A method for estimating free Ca within human red blood cells, with an application to the study of their Ca-dependent K permeability

Evidence against a Role of Elevated Intracellular Ca2+ during Plasmodium falciparum Preinvasion

Severe malaria is primarily caused by Plasmodium falciparum parasites during their asexual reproduction cycle within red blood cells. One of the least understood stages in this cycle is the brief preinvasion period during which merozoite-red cell contacts lead to apical alignment of the merozoite in readiness for penetration, a stage of major relevance in the control of invasion efficiency. Red blood cell deformations associated with this process were suggested to be active plasma membrane responses mediated by transients of elevated intracellular calcium. Few studies have addressed this hypothesis because of technical challenges, and the results remained inconclusive. Here, Fluo-4 was used as a fluorescent calcium indicator with optimized protocols to investigate the distribution of the dye in red blood cell populations used as P. falciparum invasion targets in egress-invasion assays. Preinvasion dynamics was observed simultaneously under bright-field and fluorescence microscopy by recording egress-invasion events. All the egress-invasion sequences showed red blood cell deformations of varied intensities during the preinvasion period and the echinocytic changes that follow during invasion. Intraerythrocytic calcium signals were absent throughout this interval in over half the records and totally absent during the preinvasion period, regardless of deformation strength. When present, calcium signals were of a punctate modality, initiated within merozoites already poised for invasion. These results argue against a role of elevated intracellular calcium during the preinvasion stage. We suggest an alternative mechanism of merozoite-induced preinvasion deformations based on passive red cell responses to transient agonist-receptor interactions associated with the formation of adhesive coat filaments.

Protein 4.2 binds to the carboxyl-terminal EF-hands of erythroid alpha-spectrin in a calcium- and calmodulin-dependent manner

Spectrin and protein 4.1 cross-link F-actin protofilaments into a network called the membrane skeleton. Actin and 4.1 bind to one end of beta-spectrin. The adjacent end of alpha-spectrin, called the EF-domain, is calmodulin-like, with calcium-dependent and calcium-independent EF-hands. It has no known function. However, the sph(1J)/sph(1J) mouse has very fragile red cells and lacks the last 13 amino acids in the EF-domain, suggesting the domain is critical for skeletal integrity. Using pulldown binding assays, we find the alpha-spectrin EF-domain either alone or incorporated into a mini-spectrin binds native and recombinant protein 4.2 at a previously identified region of 4.2 (G(3) peptide). Native 4.2 binds with an affinity comparable with other membrane skeletal interactions (K(d) = 0.30 microM). EF-domains bearing the sph(1J) mutation are inactive. Binding of protein 4.2 to band 3 (K(d) = 0.45 microM) does not interfere with the spectrin-4.2 interaction. Spectrin-4.2 binding is amplified by micromolar concentrations of Ca(2+) (but not Mg(2+)) by three to five times. Calmodulin also binds to the EF-domain (K(d) = 17 microM), and Ca(2+)-calmodulin blocks Ca(2+)-dependent binding of protein 4.2 but not Ca(2+)-independent binding. The data suggest that protein 4.2 is located near protein 4.1 at the spectrin-actin junctions. Because proteins 4.1 and 4.2 also bind to band 3, the erythrocyte anion channel, we suggest that one or both of these proteins cause a portion of band 3 to localize near the spectrin-actin junctions and provide another point of attachment between the membrane skeleton and the lipid bilayer.

Cytoplasmic calcium buffers in intact human red cells

1. Precise knowledge of the cytoplasmic Ca2+ buffering behaviour in intact human red cells is essential for the characterization of their [Ca2+]i-dependent functions. This was investigated by using a refined method and experimental protocols which allowed continuity in the estimates of [Ca2+]i, from nanomolar to millimolar concentrations, in the presence and absence of external Ca2+ chelators. 2. The study was carried out in human red cells whose plasma membrane Ca2+ pump was inhibited either by depleting the cells of ATP or by adding vanadate to the cell suspension. Cytoplasmic Ca2+ buffering was analysed from plots of total cell calcium content vs. ionized cytoplasmic Ca2+ concentration ([CaT]i vs. [Ca2+]i) obtained from measurements of the equilibrium distribution of 45Ca2+ at different external Ca2+ concentrations ([Ca2+]o), in conditions known to clamp cell volume and pH. The equilibrium distribution of 45Ca2+ was induced by the divalent cation ionophore A23187. 3. The results showed the following. (i) The known red cell Ca2+ buffer represented by alpha, with a large capacity and low Ca2+ affinity, was the main cytoplasmic Ca2+ binding agent. (ii) The value of alpha was remarkably constant; the means for each of four donors ranged from 0.33 to 0.35, with a combined value of all independent measurements of 0.34 +/- 0.01 (mean +/- S.E.M., n = 16). This contrasts with the variability previously reported. (iii) There was an additional Ca2+ buffering complex with a low capacity (approximately 80 micromol (340 g Hb)(-1)) and intermediate Ca2+ affinity (apparent dissociation constant, K(D,app) approximately 4-50 microM) whose possible identity is discussed. (iv) The cell content of putative Ca2+ buffers with submicromolar Ca2+ dissociation constants was below the detection limit of the methods used here (less than 2 micromol (340 g Hb)(-1)). 4. Vanadate (1 mM) inhibited the Vmax of the Ca2+ pump in inosine-fed cells by 99.7%. The cytoplasmic Ca2+ buffering behaviour in these cells was similar to that found in ATP-depleted cells.

Aspects of the haemolytic reaction induced by Kanagawa haemolysin of Vibrio parahaemolyticus

Vibrio parahaemolyticus, an important enteric pathogen, produces toxin (Kanagawa haemolysin, KH), the presence of which correlates well with pathogenicity. KH induced lysis of human red blood cells (HRBC); the kinetics were strongly dependent on KH concentration (0-1 HU/ml) and rather independent of target cell concentration [0.5 < or = haematocrit (%) < or = 6] and the ratio KH:HRBC. The suggestion that KH-induced haemolysis is due to colloid osmosis is supported by results indicating: (1) osmotic protection (by suspension in iso-osmotic choline chloride, D-sorbitol or L-valine, or MOPS-buffered saline with added sucrose), (2) a cell volume increase prior to lysis, and (3) an increase in HRBC cation (86Rb+) influx after KH addition, indicating raised passive cation permeation. The effect of temperature on KH-induced haemolysis indicates the importance of processes other than the action of a simple water-filled pore, because of the high activation energy [53.30 +/- 2.79 kJ (mol.)-1] involved. Although haemolytic rate was attenuated by washout after 5 min KH exposure, the KH-induced lesion itself was not susceptible to washout by either extracellular volume expansion (at constant osmolarity) or centrifugation/resuspension. This suggests that HRBC binding of KH from aqueous solution still continues after 5 min exposure at 37 degrees C. Pre-vortexing KH with dibutyl phthalate (DBP) dramatically reduced the haemolytic activity of the aqueous toxin preparation, suggesting a protein-lipid interaction, which may support the contention that KH can move from a hydrophilic to a hydrophobic environment. Two features were identified that are characteristic of highly purified TDH preparations: (1) thermostability of haemolysin, and (2) monovalent cation selectivity series of lesion: Cs+ > Li+ > K+ > Rb+ > Na+, confirming that TDH is the important leak-inducing agent of KH.

Cation flux studies of the lesion induced in human erythrocyte membranes by the thermostable direct hemolysin of Vibrio parahaemolyticus

Vibrio parahaemolyticus, an important agent of seafood-borne gastroenteritis, expresses several putative virulence factors that could account for the disease symptoms of infected humans, namely, diarrhea, nausea, and abdominal cramps. The pathogenicity of V. parahaemolyticus correlates well with the Kanagawa phenomenon (the hemolytic ability of strains grown on Wagatsuma blood agar), implicating the thermostable direct hemolysin (TDH) as the predominant toxin responsible for pathogenicity. TDH-induced hemolysis could be inhibited by the addition of the osmolyte sorbitol to the extracellular solution, supporting the hypothesis that hemolysis occurs through colloid osmosis secondary to an increase in the cation permeability of the membrane. The effect of TDH on cation permeability was investigated by measuring K+ (congener, 86Rb+) influx into human erythrocytes in which the endogenous cation transporters had been blocked (by use of ouabain, bumetanide, and nitrendipine). TDH increased K+ influx into these cells; this increase was rapid in onset and constant in magnitude, suggesting a direct action by TDH on the membrane. The kinetics of leak generation were examined; the relationship between counts accumulated and hematocrit indicated that the TDH-induced lesion is multihit in nature. TDH-induced K+ influx was sensitive to Zn2+. Time courses of hemolysis in isosmotic solutions of monovalent cation chlorides were used to obtain the selectivity series for the TDH-induced leak: Cs+ > Li+ > K+ > Rb+ > Na+. Both the Zn2+ sensitivity and this selectivity series were obtained for crude culture supernatants, suggesting that TDH is the predominant leak-inducing agent. Thus, we have identified several features of the TDH-induced leak likely to be important in the diarrhetic action of V. parahaemolyticus in the human intestine.

Effects of deoxygenation on active and passive Ca2+ transport and cytoplasmic Ca2+ buffering in normal human red cells

1. The effects of deoxygenation on cytoplasmic Ca2+ buffering, saturated Ca2+ extrusion rate through the Ca2+ pump (Vmax), passive Ca2+ influx and physiological [Ca2+]i level were investigated in human red cells to assess whether or not their Ca2+ metabolism might be altered by deoxygenation in capillaries and venous circulation. 2. The study was performed in fresh human red cells maintained in a tonometer either fully oxygenated or deoxygenated. Cytoplasmic Ca2+ buffering was estimated from the equilibrium distribution of 45Ca2+ induced by the divalent cation ionophore A23187 and the Vmax of the Ca2+ pump was measured either by the Co(2+)-exposure method or following ionophore wash-out. The passive Ca2+ influx and physiological [Ca2+]i were determined in cells preloaded with the Ca2+ chelator benz-2 and resuspended in autologous plasma. 3. Deoxygenation increased the fraction of ionized Ca2+ in cell water by 34-74% and reduced the Vmax of the Ca2+ pump by 18-32%. 4. To elucidate whether or not these effects were secondary to deoxygenation-induced pH shifts, the effects of deoxygenation on cell and medium pH, and of pH on cytoplasmic Ca2+ binding and Ca2+ pump Vmax in oxygenated cells were examined in detail. 5. Deoxygenation generated large alkaline pH shifts that could be explained if the apparent isoelectric point (pI) of haemoglobin increased by 0.2-0.4 pH units in intact cells, consistently higher than the value of 0.15 reported for pure haemoglobin solutions. 6. In oxygenated cells, the fraction of ionized cell calcium, alpha, was little affected by pH within the 7.0-7.7 range. Ca2+ pump Vmax was maximal at a medium pH of about 7.55. Comparison between pH effects elicited by HCl-NaOH additions and by replacing Cl- with gluconate suggested that Vmax was inhibited by both internal acidification and external alkalinization. Since deoxygenation alkalinized cells and medium within a range stimulatory for Vmax, the inhibition observed was not due to pH. 7. There was no significant effect of deoxygenation on passive Ca2+ uptake, or steady-state physiological [Ca2+]i level. 8. The deoxygenation-induced reduction in Ca2+ binding capacity may result from the increased protonation of haemoglobin on deoxygenation and from binding of 2,3-diphosphoglyceric acid (2,3-DPG) and ATP to deoxyhaemoglobin; inhibition of the Ca2+ pump may result from shifts in the [Mg2+]i/[ATP]i ratio away from a near optimal stimulatory value in the oxygenated state.

Assay of the Ca pump ATPase activity of intact red blood cells

An assay for the Ca pump ATPase of intact human red blood cells (RBCs) was developed. The assay utilized a small volume (typically 10 microliters) of packed RBCs in 1 ml of a buffer of known composition. The assay was based on the exposure of intact RBCs to the ionophore, A23187, in the presence of Ca. Such exposure caused a rapid degradation of ATP in RBCs. This degradation process is modeled in a numerical simulation in a companion paper (Vincenzi, F. F. and Hinds, T. R. (1992) Biochim. Biophys. Acta 1105, 63-70). The loss of ATP followed pseudo-first-order kinetics, and the rate constants for ATP degradation was taken as a measure of the capacity of the Ca pump ATPase. A number of variables were examined to optimize the activity of the ATPase. These variables included the concentrations of Ca and A23187. Because A23187 can promote loss of cellular Mg, it was necessary to include MgCl2 in the incubation medium to optimize ATPase activity. Likewise, it was determined that inclusion of iodoacetic acid optimized the rate of ATP loss, presumably by preventing the resynthesis of ATP from ADP and inorganic phosphate. Cobalt inhibited the ionophore-dependent loss of ATP by apparent competition with Ca for binding to A23187. Results of many assays demonstrated substantial differences in the rate constant for ATP loss in RBCs from different individuals. RBCs were selected according to density. Density associated loss of Ca pump ATPase activity was observed both by the intact RBC assay, and by assay of Ca pump ATPase activity in saponin lysates of RBCs. The correlation coefficient between the two assays was 0.93. It is suggested that the rate constant for ATP loss in intact RBCs exposed to A23187 and Ca can be taken as a measure of the Ca pump ATPase activity. This may be useful when isolated membrane ATPase assays fail (e.g., dog RBCs). The intact cell assay can also be carried out on very small volumes of cells and may be of particular value when RBC volumes are limited.

Calcium content of the erythrocytes: a sensitive and easy handling method for measuring free calcium ions, and modulation of the Ca2+ ion concentration by the calcium antagonists nifedipine and pentoxifylline

1. A method for determining free Ca2+-ions in the erythrocyte is described, using a commercially available ORION-Ca-electrode and calomel reference electrode assembly, where changes in free Ca2+-ion concentration upon addition of 0.01% digitonin could be measured. 2. The average value found for fresh cells from 20 healthy donors at 37 degrees C (pH = 7.4) was 0.20 +/- 0.04 mumol/L referred to a haematocrit of 10%. 3. Decrease of the simultaneously determined adenosinetriphosphate (ATP) concentration indicates that ATP is presumably needed to activate the Ca-ATPase. 4. In vitro addition of the calcium antagonists pentoxifylline and nifedipine, respectively, induced a normalization of the intraerythrocytic Ca2+-ion concentration after previous increase with the ion carrier ionophore A23187. 5. The advantages and possible clinical applications of this method are discussed.

Heterogeneous calcium and adenosine triphosphate distribution in calcium-permeabilized human red cells

1. Calcium permeabilization of inosine-fed human red cells using the divalent cation ionophore A23187 induces pump-leak steady states in which the mean total calcium content of the cells may be held below electrochemical equilibrium for hours. A new method developed to detect and separate cells with different calcium contents revealed a striking heterogeneity of calcium contents in subpopulations of cells in pump-leak steady state (García-Sancho & Lew, 1988a). Most of the mean total cell calcium was found within a fraction of cells rendered dense by the separation procedure (H cells), with relatively little within the remaining light cells (L cells). The experiments in this paper were designed to study the nature and origin of the observed heterogeneity. 2. The fraction of steady-state H cells increased, and the mean ATP content of the cells fell, both linearly, as calcium influx was increased. The H/L divide is therefore the result of a continuous variation in cell properties. When calcium influx was above about 30 mmol/(l cells.h), all cells became dense, calcium distribution was at or near equilibrium, and cell ATP was 0.1-0.2 mmol/l cells. 3. Inosine-fed cells, subjected to ionophore-mediated net calcium influx of 13-15 mmol/(l cells.h), attained a steady state with mean calcium contents far below equilibrium. After ionophore removal and reincubation in calcium-free media, the initial calcium efflux was only a fraction of that required to sustain the previous steady state (less than 25% for H cells, and less than 2% for L cells). The ATP content of L cells was normal whereas that of H cells was irreversibly reduced. These results revealed a paradoxical discrepancy between leak influx and calcium pump efflux in H and L cells which were supposed to have been in steady-state pump-leak balance. 4. The changes in cell calcium and ATP were followed in time after calcium permeabilization to characterize the development of steady-state heterogeneity. Calcium influx triggered a sharp peak in the H cell fraction within 15 s of permeabilization. The mean calcium content of H cells increased towards steady-state values as their fraction decreased; most other cells transferred from H to L density fractions (HL cells) within the first 5 min of permeabilization. 5. In substrate-starved cells calcium influx triggered an immediate fall in cell ATP, steeper in H cells than in L cells. The initial calcium and density transients were unattected.(ABSTRACT TRUNCATED AT 400 WORDS)

Properties of the residual calcium pools in human red cells exposed to transient calcium loads

1. Inosine-fed human red cells, pre-loaded with calcium with the use of the ionophore A23187, and reincubated at 37 degrees C after ionophore and external calcium removal, pumped calcium out initially fast and then substantially slower when the residual calcium was still very high (García-Sancho & Lew, 1988 a, b). Particularly surprising was the finding of such residual calcium pools in a subpopulation of cells (L cells, García-Sancho & Lew, 1988b) with normal ATP, high active calcium pumping rates, and K+ channels which remained inactive during the density separation procedure (SCN- treatment; García-Sancho & Lew, 1988a). The purpose of the present experiments was to investigate the properties and possible origins of the residual calcium pools. 2. At each ionophore concentration, the pool size increased with the duration and magnitude of the calcium load. At comparable calcium loads, the pool size was smaller the higher the ionophore concentration used. 3. In cells from the same sample, residual calcium pools were present in cells that became dense after SCN- treatment (H cells) as well as those that remained in the light-cell fraction (L cells). Residual calcium was always higher in H cells than in L cells. 4. Re-exposure of cells to ionophore in Ca2+-free media could rapidly extract over 99% of their residual calcium. Residual calcium is therefore in a rapidly mobilizable form within a membrane-bound compartment. 5. Iodoacetamide-induced ATP depletion of H cells with high residual calcium-stimulated calcium loss. Such stimulation could only occur if ATP depletion inhibited a calcium-retaining process within the cells. 6. L cells with high residual calcium may have failed to dehydrate during SCN- treatment because of irreversible K+ channel inactivation or because K+ permeabilization would no longer generate a dehydrating net cation loss. These possibilities were tested and ruled out since it was found that virtually all cells became dense in low-K+, SCN- media after valinomycin addition or re-exposure to A23187 + calcium. 7. The results suggest that part if not all of the residual calcium is contained within compartments with the properties of endocytic inside-out vesicles capable of ATP-dependent calcium accumulation, such as those found in normal and abnormal human red cells (Lew, Hockaday, Sepúlveda, Somlyo, Somlyo, Ortiz & Bookchin, 1985).

Fluorescence measurements of free Ca2+ concentration in human erythrocytes using the Ca2+-indicator fura-2

We report here the use of the fluorescent Ca2+-chelator fura-2 to directly measure free Ca2+ concentration within intact human erythrocytes and the influence of viscosity on the fluorescence of this probe. The bright fluorescence of fura-2 has permitted the use of low concentrations of indicator and cells, thus minimizing the screening effect and the intrinsic fluorescence of haemoglobin. Erythrocytes (10(8) cells/ml) were loaded with 0.5 microM fura-2AM then diluted at 10(7) cells per ml for measurements. The extracellular signal was suppressed by addition of manganese ions just before recording spectra. Under these conditions, a blood sample of 100 microliter was sufficient for analysis. To study the influence of viscosity on fura-2 fluorescence, gelatin and polyvinylpyrrolidone at various concentrations were added to a physiological buffer to perform fura-2-Ca fluorescence standard curves. Fluorescence intensities and the apparent affinity constant for Ca2+ were modified by viscosity. When intra-erythrocytic viscosity was simulated with 21 g/l polyvinylpyrrolidone to obtain a mean viscosity of 14 mPa.s similar to that observed in human erythrocytes, the mean value of free Ca2+ concentration measured in erythrocytes from healthy subjects was 78 +/- 16 nM (mean +/- S.D., n = 29).

Temperature dependence of Ca2+-activated K+ currents in the membrane of human erythrocytes

The currents through single Ca2+-activated K+ channels were studied in excised inside-out membrane patches of human erythrocytes. The effects of temperature on single-channel conductance, on channel gating and on activation by Ca2+ were investigated in the temperature range from 0 up to 47 degrees C. The single-channel conductance shows a continuous increase with increasing temperature; an Arrhenius plot of the conductance gives the activation energy of 29.6 +/- 0.4 kJ/mol. Reducing the temperature alters channel-gating kinetics which results in a significant increase of the probability of the channel being open (Po). The calcium dependence of Po is affected by temperature in different ways; the threshold concentration for activation by Ca2+ is not changed, the Ca2+ concentration of half-maximal channel activation is reduced from 2.1 mumol/l at 20 degrees C to 0.3 mumol/l at 0 degrees C, the saturation level of the dependence is reduced for temperatures higher then about 30 degrees C. The relevance of the obtained data for the interpretation of the results known from flux experiments on cells in suspensions is discussed.

Calcium transport by permeabilised rabbit small intestinal epithelial cells

Intestinal epithelial cells isolated from rabbit small intestine and whose plasma membrane had been rendered highly permeable were used to study the role of intracellular structures in Ca2+ buffering. Monitoring free Ca2+ with a selective electrode revealed that the cells could reduce Ca2+ concentration in the medium to a level of 3.6 X 10(-7) M independently, within a certain range, of the initial Ca2+ concentration or amount of cells used. Ca2+ buffering by permeabilised enterocytes was Mg2+- and ATP-dependent and was abolished in the presence of the Ca2+ ionophore A23187. The rapidity of Ca2+ buffering, but not the final Ca2+ level attained, was reduced in the combined presence of the mitochondrial inhibitors azide and oligomycin or in the presence of ruthenium red. Buffering of Ca2+ was abolished in the presence of vanadate, although some uptake was still observed. Complete blocking occurred in the presence of both vanadate and mitochondrial inhibitors. Measurement of initial rates of uptake with radioactive calcium revealed that mitochondrial uptake plays a role at relatively high Ca concentrations but that at the presumably physiological levels most of the uptake is into a non-mitochondrial compartment. Non-differentiated crypt cells seemed to handle intracellular Ca2+ in a similar way as mature villus cells, although they appeared to buffer at a level about 2 X 10(-7) M lower.

Intracellular calcium content of human erythrocytes: relation to sodium transport systems

To study the possible role of intracellular Ca (Cai) in controlling the activities of the Na+-K+ pump, the Na+-K+ cotransport and the Na+/Li+ exchange system of human erythrocytes, a method was developed to measure the amount of Ca embodied within the red cell. For complete removal of Ca associated with the outer aspect of the membrane, it proved to be essential to wash the cells in buffers containing less than 20 nM Ca. Ca was extracted by HClO4 in Teflon vessels boiled in acid to avoid Ca contaminations and quantitated by flameless atomic absorption. Cai of fresh human erythrocytes of apparently healthy donors ranged between 0.9 and 2.8 mumol/liter cells. The mean value found in females was significantly higher than in males. The interindividual different Ca contents remained constant over periods of more than one year. Sixty to 90% of Cai could be removed by incubation of the cells with A23187 and EGTA. The activities of the Na+-K+ pump, of Na+-K+ cotransport and Na+/Li+ exchange and the mean cellular hemoglobin content fell with rising Cai; the red cell Na+ and K+ contents rose with Cai. Ca depletion by A23187 plus EGTA as well as chelation of intracellular Ca2+ by quin-2 did not significantly enhance the transport rates. It is concluded that the large scatter of the values of Cai of normal human erythrocytes reported in the literature mainly results from a widely differing removal of Ca associated with the outer aspect of the membrane.

Passive transport and binding of lead by human red blood cells

The uptake of Pb into human red blood cells has been studied using Pb buffers. Passive Pb movements can be studied conveniently when the cells are depleted of adenosine 5'-triphosphate (ATP), to eliminate active transport, and of inorganic phosphate, to prevent precipitation of lead phosphate. Pb can cross the membrane passively in either direction. Influx and efflux show similar properties. Passive Pb transport is strongly stimulated by HCO3-, and is reduced by replacing Cl- with ClO4-. It is inhibited by low concentrations of 4-acetamido-4'-isothiocyanostilbene-2,2'-disulphonic acid (SITS) and 4,4'-diisothiocyanostilbene-2.2'-disulphonic acid (DIDS), characteristic inhibitors of anion transport. Pb uptake is unaffected by varying the external concentrations of Na+, K+ and Ca2+. When Pb enters the cell, it binds mainly to haemoglobin. The ratio of bound Pb:free Pb2+ in the cytosol is estimated to be 6000:1. Pb binding to haemoglobin is unaffected by oxygenation. Binding to albumin is quantitatively similar to binding to haemoglobin. The implications of these results for the transport and binding of Pb in the blood are discussed.

Determination of intracellular potassium ion concentration in isolated rat ventricular myocytes

The sarcoplasmic potassium concentration of a suspension of rat ventricular myocytes, prepared by collagenase-induced disruption of the myocardial mass, was determined by a null-point technique. Addition of digitonin resulted in a release of potassium from the cells which was interpreted as a flux from the sarcoplasm. The intracellular potassium concentration was estimated to be 113 +/- 6mM.

Volume regulation by Amphiuma red blood cells: cytosolic free Ca and alkali metal-H exchange

Osmotic swelling of Amphiuma red blood cells results in activation of electroneutral K-H exchange, whereas cell shrinkage activates an electroneutral Na-H exchange. These K-H and Na-H exchangers function to restore cell volume to normal after cell swelling and shrinkage, respectively. Our previous studies have suggested that Ca plays a role in volume-dependent activation of K-H exchange. In the present studies, intracellular free Ca levels were measured employing the Ca-sensitive extracellular dye arsenazo III and a previously described null-point method. Control values for intracellular free Ca averaged 0.46 +/- 0.15 microM. Cell shrinkage caused this value to decrease to 0.16 +/- 0.11 microM, whereas either cell swelling or addition of 5 microM A23187 resulted in saturation of intracellular Ca buffers, suggesting that both treatments caused an increase in intracellular free Ca. In the presence of 7 microM A23187, the rate of K-H exchange displayed a hyperbolic relationship as a function of extracellular Ca (Cao). The apparent half-maximal concentration for Cao (in the presence of 7 microM A23187) was 0.27 mM for osmotically swollen cells and 1.9 mM for cells in isotonic medium, suggesting that the Ca affinity of a modulating site is increased in swollen cells. Inhibitors of Ca-mediated processes, such as quinidine and the phenothiazines, inhibited K-H exchange. In contrast, the phenothiazines chlorpromazine and trifluoperazine stimulated Na-H exchange by osmotically shrunken cells. These results suggest that increases in intracellular free Ca are involved in stimulating K-H exchange while repressing Na-H exchange in Amphiuma red blood cells.

Passive permeability of human red blood cells to calcium

Ca2+ influx was measured into human erythrocytes in which efflux was blocked by either introduction of an intracellular Ca2+ chelator, introduction of the Ca2+ chelator followed by ATP depletion, or depletion of the Ca2+ pump cofactors ATP and Mg2+. The Ca2+ influx under all three conditions was 14-20 mumol . 1 cells-1 . h-1, which is an order of magnitude higher than the influx previously reported for cells depleted of either ATP or Mg2+ separately. The difference between the two values was explained by the finding of substantial Ca2+ efflux from the Ca2+-loaded ATP-depleted cells, whereas this efflux was insignificant from cells loaded with quin 2 and then ATP depleted. Under these latter conditions Ca2+ influx estimates the unidirectional permeability to this cation. Studies using this technique showed that Ca2+ influx was the same in media of isotonic sodium, potassium, lithium, choline, or magnesium chlorides. Moreover the dependence of Ca2+ influx on external Ca2+ concentration was well described by the sum of saturable and nonsaturable (linear) components.

Evidence for a Na-K-ATPase-inhibitor in erythrocytes of patients with essential hypertension

ATPase activities were determined in haemolysed and dialysed erythrocytes and in haemoglobin-free membranes of twenty patients with essential hypertension and twenty normotensive controls. Ouabain-sensitive ATPase (Na-K-ATPase) activity of haemolysate but not that of membranes was decreased in hypertensives whereas ouabain-insensitive ATPase (Mg-ATPase + some residual Ca-ATPase) activity was increased in both enzyme preparations when measurements were preformed in the absence of Ca2+-chelating substances. In haemolysed erythrocytes ouabain-sensitivity as a percentage of total ATPase activity was a good discriminator between both groups and may be a possible marker for essential hypertension. The decreased activity of Na-K-ATPase in haemolysate is apparently due to a non dialysable inhibitor of Na-K-ATPase which is either tightly bound to the erythrocyte membrane or dissolved in the cytoplasm. Following haemolysis with subsequent centrifugation the Na-K-ATPase inhibitor is removed, at least in part, and thus differences in Na-K-ATPase activity demonstrable in haemolysed and dialysed erythrocytes are no longer apparent in haemoglobin-free membranes.

Calcium-ATPase activity in erythrocyte ghosts from patients with familial benign hypercalcaemia

It has been suggested that the parathyroid glands and the kidneys are insensitive to the high extracellular calcium levels found in familial benign hypercalcaemia (FBH) (familial hypocalciuric hypercalcaemia) and that there may be a general disorder of the plasma membrane 'calcium pump'. We have found that the activity of the calcium-stimulated, magnesium-dependent ATPase of erythrocyte ghost membranes from patients with FBH was significantly higher (p less than 0.01) than that from normal subjects. Values in FBH, as a group, were higher than those in primary hyperparathyroidism, but the difference was not significant. We suggest that the membrane abnormality in FBH could be a disorder of the regulation of the calcium pump.

The Ca2+-sensitive K+-conductance of the human red cell membrane is strongly dependent on cellular pH

The conductance of the Ca2+-sensitive K+-channels in human red cell membranes has been determined as a function of the intracellular pH. A sudden increase in the intracellular concentration of ionized calcium was established by addition of ionophore A23187 to a suspension of cells in buffer-free, Ca2+-containing salt solution. At the various cellular pH-values cellular concentrations of ionized Ca, saturating with respect to activation of the Ca2+-sensitive K+-conductance, were obtained by the use of varied concentrations of extracellular Ca2+ and added ionophore A23187. Changes in membrane potential was monitored as CCCP-mediated changes in extracellular pH. Initial net effluxes of K+, cellular K+ contents and the K+ Nernst equilibrium potentials were calculated from flame photometric measurements. Cellular Ca-contents were determined by aid of 45Ca. With cellular Ca2+ at the saturating level with respect to activation of the K+-channel the K+-conductance calculated from these data was independent of extracellular pH and a steep function of cellular pH with a half maximal conductance of 31 microSeconds/cm2 at a cellular pH of 6.1. The K+-conductance is not a simple function of cellular pH (pHc). From pHc = 6.5 and down to pHc = 6.0 a Hill-coefficient of 2.5 was found, indicating cooperativity between at least two sites regulating the conductance. Below pHc = 6.0 an extremely high Hill-coefficient of 11 was found, probably indicating that the additional titration of the channel protein leads to an increased cooperativity. The importance, as a physiological regulatory mechanism, of a K+-conductance increasing from zero to maximal conductance within less than one unit of pH, is discussed.

Ca2+ causes active contraction of bile canaliculi: direct evidence from microinjection studies

Cytoplasmic microinjection of Ca2+ triggers contraction of bile canaliculi in freshly isolated monolayer cultures of rat hepatocytes. Unseparated paired hepatocytes were used to demonstrate this motility-based phenomenon. Only one cell of the pair was injected, but fluorescein spread from the target cell to the opposite cell; also, the contractions were always uniform, equally involving both hepatocytes that form the canaliculus, indicating that communication exists between the cell pairs. Inhibitors of calmodulin and actin filaments, trifluoperazine and cytochalasin B, respectively, inhibited the Ca2+-induced contractions. Hence, the mechanism of contraction has features in common with actin-myosin based cytoplasmic motility behavior found in other non-muscle cells.

Active transport of lead by human red blood cells

Human red cells suspended in lead-citrate buffers (2.6 microM Pb2+) take up much less Pb than predicted from studies of equilibrium binding of Pb to haemolysates. Pb uptake is increased by ATP depletion, or by loading at 0 degrees C. Tracer studies with 203Pb indicate that the low uptake at 37 degrees C in the presence of substrate is not due to membrane impermeability to Pb. Cold-loaded cells extrude Pb against a concentration gradient at 37 degrees C when glucose is present. These results suggest that the cellular loading of Pb is dependent on the balance between an inward leak and an outward pump. The extrusion of Pb from the cells is possibly brought by the Ca pump.

Correlation of Ca2+-and calmodulin-dependent protein kinase activity with secretion of insulin from islets of Langerhans

A Ca2+-activated and calmodulin-dependent protein kinase activity which phosphorylates predominantly two endogenous proteins of 57kDa and 54kDa was found in a microsomal fraction from islet cells. Half-maximal activation of the protein kinase occurs at approx. 1.9 microM-Ca2+ and 4 micrograms of calmodulin/ml (250 nM) for phosphorylation of both protein substrates. Similar phosphoprotein bands (57kDa and 54kDa) were identified in intact islets that had been labelled with [32P]Pi. Islets prelabelled with [32P]Pi and incubated with 28 mM-glucose secreted significantly more insulin and had greater incorporation of radioactivity into the 54 kDa protein than did islets incubated under basal conditions in the presence of 5 mM-glucose. Thus the potential importance of the phosphorylation of these proteins in the regulation of insulin secretion is indicated both by activation of the protein kinase activity by physiological concentrations of free Ca2+ and by correlation of the phosphorylation of the substrates with insulin secretion in intact islets. Experiments undertaken to identify the endogenous substrates indicated that this calmodulin-dependent protein kinase may phosphorylate the alpha- and beta-subunits of tubulin. These findings suggest that Ca2+-stimulated phosphorylation of islet-cell tubulin via a membrane-bound calmodulin-dependent protein kinase may represent a critical step in the initiation of insulin secretion from the islets of Langerhans.

The role of calcium in the regulation of sugar transport in the pigeon red blood cell

The saturable, 'carrier-mediated' pathway for sugar transport in pigeon red blood cells may be stimulated by metabolic depletion or by loading the cells with Ca by means of a high-voltage discharge or the ionophore A 23187. All of these methods for stimulating the saturable pathway of sugar transport also cause a drop in cellular ATP levels. The relationship between the stimulation of transport and the fall in ATP is very similar in metabolically depleted or Ca-loaded cells, but cells treated with Ca and A23187 show a greater stimulation of transport than would be expected from the decline in ATP. Altering free Ca2+ levels during metabolic depletion has little or no effect on stimulation of the saturable pathway. Conversely, metabolic depletion of fresh cells in Ca-free solutions has no detectable effect on intracellular free Ca2+ levels. These results suggest that Ca2+ ions are not involved in regulation of this pathway. The non-saturable pathway for sugar transport is stimulated by a rise in cell Ca. This process is probably stimulated half-maximally by about 10 microM-free Ca2+.

Comparison of the properties of active Ca2+ transport by the islet-cell endoplasmic reticulum and plasma membrane

The properties of active or ATP-dependent calcium transport by islet-cell endoplasmic reticulum and plasma membrane-enriched subcellular fractions were directly compared. These studies indicate that the active calcium transport systems of the two membranes are fundamentally distinct. In contrast to calcium uptake by the endoplasmic reticulum-enriched fraction, calcium uptake by islet-cell plasma membrane-enriched vesicles exhibited a different pH optimum, was not sustained by oxalate, and showed an approximate 30-fold greater affinity for ionized calcium. A similar difference in affinity for calcium was exhibited by the Ca2+-stimulated ATPase activities which are associated with these islet-cell subcellular fractions. Consistent with the effects of calmodulin on calcium transport, calmodulin stimulated Ca2+-ATPase in the plasma membranes, but did not increase calcium-stimulated ATPase activity in the endoplasmic reticulum membranes. The physiological significance of the differences observed in calcium transport by the endoplasmic reticulum and plasma membrane fractions relative to the regulation of insulin secretion by the islets of Langerhans is discussed.

Rate constants for calmodulin binding to Ca2+-ATPase in erythrocyte membranes

The Ca2+-ATPase (ATP phosphohydrolase, EC 3.6.1.3) in human erythrocyte membranes, which is part of the Ca2+ pump, can be activated by binding of calmodulin. Rate constants (k1) for association of calmodulin and enzyme, which depends on the Ca2+ concentration, have been determined by the aid of an enzyme model. k1 increased from 0.25 . 10(6) to 17.3 . 10(6) M-1 . min-1 (70 times) when the free Ca2+ concentration was raised from 0.7 to 20 microM. The binding of calmodulin to the Ca2+-ATPase is reversible. The rate constants (k-1) for dissociation of enzyme-calmodulin complex decreased from 6.0 to 0.044 min-1 (135 times) when the free Ca2+ concentration was increased from 0.1 to 2-20 microM. The apparent dissociation constant Kd = k-1/k1 accordingly increased from 2.5 nM to 25 microM (or higher) when the Ca2+ concentration was reduced from 20 to 0.1 microM. Therefore, at 10(-7) M free Ca2+ most of the Ca2+-pump enzyme will not bind calmodulin. For the intact cell the time dependences of activation and deactivation of the Ca2+-pump enzyme have been estimated from the rate constants above. The results suggest that the Ca2+ pump is well suited to maintain a cytosolic concentration of 10(-7) M free Ca2+ (or lower) in the unstimulated cell and, when the cell is stimulated, to allow transient Ca2+ signals up to approx. 10(-5) M in the cytosol.