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

Proton-gated ion channels in cultured mouse cortical neurons

Proton-gated ion channels in cultured mouse cortical neurons were characterized using the patch clamp technique. In voltage clamp, rapid shifts of the extracellular saline from pH 7.4 to < 7.0 invariably triggered inward currents carried by sodium. The currents were inhibited by Amiloride (IC50: 6.2 microM). In current clamp, acidic saline depolarized the neurons and triggered trains of action potentials. Concentration-response experiments revealed an extreme intercell variance as the EC50-value for protons varied from pH 6.8 to 5.6, indicating heterogeneity in channel type expression from cell to cell. The possible involvement of acid sensing ion channels in ischemic neurodegeneration is discussed.

Effects of pH conditions on Ca2+ transport catalyzed by ionophores A23187, 4-BrA23187, and ionomycin suggest problems with common applications of these compounds in biological systems

Phospholipid vesicles loaded with Quin-2 and 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein (BCECF) have been used to investigate the effects of pH conditions on Ca2+ transport catalyzed by ionophores A23187, 4-BrA23187, and ionomycin. At an external pH of 7.0, a delta pH (inside basic) of 0.4-0.6 U decreases the rate of Ca2+ transport into the vesicles by severalfold under some conditions. The apparent extent of transport is also decreased. In contrast, raising the pH by 0.4-0.6 U in the absence of a delta pH increases both of these parameters, although by smaller factors. The relatively large effects of a delta pH on the transport properties of Ca2+ ionophores seem to reflect a partial equilibration of the transmembrane ionophore distribution with the H+ concentration gradient across the vesicle membrane. This unequal distribution of ionophore can cause a very slow or incomplete ionophore-dependent equilibration of delta pCa with delta pH. A second factor of less certain origin retards full equilibration of delta pCa when delta pH = 0. These findings call into question several ionophore-based methods that are used to investigate the regulatory activities of Ca2+ and other divalent cations in biological systems. Notable among these are the null-point titration method for determining the concentration of free cations within cells and the use of ionophores plus external cation buffers to calibrate intracellular cation indicators. The present findings also indicate that the transport mode of Ca2+ ionophores is more strictly electroneutral than was thought, based upon previous studies.

Erythrocyte Ca2+ handling in the spontaneously hypertensive rat, effect of vanadate ions

Cytosolic Ca2+ concentration ([Ca2+]i) and 45Ca2+ influx were investigated in erythrocytes from conscious spontaneously hypertensive rats (SHR) and their normotensive controls Wistar-Kyoto (WKY). [Ca2+]i was evaluated with fura-2 and intra- and extra-cellular calibration parameters were compared. Irrespective of the calibration parameters used, erythrocyte [Ca2+]i was always significantly higher in SHR than in WKY and Wistar rats (by 25 and 40%, p < 0.01 and 0.001). A rise of the external Ca2+ concentration from 1 to 2 mmol/l increased less [Ca2+]i in SHR than in WKY erythrocytes (17 vs 37%, p < 0.01). SHR erythrocytes incorporated more 45Ca2+ than those from WKY, with an initial rate of 45Ca2+ uptake higher by 57% than that of WKY erythrocytes (p < 0.05). Vanadate ions, after corrections of their quenching effect on red cell and fura-2 fluorescence signals, increased [Ca2+]i by 19% in WKY erythrocytes (p = 0.05), but did not modify the SHR values. They also increased 45Ca2+ accumulation and the initial rate of 45Ca2+ influx in WKY erythrocytes only (p < 0.01). This study indicates that, when compared to WKY rats, erythrocytes from SHR are characterized by higher [Ca2+]i values, higher initial rate of Ca2+ influx and low sensitivity to vanadate ions.

Ca2+-activated K+ conductance of the human red cell membrane: voltage-dependent Na+ block of outward-going currents

Human red cells were prepared with various cellular Na+ and K+ concentrations at a constant sum of 156 mM. At maximal activation of the K+ conductance. gK(Ca). the net efflux of K+ was determined as a function of the cellular Na+ and K+ concentrations and the membrane potential. Vm, at a fixed [K+]ex of approximately 3.5 mM. Vm was only varied from (Vm-EK) approximately equal to 25 mV and upwards, that is, outside the range of potentials with a steep inward rectifying voltage dependence (Stampe & Vestergaard-Bogind, 1988). gK(Ca) as a function of cellular Na+ and K+ concentrations at Vm = -40.0 and 40 mV indicated a competitive, voltage-dependent block of the outward current conductance by cellular Na+. Since the present Ca2+-activated K+ channels have been shown to be of the multi-ion type, the experimental data from each set of Na+ and K+ concentrations were fitted separately to a Boltzmann-type equation, assuming that the outward current conductance in the absence of cellular Na+ is independent of voltage. The equivalent valence determined in this way was a function of the cellular Na+ concentration increasing from 0.5 to 1.5 as this concentration increased from 11 to 101 mM. Data from a previous study of voltage dependence as a function of the degree of Ca2+ activation of the channel could be accounted for in this way as well. It is therefore suggested that the voltage dependence of gK(Ca) for outward currents at (Vm-Ek) greater than 25 mV reflects a voltage-dependent Na+ block of the Ca2+-activated K+ channels.

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.

Ca2+-activated K+ conductance of human red cell membranes exhibits two different types of voltage dependence

The voltage dependence for outward-going current of the Ca-activated K+ conductance (gK(Ca] of the human red cell membrane has been examined over a wide range of membrane potentials (Vm at constant values of [K+]ex, [K+]c and pHc, the intact cells being preloaded to different concentrations of ionized calcium. Outward-current conductances were calculated from initial net effluxes of K+ and the corresponding (Vm - EK) values. The basic conductance, defined as the outward-current conductance at (Vm - EK) greater than or equal to 20 mV and [K+]ex greater than or equal to 3 mM (B. Vestergaard-Bogind, P. Stampe and P. Christophersen, J. Membrane Biol. 95:121-130, 1987) was found to be a function of cellular ionized Ca. At all degrees of Ca activation gK(Ca) was an apparently linear function of voltage (Vm range -40 to +70 mV), the absolute level as well as the slope decreasing with decreasing activation. In a simple two-state model the constant voltage dependence can, at the different degrees of Ca activation, be accounted for by a Boltzmann-type equilibrium function with an equivalent valence of approximately 0.4, assuming chemical equilibrium at Vm = 0 mV. Alternatively, the phenomenon might be explained by a voltage-dependent block of the outward current by an intracellular ion. Superimposed upon the basic conductance is the apparently independent inward-rectifying steep voltage function with an equivalent valence of approximately 5 and chemical equilibrium at the given EK value.

The effect of ATP, intracellular calcium and the anion exchange inhibitor DIDS on conductive anion fluxes across the human red cell membrane

The influence of ATP depletion, the intracellular ionized Ca-concentration, anion substitution and DIDS on the conductive anion fluxes across the human red cell membrane has been examined. Under physiological or near physiological conditions it is not possible to observe conductive anion fluxes across the erythrocyte membrane in that anions totally dominate the membrane conductance. Consequently anions are at electro-chemical equilibrium and the netflux is zero. However, conductive anion fluxes can be induced by raising the potassium conductance, either by addition of valinomycin, or by triggering the native calcium activated potassium channel by addition of the Ca2+ ionophore A23187 to cells suspended in a calcium containing medium. The interpretation of data from experiments with valinomycin induced netfluxes has normally been done according to a constant field model, and the results have consequently been given as permeabilities. Since it has been demonstrated recently, that these cation pathways do not conform to a constant field scheme (Bennekou, P. and Christophersen, P. (1986) J. Membr. Biol. 93, 221-227 and Vestergaard-Bogind, B., Stampe, P. and Christophersen, P. (1985) J. Membr. Biol. 88, 67-75), it has been chosen, instead of permeabilities, to calculate the ion conductances from net efflux data, using an independent estimate of the membrane potential. The main result reported, is that only one component is found for the conductive anion fluxes in the presence of DIDS using the latter theoretical framework, whereas a sizeable DIDS-insensitive component is found when the constant field analysis is used. Furthermore it is found that ATP and intracellular calcium do not influence the anion conductances.

Regulation of ion permeability in frog brain venules. Significance of calcium, cyclic nucleotides and protein kinase C

1. The effect on ionic permeability of frog brain endothelium of various second messengers was studied by a technique based on continuous recording of the electrical resistance of the venular endothelium in vivo. 2. Augmentation of the cytosolic Ca2+ concentration in endothelial cells induced with the ionophores ETH 1001 and A23187 increased ion permeability significantly as reflected in the reduced electrical resistance. 3. The electrical resistance fell reversibly within 1-2 s after administration of Ca2+-activating agents. The maximal effect was a reduction to about 0.70 times the pre-experimental resistance value. The resistance decrease was similar to that induced by several inflammatory mediators (Olesen & Crone, 1986). 4. Administration of the following agents did not change the electrical wall resistance: 8-bromo-cyclic AMP, dibutyryl-cyclic AMP, forskolin, 8-bromo-cyclic GMP, dibutyryl-cyclic GMP, sodium nitroprusside, phorbol myristate acetate (a protein kinase C stimulator). Changes in cytosolic Mg2+ did not affect permeability. 5. Ca2+ may be an important cytosolic signal in the endothelial cell, acting as an intracellular mediator for several permeability-augmenting substances.

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.

Bile salts induce calcium uptake in vitro by human erythrocytes

At high concentrations, bile salts induce hemolysis by comicellization of lipid components of the cell membrane. However, bile salts are also associated with hemolysis at lower concentrations by mechanisms which have not been characterized. To investigate the possibility that bile salts promote calcium uptake by red blood cells and that bile salt-associated hemolysis is, in part, calcium-mediated, calcium uptake by red blood cells was measured in the presence of individual bile salts, and hemolysis dependence upon calcium availability was examined. Washed human red blood cells with or without ATP depletion were incubated with 1 mM CaCl2 and tracer amounts of 45CaCl2 in the presence of selected bile salts at concentrations (0.01 to 0.3 mM) reported to be below critical micellar concentrations. Calcium uptake (defined for the purposes of this study as 45Ca retained in red blood cells) was monitored over 5 hr, after which hemolysis and membrane phospholipid content were determined. The presence of bile salts stimulated calcium uptake 4- to 25-fold--the magnitude of which was partly related to the lipid solubility of the bile salts. ATP depletion or exposure to trifluoperazine, procedures which inhibit calcium pump activity in red blood cells, enhanced bile salt-induced calcium uptake relative to controls. The percentage of associated hemolysis (2 to 14%) at the end of 5 hr correlated directly with the observed calcium uptake. Removal of calcium from the extracellular space reduced hemolysis in the presence of bile salts to control levels.(ABSTRACT TRUNCATED AT 250 WORDS)

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 mediated calcium uptake in ATP depleted human red cells

The A23187 induced calcium uptake in ATP depleted cells was determined at pH 6.9 in the presence of trifluoperazine (TFP, 0.30 mM), 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). Apart from verapamil the drugs all increased the maximum rate of ionophore-mediated calcium flux by 50-60 per cent. After the ionophore addition some time elapsed before the calcium flux attained the maximum value, and this time dependence could be interpreted as a slow uptake of A23187 into the membrane: five seconds after the addition of A23187 half of the added ionophore was able to transport calcium through the membrane. The effect of pH on the ionophore-mediated calcium uptake was determined in the absence and presence of TFP. At pH 7.4 the maximum rate of calcium flux in the absence of TFP was two to three times higher than that at pH 6.9 and TFP increased the uptake rate by 98 per cent.

K+-valinomycin and chloride conductance of the human red cell membrane. Influence of the membrane protonophore carbonylcyanide m-chlorophenylhydrazone

Chloride ion conductance of the human red cell membrane has been calculated, as the ratio between ion net charge flux and driving potential. The proton carrier CCCP was used to monitor changes in membrane potential following addition of valinomycin in sufficient quantities to raise the K+ conductance to a level comparable to the Cl- conductance. A K+-specific electrode was used to monitor changes in extracellular K+ concentration, and an H+-sensitive glass electrode for changes in extracellular pH, reflecting changes in membrane potential. The effects of varied concentrations of valinomycin and CCCP upon K+ and Cl- conductances were studied. It was found that, within an experimental error of about 10% S.D., the chloride conductance was constant for valinomycin concentrations in the range 1.0 X 10(-8)-1.0 X 10(-6), and for CCCP-concentrations in the range 2.0 X 10(-7)-2.0 X 10(-5) mol per litre cell suspension, while at a constant concentration of valinomycin the induced K+ conductance was considerably augmented by addition of CCCP.