Kinetics of Ca2+ binding to the SR Ca-ATPase in the E1 state

The time-resolved kinetics of Ca2+ binding to the SR Ca-ATPase in the E1 state was investigated by Ca(2+)-concentration jump experiments. Ca2+ was released by an ultraviolet-light flash from caged calcium, and charge movements in the membrane domain of the ion pumps were detected by the fluorescent styryl dye 2BITC. The partial reaction (H3E1 <-->) E1 <--> CaE1 <--> Ca2E1 can be characterized by two time constants, tau1 and tau2, both of which are not significantly Ca(2+)-concentration-dependent and only weakly pH-dependent at pH < 7.5. Both time constants differ by a factor of approximately 50 (4.7 vs. 200 ms). The weak substrate-dependence indicates that the rate-limiting process is not related to Ca2+ migration through the access channel and ion binding to the binding sites but to conformational rearrangements preceding the ion movements. The high activation energy obtained for both processes, 42.3 kJ mol(-1) and 60.3 kJ mol(-1) at pH 7.2, support this concept. Transient binding of Ca ions to the loop L67 and a movement of the Ca-loaded loop are discussed as a mechanism that facilitates the entrance of both Ca ions into the access channel to the ion-binding sites.     

Kinetics of luminal proton binding to the SR Ca-ATPase

An open membrane preparation containing SR Ca-ATPase was prepared from sarcoplasmic-reticulum vesicles to study the ion binding kinetics in the P-E₂ conformation. Because Ca²⁺ and H⁺ binding are electrogenic reactions, fluorescent styryl dyes could be used to determine changes in the binding site occupation in equilibrium titration experiments and time-resolved relaxation processes triggered by a pH jump. By photo release from caged proton the pH of the electrolyte could be decreased in a step of 0.1 pH units by a single ultraviolet-laser flash. Analysis of the pH-jump induced relaxation process in the P-E₂ conformation showed that three Ca-ATPase-specific processes could be identified, fast H⁺ binding (τ < 100 μs) and pH-insensitive conformational relaxations after the release of the Ca²⁺ ion (τ ∼160 ms), and a slow process (τ ∼3.4 s) whose origin could not be unambiguously revealed. The Ca²⁺-binding affinity in the P-E₂ conformation was reduced with increasing pH, a behavior that can be explained by a reversible transition of the empty P-E₂ state to an inactivated state of the ion pump. All findings are interpreted in the framework of the Post-Albers pump cycle introduced previously, supplemented by an additional transition to an inhibited state of the ion pump.     

Thermal dependence of cardiac SR Ca-ATPase from fish and mammals

The thermal sensitivity of metabolic performance in vertebrates requires a better understanding of the temperature sensitivity of cardiac function. The cardiac sarco/endoplasmic reticulum Ca²⁺-ATPase (SERCA2) is vital for excitation–contraction (E–C) coupling and intracellular Ca²⁺ homeostasis in heart cells. To better understand the thermal dependency of cardiac output in vertebrates, we present comparative analyses of the thermal kinetics properties of SERCA2 from ectothermic and endothermic vertebrates. We directly compare SR ventricular microsomal preparations using similar experimental conditions from sarcoplasmic reticulum isolated from cardiac tissues of mammals and fish. The experiments were designed to delineate the thermal sensitivity of SERCA2 and its role in thermal sensitivity Ca²⁺ uptake and E–C coupling. Ca²⁺ transport in the microsomal SR fractions from rabbit and bigeye tuna (Thunnus obesus) ventricles were temperature dependent. In contrast, ventricular SR preparations from coho salmon (Onchorhychus kisutch) were less temperature dependent and cold tolerant, displaying Ca²⁺ uptake as low as 5 °C. As a consequence, the Q₁₀ values in coho salmon were low over a range of different temperature intervals. Maximal Ca²⁺ transport activity for each species occurred in a different temperature range, indicating species-specific thermal preferences for SERCA2 activity. The mammalian enzyme displayed maximal Ca²⁺ uptake activity at 35 °C, whereas the fish (tuna and salmon) had maximal activity at 30 °C. At 35 °C, the rate of Ca²⁺ uptake catalyzed by the bigeye tuna SERCA2 decreased, but not the rate of ATP hydrolysis. In contrast, the salmon SERCA2 enzyme lost its activity at 35 °C, and ATP hydrolysis was also impaired. We hypothesize that SERCA2 catalysis is optimized for species-specific temperatures experienced in natural habitats and that cardiac aerobic scope is limited when excitation–contraction coupling is impaired at low or high temperatures due to loss of SERCA2 enzymatic function.     

Electrogenic steps of the SR Ca-ATPase enzymatic cycle and the effect of curcumin

Sarcoplasmic reticulum (SR) vesicles were adsorbed on an octadecanethiol/phosphatidylcholine mixed bilayer anchored to a gold electrode, and the Ca-ATPase contained in the vesicles was activated by ATP concentration jumps in the presence of calcium ions. The resulting capacitive current transients are compared with those calculated on the basis of the enzymatic cycle of the calcium pump. This comparison provides information on the kinetics of the E(2)-E(1) conformational change and on its pH dependence. The alteration in the current transients following ATP concentration jumps in the presence of curcumin is examined. In particular, curcumin decreases the rate of slippage of the Ca-ATPase, and at concentrations above 10 microM reduces calcium transport by this pump.     

Electrogenic steps of the SR Ca-ATPase enzymatic cycle and the effect of curcumin

Sarcoplasmic reticulum (SR) vesicles were adsorbed on an octadecanethiol/phosphatidylcholine mixed bilayer anchored to a gold electrode, and the Ca-ATPase contained in the vesicles was activated by ATP concentration jumps in the presence of calcium ions. The resulting capacitive current transients are compared with those calculated on the basis of the enzymatic cycle of the calcium pump. This comparison provides information on the kinetics of the E₂-E₁ conformational change and on its pH dependence. The alteration in the current transients following ATP concentration jumps in the presence of curcumin is examined. In particular, curcumin decreases the rate of slippage of the Ca-ATPase, and at concentrations above 10 μM reduces calcium transport by this pump.     

Characterization of the macrocyclic carbon suboxide factors as potent Na,K-ATPase and SR Ca-ATPase inhibitors

Recently discovered macrocyclic carbon suboxide (MCS) factors with the general formula (C(3)O(2))(n) were found to strongly inhibit rabbit and rat Na,K-ATPase as well as SR Ca-ATPase. Highly active MCS factors were obtained by a base/acid treatment of their lipophilic precursor isolated from plants. In the ESI-MS spectra, the dominant molar mass ion of 431 Da corresponds to a 1:1 complex of the carbon suboxide hexamer (n=6; M(r)=408 Da) with a Na(+) ion. Additional mass ions identified in positive and negative ion mode were assigned as complexes of the MCS hexamer (n=6) and octamer (n=8) with Na(+) or with TFA(-) in various ratios. The dominant mass ion values of these active MCS factors from plants are also found in mass spectra of previously described endogenous digitalis-like factors (EDLF) from animals. This would suggest that ubiquitously distributed MCS factors may function as putative endogenous regulatory substances of Na,K-ATPase and possibly of other ATPases. With the symmetric display of several equivalent carbonyl or hydroxy groups, the structure of MCS factors is particularly suited for interactions with proteins and other bio-molecules. This could explain the high biological activity and the unusual properties of the MCS factors.     

Kinetics of dissociation of alpha-lactalbumin complexes with Ca2+ and Mg2+ ions

Kinetics of dissociation of the complexes of bovine alpha-lactalbumin with Ca2+ and Mg2+ ions induced by mixing of the Ca2+- or Mg2+-loaded protein with the chelator of divalent cations EDTA has been studied by means of intrinsic fluorescence stopped flow method. Within the temperature region from 10 to approximately 37 degrees C the fluorescence kinetics curves for the Ca2+ removal are well fitted by one exponent with the rate constant ranging from 6.10(-3) to 1 s-1. Taking into account rather low rate of the fluorescence changes, one can assume that the limiting stage in this case is the dissociation of the single bound Ca2+ ion from the protein but not a conformational change which occurs after the Ca2+ dissociation. At temperatures above 37 degrees C the kinetics curves are best fitted by two exponents. The second exponent seems to be due to the denaturation of the apo-form of alpha-lactalbumin which takes place at these temperatures. The values of the dissociation rate constants of Mg2+ practically coincide with the values for Ca2+.     

Coincidence of H+ binding and Ca2+ dissociation in the sarcoplasmic reticulum Ca-ATPase during ATP hydrolysis

H+ and Ca2+ concentration changes in the reaction medium following MgATP addition at pH 6.0 were determined with the partially purified Ca-ATPase from sarcoplasmic reticulum vesicles in the presence of 25-50 microM CaCl2 and 5 mM MgCl2 at 4 degrees C. Previously, we showed a sequential occurrence of H+ binding and H+ dissociation in the Ca-ATPase during ATP hydrolysis and further suggested that the H+ binding takes place inside the vesicles (Yamaguchi, M., and Kanazawa, T. (1984) J. Biol. Chem. 259, 9526-9531). The present results demonstrate that the H+ binding occurred coincidently with Ca2+ dissociation from the enzyme upon conversion of the phosphoenzyme (EP) intermediate from the ADP-sensitive form to the ADP-insensitive form in the catalytic cycle of ATP hydrolysis. As KCl decreased in the medium, the extent of the H+ binding increased almost proportionately with the extent of either the Ca2+ dissociation or the accumulation of ADP-insensitive EP. Both the H+ binding and the Ca2+ dissociation were prevented by a modification of the specific SH group of the enzyme essential for the conversion of ADP-sensitive EP to ADP-insensitive EP. In the late stage of the reaction, H+ dissociation from the enzyme occurred coincidently with Ca2+ binding to the dephosphoenzyme which was formed by EP decomposition. These results are consistent with the possibility that the H+ ejection during the Ca2+ uptake with the intact vesicles previously shown by several investigators takes place through a Ca2+/H+ exchange directly mediated by the membrane-bound Ca-ATPase.     

Thermodynamics of Mg and Ca complexation with AMP,ADP, ATP

The thermodynamic parameters (ΔG, ΔH, ΔS) of complexation have been measured by potentiometric and calorimetric titration for formation of ML and MHL (M  Mg²⁺, Ca²⁺; L  AMP²⁻, ADP³⁻, ATP⁴−). The parameters are interpreted to support a model of inner sphere complexation of the metal cations to the phosphate groups with no evidence of metal-ring interaction in the ML complexes. In the MHL complexes, the protonation (of a ring nitrogen) seemingly leads to ‘backfolding’ interaction between the metal and the ring system in addition to the interaction between the metal and the phosphate groups.     

Interaction of the purified Ca2+, Mg2+-ATPase from human erythrocytes with phospholipids and calmodulin

The Ca2+-pumping ATPase has been purified in a functional form from human erythrocytes by calmodulin affinity chromatography. The purified enzyme has a specific activity at least 300-fold higher than the membrane bound enzyme. It consists of one major protein band of 140000 Dalton, and after reconstitution in liposomes it transports Ca2+ with an efficiency of at least 1 Ca2+/ATP. In the presence of calmodulin, the affinity of the enzyme for Ca2+, and its specific activity, are greatly increased. Acidic phospholipids have an unexpected effect on the isolated enzyme: ATPase isolated or reconstituted in acidic phospholipids behaves as if calmodulin were present. Acidic phospholipids mimic the effect of calmodulin.     

Interaction of Opiates with Opioid Binding Sites in the Bovine Adrenal Medulla: II. Interaction with K Sites

Abstract: In this study we examined the interaction of opiates with K binding sites in the bovine adrenal medulla. [³H]Ethylketocyclazocine (EKC), [³H]etorphine, and [³H]bremazocine stereoselective bindings were used to assay these interactions. The K sites were found to be heterogeneous: [³H]bremazocine identified with high affinity all subtypes of these sites. [³H]EKC, in the presence of saturating concentrations of [D-Ala², D-Leut]-enkephalin (DADLE) (5μM), was used to identify K¹ sites, on which dynorphin A (1–13) bound with high affinity. Either [³H]EKC or [³H]etorphine in the presence of 5μM DADLE identified the K² subtype. This subtype was found to interact with β-endorphin and especially with the octapeptide Met⁵-enkephalyl-Arg⁶-Gly⁷-Leu⁸. Furthermore, [³H]etorphine identified in the bovine adrenal medulla a third high-affinity component, in the presence of 5 μM DADLE. This residual interaction was found to be equally stereoselective and presenting K selectivity. Met⁵-enkephalyl-Arg⁶-Phe⁷ interacted preferentially with this site. The three K subtypes interacted differentially with monovalent (Na⁺, K⁺, and Li⁺) and divalent (Ca²⁺, Mg²⁺, and Mn²⁺) ions by modification of the apparent concentration of the accessible sites and/or by changes of the apparent K_D for radioligands. Modifying agents (proteolytic enzymes, thiol-modifying reagents, and A₂-phospholipase) produced different effects on each subtype of the K site, suggesting a different protein (or protein-lipid?) composition.     

Kinetics studies of the cardiac Ca-ATPase expressed in Sf21 cells: new insights on Ca-ATPase regulation by phospholamban

Kinetics studies of the cardiac Ca-ATPase expressed in Sf21 cells (Spodoptera frugiperda insect cells) have been carried out to test the hypotheses that phospholamban inhibits Ca-ATPase cycling by decreasing the rate of the E1.Ca to E1'.Ca transition and/or the rate of phosphoenzyme hydrolysis. Three sample types were studied: Ca-ATPase expressed alone, Ca-ATPase coexpressed with wild-type phospholamban (the natural pentameric inhibitor), and Ca-ATPase coexpressed with the L37A-phospholamban mutant (a more potent monomeric inhibitor, in which Leu(37) is replaced by Ala). Phospholamban coupling to the Ca-ATPase was controlled using a monoclonal antibody against phospholamban. Gel electrophoresis and immunoblotting confirmed an equivalent ratio of Ca-ATPase and phospholamban in each sample (1 mol Ca-ATPase to 1.5 mol phospholamban). Steady-state ATPase activity assays at 37 degrees C, using 5 mM MgATP, showed that the phospholamban-containing samples had nearly equivalent maximum activity ( approximately 0.75 micromol. nmol Ca-ATPase(-1).min(-1) at 15 microM Ca(2+)), but that wild-type phospholamban and L37A-phospholamban increased the Ca-ATPase K(Ca) values by 200 nM and 400 nM, respectively. When steady-state Ca-ATPase phosphoenzyme levels were measured at 0 degrees C, using 1 microM MgATP, the K(Ca) values also shifted by 200 nM and 400 nM, respectively, similar to the results obtained by measuring ATP hydrolysis at 37 degrees C. Measurements of the time course of phosphoenzyme formation at 0 degrees C, using 1 microM MgATP and 268 nM ionized [Ca(2+)], indicated that L37A-phospholamban decreased the steady-state phosphoenzyme level to a greater extent (45%) than did wild-type phospholamban (33%), but neither wild-type nor L37A-phospholamban had any effect on the apparent rate of phosphoenzyme formation relative to that of Ca-ATPase expressed alone. Measurements of inorganic phosphate (P(i)) release concomitant with the phosphoenzyme formation studies showed that L37A-phospholamban decreased the steady-state rate of P(i) release to a greater extent (45%) than did wild-type phospholamban (33%). However, independent measurements of Ca-ATPase dephosphorylation after the addition of 5 mM EGTA to the phosphorylated enzyme showed that neither wild-type phospholamban nor L37A-phospholamban had any effect on the rate of phosphoenzyme decay relative to Ca-ATPase expressed alone. Computer simulation of the kinetics data indicated that phospholamban and L37A-phospholamban decreased twofold and fourfold, respectively, the equilibrium binding of the first Ca(2+) ion to the Ca-ATPase E1 intermediate, rather than inhibiting rate of the E.Ca to E'.Ca transition or the rate of phosphoenzyme decay. Therefore, we conclude that phospholamban inhibits Ca-ATPase cycling by decreasing Ca-ATPase Ca(2+) binding to the E1 intermediate.     

Effect of thermostable protein kinase modulator on Mg, Ca-ATPase from nervous tissue]

Isoelectric focusing of a purified fraction of thermostable modulator of 3',5'-AMP-dependent protein kinase revealed five individual proteins, the main protein having an isoelectric point of 4,05. The molecular weight of this protein as determined by gel filtration is 8000--9000. The protein with a pI of 4,05 binds Ca2+ and in contrast to the original modulator inhibits the endogenous 3',5'-AMP-dependent phosphorylation of synaptic membranes. An addition of the original modulator fraction to the microsomes isolated from nervous tissue increases the Mg, Ca-ATPase activity and absorption of 45Ca. Neither the protein with a pI of 4,05 nor other individual proteins affect the activity of transport ATPase. The activating effect is partly restored after mixing of all the five subfractions. It is assumed that these proteins are aggregated by Ca2+ and change the activity of ATPase or membrane 3',5'-AMP-dependent protein kinase depending on the concentration of calcium ions.     

Interaction of Ca2+ and H+ with heme A in cytochrome oxidase

Ca²⁺ ions shift the absorption spectrum of reduced cytochromea in mitochondria by acting from the outside of the membrane. In isolated cytochrome oxidase the shift may be induced by either Ca²⁺ or H⁺, the apparent pK varying between 6.20 and 5.75 depending on the state of cytochromea ₃. Studies of the Soret band show that Ca²⁺ also shifts the spectrum of ferrocytochromea ₃ in isolated oxidase in contrast to the situation in mitochondria or isolated oxidase reconstituted into liposomes. Model studies with reduced bis-imidazole heme A reveals an analogous spectral shift induced by Ca²⁺. Esterification of the propionate carboxyls of heme A abolishes the spectral shift, suggesting that it is due to interaction of Ca²⁺ with these groups. When taken together with the data with intact mitochondria, this suggests that the propionate side chains of cytochromea are accessible to Ca²⁺ and H⁺ from the outside of the mitochondrial membrane. In the soluble enzyme both hemesa anda ₃ are accessible. Thus hemea may be located near the outside of the inner membrane whereas hemea ₃ experiences a different environment in which no Ca²⁺ shift occurs.     

Probing the Interaction of SR141716A with the CB1 Receptor

SR141716A binds selectively to the brain cannabinoid (CB1) receptor and exhibits a potent inverse agonist/antagonist activity. Although SR141716A, also known as rimonabant, has been withdrawn from the market due to severe side effects, there remains interest in some of its many potential medical applications. Consequently, it is imperative to understand the mechanism by which SR141716A exerts its inverse agonist activity. As a result of using an approach combining mutagenesis and molecular dynamics simulations, we determined the binding mode of SR141716A. We found from the simulation of the CB1-SR141716A complex that SR141716A projects toward TM5 to interact tightly with the major binding pocket, replacing the coordinated water molecules, and secures the Trp-356^6.48 rotameric switch in the inactive state to promote the formation of an extensive water-mediated H-bonding network to the highly conserved SLAXAD and NPXXY motifs in TM2/TM7. We identify for the first time the involvement of the minor binding pocket formed by TM2/TM3/TM7 for SR141716A binding, which complements the major binding pocket formed by TM3/TM5/TM6. Simulation of the F174^2.61A mutant CB1-SR141716A complex demonstrates the perturbation of TM2 that attenuates SR141716A binding indirectly. These results suggest SR141716A exerts inverse agonist activity through the stabilization of both TM2 and TM5, securing the Trp-356^6.48 rotameric switch and restraining it from activation.     

Functional Contribution of Ca2+ and Mg2+ to the Intermolecular Interaction of Visinin-like Proteins

The interaction of human visinin-like protein 1 (VILIP1) and visinin-like protein 3 (VILIP3) with divalent cations (Mg²⁺, Ca²⁺, Sr²⁺ and Ba²⁺) was explored using circular dichroism and fluorescence measurement. These results showed that the four cations each induced a different subtle change in the conformation of VILIPs. Moreover, VILIP1 and VILIP3 bound with Ca²⁺ or Mg²⁺ in a cooperative manner. Studies on the truncated mutants showed that the intact EF-3 and EF-4 were essential for the binding of VILIP1 with Ca²⁺ and Mg²⁺. Pull-down assay revealed that Ca²⁺ and Mg²⁺ enhanced the intermolecular interaction of VILIPs, and led to the formation of homo- and hetero-oligomer of VILIPs. Together with previous findings that Ca²⁺-dependent localization of VILIPs may be involved in the regulation of distinct cascades and deprivation of Ca²⁺-binding capacity of VILIPs did not completely eliminate their activity, it is likely to reflect that Mg²⁺-bound VILIPs may play a role in regulating the biological function of VILIPs in response to a concentration fluctuation of Ca²⁺ in cells.