The functional unit of sarcoplasmic reticulum Ca2+-ATPase. Active site titration and fluorescence measurements

Characterization of detergent-solubilized sarcoplasmic reticulum Ca2+-ATPase by high-performance liquid chromatography

Sarcoplasmic reticulum Ca2+-ATPase solubilized by the nonionic detergent octaethylene glycol monododecyl ether was studied by molecular sieve high-performance liquid chromatography (HPLC) and analytical ultracentrifugation. Significant irreversible aggregation of soluble Ca2+-ATPase occurred within a few hours in the presence of less than or equal to 50 microM Ca2+. The aggregates were inactive and were primarily held together by hydrophobic forces. In the absence of reducing agent, secondary formation of disulfide bonds occurred. The stability of the inactive dimer upon dilution permitted unambiguous assignment of its elution position and sedimentation coefficient. At high Ca2+ concentration (500 microM), monomeric Ca2+-ATPase was stable for several hours. Reversible self-association induced by variation in protein, detergent, and lipid concentrations was studied by large-zone HPLC. The association constant for dimerization of active Ca2+-ATPase was found to be 10(5)-10(6) M-1 depending on the detergent concentration. More detergent was bound to monomeric than to dimeric Ca2+-ATPase, even above the critical micellar concentration of the detergent. Binding of Ca2+ and vanadate as well as ATP-dependent phosphorylation was studied in monomeric and in reversibly associated dimeric preparations. In both forms, two high-affinity Ca2+ binding sites per phosphorylation site existed. The delipidated monomer purified by HPLC was able to form ADP-insensitive phosphoenzyme and to bind ATP and vanadate simultaneously. These results suggest that formation of Ca2+-ATPase oligomers in the membrane is governed by nonspecific forces (low affinity) and that each polypeptide chain constitutes a functional unit.

Distinguishing between functional monomeric and oligomeric complexes of the Ca,Mg-ATPase in sarcoplasmic reticulum

Techniques are described for using blocking agents to distinguish between enzymes which are functional monomers and oligomers. To achieve this distinction the blocking agent must react exclusively at the active site with a stoichiometry of one mole of site per mole enzyme. The effect of the blocking agent on enzymatic activity in oligomers of n = 2 and 4 are described and the optimal degree of blocking is considered for tests of enzyme activity at saturating and less than saturating substrate concentrations. For saturating concentrations and a dimer the distinction between dimer and monomer is best observed with 50 per cent of sites blocked. For a tetramer the distinction is best made at higher degrees of blockade. The use of saturating substrate concentrations is thus limited to small oligomers. If nonsaturating substrate concentrations are used and normalized double reciprocal plots of the dependence of enzyme activity on substrate concentrations are made then the distinction between monomer and oligomer can readily be made for dimers, tetramers, and higher n-mers. The principles developed to distinguished monomeric from oligomeric enzymes are applied to published data obtained with the Ca Mg-ATPase of sarcoplasmic reticulum. Fluorescein isothiocyanate is the blocking agent. Plots of the published data support both the monomeric and tetrameric models for allosteric regulation with the preponderance of the data supporting the monomeric model.

Thermoinactivation and aggregation of alpha beta units in soluble and membrane-bound (Na,K)-ATPase

Stability and conformational transitions of soluble and fully active alpha beta units of (Na,K)-ATPase in n-dodecyl octaethylene glycol monoether (C12E8) are examined. Sedimentation equilibrium centrifugation gave a molecular weight of 143 000 for the alpha beta unit eluting from TSK 3000 SW gel chromatography columns. Fluorescence analysis and phosphorylation experiments show that E1-E2 transitions between both dephospho and phospho forms of soluble (Na,K)-ATPase are similar to those previously observed in the membrane-bound state. The two conformations can also be identified by their different susceptibilities to irreversible temperature-dependent inactivation. E1 forms of both soluble and membrane-bound (Na,K)-ATPase are more thermolabile than E2 forms. Gel chromatography on TSK 3000 SW and 4000 SW columns shows that thermal inactivation of soluble (Na,K)-ATPase at 40 degrees C is accompanied by aggregation of alpha beta units to (alpha beta)2 units and higher oligomers. The aggregates are stable in C12E8 but dissolve in sodium dodecyl sulfate. Similar aggregation accompanies inactivation of membrane-bound (Na,K)-ATPase at 55-60 degrees C. These data suggest that inactivation both in the soluble and in the membrane-bound state involves exposure of hydrophobic residues to solvent. The instability of the soluble E1 form may be related to inadequate length of the dodecyl alkyl chain of C12E8 for stabilization of hydrophobic protein domains that normally associate with alkyl chains of phospholipids in the membrane. Interaction between alpha beta units-does not seem to be required for the E1-E2 conformational change, but irreversible aggregation appears to be a consequence of denaturation of (Na,K)-ATPase in both soluble and membranous states.

Primary structure of the nucleotide binding domain of the Ca,Mg-ATPase from cardiac sarcoplasmic reticulum

The nucleotide binding domain of the active site of the Ca,Mg-ATPase of cardiac sarcoplasmic reticulum (SR) has been isolated using fluorescein isothiocyanate (FITC) as an active site label and sequenced. After removal of non-specifically incorporated FITC with hydroxylamine, the amount of label incorporated was stoichiometric with residual ATPase activity, demonstrating that the label was incorporated uniquely at the active site. The SR was succinylated before digestion by trypsin in order to obtain a peptide of sufficient length to determine if the cardiac SR ATPase is a candidate for the unidentified cDNA clone recently sequenced by MacLennan et al. (Nature 316: 696-700, 1985). The sequence of the labeled SR peptide, obtained by affinity chromatography on a FITC antibody column, was T S M S K M F K G P E V I D R. This sequence was identical with that predicted by the unidentified clone and is significantly different from the sequence reported by Kirley et al. (Biochem. Biophys. Res. Commun. 130: 732-738, 1985) for a FITC labeled peptide isolated from cardiac SR.

Localization of E1-E2 conformational transitions of sarcoplasmic reticulum Ca-ATPase by tryptic cleavage and hydrophobic labeling

Tryptic peptides of Ca-ATPase in E1 and E2 conformational states (Andersen, J. P., Jørgensen, P. L., J. Membrane Biol. 88:187-198 (1985] have been isolated by size exclusion high performance liquid chromatography in sodium dodecyl sulfate. This permitted unambiguous localization of a conformational sensitive tryptic split at Arg 198 by N-terminal amino acid sequence analysis. Other splits at Arg 505 and at Arg 819-Lys 825 were insensitive to E1-E2 transitions. Tryptic cleavage of Ca-ATPase after phosphorylation by inorganic phosphate showed that this enzyme form has a conformation similar to that of the vanadate-bound E2 state, both in membranous and in soluble monomeric Ca-ATPase. Hydrophobic labeling of Ca-ATPase in sarcoplasmic reticulum vesicles with the photoactivable reagent trifluoromethyl-[125I]iodophenyl-diazirine indicated that E2 and E2V states are more exposed to the membrane phase than E1 and E1P (Ca2+-occluded) states. The preferential hydrophobic labeling in E2 forms was found to be localized in the A1 tryptic fragment.

Lipid-protein interactions and the function of the Ca2+-ATPase of sarcoplasmic reticulum

Regardless of the nature of the protein constituents of membranes, the molecular arrangement of lipids interacting with them must satisfy hydrophobic, ionic, and steric requirements. Biological membranes have a great diversity of lipid constituents, and this diversity might have functional roles. It has been proposed, for example, that the hydrophobic regions of membrane proteins are stabilized in the membrane through interactions with lipids able to adopt configurations other than the bilayer structure. Progress in understanding at the molecular level how lipid-protein interactions control the properties of membrane proteins has been hindered by the lack of information concerning the structure of the hydrophobic regions of membrane proteins. Nevertheless, there are many examples in the literature describing how changes in the lipid environment affect physical and biochemical properties of membrane proteins. From these studies, discussed in this review, an overall picture of how lipids and proteins interact in membranes is beginning to emerge.

Mechanism of allosteric regulation of the Ca,Mg-ATPase of sarcoplasmic reticulum: studies with 5'-adenylyl methylenediphosphate

Four mechanisms for the allosteric regulation of the calcium and magnesium ion activated adenosinetriphosphatase (Ca,Mg-ATPase) of sarcoplasmic reticulum were examined. Negative cooperativity in substrate binding was not supported by 3H-labeled 5'-adenylyl methylenediphosphate (AMPPCP) binding, which was best fit by a single class of sites. Although calcium had no effect on the absence of cooperativity, it did increase the affinity of the enzyme for AMPPCP. Allosteric regulation via an effector site for AMPPCP or ATP on the same ATPase chain was eliminated by the stoichiometry of ATP and AMPPCP binding, 1 mol of site per mole of enzyme. The possibility that AMPPCP acts at an effector site was eliminated by showing that it competitively inhibits the rate of phosphoenzyme formation. Allosteric regulation of kinetics via site-site interaction in an oligomer was eliminated by showing that the inhibition of ATPase activity by fluorescein isothiocyanate is linearly dependent upon its incorporation into the sarcoplasmic reticulum. The fourth mechanism considered was stimulation of ATPase activity by the binding of ATP or AMPPCP at the active site after departure of ADP but before the departure of inorganic phosphate. This hypothesis was supported by site stoichiometry and by the observation that AMPPCP or ATP stimulates v/EP, the rate of ATP hydrolysis for a given level of phosphoenzyme. Computer simulation of this branched monomeric model could duplicate all experimental observations made with AMPPCP and ATP as allosteric regulators. The condition that the affinity of ATP binding to the enzyme be reduced when it is phosphorylated, which is required by the computer model, was confirmed experimentally.

High-affinity and low-affinity vanadate binding to sarcoplasmic reticulum Ca2+-ATPase labeled with fluorescein isothiocyanate

Conditions were found that allowed both the fluorescence detection of vanadate binding to the Ca2+-ATPase of skeletal muscle sarcoplasmic reticulum and the vanadate-induced formation of two-dimensional arrays of the enzyme. The fluorescence intensity of fluorescein isothiocyanate-labeled Ca2+-ATPase increased with high-affinity vanadate binding (Ka = 10(6) M-1) as reported by Pick and Karlish (Pick, U. and Karlish, S.D. (1982) J. Biol. Chem. 257, 6120-6126). The Ca2+ and Mg2+ dependencies for high-affinity vanadate binding were similar but not identical to those for orthophosphate. In addition, it was found that there is low-affinity (Ka = 380 M-1) vanadate binding, which causes a 25% decrease in fluorescence. The Ca2+ and Mg2+ dependencies of the low-affinity vanadate binding were different from those of orthophosphate or high-affinity vanadate binding. The covalent attachment of fluorescein isothiocyanate (FITC) in the ATP site of the Ca2+-ATPase did not affect the formation of two-dimensional arrays, as detected by negatively stained electron micrographs. Vanadate concentrations high enough to saturate the low-affinity binding caused two-dimensional arrays as reported by Dux and Martonosi (Dux, L. and Martonosi, A. (1983) J. Biol. Chem. 258, 2599-2603). In addition, freeze-fracture replicas of quick-frozen specimens showed rows of indentations in the inner leaflet of the bilayer that corresponds to the arrays seen on the outer leaflet. This appearance of indentations suggests that low-affinity vanadate binding causes a transmembrane movement of the Ca2+-ATPase. By contrast, high-affinity vanadate binding was shown to cause neither array formation nor the appearance of indentations.

Conformational states of sarcoplasmic reticulum Ca2+-ATPase as studied by proteolytic cleavage

Conformational states in sarcoplasmic reticulum Ca2+-ATPase have been examined by tryptic and chymotryptic cleavage. High affinity Ca2+ binding (E1 state) exposes a peptide bond in the A fragment of the polypeptide chain to trypsin. Absence of Ca2+ (E2 state) exposes bonds in the B fragment, which are protected by binding of Mg2+ or ATP. After phosphorylation from ATP the tryptic cleavage pattern depends on the predominant phosphoenzyme species present. ADP-sensitive E1P and ADP-insensitive E2P have cleavage patterns identical to those of unphosphorylated E1 and E2, respectively, indicating that two major conformational states are involved in Ca2+ translocation. The transition from E1P to E2P is inhibited by secondary tryptic splits in the A fragment, suggesting that parts of this fragment are of particular importance for the energy transduction process. The tryptic cleavage patterns of phosphorylated forms of detergent solubilized monomeric Ca2+-ATPase were similar to those of the membrane-bound enzyme, indicating that Ca2+ translocation depends mainly on structural changes within a single peptide chain. On the other hand, the protection of the second cleavage site as observed after vanadate binding to membranous Ca2+-ATPase could not be achieved in the soluble monomeric enzyme. Shielding of this peptide bond may therefore be due to protein-protein interactions in the semicrystalline state of the vanadate-bound Ca2+-ATPase in membranous form.

Solubilized monomeric sarcoplasmic reticulum Ca pump protein. Phosphorylation by inorganic phosphate

Phosphorylation (by inorganic phosphate) of sarcoplasmic reticulum Ca pump protein has been studied in a detergent solution in which the protein has been previously shown to exist as a monomer. The course of the reaction is qualitatively similar to that observed for membrane-bound (possibly oligomeric) protein. In particular, the results indicate that alternation between the two principal conformational states of the Ca pump protein persists in the monomeric state, which suggests that the machinery for coupling of ATP hydrolysis to Ca2+ transport is intact. There are quantitative differences between monomeric and membrane-bound protein with respect to phosphorylation, but they are not necessarily related to the state of association.

Evidence that the ATP binding site of sarcoplasmic reticulum CaATPase has a Mg(2+) ion binding sub-site

The CaATPase of skeletal muscle sarcoplasmic reticulum was specifically labeled in the ATP binding site with fluorescein isothiocyanate under gentle conditions (pH 7 X 5). Fluorescence energy transfer from the attached fluorescein to Nd3+ indicated that a cation binding site was about 1 X 0 nm away from the fluorescein. Thus it appears that the ATP site includes a cation binding site. At 25 degrees C in 0 X 5 M KCl, the association constants for Nd3+, Ca2+ and Mg2+ were 3 X 3 X 10(5) M-1, 84 M-1 and 35 M-1, respectively, making it possible that, in vivo, the site binds Mg2+.

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 Ca2+ permeability of sarcoplasmic reticulum vesicles. I. Ca2+ outflow in the non-energized state of the calcium pump

Passive Ca2+ permeability of sarcoplasmic reticulum vesicles has been studied after maximal loading with Ca2+ (150-200 nmol/mg protein) in the presence of Ca2+, MgATP and an ATP generating system of limited capacity. Outflow of accumulated Ca2+ in the non-energized state of the system was studied by depletion of the medium of one of the substrates, either MgATP (by complete consumption) or Ca2+ (by complexation with EGTA). It was found that Ca2+ outflow under these conditions is relatively slow and independent of the medium concentration of Ca2+ (5 X 10(-9)-5 X 10(-5) M) or MgATP (0.7-730 microM). Outflow curves were steep at the beginning of the outflow phase (30-60 nmol/min per mg protein), and outflow proceeded at a much lower rate below 100 nmol Ca2+/mg protein. Outflow could be completely inhibited by La3+. The Ca2+ release curves are not compatible with simple diffusion, and cannot be accounted for by Ca2+ binding inside the vesicles. Neither are our observations consistent with permeation mediated via the Ca2+ translocation sites involved in active transport. We suggest that non-energized Ca2+ outflow may proceed by a process of ion-exchange through negatively charged, water-filled channels in the membrane, the properties of which are altered by a high intravesicular concentration of Ca2+.

Perturbation of the structure and function of a membranous Ca2+-ATPase by non-solubilizing concentrations of a non-ionic detergent

The present study characterizes the effect of octa(ethyleneglycol)-monododecylether (C12E8) on Ca2+-ATPase membranes, prepared from sarcoplasmic reticulum (SR). At low concentrations C12E8 is incorporated into the membrane (less than or equal to 0.2 g/g protein), without any solubilization or appreciable morphological changes of freeze-fracture replica. Binding studies of C12E8 to ATPase membranes and SR lipid liposomes suggest that the major part of the detergent interacts with lipid. Solubilization of ATPase membranes occurs at a free concentration of C12E8 close to the critical micellar concentration (c.m.c); at low temperatures (2 degrees C) phospholipid is extracted somewhat more easily than ATPase. Electron-spin resonance (ESR) spectra of appropriate spin labels, incorporated into ATPase membranes, show that C12E8 strongly increases the fluidity of the lipid phase and the rotational diffusion of ATPase in the membrane. The effect of C12E8 on the ESR spectra is indistinguishable from that produced by a rise in temperature. Incorporation of C12E8 alters the functional properties of Ca2+-ATPase in a characteristic way: V is decreased and the modulatory effect of high ATP concentrations is reduced, in contrast to what occurs by a rise of temperature. The intrinsic fluorescence of the protein is increased, especially in the absence of Ca2+, suggesting that C12E8 modified in particular the E* form (Ca2+-depleted conformation) of the enzyme. Furthermore, stopped-flow data indicate that C12E8 strongly activates the E* to E transition, which may account for the effect of the detergent on ATP modulation during steady-state ATP hydrolysis. It is concluded that C12E8 perturbs ATPase turnover by direct interaction with the enzyme, rather than by an indirect effect exerted via a change in the lipid phase or protein aggregation.

Soluble and enzymatically stable (Na+ + K+)-ATPase from mammalian kidney consisting predominantly of protomer alpha beta-units. Preparation, assay and reconstitution of active Na+, K+ transport

Soluble (Na+ + K+)-ATPase consisting predominantly of alpha beta-units with Mr below 170 000 was prepared by incubating pure membrane-bound (Na+ + K+)-ATPase (35-48 mumol Pi/min per mg protein) from the outer renal medulla with the non-ionic detergent dodecyloctaethyleneglycol monoether (C12E8). (Na+ + K+)-ATPase and potassium phosphatase remained fully active in the detergent solution at C12E8/protein ratios of 2.5-3, at which 50-70% of the membrane protein was solubilized. The soluble protomeric (Na+ + K+)-ATPase was reconstituted to Na+, K+ pumps in phospholipid vesicles by the freeze-thaw sonication procedure. Protein solubilization was complete at C12E8/protein ratios of 5-6, at the expense of partial inactivation, but (Na+ + K+)-ATPase and potassium phosphatase could be reactivated after binding of C12E8 to Bio-Beads SM2. At C12E8/protein ratios higher than 6 the activities were irreversibly lost. Inactivation could be explained by delipidation. It was not due to subunit dissociation since only small changes in sedimentation velocities were seen when the C12E8/protein ratio was increased from 2.9 to 46. As determined immediately after solubilization, S20,w was 7.4 S for the fully active (Na+ + K+)-ATPase, 7.3 S for the partially active particle, and 6.5 S for the inactive particle at high C12E8/protein ratios. The maximum molecular masses determined by analytical ultracentrifugation were 141 000-170 000 dalton for these protein particles. Secondary aggregation occurred during column chromatography, with formation of enzymatically active (alpha beta)2-dimers or (alpha beta)3-trimers with S20,w = 10-12 S and apparent molecular masses in the range 273 000-386 000 daltons. This may reflect non-specific time-dependent aggregation of the detergent micelles.

Reconstitution of sarcoplasmic reticulum Ca2+-ATPase with excess lipid dispersion of the pump units

Sarcoplasmic reticulum Ca2+-ATPase has been reconstituted with excess lipid (25-150 g egg phosphatidylcholine per g sarcoplasmic reticulum protein) by a procedure combining the use of a non-ionic detergent with cholate dialysis. The reconstituted vesicles were analyzed by sucrose density fractionation and freeze-fracture electron microscopy. At the lowest lipid to protein ratios some vesicles containing aggregated protein were observed. At a lipid to protein ratio of 150:1 (w/w) only 30-40% of the reconstituted protein sedimented through 7% (w/v) sucrose. The remainder of the latter preparation was characterized by a high Ca2+-uptake capacity and a coupling ratio of 1.6 mol Ca2+ transported per mol ATP hydrolyzed. Intramembranous particles in this preparation occurred isolated in the membrane. In most cases only one particle could be seen on a fracture face. Cross-linking with cupric phenanthroline indicated that protein-protein contacts were drastically reduced by reconstitution. It is concluded that aggregation of intramembranous particles is not required for optimal Ca2+-transport function. The dispersed preparation obtained by a combined reconstitution and sucrose density fractionation procedure is useful for further characterization of the Ca2+ pump.