Spontaneous inactivation of the Ca2+-sensitive K+ channels of human red cells at high intracellular Ca2+ activity

Caffeine activates a mechanosensitive Ca(2+) channel in human red cells

Caffeine is known to activate influx of both mono- and divalent cations in various cell types, suggesting that this xanthine opens non-selective cation channels at the plasma membrane. This possibility was investigated in human erythrocytes, studying the caffeine action on net Ca(2+), Na(+) and K(+) movements in ATP-depleted cells. Whole populations and subpopulations of young and old erythrocytes were employed. Caffeine was tested in the presence of known mechanosensitive channel blockers (Gd(3+), neomycin and amiloride) and ruthenium red as a possible inhibitor. Caffeine enhanced net cation fluxes in a concentration-dependent way. In whole populations, the Ca(2+) entry elicited by 20 mM caffeine was fully suppressed by Gd(3+) (5 microM), amiloride (250 microM) and ruthenium red (100 microM) and partially blocked by neomycin (100 microM). The above blockers also inhibited caffeine-dependent Na(+) entry whilst showing antagonistic effects on the corresponding K(+) efflux. These compounds fully suppressed hypotonically-induced (-35 mOsm/kg) Ca(2+) influx at nearly the same concentrations completely blocking caffeine-stimulated Ca(2+) entry. The effect of inhibitors on Ca(2+) influx in young cells exceeded that in old cells at similar concentrations. The results clearly show that caffeine stimulates a stretch-activated Ca(2+) channel in human red cells and that aged cells are less susceptible to mechanosensitive channel blockers.

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.

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.

Steady-state and transient membrane potentials in human red cells determined by protonophore-mediated pH changes

Protonophores have been used frequently to determine changes in membrane potential in suspensions of red cells, since such changes are reflected by changes in extracellular pH, due to proton and consequently protonophore reequilibration. In a previous paper (Bennekou, P. 1988, J. Membrane Biol. 102:225-234) a kinetic model for the translocation of a protonophore, CCCP, across the human red cell membrane was established. This model accounts for the protonophore reequilibration following abrupt changes in membrane potential. In this paper the limitations of the method with regard to the estimation of transient membrane potentials are examined, using the transport model to simulate changes in extracellular pH in response to noninstantaneous changes in membrane potential. The temperature and time resolution calculated from the model are reported. Furthermore, it is shown that the transport model established for CCCP is valid for another protonophore, TCS, thus indicating the general validity of the transport scheme for the entire class of protonophores.

Oscillation of ion fluxes in mammalian erythrocytes. Mechanism of oscillation

The dependence of ionophore-induced oscillations in rat erythrocytes on various concentrations of A23187, FCCP and Ca2+ was analysed using ion-selective electrodes. The oscillations were shown to be independent of the extracellular concentration of carbonylcyanide p-trifluoromethoxyphenylhydrazone and Ca2+. The dependence of oscillations on the concentration A23187 was shown to be a threshold characteristic and represented by a bell-shaped curve. In the course of oscillations the redistribution of A23187 between cells and the incubation medium was demonstrated using high-speed centrifugation. A hypothesis for oscillatory-state generation in erythrocytes was suggested on the basis of pH-dependent changes of the Ca2+ ionophore A23187 content in cells. According to this hypothesis the H+ concentration within the external membrane-adjacent layer serves as a causative factor for induction of cyclic desorption of A23187 molecules from the cell membrane.

Voltage dependence of the Ca2+-activated K+ conductance of human red cell membranes is strongly dependent on the extracellular K+ concentration

The conductance of the Ca2+-activated K+ channel (gK(Ca)) of the human red cell membrane was studied as a function of membrane potential (Vm) and extracellular K+ concentration ([K+]ex). ATP-depleted cells, with fixed values of cellular K+ (145 mM) and pH (approximately 7.1), and preloaded with approximately 27 microM ionized Ca were transferred, with open K+ channels, to buffer-free salt solutions with given K+ concentrations. Outward-current conductances were calculated from initial net effluxes of K+, corresponding Vm, monitored by CCCP-mediated electrochemical equilibration of protons between a buffer-free extracellular and the heavily buffered cellular phases, and Nernst equilibrium potentials of K ions (EK) determined at the peak of hyperpolarization. Zero-current conductances were calculated from unidirectional effluxes of 42K at (Vm-EK) approximately equal to 0, using a single-file flux ratio exponent of 2.7. Within a [K+]ex range of 5.5 to 60 mM and at (Vm-EK) greater than or equal to 20 mV a basic conductance, which was independent of [K+]ex, was found. It had a small voltage dependence, varying linearly from 45 to 70 microS/cm2 between 0 and -100 mV. As (Vm-EK) decreased from 20 towards zero mV gK(Ca) increased hyperbolically from the basic value towards a zero-current value of 165 microS/cm2. The zero-current conductance was not significantly dependent on [K+]ex (30 to 156 mM) corresponding to Vm (-50 mV to 0). A further increase in gK(Ca) symmetrically around EK is suggested as (Vm-EK) becomes positive. Increasing the extracellular K+ concentration from zero and up to approximately 3 mM resulted in an increase in gK(Ca) from approximately 50 to approximately 70 microS/cm2. Since the driving force (Vm-EK) was larger than 20 mV within this range of [K+]ex this was probably a specific K+ activation of gK(Ca).

IN CONCLUSION

The Ca2+-activated K+ channel of the human red cell membrane is an inward rectifier showing the characteristic voltage dependence of this type of channel.

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

The net Ca2+ influx was increased in human red cells in suspension by adding moderate concentrations of the Ca2+ ionophore A23187, and due to the increased cellular Ca2+ concentration [( Ca]i) the K+ channels opened (the 'Gardos effect'). At low K+ concentration and with the protonophore CCCP in the buffer-free medium the cells hyperpolarized and the extracellular pH (pH0) increased, enhancing the A23187-mediated net Ca2+ influx. This elicited a prolonged response, viz. a primary transient increase of pH0 and [Ca]i followed by one or more spontaneous pH0 and [Ca]i transients. We explored the pump-mediated Ca2+ efflux by blocking the A23187-mediated Ca2+ flux with CoCl2 at appropriate times during the prolonged response. The Ca2+ pumping was higher during the descendent than during the ascendent phase of the primary transient at equal values of [Ca]i. The data were analyzed using a mathematical model that accounts for the prolonged oscillatory response, including pH0 and [Ca]i. In conclusion, the activation of the Ca2+ pump is delayed due to slow binding of cellular calmodulin, which is a hysteretic response to a rapid increase of the cellular Ca2+ concentration. This mechanism may be important for generation and execution of transient signals in other types of cell.

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.

Single-file diffusion through the Ca2+-activated K+ channel of human red cells

The ratio between the unidirectional fluxes through the Ca2+-activated K+-specific ion channel of the human red cell membrane has been determined as a function of the driving force (Vm-EK). Net effluxes and 42K influxes were determined during an initial period of approximately 90 sec on cells which had been depleted of ATP and loaded with Ca. The cells were suspended in buffer-free salt solutions in the presence of 20 microM of the protonophore CCCP, monitoring in this way changes in membrane potential as changes in extracellular pH. (Vm-EK) was varied at constant EK by varying the Nernst potential and the conductance of the anion and the conductance of the potassium ion. In another series of experiments EK was varied by suspending cells in salt solutions with different K+ concentrations. At high extracellular K+ concentrations both of the unidirectional fluxes were determined as 42K in- and effluxes in pairs of parallel experiments. Within a range of (Vm-EK) of -6 to 90 mV the ratio between the unidirectional fluxes deviated strongly from the values predicted by Ussing's flux ratio equation. The Ca2+-activated K+ channel of the human red cell membrane showed single-file diffusion with a flux ratio exponent n of 2.7. The magnitude of n was independent of the driving force (Vm-EK), independent of Vm and independent of the conductance gK.

Effect of trifluoperazine, compound 48/80, TMB-8 and verapamil on ionophore A23187 induced calcium transients in human red cells

A transient increase of cellular calcium was induced by addition of the divalent cation ionophore A23187 to human red cells in the absence or presence of drugs. The peak height of the calcium transient was increased about five times at pH 6.9 and up to eighteen times at pH 7.4 by trifluoperazine (0.30 mM), and two to three times at pH 6.9 by compound 48/80 (0.89 mg/ml), 8-(N,N-diethylamino)octyl-3,4,5-trimethoxybenzoate (TMB-8, 2.13 mM) and verapamil (1.81 mM). The time-dependent changes of cellular calcium were analysed by the aid of a pump-leak model based partly on the calcium dependent parameters obtained from calcium ATPase experiments, partly on the A23187 induced calcium fluxes determined in experiments with ATP depleted cells. The transient increase of cellular calcium induced within few minutes after the addition of ionophore A23187 could be explained satisfactorily by the model both in the absence and presence of the four drugs, whereas the final level of cellular calcium in the drug experiments was more difficult to predict from the pump-leak model. Comparison of experimental and model calcium transients suggested that trifluoperazine and TMB-8 affected both pump and leak, whereas compound 48/80, probably due to low membrane-permeability, mainly affected the leak and verapamil affected the pump only.

Trans to cis proton concentration gradients accelerate ionophore A23187-mediated net fluxes of Ca2+ across the human red cell membrane

Ionophore A23187-mediated net influx of Ca2+ in ATP-depleted human red cells was studied as a function of the pH and the proton concentration gradient across the membranes. Utilizing the Ca2+-induced increase in K+ conductance of the cell membranes, various CCCP-mediated proton gradients were raised across the membranes of cells suspended in unbuffered salt solutions with different K+ concentrations. In ionophore-mediated equilibrium the concentration ratios of ionized Ca between ATP-depleted, DIDS-treated cells and their suspension medium were equal to the concentration ratios of protons raised to the second power. With no proton concentration gradient across the membranes the net influxes of Ca2+ as a function of pH resembled a titration curve of a weak acid, with half maximal net influx at pH 7.3, at 100 microM extracellular Ca2+. With cellular pH fixed at various values, the net influx of Ca2+ was determined as a function of the proton concentration gradient. A linear relationship between the logarithm of net influx and the difference between extracellular and cellular pH was found at all cellular pH values tested, but the proton concentration gradient acceleration was a function of the cellular pH. Accelerations between 10- and 40- times per unit delta pH were found and net effluxes were correspondingly decreased. The results are discussed in relation to present models of the mechanism of ionophore A23187-mediated Ca2+ transport. The importance of the proton concentration gradient dependency is discussed in relation to the induced oscillations in K+-conductance of human red cell membranes previously reported (Vestergaard-Bogind and Bennekou (1982) Biochim. Biophys. Acta 688, 37-44).

Effect of pH and proton buffer on oscillations of ion fluxes in rat erythrocytes

The pH-dependence of ionophore-induced oscillations of transmembrane H+ and K+ fluxes in rat erythrocytes has been studied. It is stated that the oscillations are strongly depressed at pH lower than 6.9 and higher than 7.3. Proton buffers of different nature (Tris/HCl, Mops and glycylglycine) are shown to effectively inhibit the oscillatory process. The significance of H+ concentration in unstirred layers adjacent to the membrane in the mechanism of oscillations is suggested.

A calmodulin activated Ca2+-dependent K+ channel in human erythrocyte membrane inside-out vesicles

The role of calmodulin in stimulating active calcium transport in the human red cell membrane is well documented. In contrast, efforts to characterize the effect of calmodulin on the Ca2+-dependent K+ channel in erythrocyte membranes have given rise to conflicting reports. These studies have indicated that experimental conditions may play a critical role in preserving the Ca2+-dependent K+ channels in erythrocyte inside-out vesicles. With these observations in mind, a double-labelling study of simultaneous active Ca2+ and passive Rb+ uptake in red-cell inside-out vesicles was undertaken. Addition of calmodulin and ATP to a suspension of inside-out vesicles containing 1 mM K+ caused a Ca2+-dependent increase in both the rate of active calcium transport and Rb+ uptake. The initial Rb+ isotope flux was increased 3-fold over the rate observed in the absence of calmodulin. The k1/2 for activation of K+ permeability was approx. 5 X 10(-7) M Ca2+ as compared to 10(-6) M Ca2+ for active Ca2+ transport. Addition of the calmodulin antagonists pimozide and chlorpromazine blocked calmodulin activation of the Ca2+-dependent K+ channel. The observation that activation of the K+ channel occurs at Ca2+ concentrations which are lower than those required for maximum stimulation of the calcium pump suggests that these processes are dependent on two states of the calmodulin molecule, characterized by a lower or higher amount of Ca2+ bound to calmodulin.

Hysteretic activation of the Ca2+ pump revealed by calcium transients in human red cells

The enzymatic basis for the Ca2+ pump in human red cells is an ATPase with hysteretic properties. The Ca2+-ATPase shifts slowly between a ground state deficient in calmodulin and an active state saturated with calmodulin, and rate constants for the reversible shifts of state were recently determined at different Ca2+ concentrations (Scharff, O. and Foder, B. (1982) Biochim. Biophys. Acta 691, 133-143). In order to study whether the Ca2+ pump in intact red cells also exhibits hysteretic properties we have analysed transient increases of intracellular calcium concentrations (Cai), induced by the divalent cation ionophore A23187. The time-dependent changes of Cai were measured by use of radioactive calcium (45Ca2+) and analysed with the aid of a mathematical model, based partly on the Ca2+-dependent parameters obtained from Ca2+-ATPase experiments, partly on the A23187-induced Ca2+ fluxes determined in experiments with intact red cells. According to the model a delay in the activation of the Ca2+ pump is a prerequisite for the occurrence of A23187-induced calcium transients in the red cells, and we conclude that the Ca2+ pump in human red cells responds hysteretically. It is suggested that Ca2+ pumps in other types of cell also have hysteretic properties.