Acid-labile ATP and/or ADP/P(i) binding to the tetraprotomeric form of Na/K-ATPase accompanying catalytic phosphorylation-dephosphorylation cycle.

The Na/K-ATPase has been shown to bind 1 and 0.5 mol of (32)P/mol of alpha-chain in the presence [gamma-(32)P]ATP and [alpha-(32)P]ATP, respectively, accompanied by a maximum accumulation of 0.5 mol of ADP-sensitive phosphoenzyme (NaE1P) and potassium-sensitive phosphoenzyme (E2P). The former accumulation was followed by the slow constant liberation of P(i), but the latter was accompanied with a rapid approximately 0.25 mol of acid-labile P(i) burst. The rubidium (potassium congener)-occluded enzyme (approximately 1.7 mol of rubidium/mol of alpha-chain) completely lost rubidium on the addition of sodium + magnesium. Further addition of approximately 100 microM [gamma-(32)P]ATP and [alpha-(32)P]ATP, both induced 0.5 mol of (32)P-ATP binding to the enzyme and caused accumulation of approximately 1 mol of rubidium/mol of alpha-chain, accompanied by a rapid approximately 0.5 mol of P(i) burst with no detectable phosphoenzyme under steady state conditions. Electron microscopy of rotary-shadowed soluble and membrane-bound Na/K-ATPases and an antibody-Na/K-ATPase complex, indicated the presence of tetraprotomeric structures (alphabeta)(4). These and other data suggest that Na/K-ATP hydrolysis occurs via four parallel paths, the sequential appearance of (NaE1P:E.ATP)(2), (E2P:E.ATP:E2P:E. ADP/P(i)), and (KE2:E.ADP/P(i))(2), each of which has been previously referred to as NaE1P, E2P, and KE2, respectively.     

Transport protons do not participate in ATP synthesis/hydrolysis at the nucleotide binding site of the H(+)-ATPase from chloroplasts.

The H(+)-ATPase from chloroplasts CFoF1, was brought into the active, reduced state by illumination of thylakoids in the presence of thioredoxin and dithiothreitol. Uni-site ATP synthesis was initiated by the addition of 20 nM [alpha-32P]ADP, and enzyme-bound and free nucleotides were separated by a pressure column. The ratio of enzyme-bound ADP to ATP was 0.55 +/- 0.05. In a second experiment, uni-site ATP hydrolysis under energized conditions was initiated by the addition of 36 nM [alpha-32P]ATP; enzyme-bound and free nucleotides were separated by a pressure column. Both procedures were carried out under continuous illumination. The ratio of enzyme-bound ADP to ATP was 0.46 +/- 0.04. In a third experiment, uni-site ATP hydrolysis under de-energized conditions was initiated by the addition of 39 nM [alpha-32P]ATP and NH4Cl/valinomycin in the absence of illumination. Free and enzyme-bound nucleotides were separated also by a pressure column. The ratio of enzyme-bound ADP to ATP was 0.43 +/- 0.02. This ratio was always the same irrespective of whether the reaction runs in the synthesis or the hydrolysis direction. Furthermore, the ratio does not depend on the membrane energization. We conclude, therefore, that the protons are not directly involved in the reaction at the catalytic site.     

Uni-site catalysis in thylakoids. The influence of membrane energization on ATP hydrolysis and ATP-Pi exchange

ATP-hydrolysis was measured with thylakoid membranes during continuous illumination. The concentrations of free and enzyme-bound ATP, ADP and Pi were measured using either cold ATP, [gamma-32P]ATP or [14C]ATP. The concentration of free ATP was constant, free ADP and enzyme-bound ATP were below the detection limit. Nevertheless, [gamma-32P]ATP was bound, hydrolyzed and 32Pi was released. The ADP was not released from the enzyme but cold Pi was bound from the medium, cold ATP was resynthesized and released. A quantitative analysis gave the following rate constants: ATP-binding kATP = 2 . 10(5) M-1 s-1, ADP-release: kADP less than 10(-2)s-1, Pi-release: kPi = 0.1 s-1. These rate constants are considerably smaller than under deenergized conditions. The rate constant for the release of ATP can be estimated to be at least 0.2 s-1 under energized conditions. Obviously, energization of the membrane, i.e. protonation of the enzyme leads mainly to a decrease of the rate of ATP-binding, to an increase of the rate of ATP release and to a decrease of the rate of ADP-release.     

Phosphoenzyme formation from ATP in the ATPase of sarcoplasmic reticulum. Effect of KCl or ATP and slow dissociation of ATP from precursor enzyme-ATP complex

The ATP-dependent phosphoenzyme formation and its reversal were studied at 0 degrees C and pH 7.0 in the ATPase of sarcoplasmic reticulum. Addition of KCl or several other salts (approximately 100 mM) decreased the maximum rate of ADP-induced dephosphorylation of phosphoenzyme as well as the apparent affinity of the phosphoenzyme toward ADP. High ATP had a similar effect on the latter, whereas it had little effect on the former. In contrast, high KCl or a considerable change in the ionic strength had little effect on the initial rate of phosphoenzyme formation at saturating ATP concentrations. During steady state phosphorylation at 1.0 mM MgCl2 and 5.0 mM CaCl2 in the absence of added KCl, a significant amount of [gamma-32P]ATP remained bound to the enzyme even when the enzyme concentration was much in excess over that of [gamma-32P]ATP. Evidence is presented that this enzyme-ATP complex represents a precursor to the phosphoenzyme. ATP dissociated slowly (0.20 s-1) from this enzyme-ATP complex and addition of high KCl or other salts accelerated its dissociation. In contrast, when the enzyme was complexed with adenyl-5'-yl (beta, gamma-methylene)diphosphonate in the absence of added KCl under these conditions, dissociation of the nucleotide from the complex as estimated in the displacement experiment with [gamma-32P]ATP, was found to be much faster than that of ATP.     

Nucleotide-free kinesin hydrolyzes ATP with burst kinetics

Bovine brain kinesin binds ADP tightly and contains a stoichiometric amount of ADP at its active site when isolated in the presence of free Mg2+ (Hackney, D. D. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 6314-6318). EDTA in excess of Mg2+ weakens ADP binding and nucleotide-free kinesin can be prepared by gel filtration with excess EDTA. On addition of ATP, this nucleotide-free enzyme catalyzes the rapid hydrolysis of a stoichiometric amount of ATP in a burst phase followed by much slower continued ATP hydrolysis limited by the release of ADP from the active site. This burst reaction is evident both by formation of [32P]Pi from [gamma-32P]ATP and by formation of [alpha-32P]ADP from [alpha-32P]ATP. At 1.1 nM kinesin active sites, the observed rate of the burst phase increases linearly with ATP over the 1-20 nM range yielding a bimolecular rate of net ATP binding and hydrolysis of 2.5 microM-1 s-1. The intercept at zero ATP is 0.008 s-1 which equals the ADP release rate at 0.008-0.009 s-1. This predicts a Km for ATP of approximately 3.5 nM and measurements of the dependence on ATP concentration of the steady state rate and amount of bound ADP are consistent with a Km of this magnitude.     

Localization of the ATP binding site on alpha-tubulin

The binding site for ATP to tubulin was established by use of the photoaffinity label [gamma-32P]N3ATP. Photolysis of the analog in the presence of tubulin resulted in covalent modification of the protein as revealed by autoradiography of electropherograms. Scanning the autoradiograms showed that the ATP analog was bound mainly to the alpha subunit of the tubulin dimer; the alpha subunit was two to three times more radioactive than was the beta subunit. The location of a particular site on the alpha subunit was further defined by peptide maps. The alpha and beta subunits from affinity-labeled tubulin were separated and digested with Staphylococcus protease. Radioactivity was found predominantly in one peptide band from the alpha subunit. The location of the [gamma-32P]N3ATP binding site on the alpha subunit distinguishes it from the previously known exchangeable GTP binding site which is on the beta subunit. Moreover, excess GTP did not compete with [gamma-32P]N3ATP binding. The ATP binding site is distinct from the nonexchangeable GTP binding site. The GTP content of tubulin was the same after dialysis in 0.5 mM ATP as it was following dialysis against ATP-free buffer. Proof that the binding site for [gamma-32P]N3ATP is the same as that for ATP was obtained by competition experiments. In the presence of ATP, photolysis of the affinity analog did not label the alpha subunit preferentially.     

Nucleosidediphosphate kinase from Ehrlich ascites tumor cells

A phosphate-incorporating protein has been highly purified from the cytosol of Ehrlich ascites tumor cells (EAT cells). The nitrocellulose membrane method was used to follow the progress of the purification by quantitation of the [32P]phosphorylated form of the protein. The purified protein was identified as an NDP-kinase since it exhibited NDP-kinase activity and had enzyme characteristics in common with other NDP-kinases from various mammalian cells. The purified NDP-kinase was found to have a molecular weight of approximately 76,000 daltons. Moreover, the enzyme appears to consist of two distinct polypeptides (18,000 and 20,000 daltons). This enzyme contained 19 amino acids, with high levels of glycine (9.8%) and lysine (9.0%). The enzyme rapidly formed a [32P]phosphoenzyme when incubated with [gamma-32P]ATP in the presence of Mg2+ (1 mM) at the optimum pH of 7.5 even at low temperature (below 4 degrees C). This phosphoenzyme is an enzyme-bound, high-energy-phosphate intermediate, because ATP was formed from it on incubation with ADP in the presence of Mg2+ (1 mM). This finding suggests that the phosphoenzyme functions as an intermediate in NDP-kinase action.     

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)     

Functionally similar vanadate-induced 8-azidoadenosine 5'-[alpha-(32)P]Diphosphate-trapped transition state intermediates of human P-glycoprotin are generated in the absence and presence of ATP hydrolysis

P-glycoprotein (Pgp) is an ATP-dependent drug efflux pump whose overexpression confers multidrug resistance to cancer cells. Pgp exhibits a robust drug substrate-stimulable ATPase activity, and vanadate (Vi) blocks this activity effectively by trapping Pgp nucleotide in a non-covalent stable transition state conformation. In this study we compare Vi-induced [alpha-(32)P]8-azido-ADP trapping into Pgp in the presence of [alpha-(32)P]8-azido-ATP (with ATP hydrolysis) or [alpha-(32)P]8-azido-ADP (without ATP hydrolysis). Vi mimics P(i) to trap the nucleotide tenaciously in the Pgp.[alpha-(32)P]8-azido-ADP.Vi conformation in either condition. Thus, by using [alpha-(32)P]8-azido-ADP we show that the Vi-induced transition state of Pgp can be generated even in the absence of ATP hydrolysis. Furthermore, half-maximal trapping of nucleotide into Pgp in the presence of Vi occurs at similar concentrations of [alpha-(32)P]8-azido-ATP or [alpha-(32)P]8-azido-ADP. The trapped [alpha-(32)P]8-azido-ADP is almost equally distributed between the N- and the C-terminal ATP sites of Pgp in both conditions. Additionally, point mutations in the Walker B domain of either the N- (D555N) or C (D1200N)-terminal ATP sites that arrest ATP hydrolysis and Vi-induced trapping also show abrogation of [alpha-(32)P]8-azido-ADP trapping into Pgp in the absence of hydrolysis. These data suggest that both ATP sites are dependent on each other for function and that each site exhibits similar affinity for 8-azido-ATP (ATP) or 8-azido-ADP (ADP). Similarly, Pgp in the transition state conformation generated with either ADP or ATP exhibits drastically reduced affinity for the binding of analogues of drug substrate ([(125)I]iodoarylazidoprazosin) as well as nucleotide (2'(3')-O-(2,4,6-trinitrophenyl)adenosine 5'-triphosphate). Analyses of Arrhenius plots show that trapping of Pgp with [alpha-(32)P]8-azido-ADP (in the absence of hydrolysis) displays an approximately 2.5-fold higher energy of activation (152 kJ/mol) compared with that observed when the transition state intermediate is generated through hydrolysis of [alpha-(32)P]8-azido-ATP (62 kJ/mol). In aggregate, these results demonstrate that the Pgp.[alpha-(32)P]8-azido-ADP (or ADP).Vi transition state complexes generated either in the absence of or accompanying [alpha-(32)P]8-azido-ATP hydrolysis are functionally indistinguishable.     

Phosphorylation of ATP citrate lyase in response to glucagon.

Incubation of hepatocytes with [32P]orthophosphate resulted in the incorporation of 32P into material that is precipitated by reaction with antibodies to ATP citrate lyase. The amount of radioactivity precipitated was decreased when unlabeled, purified ATP citrate lyase was added to extracts of hepatocytes that had been incubated with [32P]orthophosphate. Addition of glucagon to hepatocytes that had been preincubated with [32P]orthophosphate resulted in a 56% increase in acid-stable 32P in the trichloroacetic acid-insoluble portion of immunoprecipitates. Catalytic phosphate bound to ATP citrate lyase reaction with ATP and Mg2+ is acid-labile; thus, glucagon-dependent phosphorylation is distinguished from the catalytic phosphate. When hepatocytes were incubated in the absence of [32P]orthophosphate and extracted in a medium containing [gamma-32P]ATP, no acid-stable 32P was present in immunoprecipitates. This indicates that the incorporation into ATP citrate lyase of acid-stable phosphate occurs prior to extraction of the enzyme. Preliminary studies, using a procedure that allows for measurement of enzyme activity starting 1 min after beginning the extraction of lyase from hepatocytes, have shown no difference in lyase activity when hepatocytes are treated with or without glucagon.     

The enzymatic preparation of [alpha-(32)P]nucleoside triphosphates, cyclic [32P] AMP, and cyclic [32P] GMP.

A method has been developed for the enzymatic preparation of alpha-(32)P-labeled ribo- and deoxyribonucleoside triphosphates, cyclic [(32)P]AMP, and cyclic [(32)P]GMP of high specific radioactivity and in high yield from (32)Pi. The method also enables the preparation of [gamma-(32)P]ATP, [gamma-(32)P]GTP, [gamma-(32)P]ITP, and [gamma-(32)P]-dATP of very high specific activity and in high yield. The preparation of the various [alpha-(32)P]nucleoside triphosphates relies on the phosphorylation of the respective 3'-nucleoside monophosphates with [gamma-(32)P]ATP by polynucleotide kinase and a subsequent nuclease reaction to form [5'-(32)P]nucleoside monophosphates. The [5'-(32)P]nucleoside monophosphates are then converted enzymatically to the respective triphosphates. All of the reactions leading to the formation of [alpha-(32)P]nucleoside triphosphates are carried out in the same reaction vessel, without intermediate purification steps, by the use of sequential reactions with the respective enzymes. Cyclic [(32)P]AMP and cyclic [(32)P]GMP are also prepared enzymatically from [alpha-(32)P]ATP or [alpha-(32)P]GTP by partially purified preparations of adenylate or guanylate cyclases. With the exception of the cyclases, all enzymes used are commerically available. The specific activity of (32)P-labeled ATP made by this method ranged from 200 to 1000 Ci/mmol for [alpha-(32)P]ATP and from 5800 to 6500 Ci/mmol for [gamma-(32)P]ATP. Minor modifications of the method should permit higher specific activities, especially for the [alpha-(32)P]nucleoside triphosphates. Methods for the use of the [alpha-(32)P]nucleoside phosphates are described for the study of adenylate and guanylate cyclases, cyclic AMP- and cyclic GMP phosphodiesterase, cyclic nucleotide binding proteins, and as precursors for the synthesis of other (32)P-labeled compounds of biological interest. Moreover, the [alpha-(32)P]nucleoside triphosphates prepared by this method should be very useful in studies on nucleic acid structure and metabolism and the [gamma-(32)P]nucleoside triphosphates should be useful in the study of phosphate transfer systems.     

Bovine brain Na+, K+-stimulated ATP phosphohydrolase studied by a rapid-mixing technique. Detection of a transient [32P]phosphoenzyme formed in the presence of potassium ions.

1. Conditions for binding of [gamma-32P]ATP to bovine brain Na+,K+-stimulated ATPase were investigated by the indirect technique of measuring the initial rate of 32P-labelling of the active site of the enzyme. 2. At 100 muM [gamma-32P]ATP in the presence of 3 mM MgCl2, approximately the same very high rate of formation of [32P]phosphoenzyme was obtained irrespective of whether [gamma-32P]ATP was added to the enzyme simultaneously with, or 70 ms in advance of the addition of NaCl. A comparatively slow rate of phosphorylation was obtained at 5 muM[gamma-32P]ATP without preincubation. However, on preincubation of the enzyme with 5 muM[gamma-32P]ATP a rate of formation of [32P]phosphoenzyme almost as rapid as at 100 muM[gamma-32P]ATP was observed. 3. A transient [32P]phosphoenzyme was discovered. It appeared in the presence of K+, under conditions which allowed extensive binding of [gamma-32P]-ATP. The amount of [gamma-32P]ATP that could be bound to the enzyme seemed to equal the amount of [32P] phosphorylatable sites. 4. The formation of the transient [32P] phosphoenzyme was inhibited by ADP. The transient [32P] phosphoenzyme was concluded mainly to represent the K+-insensitive and ADP-sensitive E1-32P. 5. When KCl was present in the enzyme solution before the addition of NaCl only a comparatively slow rate of phosphorylation was observed. On preincubation of the enzyme with [gamma-32]ATP an increase in the rate of formation of [32P] phosphoenzyme was obtained, but there was no transient [32P]-phosphoenzyme. The transient [32P]phosphoenzyme was, however, detected when the enzyme solution contained NaCl in addition to KCl and the phosphorylation was started by the addition of [gamma-32P]ATP.     

Localization of the high-affinity binding site for ATP on the membrane-bound chloroplast ATP synthase

The photoaffinity analog 2-azido-ADP has been used to investigate the high-affinity binding site(s) for ATP on the chloroplast thylakoid membrane. Photophosphorylation of 2-azido-ADP results in the rapid formation of 2-azido-ATP, which remains tightly bound to the membranes after extensive washing. The kinetic parameters of the tight binding of ATP and of 2-azido-ATP are similar (apparent Km = 1-2 microM; maximum extent = 0.2-0.4 nmol/mg of chlorophyll). Ultraviolet irradiation of washed thylakoid membranes containing tightly bound 2-azido-[gamma-32P]ATP induces covalent incorporation of the label exclusively into the beta subunit of the chloroplast coupling factor one. Previous results have shown that the tight binding site for ADP is also located on the beta subunit of the ATP synthase (Czarnecki, J. J., Abbott, M. S., and Selman, B. R. (1983) Eur. J. Biochem. 136, 19-24). To further characterize the tight binding sites for ADP and ATP, the membrane-bound coupling factor has been covalently modified with either tightly bound 2-azido-[gamma-32P]ATP or tightly bound 2-azido-[beta-32P]ADP. The photolabeled beta subunits have been isolated and subjected to partial proteolytic digestion and SDS-gel electrophoresis. The results of these experiments demonstrate that the tight binding sites for ADP and ATP are located on identical portions of beta subunit polypeptide.     

Phosphate from the phosphointermediate (EP) of the human red blood cell Na/K pump is coeffluxed with Na, in the absence of external K

This study is concerned with Na/K pump-mediated phosphate efflux that occurs during uncoupled Na efflux in human red blood cells. Uncoupled Na efflux is known to be a ouabain-sensitive mode of the Na/K pump that occurs in the absence of external Nao and Ko. Because this efflux (measured with 22Na) is also inhibited by 5 mM Nao, the efflux can be separated into a Nao-sensitive and a Nao-insensitive component. Previous work established that the Nao-sensitive efflux is actually comprised of an electroneutral coefflux of Na with cellular anions, such as SO4 (as 35SO4). The present work focuses on the Nao-insensitive component in which the principal finding is that orthophosphate (P(i)) is coeffluxed with Na in a ouabain-sensitive manner. This P(i) efflux can be seen to occur, in the absence of Ko, in both DIDS-treated intact cells and resealed red cell ghosts. This efflux of P(i) was shown to be derived directly from the pump's substrate, ATP, by the use of resealed ghosts made to contain both ATP and P(i) in which either the ATP or the P(i) were labeled with, respectively, [gamma-32P]ATP or [32P]H3PO4. (These resealed ghosts also contained Na, Mg, P(i), SO4, Ap5A, as well as an arginine kinase/creatine kinase nucleotide regenerating system for the control of ATP and ADP concentrations, and were suspended usually in (NMG)2SO4 at pH 7.4.) It was found that 32P was only coeffluxed with Na when the 32P was contained in [gamma-32P]ATP and not in [32P]H3PO4. This result implies that the 32P that is released comes from ATP via the pump's phosphointermediate (EP) without commingling with the cellular pool of P(i). Ko (as K2SO4) inhibits this 32P efflux as well as the Nao-sensitive 35SO4 efflux, with a K0.5 of 0.3-0.4 mM. The K0.5 for inhibition of P(i) efflux by Ko is not influenced by Nao, nor can Nao act as a congenor for Ko in any of the flux reactions involving Ko. The stoichiometry of Na to SO4 and Na to P(i) efflux is approximately 2:1 under circumstances where the stoichiometry of Na effluxed to ATP utilized is 3:1. From these and other results reported, it is suggested that there are two types of uncoupled Na efflux that differ from each other on the basis of their sensitivity to Nao, the source (cellular vs substrate) and kind of anion (SO4 vs P(i)) transported.(ABSTRACT TRUNCATED AT 400 WORDS)     

Constitutive release of ATP and evidence for major contribution of ecto-nucleotide pyrophosphatase and nucleoside diphosphokinase to extracellular nucleotide concentrations

Nucleotides are important extracellular signaling molecules. At least five mammalian P2Y receptors exist that are specifically activated by ATP, UTP, ADP, or UDP. Although the existence of ectoenzymes that metabolize extracellular nucleotides is well established, the relative flux of ATP and UTP through their extracellular metabolic products remains undefined. Therefore, we have studied the kinetics of accumulation and metabolism of endogenous ATP in the extracellular medium of four different cell lines. ATP concentrations reached a maximum immediately after change of medium and decreased thereafter with a single exponential decay (t(1/2);1 approximately;230-40 min). ATP levels did not fall to zero but attained a base-line concentration that was independent of the medium volume and of the initial ATP concentration. Although the base-line concentration of ATP remained stable for up to 12 h, [gamma-(32)P]ATP added to resting cells as a radiotracer was completely degraded within 120 min, indicating that steady state reflected a basal rate of ATP release balanced by ATP hydrolysis (20-200 fmol x min(-)(1) x cell(-)(6)). High performance liquid chromatography analysis revealed that the gamma-phosphate of ATP was rapidly, although transiently, transferred during steady state to species subsequently identified as UTP and GTP, indicating the existence of both ecto-nucleoside diphosphokinase activity and the accumulation of endogenous UDP and GDP. Conversely, addition of [gamma-(32)P]UTP to resting cells resulted in transient formation of [gamma-(32)P]ATP, indicating phosphorylation of endogenous ADP by nucleoside diphosphokinase. The final (32)P-products of [gamma-(32)P]ATP metabolism were [(32)P]orthophosphoric acid and a (32)P-labeled species that was further purified and identified as [(32)P]inorganic pyrophosphate. In C6 cells, the formation of [(32)P]pyrophosphate from [gamma-(32)P]ATP at steady state exceeded by 3-fold that of [(32)P]orthophosphate. These results illustrate for the first time a constitutive release of ATP and other nucleotides and reveal the existence of a complex extracellular metabolic pathway for released nucleotides. In addition to the existence of an ecto-ATPase activity, our results suggest a major scavenger role of ecto-ATP pyrophosphatase and a transphosphorylating activity of nucleoside diphosphokinase.     

Phosphorylation of the plasma membrane calcium pump at high ATP concentration. On the mechanism of ATP hydrolysis

The plasma membrane calcium ATPase (PMCA) reacts with ATP to form acid-stable phosphorylated intermediates (EP) that can be measured using (gamma-32P)ATP. However, the steady-state level of EP at [ATP] higher than 100 microM has not yet been studied due to methodological problems. Using a microscale method and a purified preparation of PMCA from human red blood cells, we measured the steady-state concentration of EP as a function of [ATP] up to 2 mM at different concentrations of Mg2+, both at 4 and 25 degrees C. We have measured the Ca2+-ATPase activity (v) under the same conditions as those used for phosphorylation experiments. While the curves of ATPase activity vs [ATP] were well described by the Michaelis-Menten equation, the corresponding curves of EP required more complex fitting equations, exhibiting at least a high- and a low-affinity component. Mg2+ increases the apparent affinity for ATP of this latter component, but it shows no significant effect on its high-affinity one or on the Ca2+-ATPase activity. We calculated the turnover of EP (k(pEP)) as the ratio v/EP. At 1 mM Mg2+, k(pEP) increases hyperbolically with [ATP], while at 8 microM Mg2+, it exhibits a behavior that cannot be explained by the currently accepted mechanism for ATP hydrolysis. These results, together with measurements of the rate of dephosphorylation at 4 degrees C, suggest that ATP is acting in additional steps involving the interconversion of phosphorylated intermediates during the hydrolysis of the nucleotide.     

Functional consequences of the oligomeric form of the membrane-bound gastric H,K-ATPase

Cross-linking and two-dimensional crystallization studies have suggested that the membrane-bound gastric H,K-ATPase might be a dimeric alpha,beta-heterodimer. Effects of an oligomeric structure on the characteristics of E(1), E(2), and phosphoenzyme conformations were examined by measuring binding stoichiometries of acid-stable phosphorylation (EP) from [gamma-(32)P]ATP or (32)P(i) or of binding of [gamma-(32)P]ATP and of a K(+)-competitive imidazonaphthyridine (INT) inhibitor to an enzyme preparation containing approximately 5 nmol of ATPase/mg of protein. At <10 microM MgATP, E(1)[ATP].Mg.(H(+)):E(2) is formed at a high-affinity site, and is then converted to E(1)P.Mg.(H(+)):E(2) and then to E(2)P.Mg:E(1) with luminal proton extrusion. Maximal acid-stable phosphorylation yielded 2.65 nmol/mg of protein. Luminal K(+)-dependent dephosphorylation returns this conformation to the E(1) form. At high MgATP concentrations (>0.1 mM), the oligomer forms E(2)P.Mg:E(1)[ATP].Mg.(H(+)). The sum of the levels of maximal EP formation and ATP binding was 5.3 nmol/mg. The maximal amount of [(3)H]INT bound was 2.6 nmol/mg in the presence of MgATP, Mg(2+), Mg-P(i), or Mg-vanadate with complete inhibition of activity. K(+) displaced INT only in nigericin-treated vesicles, and thus, INT binds to the luminal surface of the E(2) form. INT-bound enzyme also formed 2.6 nmol of EP/mg at high ATP concentrations by formation of E(2).Mg.(INT)(exo):E(1)[ATP].Mg.(H(+)) which is converted to E(2).Mg.(INT)(exo):E(1)P.Mg.(H(+))(cyto), but this E(1)P form was K(+)-insensitive. Binding of the inhibitor fixes half the oligomer in the E(2) form with full inhibition of activity, while the other half of the oligomer is able to form E(1)P only when the inhibitor is bound. It appears that the catalytic subunits of the oligomer during turnover in intact gastric vesicles are restricted to a reciprocal E(1):E(2) configuration.     

Slow dissociation of ATP from the calcium ATPase

The acyl-phosphate intermediate of the sarcoplasmic reticulum calcium ATPase reaction, formed in a brief incubation of vesicular enzyme with 5 microM [gamma-32P]ATP and calcium, reacts biphasically with added ADP (pH 7.0, 25 degrees C, 100 mM KCl, 5 mM MgSO4). Both the burst size and the rate constant for the slow phase increase with increasing ADP concentration in the way that is expected if the burst represents very rapid formation of an equilibrium amount of enzyme-bound ATP and the slow phase represents rate-limiting dissociation of ATP. Also consistent with this interpretation are the slow labeling of phosphoenzyme under conditions in which unlabeled ATP must dissociate first and the observation of a burst of ATP formation on ADP addition to phosphoenzyme. Values of the equilibrium constants for ADP dissociation from phosphoenzyme (0.75 mM), for ATP formation on the enzyme (2.3), and for the ATP dissociation rate constant (37 s-1) were obtained from a quantitative analysis of the data.     

ATP binding/hydrolysis by and phosphorylation of peroxisomal ATP-binding cassette proteins PMP70 (ABCD3) and adrenoleukodystrophy protein (ABCD1)

The 70-kDa peroxisomal membrane protein (PMP70) and adrenoleukodystrophy protein (ALDP), half-size ATP-binding cassette transporters, are involved in metabolic transport of long and very long chain fatty acids into peroxisomes. We examined the interaction of peroxisomal ATP-binding cassette transporters with ATP using rat liver peroxisomes. PMP70 was photoaffinity-labeled at similar efficiencies with 8-azido-[alpha-32P]ATP and 8-azido-[gamma-32P]ATP when peroxisomes were incubated with these nucleotides at 37 degrees C in the absence Mg2+ and exposed to UV light without removing unbound nucleotides. The photoaffinity-labeled PMP70 and ALDP were co-immunoprecipitated together with other peroxisomal proteins, which also showed tight ATP binding properties. Addition of Mg2+ reduced the photoaffinity labeling of PMP70 with 8-azido-[gamma-32P]ATP by 70%, whereas it reduced photoaffinity labeling with 8-azido-[alpha-32P]ATP by only 20%. However, two-thirds of nucleotide (probably ADP) was dissociated during removal of unbound nucleotides. These results suggest that ATP binds to PMP70 tightly in the absence of Mg2+, the bound ATP is hydrolyzed to ADP in the presence of Mg2+, and the produced ADP is dissociated from PMP70, which allows ATP hydrolysis turnover. Properties of photoaffinity labeling of ALDP were essentially similar to those of PMP70. Vanadate-induced nucleotide trapping in PMP70 and ALDP was not observed. PMP70 and ALDP were also phosphorylated at a tyrosine residue(s). ATP binding/hydrolysis by and phosphorylation of PMP70 and ALDP are involved in the regulation of fatty acid transport into peroxisomes.     

Two-step internalization of Ca2+ from a single E approximately P.Ca2 species by the Ca2+-ATPase

Phosphorylation by ATP of E.*Ca2 (sarcoplasmic reticulum vesicles (SRV) with bound 45Ca2+) during 5-10 ms leads to the occlusion of 2 *Ca2+/EPtot [quench by ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA) alone] in both "empty" (10 microM free Ca2+in) or "loaded" SRV (20-40 mM free Ca2+in). The rate of Ca2+ "internalization" from the occluded E approximately P.*Ca2 was measured by using an ADP + EGTA quench; a *Ca2+ ion that is not removed by this quench is defined as internalized. In the presence of 20-40 mM unlabeled Ca2+ inside SRV, 1 *Ca2+/EPtot is internalized from 45Ca-labeled E approximately P.*Ca2 with a first-order rate constant of kl = 34 s-1. Empty SRV take up 2 *Ca2+/EPtot with the same initial rate, but the overall rate constant is kobsd = 17 s-1. The apparent rate constant (kb = 17 s-1) for internalization of the second *Ca2+ is inhibited by [Ca]in, with K0.5 approximately 1.3 mM and a Hill coefficient of n = 1.1. These data show that the two Ca2+ ions are internalized sequentially, presumably from separate sequential sites in the channel. [32P]EP.Ca2 obtained by rapid mixing of E.Ca2 with [gamma-32P]ATP and EGTA disappears in a biphasic time course with a lag corresponding to approximately 34 s-1, followed by EP* decay with a rate constant of approximately 17 s-1. This shows that both Ca2+ ions must be internalized before the enzyme changes its specificity for catalysis of phosphoryl transfer to water instead of to ADP. Increasing the concentration of ATP from 0.25 to 3 mM accelerates the rate of 45Ca2+ internalization from 34 to 69 s-1 for the first Ca2+ and from 17 to 34 s-1 for the second Ca2+. High [ATP] also accelerates both phases of [32P]EP.Ca2 disappearance by the same factor. The data are consistent with a single form of ADP-sensitive E approximately P.Ca2 that sequentially internalizes two ions. The intravesicular volume was estimated to be 2.0 microL/mg, so that one turnover of the enzyme gives 4 mM internal [Ca2+].