Binding of two Sr2+ ions changes the chemical specificities for phosphorylation of the sarcoplasmic reticulum calcium ATPase through a stepwise mechanism

Mn(2+) transport by Ca(2+) -ATPase of sarcoplasmic reticulum

Ca(2+) -ATPase of sarcoplasmic reticulum is known to pump Mn(2+) in addition to Ca(2+) , but whether its transport mechanism is identical to that of Ca(2+) is ambiguous. To clarify, we examined, by atomic absorption spectroscopy, competition between Mn(2+) and Ca(2+) in active transport using vesicles of sarcoplasmic reticulum (SR). Here, we demonstrate that Ca(2+) -ATPase transports Ca(2+) and Mn(2+) concomitantly but has a much lower affinity for Mn(2+) (apparent Kd ~ 0.5 mm). Stoichiometries of transported ions per ATP hydrolysed, Vmax values and activation energies are very similar. Altogether, Ca(2+) -ATPase appears to use the same mechanism for transporting Mn(2+) as that for Ca(2+) .

Slippage and uncoupling in P-type cation pumps; implications for energy transduction mechanisms and regulation of metabolism

P-type ATPases couple scalar and vectorial events under optimized states. A number of procedures and conditions lead to uncoupling or slippage. A key branching point in the catalytic cycle is at the cation-bound form of E(1)-P, where isomerization to E(2)-P leads to coupled transport, and hydrolysis leads to uncoupled release of cations to the cis membrane surface. The phenomenon of slippage supports a channel model for active transport. Ability to occlude cations within the channel is essential for coupling. Uncoupling and slippage appear to be inherent properties of P-type cation pumps, and are significant contributors to standard metabolic rate. Heat production is favored in the uncoupled state. A number of disease conditions, include ageing, ischemia and cardiac failure, result in uncoupling of either the Ca(2+)-ATPase or Na(+)/K(+)-ATPase.

Presynaptic strontium dynamics and synaptic transmission

Strontium can replace calcium in triggering neurotransmitter release, although peak release is reduced and the duration of release is prolonged. Strontium has therefore become useful in probing release, but its mechanism of action is not well understood. Here we study the action of strontium at the granule cell to Purkinje cell synapse in mouse cerebellar slices. Presynaptic residual strontium levels were monitored with fluorescent indicators, which all responded to strontium (fura-2, calcium orange, fura-2FF, magnesium green, and mag-fura-5). When calcium was replaced by equimolar concentrations of strontium in the external bath, strontium and calcium both entered presynaptic terminals. Contaminating calcium was eliminated by including EGTA in the extracellular bath, or by loading parallel fibers with EGTA, enabling the actions of strontium to be studied in isolation. After a single stimulus, strontium reached higher peak free levels than did calcium (approximately 1.7 times greater), and decayed more slowly (half-decay time 189 ms for strontium and 32 ms for calcium). These differences in calcium and strontium dynamics are likely a consequence of greater strontium permeability through calcium channels, lower affinity of the endogenous buffer for strontium, and less efficient extrusion of strontium. Measurements of presynaptic divalent levels help to explain properties of release evoked by strontium. Parallel fiber synaptic currents triggered by strontium are smaller in amplitude and longer in duration than those triggered by calcium. In both calcium and strontium, release consists of two components, one more steeply dependent on divalent levels than the other. Strontium drives both components less effectively than does calcium, suggesting that the affinities of the sensors involved in both phases of release are lower for strontium than for calcium. Thus, the larger and slower strontium transients account for the prominent slow component of release triggered by strontium.

The cytoplasmic loop located between transmembrane segments 6 and 7 controls activation by Ca2+ of sarcoplasmic reticulum Ca2+-ATPase

During active cation transport, sarcoplasmic reticulum Ca2+-ATPase, like other P-type ATPases, undergoes major conformational changes, some of which are dependent on Ca2+ binding to high affinity transport sites. We here report that, in addition to previously described residues of the transmembrane region (Clarke, D. M., Loo, T. W., Inesi, G., and MacLennan, D. H. (1989) Nature 339, 476-478), the region located in the cytosolic L6-7 loop connecting transmembrane segments M6 and M7 has a definite influence on the sensitivity of the Ca2+-ATPase to Ca2+, i.e. on the affinity of the ATPase for Ca2+. Cluster mutation of aspartic residues in this loop results in a strong reduction of the affinity for Ca2+, as shown by the Ca2+ dependence of ATPase phosphorylation from either ATP or Pi. The reduction in Ca2+ affinity for phosphorylation from Pi is observed both at acidic and neutral pH, suggesting that these mutations interfere with binding of the first Ca2+, as proposed for some of the intramembranous residues essential for Ca2+ binding (Andersen, J. P. (1995) Biosci. Rep. 15, 243-261). Treatment of the mutated Ca2+-ATPase with proteinase K, in the absence or presence of various Ca2+ concentrations, leads to Ca2+-dependent changes in the proteolytic degradation pattern similar to those in the wild type but observed only at higher Ca2+ concentrations. This implies that these effects are not due to changes in the conformational state of Ca2+-free ATPase but that changes affecting the proteolytic digestion pattern require higher Ca2+ concentrations. We conclude that aspartic residues in the L6-7 loop might interact with Ca2+ during the initial steps of Ca2+ binding.

Direct demonstration of Ca2+ binding defects in sarco-endoplasmic reticulum Ca2+ ATPase mutants overexpressed in COS-1 cells transfected with adenovirus vectors

Single mutations of specific amino acids within the membrane-bound region of the sarco-endoplasmic reticulum Ca2+ (SERCA)-1 ATPase interfere with Ca2+ inhibition of ATPase phosphorylation by Pi (1), suggesting that these residues may be involved in complexation of two Ca2+ that are known to bind to the enzyme. However, direct measurements of Ca2+ binding in the absence of ATP have been limited by the low quantities of available mutant protein. We have improved the transfection efficiency by means of recombinant adenovirus vectors, yielding sufficient expression of wild type and mutant SERCA-1 ATPase for measurements of Ca2+ binding to the microsomal fraction of the transfected cells. We find that in the presence of 20 microM Ca2+ and in the absence of ATP, the Glu771 --> Gln, Thr799 --> Ala, Asp800 --> Asn, and Glu908 --> Ala mutants exhibit negligible binding, indicating that the oxygen functions of Glu771, Thr799, Asp800, and Glu908 are involved in interactions whose single disruption causes major changes in the highly cooperative "duplex" binding. Total loss of Ca2+ binding is accompanied by loss of Ca2+ inhibition of the Pi reaction. We also find that, at pH 7.0, the Glu309 --> Gln and the Asn796 --> Ala mutants bind approximately half as much Ca2+ as the wild type ATPase and do not interfere with Ca2+ inhibition of the Pi reaction. At pH 6.2, the Glu309 --> Gln mutant does not bind any Ca2+, and its phosphorylation by Pi is not inhibited by Ca2+. On the contrary, the Asn796 --> Ala mutant retains the behavior displayed at pH 7.0. This suggests that in the Glu309 --> Gln mutant, ionization of acidic functions in other amino acids (e.g. Glu771 and Asp800) occurs as the pH is shifted, thereby rendering Ca2+ binding possible. In the Asn796 --> Ala mutant, on the other hand, the Glu309 carboxylic function allows binding of inhibitory Ca2+ even at pH 6.2. In all cases mutational interference with the inhibition of the Pi reaction by Ca2+ can be overcome by raising the Ca2+ concentration to the mM range, consistent with a general effect of mutations on the affinity of the ATPase for Ca2+.

Site-directed disulfide mapping of helices M4 and M6 in the Ca2+ binding domain of SERCA1a, the Ca2+ ATPase of fast twitch skeletal muscle sarcoplasmic reticulum

In an attempt to define the spatial relationships among SERCA1a transmembrane helices M4, M5, M6, and M8, involved in Ca2+ binding, all six cysteine residues were removed from predicted transmembrane sequences by substitution with Ser or Ala. The cysteine-depleted protein retained 44% of wild type Ca2+ transport activity. Pairs of cysteine residues were then reintroduced to determine whether their juxtaposition would result in the formation of disulfide cross-links between transmembrane helices. In initial studies designed to map the juxtaposition of Ca2+ binding residues, Cys was substituted for Glu309 or Gly310 in transmembrane sequence M4, in combination with the substitution of Cys for Glu771 in M5; for Asn796, Thr799, or Asp800 in M6; or for Glu908 in M8. These double mutants all retained the capacity to form a phosphoenzyme intermediate from Pi (but not from ATP in the presence of Ca2+), and in all but mutants E309C/N796C and G310C/N796C, phosphoenzyme formation was insensitive to 100 microM Ca2+. These results support the view that both Glu309 and Asn796 contribute to Ca2+ binding site II, which is not required for conversion of E2, the substrate for Pi phosphorylation, to E1. Cross-linking in mutants E309C/N796C and G310C/D800C established reference points for the orientation of M4 and M6 relative to each other and provided the basis for the prediction of potential additional cross-links. Strong links were formed with the pairs T317C/A804C and T317C/L807C near the cytoplasmic ends of the two helices and with A305C/L792C and A305C/L793C near the lumenal ends. These combined results support the conclusion that M4 and M6 form a right-handed coiled-coil structure that forms part of the pathway of Ca2+ translocation. In addition to providing a possible explanation for the mutation sensitivity of several pairs of residues in these helices, the proposed association of M4 and M6 supports a new model for the orientation of the two Ca2+ binding sites among transmembrane helices M4, M5, and M6.

Structure-function relationships in the Ca(2+)-ATPase of sarcoplasmic reticulum: facts, speculations and questions for the future

Structural data on the Ca(2+)-ATPase of sarcoplasmic reticulum are integrated with kinetic data on Ca2+ transport. The emphasis is upon ATPase-ATPase interactions, the requirement for phospholipids, and the mechanism of Ca2+ translocation. The possible role of cytoplasmic [Ca2+] in the regulation of the synthesis of Ca(2+)-ATPase is discussed.

Binding of ADP to sarcoplasmic reticulum Ca(2+)-ATPase in the absence of Mg2+ is specifically inhibited by thapsigargin: observations on the ligand stoichiometry

The conditions of nucleotide binding to native, though partly purified, Ca(2+)-ATPase from SR as well as the stoichiometry of nucleotide and strontium binding and the phosphorylation capacity was reevaluated. Binding of MgADP appeared to be aberrant whereas even high-affinity binding of [14C]-ADP took place in the absence of Mg2+. Also low-affinity ATP binding was possible in the absence of divalent cations. A heterogeneity in ADP binding compatible with a two-component model in the absence of thapsigargin was changed to an apparent homogeneity of low-affinity receptors following a mole:mole interaction of enzyme and thapsigargin. Since the affinity of both components was reduced by thapsigargin, high- as well as low-affinity ADP binding seem to be specific and probably to the substrate receptor proper. Analysis of ADP binding isotherms in the absence of Mg2+ according to a model of two independent populations of sites was compatible with a binding capacity of 8.49 +/- 0.43 nmoles/mg protein corresponding to a molecular mass of 118 +/- 6 kD per ADP site. The same total binding capacity was found for ATP. The phosphorylation capacity corresponded to more than one and less than two approximately P per two 110-kD peptides (formally one approximately P per 154 kD protein). Specific binding of Ca2+ and the congener Sr2+ to SR Ca(2+)-ATPase was compatible with their interaction with a single population of sites. The binding capacity was equal to one divalent cation per nucleotide binding peptide. The binding of one nucleotide and one divalent cation per approximately 110 kD peptide and the absence of cooperativity in divalent cation binding might imply that Ca(2+)-ATPase works as a monomer.

How do Ca2+ ions pass through the sarcoplasmic reticulum membrane

We propose an overview of the mechanism of Ca2+ transport through the sarcoplasmic reticulum membrane via the Ca(2+)-ATPase. We describe cytoplasmic calcium binding, calcium occlusion in the membrane and lumenal calcium dissociation. A channel-like structure is discussed and related to structural data on the membranous domain of the Ca(2+)-ATPase.

The structure and interactions of Ca(2+)-ATPase

Electron crystallographic studies on membrane crystals of Ca(2+)-ATPase reveal different patterns of ATPase-ATPase interactions depending on enzyme conformation. Physiologically relevant changes in Ca2+ concentration and membrane potential affect these interactions. Ca2+ induced difference FTIR spectra of Ca(2+)-ATPase triggered by photolysis of caged Ca2+ are consistent with changes in secondary structure and carboxylate groups upon Ca2+ binding; the changes are reversed during ATP hydrolysis suggesting that a phosphorylated enzyme form of low Ca2+ affinity is the dominant intermediate during Ca2+ transport. A two-channel model of Ca2+ translocation is proposed involving the membrane-spanning helices M2-M5 and M4, M5, M6 and M8 respectively, with separate but interacting Ca2+ binding sites.

The mechanism of coupling chemical and physical reactions by the calcium ATPase of sarcoplasmic reticulum and other coupled vectorial systems

The coupling of the chemical reaction of ATP hydrolysis to the transport of calcium from the cytoplasm into the lumen of sarcoplasmic reticulum vesicles can be defined by a set of rules that define alternating changes in the specificities of the enzyme for catalysis of chemical and physical reactions.

Variable stoichiometric efficiency of Ca2+ and Sr2+ transport by the sarcoplasmic reticulum ATPase

In comparative experiments with Ca2+ ATPase in native sarcoplasmic reticulum vesicles and reconstituted proteoliposomes, we find that a variable stoichiometry of Ca2+ or Sr2+ transport per ATPase cycle is observed in the absence of passive leak through independent channels. The observed ratio is commonly lower than the optimal value of 2 and depends on the composition of the reaction mixture. In all cases, a progressive rise in the lumenal concentration of Ca2+ and Sr2+ is accompanied by a parallel reduction of coupling ratios. Significant ATPase activity remains even after asymptotic levels of Ca2+ accumulation are reached. This residual activity subsides if the Ca2+ concentration in the outer medium is reduced below activating levels (as it would following Ca2+ transients in muscle fibers). The reduction of stoichiometric coupling is explained with a reaction scheme, including a branched pathway for hydrolytic cleavage of phosphorylated intermediate before release of Ca2+ into the lumen of the vesicles. Flux through this pathway is favored when net lumenal Ca2+ dissociation from the phosphoenzyme is impeded and results in P(i) production accompanied by lumenal and medium Ca2+ exchange. Occurrence of reactions through branched pathways may have general implications for the stoichiometric efficiency of energy-transducing enzymes.

Structure-function relationships of cation translocation by Ca(2+)- and Na+, K(+)-ATPases studied by site-directed mutagenesis

Site-directed mutagenesis studies of the sarcoplasmic reticulum Ca(2+)-ATPase have pinpointed five amino acid residues that are essential to Ca2+ occlusion, and these residues have been assigned to different parts of a Ca2+ binding pocket with channel-like structure. Three of the homologous Na+, K(+)-ATPase residues have been shown to be important for binding of cytoplasmic Na+ at transport sites. In addition, three of the above mentioned Ca(2+)-ATPase residues appear to participate in the countertransport of H+, and two of the Na+, K(+)-ATPase residues to participate in the countertransport of K+. Residues involved in energy transducing conformational changes have also been identified by mutagenesis. In the Ca(2+)-ATPase, ATP hydrolysis is uncoupled from Ca2+ transport following mutation of a tyrosine residue located at the top of transmembrane segment M5. This tyrosine, present also in the Na+, K(+)-ATPase, may play a critical role in closing the gate to a transmembrane channel.

Mutational analysis of Glu771 of the Ca(2+)-ATPase of sarcoplasmic reticulum. Effect of positive charge on dephosphorylation

The glutamic acid residue Glu771 in the fifth transmembrane segment M5 of the Ca(2+)-ATPase of rabbit fast twitch muscle sarcoplasmic reticulum was substituted with lysine, alanine, and glycine by site-directed mutagenesis. Mutant Glu771-->Lys was unable to occlude Ca2+, and Ca2+ did not inhibit phosphorylation from P(i) or activate phosphorylation from ATP of this mutant. Mutants Glu771-->Ala and Glu771-->Gly were likewise unable to occlude Ca2+, but Ca2+ in the millimolar concentration range activated phosphorylation from ATP and inhibited phosphorylation from P(i) of these mutants. The dephosphorylation of the ADP-insensitive E2P phosphoenzyme intermediate of mutants Glu771-->Ala and Glu771-->Gly was found to be blocked, whereas the dephosphorylation proceeded rapidly for mutant Glu771-->Lys. This finding suggests a role of the positive charge of the lysine in induction of dephosphorylation, supporting the hypothesis that the side chain of Glu771 participates in the countertransport of two protons per Ca(2+)-ATPase cycle.

Cancellation of the cooperativity of Ca2+ binding to sarcoplasmic reticulum Ca(2+)-ATPase by the non-ionic detergent dodecylmaltoside

The perturbation of the kinetics of the sarcoplasmic reticulum (SR) membranous Ca(2+)-ATPase cycle by the non-ionic detergent dodecylmaltoside (DM) has been shown to exhibit specific features which were not observed with the related detergents octa(ethylene glycol) monododecylether and Triton X-100 [de Foresta, B., Henao, F. & Champeil, P. (1992) Eur. J. Biochem. 209, 1023-1034]. This previous study has been completed here by a detailed analysis of the perturbation by DM of the interaction of Ca2+ with membranous ATPase, both in its unphosphorylated and phosphorylated form. Equilibrium binding measurements, performed at pH 7.5 and 20 degrees C, showed that only one 45Ca2+ was bound with high affinity to the ATPase in the presence of maximally perturbing concentrations of DM, as compared to two 45Ca2+ in the absence of detergent. This binding was also assessed by a small decrease in the tryptophan fluorescence intensity. Binding of a second Ca2+ occurred only with a much lower affinity. In the presence of DM, the pCa dependence of the phosphorylation by [gamma-32P]ATP of the ATPase shifted towards 50-fold higher Ca2+ concentrations than in its absence. Furthermore, DM completely inhibited the cooperativity of this dependence. This shift strongly suggests that the phosphorylation of DM-perturbed ATPase requires the binding of this second, low-affinity Ca2+. In order to assess this, samples of ATPase were intramolecularly cross-linked with glutaraldehyde. This treatment stabilized the phosphorylated intermediated with occluded Ca2+ [Ross, D. C., Davidson, G.A. & McIntosh, D. B. (1991) J. Biol. Chem. 266, 4613-4621]. Both in the absence and presence of DM, the cross-linked enzyme occluded close to two Ca2+/phosphorylated molecule. Finally, the pCa dependences of the ATPase hydrolytic activity, measured with two different high-energy substrates, ATP or p-nitrophenylphosphate (PNpP), were also found to shift towards higher Ca2+ concentrations in the presence of DM, which was again consistent with a normal coupling ratio, i.e. two bound Ca2+/substrate hydrolyzed. As compared to other detergents, the maltoside head group of DM might favor a stronger interaction with membranous ATPase, resulting in its high perturbing effect on Ca2+ binding. The loss of cooperativity of Ca2+ binding evidenced here makes DM a useful tool in the analysis of the sequence of events occurring during Ca2+ binding.

Chimeric Ca(2+)-ATPase/Na+,K(+)-ATPase molecules. Their phosphoenzyme intermediates and sensitivity to Ca2+ and thapsigargin

Chimeric molecules consisting of parts from the sarcoplasmic reticulum Ca(2+)-ATPase and the Na+,K(+)-ATPase were expressed in COS-1 cells and analysed functionally. One chimera, in which most of the central cytoplasmic loop was derived from the Na+,K(+)-ATPase, while the transmembrane segments and the minor cytoplasmic loop came from the Ca(2+)-ATPase, was able to occlude Ca2+ and to be phosphorylated from ATP with normal apparent affinity for Ca2+ and ATP. This chimera also displayed normal sensitivity to thapsigargin, but was unable to undergo the transition from ADP-sensitive to ADP-insensitive phosphoenzyme and to transport Ca2+. The other chimera, which consisted of the NH2-terminal two-thirds of Na+,K(+)-ATPase and the COOH-terminal one-third of Ca(2+)-ATPase, was unable to phosphorylate from ATP, but phosphorylated from inorganic phosphate in a Ca(2+)-inhibitable and thapsigargin-insensitive reaction. These results can be explained in terms of a structural model in which the non-conserved residues in the central cytoplasmic domain of the Ca(2+)-ATPase are without major importance for the binding and occlusion of Ca2+, but are involved in the E1P-->E2P conformational changes of the phosphoenzyme, whereas residues in transmembrane segments on both sides of the central cytoplasmic domain are involved in formation of the Ca(2+)-binding sites. The data moreover show that thapsigargin sensitivity is dependent on residues in the NH2-terminal one-third of the Ca(2+)-ATPase molecule.

Strontium binding to sarcoplasmic reticulum Ca(2+)-ATPase. Spectroscopic differentiation of the substeps involved

We investigated the consequences of Sr2+ binding to the transport sites of sarcoplasmic reticulum (SR) Ca(2+)-ATPase for two fluorescent conformational probes located in different regions of the ATPase. Using SR vesicles in which Lys-515 in the ATPase had been previously labeled with fluorescein 5'-isothiocyanate (FITC), we found that the Sr(2+)-induced a drop in the fluorescein fluorescence of this FITC-labeled ATPase shifted toward lower Sr2+ concentrations than the Sr(2+)-induced rise in Trp fluorescence for the same FITC-labeled ATPase. The curve describing the Sr(2+)-dependent rise in Trp fluorescence had a characteristic asymmetric shape, and the changes in Trp fluorescence occurred in parallel with the activation by Sr2+ of pNPP hydrolysis by the ATPase. Analysis of these results in terms of the simplest scheme describing the sequential binding of the two Sr2+ ions suggests that under the conditions of these experiments, i.e. at neutral pH in the presence of potassium, the Sr(2+)-induced rise in the Trp fluorescence mainly reflected the formation of ATPase with two ions bound to the transport sites, whereas the binding of a single Sr2+ ion was virtually sufficient to reduce the fluorescence of bound FITC to its minimal level.