Calorimetric studies of ligand-induced modulation of calcium adenosine 5'-triphosphatase from sarcoplasmic reticulum

Energy turnover for Ca2+ cycling in skeletal muscle

The majority of energy consumed by contracting muscle can be accounted for by two ATP-dependent processes, cross-bridge cycling and Ca(2+) cycling. The energy for Ca(2+) cycling is necessary for contraction but is an overhead cost, energy that cannot be converted into mechanical work. Measurement of the energy used for Ca(2+) cycling also provides a means of determining the total Ca(2+) released from the sarcoplasmic reticulum into the sarcoplasm during a contraction. To make such a measurement requires a method to selectively inhibit cross-bridge cycling without altering Ca(2+) cycling. In this review, we provide a critical analysis of the methods used to partition skeletal muscle energy consumption between cross-bridge and non-cross-bridge processes and present a summary of data for a wide range of skeletal muscles. It is striking that the cost of Ca(2+) cycling is almost the same, 30-40% of the total cost of isometric contraction, for most muscles studied despite differences in muscle contractile properties, experimental conditions, techniques used to measure energy cost and to partition energy use and in absolute rates of energy use. This fraction increases with temperature for amphibian or fish muscle. Fewer data are available for mammalian muscle but most values are similar to those for amphibian muscle. For mammalian muscles there are no obvious effects of animal size, muscle fibre type or temperature.

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.

The use of microcalorimetry to measure thermodynamic parameters of the binding of ligands to insulin

Flow microcalorimetry was used to measure the free energies, enthalpies, and entropies of interactions between the hormone insulin and small ligand molecules or ions. Measurable amounts of heat were obtained for binding of four phenolic preservative molecules--phenol, meta-cresol, resorcinol, and methylparaben--to both two-zinc and zinc-free insulin and for binding of zinc ions to zinc-free insulin. All of the reactions were spontaneous, but the phenolic binding was driven by enthalpy, while that of zinc was entropy-driven. A combination of van der Waals interactions, hydrophobic effects, and protein conformational changes appeared to be involved in binding of the phenolic ligands. Zinc ions displayed two types of binding to insulin, both involving ion-dipole interactions.

Evidence from 18O exchange measurements for steps involving a weak acid and a slow chemical transformation in the mechanism of phosphorylation of the gastric H+, K+-ATPase by inorganic phosphate

Phosphorylation of the gastric H,K-ATPase by Pi has been studied by measuring the P18Oj16O4-j distribution as a function of time at different H+, K+, and [18O]Pi concentrations. The advantage of isotope exchange measurements is that the P18Oj16O4-j distribution depends on the relative rates of HOH loss to form the phosphoenzyme intermediate and Pi dissociation from the enzyme. Therefore, 18O exchange is a sensitive probe of mechanism. K+ increases the exchange rate (v(ex] but does not affect the partition coefficient (Pc) that determines the P18Oj16O4-j distribution. Conversely, H+ inhibits exchange. A single Pc describes the data at every pH, but the value increases from 0.04 at pH 8 to 0.64 at pH 5.5. Vex depends hyperbolically on [Pi]0. Km for Pi does not depend on pH, and Pc does not depend on [Pi]0. Individual rate constants in the phosphorylation mechanism are estimated. Formation of the E.Pi complex that looses HOH is 1-2 orders of magnitude slower at pH 5.5 than at pH 8 and is not diffusion controlled. The observed change in Pc with pH is compatible with catalysis occurring by a different mechanism when a group with pKa = 7.2 is protonated. Slower than diffusion-controlled formation of the E.Pi complex that splits out HOH is evidence for a relatively slow, unimolecular chemical transformation involving an additional intermediate in the phosphorylation mechanism, such as a protein conformational change.

Magnesium and cell proliferation

Although studies in mammalian cells and yeast suggest that Mg2+ plays an important role in cell growth and hormone response, intracellular roles of Mg2+ are poorly understood. Thus, we are developing methods to study Mg2+ regulation of growth and hormonal response. Preliminary data using cell-permeable Mg2+ indicators based on tropolone suggest the feasibility of the dynamic and selective determination of intracellular free Mg2+ concentration. "Mg2+-deficient" cell lines have also been developed. Murine S49 lymphoma cells in normal 0.8 mM Mg2+ medium double in 17 hours, but die when placed in 0.2 mM Mg2+ medium. Two classes of S49 clones have been isolated which grow in 30 microM Mg2+ with doubling times of 22 and 60 hours. Although total cell Mg2+ is decreased by 50%, the decrease is selective since cytoplasmic Mg2+ is decreased 75% while particulate Mg2+ is unchanged. Hormonal response in the Mg2+ -deficient cells is defective. Cyclic AMP accumulation in response to beta-adrenergic receptor activation is decreased more than 95%. In contrast, the Mg2+ -deficient cells lose only about 50% of their response to PGE1 receptor activation, retain 50% of their beta-receptors, and accumulate cyclic AMP in response to cholera toxin at the wild-type rate. Mg2+ transport also occurs at the wild-type rate, but with a slightly higher affinity and is no longer hormone-sensitive. Ca2+ content is normal or slightly high. T-lymphocytes isolated from rats made Mg2+ -deficient for 8 weeks give similar results, indicating that the Mg2+ -deficient S49 lymphoma cell clones are a good model for Mg2+ -deficiency. The data suggest that lack of Mg2+ causes growth abnormalities and leads to markedly altered receptor-G-protein coupling, but may have less effect on G-protein-adenylate cylase interaction.

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)

Twenty questions concerning the reaction cycle of the sarcoplasmic reticulum calcium pump

The problem of "mechanism" for the calcium pump may be divided into three parts. (1) It is an enzyme catalyzing the hydrolysis of ATP. (2) At some stage of the reaction cycle it provides a pathway through the otherwise impermeable phospholipid bilayer. (3) The two properties are linked so as to provide exchange of free energy between the two substrates (ATP and Ca2+), without any exchange of matter. The third part is the most interesting, and the mechanistic problem it poses is common to all chemiosmotic free energy transducers. All three aspects of the mechanism are reviewed here, with special emphasis on the remaining experimental questions that need to be resolved. The review will show that even such fundamental questions as the exact stoichiometry of the catalyzed reaction have not yet received definitive answers.

The flip-flop mechanism of the phosphorylation of yeast inorganic pyrophosphatase

1. An active monomeric form of inorganic pyrophosphatase from baker's yeast was prepared by maleylation of the protein at pH 10.5. 2. The dimeric and monomeric pyrophosphatase bound at non-catalytic sites 0.5 and 1.0 mol of slowly dissociating Pi per mol subunit, respectively. This stoichiometry was not affected on active site blockage with PPi. 3. Added Pi accelerated the dissociation of Pi from the dimeric but not monomeric enzyme. 4. Our results indicate a strong interaction to occur between the non-catalytic sites of two subunits of native pyrophosphatase which results in diminished stability of Pi binding to one of them.

Unifying concept for the coupling between ion pumping and ATP hydrolysis or synthesis

A mechanism is proposed for the coupling between ion transport and enzyme catalysis. The basic concept is that enzymes associated with transport exist in two possible conformations. Each conformation has the potential of catalyzing the enzymatic reaction, and pumping is associated with the conversion of one conformational form to the other. The conformational transition is triggered by the kinetic blockage of specific mechanistic steps for each conformation. Such blockages can cause a cycling between the two conformations concomitant with catalysis. This mechanistic concept is consistent with a variety of results obtained with the Na+,K+-ATPase, the Ca2+,Mg2+-ATPase, and ATP synthesizing enzymes (coupling factors).