Delayed activation of calcium pump during transient increases in cellular Ca2+ concentration and K+ conductance in hyperpolarizing human red cells

Elevated intracellular Ca2+ reveals a functional membrane nucleotide pool in intact human red blood cells

Elevated intracellular calcium generates rapid, profound, and irreversible changes in the nucleotide metabolism of human red blood cells (RBCs), triggered by the adenosine triphosphatase (ATPase) activity of the powerful plasma membrane calcium pump (PMCA). In the absence of glycolytic substrates, Ca(2+)-induced nucleotide changes are thought to be determined by the interaction between PMCA ATPase, adenylate kinase, and AMP-deaminase enzymes, but the extent to which this three-enzyme system can account for the Ca(2+)-induced effects has not been investigated in detail before. Such a study requires the formulation of a model incorporating the known kinetics of the three-enzyme system and a direct comparison between its predictions and precise measurements of the Ca(2+)-induced nucleotide changes, a precision not available from earlier studies. Using state-of-the-art high-performance liquid chromatography, we measured the changes in the RBC contents of ATP, ADP, AMP, and IMP during the first 35 min after ionophore-induced pump-saturating Ca(2+) loads in the absence of glycolytic substrates. Comparison between measured and model-predicted changes revealed that for good fits it was necessary to assume mean ATPase V(max) values much higher than those ever measured by PMCA-mediated Ca(2+) extrusion. These results suggest that the local nucleotide concentrations generated by ATPase activity at the inner membrane surface differed substantially from those measured in bulk cell extracts, supporting previous evidence for the existence of a submembrane microdomain with a distinct nucleotide metabolism.

TRPC6 contributes to the Ca(2+) leak of human erythrocytes

Human erythrocytes express cation channels which contribute to the background leak of Ca(2+), Na(+) and K(+). Excessive activation of these channels upon energy depletion, osmotic shock, Cl(-) depletion, or oxidative stress triggers suicidal death of erythrocytes (eryptosis), characterized by cell-shrinkage and exposure of phosphatidylserine at the cell surface. Eryptotic cells are supposed to be cleared from circulating blood. The present study aimed to identify the cation channels. RT-PCR revealed mRNA encoding the non-selective cation channel TRPC6 in erythroid progenitor cells. Western blotting indicated expression of TRPC6 protein in erythrocytes from man and wildtype mice but not from TRPC6(-/-) mice. According to flow-cytometry, Ca(2+) entry into human ghosts prepared by hemolysis in EGTA-buffered solution containing the Ca(2+) indicator Fluo3/AM was inhibited by the reducing agent dithiothreitol and the erythrocyte cation channel blockers ethylisopropylamiloride and amiloride. Loading of the ghosts with antibodies against TRPC6 or TRPC3/6/7 but neither with antibodies against TRPM2 or TRPC3 nor antibodies pre-adsorbed with the immunizing peptides inhibited ghost Ca(2+) entry. Moreover, free Ca(2+) concentration, cell-shrinkage, and phospholipid scrambling were significantly lower in Cl(-)-depleted TRPC6(-/-) erythrocytes than in wildtype mouse erythrocytes. In conclusion, human and mouse erythrocytes express TRPC6 cation channels which participate in cation leak and Ca(2+)-induced suicidal death.

Sperm phenotype of mice carrying a gene deletion for the plasma membrane calcium/calmodulin dependent ATPase 4

The sarcolemmal calcium pumps (PMCA for plasma membrane calcium/calmodulin dependent ATPase) are a family of 10 transmembrane domain proteins ejecting calcium from the cytosol. They are encoded by four independent genes and at least 21 splice variants have been described. Isoforms 1 and 4 are ubiquitous, whereas isoforms 2 and 3 are confined to neurons and few other cells (e.g. isoform 2 in the myocardium). In non-excitable cells they are thought to be the only calcium ejection systems and their function as governors of calcium balance is hence intuitive since cells cannot survive in a state of calcium overload. Differences in the affinity of the various isoforms for calcium, ATP and calmodulin have been described, but it is unclear whether the pumps have specialized functions over and above their 'housekeeping' role. In particular, in excitable cells, most calcium is ejected by the sodium/calcium exchanger suggesting that the PMCAs may have evolved into a specialized role. Recently, our group has identified a number of specialized functions of the PMCAs, notably a prominent regulatory role of PMCA4 (splice variant b) for neuronal NO synthase as well as for the Ras pathway. In addition, mice carrying a genetic deletion of the PMCA4 gene showed normal female, but completely infertile male animals. This is due to a highly specific defect in sperm motility, which is reduced to zero, with normal fertilization capacity. Overall, a scenario emerges where the plasma membrane calcium pumps fulfil roles far beyond the traditional housekeeping function, notably in cell signaling, sperm motility, and potentially in cell division. Consequently, we are currently exploring their potential as future drug targets for a variety of conditions, as well as their potential use in the development of a male contraception.

Delayed activation of the plasma membrane calcium pump by a sudden increase in Ca2+: fast pumps reside in fast cells

There are four genes encoding isoforms of the plasma membrane Ca(2+) pump (PMCA). PMCA variability is increased by the presence of two splicing sites. Functional differences between the variants of PMCA have been described, but little is known about the adaptive advantages of this great diversity of pumps. In this paper we studied how the different isoforms respond to a sudden increase in Ca(2+) concentration. We found that different PMCAs are activated by Ca(2+) at different rates, PMCA 3f and 2a being the fastest, and 4b the slowest. The rate of activation by Ca(2+) depends both on the rate of calmodulin binding and the magnitude of the activation by calmodulin. We found that 2a is located in heart and the stereocilia of inner ear hair cells, 3f in skeletal muscle and 4b was identified in Jurkat cells. Both cardiac and skeletal muscle, and stereocilia recover very rapidly after a cytoplasmic Ca(2+)peak, while in Jurkat cells the recovery takes up to a minute. In stereocilia, 2a is the only method for export of Ca(2+), making the analysis of them unusually straightforward. This indicates that these rates of PMCA activation by Ca(2+) are correlated with the speed of Ca(2+) concentration decay after a Ca2 spike in the cells in which these variants of PMCA are expressed. The results suggest that the type of PMCA expressed will correspond with the speed of Ca(2+) signals in the cell.

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.

Depletion of calcium stores by thapsigargin induces membrane depolarization by cation entry in human neutrophils

The ability of various cations to change the electrical potential of the plasma membrane was examined in human neutrophils by the use of the fluorescent cationic dye 3,3'-dipropylthiadicarbocyanine. When the cells were suspended in 140 mM KCl, the fluorescence was high, indicating depolarized neutrophils. Suspension in 145 mM N-methyl-D-glucamine chloride (NMG), replacing sodium and potassium chloride, resulted in hyperpolarized neutrophils. After depletion of the intracellular calcium stores of the NMG-suspended cells with thapsigargin and EDTA or EGTA, the addition of cations depolarized the neutrophils, suggesting the existence of pathways for cation entry. Besides Na+ and K+, several divalent cations were effective in the sequence: Ca2+ > Mn2+ > Ba2+ > Cd2+ > Mg2+ > Co2+ > Zn2+ > Ni2+. Pretreatment of the neutrophils with 0.5 or 1 mM CaCl2, resulting in loading of calcium stores, reduced the ability of some of the cations to depolarize the NMG-suspended cells. From the depolarizing effects of the cations it is concluded that the entries of Ca2+, Mg2+, Mn2+, Ba2+, probably Co2+, to some extent Na+ and K+, but hardly Cd2+, Zn2+, or Ni2+, are regulated by the filling state of the intracellular calcium stores in human neutrophils. The store-regulated entry pathway may contribute to the control of the membrane potential and become active when the neutrophils are stimulated.

Delayed activation of plasma membrane Ca2+ pump in human neutrophils

The interplay between Ca2+ efflux mechanisms of the plasma membrane (PM) and transient changes of the cytosolic concentration of ionized calcium ([Ca2+]i) was studied in suspensions of human neutrophils loaded with the [Ca2+]i indicator, Fura-2. To reveal Ca2+ efflux through PM the interference of intracellular Ca stores was prevented by preincubating the cells in the presence of EGTA, thapsigargin, and ionomycin. Addition of econazole prevented varying entry of divalent cations regulated by the filling state of Ca stores. The preincubation seemed to empty and permeabilize virtually all Ca stores, ensuring that the monitored changes of [Ca2+]i were caused exclusively by PM Ca2+ transporters. Following preincubation, the addition of CaCl2 induced, mediated by ionomycin, a transient rise of [Ca2+]i, a spike, eventually decreasing to an intermediary [Ca2+]i level. The ATP-dependent decrease of [Ca2+]i terminating the spike was abolished by the calmodulin antagonist, N-(6-aminohexyl)-1-naphthalenesulfonamide (W-7), but not by the protein kinase C inhibitor, staurosporine, nor by Na(+)-free medium, suggesting that neither activity of protein kinase C nor Na+/Ca2+ exchange was necessary for generation of the Ca2+ spike. In conclusion, the PM Ca2+ pump was responsible for the Ca2+ spike by responding to the rapid rise of [Ca2+]i by a delayed activation, possibly involving calmodulin. This characteristic feature of the PM pump may be important for the generation of cellular [Ca2+]i spikes in general.

Inhibition of the calcium pump by high cytosolic Ca2+ in intact human red blood cells

1. The inhibitory effect of high intracellular calcium on the saturated Ca2+ efflux through the Ca2+ pump (Vmax) was investigated in intact human red cells. Cells were loaded with Ca2+ by exposure to the calcium ionophore A23187, at different external Ca2+ concentrations ([Ca2+]o). Ca2+ extrusion by the pump was followed after either ionophore removal or Co2+ addition. 2. fifty per cent inhibition of Vmax was obtained with total intracellular calcium ([CaT]i) of approximately 3 mmol/l cells. For any given initial Ca2+ load, Vmax showed no tendency to increase as [CaT]i was progressively reduced during Ca2+ efflux. This suggests that the pump Vmax was determined by the magnitude of the initial [Ca2+]i. 3. To estimate [Ca2+]i from [CaT]i in Co(2+)-loaded cells, the possible competition between Co2+ and Ca2+ for the known cytoplasmic Ca2+ buffers (alpha-buffers) was investigated first. Comparison between Ca2+ efflux after either Co2+ exposure or ionophore wash-out showed that the efflux patterns were essentially identical, down to the lowest measurable [CaT]i. This indicates that Co2+ does not compete with Ca2+ for the alpha-buffers. Hence, since [Ca2+]i = alpha [CaT]i, and alpha approximately 0.15-0.35, the initial [Ca2+]i load for 50% Vmax inhibition was between 0.4 and 1.1 mM. 4. Ancillary new findings demonstrated that, unlike the situation with alpha-buffers, Co2+ displaced Ca2+ from the cell-incorporated calcium chelator benz-2, and that benz-2 incorporation had no effect on Co(2+)-exposed Ca2+ pump desaturation. This validates the use of benz-2 to study Ca2+ pump kinetics in intact cells.

Solitary calcium spike dependent on calmodulin and plasma membrane Ca2+ pump

Resealed human red cell ghosts were loaded with Fura-2, ATP, Mg2+, and either calmodulin (CaM) or, to prevent CaM activation of the Ca2+ pump, a synthetic peptide that antagonized endogenous CaM (an analogue of the CaM binding domain of protein kinase II, referred to as 'antiCaM'). The ghosts reduced the cytosolic concentration of ionized calcium ([Ca2+]i) to 193 +/- 60 nM (SD, n = 15) in a medium containing 1 mM Ca2+ and to 30 +/- 27 nM (SD, n = 62) in a medium without Ca2+ addition. Without ATP, i.e. no fuelling of the Ca2+ pump, the [Ca2+]i remained high (approx. 5 microM or higher). The simultaneous addition of the ionophore A23187 and Ca2+ rapidly increased the Ca2+ influx, which in the CaM loaded ghosts caused a solitary spike of [Ca2+]i, reaching maximum around 2 microM within 24 +/- 6 s (SD, n = 40). On the contrary, in the ghosts loaded with antiCaM, the addition of A23187 with Ca2+ raised [Ca2+]i during the first 2 min to a high level (2-4 microM) with no preceding spike. Pre-incubation of CaM-ghosts with Ca2+ diminished the height of the Ca2+ spike, and treatment with trypsin even removed the Ca2+ spike. The trypsin treatment activated the Ca2+ pump prior to the rise of [Ca2+]i, making the time-consuming CaM activation unnecessary. In conclusion, the Ca2+ spiking is dependent on a delayed CaM activation of the plasma membrane Ca2+ pump in response to a rapid increase of Ca2+ influx.

Effect of cyclosporin A on the membrane potential and Ca2+ level of human lymphoid cell lines and mouse thymocytes

The effect of the immunosuppressive cyclosporin A (CsA) on the cytosolic free Ca2+ concentration ([Ca2+]i) and membrane potential of human B and T lymphoblastoid cells and mouse thymocytes was studied in order to reveal some features of the early stage of drug-cell interaction. Cytosolic free Ca2+ concentration of the cells was measured by spectrofluorimetry using indo-1 and quin2 fluorescent calcium indicators. Membrane potential was monitored in a flow cytometer with oxonol dye. CsA applied at 2-20 micrograms/ml final concentrations caused a dose-dependent, rapid, transient rise of [Ca2+]i in all cell types. This effect could be blocked by chelating the extracellular Ca2+ with EGTA but was not sensitive to Ca2+ channel blockers verapamil and nifedipine or K+ channel blocker 4-aminopyridine. A possible explanation for the calcium mobilizing effect of CsA is an ionophore-like mode of action at the cell membrane level. Besides directly interfering with mitogenic signals, the elevation of [Ca2+]i could be responsible for an initial hyperpolarization observed in CsA-treated T lymphocytes. This hyperpolarization, however, was not detectable in B lymphoblastoid cells. A further difference between B and T cells was the diverse pattern of depolarization following CsA treatment. This variance in the behaviour of T and B lymphocytes and the diversity of membrane transport systems in its background could account for the different final outcome of the drug-cell interaction.

Ca2+ transients and Mn2+ entry in human neutrophils induced by thapsigargin

Human neutrophils, preloaded with the fluorescent probe, Fura-2, were exposed to Ca2+-releasing agents. The monitored traces of fluorescence were transformed by computer to cytosolic Ca2+ concentration ([ Ca2+]i). Due to quenching of Fura-2, the addition of Mn2+ enabled us to compute the cytosolic concentration of total manganese ([Mn]i). The agents used were the novel Ca2+-mobilizing agent, thapsigargin (Tg), the chemotactic peptide, formyl-methionyl-leucyl-phenylalanine (FMLP), and the divalent cation ionophore, A23187. The agents caused transient rises of [Ca2+]i and monotonous rises of [Mn]i, suggesting influx but no efflux of Mn2+. The rise time of [Ca2+]i and the time constants and magnitude of the apparent Mn2+ influx were strongly dependent on the sequence of addition of the agonist and Ca2+. Contrary to FMLP, Tg needed several minutes to exert its full effect on the rise of [Ca2+]i and on the influx of Mn2+, the latter being dependent on two phases, activation and partial inactivation. Pretreatment with phorbol 12-myristate 13-acetate (PMA) inhibited the responses of Tg, FMLP and A23187. For comparison, human red blood cells were tested. Contrary to A23187, Tg did not induce Ca2+ uptake in ATP-depleted red cells but increased the Ca2+ pump flux in intact red cells by 10%. The experimental data and computer simulations of the granulocyte data suggest that time-dependent changes of both passive Ca2+ flux into the cytosol and Ca2+ flux of the plasma membrane pump are involved in the transient [Ca2+]i response.

Halothane inhibits hyperpolarization and potassium channels in human red blood cells

The effect of halothane on the Ca2+-sensitive K+ channel in human erythrocytes has been investigated. The red cells were suspended in buffer-free salt solutions containing Ca2+ or 45Ca2+. The protonophore CCCP was added to bring about a rapid equilibration of protons across the plasma membrane. After addition of the divalent cation ionophore A23187, the cells took up Ca2+ and this caused the K+ channels to open. When the medium contained 1 mM K+, the addition of A23187 induced a transient hyperpolarization of the cells, as monitored by measurement of the pH of the medium. The cellular pH, being buffered by haemoglobin, was virtually constant. Halothane reversibly inhibited hyperpolarization and limited the release of cellular K+ in a dose-dependent way, but did not inhibit the Ca2+-transporting properties of A23187. No stimulatory effects of halothane were observed even at low halothane concentrations. In conclusion, halothane reversibly inhibits the Ca2+-sensitive K+ channel in human erythrocytes with an ED50 of about 0.5 mM.

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)

Calcium-induced conversion of adenine nucleotides to inosine monophosphate in human red cells

1. When inosine-fed human red cells are permeabilized to calcium by exposure to the ionophore A23187, progressively larger proportions of the cell population become irreversibly depleted of ATP as calcium influx is increased (Brown & Lew, 1983; García-Sancho & Lew, 1988b). When calcium influx is over 30 mmol/(l cells.h), all cells become ATP depleted and calcium equilibrated (E cells) (García-Sancho & Lew, 1988b). When calcium influx is lower, E cells co-exist with cells able to maintain normal ATP and low calcium contents in vigorous pump-leak balance (B cells). The experiments reported here investigate why calcium-induced ATP depletion of E cells is irreversible. 2. The inosine monophosphate (IMP) content of cells after 30 min of calcium permeabilization increased with the magnitude of the calcium load, roughly in inverse proportion to the fall in ATP. The calcium-induced increase in IMP was confined to the fraction of cells which became osmotically resistant after SCN- treatment (H cells), and which contained the E cells. 3. Cell nucleotides were measured after calcium permeabilization [( A23187]c = 100 mumol/l cells) in substrate-free media with different [Ca2+]o (0-0.5 mM). Calcium entry caused rapid ATP fall, AMP and IMP accumulation, and delayed ADP fall at all [Ca2+]o concentrations. Initial IMP formation increased with [Ca2+]o along a sigmoid saturation-like curve whereas AMP accumulation and ATP fall were maximal at [Ca2+]o = 20 microM and declined at the higher [Ca2+]o. The rate of IMP formation correlated positively with cell ATP and negatively with cell AMP at all [Ca2+]o values. 4. The AMP deaminase activity of red cell lysates was reversibly increased over tenfold by calcium. Half-maximal stimulation was observed at a Ca2+ concentration of about 50 microM. 5. These results suggest that the irreversibility of calcium-induced ATP depletion results from irreversible trapping of the adenine nucleotide as IMP, and help explain the mechanism of E cell formation.

Detection and separation of human red cells with different calcium contents following uniform calcium permeabilization

1. The human red cell, permeabilized to calcium with the ionophore A23187, is extensively used to study Ca2+ transport and the effects of intracellular Ca2+ on transport and metabolism. The interpretation of results with calcium-permeabilized cells, in general, has depended on the implicit assumption that the ionophore-induced calcium distribution among the cells is uniform. 2. To establish whether or not calcium permeabilization with the ionophore A23187 generated a uniform calcium distribution in normal-ATP red cells, a method was developed to detect and separate calcium-permeabilized red cells with different calcium contents. For the method to uncover pre-existing heterogeneity without itself inducing it, it was essential to preserve the calcium distribution which existed at the time of sampling. The method was based (i) on the ability of cytoplasmic Ca2+ to activate K+-selective channels in the membrane, and (ii) on the demonstration here that thiocyanate (SCN-) is a non-limiting co-ion for rapid net KSCN efflux and cell shrinkage in the cold. 3. Calcium-permeabilized cells in pump-leak steady state were washed free of ionophore using ice-cold, albumin-containing media. Subsequent incubation at 0 degrees C in low-K+ media with 45-75 mM-SCN- generated dense-cell fractions (H cells) in less than 10 min. These could be separated from the remaining light cells (L cells) by either centrifugation over phthalate oils, or differential osmotic haemolysis, with conservation of the mean total cell calcium. 4. Analysis of the calcium content of H and L cell fractions revealed striking differences in their calcium content, with 70-99% of the mean total cell calcium in the H cell fraction. 5. The ionophore content of density-separated cells, processed with omission of the ionophore removal step, was similar for cells with high- and low-calcium. Magnesium loss from ionophore-treated red cells suspended in magnesium-free media followed single exponentials. Thus ionophore distribution and induced permeability were uniform, and the unequal cell calcium content must be due to factors affecting active calcium extrusion.

Maximal calcium extrusion capacity and stoichiometry of the human red cell calcium pump

1. The uphill calcium efflux through calcium-saturated pumps in intact red cells was investigated with the aid of a new method, in initial conditions of uniform ionophore A23187-induced calcium distribution among the cells. The method is based on findings by Tiffert, García-Sancho & Lew (1984) which show that cobalt can suddenly arrest passive calcium transport by the ionophore and expose, without noticeable interference, uphill calcium extrusion by the pump. The results comprise methodological aspects and questions concerning interactions between inner pump sites, ATP and Ca2+, and the calcium: ATP stoichiometry of the calcium-saturated pump. 2. Ionophore-induced calcium influx was set to be far in excess of the maximal calcium pump capacity. This secured a uniform calcium distribution among the cells, and Ca2+ equilibration by 2 min or less of calcium permeabilization. Cobalt was added between 15 s and 5 min after ionophore addition. The calcium and ATP content of the cells was followed during ionophore-induced influx and cobalt-exposed efflux. 3. The external cobalt concentrations required to block completely ionophore-mediated calcium transport were similar or only marginally higher than those of calcium. 4. The reproducibility of independent cobalt-exposed calcium efflux measurements from single blood samples was within an 8% range. 5. During cobalt-exposed calcium efflux, the calcium content of subpopulations of cells, with and without active Ca2+-sensitive K+ channels, investigated by post-incubation of samples in low-K+, thiocyanate (SCN-) media (modified from García-Sancho & Lew, 1988a), was similar. This is consistent with the maintenance of a uniform calcium distribution among the cells during uphill calcium extrusion. 6. Cobalt-exposed calcium efflux was similar in the interval from 15 s to 5 min after calcium permeabilization although cell ATP levels had fallen by over 50% in that period. Therefore, cell ATP concentrations within the physiological range do not seem to be regulatory for calcium-saturated pumps in the intact red cell. 7. All cobalt-exposed calcium efflux curves were linear in time, at least until total cell calcium contents reached levels below 100 mumol/l cells. This suggests that internal calcium is not inhibitory for calcium-saturated efflux in intact cells in the 0.1-1 mmol/l cells range. 8. The cobalt-exposed calcium fluxes were in the range from 4 to 24 mmol/(1 cells.h) for fresh cells and from 10 to 18 mmol/1 cells. h) for samples from the Blood Bank.(ABSTRACT TRUNCATED AT 400 WORDS)

Asymmetric effects of divalent cations and protons on active Ca2+ efflux and Ca2+-ATPase in intact red blood cells

The influence of the asymmetric addition of various divalent cations and protons on the properties of active Ca2+ transport have been examined in intact human red blood cells. Active Ca2+ efflux was determined from the initial rate of 45Ca2+ loss after CoCl2 was added to block Ca2+ loading via the ionophore A23187. Ca2+-ATPase activity was measured as phosphate production over 5 min in cells equilibrated with EGTA-buffered free Ca2+ in the presence of A23187. The apparent Ca affinity of active Ca2+ efflux (K0.5 = 30-40 mumol/liter cells) was significantly lower than that measured by the Ca2+-ATPase assay (K0.5 = 0.4 microM). Possible reasons for this apparent difference are considered. Both active Ca2+ efflux and Ca2+-ATPase activity were reduced to less than 5% of maximal levels (20 mmol/liter cells.hr) in Mg2+-depleted cells, and completely restored by reintroduction of intracellular Mg2+. Active Ca2+ efflux was inhibited almost completely by raising external CaCl2 (but not MgCl2) to 20 mM, probably by interaction of Ca2+ at the externally oriented E2P conformation of the pump. Cd2+ was more potent than Ca2+ in this inhibition, while Mn2+ was less potent and 10 mM Ba2+ was without effect. A Ca2+: proton exchange mechanism for active Ca2+ efflux was supported by the results, as external protons (pH 6-6.5) stimulated active Ca2+ efflux at least twofold above the efflux rate at pH 7.8 Ca2+ transport was not affected by decreasing the membrane potential across the red cell.