Activation and deactivation of sarcoplasmic reticulum calcium release channels: Molecular dissection of mechanisms via novel semi-synthetic ryanoids

The plant alkaloids ryanodine and dehydroryanodine are high affinity, biphasic modulators of the intracellularly located, calcium-regulated calcium release channels of a variety of cell types. To date, little is certain about the molecular basis of the interactions that prompt low concentrations of ryanodine (nanomolar to low micromolar) to activate (open) the channels and higher concentrations to deactivate (functionally close) the sarcoplasmic reticulum calcium release channel. In the present study, we approached this question using novel, semi-synthetic C₁₀–O_eq ester derivatives of ryanodine and dehydroryanodine as molecular probes of the ryanodine binding sites on the calcium release channel.Binding affinities of these C₁₀–O_eq ester derivatives of ryanodine and dehydroryanodine with acidic, basic and neutral side chains (K_d values> 53.9 nM, K_d values 0.3–0.7 nM and K_d values 1.3–20.4 nM, compared with 2.3 and 2.8 nM for ryanodine and dehydroryanodine, respectively) were evaluated for their ability to modulate, the patency of the sarcoplasmic reticulum calcium release channel. With the exception of only two derivatives tested to date, all the semi-synthetic C₁₀–O_eq esters selectivelyactivate the Ca²⁺ release channel. That is, they produce no functional closure of the sarcoplasmic reticulum calcium release channels at the highest concentration, that could be tested. Half-maximal concentrations for activation (EC_50act , values) ranged from 0.87–4.2, M, compared with an EC_50act of 1.3 M for ryanodine.     

Activation and conductance properties of ryanodine-sensitive calcium channels from brain microsomal membranes incorporated into planar lipid bilayers

Summary Rat brain microsomal membranes were found to contain high-affinity binding sites for the alkaloid ryanodine (k _d 3nm.B _max 0.6 pmol per mg protein). Exposure of planar lipid bilayers to microsomal membrane vesicles resulted in the incorporation, apparently by bilayer-vesicle fusion, of at least two types of ion channel. These were selective for Cl^– and Ca²⁺, respectively. The reconstituted Ca²⁺ channels were functionally modified by 1 m ryanodine, which induced a nearly permanently open subconductance state. Unmodified Ca²⁺ channels had a slope conductance of almost 100 pS in 54mm CaHEPES and a Ca²⁺/TRIS⁺ permeability ratio of 11.0. They also conducted other divalent cations (Ba²⁺>Ca²⁺>Sr²⁺>Mg²⁺) and were markedly activated by ATP and its nonhydrolysable derivative AMPPCP (1mm). Inositol 1,4,5-trisphosphate (1–10 m) partially activated the same channels by increasing their opening rate. Brain microsomes therefore contain ryanodine-sensitive Ca²⁺ channels, sharing some of the characteristics of Ca²⁺ channels from striated but not smooth muscle sarcoplasmic reticulum. Evidence is presented to suggest they were incorporated into bilayers following the fusion of endoplasmic reticulum membrane vesicles, and their sensitivity to inositol trisphosphate may be consistent with a role in Ca²⁺ release from internal membrane stores.     

Novel actions of ryanodine and analogues—Perturbers of potassium channels

The effects of ryanodine, 9,21-didehydroryanodine and 9,21-didehydroryanodol on two types of K⁺ channel (a maxi, Ca²⁺-activated, 170 pS channel (BK channel) and an inward rectifier, stretch-sensitive channel of 35 pS conductance (IK channel) found in the plasma membrane of locust skeletal muscle have been investigated. 10^–9M-10^–5M ryanodine irreversibly induced a dose-dependent reduction of the reversal potential (V_rev) of the currents of both channels, i.e. from 60 mV in the absence of the alkaloid to 15 mV for 10^–5M ryanodine, measured under physiologically normal K⁺ and Na⁺ gradients. In both cases the change in the ionic selectivity was Ca²⁺-independent. 9,21-didehydroryanodine and 9,21-didehyroryanodol also reduced V_rev, but only to 35 mV during application of 10^–5M of these compounds. Additionally, 9,21-didehydroryanodine reversibly diminished the conductances of the two K⁺ channels. To test the hypothesis that ryanoids increase Na⁺ permeability by enlarging the K⁺ channels, the channels were probed with quaternary ammonium ions during ryanoid application. When applied to the cytoplasmic face of inside-out patches exised from locust muscle membrane, TEA blocked the K⁺ channels in a voltage-dependent fashion. The dissociation constant (K_d(0)) for TEA block of the IK channel was reduced from 44 mM to 1 mM by 10^–7 M ryanodine, but the voltage-dependence of the block was unaffected. Qualitatively similar data were obtained for the BK channel. Ryanodine had no effect on the K_d for cytoplasmically-applied TMA. However, the voltage-dependence for TMA block was increased for both K⁺ channels, from 0.47 to 0.8 with 10^–6M ryanodine. The effects of ryanodine on TEA and TMA block support the hypothesis that ryanodine enlarges the K⁺ channels so as to facilitate permeation of partially hydrated Na⁺ ions.     

Inward rectifier K channels in renal epithelioid cells (MDCK) activated by serotonin

Summary The present study has been performed to test for the effect of intracellular calcium and of serotonin on the channel activity in patches from subconfluent MDCK-cells. In inside-out patches, inwardly rectifying potassium-selective channels are observed with open probabilities of 0.01±0.01, 0.24±0.03 and 0.39±0.07, at 100 nmol/liter, 1 mol/liter or 10 mol/liter calcium activity, respectively. The single-channel slope conductance is 34±2 pS, if the potential difference across the patch (V ) is zero, and approaches 59±1 pS, ifV is –50 mV, cell negative. In the cell-attached mode, little channel activity is observed prior to application of serotonin (open probability=0.03±0.03). If 1 mol/liter serotonin is added to the bath perfusate, the open probability increases rapidly to a peak value of 0.34±0.04 within 8 sec. In continued presence of the hormone, the open probability declines to approach 0.06±0.02 within 30 sec. At zero potential difference between pipette and reference in the bath (i.e., the potential difference across the patch is equal to the potential difference across the cell membrane), the single-channel conductance is 59±4 pS. In conclusion, inwardly rectifying potassium channels have been identified in the cell membrane of subconfluent MDCK-cells, which are activated to a similar extent by increase of intracellular calcium activity to 1 mol/liter and by extracellular application of 1 mol/liter serotonin.     

Cyclic GMP-activated channels of the chick pineal gland: Effects of divalent cations,pH, and cyclic AMP

Chick pineal cells maintained in dissociated cell culture express an intrinsic photosensitive circadian oscillator, but the mechanisms of phototransduction in avian pinealocytes are not fully understood. In this study, we have used inside-out patches to examine the characteristics of cyclic GMP-activated channels of chick pinealocytes in more detail, concentrating on the effects of factors known to modulate the secretion of melatonin and/or the function of circadian pacemakers. In most patches, the predominant conductance state was 19 pS in symmetrical 145 mM NaCl. But in some patches, a second cyclic GMP-activated channel with a unitary conductance of 29 pS was also present. The current flowing through cyclic GMP-activated channels was not affected by application of salines containing 1 M Ca²⁺ to the cytoplasmic face of the patch membrane. By contrast, application of 1 mM Ca²⁺ caused a partial reduction in cyclic GMP-activated current at all membrane potentials. Application of 1–5 mM Mg²⁺ ions caused a virtually complete blockade of current at positive membrane potentials, but caused only a small decrease in current at negative membrane potentials. No obvious differences in the gating of cyclic GMP-activated channels were observed in pH 8.2, 7.4 or 6.2 salines. Application of salines containing 100 M, 500 M, or 1 mM cyclic AMP did not cause activation of the channels, but 5 mM cyclic AMP evoked a low level of channel activity. Application of 5 mM but not 100 M cyclic AMP decreased the probability of channel activation caused by 20–100 M cyclic GMP and also increased the percentage of openings to an 11 pS subconductance state. Thus, cyclic AMP acts as a weak partial agonist. Nevertheless, the gating of these channels does not seem to be controlled directly by physiologically relevant changes in intracellular Ca²⁺, pH, or cyclic AMP.     

Comparative study of K channel behavior inβ cell lines with different secretory responses to glucose

Summary The patch-clamp technique was used to identify and investigate two K channels in the cell membrane of the HIT cell, an insulin secreting cell line with glucose-sensitive secretion. Channel characteristics were compared with those of glucose-modulated K channels in the RINm5F cell, an insulin secreting cell line in which secretion is largely glucose insensitive. A 65.7 pS channel, identified with the ATP-sensitive K channel was seen in HIT cell-attached patches. Channel activity was dose-dependently inhibited by glucose, by 50 and 100% at 450 m and 8mm glucose, respectively, similar to the values previously reported for RIN cells. In inside-out patches channel activity was 50% inhibited by 56 m ATP and completely blocked between 500 m and 1mm, again, similar to the values reported for RIN cells.As in RIN cells a second, considerably larger (184 pS), K channel was glucose sensitive; the glucose sensitivity was similar to that in RIN cells with 50 and 100% channel inhibition at 7.5 and 25mm, respectively. After patch excision the mean channel conductance increased from 184 to 215 pS. Under these conditions activity was strongly calcium dependent in the rangepCa 5–7, identifying this as a calcium- and voltage-dependent K (K(Ca,V)) channel; the calcium sensitivity was similar to that of the adult rat cell K(Ca,V) channel. In inside-out RIN cell patches, the large K channel was less abundant but displayed a similar conductance (223 pS). However, its calcium sensitivity was more than 10 times lower than in HIT cells, similar to that of the K(Ca,V) channel in the neonatal rat cell, which also displays a reduced secretory response to glucose. Based on these observations, it is proposed that the low calcium sensitivity of the K(Ca,V) channel may be causally associated with secretory deficiency in RIN cells and the immature secretory response of the neonatal cell.     

Measurement of calcium fluxes in plants using 45Ca

This paper deals with the effect of calcium binding in the cell wall on the measured ⁴⁵Ca influx in Chara corallina Klein ex Will. esk. R.D. Wood. Calcium in the cell wall was in the range 687–1197 (mol · m^–2 compared to the sap which contained only 144–256 mol · m^–2. In dilute culture solutions the calcium content of the cell wall was relatively independent of external calcium at concentrations above about 0.1 mol · m^–3. The half-times for exchange of calcium from ⁴⁵Ca-labelled cell walls varied from 45 min at 0.05 mol · m^–3 to less than 2 min at 2 mol · m^–3. The effectiveness of other cations in displacing calcium from cell walls was in the order La > Zn > Co > Ni > Mg. Rinsing of ⁴⁵Ca-labelled cell walls in 2 mol · m^–3 LaCl₃ for 20 min removed more than 99% of the bound ⁴⁵Ca. However, the residual ⁴⁵Ca activity in isolated cell walls following La³⁺ rinsing was similar to that in whole cells. It is concluded that in whole cells ⁴⁵Ca influx cannot normally be distinguished from extracellular binding of calcium. Methods are described for the measurement of ⁴⁵Ca fluxes in charophyte cells by isolation of intracellular ⁴⁵Ca after the uptake period using techniques which avoid contamination from the large amount of tracer bound in the cell wall. At an external calcium concentration of 1 mol · m^–3, the plasmalemma influx was approx. 0.2 nmol · m^–2 · s^–1 of which about half entered the vacuole and half was effluxed back into the external solution. The cytoplasm filled with calcium with a half-time of 40–50 min with an apparent pool size of 50 mmol · m^–3. After 2 h the net flux to the cell was almost the same as the vacuolar flux. The fluxes reported are an order of magnitude lower than previously reported calcium fluxes in plants.Abbreviations APW artificial pond water This work was supported by the Australian Research Council. The authors wish to thank Patrick Kee for his skilful technical assistance and Professor E.A.C. MacRobbie, University of Cambridge, UK, and Dr. M. Tester for helpful discussions.     

The characterization of a monovalent cation-selective channel of mammalian cardiac muscle sarcoplasmic reticulum

Summary Rabbit cardiac muscle sarcoplasmic reticulum (SR) was isolated and separated into ryanodine-sensitive and-insensitive fractions (L.R. Jones and S.E. Cala,J. Biol. Chem. 256:11809–11818, 1981). Vesicles of cardiac SR were incorporated into planar phospholipid bilayers by fusion and the channel activity of the membrane studied under voltage-clamp conditions (C. Miller,J. Membrane Biol. 40: 1–23, 1978). Both fractions contain a monovalent cation-selective three-state channel. In the presence of 75mm K₂SO₄, the fully open state () conductance of this channel is 157.2±30 pS and the sub-state () conductance is 100.7±21 pS. Both open states display the same selectivity sequence for monovalent cations, i.e. K⁺>NH ₄ ⁺ >Rb⁺>Na⁺>Li⁺ and may be blocked by the skeletal muscle relaxants decamethonium and hexamethonium. Block occurs when the compounds are added to either side of the membrane. The properties of the cardiac SR cation channel are compared with those of the previously reported monovalent cation-selective channels of mammalian and amphibian skeletal muscle SR.     

Characterization of a chloride channel reconstituted from cardiac sarcoplasmic reticulum

We have characterized a voltage-sensitive chloride channel from cardiac sarcoplasmic reticulum (SR) following reconstitution of porcine heart SR into planar lipid bilayers. In 250 mm KCl, the channel had a main conductance level of 130 pS and exhibited two substrates of 61 and 154 pS. The channel was very selective for Cl^– over K⁺ or Na⁺ ( and ). It was permeable to several anions and displayed the following sequence of anion permeability: SCN^– > I^– > NO ₃ ^– Br^– > Cl^– > f^– > HCOO^–. Single-channel conductance saturated with increasing Cl^– concentrations (K _m= 900 mm and _max = 488 pS). Channel activity was voltage dependent, with an open probability ranging from 1.0 around 0 mV to 0.5 at +80 mV. From –20 to +80 mV, channel gating was time-independent. However, at voltages below –40 mV the channel entered a long-lasting closed state. Mean open times varied with voltage, from 340 msec at –20 mV to 6 msec at +80 mV, whereas closed times were unaffected. The channel was not Ca²⁺-dependent. Channel activity was blocked by disulfonic stilbenes, arylaminobenzoates, zinc, and cadmium. Single-channel conductance was sensitive to trans pH, ranging from 190 pS at pH 5.5 to 60 pS at pH 9.0. These characteristics are different from those previously described for Cl^– channels from skeletal or cardiac muscle SR.We thank Dr. Barry Pallotta for help with open and closed intervals analysis and Dr. Gerhard Meissner for his suggestions for the preparation of cardiac sarcoplasmic reticulum membranes. This work was supported by a grant from the National Institutes of Health to R.L.R. and a Student Grant-in-Aid from the American Heart Association, North Carolina affiliate to C.T. R.L.R. is an Established Investigator of the American Heart Association.     

Single Cl− channels in molluscan neurones: Multiplicity of the conductance states

Summary Properties of the single Cl^– channels were studied in excised patches of surface membrane from molluscan neurones using single-channel recording technique. These channels are controlled by Ca²⁺ and K⁺ acting on cytoplasmic and outer membrane surfaces, respectively, and by the membrane potential. The channels display about 16 intermediate conductance sublevels, each of them being multiples of 12.5 pS. The upper level of the channel conductance is about 200 pS. The channel behavior is consistent with an aggregation of channel-forming subunits into a cluster.     

<Superscript>65</Superscript>Zn<Superscript>2+</Superscript> transport by lobster hepato-pancreatic baso-lateral membrane vesicles

The lobster (Homarus americanus) hepato-pancreatic epithelial baso-lateral cell membrane possesses three transport proteins that transfer calcium between the cytoplasm and hemolymph: an ATP-dependent calcium ATPase, a sodium-calcium exchanger, and a verapamil-sensitive cation channel. We used standard centrifugation methods to prepare purified hepato-pancreatic baso-lateral membrane vesicles and a rapid filtration procedure to investigate whether ⁶⁵Zn²⁺ transfer across this epithelial cell border occurs by any of these previously described transporters for calcium. Baso-lateral membrane vesicles were osmotically reactive and exhibited a time course of uptake that was linear for 10–15 s and approached equilibrium by 120 s. In the absence of sodium, ⁶⁵Zn²⁺ influx was a hyperbolic function of external zinc concentration and followed the Michaelis-Menten equation for carrier transport. This carrier transport was stimulated by the addition of 150 M ATP (increase in K_m and J_max) and inhibited by the simultaneous presence of 150 mol l^–1 ATP+250 mol l^–1 vanadate (decrease in both K_m and J_max). In the absence of ATP, ⁶⁵Zn²⁺ influx was a sigmoidal function of preloaded vesicular sodium concentration (0, 5, 10, 20, 30, 45, and 75 mmol l^–1) and exhibited a Hill Coefficient of 4.03±1.14, consistent with the exchange of 3 Na⁺/1Zn²⁺. Using Dixon analysis, calcium was shown to be a competitive inhibitor of baso-lateral membrane vesicle ⁶⁵Zn²⁺ influx by both the ATP-dependent (K_i=205 nmol l^–1 Ca²⁺) and sodium-dependent (K_i=2.47 mol l^–1 Ca²⁺) transport processes. These results suggest that zinc transport across the lobster hepato-pancreatic baso-lateral membrane largely occurred by the ATP-dependent calcium ATPase and sodium-calcium exchanger carrier proteins.Communicated by: I.D. Hume     

Plasma membrane Ca2+ channels in roots of higher plants and their role in aluminium toxicity

Single Ca²⁺ channel records were obtained from plasma membrane-enriched fractions of wheat roots incorporated into artificial planar lipid bilayers. The channel had a unitary conductance of 15 pS for a 10 to 95 mM CaCl₂ gradient (cytoplasm: outside of the cell). The voltage dependence displayed by the channel agreed with that expected for Ca²⁺ channels in the plasma membrane. The channel gating was strongly modified by addition of 20 M extracellular verapamil (a Ca²⁺ channel antagonist). Extracellular AlCl₃ (70 M, pH 4.9) almost completely blocked the channel.     

In vitro analysis of ion channels in periaxolemmal-myelin and white matter clathrin coated vesicles: Modulation by calcium and GTPγS

This study reports the analysis of K⁺ channel activity in bovine periaxolemmal-myelin and white matter-derived clathrin-coated vesicles. Channel activity was evaluated by the fusion of membrane vesicles with phospholipid bilayers formed across a patch-clamp pipette. In periaxolemmal myelin spontaneous K⁺ channels were observed with amplitudes of 25–30, 45–55, and 80–100 pS, all of which exhibited mean open-times of 1–2 msec. The open state probability of the 50 pS channel in periaxolemmal-myelin was increased by 6-methyldihydro-pyran-2-one. Periaxolemmal-myelin K⁺ channel activity was regulated by Ca²⁺. Little or no change in activity was observed when Ca²⁺ was added to thecis side of the bilayer. Addition of 10 M total Ca²⁺ also resulted in little change in K⁺ channel activity. However, at 80 M total Ca²⁺ all K⁺ channel activity was suppressed along with the activation of a 100 pS Cl^– channel. The K⁺ channel activity in periaxolemmal myelin was also regulated through a G-protein. Addition of GTPS to thetrans side of the bilayer resulted in a restriction of activity to the 45–50 pS channel which was present at all holding potentials. Endocytic coated vesicles, form in part through G-protein mediated events; white matter coated vesicles were analyzed for G proteins and for K⁺ channel activity. These vesicles, which previous studies had shown are derived from periaxolemmal domains, were found to be enriched in the subunits of G₀, G_s, and G_i and the low molecular weight G protein,ras. As with periaxolemmal-myelin treated with GTPS, the vesicle membrane exhibited only the 50 pS channel. The channel was active at all holding potentials and had open times of 1–6 msec. Addition of GTPS to the bilayer fused with vesicle membrane appeared to suppress this channel activity at low voltages yet induced a hyperactive state at holding potentials of 45 mV or greater. The vesicle 50 pS K⁺ channel was also activated by the 6-methyl-dihydropyron-2-one (20 M).Abbreviations CNPase 2–3 cyclic nucleotide phosphohydrolase - EDTA ethylenediamine N,N,N,N-tetraacetic acid - G-protein GTP(guanosine triphosphate) binding protein - GTPS guanosine 5-O-(3-thiotriphosphate) - MAG myelin associated glycoprotein - Na⁺ K⁺ ATPase, Na⁺ and K⁺ stimulated adenosine triphosphatase - PLP myelin proteolipid protein Special issue dedicated to Dr. Majorie B. Lees.     

The influence of membrane potential on chloride channels activated by GABA in rat cultured hippocampal neurons

Chloride currents were activated by a low concentration of GABA (0.5 m) in neonatal rat hippocampal neurons cultured for up to 14 days. Currents elicited by 0.5 m GABA in neurons, voltage-clamped using the whole-cell technique with pipettes containing 149 mm Cl^–, reversed close to 0 mV whether pipettes contained 144 mm Na⁺ or 140 mm Cs⁺, and were blocked by 100 m bicuculline. Current-voltage curves showed outward rectification. Single channel currents appeared in cell-attached patches when the pipette tip was perfused with pipette solution containing 0.5 m GABA and disappeared when a solution containing 100 m bicuculline plus 0.5 m GABA was injected into the pipette tip. The channels showed outward rectification and, in some patches, had a much lower probability of opening at hyperpolarized potentials. The average chord conductance in 10 patches hyperpolarized by 80 mV was 7.8±1.6 pS (sem) compared with a chord conductance of 34.1±3.5 pS (sem) in the same patches depolarized by 80 mV. Similar single channel currents were also activated in cell-free, inside-out patches in symmetrical chloride solutions when 0.5 m GABA was injected into the pipette tip. The channels showed outward rectification similar to that seen in cell-attached patches, and some channels had a lower probability of opening at hyperpolarized potentials. The average chord conductance in 13 patches hyperpolarized by 80 mV was 11.8±2.3 pS (sem) compared with 42.1±3.1 pS (sem) in the same patches depolarized by 80 mV.We are grateful to B. McLachlan and M. Robertson for their general assistance, to C. McCulloch and M. Smith for writing computer programs and to W. O'Hare for making the pipette injection device.     

Characterization of ion channels in the plasma membrane of epidermal cells of expanding pea (Pisum sativum arg) leaves

Ion channels in isolated patches of the plasma membrane of pea (Pisum sativum arg) epidermal cells were studied with the patch-clamp technique. One anion and one cation channel were dominantly present in most trials. The anion channel conducts nitrate, halides and malate, with a conductance in symmetrical 100 mm Cl^– of 300 pS and can be blocked by SITS when applied to the cytoplasmic side of the membrane. The cation channel poorly discriminates between potassium, sodium and lithium, is not blocked by either TEA or Ba²⁺, and has a conductance of 35 pS in symmetrical 100 mm K⁺. The open probability of the cation channel increases with increase of the Ca²⁺ concentration on the cytoplasmic side of the membrane from 0.1 to 1 m. The possible role of these two channels in the physiology of epidermal cells is discussed.This work was supported by NSF grant DCB-890 3744 to E.V.     

A nonselective cation channel activated by membrane deformation in oocytes of the ascidianBoltenia villosa

Summary Cell-attached patch clamp recordings from unfertilized oocytes of the ascidianBoltenia villosa reveal an ion channel which is activated by mechanical deformation of the membrane. These channels are seen when suction is applied to the patch pipette, but not in the absence of suction or during voltage steps. The estimated density of these stretch-activated channels is about 1.5/m², a figure equal to or greater than the density of known voltage-dependent channels in the oocyte. Ion substitution experiments done with combined whole-cell and attached patch recording, so absolute potentials are known, indicate that the channel passes Na⁺, Ca²⁺ and K⁺, but not Cl^–. The channel has at least two open and two closed states, with the rate constant that leaves the longer-lived closed state being the primary site of stretch sensitivity. External Ca²⁺ concentration affects channel kinetics: at low calcium levels, long openings predominate, whereas at high calcium virtually all openings are to the short-lived open state. In multiple channel patches, the response to a step change in suction is highly phasic, with channel open probability decreasing over several hundred milliseconds to a nonzero steady-state level after an initial rapid increase. This channel may play a role in the physiological response of cells of the early embryo to the membrane strains associated with morphogenetic events.     

Properties of the ATP-sensitive K+ current activated by levcromakalim in isolated pulmonary arterial myocytes

Tension and patch clamp recording techniques were used to investigate the relaxation of rabbit pulmonary artery and the properties of the K⁺ current activated by levcromakalim in isolated myocytes. Under whole-cell voltage clamp, holding at –60 mV in symmetrical 139 mm K⁺, levcromakalim (10 m) induced a noisy inward current of –116 ± 19 pA (n = 13) which developed over 1 to 2 min. This current could be blocked by either glibenclamide (10 m) or phencyclidine (5–50 M) and was unaffected when extracellular Ca²⁺ was removed. Both these drugs inhibited the levcromakalim-induced relaxation of muscle strips precontracted with 20 mm [K⁺] _o . Application of voltage ramps in symmetrical 139 mm K⁺ confirmed that the levcromakalim-induced current was carried by K⁺ ions and was weakly voltage dependent over the potential range from –100 to +40 mV.The unitary current amplitude and density of the channels underlying the levcromakalim-activated whole-cell K⁺ current was estimated from the noise in the current record. We estimate that levcromakalim caused activation of around 300 channels per cell, with a single channel current of 1.1 pA, corresponding to a slope conductance of about 19 pS. Furthermore, cells dialyzed with an ATP-free pipette solution developed a large noisy inward current at –60 mV, which could subsequently be blocked by flash photolysis of caged ATP. Analysis of the noise associated with this current indicated that the single channel amplitude underlying the ATP-blocked current was 1.4 pA, a value similar to that estimated for the levcromakalim-induced current. We conclude that the conductance of this ATP-sensitive channel is likely to be small under physiological conditions and that it is present at low density.We thank SmithKline & Beecham for the gift of levcromakalim, ICI Pharmaceuticals for the gift of charybdotoxin and Prof. D. Colquhoun for the noise analysis programs. We also thank Mr. R. Davey for technical assistance with tension experiments. This work was supported by the British Heart Foundation and the Wellcome Trust. L.H.C. is a Wellcome Research Fellow and P.L. is an intermediate fellow of the BHF.     

Analysis of the T-type calcium channel in embryonic chick ventricular myocytes

Summary T-type calcium channels (I _T channels) were studied in cell-attached patch electrode recordings from the ventricular cell membrane of 14-day embryonic chick heart. All experiments were performed in the absence of Ca²⁺ with Na⁺ (120mm) as the charge carrier.I _T channels were distinguished from L-type calcium channels (I _L) by their more negative activation and inactivation potential ranges; their smaller unitary slope conductance (26 pS), and their insensitivity to isoproterenol or D600. Inactivation kinetics were voltage dependent. The time constant of inactivation was 37 msec when the membrane potential was depolarized 40 mV from rest (R+40 mV), and 20 msec atR+60 mV. The frequency histogram of channel open times ₀ was fit by a single-exponential curve while that of closed times _c was biexponeintial. _o was the same atR+40 mV andR+60 mV whereas _c was shortened atR+60 mV. The open-state probability (P _o) increased with depolarization: 0.35 atR+40 mV, 0.8 atR+60 mV and 0.88 atR+80 mV. This increase inP _o at depolarized potentials could be accounted for by the decrease in _c.     

Parameters not influenced by vesamicol: Membrane potential,calcium uptake,and internal calcium concentration of synaptosomes

In our previous study vesamicol, an inhibitor of the acetylcholine transporter of the cholinergic vesicles, inhibited veratridine-evoked external Ca²⁺-dependent acetylcholine release from striatal slices but did not influence acetylcholine release observed in Ca²⁺-free medium (4). Here we examined if the effect of veratridine on membrane potential, Ca²⁺ uptake, and intracellular Ca²⁺ concentration of synaptosomes was altered by vesamicol in parallel with the inhibition of acetylcholine release. The depolarizing effect of 10 M veratridine (from 67±2.3 mV resting membrane potential to 50.7±2.5 mV) was not significantly influenced by vesamicol (1–20 M). Vesamicol (1–20 M) had no effect on either the overall curve of the veratridine-evoked⁴⁵Ca²⁺ uptake or the amount of Ca²⁺ taken up by synaptosomes. Veratridine caused a rise in intrasynaptosomal Ca²⁺ concentration as measured by Fura2 fluorescence, and the same increase both in characteristics and in magnitude was observed in the presence of vesamicol (20 M). The K⁺-evoked (40 mM) increase of Ca²⁺ uptake and of intracellular calcium concentration were also unaltered by vesamicol. In high concentration (50 M) vesamicol inhibited both the fall in membrane potential and the elevated Ca²⁺ uptake by veratridine, indicating a possible nonspecific effect on potential-dependent Na⁺ channels at this concentration. Vesamicol, in lower concentration (20 M) when neither of the above parameters was changed, completely prevented veratridine-evoked increase of [¹⁴C]acetylcholine release. This was observed only when vesamicol was present in the media throughout the experiment after loading the preparation with [¹⁴C]choline. The results suggest that vesamicol does not interfere with veratridine-induced changes in isolated nerve terminals other than with the release of acetylcholine, thus further supporting the involvement of a vesamicol-sensitive vesicular transmitter pool in Ca²⁺-dependent veratridine-elicited acetylcholine release.     

Ion channels activated by swelling of Madin Darby Canine Kidney (MDCK) cells

Summary According to previous studies hyposmotic swelling of Madin Darby Canine Kidney (MDCK) cells leads to a marked decrease of cell membrane resistance. The present study has been performed to identify the underlying ion channels using the patchclamp technique: reduction of extracellular osmolarity to 230 mmol/liter leads to a transient activation of K⁺ channels and a sustained activation of anion channels. The K⁺ channels are inwardly rectifying with a single-channel slope conductance of 56 ± 3 pS at –50 mV (cell negative) and of 29 ± 2 pS at 0 mV PD across the patch 150 mmol/liter K⁺ in pipette). The same channels are activated by an increase of intracellular calcium activity, as shown previously. The anion channels display a single-channel slope conductance of 41 ± 4 pS at –50 mV (cell negative) and of 25 ± 3 pS at 0 mV PD across the patch (150 mmol/liter Cl^– in pipette). The channel is anion selective and conducts both bicarbonate and chloride with a preference for bicarbonate. Its open probability is not affected by changing intracellular calcium from 0.1–10 mol/liter. The channels observed explain the effects of cell swelling on PD, ion selectivity and resistance of the cell membrane in MDCK cells.The authors gratefully acknowledge the valuable discussion with Drs. P. Deetjen, E. Wöll and F. Friedrich, the skilled technical assistance of G. Siber and S. David, and the excellent mechanic and electronic support by K.-H. Streicher, Ing. M. Hirsch and M. Plank. This study was supported by the Fonds zur Förderung der wissenschaftlichen Forschung, Grant No. P5813 and P6792M.