Project description:The sarcoplasmic reticulum Ca²? ATPase (SERCA) is a membrane-bound pump that utilizes ATP to drive calcium ions from the myocyte cytosol against the higher calcium concentration in the sarcoplasmic reticulum. Conformational transitions associated with Ca²?-binding are important to its catalytic function. We have identified collective motions that partition SERCA crystallographic structures into multiple catalytically-distinct states using principal component analysis. Using Brownian dynamics simulations, we demonstrate the important contribution of surface-exposed, polar residues in the diffusional encounter of Ca²?. Molecular dynamics simulations indicate the role of Glu309 gating in binding Ca²?, as well as subsequent changes in the dynamics of SERCA's cytosolic domains. Together these data provide structural and dynamical insights into a multistep process involving Ca²? binding and catalytic transitions.

Project description:The sarco/endoplasmic reticulum Ca(2+)-ATPase (SERCA) is a transmembrane ion transporter belonging to the P(II)-type ATPase family. It performs the vital task of re-sequestering cytoplasmic Ca(2+) to the sarco/endoplasmic reticulum store, thereby also terminating Ca(2+)-induced signaling such as in muscle contraction. This minireview focuses on the transport pathways of Ca(2+) and H(+) ions across the lipid bilayer through SERCA. The ion-binding sites of SERCA are accessible from either the cytoplasm or the sarco/endoplasmic reticulum lumen, and the Ca(2+) entry and exit channels are both formed mainly by rearrangements of four N-terminal transmembrane ?-helices. Recent improvements in the resolution of the crystal structures of rabbit SERCA1a have revealed a hydrated pathway in the C-terminal transmembrane region leading from the ion-binding sites to the cytosol. A comparison of different SERCA conformations reveals that this C-terminal pathway is exclusive to Ca(2+)-free E2 states, suggesting that it may play a functional role in proton release from the ion-binding sites. This is in agreement with molecular dynamics simulations and mutational studies and is in striking analogy to a similar pathway recently described for the related sodium pump. We therefore suggest a model for the ion exchange mechanism in P(II)-ATPases including not one, but two cytoplasmic pathways working in concert.

Project description:The use of Porphyrin derivatives as photosensitizers in Photodynamic Therapy (PDT) was investigated by means of a molecular docking study. These molecules can bind to intracellular targets such as P-type CaCa(2+) ATPase of sarcoplasmic reticulum (SERCA1a). CAChe software was successfully employed for conducting the docking of Tetraphenylporphinesulfonate(TPPS), 5,10,15,20- Tetrakis (4-sulfonatophenyl) porphyrinato Iron(III) Chloride (FeTPPS) and 5,10,15,20-Tetrakis (4-sulfonatophenyl) porphyrinato Iron(III) nitrosyl Chloride (FeNOTPPS) with CaCa(2+) ATPase from sarcoplasmic reticulum of rabbit. The results show that FeNOTPPS forms the most stable complex with CaCa(2+) ATPase.

Project description:Equilibrium fluorescence methods have been used to establish a model for Ca2+ binding to the (Ca(2+)-Mg2+)-ATPase of skeletal muscle sarcoplasmic reticulum and to define the effects of H+ and Mg2+ on Ca2+ binding. The basic scheme proposed is: E2 <--> E1 <--> E1Ca <--> El'Ca <--> E1'Ca2. The E1 conformation of the ATPase initially has one high-affinity binding site for Ca2+ exposed to the cytoplasmic side of the sarcoplasmic reticulum, but in the E2 conformation this site is unable to bind Ca2+; Ca2+ does not bind to luminal sites on E2. The second, outer, Ca(2+)-binding site on the ATPase is formed after binding of Ca2+ to the first, inner, site on E1 and the E1Ca <--> E1'Ca conformation change. The pH- and Mg(2+)-dependence of the E2 <--> E1 equilibrium has been established after changes in the fluorescence of the ATPase labelled with 4-nitrobenzo-2-oxa-1,3-diazole. It is proposed that Mg2+ from the cytoplasmic side of the sarcoplasmic reticulum can bind to the first Ca(2+)-binding site on both E1 and E2. It is proposed that the change in tryptophan fluorescence intensity after binding of Ca2+ follows from the E1Ca <--> E1'Ca change. The pH- and Mg(2+)-dependence of this change defines H(+)- and Mg(2+)-binding constants at the two Ca(2+)-binding sites. It is proposed that the change in tryptophan fluorescence observed on binding Mg2+ follows from binding at the second Ca(2+)-binding site. Effects of pH and Mg2+ on the fluorescence of the ATPase labelled with 4-(bromomethyl)-6,7-dimethoxycoumarin are proposed to follow from binding to a site on the ATPase, the 'gating' site, which affects the affinity of the first Ca(2+)-binding site for Ca2+ and affects the rate of dissociation of Ca2+ from the ATPase.

Project description:Stop-flow fluorescence and rapid-filtration methods have been used to establish the kinetics of Ca2+ binding to, and dissociation from, the (Ca(2+)-Mg2+)-ATPase of skeletal-muscle sarcoplasmic reticulum and to define the effects of H+ and Mg2+ on Ca2+ binding and dissociation rates. The kinetics have been interpreted in terms of the scheme: E2 E2<==>E1<==>E1Ca<==>E1'Ca<==>E1'Ca2. The kinetics of the E2<==>E1 E1 transition have been determined by measuring the rate of change of the fluorescence of the ATPase labelled with 4-nitrobenzo-2-oxa-1,3-diazole after a pH jump or the addition of Ca2+ to the labelled ATPase in the presence of thapsigargin or thapsivillosin A. It has been shown that Mg2+ has a marked effect on Ca2+ dissociation at pH 7.2 and that changes in the tryptophan fluorescence of the ATPase follow the same time course as the dissociation of 45Ca2+. It is proposed that the effect of Mg2+ follows from binding to a 'gating' site, as detected by changes in the fluorescence of the ATPase labelled with 4-(bromomethyl)-6,7-dimethoxycoumarin. The rate of dissociation of Ca2+ from the ATPase increases with increasing pH. The rate of dissociation of Ca2+ decreases with increasing Ca2+ concentration in the medium, with an apparent affinity for Ca2+ greater than that seen for the change in fluorescence amplitude. It is shown that this follows if the first, inner, Ca(2+)-binding site on the ATPase has a lower affinity for Ca2+ than the second, outer, site. Effects of H+ and Mg2+ on Ca2+ dissociation can be treated by the quasiequilibrium approach. Mg2+ and H+ also affect the rate of Ca2+ binding to the ATPase, and effects of H+ and Mg2+ on the E2<==>E1 equilibrium explain the results of experiments in which the concentrations of H+ and Mg2+ are jumped.

Project description:ATP has dual roles in the reaction cycle of sarcoplasmic reticulum Ca(2+)-ATPase. Upon binding to the Ca2E1 state, ATP phosphorylates the enzyme, and by binding to other conformational states in a non-phosphorylating modulatory mode ATP stimulates the dephosphorylation and other partial reaction steps of the cycle, thereby ensuring a high rate of Ca(2+) transport under physiological conditions. The present study elucidates the mechanism underlying the modulatory effect on dephosphorylation. In the intermediate states of dephosphorylation the A-domain residues Ser(186) and Asp(203) interact with Glu(439) (N-domain) and Arg(678) (P-domain), respectively. Single mutations to these residues abolish the stimulation of dephosphorylation by ATP. The double mutation swapping Asp(203) and Arg(678) rescues ATP stimulation, whereas this is not the case for the double mutation swapping Ser(186) and Glu(439). By taking advantage of the ability of wild type and mutant Ca(2+)-ATPases to form stable complexes with aluminum fluoride (E2·AlF) and beryllium fluoride (E2·BeF) as analogs of the E2·P phosphoryl transition state and E2P ground state, respectively, of the dephosphorylation reaction, the mutational effects on ATP binding to these intermediates are demonstrated. In the wild type Ca(2+)-ATPase, the ATP affinity of the E2·P phosphoryl transition state is higher than that of the E2P ground state, thus explaining the stimulation of dephosphorylation by nucleotide-induced transition state stabilization. We find that the Asp(203)-Arg(678) and Ser(186)-Glu(439) interdomain bonds are critical, because they tighten the interaction with ATP in the E2·P phosphoryl transition state. Moreover, ATP binding and the Ser(186)-Glu(439) bond are mutually exclusive in the E2P ground state.

Project description:The mechanism of ATP modulation of E2P dephosphorylation of sarcoplasmic reticulum Ca(2+)-ATPase wild type and mutant forms was examined in nucleotide binding studies of states analogous to the various intermediates of the dephosphorylation reaction, obtained by binding of metal fluorides, vanadate, or thapsigargin. Wild type Ca(2+)-ATPase displays an ATP affinity of 4 ?M for the E2P ground state analog, 1 ?M for the E2P transition state and product state analogs, and 11 ?M for the E2 dephosphoenzyme. Hence, ATP binding stabilizes the transition and product states relative to the ground state, thereby explaining the accelerating effect of ATP on dephosphorylation. Replacement of Phe(487) (N-domain) with serine, Arg(560) (N-domain) with leucine, or Arg(174) (A-domain) with alanine or glutamate reduces ATP affinity in all E2/E2P intermediate states. Alanine substitution of Ile(188) (A-domain) increases the ATP affinity, although ATP acceleration of dephosphorylation is disrupted, thus indicating that the critical role of Ile(188) in ATP modulation is mechanistically based rather than being associated with the binding of nucleotide. Mutants with alanine replacement of Lys(205) (A-domain) or Glu(439) (N-domain) exhibit an anomalous inhibition by ATP of E2P dephosphorylation, due to ATP binding increasing the stability of the E2P ground state relative to the transition state. The ATP affinity of Ca(2)E2P, stabilized by inserting four glycines in the A-M1 linker, is similar to that of the E2P ground state, but the Ca(2+)-free E1 state of this mutant exhibits 3 orders of magnitude reduction of ATP affinity.

Project description:The roles of Ser(72), Glu(90), and Lys(297) at the luminal ends of transmembrane helices M1, M2, and M4 of sarcoplasmic reticulum Ca(2+)-ATPase were examined by transient and steady-state kinetic analysis of mutants. The dependence on the luminal Ca(2+) concentration of phosphorylation by P(i) ("Ca(2+) gradient-dependent E2P formation") showed a reduction of the apparent affinity for luminal Ca(2+) in mutants with alanine or leucine replacement of Glu(90), whereas arginine replacement of Glu(90) or Ser(72) allowed E2P formation from P(i) even at luminal Ca(2+) concentrations much too small to support phosphorylation in wild type. The latter mutants further displayed a blocked dephosphorylation of E2P and an increased rate of conversion of the ADP-sensitive E1P phosphoenzyme intermediate to ADP-insensitive E2P as well as insensitivity of the E2.BeF(3)(-) complex to luminal Ca(2+). Altogether, these findings, supported by structural modeling, indicate that the E2P intermediate is stabilized in the mutants with arginine replacement of Glu(90) or Ser(72), because the positive charge of the arginine side chain mimics Ca(2+) occupying a luminally exposed low affinity Ca(2+) site of E2P, thus identifying an essential locus (a "leaving site") on the luminal Ca(2+) exit pathway. Mutants with alanine or leucine replacement of Glu(90) further displayed a marked slowing of the Ca(2+) binding transition as well as slowing of the dissociation of Ca(2+) from Ca(2)E1 back toward the cytoplasm, thus demonstrating that Glu(90) is also critical for the function of the cytoplasmically exposed Ca(2+) sites on the opposite side of the membrane relative to where Glu(90) is located.

Project description:The Ca2+-transport ATPase of sarcoplasmic reticulum (SR) is an integral, transmembrane protein. It sequesters cytoplasmic calcium ions released from SR during muscle contraction, and causes muscle relaxation. Based on negative staining and transmission electron microscopy of SR vesicles isolated from rabbit skeletal muscle, we propose that the ATPase molecules might also be a calcium-sensitive membrane-endoskeleton. Under conditions when the ATPase molecules scarcely transport Ca2+, i.e., in the presence of ATP and ≤ 0.9 nM Ca2+, some of the ATPase particles on the SR vesicle surface gathered to form tetramers. The tetramers crystallized into a cylindrical helical array in some vesicles and probably resulted in the elongated protrusion that extended from some round SRs. As the Ca2+ concentration increased to 0.2 µM, i.e., under conditions when the transporter molecules fully carry out their activities, the ATPase crystal arrays disappeared, but the SR protrusions remained. In the absence of ATP, almost all of the SR vesicles were round and no crystal arrays were evident, independent of the calcium concentration. This suggests that ATP induced crystallization at low Ca2+ concentrations. From the observed morphological changes, the role of the proposed ATPase membrane-endoskeleton is discussed in the context of calcium regulation during muscle contraction.

Project description:Tyr(122)-hydrophobic cluster (Y122-HC) is an interaction network formed by the top part of the second transmembrane helix and the cytoplasmic actuator and phosphorylation domains of sarcoplasmic reticulum Ca(2+)-ATPase. We have previously found that Y122-HC plays critical roles in the processing of ADP-insensitive phosphoenzyme (E2P) after its formation by the isomerization from ADP-sensitive phosphoenzyme (E1PCa(2)) (Wang, G., Yamasaki, K., Daiho, T., and Suzuki, H. (2005) J. Biol. Chem. 280, 26508-26516). Here, we further explored kinetic properties of the alanine-substitution mutants of Y122-HC to examine roles of Y122-HC for Ca(2+) release process in E2P. In the steady state, the amount of E2P decreased so that of E1PCa(2) increased with increasing lumenal Ca(2+) concentration in the mutants with K(0.5) 110-320 microm at pH 7.3. These lumenal Ca(2+) affinities in E2P agreed with those estimated from the forward and lumenal Ca(2+)-induced reverse kinetics of the E1PCa(2)-E2P isomerization. K(0.5) of the wild type in the kinetics was estimated to be 1.5 mM. Thus, E2P of the mutants possesses significantly higher affinities for lumenal Ca(2+) than that of the wild type. The kinetics further indicated that the rates of lumenal Ca(2+) access and binding to the transport sites of E2P were substantially slowed by the mutations. Therefore, the proper formation of Y122-HC and resulting compactly organized structure are critical for both decreasing Ca(2+) affinity and opening the lumenal gate, thus for Ca(2+) release from E2PCa(2). Interestingly, when K(+) was omitted from the medium of the wild type, the properties of the wild type became similar to those of Y122-HC mutants. K(+) binding likely functions via producing the compactly organized structure, in this sense, similarly to Y122-HC.