A spectrin-dependent ATPase of the human erythrocyte membrane

Removal of spectrin from erythrocyte membranes results in the simultaneous loss of a calcium-stimulated, magnesium-dependent ATPase with an apparent KD for Ca2+ of 1 microM. This ATPase activity with high Ca2+ affinity is specifically reconstituted by addition of purified spectrin to spectrin-depleted membranes, and the reconstituted activity is directly proportional to the amount of spectrin that is reassociated with the membranes. Spectrin binding and activation of the high Ca2+ affinity Mg2+-ATPase are proportionally inhibited by thermal denaturation, trypsin digestion, or treatment of the membranes with thiol-reactive reagents. Binding of calmodulin to the Ca2+ pump ATPase requires that calmodulin contains bound ca2+. By contrast, spectrin binding to the erythrocyte membrane is Ca2+-independent. Direct assay of calmodulin is purified spectrin and absence of chlorpromazine inhibition of reconstitution demonstrate that activation of the high Ca2+ affinity ATPase resulting from spectrin binding is not a result of contamination of spectrin by calmodulin. Additional evidence that the spectrin-activated ATPase is an entity separate and distinct from the Ca2+ pump is provided by other characteristics of the activation phenomenon. It is suggested that spectrin constitutes part of an ATPase which may function as a component of the "cytoskeleton" controlling erythrocyte shape and membrane flexibility.     

Use of GTP to distinguish calcium transporting ATPase activity from other calcium dependent nucleotide phosphatases in human placental basal plasma membrane

In many cells other than the erythrocyte, the relationship between ATP dependent calcium transport and calcium dependent ATP hydrolysis is complex. The characteristics of ATP hydrolysis often differ from those of calcium transport. Demonstration of a specific transport ATPase is complicated by heterogeneity and high background activity in the presence of magnesium. In basal plasma membrane of human placental syncytiotrophoblast, the addition of 5 mM GTP greatly reduces the background release of 32Pi from 0.1 mM [gamma, 32P]-ATP. The addition of GTP permits measurement of high affinity calcium dependent ATPase under conditions which support calcium uptake. GTP does not affect the velocity of calcium uptake, and in its presence the calcium and magnesium concentration dependence of calcium uptake and calcium dependent ATPase are similar.     

Proteolytic activity of human erythrocyte membrane during ghosts preparation

1. Proteins in human erythrocyte membranes after red blood cells hemolysis revealed relatively high rate of self-digestion. 2. This indicates hemolysis as a critical moment for membrane proteases activation. 3. The detailed pattern of band 3 protein and spectrin degradation during ghosts preparation was more complicated and reflected both the changes in proteolytic susceptibility and extraction of some proteases. 4. Further extraction of membrane proteins by alkali stripping resulted in an increase in the self-digestion rate and decrease in the degradation rate of an exogenous substrate.     

Ca-2+-stimulated membrane phosphorylation and ATPase activity of the human erythrocyte.

1. Human erythrocyte membranes were preincubated with ethyleneglycolbis-(beta-aminoethyl)-N,N' tetraacetate (EGTA) and subsequently labelled for short periods with micromolar concentrations of [8-3-H, gamma-32-P]ATP. Under these conditions, and at temperatures smaller than or equal to 22 degrees C, both ATP hydrolysis and membrane phosphorylation were stimulated by Ca-2+. 2. The properties of the Ca-2+-stimulated ATP hydrolysis and associated phosphorylation of a 150 000 molecular weight protein component, previously described (Knauf, P. A., Proverbio, F. and Hoffman, J. F. (1974) J. Gen. Physiol. 63, 324-336), have been studied. The behavior of the phosphorylated component, ECaP, has properties consistent with its role as a phosphorylated intermediate of Ca-2+-ATPase activity, including: (1) similar dependence of the steady-state level of ECaP and Ca-2+-ATPase on ATP concentration; (2) rapid turnover apparent upon the addition of excess non-radioactive ATP; and (3) good correlation between the steady-state levels of Ca-2+-dependent phosphorylation and Ca-2+-ATPase activity in separate preparations possessing variable specific activity. Addition of excess EGTA to ECaP caused only partial dephosphorylation. Sensitivity of Ca-2+-stimulated ATP hydrolysis and associated phosphorylation to micromolar concentrations of Ca-2+ implicates this activity in the "high-affinity" Ca-2+-pump system of the human erythrocyte (Schatzmann, H. J. (1973) J. Physiol. London 235, 551-569).     

A new method for the preparation of band 3, the main integral protein of the human erythrocyte membrane

Band-3 protein from human erythrocyte membranes was isolated, without using detergents, by a two-step procedure: (1) The peripheral proteins were removed from the membrane by treatment with 10% acetic acid. (2) The remaining lipoprotein complex was solubilized in approximately 92% (v/v) acetic acid and then separated into its components by preparative zonal electrophoresis in a gradient made up of acetic acid, water and sucrose. Band 3 was recovered from the gradient at a yield of 60 - 70% and purity of about 95%. Approximately 25 mg of band 3 could be prepared in one run. The protein is soluble in aqueous solutions, even in the absence of organic solvents or detergents. In addition to band 3, the proteins stained by periodic acid/Schiff's reagent (the sialoglycoproteins) are also separated from the other proteins.     

Kinetic properties of the purified Ca2+-translocating ATPase from human erythrocyte plasma membrane

The basic kinetic properties of the solubilized and purified Ca2+-translocating ATPase from human erythrocyte membranes were studied. A complex interaction between the major ligands (i.e., Ca2+, Mg2+, H+, calmodulin and ATP) and the enzyme was found. The apparent affinity of the enzyme for Ca2+ was inversely proportional to the concentration of free Mg2+ and H+, both in the presence or absence of calmodulin. In addition, the apparent affinity of the enzyme for Ca2+ was significantly increased by the presence of calmodulin at high concentrations of MgCl2 (5 mM), while it was hardly affected at low concentrations of MgCl2 (2 mM or less). In addition, the ATPase activity was inhibited by free Mg2+ in the millimolar concentration range. Evidence for a high degree of positive cooperativity for Ca2+ activation of the enzyme (Hill coefficient near to 4) was found in the presence of calmodulin in the slightly alkaline pH range. The degree of cooperativity induced by Ca2+ in the presence of calmodulin was decreased strongly as the pH decreased to acid values (Hill coefficient below 2). In the absence of calmodulin, the Hill coefficient was 2 or slightly below over the whole pH range tested. Two binding affinities of the enzyme for ATP were found. The apparent affinity of the enzyme for calmodulin was around 6 nM and independent of the Mg2+ concentration. The degree of stimulation of the ATPase activity by calmodulin was dependent on the concentrations of both Ca2+ and Mg2+ in the assay system.     

Interaction of chlorpromazine with the human erythrocyte membrane

The interaction of the amphipath chlorpromazine (CPZ) with the human erythrocyte membrane was evaluated. The partition coefficient of CPZ between the membrane bilayer and the aqueous compartment, measured spectrophotometrically, ranged between 1 and 3 X 10(3). An independent estimate, 4.6 X 10(3), was obtained by a novel method which avoided the measurement of binding and determined instead the variation of the hemolytic potency of the amphipath with the ratio of buffer volume to membrane volume. The maximal uptake of CPZ exceeded 2 X 10(9) molecules/red cell, corresponding to a volume greater than that of the bilayer itself. Such heavily loaded membranes were increased in thickness more than 2-fold, suggesting the formation of a CPZ-rich zone at the center of the bilayer. Ghosts loaded with massive levels of CPZ condensed approximately 20-fold in surface area and increased proportionately in thickness, suggesting the formation of a novel CPZ-lipid solution. CPZ caused hemolysis by a colloid-osmotic mechanism. By measuring the simultaneous uptake of mannitol and sucrose, we determined that CPZ induced holes of constant size but variable number. If circular, the holes would have had a diameter of approximately 14 A. The time-averaged number of holes ranged from 0.09 per cell (signifying intermittency) to 16. Freeze-fracture electron microscopy of CPZ-treated red cells revealed multiple round patches of nearly particle-free bilayer up to 0.3 micron in diameter with crowding of the intramembrane particles into the surrounding membrane. We interpret these images to signify lateral phase separation within the CPZ-treated bilayer. Hemolysis could, therefore, result from the intermittent opening of weak seams at phase boundaries; these could then be fluctuating slits approximately 14 A in width and of variable length, rather than simple circular holes.     

Evidence of voltage-induced channel opening in Na/K ATPase of human erythrocyte membrane

Summary Previous studies have shown that human erythrocytes when subjected to a high voltage pulsation, in the microsecond time range, lysed in an isotonic medium. The hemolysis was the result of the colloid osmotic swelling, which, in turn, was caused by the voltage perforation of the red cell membranes. In this work we demonstrate that in a low ionic medium at least 35% of the pores was related to the opening of Na⁺/K⁺ ATPase channels. The membrane conductance generated by the externally applied electric field could be partially blocked by a specific inhibitor, ouabain, or by a specific cross-linking reagent, Cu⁺⁺-phenanthroline, of the ATPase. The effect of ouabain was saturable and had a mid-point of saturation at 0.15 m. This value agrees with the physiological inhibition constant of the drug. K⁺ ion in the external medium suppressed the effect of ouabain, as has also been demonstrated in physiological studies. Experiment presented in this communication also suggests that the Na⁺/K⁺ ATPase was not perforable in a high ionic medium, and that a large fraction of the voltage-induced pores occurred at as yet unidentified sites.     

Production of 1,2-diacylglycerol in human erythrocyte membranes exposed to low concentrations of calcium ions

A specific increase in the membrane content of 1,2-diacylglycerol occurred when erythorcytes were lysed at 20 °C in media which did not include a chelator of Ca²⁺ and also when Ca²⁺ was added to haemoglobin-free erythrocyte ghosts which had been prepared in the presence of ethyleneglycol-bis-(β-aminoethylether)-N,N′-tetraacetic acid (EGTA). The maximum increase was about 20-fold. The production of 1,2-diacylglycerol appeared to be caused by an endogenous membrane-bound phospholipase C which was half-maximally activated at less than 1 μM Ca²⁺ and which had access to only about 0.6–0.8% of the cells' glycerolipids. This activity was optimal at pH 7.0–7.2 in the presence of 0.1 mM Ca²⁺; under these conditions diacylglycerol production was complete within 5–10 min. Enzyme activity was markedly decreased at low temperatures, and was abolished by heating at 100 °C for 1 min.     

Alterations of human erythrocyte membrane fluidity by oxygen-derived free radicals and calcium

Two possible reasons for the structural alterations of cell membranes caused by free radicals are lipid peroxidation and an increase in the intracellular calcium ion concentration. To characterize the alterations in membrane molecular dynamics caused by oxygen-derived free radicals and calcium, human erythrocytes were spin-labeled with 5-doxyl stearic acid, and alterations in membrane fluidity were quantified by electron spin resonance oxidase (0.07 U/mL) decreased membrane fluidity, and the addition of superoxide dismutase and catalase inhibited the effect on membrane fluidity of the hypoxanthine-xanthine oxidase system. Hydrogen peroxide (0.1 and 1 nM) also decreased membrane fluidity and caused alterations to erythrocyte morphology. In addition, a decrease in membrane fluidity was observed in erythrocytes incubated with 2.8 mM CaCl₂. On the other hand, incubation of erythrocytes with calcium-free solution decreased the changes in membrane fluidity caused by hydrogen peroxide.

These results suggest that changes in membrane fluidity are directly due to lipid peroxidation and are indirectly the result of increased intracellular calcium concentration. We support the hypothesis that alterations of the biophysical properties of membranes caused by free radicals play an important role in cell injury, and that the accumulation of calcium amplifies the damge to membranes weakened by free radicals.     

Role of membrane-bound calcium in changes in the ATPase activity, permeability and structural state of human erythrocyte membranes]

A study was conducted on the reconstituted erythrocytes obtained by the method of fast reversible hemolysis. The concentration of free Ca2+ ions in the reconstituted erythrocytes was supported by Ca-EGTA and Ca-nitrate buffers. Oubain-uninhibited ATPase component with a high affinity for Ca2+ (K0.5=4 micron) and alteration of passive and active K+-permeability in the region of free Ca2+ concentration up to 10 micron could be determined only when the content of membrane-bound Ca+ varied. Depletion of the inner side of the membrane of reconstituted erythrocyte is accompanied by alteration of hydrophobic character of the hydrocarbon region of the membrane. It is suggested that Ca+-induced alterations in the structure of the erythrocyte membrane may be a direct cause of the alterations in ATPase activity with a high Ca2+ affinity and permeability for univalent cations.