Changes in the adenine nucleotide content of beef-heart mitochondrial F1 ATPase during ATP synthesis in dimethyl sulfoxide.

Beef-heart mitochondrial F1 ATPase can be induced to synthesize ATP from ADP and inorganic phosphate in 30% Me2SO. We have analyzed the adenine nucleotide content of the F1 ATPase during the time-course of ATP synthesis, in the absence of added medium nucleotide, and in the absence and presence of 10 mM inorganic phosphate. The enzyme used in these investigations was either pretreated or not pretreated with ATP to produce F1 with a defined nucleotide content and catalytic or noncatalytic nucleotide-binding site occupancy. We show that the mechanism of ATP synthesis in Me2SO involves (i) an initial rapid loss of bound nucleotide(s), this process being strongly influenced by inorganic phosphate; (ii) a rebinding of lost nucleotide; and (iii) synthesis of ATP from bound ADP and inorganic phosphate.     

Reversible binding of Pi by beef heart mitochondrial adenosine triphosphatase.

Beef heart mitochondrial ATPase (F1) exhibited a single binding site for Pi. The interaction with Pi was reversible, partially dependent on the presence of divalent metal ions, and characterized by a dissociation constant at pH 7.5 of 80 micronM. A variety of substances known to influence oxidative phosphorylation or the activity of the soluble ATPase (F1) also influenced Pi binding by the enzyme. Thus aurovertin, an inhibitor of oxidative phosphorylation, which was bound tightly by F1 and inhibited ATPase activity, enhanced Pi binding via a 4-fold increase in the affinity of the enzyme for Pi (KD = 20 micronM) but did not alter binding stoichiometry. Anions such as SO4(2-), SO3(2-), chromate, and 2,4-dinitrophenolate, which stimulated ATPase activity of F1, also enhanced Pi binding. Inhibitors of ATPase activity such as nickel/bathophenanthroline and the protein ATPase inhibitor of Pullman and Monroy (Pullman, M. E., and Monroy, G. C. (1963) J. Biol. Chem. 238, 3762-3769) inhibited Pi binding. The adenine nucleotides ADP, ATP, and the ATP analog adenylyl imidodiphosphate as well as the Pi analog arsenate, also inhibited Pi binding. The observations suggest that the Pi binding site was located in or near an adenine nucleotide binding site on the molecule.     

Adenine nucleotide-binding sites on beef heart F1-ATPase. Conditions that affect occupancy of catalytic and noncatalytic sites

Beef heart mitochondrial F1 contains a total of six adenine nucleotide-binding sites including at least two different types of sites. Three "exchangeable" sites exchange rapidly during hydrolysis of MgATP, whereas three "nonexchangeable" sites do not (Cross, R. L. and Nalin, C. M. (1982) J. Biol. Chem. 257, 2874-2881). When F1 that has been stored as a suspension in (NH4)2SO4/ATP/EDTA/sucrose/Tris, pH 8.0, is pelleted, rinsed with (NH4)2SO4, dissolved, and desalted, it retains three bound adenine nucleotides. We find that two of these endogenous nucleotides are bound at nonexchangeable sites and one at an exchangeable site. The vacant nonexchangeable site is highly specific for adenine nucleotide and is rapidly filled by ADP upon addition of ADP or during ATP hydrolysis. ADP bound at this site can be removed by reprecipitating the enzyme with (NH4)2SO4. The single nucleotide retained by desalted F1 at an exchangeable site is displaced during hydrolysis of ATP, GTP, or ITP. The binding of PPi at two sites on the enzyme also promotes its dissociation. Neither procedure affects retention of nucleotide at the nonexchangeable sites. These observations, combined with the finding that PPi is much more easily removed from exchangeable sites than ADP, have led to the development of a procedure for preparing F1 with uniform and well-defined nucleotide site occupancy. This involves sequential exposure to MgATP, PPi, and high concentrations of Pi. Unbound ligand is removed between each step. The resulting enzyme, F1[3,0], has three occupied nonexchangeable sites and three vacant exchangeable sites. Evidence that nonexchangeable and exchangeable sites represent noncatalytic and catalytic sites, respectively, suggest that this form of the enzyme will prove useful in numerous applications, including transient kinetic measurements and affinity labeling of active site residues.     

Interaction of beef-heart mitochondrial F1-ATPase with immobilized ATP in the presence of dimethylsulfoxide

Dimethylsulfoxide [Me₂SO, 30% (v/v)] promotes the formation of ATP from ADP and phosphate catalyzed by soluble mitochondrial F₁-ATPase. The effects of this solvent on the interaction of beef-heart mitochondrial F₁ with the immobilized ATP of Agarose-hexane-ATP were studied. In the presence of Me₂SO, F₁ bound less readily to the immobilized ATP, but once bound was more difficult to elute with exogenous ATP. This suggests that not only was the binding affinity for adenine nucleotide at the first binding site affected but that adenine nucleotide binding affinity at the second and/or third sites, which interact cooperatively with the first site to release bound nucleotide, was also affected. A reduction in the binding of [³H]ADP to these sites was shown. A change in the conformation of F₁ in 30% (v/v) Me₂SO was demonstrated by crosslinking and by the increased resistance of the enzyme to cold denaturation.     

Removal of "tightly bound" nucleotides from soluble mitochondrial adenosine triphosphatase (F1).

Soluble mitochondrial ATPase (F1) from beef heart prepared in this laboratory contained approximately 1.8 mol of ADP and 0 mol of ATP/mol of F1 which were not removed by repeated precipitation of the enzyme with ammonium sulfate solution or by gel filtration in low ionic strength buffer containing EDTA. This enzyme had full coupling activity. Treatment of the enzyme with trypsin (5 mug/mg of F1 for 3 min) reduced the "tightly bound" ADP to zero, abolished coupling activity, but had no effect on the ATPase activity, stability, or membrane-binding capability of the F1. When the trypsin concentration was varied between 0 and 5 mug/mg of F1, tightly bound ADP was removed to varying degrees, and a correlation was seen between amount of residual tightly bound ADP and residual coupling activity. Gel filtration of the native F1 in high ionic strength buffer containing EDTA also caused complete loss of tightly bound ADP and coupling ability, whereas ATPase activity, stability, and membrane-binding capability were retained. The ADP-depleted F1 preparations were unable to rebind normal amounts of ADP or any ATP in simple reloading experiments. The results strongly suggest that tightly bound ADP is required for ATP synthesis and for energy-coupled ATP hydrolysis on F1. The results also suggest that ATP synthesis and energy-linked ATP hydrolysis rather than involving one nucleotide binding site on F1, involve a series or "cluster" of sites. The ATP hydrolysis site may represent one component of this cluster. The results show that nonenergy-coupled ATP hydrolysis on F1 can occur in the absence of tightly bound ADP or ATP.     

Binding of adenine nucleotides to the F1-inhibitor protein complex of bovine heart submitochondrial particles.

The binding of ATP radiolabeled in the adenine ring or in the gamma- or alpha-phosphate to F1-ATPase in complex with the endogenous inhibitor protein was measured in bovine heart submitochondrial particles by filtration in Sephadex centrifuge columns or by Millipore filtration techniques. These particles had 0.44 +/- 0.05 nmol of F1 mg-1 as determined by the method of Ferguson et al. [(1976) Biochem. J. 153, 347]. By incubation of the particles with 50 microM ATP, and low magnesium concentrations (less than 0.1 microM MgATP), it was possible to observe that 3.5 mol of [gamma-32P]ATP was tightly bound per mole of F1 before the completion of one catalytic cycle. With [gamma-32P]ITP, only one tight binding site was detected. Half-maximal binding of adenine nucleotides took place with about 10 microM. All the bound radioactive nucleotides were released from the enzyme after a chase with cold ATP or ADP; 1.5 sites exchanged with a rate constant of 2.8 s-1 and 2 with a rate constant of 0.45 s-1. Only one of the tightly bound adenine nucleotides was released by 1 mM ITP; the rate constant was 3.2 s-1. It was also observed that two of the bound [gamma-32P]ATP were slowly hydrolyzed after removal of medium ATP; when the same experiment was repeated with [alpha-32P]ATP, all the label remained bound to F1, suggesting that ADP remained bound after completion of ATP hydrolysis. Particles in which the natural ATPase inhibitor protein had been released bound tightly only one adenine nucleotide per enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of homogeneous mitochondrial ATPase from rat liver with adenine nucleotides and inorganic phosphate

Mitochondrial ATPase from rat liver mitochondria contains multiple nucleotide binding sites. At low concentrations ADP binds with high affinity (1 mole/mole ATPase, K_D = 1–2 μM). At high concentrations, ADP inhibits ATP hydrolysis presumably by competing with ATP for the active site (K_I = 240–300 μM). As isolated, mitochondrial ATPase contains between 0.6 and 2.5 moles ATP/mole ATPase. This “tightly bound” ATP can be removed by repeated precipitations with ammonium sulfate without altering hydrolytic activity of the enzyme. However, the ATP-depleted enzyme must be redissolved in high concentrations of phosphate to retain activity. AMP-PNP (adenylyl imidodiphosphate) replaces tightly bound ATP removed from the enzyme and inhibits ATP hydrolysis. AMP-PNP has little effect on high affinity binding of ADP. Kinetic studies of ATP hydrolysis reveal hyperbolic velocity vs. ATP plots, provided assays are done in bicarbonate buffer or buffers containing high concentrations of phosphate. Taken together, these studies indicate that sites on the enzyme not directly associated with ATP hydrolysis bind ATP or ADP, and that in the absence of bound nucleotide, P_i can maintain the active form of the enzyme.     

Escherichia coli F1-ATPase can use GTP-nonchaseable bound adenine nucleotide to synthesize ATP in dimethyl sulfoxide.

Escherichia coli F1-ATPase contained 3 mol of tightly-bound adenine nucleotide/mol enzyme. A further 3 mol could be loaded by incubation of the enzyme with ATP. The unloaded enzyme was designated as a F1[2,1] type on the basis of the ability of GTP to displace 1 mol of adenine nucleotide/mol of F1 [Kironde, F.A.S., & Cross, R.L. (1986) J. Biol. Chem. 261, 12544-12549]. The loaded enzyme was designated F1[3,3] since GTP could displace 3 of the 6 mol of bound adenine nucleotide/mol of F1. Incubation of F1[2,1], F1[2,0], and F1[3,0] with phosphate in the presence of 30% (v/v) dimethyl sulfoxide led to the synthesis of ATP from endogenous bound ADP. Hydrolysis of newly synthesized ATP occurred on transfer of the F1 from 30% (v/v) dimethyl sulfoxide to an entirely aqueous medium. Thus, synthesis and hydrolysis of ATP can occur at GTP-nonchaseable adenine nucleotide binding sites, and these sites in dimethyl sulfoxide are not necessarily equivalent to noncatalytic sites.     

Nucleotide-binding properties of native and cold-treated mitochondrial ATPase.

1. The bound nucleotides of the beef-heart mitochondrial ATPase (F1) are lost during cold inactivation followed by (NH4)2SO4 precipitation. The release of tightly bound ATP parallels the loss of ATPase activity during this process. 2. During cold inactivation, the sedimentation coefficient (s20, w) of the ATPase first declines from 12.1 S to 9 S, then to 3.5 S. (NH4)2SO4 precipitation of the 9-S component also leads to dissociation into subunits with s20, w of 3.5 S. 3. The 9-S component still contains the bound nucleotides, which are removed when it dissociated into smaller subunits. 4. Reactivation of cold-inactivated ATPase by incubation at 30 degrees C is increased by the presence of 25% glycerol. ATP, however, does not have any clearcut effect on the degree of reactivation in the presence of glycerol. 5. ADP is an inhibitor of the reactivation, probably because it exchanges during reactivation for bound ATP giving rise to an inactive 12-S component. 6. The exchange of tightly bound nucleotides with added adenine nucleotides is more extensive and faster with cold-inactivated ATPase than with the native enzyme. During reactivation up to 1.6 moles of ATP and 1.0 mole ADP can exchange per mole enzyme. 7. Incubation with GTP, CTP or inorganic pyrophosphate induces an increased activity of the ATPase, which, however, soon declines in the presence of ATP. It also disappears on precipitation of GTP-treated enzyme with (NH4)2SO4.     

Specificity of nucleotide binding and coupled reactions utilising the mitochondrial ATPase.

1. Tightly bound ATP and ADP, found on the isolated mitochondrial ATPase, exchange only slowly at pH 8, but the exchange is increased as the pH is reduced. At pH 5.5, more than 60% of the bound nucleotide exchanges within 2.5 min. 2. Preincubation of the isolated ATPase with ADP leads to about 50% inhibition of ATP hydrolysis when the enzyme is subsequently assayed in the absence of free ADP. This effect, which is reversed by preincubation with ATP, is absent on the membrane-bound ATPase. This inhibition seems to involve the replacement of tightly bound ATP by ADP. 3. Using these two findings, the binding specificity of the tight nucleotide binding sites was determined. iso-Guanosine, 2'-deoxyadenosine and formycin nucleotides displaced ATP from the tight binding sites, while all other nucleotides tested did not. The specificities of the tight sites of the isolated and membrane-bound ATPase were similar, and higher than that of the hydrolytic site. 4. The nucleotide specificities of 'coupled processes' nucleoside triphosphate-driven reversal of electron transfer, nucleoside triphosphate-32Pi exchange and phosphorylation were higher than that of the hydrolytic site of the ATPase and similar to that of the tight nucleotide binding sites.     

Bound adenosine 5'-triphosphate formation, bound adenosine 5'-diphosphate and inorganic phosphate retention, and inorganic phosphate oxygen exchange by chloroplast adenosinetriphosphatase in the presence of Ca2+ or Mg2+

When the heat-activated chloroplast F1 ATPase hydrolyzes [3H, gamma-32P]ATP, followed by the removal of medium ATP, ADP, and Pi, the enzyme has labeled ATP, ADP, and Pi bound to it in about equal amounts. The total of the bound [3H]ADP and [3H]ATP approaches 1 mol/mol of enzyme. Over a 30-min period, most of the bound [32P]Pi falls off, and the bound [3H]ATP is converted to bound [3H]ADP. Enzyme with such remaining tightly bound ADP will form bound ATP from relatively high concentrations of medium Pi with either Mg2+ or Ca2+ present. The tightly bound ADP is thus at a site that retains a catalytic capacity for slow single-site ATP hydrolysis (or synthesis) and is likely the site that participates in cooperative rapid net ATP hydrolysis. During hydrolysis of 50 microM [3H]ATP in the presence of either Mg2+ or Ca2+, the enzyme has a steady-state level of about one bound [3H]ADP per mole of enzyme. Because bound [3H]ATP is also present, the [3H]ADP is regarded as being present on two cooperating catalytic sites. The formation and levels of bound ATP, ADP, and Pi show that reversal of bound ATP hydrolysis can occur with either Ca2+ or Mg2+ present. They do not reveal why no phosphate oxygen exchange accompanies cleavage of low ATP concentrations with Ca2+ in contrast to Mg2+ with the heat-activated enzyme. Phosphate oxygen exchange does occur with either Mg2+ or Ca2+ present when low ATP concentrations are hydrolyzed with the octyl glucoside activated ATPase. Ligand binding properties of Ca2+ at the catalytic site rather than lack of reversible cleavage of bound ATP may underlie lack of oxygen exchange under some conditions.     

The effects of octylglucoside on the interactions of chloroplast coupling factor 1 (CF1) with adenine nucleotides

The effects of octylglucoside (OcGlc) micelles, which stimulate a Mg-specific ATPase activity in chloroplast coupling factor 1 [Pick, U. and Bassilian, S. (1982) Biochemistry, 21, 6144-6152], on the interactions of the enzyme with adenine nucleotides have been studied. 1. OcGlc specifically accelerates the binding and the release of ADP but not of ATP or adenosine 5'[beta, gamma-imido]triphosphate (AdoPP[NH]P) from the tight-sites. The binding affinity for ADP and for ATP is only slightly decreased (twofold) by the detergent. ATP competitively inhibits the binding of ADP and vice versa in the presence or absence of OcGlc. 2.OcGlc-induced inactivation of CF1-ATPase is correlated with the release of bound nucleotides. In the absence of medium nucleotides ADP X CF1 is rapidly inactivated while ATP X CF1 and AdoPP[NH]P X CF1 are slowly inactivated by OcGlc in parallel with the release of bound nucleotide. In contrast, low concentrations of either ATP or ADP in the medium effectively protect against OcGlc inactivation while AdoPP[NH]P, whose binding to CF1 is inhibited by OcGlc, is ineffective even at millimolar concentrations. The results suggest that the occupancy of the tight-sites protects the enzyme against OcGlc-induced inactivation. 3. Mg ions specifically inhibit the release of bound ADP and the OcGlc-induced inactivation of CF1. High concentrations of medium ATP and ADP (K50 = 100 microM) also inhibit the OcGlc-induced release of bound nucleotides in an EDTA medium. In contrast, in the absence of OcGlc, medium ADP and ATP accelerate the release of bound adenine nucleotides. 4. Mg-ATP in the presence of OcGlc stimulates the release of bound ADP from CF1. Bound ATP is neither released nor hydrolyzed at the tight-sites under these conditions where medium ATP is rapidly hydrolyzed. Mg-ADP stimulates the release of bound ADP only in the presence of inorganic phosphate or of phosphate analogs, e.g. arsenate, pyrophosphate or selenate. 5. It is suggested that: (a) ATP and ADP bind to the same tight-sites, but OcGlc activation specifically accelerates the exchange of bound ADP at the site. (b) CF1 contains low affinity adenine nucleotide binding sites which may be the catalytical sites and which influence the tight-sites by cooperative interactions. (c) Mg-ATP in the presence of OcGlc induces a conformational change at the catalytical site which accelerates the release of ADP from the tight-site. The implications of these results to the role of adenine nucleotides in the regulation and mechanism of ATP hydrolysis by CF1 are discussed.     

Effect of the natural ATPase inhibitor on the binding of adenine nucleotides and inorganic phosphate to mitochondrial F1-ATPase

(1) Incubation of the beef heart mitochondrial ATPase, F1 with Mg-ATP was required for the binding of the natural inhibitor, IF1, to F1 to form the inactive F1-IF1 complex. When F1 was incubated in the presence of [14C]ATP and MgCl2, about 2 mol 14C-labeled adenine nucleotides were found to bind per mol of F1; the bound 14C-labeled nucleotides consisted of [14C]ADP arising from [14C]ATP hydrolysis and [14C]ATP. The 14C- labeled nucleotide binding was not prevented by IF1. These data are in agreement with the idea that the formation of the F1-IF1 complex requires an appropriate conformation of F1. (2) The 14C-labeled adenine nucleotides bound to F1 following preincubation of F1 with Mg-[14C] ATP could be exchanged with added [3H]ADP or [3H]ATP. No exchange occurred between added [3H]ADP or [3H]ATP and the 14 C-labeled adenine nucleotides bound to the F1-IF1 complex. These data suggest that the conformation of F1 in the isolated F1-IF1 complex is further modified in such a way that the bound 14C-labeled nucleotides are no longer available for exchange. (3) 32Pi was able to bind to isolated F1 with a stoichiometry of about 1 mol of Pi per mol of F1 (Penefsky, H.S. (1977) J. Biol. Chem. 252, 2891-2899). There was no binding of 32Pi to the F1-IF1 complex. Thus, not only the nucleotides sites, but also the Pi site, are masked from interaction with external ligands in the isolated F1-IF1 complex.     

Specificity of the proton adenosinetriphosphatase of Escherichia coli for adenine, guanine, and inosine nucleotides in catalysis and binding

Specificity of the Escherichia coli proton ATPase for adenine, guanine, and inosine nucleotides in catalysis and binding was studied. MgADP, CaADP, MgGDP, and MgIDP were each good substrates for oxidative phosphorylation. The corresponding triphosphates were each substrates for hydrolysis and proton pumping. At 1 mM concentration, MgATP, MgGTP, and MgITP drove proton pumping with equal efficiency. At 0.1 mM concentration, MgATP was 4-fold more efficient than MgITP or MgGTP. Nucleotide-depleted soluble F1 could rebind to F1-depleted membranes and block proton conductivity through F0; rebound nucleotide-depleted F1 catalyzed pH gradient formation with MgATP, MgGTP, or MgITP. This showed that the nonexchangeable nucleotide sites on F1 need not be occupied by adenine nucleotide for proton pumping to occur. It was further shown that no nucleotide was tightly bound in the nonexchangeable sites of F1 during proton pumping driven by MgGTP in these reconstituted membranes, whereas adenine nucleotide was tightly bound when MgATP was the substrate. Nucleotide-depleted soluble F1 bound maximally 5.9 ATP, 3.2 GTP, and 3.6 ITP of which half the ATP and almost all of the GTP and ITP exchanged over a period of 30-240 min with medium ADP or ATP. Also, half of the bound ATP exchanged with medium GTP or ITP. These data showed that inosine and guanine nucleotides do not bind to soluble F1 in nonexchangeable fashion, in contrast to adenine nucleotides. Purified alpha-subunit from F1 bound ATP at a single site but showed no binding of GTP nor ITP, supporting previous suggestions that the non-exchangeable sites in intact F1 are on alpha-subunits.     

The non-catalytic nucleotide-binding site of mitochondrial ATPase is localised on the alpha-subunit(s) of factor F1

The incubation of isolated factor F1 with the di-aldehyde derivative of ADP (oxADP) which is formed as a result of ADP treatment by periodate, causes the covalent binding of 0.9--1 molecules of the oxADP with a molecule of the enzyme. This modification of factor F1 is not accompanied by any changes in the ATPase activity of the enzyme. The modification of factor F1 is preceded by the reversible binding of oxADP with the enzyme with a Kd of 80 micro M. ADP partly prevents factor F1 from modification by oxADP. The electrophoresis of modified factor F1 in polyacrylamide gel in the presence of sodium dodecyl sulphate showed that oxADP binds with the alpha-subunit(s) of factor F1. When submitochondrial particles are incubated with [3H]oxADP, the main part of the radioactive label may be discovered in the polypeptide with a molecular weight of some 30 000 which is probably the adenine nucleotides' translocase. The isolation of factor F1 from particles preincubated with [3H]oxADP showed that the membrane-bound factor F1 covalently binds 0.2--0.3 mol of oxADP per mol of enzyme. Here again, all the oxADP is bound with the alpha subunit(s) of factor F1. The modification of membrane-bound factor F1 by oxADP is accompanied by the partial inhibition of the particles' ATPase activity. The results obtained testify to the fact that the non-catalytic site of mitochondrial ATP ase located on the alpha-subunit(s) of factor F1 may participate in the mechanism of ATP hydrolysis by membrane-bound ATPase.     

Adenine nucleotide binding sites in normal and mutant adenosine triphosphatases of Escherichia coli

Three types of assays were used to characterize adenine nucleotide binding sites on the Ca²⁺, Mg²⁺-activated ATPase of normal Escherichia coli and its unc A 401 and unc D 412 mutants. ADP was bound mainly at a single site in normal and mutant ATPase. In the absence of divalent cations ATP was bound at a single high-affinity and three low-affinity sites in normal and unc D ATPases. The 2′,3′-dialdehyde (oADP) obtained by periodate oxidation of ADP reacted with both low- and high-affinity sites whereas oATP was bound primarily at a low-affinity site. Two types of adenine nucleotide binding sites, a high-affinity site reacting with ATP and ADP and a low-affinity site for ATP, were detected by the effects of these nucleotides on the fluorescence of the aurovertin D-ATPase complex. This high-affinity site(s) was present in normal and mutant ATPases. However, the fluorescence response at both high- and low-affinity sites was modified in the unc D ATPase as a consequence of the abnormal β subunit in this enzyme. Normal fluorescence responses were not induced by the binding of oADP or oATP to the ATPases. ATP was bound at a single site on isolated α subunits of the enzyme. Since this site was not detected in the unc A ATPase, it is unlikely to be the high-affinity site detected in the intact enzyme or the binding site for the endogenous tightly bound adenine nucleotides found in the purified ATPase. It is more probable that the site detected on the isolated α subunit from the normal enzyme is that which binds oADP since this site was absent in the unc A ATPase. Pretreatment of the normal ATPase with either N, N′-dicyclohexyl-carbodiimide (DCCD) or with 4-chloro-7-nitrobenzofurazan (NbfCl), reagents which inhibit ATPase activity by reacting with a β subunit, affected binding of oADP to α subunit(s) but had less effect with oATP. Inhibition of oADP binding could be due to conformational changes induced in the α subunit by the reaction of DCCD and NbfCl with a β subunit, or to steric reasons. If the latter hypothesis is correct, the active site of the ATPase would be at the interface between α and β subunits of the enzyme.     

Inhibition of steady-state mitochondrial ATP synthesis by bicarbonate, an activating anion of ATP hydrolysis.

Bicarbonate, an activating anion of ATP hydrolysis, inhibited ATP synthesis coupled to succinate oxidation in beef heart submitochondrial particles but diminished the lag time and increased the steady-state velocity of the (32)Pi-ATP exchange reaction. The latter effects exclude the possibility that bicarbonate is inducing an intrinsic uncoupling between ATP hydrolysis and proton translocation at the level of F(1)F(o) ATPase. The inhibition of ATP synthesis was competitive with respect to ADP at low fixed [Pi], mixed at high [Pi] and non-competitive towards Pi at any fixed [ADP]. From these results we can conclude that (i) bicarbonate does not bind to a Pi site in the mitochondrial F(1); (ii) it competes with the binding of ADP to a low-affinity site, likely the low-affinity non-catalytic nucleotide binding site. It is postulated that bicarbonate stimulates ATP hydrolysis and inhibits ATP synthesis by modulating the relative affinities of the catalytic site for ATP and ADP.     

Interaction of ox heart mitochondrial F1-ATPase with immobilized ADP and ATP.

The reaction of mitochondrial F1-ATPase with immobilized substrate was studied by using columns of agarose-hexane-ATP. Mg2+ was required for binding of the enzyme to the column matrix. The column-bound enzyme could be eluted fully by ATP and other nucleoside triphosphates. Nucleoside di- and mono-phosphates were less effective. At a fixed concentration of nucleotide the effectiveness of elution was proportional to the charge on the eluting molecule. The ATP of the column matrix was hydrolysed by the bound F1-ATPase to release phosphate, probably by a uni-site reaction mechanism. Thus the F1-ATPase was bound to the immobilized ATP by a catalytic site. Treatment of the bound F1-ATPase with 4-chloro-7-nitrobenzofurazan prevented complete release of the enzyme by ATP. Only one-third of the bound enzyme was now eluted by the nucleotide. The inhibition of release could be due either to the inhibitor blocking co-operative interactions between sites or to its increasing the tightness of binding of immobilized ADP at the catalytic site.     

Adenine nucleotides as allosteric effectors of pea seed glutamine synthetase

The effects of adenine nucleotides on pea seed glutamine synthetase (EC 6.3.1.2) activity were examined as a part of our investigation of the regulation of this octameric plant enzyme. Saturation curves for glutamine synthetase activity versus ATP with ADP as the changing fixed inhibitor were not hyperbolic; greater apparent Vmax values were observed in the presence of added ADP than the Vmax observed in the absence of ADP. Hill plots of data with ADP present curved upward and crossed the plot with no added ADP. The stoichiometry of adenine nucleotide binding to glutamine synthetase was examined. Two molecules of [gamma-32P]ATP were bound per subunit in the presence of methionine sulfoximine. These ATP molecules were bound at an allosteric site and at the active site. One molecule of either [gamma-32P]ATP or [14C]ADP bound per subunit in the absence of methionine sulfoximine; this nucleotide was bound at an allosteric site. ADP and ATP compete for binding at the allosteric site, although ADP was preferred. ADP binding to the allosteric site proceeded in two kinetic phases. A Vmax value of 1.55 units/mg was measured for glutamine synthetase with one ADP tightly bound per enzyme subunit; a Vmax value of 0.8 unit/mg was measured for enzyme with no adenine nucleotide bound at the allosteric site. The enzyme activation caused by the binding of ADP to the allosteric sites was preceded by a lag phase, the length of which was dependent on the ADP concentration. Enzyme incubated in 10 mM ADP bound approximately 4 mol of ADP/mol of native enzyme before activation was observed; the activation was complete when 7-8 mol of ADP were bound per mol of the octameric, native enzyme. The Km for ATP (2 mM) was not changed by ADP binding to the allosteric sites. ADP was a simple competitive inhibitor (Ki = 0.05 mM) of ATP for glutamine synthetase with eight molecules of ADP tightly bound to the allosteric sites of the octamer. Binding of ATP to the allosteric sites led to marked inhibition.     

The characteristics and effect on catalysis of nucleotide binding to noncatalytic sites of chloroplast F1-ATPase.

The recent finding that the presence of ATP at non-catalytic sites of chloroplast F1-ATPase (CF1) is necessary for ATPase activity (Milgrom, Y. M., Ehler, L. L., and Boyer, P. D. (1990) J. Biol. Chem. 265,18725-18728) prompted more detailed studies of the effect of noncatalytic site nucleotides on catalysis. CF1 containing at noncatalytic sites less than one ADP or about two ATP was prepared by heat activation in the absence of Mg2+ and in the presence of ADP or ATP, respectively. After removal of medium nucleotides, the CF1 preparations were used for measurement of the time course of nucleotide binding from 10 to 100 microM concentrations of 3H-labeled ADP, ATP, or GTP. The presence of Mg2+ strongly promotes the tight binding of ADP and ATP at noncatalytic sites. For example, the ADP-heat-activated enzyme in presence of 1 mM Mg2+ binds ADP with a rate constant of 0.5 x 10(6) M-1 min-1 to give an enzyme with two ADP at noncatalytic sites with a Kd of about 0.1 microM. Upon exposure to Mg2+ and ATP the vacant noncatalytic site binds an ATP rapidly and, as an ADP slowly dissociates, a second ATP binds. The binding correlates with an increase in the ATPase activity. In contrast the tight binding of [3H]GTP to noncatalytic sites gives an enzyme with no ATPase activity. The three noncatalytic sites differ in their binding properties. The noncatalytic site that remains vacant after the ADP-heat-activated CF1 is exposed to Mg2+ and ADP and that can bind ATP rapidly is designated as site A; the site that fills with ATP as ADP dissociates when this enzyme is exposed to Mg2+ and ATP is called site B, and the site to which ADP remains bound is called site C. Procedures are given for attaining CF1 with ADP at sites B and C, with GTP at sites A and/or B, and with ATP at sites A, B, and/or C, and catalytic activities of such preparations are measured. For example, little or no ATPase activity is found unless ATP is at site A, but ADP can remain at site C with no effect on ATPase. Maximal GTPase activity requires ATP at site A but about one-fifth of maximal GTPase is attained when GTP is at sites A and B and ATP at site C. Noncatalytic site occupancy can thus have profound effects on the ATPase and GTPase activities of CF1.