Uni-site catalysis by Escherichia coli F1-ATPase with different numbers of bound nucleotides

We prepared two types of E. coli F1 by slightly different gel filtration procedures of the purified F1: F1(II) contained about 2 mol, and F1(V) about 5 mol of bound adenine nucleotides per mol of the enzyme. Thus F1(II) had more than 2, possibly 3, vacant catalytic sites, while F1(V) had less than one vacant catalytic site. The rate of ATP hydrolysis in uni-site catalysis (in the presence of inorganic phosphate) was about 3-fold higher with F1(II) than with F1(V), suggesting that ADP and inorganic phosphate bound at the catalytic sites of F1(V) changed the kinetics of uni-site catalysis significantly.     

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.     

Loss of unisite and multisite catalyses by Escherichia coli F1 through modification with adenosine tri- or tetraphosphopyridoxal

Pyridoxal phosphate (PLP) and adenosine diphospho (AP2-PL)-, triphospho (AP3-PL)-, and tetraphospho (AP4-PL)-pyridoxals (Tagaya, M., and Fukui, T. (1986) Biochemistry 25, 2958-2964) were tested as potential affinity probes for F1 ATPase of Escherichia coli. Both AP3-PL and AP4-PL bound and inhibited F1 ATPase, whereas PLP and AP2-PL were weak inhibitors. The concentrations of AP3-PL and AP4-PL for half-maximal inactivations of the multisite (steady state) ATPase activity were both 18 microM. The binding of these reagents to a reactive lysyl residue(s) was confirmed from the difference absorption spectra, and the stoichiometry of binding of [3H]AP3-PL to F1 at the saturating level was about 1 mol/mol F1. The analogue bound to both the alpha subunit (about two-thirds of the radioactivity) and the beta subunit (about one-third of the radioactivity). No inactivation of multisite ATPase activity or binding of AP3-PL was observed in the presence of ATP. F1 modified with about one mol of AP3-PL had essentially no uni- and multisite hydrolysis of ATP. The rate of binding of ATP decreased to 10(-2) of that of unmodified F1, and the rate of release of ATP was about two times faster. The equilibrium F1 X ATP in equilibrium F1 X ADP X Pi was shifted toward F1 X ATP, and no promotion of ATP hydrolysis at unisite was observed with excess ATP. These results suggest that the AP3-PL or AP4-PL bound to an active site, and catalysis by the two remaining sites was completely abolished.     

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.     

Tightly bound nucleotides affect phosphate binding to mitochondrial F1-ATPase

The interaction of inorganic phosphate with native and nucleotide-depleted F1-ATPase was studied. F1-ATPase depleted of tightly bound nucleotides loses the ability to bind inorganic phosphate. The addition of ATP, ADP, GTP and GDP but not AMP, restores the phosphate binding. The nucleotides affecting the phosphate binding to F1-ATPase are located at the catalytic (exchangeable) site of the enzyme. The phosphate is thought to bind to the same catalytic site where the nucleotide is already bound. It is thought that ADP is the first substrate to bind to F1-ATPase in the ATP synthesis reaction.     

Significant quantities of endogenous GDP and ADP are present on catalytic sites of the F1-ATPase isolated from M. lysodeikticus in the absence of added nucleotides.

The F1-ATPase from Micrococcus lysodeikticus is isolated in the absence of exogenous nucleotides. After removing loosely bound nucleotides from the isolated enzyme by gel permeation chromatography, analysis for tightly bound nucleotides revealed in 14 experiments 0.4 +/- 0.1 mol ADP, 0.5 +/- 0.2 mol GDP, and 0.8 +/- 0.2 mol ATP per mol of F1. Incubation of the isolated enzyme with Mg2+ or Ca2+ did not alter the endogenous nucleotide composition of the enzyme, indicating that endogenous ATP is not bound to a catalytic site. Incubation of the enzyme with P(i) decreased the amount of tightly bound ADP and GDP but did not effect the ATP content. Hydrolysis of MgATP in the presence of sulfite raised the tightly bound ADP and lowered tightly bound GDP on the enzyme. In the reciprocal experiment, hydrolysis of MgGTP in the presence of sulfite raised tightly bound GDP and lowered tightly bound ADP. Turnover did not affect the content of tightly bound ATP on the enzyme. These results suggest that endogenous ADP and GDP are bound to exchangeable catalytic sites, whereas endogenous ATP is bound to noncatalytic sites which do not exchange. The presence of endogenous GDP on catalytic sites of isolated F1 suggests that the F0F1-ATP synthase of M. lysodeikticus might synthesize both GTP and ATP under physiological conditions. In support of this hypothesis, we have found that plasma membrane vesicles derived from M. lysodeikticus synthesize [32P]GTP from [32P]P(i) using malate as electron donor for oxidative phosphorylation.     

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.     

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.     

The effect of dimethylsulfoxide on adenine nucleotide binding and ATP synthesis by beef-heart mitochondrial F1 ATPase.

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 adenine nucleotide binding properties of beef-heart mitochondrial F1 ATPase were examined. The ATP analog adenylyl-5'-imidodiphosphate bound to F1 at 1.9 and 1.0 sites in aqueous and Me2SO systems, respectively, with a KD value of 2.2 microM. Lower affinity sites were present also. Binding of ATP or adenylyl-5'-imidodiphosphate at levels near equimolar with the enzyme occurred to a greater extent in the absence of Me2SO. Addition of ATP to the nucleotide-loaded enzyme resulted in exchange of about one-half of the bound ATP. This occurred only in an entirely aqueous medium. ATP bound in Me2SO medium was not released by exogenous ATP. Comparison of the effect of different concentrations of Me2SO on ADP binding to F1 and ATP synthesis by the enzyme showed that binding of ADP was diminished by concentrations of Me2SO lower than those required to support ATP synthesis. However, one site could still be filled by ADP at concentrations of Me2SO optimal for ATP synthesis. This site is probably a noncatalytic site, since the nucleotide bound there was not converted to ATP in 30% Me2SO. The ATP synthesized by F1 in Me2SO originated from endogenous bound ADP. We conclude that 30% Me2SO affects the adenine nucleotide binding properties of the enzyme. The role of this in the promotion of the formation of ATP from ADP and phosphate is discussed.     

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.     

Interaction between aurovertin and adenine nucleotide binding sites on mitochondrial F1-ATPase and the isolated beta subunit

The effect of aurovertin on the binding parameters of ADP and ATP to native F1 from beef heart mitochondria in the presence of EDTA has been explored. Three exchangeable sites per F1 were titrated by ADP and ATP in the absence or presence of aurovertin. Curvilinear Scatchard plots for the binding of both ADP and ATP were obtained in the absence of aurovertin, indicating one high affinity site (Kd for ADP = 0.6-0.8 microM; Kd for ATP = 0.3-0.5 microM) and two lower affinity sites (Kd for ADP = 8-10 microM; Kd for ATP = 7-10 microM). With a saturating concentration of aurovertin capable of filling the three beta subunits of F1, the curvilinearity of the Scatchard plots was decreased for ATP binding and abolished for ADP binding, indicating homogeneity of ADP binding sites in the F1-aurovertin complex (Kd for ADP = 2 microM). When only the high affinity aurovertin site was occupied, maximal enhancement of the fluorescence of the F1-aurovertin complex was attained with 1 mol of ADP bound per mol of F1 and maximal quenching for 1 mol of ATP bound per mol of F1. When the F1-aurovertin complex was incubated with [3H]ADP followed by [14C]ATP, full fluorescence quenching was attained when ATP had displaced the previously bound ADP. In the case of the isolated beta subunit, both ADP and ATP enhanced the fluorescence of the beta subunit-aurovertin complex. The Kd values for ADP and ATP in the presence of EDTA were 0.6 mM and 3.7 mM, respectively; MgCl2 decreased the Kd values to 0.1 mM for both ADP and ATP. It is postulated that native F1 possesses three equivalent interacting nucleotide binding sites and exists in two conformations which are in equilibrium and recognize either ATP (T conformation) or ADP (D conformation). The negative interactions between the nucleotide binding sites of F1 are strongest in the D conformation. Upon addition of aurovertin, the site-site cooperativity between the beta subunits of F1 is decreased or even abolished.     

Fate of nucleotides bound to reconstituted Fo-F1 during adenosine 5'-triphosphate synthesis activation or hydrolysis: role of protein inhibitor and hysteretic inhibition

The protein ATPase inhibitor entraps about five nucleotides in pig heart mitochondrial F1, one at least being a triphosphate [Di Pietro, A., Penin, F., Julliard, J.H., Godinot, C., & Gautheron, D.C. (1988) Biochem. Biophys. Res. Commun. 152, 1319-1325]. The fate of these nucleotides was studied during ATP synthesis driven by NADH oxidation in reconstituted inverted submitochondrial particles. Iodinated F1, containing 0.7 mol of endogenous nucleotides/mol, was first loaded with tritiated adenine nucleotides in the presence or absence of the protein inhibitor and then reassociated with F1-depleted submitochondrial particles (ASU particles) to reconstitute an efficient NADH-driven ATP synthesis. In the absence of the protein inhibitor, 1.7 mol of labeled nucleotides remained bound per mole of reassociated F1, 0.8-0.9 mol being rapidly exchangeable against medium ADP or ATP, as measured after rapid filtration through nitrocellulose filters. In the presence of the protein inhibitor, as many as 3.25 mol of labeled nucleotides remained bound per mole of reassociated F1. Under hydrolysis conditions where ATPase activity was highly inhibited, no release of tritiated nucleotide occurred. In contrast, under ATP synthesis conditions where the protonmotive force was generated by NADH oxidation, the progressive reversal of inhibition by the protein inhibitor was correlated to a concomitant release of tritiated nucleotide. When ATP synthesis became fully active, about one nucleotide was completely exchanged whereas more than three nucleotides remained tightly bound and did not appear to be directly involved in ATP synthesis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Heterogeneous hydrolysis of substoichiometric ATP by the F1-ATPase from Escherichia coli.

The hydrolysis of 0.3 microM [alpha,gamma-32P]ATP by 1 microM F1-ATPase isolated from the plasma membranes of Escherichia coli has been examined in the presence and absence of inorganic phosphate. The rate of binding of substoichiometric substrate to the ATPase is attenuated by 2 mM phosphate and further attenuated by 50 mM phosphate. Under all conditions examined, only 10-20% of the [alpha,gamma-32P]ATP that bound to the enzyme was hydrolyzed sufficiently slowly to be examined in cold chase experiments with physiological concentrations of non-radioactive ATP. These features differ from those observed with the mitochondrial F1-ATPase. The amount of bound substrate in equilibrium with bound products observed in the slow phase which was subject to promoted hydrolysis by excess ATP was not affected by the presence of phosphate. Comparison of the fluxes of enzyme-bound species detected experimentally in the presence of 2 mM phosphate with those predicted by computer simulation of published rate constants determined for uni-site catalysis (Al-Shawi, M.D., Parsonage, D. and Senior, A.E. (1989) J. Biol. Chem. 264, 15376-15383) showed that hydrolysis of substoichiometric ATP observed experimentally was clearly biphasic. Less than 20% of the substoichiometric ATP added to the enzyme was hydrolyzed according to the published rate constants which were calculated from the slow phase of product release in the presence of 1 mM phosphate. The majority of the substoichiometric ATP added to the enzyme was hydrolyzed with product release that was too rapid to be detected by the methods employed in this study, indicating again that the F1-ATPase from E. coli and bovine heart mitochondria hydrolyze substoichiometric ATP differently.     

Investigation of the substrate structure and metal cofactor requirements of the rat liver mitochondrial ATP synthase/ATPase complex

The F1 moiety of the rat liver mitochondrial ATP synthase/ATPase complex contains as isolated 2 mol Mg2+/mol F1, 1 mol of which is nonexchangeable and the other which is exchangeable (N. Williams, J. Hullihen, and P.L. Pedersen, (1987) Biochemistry 26, 162-169). In addition, the enzyme binds 1 mol ADP/mol F1 and 3 mol AMP.PNP, the latter of which can bind in complex formation with divalent cation and displace the Mg2+ at the exchangeable site. Thus, in terms of ligand binding sites the fully loaded rat liver F1 complex contains 3 mol MgAMP.PNP, 1 mol ADP, and 1 mol Mg2+. In this study we have used several metal ATP complexes or analogs thereof to gain further insight into the ligand binding domains of rat liver F1 and the mechanism by which it catalyzes ATP hydrolysis in soluble and membrane bound form. Studies with LaATP confirmed that MgATP is the most likely substrate for rat liver F1, and provided evidence that the enzyme may contain additional Mg2+ binding sites, undetected in previous studies of F1-ATPases, that are required for catalytic activity. Thus, F1 containing the thermodynamically stable LaATP complex in place of MgATP requires added Mg2+ to induce ATP hydrolysis. As Mg2+ cannot readily displace La2+ under these conditions there appears to be a catalytically important class of Mg2+ binding sites on rat liver F1, distinct from the nonexchangeable Mg2+ site and the sites involved in binding MgATP. Additional studies carried out with exchange inert metal-nucleotide complexes involving rhodium and the Mg2+ and Cd2+ complexes of ATP beta S and ATP alpha S imply that the rate-limiting step in the ATPase reaction pathway occurs subsequent to the P gamma-O-P beta bond cleavage steps, perhaps at the level of Mg(ADP)(Pi) hydrolysis or MgADP release. Evidence is presented that Mg2+ remains coordinated to the leaving group of the reaction, i.e., the beta phosphoryl group. Finally, in contrast to soluble F1, F1 bound to F0 in the inner mitochondrial membrane failed to discriminate between the Mg2+ complexes of the ATP beta S isomers. This indicates that a fundamental difference may exist between the catalytic or kinetic mechanism of F1 and the more physiologically intact F0F1 complex.     

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.     

Functional groups at the catalytic site of F1 adenosine triphosphatase

The protection of F1 ATPase by inorganic phosphate, ADP, ATP, and magnesium ion against inactivation by 1-fluoro-2,4-dinitrobenzene, 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole, and 1-(ethoxycarbonyl)-2-ethoxy-1,2-dihydroquinoline, respectively, has been investigated. Dissociation equilibrium constants and rate constants for the labeling reactions have been deduced from a quantitative treatment of the kinetic data. Comparison of these dissociation constants with each other and with the corresponding literature values indicates that the essential Tyr, Arg, Lys, and Glu or Asp residues are indeed located at the catalytic site of the enzyme. Examination of the rate constants for the labeling reactions in the presence of excess inorganic phosphate, ADP, ATP, or magnesium ion, respectively, suggests that the essential phenol and amino groups are located nearer to the bound inorganic phosphate or the gamma-phosphate group than to the alpha- or beta-phosphate group of the bound ATP, that the essential guanidinium group is located nearer to the alpha- or beta-phosphate group than to the gamma-phosphate group of the bound ATP or the bound inorganic phosphate, and that the essential carboxylate group is located slightly farther away but complexed with magnesium ion which it shares with the bound inorganic phosphate. A mechanism consistent with these topographical relationships is proposed for the catalytic hydrolysis and synthesis of ATP.     

Exchange and hydrolysis of tightly bound nucleotides in normal and photolabelled bovine heart mitochondrial F1-ATPase

Treatment of F1 by threefold fast-column centrifugation or by single ammonium sulphate precipitation followed by fast-column centrifugation resulted in enzyme preparations containing 2.5-2.8 mol of bound nucleotides per mol of F1. Short incubations of such F1 preparations in the presence of relatively low concentrations of [14C]ATP and 2-azido[alpha-32P]ATP (100-250 microM), followed by ammonium sulphate precipitation and fast-column centrifugation, resulted in exchange of about 1 mol of the bound nucleotide per mol of F1 not affecting the total amount of bound nucleotides. Exchange of bound nucleotides with 2-azidoATP, followed by ultraviolet irradiation, results in inhibition of the enzyme activity, full inhibition being obtained (via extrapolation) when 1 mol of 2-nitreno-adenosine 5'-tri- or diphosphate (2-N-AT(D)P) is covalently bound to the presumably catalytic site on the enzyme (Van Dongen, M.B.M., De Geus, J.P., Korver, T., Harton, A.F. and Berden, J.A. (1986) Biochim. Biophys. Acta 850, 359-368). In agreement with this, it was found that incorporated [gamma-32P]ATP was hydrolysed by more than 80%. Newly incorporated, not covalently bound radioactive nucleotides could be rapidly exchanged again by the addition of non-radioactive nucleotides, but a higher concentration of nucleotides was needed to fully exchange the incorporated nucleotide. Also, when F1 was depleted of most of its bound nucleotides by repeated ammonium sulphate precipitation, part of the residual nucleotides was still rapidly exchangeable. The ability of F1 to exchange (and hydrolyse) one of the bound nucleotides was not lost when one catalytic and one non-catalytic binding site were occupied by covalently bound 8-N-ATP. Similar results were obtained with F1 containing 2-nitrenoATP covalently bound to one of the catalytic sites. Also, after photolabelling of up to four binding sites with 8-N[( 2-3H]AT(D)P, part of the two remaining non-covalently bound nucleotides could still be rapidly exchanged. In this case the exchanged nucleotide was also hydrolysed. It is concluded that one of the two bound nucleotides became exchangeable when all four other sites (i.e., two catalytic and two non-catalytic) were occupied with covalently bound nucleotides. The site involved showed catalytic properties suggestive of localisation on a beta-subunit.     

Calcium binding to the H+,K(+)-ATPase. Evidence for a divalent cation site that is occupied during the catalytic cycle

The binding and conformational properties of the divalent cation site required for H+,K(+)-ATPase catalysis have been explored by using Ca2+ as a substitute for Mg2+. 45Ca2+ binding was measured with either a filtration assay or by passage over Dowex cation exchange columns on ice. In the absence of ATP, Ca2+ was bound in a saturating fashion with a stoichiometry of 0.9 mol of Ca2+ per active site and an apparent Kd for free Ca2+ of 332 +/- 39 microM. At ATP concentrations sufficient for maximal phosphorylation (10 microM), 1.2 mol of Ca2+ was bound per active site with an apparent Kd for free Ca2+ of 110 +/- 22 microM. At ATP concentrations greater than or equal to 100 microM, 2.2 mol of Ca2+ were bound per active site, suggesting that an additional mole of Ca2+ bound in association with low affinity nucleotide binding. At concentrations sufficient for maximal phosphorylation by ATP (less than or equal to 10 microM), APD, ADP + Pi, beta,gamma-methylene-ATP, CTP, and GTP were unable to substitute for ATP. Active site ligands such as acetyl phosphate, phosphate, and p-nitrophenyl phosphate were also ineffective at increasing the Ca2+ affinity. However, vanadate, a transition state analog of the phosphoenzyme, gave a binding capacity of 1.0 mol/active site and the apparent Kd for free Ca2+ was less than or equal to 18 microM. Mg2+ displaced bound Ca2+ in the absence and presence of ATP but Ca2+ was bound about 10-20 times more tightly than Mg2+. The free Mg2+ affinity, like Ca2+, increased in the presence of ATP. Monovalent cations had no effect on Ca2+ binding in the absence of ATP but dit reduce Ca2+ binding in the presence of ATP (K+ = Rb+ = NH4 + greater than Na+ greater than Li+ greater than Cs+ greater than TMA+, where TMA is tetramethylammonium chloride) by reducing phosphorylation. These results indicate that the Ca2+ and Mg2+ bound more tightly to the phosphoenzyme conformation. Eosin fluorescence changes showed that both Ca2+ and Mg2+ stabilized E1 conformations (i.e. cytosolic conformations of the monovalent cation site(s)) (Ca.E1 and Mg.E1). Addition of the substrate acetyl phosphate to either Ca.E1 or Mg.E1 produced identical eosin fluorescence showing that Ca2+ and Mg2+ gave similar E2 (extracytosolic) conformations at the eosin (nucleotide) site. In the presence of acetyl phosphate and K+, the conformations with Ca2+ or Mg2+ were also similar. Comparison of the kinetics of the phosphoenzyme and Ca2+ binding showed that Ca2+ bound prior to phosphorylation and dissociated after dephosphorylation.(ABSTRACT TRUNCATED AT 400 WORDS)     

When beef-heart mitochondrial F1-ATPase is inhibited by inhibitor protein a nucleotide is trapped in one of the catalytic sites.

Inactivation of the isolated ATPase portion of ATP synthase from beef-heart mitochondria (F1) by its natural inhibitor protein (IP) during steady-state ATP hydrolysis is accompanied by a trapping of 1 mol nucleotide/mol F1 in one of the catalytic sites. The trapped nucleotide is not released during incubation of IP-inhibited F1 in the presence of MgATP at pH 8.0 for at least 20 min, indicating a very low turnover rate of the IP.F1 complex. The ATP/ADP ratio of the trapped nucleotides is higher than that found for transitorily bound nucleotides under the same conditions but in the absence of IP. The IP impairs the acceleration of ATP hydrolysis and product release steps that results from the binding of ATP to an alternate catalytic site. It also inhibits ATP hydrolysis by a single catalytic site or shifts the equilibrium toward ATP formation from bound ADP and Pi. At high pH, an active acidic form of the free IP is transformed to the inactive basic one with a half-time of 3-4 s. This process seems to be prevented by IP binding to F1. The inactive basic form of IP does not compete with the active acidic IP for the binding to F1. The data do not favor the existence of a long-lived catalytically active IP.F1 intermediate during IP action on F1. The reactivation of IP-inhibited membrane-bound F1 by energization may be due to a conformational change in the IP.F1 complex allowing the transformation of IP into an inactive basic state that rapidly dissociates.     

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)