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.     

Phosphorylation and dephosphorylation kinetics of potassium-stimulated ATP phosphohydrolase from hog gastric mucosa.

Partial reactions of potassium-stimulated ATP phosphohydrolase from hog gastric mucosa were studied by means of a rapid-mixing apparatus. At 21 degrees C, in the presence of 2 mM MgCl2 and 5 microM [gamma-32P]ATP there was a rapid phosphorylation of the enzyme with a pseudofirst order rate constant of 1400 min-1. Addition of the ATP about 120 ms before the MgCl2 increased this rate constant to 4400 min-1. In the absence of MgCl2 there was no phosphorylation. Addition of 4 or 10 mM KCl to the phosphoenzyme which had been formed in the absence of KCl produced a rapid initial rate of dephosphorylation (k = 2600 and 3200 min-1 respectively). An additional slow component of dephosphorylation was observed when unlabeled ATP was added together with the KCl (k = 700 to 900 min-1). At a 4 mM concentration, KCl stimulated the ATPase activity about 9-fold. At higher concentrations, the activity was reduced in parallel with a reduction of the steady state level of phosphoenzyme. Addition of KCl to the enzyme before the addition of ATP plus MgCl2 resulted in a low rate and extent of phosphorylation. KCl appeared to inhibit the phosphorylation at a level preceeding the E.ATP complex.     

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.     

Bovine brain Na+,K+-stimulated ATP phosphohydrolase studied by a rapid-mixing technique. K+-stimulated liberation of [32P] orthophosphate from [32P] phosphoenzyme and resolution of the dephosphorylation into two phases.

Dephosphorylation of [32P]phosphoenzyme of bovine brain Na+,K+-stimulated ATP phosphohydrolase (EC 3.6.1.3), labelled by [gamma-32P]ATP, was investigated at 21 degrees C by means of a rapid-mixing technique. On addition of a high concentration of KCl (10 mM) to [32P]phosphoenzyme at steady state in the presence of Mg2+ and Na+, very rapid dephosphorylation was obtained. Simultaneously, the amount of [32P]orthophosphate increased at about the same rate. It was concluded that this K+-stimulated dephosphorylation and liberation of [32P]orthophosphate from the [32P]phosphoenzyme was rapid enough to participate in the Na+,K+-stimulated hydrolysis of ATP. In order to study the dephosphorylation in absence of continuing 32P-labelling, excess unlabelled ATP or a chelator of Mg2+ was added. Simultaneous addition of a high concentration of KCl to the [32P]phosphoenzyme formed in the presence of Mg2+ and Na+ but in the absence of K+, resulted in an initial very rapid phase and a subsequent slower phase of dephosphorylation. With KCl also initially present in the incubation medium, only the slow phase was observed. The slow phase of dephosphorylation also seemed to be sufficiently rapid to participate in the Na+, K+-stimulated ATPase reaction. On addition of a high concentration of ADP (5 mM) to [32P]phosphoenzyme formed in the presence of Mg2+ and Na+, an initial comparatively rapid, and later slow phase of dephosphorylation were detected. This gave further support for different forms of phosphoenzyme. Approximate concentrations of these forms, in the absence and presence of KCl, were estimated by extrapolation and the turnover of these forms was calculated. The nature of the kinetically different components of phosphoenzyme and their role in the Na+, K+-stimulated ATPase reaction is discussed.     

(Na+ + K+)-ATPase: confirmation of the three-pool model for the phosphointermediates of Na+-ATPase activity. Estimation of the enzyme-ATP dissociation rate constant

The dephosphorylation kinetics of acid-stable phosphointermediates of (Na+ + K+)-ATPase from ox brain, ox kidney and pig kidney was studied at 0 degree C. Experiments performed on brain enzyme phosphorylated at 0 degree C in the presence of 20-600 mM Na+, 1 mM Mg2+ and 25 microM [gamma-32P]ATP show that irrespectively of the EP-pool composition, which is determined by Na+ concentration, all phosphoenzyme is either ADP- or K+-sensitive. After phosphorylation of kidney enzymes at 0 degree C with 1 mM Mg2+, 25 microM [gamma-32P]ATP and 150-1000 mM Na+ the amounts of ADP- and K+-sensitive phosphoenzymes were determined by addition of 1 mM ATP + 2.5 mM ADP or 1 mM ATP + 20 mM K+. Similarly to the previously reported results on brain enzyme, both types of dephosphorylation curves have a fast and a slow phase, so that also for kidney enzymes a slow decay of a part of the phosphoenzyme, up to 80% at 1000 mM Na+, after addition of 1 mM ATP + 20 mM K+ is observed. The results obtained with the kidney enzymes seem therefore to reinforce previous doubts about the role played by E1 approximately P(Na3) as intermediate of (Na+ + K+)-ATPase activity. Furthermore, for both kidney enzymes the sum of ADP- and K+-sensitive phosphoenzymes is greater than E tot. In experiments on brain enzyme an estimate of dissociation rate constant for the enzyme-ATP complex, k-1, is obtained. k-1 varies between 1 and 4 s-1 and seems to depend on the ligands present during formation of the complex. The highest values are found for enzyme-ATP complex formed in the presence of Na+ or Tris+. The results confirm the validity of the three-pool model in describing dephosphorylation kinetics of phosphointermediates of Na+-ATPase activity.     

Phosphorylation of Na+, K(+)-ATPase by ATP in the presence of K+ and dimethylsulfoxide but in the absence of Na+

Purified Na+, K(+)-ATPase was phosphorylated by [gamma-32P]ATP in a medium containing dimethylsulfoxide and 5 mM Mg2+ in the absence of Na+ and K+. Addition of K+ increased the phosphorylation levels from 0.4 nmol phosphoenzyme/mg of protein in the absence of K+ to 1.0 nmol phosphoenzyme/mg of protein in the presence of 0.5 mM K+. Higher velocities of enzyme phosphorylation were observed in the presence of 0.5 mM K+. Increasing K+ concentrations up to 100 mM lead to a progressive decrease in the phosphoenzyme (EP) levels. Control experiments, that were performed to determine the contribution to EP formation from the Pi inevitably present in the assays, showed that this contribution was of minor importance except at high (20-100 mM) KCl concentrations. The pattern of EP formation and its KCl dependence is thus characteristic for the phosphorylation of the enzyme by ATP. In the absence of Na+ and with 0.5 mM K+, optimal levels (1.0 nmol EP/mg of protein) were observed at 20-40% dimethylsulfoxide and pH 6.0 to 7.5. Addition of Na+ up to 5 mM has no effect on the phosphoenzyme level under these conditions. At 100 mM Na+ or higher the full capacity of enzyme phosphorylation (2.2 nmol EP/mg of protein) was reached. Phosphoenzyme formed from ATP in the absence of Na+ is an acylphosphate-type compound as shown by its hydroxylamine sensitivity. The phosphate radioactivity was incorporated into the alpha-subunit of the Na+, K(+)-ATPase as demonstrated by acid polyacrylamide gel electrophoresis followed by autoradiography.     

Phosphorylation from adenosine triphosphate of sodium- and potassium-activated adenosine triphosphatase. Comparison of enzyme-ligand complexes as precursors to the phosphoenzyme.

The relative effectiveness of the ligands Mg2+, Na+, and ATP in preparing sodium plus potassium ion transport adenosine triphosphatase for phosphorylation was studied by means of a rapid mixing apparatus. Addition of 2 mM MgC12, 120 mM NaC1, and 5 muM [gamma-32P]ATP simultaneously to the free enzyme gave an initial phosphorylation rate of about 0.3 mu mol-mg-1-min-1 at 25 degrees and pH7.4. Addition of Mg2+ to the enzyme beforehand, separately or in combination with Na+ or ATP, had little effect on the initial rate. Addition of Na+ only to the enzyme beforehand increased this rate 1.5- to 3-fold. Early addition of ATP 130 ms before Na+ plus Mg2+ increased the rate 6- to 7-fold. Early addition of Na+ plus ATP was most effective; it increased the rate about 10-fold. The data indicate that Na+ and ATP bind in a random order and that each ligand potentiates the effect of the other. The rate of dissociation of ATP from the enzyme was estimated by a chase of unlabeled ATP of variable duration. This rate was slowest in the presence of Mg2+ (k = 540 min-1), most rapid in the presence of Na+ (k = 2000 min-1), and intermediate (k = 1100 min-1) in the absence of metal ions. The effect of Na+ concentration on the rate of phosphorylation was estimated when Na+ with Mg2+ was added to the enzyme-ATP complex. The rate followed Michaelis-Menten kinetics with a maximum of 2.9 mu mol-mg-1 and a Km of 8 mM. The effect of Na+ concentration was also estimated on the increment in the rate of phosphorylation produced by the presence of Na+ with the enzyme-ATP complex beforehand. The increment followed the same kinetics with a maximum of 3.75 mu mol-mg-1-min-1 and a Km of 5.4 mM. In both cases estimation of the Hill coefficient failed to show cooperativity between binding sites for Na+. In contrast, the dependence of ouabain-sensitive ATPase activity on Na+ concentration in the absence of K+ indicated two sites for Na+ with apparent Km values of 0.16 and 8.1 mM, respectively.     

Kinetic and thermodynamic control of ATP synthesis by sarcoplasmic reticulum adenosinetriphosphatase

Several experimental parameters, critical to the analysis of ATP synthesis by sarcoplasmic reticulum ATPase, were determined experimentally. 1) The phosphorylated enzyme intermediate obtained with acetylphosphate in the presence of a Ca2+ gradient was shown to be entirely ADP sensitive but quite stable in the absence of added ADP. On the contrary, the phosphoenzyme obtained with ATP is unstable due to the ADP formed during the phosphoryl transfer reaction. For this reason, addition of ADP to [32P]phosphoenzyme obtained with [32P]acetylphosphate provides the simplest conditions for kinetic studies on [gamma-32P]ATP synthesis. 2) The dissociation rate constant of newly synthesized ATP (in the reverse direction of the ATPase cycle) was measured experimentally and found to be 16 s-1. This value agrees well with the dissociation rate constant determined for adenyl-5'-yl imidodiphosphate bound to this enzyme. 3) ATP synthesis observed in the absence of a Ca2+ gradient was shown to be a kinetic overshoot due to ligand-induced perturbation of a limited number of partial reactions and occurring before equilibration of the entire system. Most of the ATP formed under these conditions was subsequently hydrolyzed as the overall equilibrium was reached. 4) Based on these and other (previously characterized) parameters, satisfactory simulations of single and multiple cycle ATP synthesis, in the presence and in the absence of a Ca2+ gradient, were obtained.     

Gastric H/K-ATPase liberates two moles of Pi from one mole of phosphoenzyme formed from a high-affinity ATP binding site and one mole of enzyme-bound ATP at the low-affinity site during cross-talk between catalytic subunits

The maximum amount of acid-stable phosphoenzyme (E32P)/mol of alpha chain of pig gastric H/K-ATPase from [gamma-32P]ATP (K(1/2) = 0.5 microM) was found to be approximately 0.5, which was half of that formed from 32P(i) (K(1/2) = 0.22 mM). The maximum 32P binding for the enzyme during turnover in the presence of [gamma-32P]ATP or [alpha-32P]ATP was due to 0.5 mol of E32P + 0.5 mol of an acid-labile enzyme-bound [gamma-32P]ATP (EATP) or 0.5 mol of an acid-labile enzyme-bound [alpha-32P]ATP, respectively. The K(1/2) for EATP formation in both cases was 0.12 approximately 0.14 mM. The turnover number of the enzyme (i.e., the H+-ATPase activity/(EP + EATP)) was very close to the apparent rate constants for EP breakdown and P(i) liberation, both of which decreased with increasing concentrations of ATP. The ratio of the amount of P(i) liberated to that of EP that disappeared increased from 1 to approximately 2 with increasing concentrations of ATP (i.e., equal amounts of EP and EATP exist, both of which release phosphate in the presence of high concentrations of ATP). This represents the first direct evidence, for the case of a P-type ATPase, in which 2 mol of P(i) liberation occurs simultaneously from 1 mol of EP for half of the enzyme molecules and 1 mol of EATP for the other half during ATP hydrolysis. Each catalytic alpha chain is involved in cross-talk, thus maintaining half-site phosphorylation and half-site ATP binding which are induced by high- and low-affinity ATP binding, respectively, in the presence of Mg2+.     

Inactivation of (Na+ + K+)-ATPase by chromium(III) complexes of nucleotide triphosphates

(Na+ + K+)-ATPase from beef brain and pig kidney are slowly inactivated by chromium(III) complexes of nucleotide triphosphates in the absence of added univalent and divalent cations. The inactivation of (Na+ + K+)-ATPase activity was accompanied by a parallel decrease of the associated K+-activated p-nitrophenylphosphatase and a parallel loss of the capacity to form, Na+-dependently, a phosphointermediate from [gamma-32P]ATP. The kinetics of inactivation and of phosphorylation with [gamma-32P]CrATP and [alpha-32P]CrATP are consistent with the assumption of the formation of a dissociable complex of CrATP with the enzyme (E) followed by phosphorylation of the enzyme: formula: (see text). The dissociation constant of the CrATP complex of the pig kidney enzyme at 37 degrees C was 43 microM. The inactivation rate constant (k + 2 = 0.033 min-1) was in the range of the dissociation rate constant kd of ADP from the enzyme of 0.011 min-1. The phosphoenzyme was unreactive towards ADP as well as to K+. No hydrolysis of the native isolated phosphoenzyme was observed within 6 h under a variety of conditions, but high concentrations of Na+ reactivated it slowly. The capacity of the Cr-phosphoenzyme of 121 +/- 18 pmol/unit enzyme is identical with the capacity of the unmodified enzyme to form, Na+-dependently, a phosphointermediate. The Cr-phosphoenzyme behaved after acid denaturation like an acylphosphate towards hydroxylamine, but the native phosphoenzyme was not affected by it. ATP protected the enzyme against the inactivation by CrATP (dissociation constant of the enzyme ATP complex = 2.5 microM) as well as low concentrations of K+. CrATP was a competitive inhibitor of (Na+ + K+)-ATPase. It is concluded that CrATP is slowly hydrolyzed at the ATP-binding site of (Na+ + K+)-ATPase and inactivates the enzyme by forming an almost non-reactive phosphoprotein at the site otherwise needed for the Na+-dependent proteinkinase reaction as the phosphate acceptor site.     

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.     

Stimulation of adenosine triphosphatase activity of sarcoplasmic reticulum by adenylyl methylene diphosphate.

The effects of adenylyl methylene diphosphate (AMD), a non-hydrolyzable ATP analogue, were examined in sarcoplasmic reticulum vesicles isolated from rabbit skeletal muscle. The Ca2+-dependent APTase activity measured at 5 degrees C and pH 7.0 in 5.2 micrometer [gamma-32P]ATP and in the absence of added alkali metal salts was stimulated by added AMD. The steady state level of phosphoenzyme, however, was not decreased greatly by added AMP under these conditions. The hydrolysis of the phosphoenzyme formed at the steady state in the absence of added alkali metal salts was accelerated by added AMD to an extent that can account for the stimulation of the ATPase activity. At 5 degrees C and pH 7.0 the maximum stimulation of phosphoenzyme hydrolysis by AMD and the Km value for this ATP analogue were 4.3-fold and 40 micrometer, respectively. These results provide further support for our previous conclusion (Shigekawa, M., Dougherty, J.P. and Katz, A.M. (1978) J.Biol. Chem. 253, 1442--1450) that 2 classes of ATP site exist in the calcium pump ATPase in the absence of added alkali metal salts, one being the catalytic site and the other being the regulation site which activates the activity of the catalytic site.     

Reaction mechanism of Ca2+-dependent adenosine triphosphatase of sarcoplasmic reticulum. ATP hydrolysis with CaATP as a substrate and role of divalent cation

ATP hydrolysis with CaATP as a substrate was characterized at 0 degrees C and pH 7.0 using purified ATPase preparations of sarcoplasmic reticulum and compared with that with MgATP as a substrate. The maximal rate of enzyme phosphorylation and the Km value for the phosphorylation were 8 to 10 times less for CaATP than for MgATP. Each substrate appeared to act as a competitive inhibitor with respect to the other in enzyme phosphorylation. The phosphoenzyme formed from CaATP turned over slowly because the conversion rate of the ADP-sensitive (E1P) to ADP-insensitive (E2P) phosphoenzyme was very slow. E2Ps, formed from both CaATP and MgATP, were similar in that KCl, MgCl2, or ATP accelerated their decomposition. Their sensitivity to KCl and/or ATP was retained even after a long incubation with excess EDTA. When the enzyme had been phosphorylated from CaATP, calcium remained bound to the enzyme even in the presence of excess EDTA. The observed parallelism between the amount and behavior of the enzyme-bound calcium and those of E2P strongly suggests that 1 mol of E2P has 1 mol of tightly bound calcium. During steady state ATP hydrolysis with CaATP as a substrate, a significant amount of the enzyme-ATP complex accumulated as a reaction intermediate because of slow dissociation of CaATP from the CaATP-enzyme complex and slow enzyme phosphorylation from the CaATP-enzyme complex. These results indicate that Mg2+ is not essential for the turnover of the calcium pump ATPase. It was proposed that the metal component of the substrate basically determines affinity of the substrate to the enzyme and the catalytic mechanism of subsequent reaction steps.     

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.     

Phosphorylation of the calcium-transporting adenosinetriphosphatase by lanthanum ATP: rapid phosphoryl transfer following a rate-limiting conformational change

The calcium-transport ATPase (CaATPase) of rabbit sarcoplasmic reticulum preincubated with 0.02 mM Ca2+ (cE.Ca2) is phosphorylated upon the addition of 0.25 mM LaCl3 and 0.3 mM [gamma-32P]ATP with an observed rate constant of 6.5 s-1 (40 mM MOPS, pH 7.0, 100 mM KCl, 25 degrees C). La.ATP binds to cE.Ca2 with a rate constant of 5 X 10(6) M-1 s-1, while ATP, Ca2+, and La3+ dissociate from cE.Ca2.La.ATP at less than or equal to 1 s-1. The reaction of ADP with phosphoenzyme (EP) formed from La.ATP is biphasic. An initial rapid loss of EP is followed by a slower first-order disappearance, which proceeds to an equilibrium mixture of EP.ADP and nonphosphorylated enzyme with bound ATP. The fraction of EP that reacts in the burst (alpha) and the first-order rate constant for the slow phase (kb) increase proportionally with increasing concentrations of ADP to give maximum values of 0.34 and 65 s-1, respectively, at saturating ADP (KADPS = 0.22 mM). The burst represents rapid phosphoryl transfer and demonstrates that ATP synthesis and hydrolysis on the enzyme are fast. The phosphorylation of cE.Ca2 by La.ATP at 6.5 s-1 and the kinetics for the reaction of EP with ADP are consistent with a rate-limiting conformational change in both directions. The conformational change converts cE.Ca2.La.ATP to the form of the enzyme that is activated for phosphoryl transfer, aE.Ca2.La.ATP, at 6.5 s-1; this is much slower than the analogous conformational change at 220 s-1 with Mg2+ as the catalytic ion [Petithory & Jencks (1986) Biochemistry 25, 4493]. The rate constant for the conversion of aE.Ca2.La.ATP to cE.Ca2.La.ATP is 170 s-1. ATP does not dissociate measurably from aE.Ca2.La.ATP. Labeled EP formed from cE.Ca2 and La.ATP with leaky vesicles undergoes hydrolysis at 0.06 s-1. It is concluded that the reaction mechanism of the CaATPase is remarkably similar with Mg.ATP and La.ATP; however, the strong binding of La.ATP slows both the conformational change that is rate limiting for EP formation and the dissociation of La.ATP. An interaction between La3+ at the catalytic site and the calcium transport sites decreases the rate of calcium dissociation by greater than 60-fold. When cE-Ca2 is mixed with 0.3 mM ATP and 1.0 mM Cacl2, the phosphoenzyme is formed with an observed rate constant of 3 s-1. The phosphoenzyme formed from Ca.ATP reacts with 2.0 mM ADP and labeled ATP with a rate constant of 30 s-1; there may be a small burst (alpha less than or equal to 0.05).     

Intermediate phosphorylation reactions in the mechanism of ATP utilization by the copper ATPase (CopA) of Thermotoga maritima

Recombinant and purified Thermotoga maritima CopA sustains ATPase velocity of 1.78-2.73 micromol/mg/min in the presence of Cu+ (pH 6, 60 degrees C) and 0.03-0.08 micromol/mg/min in the absence of Cu+. High levels of enzyme phosphorylation are obtained by utilization of [gamma-32P]ATP in the absence of Cu+. This phosphoenzyme decays at a much slower rate than observed with Cu.E1 approximately P. In fact, the phosphoenzyme is reduced to much lower steady state levels upon addition of Cu+, due to rapid hydrolytic cleavage. Negligible ATPase turnover is sustained by CopA following deletion of its N-metal binding domain (DeltaNMBD) or mutation of NMBD cysteines (CXXC). Nevertheless, high levels of phosphoenzyme are obtained by utilization of [gamma-3)P]ATP by the DeltaNMBD and CXXC mutants, with no effect of Cu+ either on its formation or hydrolytic cleavage. Phosphoenzyme formation (E2P) can also be obtained by utilization of Pi, and this reaction is inhibited by Cu+ (E2 to E1 transition) even in the DeltaNMBD mutant, evidently due to Cu+ binding at a (transport) site other than the NMBD. E2P undergoes hydrolytic cleavage faster in DeltaNMBD and slower in CXXC mutant. We propose that Cu+ binding to the NMBD is required to produce an "active" conformation of CopA, whereby additional Cu+ bound to an alternate (transmembrane transport) site initiates faster cycles including formation of Cu.E1 approximately P, followed by the E1 approximately P to E2-P conformational transition and hydrolytic cleavage of phosphate. An H479Q mutation (analogous to one found in Wilson disease) renders CopA unable to utilize ATP, whereas phosphorylation by Pi is retained.     

Direct evidence for an ADP-sensitive phosphointermediate of (K+ + H+)-ATPase

Direct evidence for the occurrence of an ADP-sensitive phosphoenzyme of (K+ + H+)-ATPase, the proton-pumping system of the gastric parietal cell is presented. The enzyme is phosphorylated with 5 microM [gamma-32P]ATP in 50 mM imidazole-HCl (pH 7.0) and in the presence of 7-15 microM Mg2+. Addition of 5 mM ADP to this preparation greatly accelerates its hydrolysis. We have been able to establish this by stopping the phosphorylation with radioactive ATP, by adding 1 mM non-radioactive ATP, which leads to a slow monoexponential process of dephosphorylation of 32P-labeled enzyme. The relative proportion of the ADP-sensitive phosphoenzyme is 22% of the total phosphoenzyme. Values for the rate constants of breakdown and interconversion of the two phosphoenzyme forms have been determined.     

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.     

Kinetic evidence for two nucleotide binding sites on the CaATPase of sarcoplasmic reticulum.

The CaATPase of sarcoplasmic reticulum was reacted with [gamma-32P]ATP to form the covalent phosphoenzyme intermediate. Noncompetitive inhibition by reactive red-120 and chelation of calcium allowed us to monitor single-turnover kinetics of the phosphoenzyme reacting with water or added ADP at 0 degrees C. When ADP was added and the amount of product, [gamma-32P]ATP, formed was measured, we found that added cold ATP did not interfere with the phosphoenzyme reacting with ADP. We conclude that ATP cannot bind where ADP binds, the phosphorylated active site. This implies that when ATP at high concentrations causes an acceleration of phosphoenzyme hydrolysis, it must do so by binding to an allosteric site. Considering the monoexponential nature of product formation we observed, simple one-nucleotide-site models cannot account for the above result.     

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.