Properties of the Ca2+-activated K+ channel in one-step inside-out vesicles from human red cell membranes

Ca2+-activated K+ channels in human red cells. Comparison of single-channel currents with ion fluxes

Exposure of the inner surface of intact red cells or red cell ghosts to Ca2+ evokes unitary currents that can be measured in cell-attached and cell-free membrane patches. The currents are preferentially carried by K+ (PK/PNa 17) and show rectification. Increasing the Ca2+ concentration from 0 to 5 microM increases the probability of the open state of the channels parallel to the change of K+ permeability as observed in suspensions of red cell ghosts. Prolonged incubation of red cell ghosts in the absence of external K+ prevents the Ca2+ from increasing K+ permeability. Similarly, the probability to find Ca2+-activated unitary currents in membrane patches is drastically reduced. These observations suggest that the Ca2+-induced changes of K+ permeability observed in red cell suspensions are causally related to the appearance of the unitary K+ currents. Attempts to determine the number of K+ channels per cell were made by comparing fluxes measured in suspensions of red cells with the unitary currents in membrane patches as determined under comparable ionic conditions. At 100 mM KCl in the external medium, where no net movements of K+ occur, the time course of equilibration of 86Rb+ does not follow a single exponential. This indicates a heterogeneity of the response to Ca2+ of the cells in the population. The data are compatible with the assumption that 25% of the cells respond with Pk = 33.2 X 10(-14)cm3/s and 75% with Pk = 3.1 X 10(-14)cm3/s. At 100 mM external K+ the zero current permeability of a single channel is 6.1 X 10(-14)cm3/s (corresponding to a conductance of 22 pS). Using appropriate values for the probability of a channel in the open state, we estimated that 25% of the cells in the population contain 11-55, and 75% of the cells 1-5 channels per cell that are activated in the time average (20 degrees C, pH 7.6).

Effects of electron donors on Ca2+-dependent K+ transport in one-step inside-out vesicles from the human erythrocyte membrane

The interactions between reducing agents and Ca2+ in the activation of Ca2+-dependent K+ transport have been studied in one-step inside-out vesicles. The artificial electron donor system ascorbate + phenazine methosulphate increases the apparent sensitivity to Ca2+ by about 5-times over control values (half activation constant, about 5 X 10(-8) M) while oxidized cytochrome c decreases the sensitivity to about 1/3 of the controls. Using redox buffers at a fixed pCa it is shown that the shift from the low to the high-affinity state can be accounted by the reduction of a membrane component accepting two electrons and with an apparent standard redox potential (pH 7.5) of 47 mV. The electrons can be transferred directly from reduced PMS or to oxidized cytochrome c, but not from ascorbate, NADH or reduced glutathione.

Mechanism, regulation and physiological significance of the loop diuretic-sensitive NaCl/KCl symport system in animal cells

Investigations in numerous laboratories have characterized a salt transport system, present in many animal cell types, which catalyzes the transmembrane transport of NaCl and KCl in a tightly coupled process. The system is inhibited by loop diuretics such as furosemide and bumetanide. This transport system has been designated the loop diuretic-sensitive NaCl/KCl symporter. It has been implicated in transepithelial salt secretion and absorption as well as in cell volume regulation, and it may be defective in patients suffering from essential hypertension. This review serves to evaluate research conducted to date regarding the mechanism, mode of regulation, and physiological significance of the transport system. Ion binding specificities and absolute binding constants for all three naturally occurring ions have been determined in one cell system, the MDCK kidney epithelial cell line. In that same cell line, substrate binding was shown to exhibit apparent cooperativity. although a few reports suggest unidirectional transport of ions via this system under certain conditions, the consensus of reports indicates fully reversible, bidirectional salt transport with the direction of net flux determined by the magnitudes of the gradients of the three transported ions. Growth of cells in media containing a low concentration of K+ (less than 0.25 mM) allows selection of mutants lacking or defective in the symporter. Kinetic analyses with the MDCK cell line have shown that the symporter catalyzes accelerative exchange transport. However, exchange transport of one ion in the absence of one of the other two ionic substrates has not been documented. Comparison with other well-characterized transmembrane transport systems has shown that the characteristics of the NaCl/KCl symporter most resemble those of two-species facilitators (chemiosmotically-coupled symporters) found in prokaryotes and eukaryotes alike. these two-species facilitators consist of a single transmembrane protein and may function by a carrier-type mechanism as originally proposed by Peter Mitchell. A molecular model for the NaCl/KCl symporter is presented and discussed. Activation of symport activity requires ATP and probably occurs by a protein kinase-catalyzed mechanism. In some cell types activation is cyclic AMP dependent. ATP hydrolysis is not stoichiometric with transport. Phosphorylation of an integral membrane protein with an apparent size of 240 000 daltons correlates with activation of transport. It is postulated that this protein is the loop diuretic-sensitive NaCl/KCl symporter.

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.

Volume-induced increase of K+ and Cl- permeabilities in Ehrlich ascites tumor cells. Role of internal Ca2+

Ehrlich ascites tumor cells resuspended in hypotonic medium initially swell as nearly perfect osmometers , but subsequently recover their volume within 5 to 10 min with an associated KCl loss. 1. The regulatory volume decrease was unaffected when nitrate was substituted for Cl-, and was insensitive to bumetanide and DIDS. 2. Quinine, an inhibitor of the Ca2+- activated K+ pathway, blocked the volume recovery. 3. The hypotonic response was augmented by addition of the Ca2+ ionophore A23187 in the presence of external Ca2+, and also by a sudden increase in external Ca2+. The volume response was accelerated at alkaline pH. 4. The anti-calmodulin drugs trifluoperazine, pimozide, flupentixol, and chlorpromazine blocked the volume response. 5. Depletion of intracellular Ca2+ stores inhibited the regulatory volume decrease. 6. Consistent with the low conductive Cl- permeability of the cell membrane there was no change in cell volume or Cl- content when the K+ permeability was increased with valinomycin in isotonic medium. In contrast, addition of the Ca2+ ionophore A23187 in isotonic medium promoted Cl- loss and cell shrinkage. During regulatory volume decrease valinomycin accelerated the net loss of KCl, indicating that the conductive Cl- permeability was increased in parallel with and even more than the K+ permeability. It is proposed that separate conductive K+ and Cl- channels are activated during regulatory volume decrease by release of Ca2+ from internal stores, and that the effect is mediated by calmodulin.

Properties of the CA2+-activated K+ conductance of human red cells as revealed by the patch-clamp technique

Application of Ca2+ to the inner surface of red-cell membranes activates unitary currents that can be measured in cell-attached and cell-free membrane patches. Ca2+ can be replaced by Pb2+ to activate the single channels. In addition to internal Ca2+ external K+ has to be present. The channels are preferentially permeable to K+ with a selectivity ratio PK:PNa of about 15:1 as estimated from measurement of reversal potentials. The dependence of channel activity on Ca2+ is compatible with the conception that the binding of two Ca2+ is necessary to open a single channel. Both the channel activity and the single-channel conductance exhibit inward rectification. External and internal Na+ inhibit the K+ currents. The reported results suggest that the unitary current events are responsible for the Ca2+-dependent K+ permeability known from measurement on cell suspensions. Therefore, comparison of the two techniques allows calculation of the number of K+ channels per red cell, which on average is about 10.

Effects of redox agents on the Ca2+-activated K+ channel

The sensitivity to Ca2+ of the Ca2+-dependent K+ channel can be increased by the artificial electron donor system ascorbate + phenazine-methosulphate in a variety of animal cells. In the human erythrocyte the shift from the 'low' to the 'high-affinity' state seems to depend on the reduction of a membrane component accepting 2 electrons and with an standard redox potential (pH 7.5) of about 47 mV. The relevance of this redox modulation under physiological circumstances is unknown at the moment.

Effects of p-nitrophenylphosphate on Ca2+ transport in inside-out vesicles from human red-cell membranes

Ca2+-ATPase activity and Ca2+ uptake in inside-out vesicles from human red cell membranes are changed in parallel by p-nitrophenylphosphate. This indicates that, unlike the Ca2+ pump of sarcoplasmic reticulum, the Ca2+ pump of the red cell membrane does not utilize p-nitrophenylphosphate hydrolysis to drive Ca2+ transport.

Ca2+ regulation of tight-junction permeability and structure in Necturus gallbladder

To explore the role of Ca2+ in tight-junction permeability, the Necturus gallbladder was exposed to varying Ca2+ concentrations and to the Ca2+ ionophore A23187 added to the mucosal side (1.9 X 10(-6) to 6.8 X 10(-5) M). Electrophysiological parameters measured in an Ussing-type chamber were correlated with tight-junction morphology revealed by freeze-fracture electron microscopy. In Ca2+-free bathing media, transepithelial resistance decreases and tight-junctional ultrastructure is fragmented. In 1.8 mM Ca2+ media, A23187 induces an initial drop in transepithelial resistance, followed by an increase in transepithelial resistance to a value 20% above base line. At peak response to A23187, NaCl diffusion potentials decrease. Freeze-fracture replicas reveal that the number of junctional strands increase pari passu with junctional depth. Both physiological and morphological changes were partially reversible. The initial decrease in transepithelial resistance coincided with a persistent hyperpolarization of the mucosal cell membrane potential difference and a decrease in the mucosal-to-serosal cell membrane resistance ratio. Thus A23187 alters both the transcellular and paracellular pathway, resulting in opposing effects on transepithelial resistance.

Induction of 86Rb fluxes by Ca2+ and volume changes in thymocytes and their isolated membranes

Cell swelling and elevated intracellular Ca2+ increase K+ permeability in lymphocytes. Experiments were performed to test whether these effects can also be elicited in isolated plasma membrane vesicles. Rabbit thymocytes, used as a source of membrane vesicles, were found to regain their volume after swelling in hypotonic, low-K+ media. This regulatory volume decrease (RVD) was inhibited by quinine and trifluoperazine, but not affected by ouabain. Both efflux and uptake of K+ (86Rb) were stimulated by hypotonicity. Addition of A23187 plus Ca2+ also increased 86Rb fluxes. Ca2+- and volume-induced 86Rb fluxes were also studied in isolated membranes. A plasma membrane-rich vesicle fraction, enriched over 11-fold in 5'-nucleotidase, was isolated from thymocytes. The vesicles were about 35% inside-out and trapped 86Rb in an osmotically active compartment of approximately 1.3 microliter/mg protein. Equilibrium exchange fluxes of 86Rb in the vesicles were unaffected by Ca2+ with or without A23187. Calmodulin had no effect on 86Rb permeability but stimulated ATP-dependent Ca2+ accumulation. Hypotonic swelling increased both uptake and efflux of 86Rb from vesicles. However, this increase was not blocked by either quinine or trifluoperazine, was not specific for K+ (86Rb), and is probably unrelated to RVD. It is concluded that components essential for the volume- and Ca2+-induced changes in K+ permeability are lost or inactivated during membrane isolation. An intact cytoarchitecture may be required for RVD.

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

Ionophore A23187-mediated Ca2+-induced oscillations in the conductance of the Ca2+-sensitive K+ channels of human red cells were monitored with ion specific electrodes. The membrane potential was continuously reflected in CCCP-mediated pH changes in the buffer-free medium, changes in extracellular K+ activity were followed with a K+-selective electrode, and changes in the intracellular concentration of ionized calcium were calculated on the basis of cellular 45Ca content. An increased cellular 45Ca content at the successive minima of the oscillations where the K+ channels are closed indicates that the activation of the channels might be a (dCa2+/dt)-sensitive process and that accommodation to enhanced levels of intracellular free calcium may occur. An incipient inactivation of the K+ channels at intracellular ionized calcium levels of about 10 microM and a concurrent membrane potential of about -65 mV was observed. At a membrane potential of about -70 mV and an intracellular concentration of about 2 X 10(-4) M no inactivation of K+ channels took place. Inactivation of the K+ channels is suggested to be a compound function of the intracellular level of free calcium and the membrane potential. The observed sharp peak values in cellular 45Ca content support the notion that a necessary component of the oscillatory system is a Ca2+ pump operating with a significant delay in the activation/inactivation process in response to changes in cellular concentration of ionized calcium.