Short-chain alkanols and the functional efficiency of the Ca pump in the sarcoplasmic reticulum of rabbit skeletal muscles

The effect of 10 low molecular mass alkanols on the activity of Ca-ATPase (EC 3.6.1.38), Ca uptake and Ca efflux as well as the functional efficiency of the Ca pump in the fragmented sarcoplasmic reticulum of rabbit skeletal muscles has been studied. Some alkanols, especially when taken at low concentration, have been found to stimulate the activity of the Ca pump and Ca-ATPase, namely tert-butanol, isopropanol and ethanol (from the group of hydrophilic alkanols), and pentanol, isopentanol and hexanol (from the more hydrophobic alkanols). Methanol (from the first group) and isobutanol, butanol and propanol (from the second) do not stimulate the Ca pump compared with the control. The specific effect of different alkanols cannot be explained in terms of a unitary mechanism based on 'fluidity' changes of the membrane. It is assumed that, at low concentrations, certain alkanols (or groups of related alkanols) are able to promote the specific transition of membrane proteins into the active state, whereas at higher concentrations all alkanols provide for the non-functional state of the proteins.     

The role of free calmodulin in the regulation of calcium-pump activity in erythrocytes

The activity of Ca-pump in inside-out oriented vesicles obtained from erythrocyte membranes after their 30 min treatment with EGTA at 20 degrees C (membranes A) and 37 degrees C (membranes B) was investigated. It was shown that in membranes A placed into an incubation medium containing 0.1 mM EGTA (pH 7.4) the overall effect of exogenous calmodulin is due to the increase in the maximal activity of the enzyme, its affinity for Ca2+ being unaffected thereby. In membranes B placed into the same medium (pH 6.75) the activation of the Ca-pump by calmodulin is due to the increased affinity for Ca2+ at a constant maximal activity of the enzyme. The dependencies of the value of the calmodulin-stimulated component of membranes A and the Ca2+-binding capacity of calmodulin measured by the intensity of N-phenyl-1-naphthylamine fluorescence on the concentration of free Ca2+ are coincident. In the case of membranes B, the stimulation of Ca-pump by calmodulin occurs at much lower Ca2+ concentrations than the Ca2+ binding-induced conformational shifts in calmodulin. The experimental results suggest that the affinity of the Ca-pump for Ca2+ may affect calmodulin existing in a Ca2+-independent state. The hydrophobic interactions between the Ca-calmodulin complex and the Ca-ATPase molecule are apparently essential for the regulation of the maximal enzyme activity.     

Mechanism of involvement of calmodulin in the regulation of affinity to Ca2+ and maximum activity of Ca-pump in the erythrocyte membrane

The activity of the Ca-pump in inside-out oriented human erythrocyte membrane vesicles was studied with the use of 45Ca and membrane filters. It was found that trifluoroperazine fully inhibits the calmodulin-induced increase in the maximal activity of the Ca-pump without affecting the calmodulin-stimulated increase in the Ca-pump affinity for Ca2+. The dependence of calcium concentrations of calmodulin-stimulated components of the Ca-pump activity, both inhibited and noninhibited by trifluoroperazine, as well as the dependence on calcium concentrations of the fluorescence intensity of N-phenyl-1-naphthylamine were analyzed. This analysis revealed essential differences between the mechanisms of calmodulin action on the maximal activity of the Ca-pump and its affinity for Ca2+. The maximal activity was elevated by addition of the Ca-calmodulin complex, whereas the increase in the affinity for Ca2+ was induced by calmodulin alone. These findings were supported by data on the dependence of the Ca-pump activity on calmodulin concentrations at low and saturating concentrations of Ca2+ as well as by data obtained in the study on moderate treatment of erythrocyte membranes with trypsin.     

Intestinal basolateral membrane Ca-ATPase activity with properties distinct from those of the Ca-pump

The Ca-pump in rat intestinal basolateral membranes had been studied previously as vesicular ATP-dependent Ca-uptake. In the present studies, Ca-stimulated ATP hydrolysis (Ca-ATPase activity) was measured and found to differ from the Ca-pump in having higher activity and being insensitive to vanadate. Whereas the pump was specific for ATP, hydrolytic activity was found with ATP, GTP or ADP but not with AMP or p-nitro-phenyl-phosphate. In contrast to Ca-pump activity, Ca-ATPase activities were similar for different intestinal segments, for duodenal villus/crypt cell-fractions and for vitamin D-deficient animals. Thus, as usually measured, intestinal basolateral membrane Ca-ATPase activity is not equivalent to the Ca-pump.     

An autoinhibitory peptide from the erythrocyte Ca-ATPase aggregates and inhibits both muscle Ca-ATPase isoforms.

We have studied the effects of C28R2, a basic peptide derived from the autoinhibitory domain of the plasma membrane Ca-ATPase, on enzyme activity, oligomeric state, and E1-E2 conformational equilibrium of the Ca-ATPase from skeletal and cardiac sarcoplasmic reticulum (SR). Time-resolved phosphorescence anisotropy (TPA) was used to determine changes in the distribution of Ca-ATPase among its different oligomeric species in SR. C28R2, at a concentration of 1-10 microM, inhibits the Ca-ATPase activity of both skeletal and cardiac SR (CSR). In skeletal SR, this inhibition by C28R2 is much greater at low (0.15 microM) than at high (10 microM) Ca2+, whereas in CSR the inhibition is the same at low and high Ca2+. The effects of the peptide on the rotational mobility of the Ca-ATPase correlated well with function, indicating that C28R2-induced protein aggregation and Ca-ATPase inhibition are much more Ca-dependent in skeletal than in CSR. In CSR at low Ca2+, phospholamban (PLB) antibody (functionally equivalent to PLB phosphorylation) increased the inhibitory effect of C28R2 slightly. Fluorescence of fluorescein 5-isothiocyanate-labeled SR suggests that C28R2 stabilizes the E1 conformation of the Ca-ATPase in skeletal SR, whereas in CSR it stabilizes E2. After the addition of PLB antibody, C28R2 still stabilizes the E2 conformational state of CSR. Therefore, we conclude that C28R2 affects Ca-ATPase activity, conformation, and self-association differently in cardiac and skeletal SR and that PLB is probably not responsible for the differences.     

A possible role for the dimer ribbon state of scallop sarcoplasmic reticulum. Dimmer ribbons are associated with stabilization of the Ca(2+)-free Ca-ATPase

The Ca-ATPase activity of membranous scallop sarcoplasmic reticulum was found to be unstable when the Ca(2+)-binding sites on the Ca-ATPase were unoccupied. The decay in activity could be slowed or halted by inclusion in the preincubation medium of Na+, K+, nucleotides, ethylene glycol, or high concentrations of choline chloride. Stabilization of the Ca(2+)-free Ca-ATPase by Na+ and K+ showed a markedly different concentration dependence to that seen with activation of the Ca(2+)-activated ATPase activity by the two ions. Examination in the electron microscope of scallop membranes negatively stained in the presence of EGTA under conditions where the enzyme had been stabilized against lack of Ca2+ always showed vesicles containing dimer ribbon structures, whereas unstabilized membranes did not show dimer ribbons. There was an association between the effectiveness of a medium in stabilizing the enzyme in the presence of EGTA and the extent and quality of the dimer arrays seen in the microscope. Comparison of the range of Ca2+ concentration over which the Ca(2+)-binding sites on the scallop Ca-ATPase titrated with the range over which the dimer ribbon structural state was lost indicated that the Ca(2+)-binding sites on the Ca-ATPase must be empty for dimer ribbon formation to occur. Previous studies (Franzini-Armstrong, C., Ferguson, D. G., Castellani, L., and Kenney, L. J. (1987) Ann. N. Y. Acad. Sci. 483, 44-56) have found that the Ca-ATPase molecules in scallop adductor muscle freeze-fractured after fixation under relaxing conditions are arranged in dimer ribbons. Thus, the association of stabilization of the Ca(2+)-free Ca-ATPase with the presence of dimer ribbons implies that one function of the dimer state may be to stabilize the scallop enzyme in situ, when the Ca2+ concentration in the sarcoplasm is low and the muscle is relaxed.     

Interaction of different nucleotides with Ca-release channels from heavy sarcoplasmic reticulum

Calcium accumulation and release from the heavy fraction of sarcoplasmic reticulum vesicles have been studied in the presence of different nucleotides with the use of the Ca-sensitive dye antipyrylazo III for monitoring of the free Ca2+ concentration. The calcium- and caffeine-induced Ca2+ release is observed only with ATP but not with any of nonadenine nucleotides used as substrates for the Ca-pump. Adenine nucleotides provide for a rapid ruthenium red sensitive Ca2+ release from the vesicles, when nonadenine nucleotides are used as energy sources for Ca2+ uptake. A comparison of the nucleotides interaction with Ca-channels and Ca-ATPase supports the hypothesis that Ca-ATPase is involved in the operation of Ca-channels.     

Dependence of the red blood cell calcium pump on the membrane potential

(1) It is shown that the rate of calcium extrusion from intact human red cells is faster at a membrane potential of approximately +50 mV (inside) than at approximately -50 mV. (2) The positive potential applied was the chloride potential of KCl cells in a K-gluconate medium when the Ca2+ sensitive K+ channel was blocked by 0.3mM quinidine. The negative potential resulted from the high K+ permeability in Ca2+ loaded cells (the cells were loaded to a Ca2+ activity in the cell water of about 50 microM). (3) It is further demonstrated that the Ca2+ affinity of the pump ATPase is decreased both at the internal (high affinity) and external (low affinity) site by increasing the proton concentration. Acidification thus inhibits internally and stimulates externally. (4) An indirect effect of the membrane potential on the pump activity via the accompanying pH shifts on either side of the membrane could be ruled out by choosing Ca2+ concentrations which are fully activating at the internal Ca2+ binding site at pH 6.5 and not yet inhibitory at the external Ca2+ binding site at pH 8. (5) The result is compatible with the assumption that the human red cell Ca-pump is exchanging Ca2+ for protons, yet is electrogenic by virtue of a stoichiometry of 1H+:1Ca2+ for this exchange.     

Role of interprotein interactions in the regulation of the sarcoplasmic reticulum Ca-pump

The data on the structural state of sarcoplasmic reticulum membranes in skeletal muscles of rabbit were obtained by EPR-spectroscopy, fluorescent analysis and flash-photolysis and discussed in the paper. Comparison of the functional state of Ca-pump and variations in hydrophobic volume and membrane microviscosity permits concluding that thermoinduced anomalies of the enzymic activity are due to changes in the phase state of lipids. It is shown that changes in the physiochemical state of lipids affect the interprotein interactions in the oligomeric Ca-pump structure. In this case ATP weakens the interaction between Ca-pump globules, while a decrease in the hydrophobic membrane volume intensifies it. An assumption is advanced that the modifying ATP effect on Ca-pump is based on an increase in the functional independence of Ca2+-ATPase monomers, and therefore it is under the control of the membrane lipid phase.     

Assessment of the role of endogenous regulators in the activation of Ca-ATPase in erythrocyte membranes

The contribution of calmodulin and protein kinases A or C to the activation of membrane Ca-ATPase was studied on saponin-permeabilized rat erythrocytes. In the presence of all endogenous regulators, the dependence of the Ca-ATPase activity of Ca2+ concentration was described by a bell-shaped curve with a maximum at 2-5 microM Ca2+; K0.5 = 0.43 microM Ca2+. Washing of erythrocyte membranes with 5-10 microM Ca2+ maintained up to 75% of the ATPase activity, while washing with EGTA (2 mM) decreased the activity, on the average, 5-fold, and increased K0.5 up to 0.54-0.6 microM Ca2+. An addition of an EGTA extract to washed membranes restored up to 75% of the original ATPase activity, while calmodulin restored about 40% of the original Ca-ATPase activity and decreased K0.5 to 0.23-0.3 microM Ca2+. The calmodulin inhibitor R24571 failed to alter the Ca-ATPase activity in permeabilized erythrocytes but slightly diminished it in reconstituted membranes. The protein kinase C inhibitors H7 and polymyxin increased the Ca-ATPase activity in permeabilized red cells and suppressed it in reconstituted membranes. The data obtained suggest that in native red cell membranes Ca-ATPase is activated by regulator(s) dependent on Ca2+ and protein kinase which are other than calmodulin.     

Does calmodulin participate in the regulation of the Ca-pump of erythrocytes in vivo?

Using a highly effective chelator of Ca2+ and 45Ca, the concentration of Cai2+ in human and rat erythrocytes was measured both at normal and accelerated Ca2+ influx into the cells. No effect of the calmodulin-dependent reaction inhibitor R24571 was observed. The Ca-ATPase from saponin-treated erythrocytes was characterized by a high affinity for Ca2+ (K 0.5-0.7 microM). This value is 2-3 times as low as that for Ca2+ concentration causing a 50% increase of the Ca-ATPase activity in erythrocyte ghosts obtained during hypoosmotic hemolysis. The Ca-ATPase activity in saponin-treated erythrocytes did not change either under the effect of calmodulin or by R24571. It was assumed that calmodulin did not participate in the regulation of the Ca2+-pump operation in erythrocytes in vivo.     

Effects of calcium and soluble cytoplasmic activator protein (calmodulin) on various states of (Ca2+ + Mg2+)-ATPase activity in isolated membranes of human red cells

(Ca2+ + Mg2+)-ATPase activity of red cells and their isolated membranes was investigated in the presence of various Ca2+ concentrations and cytoplasmic activator protein. Red cell ATPase activity was high at low Ca2+ concentrations, and low at moderate and high concentrations of Ca2+. In the case of isolated membranes, both low and moderate ca2+ concentrations produced higher (Ca2+ + Mg2+)-ATPase activity than high Ca2+ concentration. Membrane-free hemolysate containing soluble activator of (Ca2+ + Mg2+)-ATPase produced a significant increase in (Ca2+ + Mg2+)-ATPase activity only at low ca2+ concentration. Regardless of Ca2+ and activator concentrations, the enzyme activity in the membrane was lower than lysed red cells. The low level of (Ca2+ + Mg2+)-ATPase activity seen at high Ca2+ concentration can be augmented by lowering the Ca2+ concentration of EGTA in the assay medium. However, once the membrane was exposed to a high Ca2+ concentration, the activator could no longer exert it maximum stimulation at the low Ca2+ concentration brought about by addition of EGTA. This loss of activation was not attributable to the Ca2+-induced denaturation of activator protein but rather related to the alteration of (Ca2+ + Mg2+)-ATPase states in the membrane. On the basis of these data, it is suggested that only a small portion of (Ca2+ + Mg2+)-ATPase activity of isolated membranes can be stimulated by the soluble activator and that (ca2+ + Mg2+)ATPase most likely exists in various states depending upon ca2+ concentration and the presence of activator. The enzyme state exhibiting the high degree of stimulation by activator may undergo irreversible damage in the presence of high Ca2+ concentrations.     

Calcium transport and calcium-ATPase activity in human lymphocyte plasma membrane vesicles

We have studied Ca transport and the Ca-activated Mg-ATPase in plasma membrane vesicles prepared from normal human lymphocytes. Membrane vesicles that were exposed to oxalate as a Ca-trapping agent accumulated Ca in the presence of Mg2+ and ATP. ADP, AMP, GTP, UTP, ITP, TTP, or CTP did not substitute for ATP in energizing uptake. The Vmax for Ca uptake was 2.4 pmol of Ca/micrograms of protein/min, and the Km values for Ca and ATP were 1.0 and 80 microM, respectively. One microM A23187, added initially, completely inhibited net Ca uptake and, if added later, caused the release of Ca accumulated previously. Cyanide, oligomycin, ouabain, or varying Na+ or K+ concentrations had no effect on Ca uptake. A Ca-activated ATPase was present in the same membrane vesicles, which had a Vmax of 25 pmol of Pi/micrograms of protein/min at a free Ca concentration of 4-5 microM. This Ca-ATPase had Km values for Ca and ATP of 0.6 and 90 microM, respectively. These kinetic parameters were similar to those observed for uptake of Ca by the vesicles. The Ca-ATPase activity was insensitive to azide, oligomycin, ouabain, or varying Na+ or K+ concentrations. No Ca-activated hydrolysis of GTP or UTP was observed. Both Ca transport and the Ca-ATPase activity of ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid-treated lymphocyte plasma membranes were stimulated 2-fold by a cytoplasmic component (calmodulin) that was purified 500-fold from lymphocyte cytoplasm. Thus, human lymphocyte plasma membranes have both a Ca transport activity and a Ca-stimulated ATPase activity with similar substrate affinities and specificities and similar sensitivities to calmodulin.     

Alcohols produce reversible and irreversible acceleration of phospholipid flip-flop in the human erythrocyte membrane.

The slow, non-mediated transmembrane movement of the lipid probes lysophosphatidylcholine, NBD-phosphatidylcholine and NBD-phosphatidylserine in human erythrocytes becomes highly enhanced in the presence of 1-alkanols (C2-C8) and 1,2-alkane diols (C4-C8). Above a threshold concentration characteristic for each alcohol, flip rates increase exponentially with the alcohol concentration. The equieffective concentrations of the alcohols decrease about 3-fold per methylene added. All 1-alkanols studied are equieffective at comparable calculated membrane concentrations. This is also observed or the 1,2-alkane diols, albeit at a 5-fold lower membrane concentration. At low alcohol concentrations, flip enhancement is reversible to a major extent upon removal of the alcohol. In contrast, a residual irreversible flip acceleration is observed following removal of the alcohol after a treatment at higher concentrations. The threshold concentrations to produce irreversible flip acceleration by 1-alkanols and 1,2-alkane diols are 1.5- and 3-fold higher than those for flip acceleration in the presence of the corresponding alcohols. A causal role in reversible flip-acceleration of a global increase of membrane fluidity or membrane polarity seems to be unlikely. Alcohols may act by increasing the probability of formation of transient structural defects in the hydrophobic barrier that already occur in the native membrane. Membrane defects responsible for irreversible flip-acceleration may result from alterations of membrane skeletal proteins by alcohols.     

A Ca2+-stimulated adenosine triphosphatase in Golgi-enriched membranes of lactating murine mammary tissue.

A membrane fraction isolated from lactating murine mammary tissue and enriched for the Golgi membrane marker enzyme galactosyltransferase exhibited Ca2+-stimulated ATPase activity (Ca-ATPase) in 20 microM-free Mg2+ and 10 microM-MgATP, with an apparent Km for Ca2+ of 0.8 microM. Exogenous calmodulin did not enhance Ca2+ stimulation, nor could Ca-ATPase activities be detected in millimolar total Mg2+ and ATP. When assayed with micromolar Mg2+ and MgATP the Ca-ATPases of skeletal-muscle sarcoplasmic reticulum and of calmodulin-enriched red blood cell plasma membranes were half-maximally activated by 0.1 microM- and 0.6 microM-Ca2+ respectively. All three Ca-ATPases were inhibited by similar micromolar concentrations of trifluoperazine, but the Golgi activity was unaffected by quercetin in concentrations which completely inhibited both the sarcoplasmic-reticulum and red-blood-cell enzymes. The results are consistent with the hypothesis that the high-affinity Ca-ATPase is responsible for the ATP-dependent Ca2+ transport exhibited by Golgi-enriched vesicles derived from lactating mammary gland [Neville, Selker, Semple & Watters (1981) J. Membr. Biol. 61, 97-105; West (1981) Biochim. Biophys. Acta 673, 374-386].     

Spectral and catalytical properties of the sarcoplasmic reticulum Ca-ATPase labeled with N-cyclohexyl-N'-(4-dimethylamino-1-naphthyl)-carbodiimide

N-Cyclohexyl-N'-(dimethylamino)-carbodiimide (NCD-4) labels three sites in the sarcoplasmic reticulum Ca-ATPase which can be resolved by their spectral properties and by their effects on the catalytical activity of the enzyme. One site is not protectable by Ca2+ ions or by dicyclohexylcarbodiimide and is not essential for catalytical activity. Two Ca2+-protectable sites, whose modification leads to a biphasic inhibition of Ca-ATPase activity, have fluorescence emission maxima at 407 nm and 425 nm. The Ca-ATPase modified by NCD-4 hydrolyses ATP but does not translocate Ca2+ nor does it undergo the conformational changes associated with Ca2+ binding in the native enzyme. High concentrations of Ca2+ induce slow biphasic fluorescence quenching in the Ca-ATPase labeled selectively at the 407-nm site but the signals are largely abolished by modification of the 425-nm site. Both vanadate ions and ATP reverse this Ca2+-induced fluorescence quenching. It is proposed that NCD-4 labels the two high-affinity Ca2+-binding sites of the Sarcoplasmic reticulum Ca-ATPase and that the conformational changes in the modified enzyme may reflect interactions between the two sites.     

Alternative membrane protein conformations in alcohols

Alcohols modulate the oligomerization of membrane proteins in lipid bilayers. This can occur indirectly by redistributing lateral membrane pressure in a manner which correlates with alcohol hydrophobicity. Here we investigate the direct impact of different alcohol-water mixtures on membrane protein stability and solubility, using the two detergent-solubilized alpha-helical membrane proteins DsbB and NhaA. Both proteins precipitate extensively at intermediate concentrations of alcohols, forming states with extensive (40-60%) beta-sheet structure and affinity for the fibril-specific dye thioflavin T, although atomic force microscopy images reveal layer-like and spherical deposits, possibly early stages in a fibrillation process trapped by strong hydrophobic contacts. At higher alcohol concentrations, both DsbB and NhaA are resolubilized and form non-native structures with increased (DsbB) or decreased (NhaA) helicity compared to the native state. The alternative conformational states cannot be returned to the functional native state upon dilution of alcohol. The efficiency of precipitation and the degree to which DsbB is destabilized at low alcohol concentrations show the same correlation with alcohol hydrophobicity. Thus, in addition to their effect on the membrane, alcohols perturb membrane proteins directly by solvating the hydrophobic regions of the protein. At intermediate concentrations, this perturbation exposes hydrophobic segments but does not provide sufficient solvation to avoid intermolecular association. Resolubilization requires a reduction in the relative dielectric constant below 65 in conjunction with specific properties of the individual alcohols. We conclude that alcohols provide access to a diversity of conformations for membrane proteins but are not a priori suitable for solution studies requiring reversible denaturation of monomeric proteins.     

Effect of tetracaine and sovcaine on the ATP-dependent calcium accumulation in sarcoplasmic reticulum vesicles of skeletal muscles

The tetracaine and cinchocaine in concentration less than 2 mM and 0.5 mM, respectively, stimulate ATP-dependent Ca-loading by enhancing the initial rate of Ca2+-accumulation, do not affect the Ca2+-binding and Ca-ATPase activity of sarcoplasmic reticulum vesicles. These data suggest blocking of Ca2+-efflux from vesicles which occurs during Ca-accumulation. Higher concentrations of the same compounds (above 2 mM and 0.5 mM for tetracaine and cinchocaine, respectively) caused inhibition of the Ca-ATPase activity and decreased the ability of SR vesicles to retain Ca2+, probably, due to their nonspecific lipophilic action.     

Plasma Membrane Ca-ATPase of Radish Seedlings : II. Regulation by Calmodulin

The effect of calmodulin on the activity of the plasma membrane Ca-ATPase was investigated on plasma membranes purified from radish (Raphanus sativus L.) seedlings. Calmodulin stimulated the hydrolytic activity and the transport activity of the plasma membrane Ca-ATPase to comparable extents in a manner dependent on the free Ca²⁺ concentration. Stimulation was marked at low, nonsaturating Ca²⁺ concentrations and decreased increasing Ca²⁺, so that the effect of calmodulin resulted in an increase of the apparent affinity of the enzyme for free Ca²⁺. The pattern of calmodulin stimulation of the plasma membrane Ca-ATPase activity was substantially the same at pH 6.9 and 7.5, in the presence of ATP or ITP, and when calmodulin from radish seeds was used rather than that from bovine brain. At pH 6.9 in the presence of 5 micromolar free Ca²⁺, stimulation of the plasma membrane Ca-ATPase was saturated by 30 to 50 micrograms per milliliter bovine brain calmodulin. The calmodulin antagonist calmidazolium inhibited both basal and calmodulin-stimulated plasma membrane Ca-ATPase activity to comparable extents.     

Ability of nucleoside triphosphates to provide for Ca 2+ transport by sarcoplasmic reticulum fragments

The Ca2+ transport by sarcoplasmic reticulum fragments was studied. ATP, CTP, ITP, GTP and UTP provided the same Ca-pump efficiency. When the NTP was exhausted, Ca2+ actively accumulated from the sarcoplasmic reticulum vesicles outflow, and with the higher rate of ATP was a substrate. The Ca-ATPase conformational transitions induced by ATP are discussed for their role in the provision of energy.