Monoclonal antibody modification of the ATPase activity of Escherichia coli F1 ATPase

Monoclonal antibodies (mAbs) have been made against each of the five subunits of ECF1 (alpha, beta, gamma, delta, and epsilon), and these have been used in topology studies and for examination of the role of individual subunits in the functioning of the enzyme. All of the mAbs obtained reacted with ECF1, while several failed to react with ECF1F0, including three mAbs against the gamma subunit (gamma II, gamma III, and gamma IV), one mAb against delta, and two mAbs against epsilon (epsilon I and epsilon II). These topology data are consistent with the gamma, delta, and epsilon subunits being located at the interface between the F1 and F0 parts of the complex. Two forms of ECF1 were used to study the effects of mAbs on the ATPase activity of the enzyme: ECF1 with the epsilon subunit tightly bound and acting to inhibit activity and ECF1* in which the delta and epsilon subunits had been removed by organic solvent treatment. ECF1* had an ATPase activity under standard conditions of 93 mumol of ATP hydrolyzed min-1 mg-1, cf. an activity of 7.5 units mg-1 for our standard ECF1 preparation and 64 units mg-1 for enzyme in which the epsilon subunit had been removed by trypsin treatment. The protease digestion of ECF1* reduced activity to 64 units mg-1 in a complicated process involving an inhibition of activity by cleavage of the alpha subunit, activation by cleavage of gamma, and inhibition with cleavage of the beta subunit. mAbs to the gamma subunit, gamma II and gamma III, activated ECF1 by 4.4- and 2.4-fold, respectively, by changing the affinity of the enzyme for the epsilon subunit, as evidenced by density gradient centrifugation experiments. The gamma-subunit mAbs did not alter the ATPase activity of ECF1*- or trypsin-treated enzyme. The alpha-subunit mAb (alpha I) activated ECF1 by a factor of 2.5-fold and ECF1F0 by 1.3-fold, but inhibited the ATPase activity of ECF1* by 30%.     

The membrane ATPase of alkalophilic Bacillus firmus RAB is an F1-type ATPase

At the optimal pH for growth (pH 10.5), alkalophilic Bacillus firmus RAB, an obligate aerobe, exhibits normal rates of oxidative phosphorylation despite the low transmembrane proton electrochemical gradient, about -60 mV (delta psi = -180 mV and delta pH = +120 mV). This bioenergetic problem might be resolved by use of an Na+ coupled ATP synthase; otherwise an F1F0-ATPase must be able to utilize low driving forces in this organism. The ATPase activity was extracted from everted membrane vesicles by low ionic strength treatment and purified to homogeneity by hydrophobic interaction chromatography and sucrose density gradient centrifugation. The ATPase preparation had the characteristic F1-ATPase subunit structure, with Mr values of 51,500 (alpha), 48,900 (beta), 34,400 (gamma), 23,300 (delta), and 14,500 (epsilon); the identity of the alpha and beta subunits was confirmed by immunoblotting with anti-beta of Escherichia coli and anti-B. firmus RAB F1. Methanol and octyl glucoside, agents that stimulated the low basal membrane ATPase activity 10- to 12-fold, dramatically elevated the MgATPase activity of the purified F1, more than 150-fold, to 50 mumol min-1 mg protein-1. Anti-F1 inhibited membrane ATPase activity greater than or equal to 80%. The membranes exhibited no Na+-stimulated or vanadate-sensitive ATPase activity when prepared in the absence or presence of Na+ or ATP. These findings, which are consistent with previous studies, establish that in alkalophilic bacteria, ATP hydrolysis, and presumably ATP synthesis is catalyzed by an F1F0-ATPase rather than a Na+ ATPase.     

Simultaneous bindings of ATPase inhibitor and 9K protein to F1F0-ATPase in the presence of 15K protein in yeast mitochondria

Yeast mitochondrial ATP synthase has three regulatory proteins, ATPase inhibitor, 9K protein, and 15K protein. The 9K protein binds directly to purified F1-ATPase, as does the ATPase inhibitor, but the 15K protein does not [Hashimoto, T. et al. (1987) J. Biochem. 102, 685-692]. In the present study, we found that 15K protein bound to purified F1F0-ATPase, forming an equimolar complex with the enzyme. The apparent dissociation constant was calculated to be 1.4 x 10(-5) M. The ATPase inhibitor and 9K protein also bound to F1F0-ATPase in the presence of ATP and Mg2+, and the dissociation constants of their bindings were about 3 X 10(-6) M. They bound to the enzyme competitively in the absence of 15K protein, but in its presence, they bound in equimolar amounts to the enzyme. The ATP-hydrolyzing activity of the enzyme-ligand complex was greatly influenced by the order of bindings of ATPase inhibitor and 9K protein: when the ATPase inhibitor was bound first, the activity of the enzyme was inhibited completely and was not restored by 9K protein, but when 9K protein was added first, the activity was inhibited only partially even after equimolar binding of the ATPase inhibitor to the enzyme. These observations strongly suggest that the 15K protein binds to the F0 part and functions to hold the ATPase inhibitor or 9K protein on the F1 subunit.     

Effect of the delta subunit on assembly and proton permeability of the F0 proton channel of Escherichia coli F1F0 ATPase.

During the assembly of the Escherichia coli proton-translocating ATPase, the subunits of F1 interact with F0 to increase the proton permeability of the transmembrane proton channel. We tested the involvement of the delta subunit in this process by partially and completely deleting uncH (delta subunit) from a plasmid carrying the genes for the F0 subunits and delta and testing the effects of those F0 plasmids on the growth of unc+ and unc mutant E. coli strains. We found that the delta subunit was required for inhibition of growth of unc+ cells. We also tested membranes isolated from unc-deleted cells containing F0 plasmids for F1-binding ability. In unc-deleted cells, these plasmids produced F0 in amounts comparable to those found in normal unc+ E. coli cells, while having only small effects on cell growth. These studies demonstrate that the delta subunit plays an important role in opening the F0 proton channel but that it does not serve as a temporary plug of F0 during assembly, as had been previously speculated (S. Pati and W. S. A. Brusilow, J. Biol. Chem. 264:2640-2644, 1989).     

Role of the delta subunit in enhancing proton conduction through the F0 of the Escherichia coli F1F0 ATPase.

We studied the effect of the delta subunit of the Escherichia coli F1 ATPase on the proton permeability of the F0 proton channel synthesized and assembled in vivo. Membranes isolated from an unc deletion strain carrying a plasmid containing the genes for the F0 subunits and the delta subunit were significantly more permeable to protons than membranes isolated from the same strain carrying a plasmid containing the genes for the F0 subunits alone. This increased proton permeability could be blocked by treatment with either dicyclohexyl-carbodiimide or purified F1, both of which block proton conduction through the F0. After reconstitution with purified F1 in vitro, both membrane preparations could couple proton pumping to ATP hydrolysis. These results demonstrate that an interaction between the delta subunit and the F0 during synthesis and assembly produces a significant change in the proton permeability of the F0 proton channel.     

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.     

Characterization of the Na+-stimulated ATPase of Propionigenium modestum as an enzyme of the F1F0 type

The ATP-hydrolyzing activity of Propionigenium modestum was extracted from the membranes with Triton X-100 or by incubation with EDTA at low ionic strength. The ATPase in the Triton extract was highly sensitive to dicyclohexylcarbodiimide but not to vanadate. These properties are characteristic for enzymes of the F1 F0 type. The ATPase was specifically activated by Na+ ions yielding a 15-fold increase in catalytic activity at 5 mM Na+ concentration. The additional presence of 1% Triton X-100 caused a further 1.5-fold activation. In the absence of Na+ Triton stimulated the ATPase about 13-fold. The Triton-stimulated ATPase was further activated about 1.5-2-fold by Na+ addition. The ATPase extracted by the low-ionic-strength treatment was purified to homogeneity by fractionation with poly(ethylene glycol) and gel chromatography. The enzyme had the characteristic F1-ATPase subunit structure with Mr values of 58,000 (alpha), 56,000 (beta), 37,600 (gamma), 22,700 (delta), and 14,000 (epsilon). The F1-ATPase was not stimulated by Na+ ions. The membrane-bound ATPase was reconstituted from the purified F1 part and F1-depleted membranes, thus further indicating an F1 F0 structure for the ATPase of P. modestum. Upon reconstitution the ATPase recovered its stimulation by Na+ ions, suggesting that the binding site for Na+ is localized on the membrane-bound F0 part of the enzyme complex.     

Correspondence of minor subunits of plant mitochondrial F1ATPase to F1F0ATPase subunits of other organisms

In addition to two major alpha- and beta-subunits, the soluble oligomycin-insensitive F1ATPase purified from sweet potato root mitochondria contains four different minor subunits of gamma (Mr = 35,500), delta (Mr = 27,000), delta' (Mr = 23,000), and epsilon (Mr = 12,000) (Iwasaki, Y., and Asashi, T. (1983) Arch. Biochem. Biophys. 227, 164-173). Among these minor subunits, the delta-subunit specifically cross-reacted with an antibody against the delta-subunit of maize mitochondrial F1 which contains only three minor gamma-, delta- and epsilon-subunits like F1ATPases from other organisms, indicating that the delta'-subunit is an extra subunit of sweet potato F1 which is absent in the maize F1. All of the four minor subunits of sweet potato F1 were purified and their N-terminal amino acid sequences of 30-36 residues were determined. The N-terminal sequence of gamma-subunit was homologous to those of the gamma-subunits of bacterial F1 and mammalian mitochondrial F1. The N-terminal sequence of the delta-subunit was homologous to those of the delta-subunits of bacterial F1, chloroplast CF1, and oligomycin sensitivity conferring protein of bovine mitochondrial F1F0. A sequence homology was also observed between the sweet potato epsilon-subunit and the epsilon-subunit of bovine mitochondrial F1. The N-terminal sequence of the delta'-subunit did not show any significant sequence homology to known protein sequences. These subunit correspondences place plant mitochondrial F1 at an unique position in the evolution of F1ATPase.     

H+-ATPase activity of Escherichia coli F1F0 is blocked after reaction of dicyclohexylcarbodiimide with a single proteolipid (subunit c) of the F0 complex

Dicyclohexylcarbodiimide (DCCD) specifically inhibits the F1F0-H+-ATP synthase complex of Escherichia coli by covalently modifying a proteolipid subunit that is embedded in the membrane. Multiple copies of the DCCD-reactive protein, also known as subunit c, are found in the F1F0 complex. In order to determine the minimum stoichiometry of reaction, we have treated E. coli membranes with DCCD, at varying concentrations and for varying times, and correlated inhibition of ATPase activity with the degree of modification of subunit c. Subunit c was purified from the membrane, and the degree of modification was determined by two methods. In the "specific radioactivity" method, the moles of [14C]DCCD per total mole of subunit c was calculated from the radioactivity incorporated per mg of protein, and conversion of mg of protein to mol of protein based upon amino acid analysis. In the "high performance liquid chromatography (HPLC) peak area" method, the DCCD-modified subunit c was separated from unmodified subunit c on an anion exchange AX300 HPLC column, and the areas of the peaks from the chromatogram quantitated. The shape of the modification versus inhibition curve indicated that modification of a single subunit c per F0 was sufficient to abolish ATPase activity. The titration data were fit by nonlinear regression analysis to a single hit mathematical model, A = Un(1 - r) + r, where A is the relative activity, U is the ratio of unmodified/total subunit c, n is the number of subunit c per F0, and r is a residual fraction of ATPase activity that was resistant to inhibition by DCCD. The two methods gave values for n equal to 10 by the specific radioactivity method and 14 by the HPLC peak area method, and values for r of 0.28 and 0.30, respectively. Most of the r value was accounted for by the observed dissociation of 15-20% of the F1-ATPase from the membrane under ATPase assay conditions. When the minimal, experimentally justified value of r = 0.15 was used in the equation above, the calculated values of n were reduced to 8 and 11, respectively. The value of n determined here, with a probable range of uncertainty of 8-14, is consistent with, and provides an independent type of experimental support for, the suggested stoichiometry of 10 +/- 1 subunit c per F1F0, which was determined by a more precise radiolabeling method (Foster, D. L., and Fillingame, R. H. (1982) J. Biol. Chem. 257, 2009-2015).     

Plant mitochondrial F0F1 ATP synthase. Identification of the individual subunits and properties of the purified spinach leaf mitochondrial ATP synthase.

Spinach leaf mitochondrial F0F1 ATPase has been purified and is shown to consist of twelve polypeptides. Five of the polypeptides constitute the F1 part of the enzyme. The remaining polypeptides, with molecular masses of 28 kDa, 23 kDa, 18.5 kDa, 15 kDa, 10.5 kDa, 9.5 kDa and 8.5 kDa, belong to the F0 part of the enzyme. This is the first report concerning identification of the subunits of the plant mitochondrial F0. The identification of the components is achieved on the basis of the N-terminal amino acid sequence analysis and Western blot technique using monospecific antibodies against proteins characterized in other sources. The 28-kDa protein crossreacts with antibodies against the subunit of bovine heart ATPase with N-terminal Pro-Val-Pro- which corresponds to subunit F0b of Escherichia coli F0F1. Sequence analysis of the N-terminal 32 amino acids of the 23-kDa protein reveals that this protein is similar to mammalian oligomycin-sensitivity-conferring protein and corresponds to the F1 delta subunit of the chloroplast and E. coli ATPases. The 18.5-kDa protein crossreacts with antibodies against subunit 6 of the beef heart F0 and its N-terminal sequence of 14 amino acids shows a high degree of sequence similarity to the conserved regions at N-terminus of the ATPase subunits 6 from different sources. ATPase subunit 6 corresponds to subunit F0a of the E. coli enzyme. The 15-kDa protein and the 10.5-kDa protein crossreact with antibodies against F6 and the endogenous ATPase inhibitor protein of beef heart F0F1-ATPase, respectively. The 9.5-kDa protein is an N,N'-dicyclohexylcarbodiimide-binding protein corresponding to subunit F0c of the E. coli enzyme. The 8.5-kDa protein is of unknown identity. The isolated spinach mitochondrial F0F1 ATPase catalyzes oligomycin-sensitive ATPase activity of 3.5 mumol.mg-1.min-1. The enzyme catalyzes also hydrolysis of GTP (7.5 mumol.mg-1.min-1) and ITP (4.4 mumol.mg-1.min-1). Hydrolysis of ATP was stimulated fivefold in the presence of amphiphilic detergents, however the hydrolysis of other nucleotides could not be stimulated by these agents. These results show that the plant mitochondrial F0F1 ATPase complex differs in composition from the other mitochondrial, chloroplast and bacterial ATPases. The enzyme is, however, more closely related to the yeast mitochondrial ATPase and to the animal mitochondrial ATPase than to the chloroplast enzyme. The plant mitochondrial enzyme, however, exhibits catalytic properties which are characteristic for the chloroplast enzyme.     

The F1-type ATPase in anaerobic Lactobacillus casei

An ATPase from anaerobic Lactobacillus casei has been isolated and 100-times purified. The 400 kDa enzyme molecule was found to have a hexagonal structure 10 nm in diameter composed of at least six protein masses. SDS-electrophoresis reveals four or, under certain conditions, five types of subunit, of apparent molecular masses 57 (alpha), 55 (beta), 40 (gamma), 22 (delta) and 14 (epsilon) kDa with stoichiometry of 3 alpha, 3 beta, gamma, delta, epsilon. The following features resembling F1-ATPases from other sources were found to be inherent in the solubilized L. casei ATPase. (i) Detachment from the membrane desensitizes ATPase to low DCCD concentrations and sensitizes it to water-soluble carbodiimide. (ii) Soluble ATPase is inhibited by Nbf chloride and azide, is resistant to SH-modifiers and is activated by sulfite and octyl glucoside, the activating effect being much stronger than in the case of the membrane-bound ATPase. Substrate specificity of the enzyme is also similar to that of other factors F1. Divalent cations strongly activate the soluble enzyme when added at a concentration equal to that of ATP. An excess of Mn2+, Mg2+ or Co2+ inhibits ATPase activity of F1, whereas that of Ca2+ induces its further activation. No other F1-like ATPases are found in L. casei. It is concluded that this anaerobic bacterium possesses a typical F1-ATPase similar to those in mitochondria, chloroplasts, aerobic and photosynthetic eubacteria.     

Purification and reconstitution of the F1F0-ATP synthase from alkaliphilic Bacillus firmus OF4. Evidence that the enzyme translocates H+ but not Na+

The F1F0-ATP synthase from the alkaliphilic Bacillus firmus OF4 was purified in a reconstitutively active form, in good yield and with a high specific ATPase activity when appropriately activated. The purification procedure involved octyl glucoside extraction of washed membrane vesicles in the presence of 20% glycerol and asolectin followed by ammonium sulfate fractionation and sucrose density gradient centrifugation. The purified preparation was resolved into seven bands by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, corresponding to the five F1 subunits, alpha, beta, gamma, delta, and epsilon, and to the b and c subunits of the F0. Two-dimensional sodium dodecyl sulfate-poly-acrylamide gel analysis revealed a candidate for the alpha subunit of F0. The MgATPase activity of B. firmus OF4 F1F0 was barely detectable but could be stimulated, optimally more than 100-fold, by sulfite, methanol, and octyl thioglucoside. The enzyme was inhibited by N,N'-dicyclohexylcarbodiimide and sodium azide, but not by aurovertin, an inhibitor of the F1 from Escherichia coli. The F1F0 reconstituted into proteoliposomes catalyzed ATPase activity, ATP-Pi exchange, and ATP-dependent delta pH and delta psi formation. ATP hydrolysis was stimulated by protonophores while the other activities were abolished by protonophores. These activities were neither dependent on added sodium ions nor significantly affected by them. F1F0 proteoliposomes made from crude octyl glucoside extracts that also contained the Na+/H+ antiporter were shown to catalyze ATP-dependent Na+ uptake that was completely sensitive to carbonyl cyanide m-chlorophenyl-hydrazone; Na+ uptake activity was absent in proteoliposomes containing more purified F1F0 but lacking the Na+/H+ antiporter. These data show that the F1F0 translocates protons and does not substitute Na+ for H+ in energy coupling.     

The mitochondrial F1ATPase alpha-subunit is necessary for efficient import of mitochondrial precursors.

The mitochondrial import and assembly of the F1ATPase subunits requires, respectively, the participation of the molecular chaperones hsp70SSA1 and hsp70SSC1 and other components operating on opposite sides of the mitochondrial membrane. In previous studies, both the homology and the assembly properties of the F1ATPase alpha-subunit (ATP1p) compared to the groEL homologue, hsp60, have led to the proposal that this subunit could exhibit chaperone-like activity. In this report the extent to which this subunit participates in protein transport has been determined by comparing import into mitochondria that lack the F1ATPase alpha-subunit (delta ATP1) versus mitochondria that lack the other major catalytic subunit, the F1ATPase beta-subunit (delta ATP2). Yeast mutants lacking the alpha-subunit but not the beta-subunit grow much more slowly than expected on fermentable carbon sources and exhibit delayed kinetics of protein import for several mitochondrial precursors such as the F1 beta subunit, hsp60MIF4 and subunits 4 and 5 of the cytochrome oxidase. In vitro and in vivo the F1 beta-subunit precursor accumulates as a translocation intermediate in absence of the F1 alpha-subunit. In the absence of both the ATPase subunits yeast grows at the same rate as a strain lacking only the beta-subunit, and import of mitochondrial precursors is restored to that of wild type. These data indicate that the F1 alpha-subunit likely functions as an "assembly partner" to influence protein import rather than functioning directly as a chaperone. These data are discussed in light of the relationship between the import and assembly of proteins in mitochondria.     

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.     

A model of the quaternary structure of the Escherichia coli F1 ATPase from X-ray solution scattering and evidence for structural changes in the delta subunit during ATP hydrolysis.

The shape and subunit arrangement of the Escherichia coli F1 ATPase (ECF1 ATPase) was investigated by synchrotron radiation x-ray solution scattering. The radius of gyration and the maximum dimension of the enzyme complex are 4.61 +/- 0.03 nm and 15.5 +/- 0.05 nm, respectively. The shape of the complex was determined ab initio from the scattering data at a resolution of 3 nm, which allowed unequivocal identification of the volume occupied by the alpha3beta3 subassembly and further positioning of the atomic models of the smaller subunits. The delta subunit was positioned near the bottom of the alpha3beta3 hexamer in a location consistent with a beta-delta disulfide formation in the mutant ECF1 ATPase, betaY331W:betaY381C:epsilonS108C, when MgADP is bound to the enzyme. The position and orientation of the epsilon subunit were found by interactively fitting the solution scattering data to maintain connection of the two-helix hairpin with the alpha3beta3 complex and binding of the beta-sandwich domain to the gamma subunit. Nucleotide-dependent changes of the delta subunit were investigated by stopped-flow fluorescence technique at 12 degrees C using N-[4-[7-(dimethylamino)-4-methyl]coumarin-3-yl]maleimide (CM) as a label. Fluorescence quenching monitored after addition of MgATP was rapid [k = 6.6 s-1] and then remained constant. Binding of MgADP and the noncleavable nucleotide analog AMP . PNP caused an initial fluorescent quenching followed by a slower decay back to the original level. This suggests that the delta subunit undergoes conformational changes and/or rearrangements in the ECF1 ATPase during ATP hydrolysis.     

Diethylstilbestrol. A novel F0-directed probe of the mitochondrial proton ATPase

At low concentrations, diethylstilbestrol (DES) is shown to be a potent F0-directed inhibitor of the F0F1-ATPase of rat liver mitochondria. In analogy to other F0-directed inhibitors, DES inhibits both the ATPase and ATP-dependent proton-translocation activities of the purified and membrane bound enzyme. When added at low concentrations with dicyclohexylcarbodiimide (DCCD), a covalent inhibitor, DES acts synergistically to inhibit ATPase activity of the complex. At higher concentrations, DES restores DCCD-inhibited ATPase activity. However, there is no restoration of ATP-dependent proton translocation. Under these conditions DCCD remains covalently bound to the F0F1-ATPase complex and F1 remains bound to Fo. Significantly, when the F0F1-ATPase is inhibited by the Fo-directed inhibitor venturicidin rather than DCCD, DES is also able to restore ATPase activity. In contrast, DES is unable to restore ATPase activity to F0F1 preparations inhibited by the Fo-directed inhibitors oligomycin or tricyclohexyltin. However, combinations of [DES + DCCD] or [DES + venturicidin] can restore ATPase activity to F0F1 preparations inhibited by either oligomycin or tricyclohexyltin. Results presented here indicate that the F0 moiety of the rat liver mitochondrial proton ATPase contains a distinct binding site for DES. In addition, they suggest that at saturating concentrations simultaneous occupancy of the DES binding site and sites for either DCCD or venturicidin promote "uncoupled" ATP hydrolysis.     

Differential scanning calorimetry study of local anesthetic effects on F1ATPase and submitochondrial particles

The differential scanning calorimetry trace of F1ATPase, prepared from beef heart submitochondrial particles, has a single sharp endothermic transition at 80.5 +/- 1.0 degrees C and a half-height peak width of 2.0 +/- 0.2 degrees. The transition enthalpy is 19 +/- 2 cal/g of protein. Submitochondrial particles (SMP) have a similar peak at 75.1 +/- 0.5 degrees C with a half-height peak width of 1.8 +/- 0.1 degrees and an enthalpy of 5 +/- 1 cal/g of SMP protein. The SMP transition is provisionally identified as being due to membrane-bound F1ATPase. Tetracaine and dibucaine cause these transitions to shift to lower temperatures; addition of 0.3 mM dibucaine gives peaks at 71.7 and 64.9 degrees C for F1ATPase and SMP, respectively, and 1.0 mM tetracaine gives peaks at 70.0 and 60.5 degrees C for F1ATPase and SMP, respectively. These anesthetic concentrations also give appreciable inhibition of enzyme activity at 25 degrees C. We conclude that the local anesthetics induce conformational alterations in the F1ATPase-protein complex which result both in enzyme inhibition and in the lowering of the thermal denaturation transition temperature.     

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)     

Coupling factor F1 ATPase with defective beta subunit from a mutant of Escherichia coli

The defective coupling factor F1 ATPase from a mutant strain (KF11) of Escherichia coli was purified to a practically homogeneous form. The final specific activity of Mg2+-ATPase was 6-9 units/mg protein, which is about 10-15 times lower than that of F1 ATPase from the wild-type strain. The mutant F1 had a ratio of Ca2+-ATPase to Mg2+-ATPase of about 3.5, whereas the wild-type F1 had ratio of about 0.8. The mutant F1 was more unstable than wild-type F1: on storage at -80 degrees C for 2 weeks, about 80% of its activity (dependent on Ca2+ or Mg2+) was lost, whereas none of the activity of the wild-type F1 was lost. The following results indicate that the mutation is in the beta subunit. (i) High Mg2+-ATPase activity (about 20 units/mg protein) was reconstituted when the beta subunit from wild type F1 was added to dissociated mutant F1 and the mixture was dialyzed against buffer containing ATP and Mg2+. (ii) Low ATPase activity having the same ratio of Ca2+-ATPase to Mg2+-ATPase as the mutant F1 was reconstituted when a mixture of the beta subunit from the mutant F1 and the alpha and gamma subunits from wild-type F1 was dialyzed against the same buffer. (iii) Tryptic peptide analysis of the beta subunit of the mutant showed a difference in a single peptide compared with the wild-type strain.     

The effect of Mg2+ on mitochondrial F0.F1 ATPase and characteristics of the nucleotide binding sites

The interaction of Mg2+ with nucleotide-washed F0.F1 ATPase from pig heart was studied. Mg2+ had no effect on nucleotide-washed F0.F1 ATPase, but it competitively inhibited the hydrolytic activity of washed F0.F1 ATPase preincubated with ADP and slightly activated the hydrolytic activity of washed F0.F1 ATPase preincubated with ATP. In the last two cases, it revealed negative cooperativity. The effect of Mg2+ on F0.F1 ATPase is therefore closely related to the characteristics of the nucleotide binding sites on mitochondrial F0.F1 ATPase.