Mechanism of calcium-independent phosphorylation of sarcoplasmic reticulum ATPase by orthophosphat. Evidence of magnesium-phosphoprotein formation

An Investigation into the Relative Efficacy of High-Velocity Air-Fuel-Sprayed Hydroxyapatite Implants Based on the Crystallinity Index, Residual Stress, Wear, and In-Flight Powder Particle Behavior

Due to its resemblance to the bone, hydroxyapatite (HA) has been widely used for bioactive surface modification of orthopedic implants. However, it undergoes significant thermal decomposition and phase transformations at a high operating temperature, leading to premature implant failure. This investigation uses high-velocity air-fuel (HVAF) spray, an emerging low-temperature thermal spray technique, to deposit HA over the Ti-6Al-4V substrate. Coating characteristics, such as the crystallinity index and phase analysis, were measured using X-ray diffraction, Raman analysis, and Fourier transform infrared spectroscopy, residual stress using the sin2ψ method, and tribological performance by a fretting wear test. The coating retained an over 90% crystallinity index, a crystallite size of 41.04 nm, a compressive residual stress of -229 ± 34.5 MPa, and a wear rate of 1.532 × 10-3 mm3 N-1 m-1. Computational in-flight particle traits of HA particles (5 to 60 μm) were analyzed using computational fluid dynamics; it showed that 90% of particles were deposited at a 700 to 1000 m/s velocity and a 900 to 1450 K temperature with a 2.1 ms mean residence time. In-flight particle oxidation was minimized, and particle impact deformation was maximized, which caused severe plastic deformation, forming crystalline, compressive residual stressed coatings. The thermal decomposition model of low-temperature HVAF-sprayed HA particles helped to understand the implants' crystallinity index, residual stress, and tribological characteristics. Hence, this experimental and computational analysis shows that the HVAF process can be a promising candidate for biomedical applications for having strong and durable implants.

Inhibition of the intracellular Ca(2+) transporter SERCA (Sarco-Endoplasmic Reticulum Ca(2+)-ATPase) by the natural polyphenol epigallocatechin-3-gallate

The use of a microsomal preparation from skeletal muscle revealed that both Ca(2+) transport and Ca(2+)-dependent ATP hydrolysis linked to Sarco-Endoplasmic Reticulum Ca(2+)-ATPase are inhibited by epigallocatechin-3-gallate (EGCG). A half-maximal effect was achieved at approx. 12 μM. The presence of the galloyl group was essential for the inhibitory effect of the catechin. The relative inhibition of the Ca(2+)-ATPase activity decreased when the Ca(2+) concentration was raised but not when the ATP concentration was elevated. Data on the catalytic cycle indicated inhibition of maximal Ca(2+) binding and a decrease in Ca(2+) binding affinity when measured in the absence of ATP. Moreover, the addition of ATP to samples in the presence of EGCG and Ca(2+) led to an early increase in phosphoenzyme followed by a time-dependent decay that was faster when the drug concentration was raised. However, phosphorylation following the addition of ATP plus Ca(2+) led to a slow rate of phosphoenzyme accumulation that was also dependent on EGCG concentration. The results are consistent with retention of the transporter conformation in the Ca(2+)-free state, thus impeding Ca(2+) binding and therefore the subsequent steps when ATP is added to trigger the Ca(2+) transport process. Furthermore, phosphorylation by inorganic phosphate in the absence of Ca(2+) was partially inhibited by EGCG, suggesting alteration of the native Ca(2+)-free conformation at the catalytic site.

Evidence Calcium Pump Binds Magnesium before Inorganic Phosphate

Calcium pump-catalyzed (18)O exchange between inorganic phosphate and water was studied to test the hypothesis that all P-type pumps bind Mg(2+) before P(i) and validate utilization of the rate equation for ordered binding to interpret differences between site-directed mutants and wild-type enzyme. The results were remarkably similar to those obtained earlier with sodium pump (Kasho, V. N., Stengelin, M., Smirnova, I. N., and Faller, L. D. (1997) Biochemistry 36, 8045- 8052). The equation for ordered binding of Mg(2+) before P(i) fit the data best with only a slight chance (0.6%) of P(i) binding to apoenzyme. Therefore, P(i) is the substrate, and Mg(2+) is an obligatory cofactor. The intrinsic Mg(2+) dissociation constant from metalloenzyme (K(M) = 3.5 +/- 0.3 mm) was experimentally indistinguishable from the sodium pump value. However, the half-maximal concentration for P(i) binding to metalloenzyme ((K(p)(')=6.3+/-0.6 mM)) was significantly higher ( approximately 6-fold), and the probability of calcium pump forming phosphoenzyme from bound P(i) (P(c) = 0.04 +/- 0.03) was significantly lower ( approximately 6-fold) than for the sodium pump. From estimates of the rate constants for phosphorylation and dephosphorylation, the calcium pump appears to catalyze phosphoryl group transfer less efficiently than the sodium pump. Ordered binding of Mg(2+) before P(i) implies that both calcium pump and sodium pump form a ternary enzyme.metal.phosphate complex, consistent with molecular structures of other haloacid dehalogenase superfamily members that were crystallized with Mg(2+) and phosphate, or a phosphate analogue, bound.

Calcium dependence of Pi phosphorylation of sarcoplasmic reticulum Ca2+-ATPase at low water content: water dependence of the E2-->E1 conversion

Enzymes entrapped in reverse micelles can be studied in low-water environments that have the potential of restricting conformational mobility in specific steps of the reaction cycle. Sarcoplasmic reticulum Ca2+-ATPase was incorporated into a reverse-micelle system (TPT) composed of toluene, phospholipids, Triton X-100 and varying amounts of water (0.5-7%, v/v). Phosphorylation of the Ca2+-ATPase by ATP required the presence of both water and Ca2+ in the micelles. No phosphoenzyme (EP) was detected in the presence of EGTA. Phosphorylation by Pi (inorganic phosphate) in the absence of Ca2+ was observed at water content below that necessary for phosphorylation by ATP. In contrast to what is observed in a totally aqueous medium, EP formed by Pi was partially resistant to dephosphorylation by Ca2+. However, the addition of non-radioactive Pi to the EP already formed caused a rapid decrease in radiolabelled enzymes, as expected for the isotopic dilution, indicating the existence of an equilibrium (E+Pi<-->EP). Phosphorylation by Pi also occurred in TPT containing millimolar Ca2+ concentrations in a range of water concentrations (2-5% v/v). The substrates p-nitrophenyl phosphate, acetyl phosphate, ATP and GTP increased the EP level under these conditions. These results suggest that: (1) the rate of conversion of the ATPase conformer E2 into E1 is greatly reduced at low water content, so that E2-->E1 becomes the rate-limiting step of the catalytic cycle; and (2) in media of low water content, Pi can phosphorylate both E1Ca and E2. Thus, the effect of enzyme hydration is complex and involves changes in the phosphorylation reaction at the catalytic site, in the equilibrium between E2 and E1 conformers, and in their specificity for substrates.

Mutations of Arg198 in sarcoplasmic reticulum Ca2+-ATPase cause inhibition of hydrolysis of the phosphoenzyme intermediate formed from inorganic phosphate

Arg198 of sarcoplasmic reticulum Ca2+-ATPase was substituted with lysine, glutamine, glutamic acid, alanine, and isoleucine by site-directed mutagenesis. Kinetic analysis was performed with microsomal membranes isolated from COS-1 cells which were transfected with the mutated cDNAs. The rate of dephosphorylation of the ADP-insensitive phosphoenzyme was determined by first phosphorylating the Ca2+-ATPase with 32Pi and then diluting the sample with non-radioactive Pi. This rate was reduced substantially in the mutant R198Q, more strongly in the mutants R198A and R1981, and most strongly in the mutant R198E, but to a much lesser extent in R198K. The reduction in the rate of dephosphorylation was consistent with the observed decrease in the turnover rate of the Ca2+-ATPase accompanied by the steady-state accumulation of the ADP-insensitive phosphoenzyme formed from ATP. These results indicate that the positive charge and high hydrophilicity of Arg198 are critical for rapid hydrolysis of the ADP-insensitive phosphoenzyme.

Formation of the ADP-insensitive phosphoenzyme intermediate in the sarcoplasmic reticulum Ca2+-ATPase of which both Cys344 and Cys364 are modified by N-ethylmaleimide

Sarcoplasmic reticulum vesicles were pretreated with N-ethylmaleimide under the conditions in which both Cys344 and Cys364 (SHD) of the Ca2+-ATPase are selectively modified. Effects of the modification on the transition of the phosphoenzyme intermediate (EP) from ADP-sensitive form to ADP-insensitive form and on the formation of ADP-insensitive EP from Pi were examined without added K+. At pH 7.0-8.0 in totally aqueous media, the EP transition and the EP formation from Pi were almost completely inhibited by the SHD modification. The formation of ADP-insensitive EP from ATP and from Pi in the SHD-modified enzyme occurred to some extent at pH 6.0-6.5 and were greatly increased by addition of dimethyl sulfoxide at pH 6. 0-8.0. The inhibition by the SHD modification of the EP formation from Pi in the absence of dimethyl sulfoxide was attributed to a decrease in the equilibrium constant for the EP formation from the enzyme-Pi-Mg complex. When 40% (v/v) dimethyl sulfoxide was present, almost all the phosphorylation sites in the SHD-modified enzyme were phosphorylated with ATP at pH 6.0 or with Pi at pH 6.0-7.0, and all the EP formed was ADP-insensitive. These results lead to the possibility that the previously reported exclusion of water from the catalytic site upon the EP transition and upon the EP formation from the enzyme-Pi-Mg complex is inhibited by the SHD modification. The present study has revealed the conditions in which the enzyme is released from the inhibition by this modification. The modification of SHD, which brackets the phosphorylation site (Asp351), may provide a useful tool for the analysis of conformational changes at the phosphorylation site occurring in the catalytic cycle.

Modification of histidine 5 in sarcoplasmic reticulum Ca2+-ATPase by diethyl pyrocarbonate causes strong inhibition of formation of the phosphoenzyme intermediate from inorganic phosphate

Sarcoplasmic reticulum vesicles were modified with diethyl pyrocarbonate (DEPC), a histidine-modifying reagent. Phosphoenzyme formation from Pi in the Ca2+-ATPase (reversal of hydrolysis of the phosphoenzyme intermediate) was almost completely inhibited by this modification. Tight binding of F- and Mg2+ and high affinity binding of vanadate in the presence of Mg2+, both of which produce transition state analogs for phosphoenzyme formation from the magnesium-enzyme-phosphate complex, were also inhibited. Formation of the phosphoenzyme from acetyl phosphate in the forward reaction was only weakly inhibited, but hydrolysis of the phosphoenzyme was strongly inhibited. The enzyme was protected by tight binding of F- and Mg2+ or by high affinity binding of vanadate in the presence of Mg2+ against the DEPC-induced inhibition of phosphoenzyme formation from Pi. The enzyme was also protected by tight binding of F- and Mg2+ against the DEPC-induced inhibition of phosphoenzyme hydrolysis. Peptide mapping of the tryptic digests, detection of peptides containing DEPC-modified histidine by UV absorption at 240 nm, amino acid analysis, sequencing, and mass spectrometry showed that His-5 was a single major residue protected by the above transition state analogs against the modification with DEPC. These results indicate that modification of His-5 with DEPC is responsible for the DEPC-induced inhibition of phosphoenzyme formation from Pi and of phosphoenzyme hydrolysis and suggest that His-5 is located in or very close to the catalytic site in the transition state for phosphoenzyme formation from the magnesium-enzyme-phosphate complex and is likely involved in the catalytic process of this reaction step.

Modification of arginine-198 in sarcoplasmic reticulum Ca2+-ATPase by 1,2-cyclohexanedione causes inhibition of formation of the phosphoenzyme intermediate from inorganic phosphate

Sarcoplasmic reticulum vesicles were modified with 1,2-cyclohexanedione (CHD), a specific arginine-modifying reagent, in sodium borate (pH 8.0 or 8.8). Phosphoenzyme formation from Pi in the Ca2+-ATPase (reversal of hydrolysis of the phosphoenzyme intermediate) was almost completely inhibited by the modification with CHD. Tight binding of F- and Mg2+ and high affinity binding of vanadate in the presence of Mg2+, either of which produces a transition state analog for phosphoenzyme formation from the magnesium-enzyme-phosphate complex, were also markedly inhibited. In contrast, phosphoenzyme formation from acetyl phosphate in the forward reaction was unaffected. The enzyme was appreciably protected by tight binding of F- and Mg2+ or by high affinity binding of vanadate in the presence of Mg2+, but not by the presence of 20 mM MgCl2 alone or 150 mM Pi alone, against the CHD-induced inhibition of phosphoenzyme formation from Pi. Peptide mapping of the tryptic digests, detection of peptides containing CHD-modified arginyl residues with Girard's reagent T, sequencing, and mass spectrometry showed that Arg-198 was a single major residue protected by tight binding of F- and Mg2+ against the modification with CHD. These results indicate that modification of Arg-198 with CHD is responsible for at least a part (the portion reduced by the transition state analogs) of the CHD-induced inhibition of phosphoenzyme formation from Pi and suggest that Arg-198 is located in or close to the catalytic site in the transition state for phosphoenzyme formation from the magnesium-enzyme-phosphate complex.

A proposal for the Mg2+ binding site of P-type ion motive ATPases and the mechanism of phosphoryl group transfer

Mutations of D586 in the DPPR sequence of sodium pump decrease the enzyme's affinity for inorganic phosphate [Farley R. A., Heart, E., Kabalin, M., Putnam, D., Wang, K., Kasho, V. N., and Faller, L. D. (1997) Biochemistry 36, 941-951]. Therefore, it was proposed that D586 coordinates the Mg2+ required for catalytic activity. This hypothesis is tested (1) by determining the substrate for catalysis of 18O exchange between inorganic phosphate and water and (2) by comparing conserved amino acid sequences in P-type pumps with the primary structures of enzymes of known tertiary structure that catalyze phosphoryl group transfer. From the isotope exchange data, it is concluded that the Mg2+-dependent and Na+- and K+-stimulated ATPase binds Mg2+ before inorganic phosphate. Sequence homology is demonstrated between the conserved DPPR and MV(I,L)TGD sequences of P-type pumps and two conserved adenylate kinase sequences that coordinate Mg2+ and/or bind nucleotide in the crystal structure of the yeast enzyme. A model for the Mg2+ site of P-type pumps and the mechanism of phosphoryl group transfer is proposed and tested by demonstrating that the conserved sequences are also structurally homologous.

Effect of haloperidol on the sarcoplasmic reticulum Ca-dependent adenosine triphosphatase

Several effects of the neuroleptic agent haloperidol on the sarcoplasmic reticulum (SR) Ca-dependent adenosine triphosphatase (Ca-ATPase) and Ca transport are described. Haloperidol inhibits the Ca-ATPase activity in the presence of calcimycin. The effect depends on the conditions of preexposure of the membranes to the drug: the inhibition increases with the preincubation time; Ca and Mg protect the enzyme against the effect of the drug. The inhibitory effect of haloperidol decreases upon increasing [Ca2+], at constant [Mg], and disappears at 20 mM [Mg] for any [Ca2+], and at 0.5 mM [Ca2+] for any [Mg2+]. Haloperidol also inhibits phosphorylation of the enzyme by Pi, and ATP-dependent Ca2+ uptake, in both cases with apparent Ki = 0.10-0.15 mM, and increases the rate of Ca efflux from preloaded vesicles in this concentration range. The results suggest that haloperidol interacts with the catalytic site, interfering with the effect of the divalent catalytic cation, but not at other steps of the enzymatic cycle, where Mg2+ and Ca2+ are also activators. They are consistent with a reaction model where haloperidol interacts with the E2 conformers of the enzyme, with lower affinity for the phosphoenzyme than for the dephospho species. The inhibition of Ca uptake by SR vesicles is ascribed to an increased Ca2+ permeability rather than to the inhibition of the Ca-ATPase, which requires higher concentrations of the drug.

Manganese as a cosubstrate for the phosphorylation of the sarcoplasmic reticulum Ca-dependent adenosine triphosphatase with orthophosphate

The phosphorylation of the sarcoplasmic reticulum Ca-ATPase (EC 3.6.1.38) with P(i) was characterized using Mn as a Mg analogue. Steady state and transient fluorescence and radioisotopic techniques were used; the affinities of Mn and P(i) for the enzyme and the rate constants of the phosphorylation and dephosphorylation reactions were determined, under several conditions. The reactions were carried out at pH 5.5 to minimize the binding of contaminant Ca to the transport sites, thus avoiding the use of Ca chelators. The apparent affinity of Mn binding at low [Mn] is larger in the absence of P(i) (35 microM) than in the presence of saturating P(i) (70 microM). On the contrary, the apparent affinity of Mn for the formation of the phosphoenzyme increases, from 1.5 mM to 0.15 mM, upon increasing [P(i)] in the millimolar range. The apparent affinty of P(i) for the formation of the phosphoenzyme also increases, from 2.2 mM to 0.2 mM, upon increasing [Mn] in the millimolar range. The equilibrium of the phosphoenzyme with the noncovalent Mn.P(i). Enzyme complex favors the covalent species. The simulation of a reaction model including the random binding of 2 Mn and I P(i) per mol of ATPase and a noncovalent complex in equilibrium with the phosphoenzyme, using a set of equilibrium constants deduced from the results, agree with the experimental data.

The binding of ATP and Mg2+ to the calcium adenosinetriphosphatase of sarcoplasmic reticulum follows a random mechanism

The enzyme form of the calcium adenosinetriphosphatase of sarcoplasmic reticulum (CaATPase) that is stable in the presence of calcium, cE.Ca2, has a binding site for the catalytic Mg2+ ion with a dissociation constant of 0.94 +/- 0.15 mM at 25 degrees C, pH 7.0, and 100 mM KCl. This is approximately 10 times smaller than that reported for the free enzyme, E, (8.8 mM) under similar conditions [Punzengruber, C., Prager, R., Kolassa, N., Winkler, F., & Suko, J. (1978) Eur. J. Biochem. 92, 349-359]. This difference shows that the sites for the catalytic and the transported ions interact in the absence of ATP. The addition of ATP and EDTA to enzyme that had been incubated with Ca2+ and Mg2+ resulted in the formation of 61% phosphoenzyme. The addition of unlabeled ATP and Mg2+ to enzyme that had been incubated with 3.5 microM free Ca2+ and labeled ATP gave 39% labeled phosphoenzyme. This shows that the binding of ATP and Mg2+ to cE.Ca2 follows a random mechanism. The rate constants for dissociation of ATP and Mg2+ from cE.Ca2.ATP.Mg are different: kdiss(ATP) = 120 s-1 and kdiss(Mg2+) = 60 s-1. This shows that Mg2+ and ATP can bind and dissociate independently; they do not have to associate or dissociate from cE as a Mg.ATP complex. Calcium-free enzyme binds metal-free ATP at the active site with a dissociation constant of 44 +/- 4 microM, kdiss = 130 +/- 7 s-1, and a calculated association rate constant of 3 x 10(6) M-1 s-1. Calcium-free enzyme that was incubated with [gamma-32P]ATP gave 38% labeled phosphoenzyme when chased with unlabeled ATP, Mg2+, and Ca2+. An increase of the Mg2+ concentration did not increase the amount of E32P formed. This shows that the binding of Mg2+ and ATP to free E also follows a random mechanism. The Mg2+ ion is not buried under ATP, and ATP is not under a Mg2+ ion. Incubation of free E with Mg2+ and ATP causes a conformational change that activates the enzyme for phosphorylation and decreases the rate constant for the dissociation of ATP from kdiss = 120 s-1 to kdiss = 47 s-1.

Quasi-irreversible inactivation of the sarcoplasmic reticulum Ca(2+)-ATPase by simultaneous tight binding of magnesium and fluoride to the catalytic site

The sarcoplasmic reticulum Ca(2+)-ATPase was inactivated quasi-irreversibly by the treatment with KF in the presence of Mg2+ and absence of Ca2+. This inactivation was Mg(2+)-dependent, and prevented by high-affinity Ca2+ binding. The enzyme was completely protected by ATP against the inactivation with an affinity consistent with that of the catalytic site for ATP. The affinity for Mg2+ in this inactivation was in agreement with that for Mg2+ in phosphorylation of the enzyme with Pi. Mg.ATP did not bind to the inactivated enzyme, whereas metal-free ATP did bind to it with a high affinity. These findings suggest that the Mg2+ binding sub-site in the catalytic site of the inactivated enzyme is occupied by tightly-bound Mg2+. The enzyme was completely protected by Pi against the inactivation with an affinity consistent with that of the catalytic site for Pi. The inactivated enzyme showed neither phosphorylation with Pi nor high-affinity vanadate binding. These findings suggest that the phosphorylation site of the inactivated enzyme is occupied by tightly-bound F-. The contents of tightly-bound Mg2+ and F- in the inactivated enzyme were determined after unbound Mg2+ and F- were removed by gel filtration. 2.3 mol of Mg2+ and 3.7 mol of F- per mol of phosphorylation sites were tightly bound to the enzyme. The tight binding of these ligands depended on the presence of each other, and was completely prevented by high-affinity Ca2+ binding. Linear relationships were found between the contents of the tightly-bound ligands and the extent of the enzyme inactivation. The tightly-bound Mg2+ and F- were entirely released by low-affinity Ca2+ binding, and correspondingly the ATPase activity was restored. It is concluded that the observed enzyme inactivation is caused by simultaneous tight binding of Mg2+ and F- to the catalytic site.

The influence of Mg2+ on anion binding to sarcoplasmic reticulum membranes as detected by 35Cl-NMR

35Cl-NMR spectroscopy has been used to study the competition between anions, including nucleotides, on skeletal muscle sarcoplasmic reticulum membranes. Different chloride binding sites can be distinguished according to their Mg2+ sensitivity. Phosphate binding is enhanced by Mg2+ whereas the anion transport inhibitor pyridoxalphosphate-6-azophenyl-2'-sulfonic acid (PPAPS) binding is not. The affinity of the enzyme for the Mg-adenylyl imidodiphosphate (MgAMP-PNP) complex is decreased whereas that for MgATP is increased. Three sets of binding sites can be discriminated from which chloride is displaced by different anions with varying efficiency. High affinity binding of AMP-PNP and PPAPS occurs at the same site, that can also be occupied by phosphate. Low-affinity binding of PPAPS and AMP-PNP also coincides, but in a site where phosphate binding is negligible. ATP and ADP bind to both sites. In the presence of Mg2+ a third anion binding site can be occupied by phosphate but neither by AMP-PNP nor PPAPS.

Direct demonstration of an acid-labile phosphoenzyme in the cycle of the sarcoplasmic reticulum Ca2(+)-dependent adenosinetriphosphatase

The Ca2(+)-dependent adenosinetriphosphatase (Ca2(+)-ATPase) from the sarcoplasmic reticulum (SR) of rat skeletal muscles is phosphorylated by inorganic phosphate (Pi) in the absence of Ca2+. The reaction can be described by the following simplified scheme: [formula: see text] where E-P is a covalent, acid-stable and ADP-insensitive phosphoenzyme, and E.Pi is a noncovalent and acid-labile complex. The reaction is Mg2(+)-dependent. Membrane fragments deposited on Millipore filters were successively perfused with two solutions, at constant flow. The effluent samples were analyzed. The perfused solutions were Ca2+ free and always contained 40% dimethylsulfoxide (DMSO), plus other reactants. Following the successive perfusion of solutions without and with [32P]Pi, 32P binding is only detected in the presence of Mg2+, indicating the formation of the phosphoenzymes (E.Pi and E-P). Following perfusions of the phosphoenzymes with 5% trichloroacetic acid, 32P release indicates the amount of the acid-labile moiety (E.Pi). After phosphorylations, the filters were washed with acid and unlabeled Pi, and the remaining radioactivity was measured to evaluate the acid-stable phosphoenzyme (E-P). The acid-labile and acid-stable phosphoenzymes amounted, respectively, 0.72 +/- 0.12, and 1.48 +/- 0.10 nmol of Pi/mg of protein ( +/- S.E., n = 5), after phosphorylations with 20 microM Pi. The results indicate: (1) The method allowed the evaluation of the acid-labile intermediate of the SR Ca2(+)-ATPase cycle. Keq = k2/k-2), in the above scheme, approaches 2.0. (2) The substrate of the phosphorylation reaction, in the presence of DMSO, is likely to be the Mg.Pi complex, since Mg2+ is necessary for step 1 in the above scheme.

Interaction of magnesium and inorganic phosphate with calcium-deprived sarcoplasmic reticulum adenosinetriphosphatase as reflected by organic solvent induced perturbation

The mechanism of sarcoplasmic reticulum (SR) ATPase Mg2+-dependent phosphorylation from Pi was investigated in the presence of 15% v/v dimethyl sulfoxide at pH 6, 20 degrees C, and in the absence of potassium. Measurements of intrinsic fluorescence changes and of 32P-labeled phosphoprotein (*E-P) were in agreement, both at equilibrium and in transient situations. We found that the amount of phosphoenzyme present and its rate of formation depended solely on the concentration of the (Mg X Pi) complex. Up to 6 nmol of phosphate/mg of protein was covalently bound to the enzyme, implying almost complete phosphorylation. Oxygen exchange experiments were also performed in order to allow calculation of the absolute rate constant of *E-P hydrolysis to the noncovalent complex (0.8-1.0 s-1), which differs from the observed rate of enzyme dephosphorylation (0.3-0.5 s-1); in addition, they allowed calculation of the bimolecular rate constant of substrate binding (2-2.4 M-1 s-1). The results demonstrate that in the presence of dimethyl sulfoxide, phosphorylation occurs by the following simple mechanism: relatively slow binding of the neutral substrate (Mg X Pi), with poor affinity, followed by a thermodynamically favorable formation of the covalent bond between phosphate and the possibly hydrophobic active site. The interaction between magnesium and calcium-deprived SR vesicles was studied in the presence of 0-20% v/v dimethyl sulfoxide (or 0-30% v/v glycerol) at pH 7 and 20 degrees C. The presence of either solvent led to the disappearance of the two typical pH-dependent effects we previously characterized for magnesium: loss of the Mg2+-induced spectral shift of tryptophan fluorescence emission and loss of the biphasic pattern displayed by the intrinsic fluorescence rise after addition of calcium to Ca2+-deprived Mg2+-preincubated vesicles. In the absence of solvent, the interaction of magnesium with the calcium-deprived ATPase was also characterized from the point of view of phosphoenzyme formation from ATP or Pi at pH 7 in the absence of potassium: we found that calcium-independent phosphorylation was slower when phosphate was added to SR vesicles preincubated with magnesium that when magnesium was added to vesicles preincubated with phosphate, suggesting that preincubation with magnesium had depleted the phosphate-reactive conformation of the ATPase. A simple reaction scheme for phosphoenzyme formation is described: it implies that the (Mg X Pi) complex is a substrate for this reaction, whereas the Mg2+ itself acts as a pH-dependent, dimethyl sulfoxide sensitive inhibitor of full enzyme phosphorylation.(ABSTRACT TRUNCATED AT 400 WORDS)

Formation of magnesium-phosphoenzyme and magnesium-calcium-phosphoenzyme in the phosphorylation of adenosine triphosphatase by orthophosphate in sarcoplasmic reticulum. Models of a reaction sequence

The aim of the present study was to test simple reaction sequences which describe calcium-independent plus calcium-dependent phosphorylation of sarcoplasmic reticulum transport. ATPase by orthophosphate including the function of magnesium in phosphoenzyme formation. The reaction schemes considered were based on the reaction sequence for calcium-independent phosphorylation proposed previously; namely that the transport enzyme (E) forms a ternary complex (Mg . E . Pi), by random binding of free magnesium and free orthophosphate, which is in equilibrium with the magnesium-phosphoenzyme (Mg . E-P). Phosphorylation, performed at pH 7.0 20 degrees C and a constant free orthophosphate concentration using sarcoplasmic reticulum vesicles either unloaded or loaded passively with calcium in the presence of 5 mM or 40 mM CaCl2, resulted in a gradual decrease in the apparent magnesium half-saturation constant and an increase in maximum phosphoprotein formation with increasing calcium loads. When phosphorylation of sarcoplasmic reticulum vesicles preloaded in the presence of 5 mM CaCl2 was performed at a constant free magnesium concentration, a decrease in the apparent orthophosphate half-saturation constant and an increase in maximum phosphoprotein formation was observed as compared with vesicles from which calcium inside has been removed by ionophore X-537A plus EGTA treatment; however, both parameters remained unchanged by increasing free magnesium from 20 mM to 30 mM. When phosphorylation of sarcoplasmic reticulum vesicles passively loaded with calcium in the presence of 40 mM CaCl2, at which the saturation of the low-affinity calcium binding sites of the ATPase is presumably near maximum, was performed at increasing concentrations of free orthophosphate, there was a parallel shift of phosphoprotein formation as a function of free magnesium and vice versa, with no change in the maximum phosphoenzyme formation. Comparison of the experimental data with the pattern of phosphoprotein formation predicted from model equations for various theoretical possible reaction sequences suggests that phosphoenzyme formation from orthophosphate possesses the following features. Firstly, calcium present at the inside of the sarcoplasmic reticulum membrane binds to the free enzyme and in sequential order to E . Mg . Pi or Mg . E-P or to both, but neither to E. Mg nor to E . Pi. Secondly, calcium-independent and calcium-dependent phosphoproteins are magnesium-phosphoenzymes. Calcium-dependent phosphoenzyme is a magnesium-calcium-enzyme phosphate complex with 1 magnesium, 2 calciums and 1 orthophosphate (the last covalently) bound to the enzyme [Mg . E-P . (Cai)2], and not a 'calcium-phosphoprotein' without bound magnesium.

Occlusion of divalent cations in the phosphorylated calcium pump of sarcoplasmic reticulum

The calcium pump of sarcoplasmic reticulum possesses high-affinity calcium-binding and ATP-binding sites. At 0 degrees C pH 6.8 and in the absence of calcium, about 3.5 nmol/mg of high-affinity ATP-binding sites are titrated with a dissociation constant, Kd, of 5 microM. In the presence of Ca2+, ATP phosphorylates the enzyme at a much lower concentration: K 1/2 = 100 nM. In the absence of ATP the calcium ions reversibly bind to the high-affinity calcium sites (6.5 nmol/mg); however the following is shown in this paper. 1. Phosphorylation of the enzyme in the presence of calcium leads to the immediate occlusion of the calcium ions bound to the high-affinity sites. 2. Two moles of calcium are occluded per mole of phosphoenzyme formed. 3. Occlusion can be reversed by ADP. 4. Transport is a slower process which occurs in the presence of Mg2+ at the same rate as the spontaneous decay of the phosphoenzyme. Experiments performed in the absence of magnesium reveal another divalent cation binding site which is probably directly involved in ATP and Pi binding. The nature of the cation bound to this site determines the stability and ADP-sensitivity of the phosphoenzyme.