Effect of ADP on the rate of acetyl phosphate hydrolysis by the Ca2+-ATPase of sarcoplasmic reticulum

Hydrolysis of acetyl phosphate is inhibited by high concentrations of Pi and MgCl2, probably due to an increase in the steady-state level of phosphoenzyme formed from Pi in the medium. A dual effect of ADP during steady-state hydrolysis of acetyl phosphate was observed. ADP inhibited hydrolysis in the presence of 5 mM MgCl2 and no added Pi, whereas it stimulated hydrolysis when phosphoenzyme formation by Pi was favored by including 6 mM Pi and 20 mM MgCl2 in the assay medium. ATP inhibited acetyl phosphate hydrolysis in both of these assay media. When phosphoenzyme formation by Pi in the presence of acetyl phosphate was stimulated at Ca2+ concentrations sufficient to saturate the low-affinity Ca2+-binding sites, ADP stimulated acetyl phosphate hydrolysis and also promoted ATP synthesis by reversal of the catalytic cycle. The rate of ATP synthesis was dependent on ADP, Pi and Ca2+. Phosphoenzyme formation by Pi and MgCl2, whether in the absence of Ca2+ and acetyl phosphate, or during acetyl phosphate hydrolysis, was inhibited by ADP and ATP. These results suggest that ADP interacts with different intermediates of the catalytic cycle and that expression of inhibition or activation of acetyl phosphate hydrolysis depends on the steady-state level of phosphoenzyme formed by Pi.     

Rate of calcium release and ATP synthesis in sarcoplasmic reticulum vesicles

Sarcoplasmic reticulum vesicles can catalyze the synthesis of ATP coupled to the efflux of calcium. The rate of this reaction is much faster when the vesicles are loaded in a medium containing phosphate than when oxalate is the precipitating agent. Two components of ATP synthesis can be observed when vesicles loaded with calcium phosphate are used. In the millisecond range and when the loaded vesicles are phosphorylated by Pi, the addition of ADP leads to an initial burst of ATP synthesis and after 50 ms approximately 3.0 nmol of ATP/mg protein are synthesized. This burst is not inhibited by ATP and is enhanced by physiological concentrations of KCl. The slow component of ATP synthesis is inhibited by both ATP and 100 mM KCl. In the physiological pH range, betaine, a trimethylamine present in different tissues, increases the level of phosphoenzyme formed by Pi and enhances the amount of ATP synthesized during the first turn of the reversal of the calcium pump.     

Functional consequences of alterations to amino acids located in the hinge domain of the Ca(2+)-ATPase of sarcoplasmic reticulum.

Site-specific mutagenesis of the sarcoplasmic reticulum Ca(2+)-ATPase was used to investigate the functional roles of 18 amino acid residues located at or near the "hinge-domain," a highly conserved region of the cation-transporting ATPases. Mutation of Lys684 to arginine, alanine, histidine, and glutamine resulted in complete loss of calcium transport function and ATPase activity. For the Lys684----Ala, histidine, and glutamine mutants, this coincided with a loss of the ability to form a phosphorylated intermediate from ATP or Pi. The Lys684----Arg mutant retained the ability to phorphorylate from ATP with normal apparent affinity, demonstrating the importance of the positive charge. On the other hand, no phosphorylation was observed with Pi as substrate in this mutant. Examination of the partial reactions after phosphorylation from ATP in the Lys684----Arg mutant demonstrated a reduction of the rate of transformation of the ADP-sensitive phosphoenzyme intermediate (E1P) to the ADP-insensitive phosphoenzyme intermediate (E2P), which could account for the loss of transport function. Once accumulated, the E2P intermediate was able to decompose rapidly in the presence of K+ at neutral pH. These results may be interpreted in terms of a preferential destabilization of protein phosphate interactions in the E2P form of this mutant. The Asp703----Ala and Asn-Asp707----Ala-Ala mutants were completely inactive and unable to form phosphoenzyme intermediates from ATP or Pi. In these mutants as well as in the Lys684----Ala mutant, nucleotides were found to protect with normal affinity against intramolecular cross-linking induced with glutaraldehyde, indicating that the nucleotide binding site was intact. Mutation of Glu646, Glu647, Asp659, Asp660, Glu689, Asp695, Glu696, Glu715, and Glu732 to alanine did not affect the maximum rates of calcium transport and ATP hydrolysis or the apparent affinities for calcium and ATP. Mutation of the 2 highly conserved proline residues, Pro681 and Pro709, as well as Lys728, to alanine resulted in partially inhibited Ca(2+)-ATPase enzymes with retention of the ability to form a phosphoenzyme intermediate from ATP or Pi and with normal apparent affinities for ATP and calcium. The proline mutants retained the biphasic ATP concentration dependence of ATPase activity, characteristic of the wild-type, and therefore the partial inhibition of turnover could not be ascribed to a disruption of the low affinity modulatory ATP site.(ABSTRACT TRUNCATED AT 400 WORDS)     

Reaction mechanism of the calcium-transport ATPase in endoplasmic reticulum of rat liver. Demonstration of different reactive forms of the phosphorylated intermediate

A calcium-transport ATPase is inserted into the endoplasmic reticulum of rat liver. Catalysis of calcium translocation involves transient covalent binding of the terminal phosphate residue of ATP by the enzyme, resulting in the formation of an alkali- and hydroxylamine-labile phosphorylprotein intermediate. Both MgATP as well as CaATP can be utilized in the phosphorylation reaction which requires calcium as a cofactor. Magnesium accelerates the turnover of the phosphorylprotein intermediate. An ADP-reactive and ADP-unreactive state of the phosphoenzyme could be distinguished. In the ADP-reactive state with tightly bound calcium, the phosphoenzyme can transphosphorylate its phosphate residue to ADP, giving rise to synthesis of ATP. The ADP-reactive phosphoenzyme can be converted into an ADP-unreactive state by prolonged incubation with excess EGTA (ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid). It is suggested that this conversion is brought about by the removal of tightly bound calcium from the phosphoenzyme. A strong homology of the sequential reaction steps during calcium translocation by the calcium-transport ATPases in endoplasmic reticulum from rat liver and sarcoplasmic reticulum from skeletal muscle is suggested.     

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.     

Reversal of the sarcoplasmic reticulum ATPase cycle by substituting various cations for magnesium. Phosphorylation and ATP synthesis when Ca2+ replaces Mg2+

Reversal of the cycle of sarcoplasmic reticulum ATPase starts from ATPase phosphorylation by Pi, in the presence of Mg2+, and leads to ATP synthesis. We show here that ATP can also be synthesized when Ca2+ replaces Mg2+. In the absence of a calcium gradient and in the presence of dimethyl sulfoxide, ATPase phosphorylation from Pi and Ca2+ led to the formation of an unstable phosphoenzyme. This instability was due to a competition between the phosphorylation reaction induced by Pi and Ca2+ and the transition induced by Ca2+ binding to the transport sites, which led to a conformation that could not be phosphorylated from Pi. Dimethyl sulfoxide and low temperature stabilized the calcium phosphoenzyme, which under appropriate conditions, subsequently reacted with ADP to synthesize ATP. Substitution of Co2+, Mn2+, Cd2+, or Ni2+ for Mg2+ induced ATPase phosphorylation from Pi, giving phosphoenzymes of various stabilities. However, substitution of Ba2+, Sr2+, or Cr3+ produced no detectable phosphoenzymes, under the same experimental conditions. Our results show that ATPase phosphorylation from Pi, like its phosphorylation from ATP, does not have a strict specificity for magnesium.     

Functional consequences of alterations to amino acids located in the nucleotide binding domain of the Ca2(+)-ATPase of sarcoplasmic reticulum

Amino acids in three highly conserved segments of the Ca2(+)-ATPase. Asp-Pro-Pro-Arg604, Thr-Gly-Asp627, Thr-Gly-Asp703 as well as Asp707, have been proposed to participate in formation of the nucleotide binding site. We have tested this hypothesis by investigating the properties of mutants with alterations to amino acids within these segments. Most of the mutants were found to be defective in Ca2+ transport function. The inactive mutants could be separated into two classes on the basis of the kinetics of phosphoenzyme intermediate formation and decomposition. One group, Asp601----Asn, Pro603----Leu, Asp627----Glu, and Asp703----Asn, formed phosphoenzyme intermediates with ATP in the presence of Ca2+ and with inorganic phosphate only in the absence of Ca2+, indicating that both the high affinity Ca2+ binding sites and the nucleotide binding sites were intact. In each of these mutants, however, the ADP-sensitive phosphoenzyme intermediate (E1P) decayed to the ADP-insensitive phosphoenzyme intermediate very slowly, relative to the wild-type enzyme. Thus the inability of these mutants to transport Ca2+ was accounted for by an apparent block of the transport reaction at the E1P to E2P conformational transition. Another group, Asp601----Glu, Pro603----Gly, Asp707----Glu, and Asp707----Asn, did not form detectable phosphoenzyme intermediates from either ATP or Pi. Although we have demonstrated an effect on Ca2+ transport of mutations in each of the highly conserved regions predicted to be involved in ATP binding, we cannot yet define their roles in ATP-dependent Ca2+ transport.     

Polyphosphate kinase of Acinetobacter sp. strain ADP1: purification and characterization of the enzyme and its role during changes in extracellular phosphate levels.

Polyphosphate (polyP) is a ubiquitous biopolymer whose function and metabolism are incompletely understood. The polyphosphate kinase (PPK) of Acinetobacter sp. strain ADP1, an organism that accumulates large amounts of polyP, was purified to homogeneity and characterized. This enzyme, which adds the terminal phosphate from ATP to a growing chain of polyP, is a 79-kDa monomer. PPK is sensitive to magnesium concentrations, and optimum activity occurs in the presence of 3 mM MgCl(2). The optimum pH was between pH 7 and 8, and significant reductions in activity occurred at lower pH values. The greatest activity occurred at 40 degrees C. The half-saturation ATP concentration for PPK was 1 mM, and the maximum PPK activity was 28 nmol of polyP monomers per microg of protein per min. PPK was the primary, although not the sole, enzyme responsible for the production of polyP in Acinetobacter sp. strain ADP1. Under low-phosphate (P(i)) conditions, despite strong induction of the ppk gene, there was a decline in net polyP synthesis activity and there were near-zero levels of polyP in Acinetobacter sp. strain ADP1. Once excess phosphate was added to the P(i)-starved culture, both the polyP synthesis activity and the levels of polyP rose sharply. Increases in polyP-degrading activity, which appeared to be mainly due to a polyphosphatase and not to PPK working in reverse, were detected in cultures grown under low-P(i) conditions. This activity declined when phosphate was added.     

Eukaryote polyphosphate kinases: is the 'Kornberg' complex ubiquitous?

Polyphosphate (poly P) is a polymer of up to several hundred phosphate residues and is important to a variety of cell processes. The main poly P synthetic enzyme in many bacteria is poly P kinase 1 (PPK1), which until recently had been detected among eukaryotes in some protists only. There is now evidence for the presence in several other eukaryotes of PPK1 homologues and also a second bacteria-type enzyme, PPK2. The latest genome databases reveal that the 'Kornberg' enzyme complex of three actin-related proteins, termed DdPPK2 in Dictyostelium discoideum, might also be ubiquitous in eukaryotes. Owing to the intimate association of poly P synthesis with the formation of structural fibres, this ubiquity indicates a central role for this molecule in the evolution of eukaryotic cells.     

Functional role of "N" (nucleotide) and "P" (phosphorylation) domain interactions in the sarcoplasmic reticulum (SERCA) ATPase

Experimental perturbations of the nucleotide site in the N domain of the SR Ca2+ ATPase were produced by chemical derivatization of Lys492 or/and Lys515, mutation of Arg560 to Ala, or addition of inactive nucleotide analogue (TNP-AMP). Selective labeling of either Lys492 or Lys515 produces strong inhibition of ATPase activity and phosphoenzyme intermediate formation by utilization of ATP, while AcP utilization and reverse ATPase phosphorylation by Pi are much less affected. Cross-linking of the two residues with DIDS, however, drastically inhibits utilization of both ATP and AcP, as well as of formation of phosphoenzyme intermediate by utilization of ATP, or reverse phosphorylation by Pi. Mutation of Arg560 to Ala produces strong inhibition of ATPase activity and enzyme phosphorylation by ATP but has a much lower effect on enzyme phosphorylation by Pi. TNP-AMP increases the ATPase activity at low concentrations (0.1-0.3 microM), but inhibits ATP, AcP, and Pi utilization at higher concentration (1-10 microM). Cross-linking with DIDS and TNP-AMP binding inhibits formation of the transition state analogue with orthovanadate. It is concluded that in addition to the binding pocket delimited by Lys 492 and Lys515, Arg560 sustains an important and direct role in nucleotide substrate stabilization. Furthermore, the effects of DIDS and TNP-AMP suggest that approximation of N (nucleotide) and P (phosphorylation) domains is required not only for delivery of nucleotide substrate, but also to favor enzyme phosphorylation by nucleotide and nonnucleotide substrates, in the presence and in the absence of Ca2+. Domain separation is then enhanced by secondary nucleotide binding to the phosphoenzyme, thereby favoring its hydrolytic cleavage.     

Novel mechanisms of Escherichia coli succinyl-coenzyme A synthetase regulation.

Low concentrations of ADP are shown to increase the rate of phosphoenzyme formation of E. coli succinyl-coenzyme A (CoA) synthetase (SCS) without altering the fraction of phosphorylated enzyme. This is true when either ATP or succinyl-CoA and Pi are used to phosphorylate the enzyme. The stimulatory effect of ADP is not altered by sample dilution, is retained upon partial purification of the enzyme, and reflects the binding of ADP to a site other than the catalytic site. GDP also alters the phosphorylation of the E. coli SCS but does so primarily by enhancing the level of the phosphoenzyme and only when ATP is used as the phosphate donor. GDP appears to function by neutralizing the action of a specific inhibitory protein. This inhibitor of SCS allows for interconversion of succinate and succinyl-CoA in a manner dissociated from changes in ATP-ADP metabolism. These previously unidentified and varied mechanisms by which SCS is regulated focus attention on this enzyme as an important control point in determining the cell's potential to meet its metabolic demands.     

Mechanism of the calcium pump in the endoplasmic reticulum of liver: phosphoproteins as reaction intermediates

Microsomal fractions, highly enriched with endoplasmic reticulum of rat and human liver exhibit Ca2+ uptake catalyzed by a Ca2+-pumping ATPase. The mechanism of Ca2+-translocation involves: (i) reversible Ca2+-dependent formation of an acyl-phosphoenzyme intermediate (Mr 116,000 to 118,000) with bound Ca2+, which in the reversed reaction can transphosphorylate its Pi to ADP to re-synthesize ATP; (ii) reversible transition of the ADP-reactive phosphoenzyme into an isomer without bound Ca2+, not further reactive to ADP; (iii) hydrolytic cleavage, stimulated by Mg2+, K+, and ATP of the ADP-unreactive phosphoenzyme with liberation of Pi. By analogy to a mechanism proposed for the Ca2+ pump of sarcoplasmic reticulum, the translocation of Ca2+ to and dissociation from the inner side of the membrane is suggested to occur by a conformational change, coupled with a decrease in Ca2+-affinity of the phosphoenzyme during its transition into the ADP-unreactive isomer. With CaATP as the effective substrate the reactions proceed normally but at a considerably slower rate.     

Modulation of the binding characteristics of a fluorescent nucleotide derivative to the sarcoplasmic reticulum adenosinetriphosphatase

Trinitrophenyladenosine monophosphate (TNP-AMP) binding to the phosphorylated Ca2+-ATPase of sarcoplasmic reticulum results in manyfold higher fluorescence intensity and longer lifetimes of the nucleotide analogue, as compared to TNP-AMP binding to the nonphosphorylated enzyme. This is observed when the phosphoenzyme intermediate is formed either from ATP or from inorganic phosphate (Pi). An important question is whether the TNP-AMP fluorescence properties can also reflect the kinetically defined interconversions of different phosphoenzyme species during catalysis. We have approached this question by manipulating the phosphorylation conditions in a manner which is known to result in accumulation of different species of the phosphoenzyme, i.e., by variations in pH, substrates, and K+ and Ca2+ concentrations. Decreasing pH or increasing [K+] caused large decreases in fluorescence intensity at a given concentration of TNP-AMP under conditions of phosphorylation with either ATP or Pi. In contrast, low to high intravesicular Ca2+ concentrations had no effect on fluorescence during steady-state turnover. TNP-AMP titrations of the phosphorylated enzyme stabilized in different states revealed that H+ and K+ caused a shift in TNP-AMP binding affinity to the site responsible for high fluorescence enhancement, while maintaining approximately the same maximal fluorescence yield at saturation. The fluorescence lifetimes of TNP-AMP bound to phosphoenzyme did not change with variations in pH, [K+], and substrates. We conclude that the environment of that part of the TNP-AMP binding site which binds the trinitrophenyl moiety undergoes a change upon enzyme phosphorylation resulting in enhanced fluorescence yield; this change is invariant between different phosphoenzyme species.(ABSTRACT TRUNCATED AT 250 WORDS)     

Functional consequences of mutations in the beta-strand sector of the Ca2(+)-ATPase of sarcoplasmic reticulum

Kinetic studies of the phosphoenzyme intermediates of site-specific mutants were used to examine the role of Gly233 in the reaction mechanism of the sarcoplasmic reticulum Ca2(+)-ATPase. When this glycine residue, which is highly conserved among cation-transporting ATPases, was replaced by valine, arginine, or glutamic acid, a complete loss of the ability to pump Ca2+ was observed. The mutant enzymes were able to form an ADP-sensitive phosphoenzyme intermediate (E1P) by reaction with ATP in the presence of Ca2+, but this intermediate decayed to the ADP-insensitive form (E2P) very slowly, relative to the wild-type enzyme. The mutant phosphoenzyme intermediate remained ADP-sensitive, even when phosphorylation from ATP was performed under conditions which permitted accumulation of the ADP-insensitive phosphoenzyme intermediate in the wild type. The mutants were also defective in their ability to form the ADP-insensitive phosphoenzyme intermediate by phosphorylation from inorganic phosphate. In addition, they displayed a higher affinity for Ca2+ and a lower cooperativity in Ca2+ binding than did the wild-type enzyme, as measured through the phosphorylation reaction with ATP. These findings can be rationalized either in terms of a parallel shift of E1 to E2 and E1P to E2P conformational equilibria toward the E1 and E1P forms, respectively, or in terms of destabilization of the phosphoryl-protein interaction in the E2P form. The roles of 7 other residues located in the vicinity of Gly233 were also examined by mutation. Although the side chains of these residues are potential Ca2+ ligands, their replacement did not affect the Ca2+ affinity of the enzyme, suggesting the lack of a role of this region of the peptide in formation of Ca2(+)-binding sites.     

Autophosphorylation of rabbit skeletal muscle cyclic AMP-dependent protein kinase I catalytic subunit.

The catalytic subunit of rabbit skeletal muscle cyclic AMP-dependent protein kinase I can catalyze self-phosphorylation. The autophosphorylation reaction uses ATP as the phosphoryl donor, requires Mg2+, and is inhibited by polyarginine. Prior treatment of the catalytic subunit with Escherichia coli alkaline phosphatase in the presence of bovine serum albumin greatly enhances the autophosphorylation of the subunit. The protein-bound phosphate is stable in acid but labile in base. Incubation of the 32P-labeled phosphoenzyme with histones led neither to the phosphorylation of histones nor to a loss of radioactivity from the phosphoenzyme. The results suggest that the phosphoenzyme does not represent an intermediate of the phosphotransferase reaction.     

Solvent effects on substrate and phosphate interactions with the (Na+ + K+)-ATPase

(Na+ + K+)-ATPase activity of a dog kidney enzyme preparation was markedly inhibited by 10-30% (v/v) dimethyl sulfoxide (Me2SO) and ethylene glycol (Et(OH)2); moreover, Me2SO produced a pattern of uncompetitive inhibition toward ATP. However, K+-nitrophenylphosphatase activity was stimulated by 10-20% Me2SO and Et(OH)2 but was inhibited by 30-50%. Me2SO decreased the Km for this substrate but had little effect on the Vmax below 30% (at which concentration Vmax was then reduced). Me2SO also reduced the Ki for Pi and acetyl phosphate as competitors toward nitrophenyl phosphate but increased the Ki for ATP, CTP and 2-O-methylfluorescein phosphate as competitors. Me2SO inhibited K+-acetylphosphatase activity, although it also reduced the Km for that substrate. Finally, Me2SO increased the rate of enzyme inactivation by fluoride and beryllium. These observations are interpreted in terms of the E1P to E2P transition of the reaction sequence being associated with an increased hydrophobicity of the active site, and of Me2SO mimicking such effects by decreasing water activity: (i) primarily to stabilize the covalent E2P intermediate, through differential solvation of reactants and products, and thereby inhibiting the (Na+ + K+)-ATPase reaction and acting as a dead-end inhibitor to produce the pattern of uncompetitive inhibition; inhibiting the K+-acetylphosphatase reaction that also passes through an E2P intermediate; but not inhibiting (at lower Me2SO concentrations) the K+-nitrophenylphosphatase reaction that does not pass through such an intermediate; and (ii) secondarily to favor partitioning of Pi and non-nucleotide phosphates into the hydrophobic active site, thereby decreasing the Km for nitrophenyl phosphate and acetyl phosphate, the Ki for Pi and acetyl phosphate in the K+-nitrophenylphosphatase reaction, accelerating inactivation by fluoride and beryllium acting as phosphate analogs, and, at higher concentrations, inhibiting the K+-nitrophenylphosphatase reaction by stabilizing the non-covalent E2.P intermediate of that reaction. In addition, Me2SO may decrease binding at the adenine pocket of the low-affinity substrate site, represented as an increased Ki for ATP, CTP and 3-O-methylfluorescein phosphate.     

Rates of various reactions catalyzed by ATP synthase as related to the mechanism of ATP synthesis.

The forward and reverse rates of the overall reaction catalyzed by the ATP synthase in intact rat heart mitochondria, as measured with 32P, were compared with the rates of two partial steps, as measured with 18O. Such rates have been measured previously, but their relationship to one another has not been determined, nor have the partial reactions been measured in intact mitochondria. The partial steps measured were the rate of medium Pi formation from bound ATP (in state 4 this also equals the rate of medium Pi into bound ATP) and the rate of formation of bound ATP from bound Pi within the catalytic site. The rates of both partial reactions can be measured by 31P NMR analysis of the 18O distribution in Pi and ATP released from the enzyme during incubation of intact mitochondria with highly labeled [18O]Pi. Data were obtained in state 3 and 4 conditions with variation in substrate concentrations, temperature, and mitochondrial membrane electrical potential gradient (delta psi m). Although neither binding nor release of ATP is necessary for phosphate/H2O exchange, in state 4 the rate of incorporation of at least one water oxygen atom into phosphate is approximately twice the rate of the overall reaction rate under a variety of conditions. This can be explained if the release of Pi or ATP at one catalytic site does not occur, unless ATP or Pi is bound at another catalytic site. Such coupling provides strong support for the previously proposed alternating site mechanism. In state 3 slow reversal of ATP synthesis occurs within the mitochondrial matrix and can be detected as incorporation of water oxygen atoms into medium Pi even though medium [32P]ATP does not give rise to 32Pi in state 3. These data can be explained by lack of translocation of ATP from the medium to the mitochondrial matrix. The rate of bound ATP formation from bound Pi at catalytic sites was over twice the rate of the overall reaction in both states 4 and 3. The rate of reaction at the catalytic site is considerably less sensitive to the decrease in membrane potential and the concentration of medium ADP than is the rate of medium ATP formation. This supports the view that the active catalytic site is occluded and proceeds at a rapid rate which is relatively independent of delta psi m and of media substrates.     

ATP synthesis catalyzed by the purified erythrocyte Ca-ATPase in the absence of calcium gradients

The Ca2+-transporting ATPase of erythrocytes was isolated by calmodulin affinity chromatography. The backward reaction of the ATPase was investigated. The phosphorylation of the solubilized enzyme by Pi required Mg and was inhibited by Ca and vanadate in the micromolar concentration range. Significant amounts of phosphoenzyme could be obtained only in a medium containing high dimethyl sulfoxide concentrations (greater than 25%) in order to diminish water activity at the phosphorylation site. The phosphoenzyme formed in this way could not phosphorylate ADP. However, upon addition of Ca2+ ions and dilution of dimethyl sulfoxide in the phosphorylated preparation (water activity jump), a highly reactive phosphoenzyme species was obtained which could transfer phosphate in nearly stoichiometric amounts to ADP to form ATP.     

Phosphorylation and dephosphorylation reactions of the red beet plasma membrane ATPase studied in the transient state

The reaction mechanism of the solubilized red beet (Beta vulgaris L.) plasma membrane ATPase was studied with a rapid quenching apparatus. Using a dual-labeled substrate ([γ-³²P]ATP and [5′,8-³H]ATP), the presteady-state time course of phosphoenzyme formation, phosphate liberation and ADP liberation was examined. The time course for both phosphoenzyme formation and ADP liberation showed a rapid, initial rise while the timecourse for phosphate liberation showed an initial lag. This indicated that ADP was released with formation of the phosphoenzyme while phosphate was released with phosphoenzyme breakdown. Phosphoenzyme formation was Mg²⁺-dependent and preincubation of the enzyme with free ATP followed by the addition of Mg²⁺ increased the rate of phosphoenzyme formation 2.3-fold. This implied that phosphoenzyme formation could result from a slow reaction of ATP binding followed by a more rapid reaction of phosphate group transfer. Phosphoenzyme formation was accelerated as the pH was decreased, and the relationship between pH and the apparent first-order rate constants for phosphoenzyme formation suggested the role of a histidyl residue in this process. Transient kinetics of phosphoenzyme breakdown confirmed the presence of two phosphoenzyme forms, and the discharge of the ADP-sensitive form by ADP correlated with ATP synthesis. Potassium chloride increased the rate of phosphoenzyme turnover and shifted the steady-state distribution of phosphoenzyme forms. From these results, a minimal catalytic mechanism is proposed for the red beet plasma membrane ATPase, and rate constants for several reaction steps are estimated.