A putative K(+)-selective channel in the plasma membrane of yeast that is blocked by micromolar concentrations of external divalent cations and is insensitive to tetraethylammonium

At pH 7, addition of glucose to an anaerobic suspension of non-metabolizing yeast cells causes a transient net efflux of K+ from the cells and a concomitant transient hyperpolarization of the plasma membrane (Van de Mortel, J.B.J., et al. (1988) Biochem. Biophys. Acta 936, 421-428). Both phenomena are effectively suppressed in the presence of low concentrations of polyvalent cations. The concentrations of Mn2+, Ca2+, Ba2+, Mg2+, Sr2+ and La3+ required for half-maximal suppression of the transient hyperpolarization are 10, 17, 20, 38, 47 and 5 microM, respectively. Subsequent addition of EDTA 90 s after that of Ca2+ immediately restores both K+ efflux and cellular uptake of the fluorescent membrane potential probe 2-(dimethylaminostyryl)-1-ethylpyridinium (DMP). This suggests that an interaction of polyvalent cations with an external binding site blocks the putative K(+)-selective channel. Opening of this channel is not blocked by 20 mM tetraethylammonium nor by 100 microM 3,4-diaminopyridine. It is argued that this glucose-induced K(+)-conductive pathway is not identical to the voltage-gated K+ channels identified until now in patch-clamp studies of the yeast plasma membrane.     

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).(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Calcium-Activated K+ Channels and Calcium-Induced Calcium Release by Slow Vacuolar Ion Channels in Guard Cell Vacuoles Implicated in the Control of Stomatal Closure

Stomatal closing requires the efflux of K+ from the large vacuolar organelle into the cytosol and across the plasma membrane of guard cells. More than 90% of the K+ released from guard cells during stomatal closure originates from the guard cell vacuole. However, the corresponding molecular mechanisms for the release of K+ from guard cell vacuoles have remained unknown. Rises in the cytoplasmic Ca2+ concentration have been shown to trigger ion efflux from guard cells, resulting in stomatal closure. Here, we report a novel type of largely voltage-independent K+-selective ion channel in the vacuolar membrane of guard cells that is activated by physiological increases in the cytoplasmic Ca2+ concentration. These vacuolar K+ (VK) channels had a single channel conductance of 70 pS with 100 mM KCI on both sides of the membrane and were highly selective for K+ over NH4+ and Rb+. Na+, Li+, and Cs+ were not measurably permeant. The Ca2+, voltage, and pH dependences, high selectivity for K+, and high density of VK channels in the vacuolar membrane of guard cells suggest a central role for these K+ channels in the initiation and control of K+ release from the vacuole to the cytoplasm required for stomatal closure. The activation of K+-selective VK channels can shift the vacuolar membrane to more positive potentials on the cytoplasmic side, sufficient to activate previously described slow vacuolar cation channels (SV-type). Analysis of the ionic selectivity of SV channels demonstrated a Ca2+ over K+ selectivity (permeability ratio for Ca2+ to K+ of ~3:1) of these channels in broad bean guard cells and red beet vacuoles, suggesting that SV channels play an important role in Ca2+-induced Ca2+ release from the vacuole during stomatal closure. A model is presented suggesting that the interaction of VK and SV channel activities is crucial in regulating vacuolar K+ and Ca2+ release during stomatal closure. Furthermore, the possibility that the ubiquitous SV channels may represent a general mechanism for Ca2+-induced Ca2+ release from higher plant vacuoles is discussed.     

Cadmium as a tool for studying calcium-dependent cation permeability of the human red blood cell membrane.

Three Ca(2+)-dependent procedures known to increase cation permeability of red blood cell membranes were tested with Cd2+ ions which equal Ca2+ ions both in their charge and the crystal radius, 1. Increase of non-selective permeability for monovalent cations by incubating the red cells in a Ca(2+)-free sucrose medium. Addition of Cd2+ to the suspension of leaky cells failed to restore the initial impermeability of the red cell membrane while a repairing effect of Ca2+ was evident both in the presence and absence of Cd2+. Thus, in low electrolyte medium, Cd2+ could neither mimic Ca2+, nor prevent the latter from interacting with membrane structures which control cation permeability. 2. Increase of the K(+)-selective permeability by propranolol plus Ca2+. Cd2+ added to a Ca(2+)-free Ringer type medium containing propranolol enhanced K+ permeability similar to that obtained with Ca2+. No changes of membrane permeability could be detected in the presence of 0.5 mmol/l Cd2+ in absence of propranolol. The Cd(2+)-stimulated K+ channels were different from those induced by Ca2+. They proved to be insensitive to quinine, exhibited a low K+/Na+ selectivity, and showed no tendency to self-inactivation. 3. Stimulation of K+ permeability by electron donors plus Ca2+. Substitution of Ca2+ by Cd2+ yielded results similar to those obtained with propranolol. The ability of Cd2+ to overtake the role of Ca2+ appears to depend on the system studied. It supplies information allowing to distinguish between the diverse Ca(2+)-dependent systems in cell membranes.     

Effect of hemolysate on calcium inhibition of the (Na+ + K+)-ATPase of human red blood cells

The sensitivity of the (Na+ + K+)-ATPase in human red cell membranes to inhibition by Ca2+ is markedly increased by the addition of diluted cytoplasm from hemolyzed human red blood cells. The concentration of Ca2+ causing 50% inhibition of the (Na+ + K+)-ATPase is shifted from greater than 50 microM free Ca2+ in the absence of hemolysate to less than 10 microM free Ca2+ when hemolysate diluted 1:60 compared to in vivo concentrations is added to the assay mixture. Boiling the hemolysate destroys its ability to increase the sensitivity of the (Na+ + K+)-ATPase to Ca2+. Proteins extracted from the membrane in the presence of EDTA and concentrated on an Amicon PM 30 membrane increased the sensitivity of the (Na+ + K+)-ATPase to Ca2+ in a dose-dependent fashion, causing over 80% inhibition of the (Na+ + K+)-ATPase at 10 microM free Ca2+ at the highest concentration of the extract tested. The active factor in this membrane extract is Ca2+-dependent, because it had no effect on the (Na+ + K+)-ATPase in the absence of Ca2+. Trypsin digestion prior to the assay destroyed the ability of this protein extract to increase the sensitivity of the (Na+ + K+)-ATPase to Ca2+.     

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).     

Potassium channels in primary cultures of seawater fish gill cells. I. Stretch-activated K(+) channels

Previous studies using the patch-clamp technique demonstrated the presence of a small conductance Cl(-) channel in the apical membrane of respiratory gill cells in primary culture originating from sea bass Dicentrarchus labrax. We used the same technique here to characterize potassium channels in this model. A K(+) channel of 123 +/- 3 pS was identified in the cell-attached configuration with 140 mM KCl in the bath and in the pipette. The activity of the channel declined rapidly with time and could be restored by the application of a negative pressure to the pipette (suction) or by substitution of the bath solution with a hypotonic solution (cell swelling). In the excised patch inside-out configuration, ionic substitution demonstrated a high selectivity of this channel for K(+) over Na(+) and Ca(2+). The mechanosensitivity of this channel to membrane stretching via suction was also observed in this configuration. Pharmacological studies demonstrated that this channel was inhibited by barium (5 mM), quinidine (500 microM), and gadolinium (500 microM). Channel activity decreased when cytoplasmic pH was decreased from 7.7 to 6.8. The effect of membrane distension by suction and exposure to hypotonic solutions on K(+) channel activity is consistent with the hypothesis that stretch-activated K(+) channels could mediate an increase in K(+) conductance during cell swelling.     

Fatty acid modifies Ca2+-dependent potassium channel activity in smooth muscle cells from the human aorta

By using the patch-clamp technique the effect of 2-decenoic acid (DA) on Ca2+-activated potassium (K+) channels in the membrane of smooth muscle cells from the human aorta was studied. In the presence of 0.5 microM Ca2+ and 2 mM Mg2+ on the cytoplasmic side of the membrane, a more than tenfold elevation in the probability of the channels being open (po) was observed under the effect of DA. With divalent cation concentrations of less than 1 nM DA caused a more than twofold elevation in po. In the DA-treated membranes Mg2+ ions, which normally fail to activate the channels, brought about a nearly threefold increase in the channel activity when applied to the inner membrane surface. Channel sensitivity to the activating effect of cytoplasmic Ca2+ ions did not increase with the application of DA. Single-channel conductance was unchanged by DA exposure. We suggest that DA alters the Ca2+-binding mechanism of the channel, increasing its sensitivity to Mg2+ ions, presumably owing to membrane fluidization.     

Ca2(+)-activated K+ channels from rabbit kidney medullary thick ascending limb cells expressed in Xenopus oocytes.

Ca2(+)-activated K+ channels are present in muscle, nerve, pancreas, macrophages, and renal cells. They are important in such diverse functions as neurotransmitter release, muscle excitability, pancreatic secretion, and cell volume regulation. Although much is known about the biophysics of Ca2(+)-activated K+ channels, the molecular structure, cDNA and amino acid sequences are unknown. We injected size-fractionated mRNA isolated from cultured rabbit kidney medullary thick ascending limb cells in Xenopus oocytes and observed newly expressed K+ currents using two-microelectrode voltage-clamp technique. The expressed K+ currents are Ca2+ dependent and inhibited by charybdotoxin, a specific blocker of Ca2(+)-activated K+ channels. Amplitudes of the current ranged from 30 nA to more than 1 microA at a membrane potential of +30 mV. Reversal potential of the current suggested a K(+)-selective channel. The peak activity of Ca2(+)-activated K+ channels were observed in fractions corresponding to a message RNA with size of approximately 4.5 kilobases.     

Calcium-induced oscillations in K+ conductance and membrane potential of human erythrocytes mediated by the ionophore A23187

The time-dependence of ionophore A23187-induced changes in the conductance of the Ca2+-sensitive K+ channels of the human red cell has been monitored with ion-specific electrodes. The membrane potential was reflected in CCCP-mediated pH changes in a buffer-free extracellular medium, and changes in extracellular K+ activity and electrode potential of an extracellular Ca2+-electrode were recorded. Within a narrow range of ionophore-mediated Ca2+ influx, the above-mentioned parameters were found to oscillate when ionophore was added to a suspension of glucose-fed cells. The period of oscillation was about 2 min/cycle depending on ionophore concentration, and the amplitude of hyperpolarization was about 60 mV, corresponding to a maximal gK+ of the same magnitude as gCl-. Without CCCP present no oscillation in K+ conductance was observed. The Ca2+ affinity for the opening process was in the micromolar range. The closing of the K+ channels was a spontaneous process in that the depolarization was well under way before the Ca2+-ATPase-mediated Ca2+ net efflux started. Below the Ca2+ influx range for oscillations, no response was observed for up to 20 min after the addition of ionophore. Above the upper limit, a permanent hyperpolarization resulted with an extracellular K+ activity increasing monotonically as a function of time. In experiments with ATP-depleted cells, responses of the latter type ensued at all ionophore concentrations above the lower limit. Addition of surplus EGTA to suspensions of hyperpolarized cells restores the normal membrane potential in the case of glucose-fed cells, whereas the K+-channels in ATP-depleted cells remained open.     

Somatostatin inhibits insulin secretion by a G-protein-mediated decrease in Ca2+ entry through voltage-dependent Ca2+ channels in the beta cell.

We tested the hypothesis that somatostatin (SRIF) inhibits insulin secretion from an SV40 transformed hamster beta cell line (HIT cells) by an effect on the voltage-dependent Ca2+ channels and examined whether G-proteins were involved in the process. Ca2+ currents were recorded by the whole cell patch-clamp method, the free cytosolic calcium, [Ca2+]i, was monitored in HIT cells by fura-2, and cAMP and insulin secretion were measured by radioimmunoassay. SRIF decreased Ca2+ currents, [Ca2+]i, and basal insulin secretion in a dose-dependent manner over the range of 10(-12)-10(-7)M. The increase in [Ca2+]i and insulin secretion induced by either depolarization with K+ (15 mM) or by the Ca2+ channel agonist, Bay K 8644 (1 microM) was attenuated by SRIF in a dose-dependent manner over the same range of 10(-12)-10(-7) M. the half-maximal inhibitory concentrations (IC50) for SRIF inhibition of insulin secretion were 8.6 X 10(-12) M and 8.3 X 10(-11) M for K+ and Bay K 8644-stimulated secretion and 1 X 10(-10) M and 2.9 X 10(-10) M for the SRIF inhibition of the K+ and Bay K 8644-induced rise in [Ca2+]i, respectively. SRIF also attenuated the rise in [Ca2+]i induced by the cAMP-elevating agent, isobutylmethylxanthine (1 mM) in the presence of glucose. Bay K 8644, K+ and SRIF had no significant effects on cAMP levels and SRIF had no effects on adenylyl cyclase activity at concentrations lower than 1 microM. SRIF (100 nM) did not change K+ efflux (measured by 86Rb+) through ATP-sensitive K+ channels in HIT cells. SRIF (up to 1 microM) had no significant effect on membrane potential measured by bisoxonol fluorescence. Pretreatment of the HIT cells with pertussis toxin (0.1 microgram/ml) overnight abolished the effects of SRIF on Ca2+ currents, [Ca2+]i and insulin secretion implying a G-protein dependence in SRIF's actions. Thus, one mechanism by which SRIF decreases insulin secretion is by inhibiting Ca2+ influx through voltage-dependent Ca2+ channels, an action mediated through a pertussis toxin-sensitive G-protein.     

Inhibition by quercetin of thyroid hormone stimulation in vitro of human red blood cell Ca2+-ATPase activity

Human red blood cell membrane Ca2+-ATPase activity is stimulated in vitro by physiological concentrations of thyroid hormone. Quercetin, a flavonoid that inhibits several membrane-linked ATPases, suppressed thyroid hormone action on red cell Ca2+-ATPase activity and also interfered with binding of the hormone by red cell membranes. These effects of quercetin were dose-dependent over a range of concentrations (1-50 microM). In contrast, in the absence of thyroid hormone, quercetin at low concentrations stimulated Ca2+-ATPase activity and at 50 microM inhibited the enzyme. The effects of quercetin at low concentrations (1-10 microM), namely, stimulation of Ca2+-ATPase and inhibition of membrane-binding of thyroid hormone, mimic those of thyroid hormone and are consistent with the thyronine-like structure of quercetin. At high concentrations, quercetin is generally inhibitory of Ca2+-ATPase activity. Chalcone, fisetin, hesperetin and tangeretin are other flavonoids shown to reduce susceptibility of membrane Ca2+-ATPase to hormonal stimulation.     

Multiple types of voltage-dependent Ca2+-activated K+ channels of large conductance in rat brain synaptosomal membranes

K+-selective ion channels from a mammalian brain synaptosomal membrane preparation were inserted into planar phospholipid bilayers on the tips of patch-clamp pipettes, and single-channel currents were measured. Multiple distinct classes of K+ channels were observed. We have characterized and described the properties of several types of voltage-dependent, Ca2+-activated K+ channels of large single-channel conductance (greater than 50 pS in symmetrical KCl solutions). One class of channels (Type I) has a 200-250-pS single-channel conductance. It is activated by internal calcium concentrations greater than 10(-7) M, and its probability of opening is increased by membrane depolarization. This channel is blocked by 1-3 mM internal concentrations of tetraethylammonium (TEA). These channels are similar to the BK channel described in a variety of tissues. A second novel group of voltage-dependent, Ca2+-activated K+ channels was also studied. These channels were more sensitive to internal calcium, but less sensitive to voltage than the large (Type I) channel. These channels were minimally affected by internal TEA concentrations of 10 mM, but were blocked by a 50 mM concentration. In this class of channels we found a wide range of relatively large unitary channel conductances (65-140 pS). Within this group we have characterized two types (75-80 pS and 120-125 pS) that also differ in gating kinetics. The various types of voltage-dependent, Ca2+-activated K+ channels described here were blocked by charybdotoxin added to the external side of the channel. The activity of these channels was increased by exposure to nanomolar concentrations of the catalytic subunit of cAMP-dependent protein kinase. These results indicate that voltage-dependent, charybdotoxin-sensitive Ca2+-activated K+ channels comprise a class of related, but distinguishable channel types. Although the Ca2+-activated (Type I and II) K+ channels can be distinguished by their single-channel properties, both could contribute to the voltage-dependent Ca2+-activated macroscopic K+ current (IC) that has been observed in several neuronal somata preparations, as well as in other cells. Some of the properties reported here may serve to distinguish which type contributes in each case. A third class of smaller (40-50 pS) channels was also studied. These channels were independent of calcium over the concentration range examined (10(-7)-10(-3) M), and were also independent of voltage over the range of pipette potentials of -60 to +60 mV.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cadmium uptake and toxicity via voltage-sensitive calcium channels

The mechanism of cellular uptake of cadmium, a highly toxic metal ion, is not known. We have studied cadmium uptake and toxicity in an established secretory cell line, GH4C1, which has well characterized calcium channels. Nimodipine, an antagonist of voltage-sensitive calcium channels, protected cells against cadmium toxicity by increasing the LD50 for CdCl2 from 15 to 45 microM, whereas the calcium channel agonist BAY K8644 decreased the LD50. Organic calcium channel blockers of three classes protected cells from cadmium toxicity at concentrations previously shown to block high K+-induced 45Ca2+ influx and secretion. Half-maximal protective effects were obtained at 20 nM nifedipine, 4 microM verapamil, and 7 microM diltiazem. Increasing the extracellular calcium concentration from 20 microM to 10 mM also protected cells from cadmium by causing a 5-fold increase in the LD50 for CdCl2. Neither the calcium channel antagonist nimodipine nor the agonist BAY K8644 altered intracellular metallothionein concentrations, while cadmium caused a 9-20-fold increase in metallothionein over 18 h. Cadmium was a potent blocker of depolarization-stimulated 45Ca2+ uptake (IC50 = 4 microM), and the net uptake of cadmium measured with 109Cd2+ was less than 0.3% that of calcium. Although the rate of cadmium uptake was low relative to that of calcium, entry via voltage-sensitive calcium channels appeared to account for a significant portion of cadmium uptake; 109Cd2+ uptake at 30 min was increased 57% by high K+/BAY K8644, which facilitates entry through channels. Furthermore, calcium channel blockade with 100 nM nimodipine decreased total cell 109Cd2+ accumulation after 24 h by 63%. These data indicate that flux of cadmium through dihydropyridine-sensitive, voltage-sensitive calcium channels is a major mechanism for cadmium uptake by GH4C1 cells, and that pharmacologic blockade of calcium channels can afford dramatic protection against cadmium toxicity.     

Investigation of Ca2+ -induced changes of membrane potential of smooth muscle mitochondria using flow cytometric analysis

Using flow cytometric analysis and potential-sensitive fluorescent dye TMRM Ca2+ -induced changes of membrane potential of isolated smooth muscle mitochondria were studied. It was shown, that Ca2+ (100 microM) addition to the incubation medium induced mitochondrial membrane depolarization that probably could be explained by Ca2+/H+ -exchanger activation which functioning lead to membrane potential dissipation. In the case of ruthenium red (10 microM) preliminary presence in incubation medium, Ca2+ (100 microM) addition did not lead to membrane potential dissipation. Hence, membrane potential dissipation was caused by an increase of matrix Ca2+ concentration. In the presence of Mg2+ (3 mM) and ATP (3 mM), Ca2+ addition did not cause depolarization. It was supposed that in this case ATP synthase acted in the opposite direction as H+ -pump and prevented from mitochondrial membrane potential dissipation. Thus, the flow cytometry method allows to register membrane potential of isolated smooth muscle mitochondria and also to test the effectors, capable to modulate this parameter.     

Pathways of cadmium influx in mammalian neurons

The influx of the toxic cation Cd2+ was studied in fura 2-loaded rat cerebellar granule neurons. In cells depolarized with Ca2(+)-free, high-KCI solutions, the fluorescence emission ratio (R) increased in the presence of 100 microM Cd2(+). This increase was fully reversed by the Cd2+ chelator tetrakis(2-pyridylmethyl)ethylenediamine, indicating a cadmium influx into the cell. The rate of increase, dR/dt, was greatly reduced (67+/-5%) by 1 microM nimodipine and enhanced by 1 microM Bay K 8644. Concurrent application of nimodipine and omega-agatoxin IVA (200 nM) blocked Cd2+ permeation almost completely (88+/-5%), whereas omega-conotoxin MVIIC (2 microM) reduced dR/dt by 24+/-8%. These results indicate a primary role of voltage-dependent calcium channels in Cd2+ permeation. Stimulation with glutamate or NMDA and glycine also caused a rise of R in external Cd2+. Simultaneous application of nimodipine and omega-agatoxin IVA moderately reduced dR/dt (25+/-3%). NMDA-driven Cd2(+) entry was almost completely prevented by 1 mM Mg2+, 50 microM memantine, and 10 microM 5,7-dichlorokynurenic acid, suggesting a major contribution of NMDA-gated channels in glutamate-stimulated Cd2+ influx. Moreover, perfusion with alpha-amino-3-hydroxy-5-methylisoxazole-4-propionate caused a slow increase of R. These results suggest that Cd2+ permeates the cell membrane mainly through the same pathways of Ca2+ influx.     

Simultaneous flux and current measurement from single plant protoplasts reveals a strong link between K+ fluxes and current, but no link between Ca2+ fluxes and current

We present a thorough calibration and verification of a combined non-invasive self-referencing microelectrode-based ion-flux measurement and whole-cell patch clamp system as a novel and powerful tool for the study of ion transport. The system is shown to be capable of revealing the movement of multiple ions across the plasma membrane of a single protoplast at multiple voltages and in complex physiologically relevant solutions. Wheat root protoplasts are patch clamped in the whole-cell configuration and current-voltage relations obtained whilst monitoring net K+ and Ca2+ flux adjacent to the membrane with ion-selective electrodes. At each voltage, net ion flux (nmol m(-2) sec(-1)) is converted to an equivalent current density (mA m(-2)) taking into account geometry and electrode efficiency, and compared with the net current density measured with the patch clamp system. Using this technique, it is demonstrated that the K+-permeable outwardly rectifying conductance (KORC) is responsible for net outward K+ movement across the plasma membrane [1:1 flux-to-current ratio (1.21 +/- 0.14 SEM, n = 15)]. Variation in the K+ flux-to-current ratio among single protoplasts suggests a heterogeneous distribution of KORC channels on the membrane surface. As a demonstration of the power of the technique we show that despite a significant Ca2+ permeability being associated with KORC (analysis of tail current reversal potentials), there is no correlation between Ca2+ flux and KORC activity. A very significant observation is that large Ca2+ fluxes are electrically silent and probably tightly coupled to compensatory charge movements. This analysis demonstrates that it is mandatory to measure flux and currents simultaneously to investigate properly Ca2+ transport mechanisms and selectivity of ion channels in general.     

Identification and characterization of the inward K+ channel in the plasma membrane of Brassica pollen protoplasts.

Patch clamp techniques have been used to identify and characterize the whole-cell currents carried by inward K+ channels in isolated matured pollen protoplasts of Brassica chinensis var. chinensis. The whole-cell inward currents in the isolated pollen protoplasts were activated at hyperpolarized membrane potentials more negative than -100 mV. The magnitudes of the whole-cell inward currents were strongly dependent on the external K+ concentration, and were highly selective for K+ over other monovalent cations. The inward currents were not observed when external K+ was replaced with the same concentration of Cs+ or Na+. The addition of 1 mM or 10 mM Ba2+ in external solutions resulted in 30% or 80% inhibition of the inward currents at -180 mV, respectively. These results demonstrated that the inward K+ currents mainly account for the recorded whole-cell inward currents in Brassica pollen protoplasts. Increase of cytoplasmic Ca2+ concentrations from 10 nM to 30 microM or even 5 mM did not affect the inward K+ currents. Decrease of external Ca2+ concentrations from 10 mM to 1 mM inhibited the inward K+ currents by 25%, while the increase of external Ca2+ from 10 mM to 50 mM almost completely blocked the inward K+ currents. Physiological importance of K+ transport into pollen and its possible regulatory mechanisms are also discussed.     

Role of exercise-induced potassium fluxes underlying muscle fatigue: a brief review

The site of exercise-induced muscle fatigue is suggested to be the muscle membrane, which includes the sarcolemma and T-tubule membrane; the excitability of the membrane is dependent on the membrane potential. Significant potassium flux from the intracellular space of contracting muscle may decrease the membrane potential to half its resting value. This is true for isolated muscle preparations as well as for the whole body exercise in humans. Specific K+ channels have been identified, that may account for the intracellular K+ loss. Calcium-sensitive K+ channels open when intracellular Ca2+ concentrations increase, as during excitation. ATP-sensitive K+ channels may be involved but may open only at ATP concentrations well below those attained at exhaustion. However, ATP may be compartmentalized and only the membrane-bound ATP concentration may be of significance. Ca2+ accumulation and ATP depletion cause cell destruction; these changes induce an increased K+ conductance, which may inactivate the membrane and consequently prevent tension development. It is hypothesized that such a safety mechanism is identical to the fatigue mechanism.