhibition by triphenyltin chloride is reversible by addition of beta-mercaptoethanol, dithiothreitol, or dihydrolipoamide. (b) Factor B is a water-soluble protein of Mr (11-12) X 10(3), contains a vicinal dithiol, and is required for energy transfer to and from F1-ATPase when tested with SMP-rendered factor B deficient by extraction with ammonia-ethylenediaminetetraacetic acid (EDTA) (AE-SMP). Treatment of factor B with mono- and dithiol modifiers, such as p-(chloromercuri)benzenesulfonate (PCMPS), Cd2+, or diazenedicarboxylic acid bis(dimethylamide) (diamide), inhibits factor B. This inhibition is reversed by addition to modified factor B of appropriate mono- and dithiol compounds. Preparations of AE-SMP are partially F1 deficient and partially uncoupled. The uncoupling can be repaired completely by addition of factor B or low levels of oligomycin, or to a large extent by addition of F1-ATPase + oligomycin sensitivity conferring protein. (c) SMP, AE-SMP, and complex V can be completely uncoupled by treatment at 30 degrees C with phenylarsine oxide, Cd2+, diamide, PCMPS, monobromobimane, and mono- and bifunctional maleimides. The uncoupling by these reagents is potentiated by membrane energization. Uncoupling by diamide is greater than or equal to 80% reversed by dihydrolipoamide or beta-mercaptoethanol, the former being much more potent. Dithiothreitol and dithioerythritol are poorly effective.(ABSTRACT TRUNCATED AT 250 WORDS)     

Estimation of the turnover number of bovine heart F0F1 complexes for ATP synthesis

In mitochondria and submitochondrial particles (SMP), the rate of ATP synthesis is restricted by the rate of energy production by the respiratory chain. Fractional inactivation of the ATP synthase complexes (F0F1) of bovine heart SMP by covalent modifiers increased the rate of ATP synthesis per mole of active F0F1. Thus, by use of SMP containing fractionally inactivated F0F1 complexes, a synthetic rate of 420 mol of ATP (mol of F0F1.s)-1 was measured, which extrapolated to a Vmax of 440 s-1. At this extrapolated point, the turnover rate of F0F1 complexes was independent of the rate of energy production by the respiratory chain. These results have been discussed in relation to the effect of fractional inactivation of the F0F1 complexes of SMP on the steady-state free energy of the system. The above rate of ATP synthesis is comparable to the rate of ATP hydrolysis by SMP (400-520 s-1) in the absence of energy coupling constraints and control by the ATPase inhibitor protein. More interestingly, this rate is also comparable to the rate of ATP synthesis by chloroplast F0F1 under high light intensity (approximately 420 s-1). Under the conditions specified, bovine heart SMP and chloroplasts show similar apparent Km values for ADP. Thus, it appears that the mammalian and chloroplast ATP synthase complexes are similar not only in structure but also in catalytic efficiency for ATP synthesis.     

Energy-dependent transformation of F0.F1-ATPase in Paracoccus denitrificans plasma membranes

F(0).F(1)-ATP synthase in tightly coupled inside-out vesicles derived from Paracoccus denitrificans catalyzes rapid respiration-supported ATP synthesis, whereas their ATPase activity is very low. In the present study, the conditions required to reveal the Deltamu(H+)-generating ATP hydrolase activity of the bacterial enzyme have been elucidated. Energization of the membranes by respiration results in strong activation of the venturicidin-sensitive ATP hydrolysis, which is coupled with generation of Deltam?(H+). Partial uncoupling stimulates the proton-translocating ATP hydrolysis, whereas complete uncoupling results in inhibition of the ATPase activity. The presence of inorganic phosphate is indispensable for the steady-state turnover of the Deltam?(H+)-activated ATPase. The collapse of Deltam?(H+) brings about rapid deactivation of the enzyme, which has been subjected to pre-energization. The rate and extent of the deactivation depend on protein concentration, i.e. the more vesicles are present in the assay mixture, the higher the rate and extent of the deactivation is seen. Sulfite and the ADP-trapping system protect ATPase against the Deltam?(H+) collapse-induced deactivation, whereas phosphate delays the rate of deactivation. A low concentration of ADP (<1 microm) increases the rate of deactivation. Taken together, the results suggest that latent proton-translocating ATPase in P. denitrificans is kinetically equivalent to the previously characterized ADP(Mg2+)-inhibited, azide-trapped bovine heart mitochondrial F(0).F(1)-ATPase (Galkin, M. A., and Vinogradov, A. D. (1999) FEBS Lett. 448, 123-126). A Deltam?(H+)-sensitive mechanism operates in P. denitrificans that prevents physiologically wasteful consumption of ATP by F(0).F(1)-ATPase (synthase) complex when the latter is unable to maintain certain value of Deltam?(H+).     

Chemical modification of thiol groups of mitochondrial F1-ATPase from the yeast Schizosaccharomyces pombe. Involvement of alpha- and gamma-subunits in the enzyme activity

Mitochondrial F1-ATPase from the yeast Schizosaccharomyces pombe has been prepared under a stable form and in relatively high amounts by an improved purification procedure. Specific chemical modification of the enzyme by the thiol reagent N-ethylmaleimide (NEM) at pH 6.8 leads to complete inactivation characterized by complex kinetics and pH dependence, indicating that several thiols are related to the enzyme activity. A complete protection against NEM effect is afforded by low concentrations of nucleotides in the presence of Mg2+, with ADP and ATP being more efficient than GTP. A total binding of 5 mol of [14C]NEM/mol of F1-ATPase is obtained when the enzyme is 85% inactivated: 3 mol of the label are located on the alpha-subunits and 2 on the gamma-subunit. Two out of the 3 mol on the alpha-subunits bind very rapidly before any inactivation occurs, indicating that the two thiols modified are unrelated to the inactivation process. Complete protection by ATP against inactivation by NEM prevents the modification of three essential thiols out of the group of five thiols labeled in the absence of ATP: one is located on a alpha-subunit and two on the gamma-subunit. These two essential thiols of the gamma-subunit can be differentiated by modification with 6,6'-dithiodinicotinic acid (CPDS), another specific thiol reagent. A maximal binding of 4 mol of [14C]CPDS/mol of enzyme is obtained, concomitant to a 25% inhibition. Sequential modification of the enzyme by CPDS and [14C]NEM leads to the same final deep inactivation as that obtained with [14C]NEM alone. One out of the two thiols of the gamma-subunit is no longer accessible to [14C]NEM after CPDS treatment. When incubated at pH 6.8 with [3H]ATP in the presence of Mg2+, F1-ATPase is able to bind 3, largely exchangeable, mol of nucleotide/mol of enzyme. Modification of the three essential thiols by NEM dramatically decreases the binding of 3H-nucleotide down to about 1 mol/mol of enzyme. Partial modification modifies the cooperative properties, the enzyme being no longer sensitive to anion activation.     

Reversible assembly of the ATP-binding cassette transporter Mdl1 with the F1F0-ATP synthase in mitochondria

The half-ABC transporter Mdl1 is localized in the inner membrane of mitochondria and mediates the export of peptides generated upon proteolysis of mitochondrial proteins. The physiological role of the peptides released from mitochondria is currently not understood. Here, we have analyzed the oligomeric state of Mdl1 in the inner membrane and demonstrate nucleotide-dependent binding to the F(1)F(0)-ATP synthase. Mdl1 forms homo-oligomeric, presumably dimeric complexes in the presence of ATP, but was found in association with the F(1)F(0)-ATP synthase at low ATP levels. Mdl1 binds membrane-embedded parts of the ATP synthase complex after the assembly of the F(1) and F(0) moieties. Although independent of Mdl1 activity, complex formation is impaired upon inhibition of the F(1)F(0)-ATP synthase with oligomycin or N,N'-dicyclohexylcarbodiimide. These results are consistent with an activation of Mdl1 upon dissociation from the ATP synthase and suggest a link of peptide export from mitochondria to the activity of the F(1)F(0)-ATP synthase and the cellular energy metabolism.     

The H+-translocating ATP synthase in Halobacterium halobium differs from F0F1-ATPase/synthase

Cell envelope vesicles of Halobacterium halobium synthesize ATP by utilizing base-acid transition (an outside acidic pH jump) under optimal conditions (1 M NaCl, 80 mM MgCl2, pH 6.8) even in the presence of azide (a specific inhibitor of F0F1-ATPase) (Mukohata & Yoshida (1987) J. Biochem. 101, 311-318). An azide-insensitive ATPase was isolated from the inner face of the vesicle membrane, and shown to hydrolyze ATP under very specific conditions (1.5 M Na2SO4, 10 mM MnCl2, pH 5.8) (Nanba & Mukohata (1987) J. Biochem. 102, 591-598). This ATPase activity could also be detected when the vesicle components were solubilized by detergent. The relationship between ATP synthesis and the membrane-bound ATPase was investigated by modification of the vesicles with 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-Cl) or N-ethylmaleimide (NEM). The inhibition pattern of ATP synthesis in the modified vesicles and that of ATP hydrolysis of the solubilized modified vesicles were compared under the individual optimum conditions. The inhibition patterns were almost identical, suggesting that the ATP synthesis and hydrolysis are catalyzed by a single enzyme complex. The ATP synthase includes the above ATPase (300-320 kDa), which is composed of two pairs of 86 and 64 kDa subunits. This is a novel H+-translocating ATP synthase functioning in the extremely halophilic archaebacterium. This "archae-ATP-synthase" differs from F0F1-ATPase/synthase, which had been thought to be ubiquitous among all respiring organisms on our biosphere.     

Transient accumulation of elastic energy in proton translocating ATP synthase

ATP synthase is conceived as a rotatory engine with two reversible drives, the proton-transporting membrane portion, F0, and the catalytic peripheral portion, F1. They are mounted on a central shaft (subunit gamma) and held together by an eccentric bearing. It is established that the hydrolysis of three molecules of ATP in F1 drives the shaft over a full circle in three steps of 120 degrees each. Proton flow through F0 probably generates a 12-stepped rotation of the shaft so that four proton-translocating steps of 30 degrees each drive the synthesis of one molecule of ATP. We addressed the elasticity of the transmission between F0 and F1 in a model where the four smaller steps in F0 load a torsional spring which is only released under liberation of ATP from F1. The kinetic model of an elastic ATP synthase described a wealth of published data on the synthesis/hydrolysis of ATP by F0F1 and on proton conduction by F0 as function of the pH and the protonmotive force. The pK values of the proton-carrying group interacting with the acidic and basic sides of the membrane were estimated as 5.3-6.4 and 8.0-8.3, respectively.     

Effect of structural modulation of polyphenolic compounds on the inhibition of Escherichia coli ATP synthase

In this paper we present the inhibitory effect of a variety of structurally modulated/modified polyphenolic compounds on purified F(1) or membrane bound F(1)F(o)Escherichia coli ATP synthase. Structural modulation of polyphenols with two phenolic rings inhibited ATP synthase essentially completely; one or three ringed polyphenols individually or fused together inhibited partially. We found that the position of hydroxyl and nitro groups plays critical role in the degree of binding and inhibition of ATPase activity. The extended positioning of hydroxyl groups on imino diphenolic compounds diminished the inhibition and abridged position enhanced the inhibition potency. This was contrary to the effect by simple single ringed phenolic compounds where extended positioning of hydroxyl group was found to be effective for inhibition. Also, introduction of nitro group augmented the inhibition on molar scale in comparison to the inhibition by resveratrol but addition of phosphate group did not. Similarly, aromatic diol or triol with rigid or planar ring structure and no free rotation poorly inhibited the ATPase activity. The inhibition was identical in both F(1)F(o) membrane preparations as well as in isolated purified F(1) and was reversible in all cases. Growth assays suggested that modulated compounds used in this study inhibited F(1)-ATPase as well as ATP synthesis nearly equally.     

The F0 subunits of bovine mitochondrial ATP synthase complex: purification, antibody production, and interspecies cross-immunoreactivity.

The known subunits of the membrane sector F0 of the bovine mitochondrial ATP synthase complex are subunits b, d, 6, F6, OSCP (oligomycin sensitivity-conferring protein), the DCCD (dicyclohexylcarbodiimide) binding proteolipid, and A6L. The first six subunits were purified from SMP or preparations of the ATP synthase complex, and monospecific antibodies were raised against each. The antisera were shown to be competent for immuno-blotting, and each antiserum recognized a single polypeptide of the expected Mr in preparations of the ATP synthase complex. Immunoblots utilizing antibodies to OSCP and subunits d and 6, which exhibit the same Mr on dodecyl sulfate-polyacrylamide gels, showed clearly that these polypeptides are immunologically distinct. Immunological cross-reactivity was demonstrated between bovine, human, rat, Saccharomyces cerevisiae, Paracoccus denitrificans, and Escherichia coli for subunit 6; between bovine, human, and rat for subunits b, d, OSCP, and F6; and between bovine and rat for the DCCD binding proteolipid. Anti-subunit 6 antiserum, before or after immunopurification against the ATP synthase complex, recognized a single polypeptide in the bovine ATP synthase complex and S. cerevisiae mitochondria, but two polypeptides of different Mr in bovine SMP, human, and rat mitochondria, and Paracoccus and E. coli membranes.     

Voltage-generated torque drives the motor of the ATP synthase.

The mechanism by which ion-flux through the membrane-bound motor module (F0) induces rotational torque, driving the rotation of the gamma subunit, was probed with a Na+-translocating hybrid ATP synthase. The ATP-dependent occlusion of 1 (22)Na+ per ATP synthase persisted after modification of the c subunit ring with dicyclohexylcarbodiimide (DCCD), when 22Na+ was added first and ATP second, but not if the order of addition was reversed. These results support the model of ATP-driven rotation of the c subunit oligomer (rotor) versus subunit a (stator) that stops when either a 22Na+-loaded or a DCCD-modified rotor subunit reaches the Na+-impermeable stator. The ATP synthase with a Na+-permeable stator catalyzed 22Na+out/Na+in-exchange after reconstitution into proteoliposomes, which was not significantly affected by DCCD modification of the c subunit oligomer, but was abolished by the additional presence of ATP or by a membrane potential (DeltaPsi) of 90 mV. We propose that in the idling mode of the motor, Na+ ions are shuttled across the membrane by limited back and forth movements of the rotor against the stator. This motional flexibility is arrested if either ATP or DeltaPsi induces the switch from idling into a directed rotation. The Propionigenium modestum ATP synthase catalyzed ATP formation with DeltaPsi of 60-125 mV but not with DeltapNa+ of 195 mV. These results demonstrate that electric forces are essential for ATP synthesis and lead to a new concept of rotary-torque generation in the ATP synthase motor.     

The inhibitor protein (IF1) promotes dimerization of the mitochondrial F1F0-ATP synthase

The effect of increased expression or reconstitution of the mitochondrial inhibitor protein (IF1) on the dimer/monomer ratio (D/M) of the rat liver and bovine heart F1F0-ATP synthase was studied. The 2-fold increased expression of IF1 in AS-30D hepatoma mitochondria correlated with a 1.4-fold increase in the D/M ratio of the ATP synthase extracted with digitonin as determined by blue native electrophoresis and averaged densitometry analyses. Removal of IF1 from rat liver or bovine heart submitochondrial particles increased the F1F0-ATPase activity and decreased the D/M ratio of the ATP synthase. Reconstitution of recombinant IF1 into submitochondrial particles devoid of IF1 inhibited the F1F0-ATPase activity by 90% and restored partially the D/M ratio of the whole F1F0 complex as revealed by blue native electrophoresis and subsequent SDS-PAGE or glycerol density gradient centrifugation. Thus, the inhibitor protein promotes or stabilizes the dimeric form of the intact F1F0-ATP synthase. A possible location of the IF1 protein in the dimeric structure of the rat liver F1F0 complex is proposed. According to crystallographic and electron microscopy analyses, dimeric IF1 could bridge the F1-F1 part of the dimeric F1F0-ATP synthase in the inner mitochondrial membrane.     

2,5-Di(tert-butyl)-1,4-benzohydroquinone--a novel inhibitor of liver microsomal Ca2+ sequestration

Treatment of rat liver microsomes with 2,5-di(tert-butyl)-1,4-benzohydroquinone caused a dose-related inhibition (Ki congruent to 1 microM) of ATP-dependent Ca2+ sequestration. This was paralleled by a similar impairment of the microsomal Ca2+-stimulated ATPase activity. In contrast, the hydroquinose failed to induce Ca2+ release from Ca2+-loaded liver mitochondria (supplied with ATP), and inhibited neither the mitochondrial F1F0-ATPase nor the Ca2+-stimulated ATPase activity of the hepatic plasma membrane fraction. The inhibition of microsomal Ca2+ sequestration was not associated with any apparent alteration of membrane permeability or loss of other microsomal enzyme activities or modification of microsomal protein thiols. These findings suggest that 2,5-di(tert-butyl)-1,4-benzohydroquinone is a potent and selective inhibitor of liver microsomal Ca2+ sequestration which may be a useful tool in studies of Ca2+ fluxes in intact cells and tissues.     

Adenine nucleotide translocator promotes oxidative phosphorylation and mild uncoupling in mitochondria after dexamethasone treatment

The composition of the mitochondrial inner membrane and uncoupling protein [such as adenine nucleotide translocator (ANT)] contents are the main factors involved in the energy-wasting proton leak. This leak is increased by glucocorticoid treatment under nonphosphorylating conditions. The aim of this study was to investigate mechanisms involved in glucocorticoid-induced proton leak and to evaluate the consequences in more physiological conditions (between states 4 and 3). Isolated liver mitochondria, obtained from dexamethasone-treated rats (1.5 mg.kg(-1).day(-1)), were studied by polarography, Western blotting, and high-performance thin-layer chromatography. We confirmed that dexamethasone treatment in rats induces a proton leak in state 4 that is associated with an increased ANT content, although without any change in membrane surface or lipid composition. Between states 4 and 3, dexamethasone stimulates ATP synthesis by increasing both the mitochondrial ANT and F1-F0 ATP synthase content. In conclusion, dexamethasone increases mitochondrial capacity to generate ATP by modifying ANT and ATP synthase. The side effect is an increased leak in nonphosphorylating conditions.     

Novel features in the structure of bovine ATP synthase.

The F1F0-ATP synthase from bovine heart mitochondria catalyses the synthesis of ATP from ADP and inorganic phosphate by using the energy of an electrochemical proton gradient derived from electron transport. The enzyme consists of three major domains: the globular F1catalytic domain of known atomic structure lies outside the lipid bilayer and is attached by a central stalk to the intrinsic membrane domain, F0, which transports protons through the membrane. Proton transport through F0evokes structural changes that are probably transmitted by rotation of the stalk to the catalytic sites in F1. In an alpha3beta3gamma1subcomplex, the rotation of the central gamma subunit driven by ATP hydrolysis has been visualised by optical microscopy. In order to prevent the alpha3beta3structure from following the rotation of the central gamma subunit, it has been proposed that the enzyme might have a stator connecting static parts in F0to alpha3beta3,thereby keeping it fixed relative to the rotating parts. Here we present electron microscopy images that reveal three new features in bovine F1F0-ATPase, one of which could be a stator. The second feature is a collar structure above the membrane domain and the third feature is some additional density on top of the F1domain.     

ATP synthesis in cell envelope vesicles of Halobacterium halobium driven by membrane potential and/or base-acid transition

Cell envelope vesicles active in ATP synthesis were prepared from Halobacterium halobium cells, which genetically lack bacteriorhodopsin, by sonication in the presence of substrates. ATP was synthesized when vesicles were illuminated to build up membrane potential through the action of halorhodopsin. The threshold value of membrane potential for ATP synthesis was about -100 mV relative to the external medium, i.e., inside-negative. ATP synthesis also occurred in the dark upon acidification of the external medium of a suspension of cell envelope vesicles. This base-acid transition ATP synthesis took place when the pH difference was greater than 1.6 units. The threshold pH difference was lowered when the base-acid transition was carried out under dim light which induced a membrane potential of about -100 mV. Regardless of the sort of driving force, ATP synthesis was optimum at the intravesicular pH of around 6.5 and almost nil at 8, where ATP syntheses by F0F1 type ATPases in other organisms are most active. The synthesis could be inhibited by N,N'-dicyclohexylcarbodiimide (DCCD) with a half-maximum inhibition at around 25 microM/2 mg protein/ml. These results strongly suggest that in halobacteria a DCCD-sensitive H+-translocating ATP synthase is in operation which is driven by membrane potential and/or pH gradient, and obeys chemiosmotic energetics. The results also suggest that the ATP synthase may not be identical to F0F1 type H+-translocating ATPases found in mitochondria, chloroplasts and eubacteria.     

Intrinsic and extrinsic uncoupling of oxidative phosphorylation

This article reviews parameters of extrinsic uncoupling of oxidative phosphorylation (OxPhos) in mitochondria, based on induction of a proton leak across the inner membrane. The effects of classical uncouplers, fatty acids, uncoupling proteins (UCP1-UCP5) and thyroid hormones on the efficiency of OxPhos are described. Furthermore, the present knowledge on intrinsic uncoupling of cytochrome c oxidase (decrease of H(+)/e(-) stoichiometry=slip) is reviewed. Among the three proton pumps of the respiratory chain of mitochondria and bacteria, only cytochrome c oxidase is known to exhibit a slip of proton pumping. Intrinsic uncoupling was shown after chemical modification, by site-directed mutagenesis of the bacterial enzyme, at high membrane potential DeltaPsi, and in a tissue-specific manner to increase thermogenesis in heart and skeletal muscle by high ATP/ADP ratios, and in non-skeletal muscle tissues by palmitate. In addition, two mechanisms of respiratory control are described. The first occurs through the membrane potential DeltaPsi and maintains high DeltaPsi values (150-200 mV). The second occurs only in mitochondria, is suggested to keep DeltaPsi at low levels (100-150 mV) through the potential dependence of the ATP synthase and the allosteric ATP inhibition of cytochrome c oxidase at high ATP/ADP ratios, and is reversibly switched on by cAMP-dependent phosphorylation. Finally, the regulation of DeltaPsi and the production of reactive oxygen species (ROS) in mitochondria at high DeltaPsi values (150-200 mV) are discussed.     

Factor B is essential for ATP synthesis by mitochondria

Factor B is a water-soluble protein, which is required for the coupled activity of the mitochondrial ATP synthase complex. Specific removal of factor B from well-coupled bovine heart submitochondrial particles (SMP) results in uncoupling and the loss of ATP-driven membrane potential formation and reverse electron transfer from succinate to NAD. Addition of recombinant human factor B (molecular mass 20,341 Da) to factor B-depleted SMP (AE-SMP) restores these properties [G.I. Belogrudov, and Y. Hatefi, (2002) J. Biol. Chem. 277, 6097-6103]. This paper shows that extraction and purification of ATP synthase complex (complex V) from bovine heart mitochondria results in extensive loss of factor B. Addition of recombinant human factor B to AE-SMP completely restores the lost oxidative phosphorylation and ATP-32P(i) exchange activities of the particles and increases the ATP-32P(i) exchange activity of complex V by 2.5-fold. These results further indicate that factor B is an essential component of the mammalian ATP synthase complex.     

F0F1 ATP synthase activity is differently modulated by coronary reactive hyperemia before and after ischemic preconditioning in the goat

The amplitude of coronary reactive hyperemia (CRH), elicited by 15 s of ischemia, is reduced in hearts subjected to 5 min of ischemic preconditioning (IP). F0F1 ATP synthase activity and ATP concentration are also altered by IP. We hypothesized that F0F1 ATP synthase is differently modulated by the inhibitor protein IF(1) during CRH elicited before (CRHnp) and after (CRHprec) IP. Hemodynamic parameters were recorded in 10 anesthetized goats. Myocardial biopsies were obtained before IP (Cnp), during CRHnp, 4 and 6 min after the onset of CRHnp, after IP (Cprec), during CRHprec, and 4 min after CRHprec. F0F1 ATP synthase activity, ATP concentration, and ATP-to-ADP ratio (ATP/ADP) were determined. Compared with CRHnp, IP blunted CRHprec. F0F1 ATP synthase activity transiently increased during CRHnp, decreased 4 min after CRHnp, and returned to control 2 min later; it was lower after IP (Cprec) and did not change during and after CRHprec. All these changes in activity were modulated by IF1. During CRHnp, ATP concentration and ATP/ADP were reduced compared with Cnp and began to rise 6 min thereafter. During Cprec, both parameters were transiently reduced but increased during and after CRHprec. Hence, during CRHnp, F0F1 ATP synthase activity transiently increases and then decreases significantly. The short-lasting inhibition of the enzyme may explain why a few seconds of occlusion do not induce IP. After IP, F0F1 ATP synthase activity is blunted, and it is not affected by a subsequent 15 s of occlusion, which induces a blunted CRHprec. These results suggest that postischemic long-lasting inhibition of F0F1 ATP synthase activity may be a feature of the preconditioned heart. The increase in ATP concentration after preconditioning is in agreement with previous reports of reduced ATP hydrolysis by cytoplasmic ATPases.     

The unique histidine in OSCP subunit of F‐ATP synthase mediates inhibition of the permeability transition pore by acidic pH

The permeability transition pore (PTP) is a Ca²⁺‐dependent mitochondrial channel whose opening causes a permeability increase in the inner membrane to ions and solutes. The most potent inhibitors are matrix protons, with channel block at pH 6.5. Inhibition is reversible, mediated by histidyl residue(s), and prevented by their carbethoxylation by diethylpyrocarbonate (DPC), but their assignment is unsolved. We show that PTP inhibition by H⁺ is mediated by the highly conserved histidyl residue (H112 in the human mature protein) of oligomycin sensitivity conferral protein (OSCP) subunit of mitochondrial F₁F_O (F)‐ATP synthase, which we also show to undergo carbethoxylation after reaction of mitochondria with DPC. Mitochondrial PTP‐dependent swelling cannot be inhibited by acidic pH in H112Q and H112Y OSCP mutants, and the corresponding megachannels (the electrophysiological counterpart of the PTP) are insensitive to inhibition by acidic pH in patch‐clamp recordings of mitoplasts. Cells harboring the H112Q and H112Y mutations are sensitized to anoxic cell death at acidic pH. These results demonstrate that PTP channel formation and its inhibition by H⁺ are mediated by the F‐ATP synthase.