Isolated epsilon subunit of thermophilic F1-ATPase binds ATP

F1-ATPase, a soluble part of the F0F1-ATP synthase, has subunit structure alpha3beta3gammadeltaepsilon in which nucleotide-binding sites are located in the alpha and beta subunits and, as believed, in none of the other subunits. However, we report here that the isolated epsilon subunit of F1-ATPase from thermophilic Bacillus strain PS3 can bind ATP. The binding was directly demonstrated by isolating the epsilon subunit-ATP complex with gel filtration chromatography. The binding was not dependent on Mg2+ but was highly specific for ATP; however, ADP, GTP, UTP, and CTP failed to bind. The epsilon subunit lacking the C-terminal helical hairpin was unable to bind ATP. Although ATP binding to the isolated epsilon subunits from other organisms has not been detected under the same conditions, a possibility emerges that the epsilon subunit acts as a built in cellular ATP level sensor of F0F1-ATP synthase.     

Isolated epsilon subunit of Bacillus subtilis F1-ATPase binds ATP

Previously, we demonstrated ATP binding to the isolated epsilon subunit of F1-ATPase from thermophilic Bacillus PS3 [Kato-Yamada Y., Yoshida M. (2003) J. Biol. Chem. 278, 36013]. However, whether it is a general feature of the epsilon subunit from other sources is yet unclear. Here, using a sensitive method to detect weak interactions between fluorescently labeled epsilon subunit and nucleotide, it was shown that the epsilon subunit of F1-ATPase from Bacillus subtilis also bound ATP. The dissociation constant for ATP binding at room temperature was calculated to be 2 mM, which may be suitable for sensing cellular ATP concentration in vivo.     

The regulator of the F1 motor: inhibition of rotation of cyanobacterial F1-ATPase by the epsilon subunit

The chloroplast-type F(1) ATPase is the key enzyme of energy conversion in chloroplasts, and is regulated by the endogenous inhibitor epsilon, tightly bound ADP, the membrane potential and the redox state of the gamma subunit. In order to understand the molecular mechanism of epsilon inhibition, we constructed an expression system for the alpha(3)beta(3)gamma subcomplex in thermophilic cyanobacteria allowing thorough investigation of epsilon inhibition. epsilon Inhibition was found to be ATP-independent, and different to that observed for bacterial F(1)-ATPase. The role of the additional region on the gamma subunit of chloroplast-type F(1)-ATPase in epsilon inhibition was also determined. By single molecule rotation analysis, we succeeded in assigning the pausing angular position of gamma in epsilon inhibition, which was found to be identical to that observed for ATP hydrolysis, product release and ADP inhibition, but distinctly different from the waiting position for ATP binding. These results suggest that the epsilon subunit of chloroplast-type ATP synthase plays an important regulator for the rotary motor enzyme, thus preventing wasteful ATP hydrolysis.     

Epsilon subunit of Escherichia coli F1-ATPase: effects on affinity for aurovertin and inhibition of product release in unisite ATP hydrolysis

The epsilon subunit of Escherichia coli F1-ATPase is a tightly bound but dissociable partial inhibitor of ATPase activity. The effects of epsilon on the enzyme were investigated by comparing the ATPase activity and aurovertin binding properties of the epsilon-depleted F1-ATPase and the epsilon-replete complex. Kinetic data of multisite ATP hydrolysis were analyzed to give the best fit for one, two, or three kinetic components. Each form of F1-ATPase contained a high-affinity component, with a Km near 20 microM and a velocity of approximately 1 unit/mg. Each also exhibited a component with a Km in the range of 0.2 mM. The velocity of this component was 25 units/mg for epsilon-depleted ATPase but only 4 units/mg for epsilon-replete enzyme. The epsilon-depleted enzyme also contained a very low affinity component not present in the epsilon-replete enzyme. In unisite hydrolysis studies, epsilon had no effect on the equilibrium between substrate ATP and product ADP.P1 at the active site but reduced the rate of product release 15-fold. These results suggest that epsilon subunit slows a conformational change that is required to reduce the affinity at the active site, allowing dissociation of product. It is suggested that inhibition of multisite hydrolysis by epsilon is also due to a reduced rate of product release. epsilon-depleted F1-ATPase showed little of no modulation of aurovertin fluorescence by added ADP and ATP. Aurovertin fluorescence titrations in buffer containing ethylenediaminetetraacetic acid (EDTA) revealed that epsilon-depleted enzyme had high affinity for aurovertin (Kd less than 0.1 microM) regardless of the presence of nucleotides.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reversible ischemic inhibition of F(1)F(0)-ATPase in rat and human myocardium

The physiological role of F(1)F(0)-ATPase inhibition in ischemia may be to retard ATP depletion although views of the significance of IF(1) are at variance. We corroborate here a method for measuring the ex vivo activity of F(1)F(0)-ATPase in perfused rat heart and show that observation of ischemic F(1)F(0)-ATPase inhibition in rat heart is critically dependent on the sample preparation and assay conditions, and that the methods can be applied to assay the ischemic and reperfused human heart during coronary by-pass surgery. A 5-min period of ischemia inhibited F(1)F(0)-ATPase by 20% in both rat and human myocardium. After a 15-min reperfusion a subsequent 5-min period of ischemia doubled the inhibition in the rat heart but this potentiation was lost after 120 min of reperfusion. Experiments with isolated rat heart mitochondria showed that ATP hydrolysis is required for effective inhibition by uncoupling. The concentration of oligomycin for 50% inhibition (I(50)) for oxygen consumption was five times higher than its I(50) for F(1)F(0)-ATPase. Because of the different control strengths of F(1)F(0)-ATPase in oxidative phosphorylation and ATP hydrolysis an inhibition of the F(1)F(0)-ATPase activity in ischemia with the resultant ATP-sparing has an advantage even in an ischemia/reperfusion situation.     

Role of the amino terminal region of the epsilon subunit of Escherichia coli H(+)-ATPase (F0F1).

Escherichia coli strain KF148(SD-) defective in translation of the uncC gene for the epsilon subunit of H(+)-ATPase could not support growth by oxidative phosphorylation due to lack of F1 binding to Fo (M. Kuki, T. Noumi, M. Maeda, A. Amemura, and M. Futai, 1988, J. Biol. Chem. 263, 17, 437-17, 442). Mutant uncC genes for epsilon subunits lacking different lengths from the amino terminus were constructed and introduced into strain KF148(SD-). F1 with an epsilon subunit lacking the 15 amino-terminal residues could bind to F0 in a functionally competent manner, indicating that these amino acid residues are not absolutely necessary for formation of a functional enzyme. However, mutant F1 in which the epsilon subunit lacked 16 amino-terminal residues showed defective coupling between ATP hydrolysis (synthesis) and H(+)-translocation, although the mutant F1 showed partial binding to Fo. These findings suggest that the epsilon subunit is essential for binding of F1 to F0 and for normal H(+)-translocation. Previously, Kuki et al. (cited above) reported that 60 residues were not necessary for a functional enzyme. However, the mutant with an epsilon subunit lacking 15 residues from the amino terminus and 4 residues from the carboxyl terminus was defective in oxidative phosphorylation, suggesting that both terminal regions affect the conformation of the region essential for a functional enzyme.     

Farnesol-induced generation of reactive oxygen species dependent on mitochondrial transmembrane potential hyperpolarization mediated by F(0)F(1)-ATPase in yeast

An isoprenoid farnesol (FOH) inhibited cellular oxygen consumption and induced mitochondrial generation of reactive oxygen species (ROS) in cells of Saccharomyces cerevisiae in correlation with hyperpolarization of the mitochondrial transmembrane potential (mtDeltaPsi). The FOH-induced events were coordinately abolished with the F(1)-ATPase inhibitor sodium azide as well as the F(0)F(1)-ATPase inhibitor oligomycin, suggesting the dependence of ROS generation on mtDeltaPsi hyperpolarization mediated by the proton pumping function of F(0)F(1)-ATPase as a result of ATP hydrolysis. The role of F(1)-ATPase activity in mtDeltaPsi hyperpolarization was supported by the intracellular depletion of ATP in FOH-treated cells and its protection with sodium azide. An indirect mechanism was suggested to exist in the regulation of F(0)F(1)-ATPase by FOH to accelerate its ATP-hydrolyzing activity.     

Inhibition of ATP hydrolysis by thermoalkaliphilic F1Fo-ATP synthase is controlled by the C terminus of the epsilon subunit

The F(1)F(o)-ATP synthases of alkaliphilic bacteria exhibit latent ATPase activity, and for the thermoalkaliphile Bacillus sp. strain TA2.A1, this activity is intrinsic to the F(1) moiety. To study the mechanism of ATPase inhibition, we developed a heterologous expression system in Escherichia coli to produce TA2F(1) complexes from this thermoalkaliphile. Like the native F(1)F(o)-ATP synthase, the recombinant TA2F(1) was blocked in ATP hydrolysis activity, and this activity was stimulated by the detergent lauryldimethylamine oxide. To determine if the C-terminal domain of the epsilon subunit acts as an inhibitor of ATPase activity and if an electrostatic interaction plays a role, a TA2F(1) mutant with either a truncated epsilon subunit [i.e., TA2F(1)(epsilon(DeltaC))] or substitution of basic residues in the second alpha-helix of epsilon with nonpolar alanines [i.e., TA2F(1)(epsilon(6A))] was constructed. Both mutants showed ATP hydrolysis activity at low and high concentrations of ATP. Treatment of the purified F(1)F(o)-ATP synthase and TA2F(1)(epsilon(WT)) complex with proteases revealed that the epsilon subunit was resistant to proteolytic digestion. In contrast, the epsilon subunit of TA2F(1)(epsilon(6A)) was completely degraded by trypsin, indicating that the C-terminal arm was in a conformation where it was no longer protected from proteolytic digestion. In addition, ATPase activity was not further activated by protease treatment when compared to the untreated control, supporting the observation that epsilon was responsible for inhibition of ATPase activity. To study the effect of the alanine substitutions in the epsilon subunit in the entire holoenzyme, we reconstituted recombinant TA2F(1) complexes with F(1)-stripped native membranes of strain TA2.A1. The reconstituted TA2F(o)F(1)(epsilon(WT)) was blocked in ATP hydrolysis and exhibited low levels of ATP-driven proton pumping consistent with the F(1)F(o)-ATP synthase in native membranes. Reconstituted TA2F(o)F(1)(epsilon(6A)) exhibited ATPase activity that correlated with increased ATP-driven proton pumping, confirming that the epsilon subunit also inhibits ATPase activity of TA2F(o)F(1).     

F0F1-ATPase/synthase is geared to the synthesis mode by conformational rearrangement of epsilon subunit in response to proton motive force and ADP/ATP balance

The epsilon subunit in F0F1-ATPase/synthase undergoes drastic conformational rearrangement, which involves the transition of two C-terminal helices between a hairpin "down"-state and an extended "up"-state, and the enzyme with the up-fixed epsilon cannot catalyze ATP hydrolysis but can catalyze ATP synthesis (Tsunoda, S. P., Rodgers, A. J. W., Aggeler, R., Wilce, M. C. J., Yoshida, M., and Capaldi, R. A. (2001) Proc. Natl. Acad. Sci. U. S. A. 98, 6560-6564). Here, using cross-linking between introduced cysteine residues as a probe, we have investigated the causes of the transition. Our findings are as follows. (i) In the up-state, the two helices of epsilon are fully extended to insert the C terminus into a deeper position in the central cavity of F1 than was thought previously. (ii) Without a nucleotide, epsilon is in the up-state. ATP induces the transition to the down-state, and ADP counteracts the action of ATP. (iii) Conversely, the enzyme with the down-state epsilon can bind an ATP analogue, 2',3'-O-(2,4,6-trinitrophenyl)-ATP, much faster than the enzyme with the up-state epsilon. (iv) Proton motive force stabilizes the up-state. Thus, responding to the increase of proton motive force and ADP, F0F1-ATPase/synthase would transform the epsilon subunit into the up-state conformation and change gear to the mode for ATP synthesis.     

Thermal inactivation of electron-transport functions and F0F1-ATPase activities

Bovine heart submitochondrial particles in suspension were heated at a designated temperature for 3 min, then cooled for biochemical assays at 30 degrees C. By enzyme activity measurements and polarographic assay of oxygen consumption, it is shown that the thermal denaturation of the respiratory chain takes place in at least four stages and each stage is irreversible. The first stage occurs at 51.0 +/- 1.0 degrees C, with the inactivation of NADH-linked respiration, ATP-driven reverse electron transport, F0F1 catalyzed ATP/Pi exchange, NADH and succinate-driven ATP synthesis. The second stage occurs at 56.0 +/- 1.0 degrees C, with the inactivation of succinate-linked proton pumping and respiration. The third stage occurs at 59.0 +/- 1.0 degrees C, with the inactivation of electron transfer from cytochrome c to cytochrome oxidase and ATP-dependent proton pumping. The ATP hydrolysis activity of F0F1 persists to 61.0 +/- 1.0 degrees C. An additional transition, detectable by differential scanning calorimetry, occurring around 70.0 +/- 2.0 degrees C, is probably associated with thermal denaturation of cytochrome c and other stable membrane proteins. In the presence of either mitochondrial matrix fluid or 2 mM mercaptoethanol, all five stages give rise to endothermic effects, with the absorption of approx. 25 J/g protein. Under aerobic conditions, however, the first four transitions become strongly exothermic, and release a total of approx. 105 J/g protein. Solubilized and reconstituted F0F1 vesicles also exhibit different inactivation temperatures for the ATP/Pi exchange, proton pumping and ATP hydrolysis activities. The first two activities are abolished at 49.0 +/- 1.0 degrees C, but the latter at 58.0 +/- 2.0 degrees C. Differential scanning calorimetry also detects biphasic transitions of F0F1, with similar temperatures of denaturation (49.0 and 54.0 degrees C). From these and other results presented in this communication, the following is concluded. (1) A selective inactivation, by the temperature treatment, of various functions of the electron-transport chain and of the F0F1 complex can be done. (2) The ATP synthesis activity of the F0F1 complex involves either a catalytic or a regulation subunit(s) which is not essential for ATP hydrolysis and the proton translocation. This subunit is 10 degrees C less stable than the hydrolytic site. Micromolar ADP stabilizes it from thermal denaturation by 4-5 degrees C, although ADP up to millimolar concentration does not protect the hydrolytic site and the proton-translocation site.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mutations in the conserved proline 43 residue of the uncE protein (subunit c) of Escherichia coli F1F0-ATPase alter the coupling of F1 to F0

The conserved Pro43 residue of the uncE protein (subunit c) of the Escherichia coli F1F0-ATPase was changed to Ser or Ala by oligonucleotide-directed mutagenesis, and the mutations were incorporated into the chromosome. The resultant mutant strains were capable of oxidative phosphorylation as indicated by their ability to grow on succinate and had growth yields on glucose that were 80-90% of wild type. Membrane vesicles from the mutants were slightly less efficient than wild type vesicles in ATP-driven proton pumping as indicated by ATP-dependent quenching of quinacrine fluorescence. The decreased quenching response was not due to increased H+ leakiness of the mutant membranes or to loss of F1-ATPase activity from the membrane. These results indicate that the mutant F1F0-ATPases are defective in coupling ATP hydrolysis to H+ translocation. The membrane ATPase activity of the mutants was inhibited less by dicyclohexylcarbodiimide than that of wild type. The decrease in sensitivity to inhibition by dicyclohexylcarbodiimide was caused primarily by dissociation of the F1-ATPase from the mutant F0 in the ATPase assay mixture. These results support the idea that Pro43, and neighboring conserved polar residues play an important role in the binding and functional coupling of F1 to F0. Although a Pro residue is found at position 43 in all species of subunit c studied, surprisingly, it is not absolutely essential to function.     

Probing conformations of the beta subunit of F0F1-ATP synthase in catalysis

A subcomplex of F0F1-ATP synthase (F0F1), alpha3beta3gamma, was shown to undergo the conformation(s) during ATP hydrolysis in which two of the three beta subunits have the "Closed" conformation simultaneously (CC conformation) [S.P. Tsunoda, E. Muneyuki, T. Amano, M. Yoshida, H. Noji, Cross-linking of two beta subunits in the closed conformation in F1-ATPase, J. Biol. Chem. 274 (1999) 5701-5706]. This was examined by the inter-subunit disulfide cross-linking between two mutant beta(I386C)s that was formed readily only when the enzyme was in the CC conformation. Here, we adopted the same method for the holoenzyme F0F1 from Bacillus PS3 and found that the CC conformation was generated during ATP hydrolysis but barely during ATP synthesis. The experiments using F0F1 with the epsilon subunit lacking C-terminal helices further suggest that this difference is related to dynamic nature of the epsilon subunit and that ATP synthesis is accelerated when it takes the pathway involving the CC conformation.     

Real-time monitoring of conformational dynamics of the epsilon subunit in F1-ATPase

It has been proposed that C-terminal two alpha-helices of the epsilon subunit of F1-ATPase can undergo conformational transition between retracted folded-hairpin form and extended form. Here, using F(1) from thermophilic Bacillus PS3, we monitored this transition in real time by fluorescence resonance energy transfer (FRET) between a donor dye and an acceptor dye attached to N terminus of the gamma subunit and C terminus of the epsilon subunit, respectively. High FRET (extended form) of F1 turned to low FRET (retracted form) by ATP, which then reverted as ATP was hydrolyzed to ADP. 5'-Adenyl-beta,gamma-imidodiphosphate, ADP + AlF4-, ADP + NaN3, and GTP also caused the retracted form, indicating that ATP binding to the catalytic beta subunits induces the transition. The ATP-induced transition from high FRET to low FRET occurred in a similar time scale to the ATP-induced activation of ATPase from inhibition by the epsilon subunit, although detailed kinetics were not the same. The transition became faster as temperature increased, but the extrapolated rate at 65 degrees C (physiological temperature of Bacillus PS3) was still too slow to assign the transition as an obligate step in the catalytic turnover. Furthermore, binding affinity of ATP to the isolated epsilon subunit was weakened as temperature increased, and the dissociation constant extrapolated to 65 degrees C reached to 0.67 mm, a consistent value to assume that the epsilon subunit acts as a sensor of ATP concentration in the cell.     

Formation of an energized inner membrane in mitochondria with a gamma-deficient F1-ATPase

Eukaryotic cells require mitochondrial compartments for viability. However, the budding yeast Saccharomyces cerevisiae is able to survive when mitochondrial DNA suffers substantial deletions or is completely absent, so long as a sufficient mitochondrial inner membrane potential is generated. In the absence of functional mitochondrial DNA, and consequently a functional electron transport chain and F(1)F(o)-ATPase, the essential electrical potential is maintained by the electrogenic exchange of ATP(4-) for ADP(3-) through the adenine nucleotide translocator. An essential aspect of this electrogenic process is the conversion of ATP(4-) to ADP(3-) in the mitochondrial matrix, and the nuclear-encoded subunits of F(1)-ATPase are hypothesized to be required for this process in vivo. Deletion of ATP3, the structural gene for the gamma subunit of the F(1)-ATPase, causes yeast to quantitatively lose mitochondrial DNA and grow extremely slowly, presumably by interfering with the generation of an energized inner membrane. A spontaneous suppressor of this slow-growth phenotype was found to convert a conserved glycine to serine in the beta subunit of F(1)-ATPase (atp2-227). This mutation allowed substantial ATP hydrolysis by the F(1)-ATPase even in the absence of the gamma subunit, enabling yeast to generate a twofold greater inner membrane potential in response to ATP compared to mitochondria isolated from yeast lacking the gamma subunit and containing wild-type beta subunits. Analysis of the suppressing mutation by blue native polyacrylamide gel electrophoresis also revealed that the alpha(3)beta(3) heterohexamer can form in the absence of the gamma subunit.     

The structure of the central stalk in bovine F(1)-ATPase at 2.4 A resolution

The central stalk in ATP synthase, made of gamma, delta and epsilon subunits in the mitochondrial enzyme, is the key rotary element in the enzyme's catalytic mechanism. The gamma subunit penetrates the catalytic (alpha beta)(3) domain and protrudes beneath it, interacting with a ring of c subunits in the membrane that drives rotation of the stalk during ATP synthesis. In other crystals of F(1)-ATPase, the protrusion was disordered, but with crystals of F(1)-ATPase inhibited with dicyclohexylcarbodiimide, the complete structure was revealed. The delta and epsilon subunits interact with a Rossmann fold in the gamma subunit, forming a foot. In ATP synthase, this foot interacts with the c-ring and couples the transmembrane proton motive force to catalysis in the (alpha beta)(3) domain.     

Activation and inhibition of the Escherichia coli F1-ATPase by monoclonal antibodies which recognize the epsilon subunit

The properties of two monoclonal antibodies which recognize the epsilon subunit of Escherichia coli F1-ATPase were studied in detail. The epsilon subunit is a tightly bound but dissociable inhibitor of the ATPase activity of soluble F1-ATPase. Antibody epsilon-1 binds free epsilon with a dissociation constant of 2.4 nM but cannot bind epsilon when it is associated with F1-ATPase. Likewise epsilon cannot associate with F1-ATPase in the presence of high concentrations of epsilon-1. Thus epsilon-1 activates F1-ATPase which contains the epsilon subunit, and prevents added epsilon from inhibiting the enzyme. Epsilon-1 cannot bind to membrane-bound F1-ATPase. The epsilon-4 antibody binds free epsilon with a dissociation constant of 26 nM. Epsilon-4 can bind to the F1-ATPase complex, but, like epsilon-1, it reverses the inhibition of F1-ATPase by the epsilon subunit. The epsilon subunit remains crosslinkable to both the beta and gamma subunits in the presence of epsilon-4, indicating that it is not grossly displaced from its normal position by the antibody. Presumably the activation arises from more subtle conformational effects. Antibodies epsilon-4 and delta-2, which recognizes the delta subunit, both bind to F1F0 in E. coli membrane vesicles, indicating that these subunits are substantially exposed in the membrane-bound complex. Epsilon-4 inhibits the ATPase activity of the membrane-bound enzyme by about 50%, and Fab prepared from epsilon-4 inhibits by about 40%. This inhibition is not associated with any substantial change in the major apparent Km for ATP. These results suggest that inhibition of membrane-bound F1-ATPase arises from steric effects of the antibody.     

Met23Lys mutation in subunit gamma of F(O)F(1)-ATP synthase from Rhodobacter capsulatus impairs the activation of ATP hydrolysis by protonmotive force

H(+)-F(O)F(1)-ATP synthase couples proton flow through its membrane portion, F(O), to the synthesis of ATP in its headpiece, F(1). Upon reversal of the reaction the enzyme functions as a proton pumping ATPase. Even in the simplest bacterial enzyme the ATPase activity is regulated by several mechanisms, involving inhibition by MgADP, conformational transitions of the epsilon subunit, and activation by protonmotive force. Here we report that the Met23Lys mutation in the gamma subunit of the Rhodobacter capsulatus ATP synthase significantly impaired the activation of ATP hydrolysis by protonmotive force. The impairment in the mutant was due to faster enzyme deactivation that was particularly evident at low ATP/ADP ratio. We suggest that the electrostatic interaction of the introduced gammaLys23 with the DELSEED region of subunit beta stabilized the ADP-inhibited state of the enzyme by hindering the rotation of subunit gamma rotation which is necessary for the activation.     

The epsilon subunit and inhibitory monoclonal antibodies interact with the carboxyl-terminal region of the beta subunit of Escherichia coli F1-ATPase

The epitopes of two classes of monoclonal antibody and the binding site for the epsilon subunit have been mapped to the carboxyl-terminal region of the beta subunit of Escherichia coli F1-ATPase using partial CNBr cleavage, weak acid hydrolysis, and Western blots. One class of antibody, B-I, inhibits ATPase activity; the other class, B-II, recognizes an epitope not exposed on the surface of intact F1. Data from two-dimensional gels and blots of beta cleaved with CNBr/weak acid showed that the B-I epitope lies between Asp-381 and the carboxyl-terminal Leu-459, and the B-II epitope lies between Asp-345 and Met-380. Weak acid hydrolysis of the beta-epsilon product obtained by cross-linking F1 with a water-soluble carbodiimide yielded a fragment containing epsilon and a 13-kDa carboxyl-terminal fragment of beta indicating that epsilon interacts with this portion of beta as well. Fab fragments from the B-I antibody beta-6 could be cross-linked to the epsilon subunit in native F1 by various cross-linking agents demonstrating that the antibody and the epsilon subunit occupy adjacent, nonoverlapping sites on the beta subunit. Implications of these results for the roles of the epsilon subunit and of the carboxyl-terminal region of the beta subunit in F1 are discussed.     

Kinetic properties of F1-ATPase influence the ability of yeasts to grow in anoxia or absence of mtDNA

A mechanism for hypoxia survival by eukaryotic cells is suggested from studies on the petite mutation of yeasts. Previous work has shown that mutations in the alpha, beta and gamma subunit genes of F1-ATPase can suppress lethality due to loss of the mitochondrial genome from the petite-negative yeast Kluyveromyceslactis. Here it is reported that suppressor mutations appear to increase the affinity of F1-ATPase for ATP. Extension of this study to other yeasts shows that petite-positive species have a higher affinity for ATP in the hydrolysis reaction than petite-negative species. Possession of a F1-ATPase with a low K(m) for ATP is considered to be an adaptation for hypoxic growth, enabling maintenance of the mitochondrial inner membrane potential, deltapsi, by enhanced export of protons through F1F0-ATP synthase connected to increased ATP hydrolysis at low substrate concentration.     

Excessive ATP hydrolysis in ischemic myocardium by mitochondrial F1F0-ATPase: effect of selective pharmacological inhibition of mitochondrial ATPase hydrolase activity

Mitochondrial F(1)F(0)-ATPase normally synthesizes ATP in the heart, but under ischemic conditions this enzyme paradoxically causes ATP hydrolysis. Nonselective inhibitors of this enzyme (aurovertin, oligomycin) inhibit ATP synthesis in normal tissue but also inhibit ATP hydrolysis in ischemic myocardium. We characterized the profile of aurovertin and oligomycin in ischemic and nonischemic rat myocardium and compared this with the profile of BMS-199264, which only inhibits F(1)F(0)-ATP hydrolase activity. In isolated rat hearts, aurovertin (1-10 microM) and oligomycin (10 microM), at concentrations inhibiting ATPase activity, reduced ATP concentration and contractile function in the nonischemic heart but significantly reduced the rate of ATP depletion during ischemia. They also inhibited recovery of reperfusion ATP and contractile function, consistent with nonselective F(1)F(0)-ATPase inhibitory activity, which suggests that upon reperfusion, the hydrolase activity switches back to ATP synthesis. BMS-199264 inhibits F(1)F(0) hydrolase activity in submitochondrial particles with no effect on ATP synthase activity. BMS-199264 (1-10 microM) conserved ATP in rat hearts during ischemia while having no effect on preischemic contractile function or ATP concentration. Reperfusion ATP levels were replenished faster and necrosis was reduced by BMS-199264. ATP hydrolase activity ex vivo was selectively inhibited by BMS-199264. Therefore, excessive ATP hydrolysis by F(1)F(0)-ATPase contributes to the decline in cardiac energy reserve during ischemia and selective inhibition of ATP hydrolase activity can protect ischemic myocardium.