Characterization of a newly found stretch-activated KCa,ATP channel in cultured chick ventricular myocytes

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Characterization of a newly found stretch-activated K_Ca,ATP channel in cultured chick ventricular myocytes

Takashi Kawakubo¹, Keiji Naruse², Tatsuaki Matsubara¹, Nigishi Hotta¹, and Masahiro Sokabe²

Departments of ¹ Internal Medicine III and ² Physiology II, Nagoya University School of Medicine, Nagoya 466-8550, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

With the use of the patch-clamp technique, five kinds of stretch-activated (SA) ion channels were identified on the basisof their single-channel conductances and ion selectivities incultured chick ventricular myocytes. Because a high-conductanceK⁺-selective channel predominated among these channels, we concentratedon characterizing its properties mostly using excised inside-outpatches. With 145 mM KCl solution in the pipette and the bath,the channel had a conductance of 199.8 ± 8.2 pS (n = 22). Theion selectivities among K⁺, Na⁺, Ca²⁺, and Cl as estimated from their permeability ratios were P_Na/P_K = 0.03,P_Ca/P_K = 0.025, and P_Cl/P_K = 0.026. The probability of the channelbeing open (P_o) increased with the Ca²⁺ concentration in the bath ([Ca²⁺]_b; dissociation constant K_d = 0.51 µM at +30 mV) and membranepotential (voltage at half-maximal P_o = 39.4 mV at 0.35 µM [Ca²⁺]_b). The channel was blocked by gadolinium, tetraethylammonium,and charybdotoxin from the extracellular surface and, consequently,was identified as a Ca²⁺-activated K⁺ (K_Ca) channel type. The channel was also reversibly activatedby ATP applied to the intracellular surface (K_d = 0.74 mM at 0.10µM [Ca²⁺]_b at +30 mV). From these data taken together, we concluded thatthe channel is a new type of K_Ca channel that could be designatedas an "SA K_Ca,ATP channel." To our knowledge, this is the firstreport of K_Ca channel in heartcells.

patch clamp; stretch-activated channel; calcium-activated potassium channel; adenosine 5'-triphosphate-activated channel

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

IT HAS BEEN DEMONSTRATED that several types of Ca²⁺-activated K⁺ (K_Ca) channels are present in various muscular and nonmuscularpreparations (16, 25). Among these channels, a large-conductancetype (big K_Ca channel) similar to that first reported by Marty(16) is the most popular and extensively studied type. Big K_Cachannels from a variety of tissues share common properties ofconductance, ion selectivity, voltage dependency, and Ca²⁺ dependency (4, 16, 25). Because of their abundance andlarge conductance, K_Ca channels are supposed to participate inrepolarizing the membrane potential after depolarization. Recently,it has been suggested that K_Ca channels in smooth muscle may serveas a negative-feedback pathway by responding to fluctuations inmembrane potential and intracellular Ca²⁺ concentration, and in this way they may serve to regulate thelevel of vascular tone (5).

Recently, special types of K_Ca channels that are activated by some factors in addition to membrane potential and intracellularCa²⁺ concentration have been reported. Robertson et al. (22) showedthat a K_Ca channel in pulmonary arterial smooth muscle cells isolatedfrom rats can be activated by Mg²⁺-ATP, and therefore they called it a K_Ca,ATP channel. The existenceof K_Ca channels modulated by membrane stretch has also been reportedin the apical membrane of cultured medullary thick ascending limbcells (28), in the apical membrane of rat and rabbit corticalcollecting tubules (21), in G292 osteoblastic-like cells (7),and in embryonic rat neuroepithelial cells (17). Curiously enough,there has been no report of the K_Ca channel in cardiac myocytedespite such a ubiquitous distribution of K_Ca channels in a varietyof celltypes.

In the past decade, a new type of ion channel called stretch-activated (SA) channel, which is supposed to be activated bymembrane tension (26), has emerged. SA channels are also carriedby a variety of cell types (18). In cardiac myocytes some typesof K⁺ channels have been reported to be stretch activated (23, 29).It is believed that this type of channel would be activated whencells are mechanically deformed. This aspect of SA channels isparticularly intriguing in heart cells because these cells arealways subjected to periodic stretch and sometimes receive mechanicaloverload that induces arrhythmias orhypertrophy.

Originally, we started our study to further characterize the SA channels in heart cells using a preparation similar to thatused by Ruknudin et al. (23). We were able to identify fivedifferent types of SA channels with conductances ranging from25 to 200 pS. Because the channel with the largest conductance(200 pS) was most frequently observed, virtually in most patches,we decided to characterize this channel and found that it is abig K_Ca channel. In this report we present our detailed analysesof the biophysical and pharmacological properties of the newlyfound K_Ca channel in cultured chick heart cells. The channel turnedout to be modulated by both membrane stretch and intracellularATP, which is a completely new aspect in regard to the big K_Cachannels. Furthermore, this is the first report of the existenceof a big K_Ca channel in heartcells.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Cell culture. Ventricles were dissected from 10- to 12-day-old White Leghorn embryos under sterile conditions. Cell suspensions were preparedby exposing the ventricles to nominally Ca²⁺-Mg²⁺-free saline containing 2 mg/ml collagenase (Sigma Chemical) for10 min at 37°C. Cells were grown in Dulbecco's modified Eagle'smedium (GIBCO BRL) supplemented with heat-inactivated horse serum(10% vol/vol), chick embryo extract (2% vol/vol), penicillin,and streptomycin. The cultures were maintained in an atmosphereof 95% air-5% CO₂ at 37°C and 95% relative humidity. Cells from3 to 14 days of culture were used for experiments because thepatches from younger cells were more fragile, preventing us frommaking stablerecordings.

Single-channel recording and analysis. We used the patch-clamp technique for high-resolution detection of single-channel currents. Patch electrodes were fabricatedfrom 100- $lambda$ glass capillaries (Drummond Scientific) in two stageson a vertical electrode puller (PP-83, Narishige) and were heatpolished on a microforge (MF-83, Narishige). Tips of freshly pulledpipettes were filled by being placed in a 1-ml sample vial containinga filtered solution for 3-5 min, and then the shanks were backfilled.Pipettes were mounted on a micromanipulator and connected to theprobe of a patch-clamp amplifier (model 3900, Dagan Instruments).Mechanical stretch in the patch was made by applying negativepressure in the pipette with a pneumatic transducer tester (DPM-1B,BIO-Tek Instruments) connected to a pipette holder. Most recordingswere done with excised inside-out patches, although cell-attachedpatches were used in a limited case. All experiments were conductedat room temperature (23 ± 2°C). Currents were stored on VHS videotapesthrough a PCM recorder (VR-10B, Instrutech). The stored raw datawere replayed through a four-pole Bessel filter and analyzed usingsoftware (PAT vers. 6.02) written by Dr. John Dempster (Universityof Strathclyde, Glasgow, UK). Channel-opening events were detectedby using the 50% amplitude-threshold criterion from segments ofrecords of 10-200 s in length. Single-channel current amplitudewas measured from the peak-to-peak distance on the amplitude histogramor directly from chart records. The probability of the channelbeing open (P_o) was calculated from amplitude histograms as theratio of open peak area to total area. In patches containing Nnumber of channels with low P_o, in which there were very few overlappedopenings, P_o was determined from the equation (26) P_o (%) =(1 $-$ P^1/N_c) × 100, where P_c is theprobability of the channel not being open in the record. In mostkinetic analyses, i.e., determination of mean open and closedtimes, we used the data from the patches containing a single channel.In inside-out patches, membrane potential was defined as the negativevalue of the pipette potential. Upward current deflections inFigs. 1-5, 7, and 8 represent cation movement from the cytoplasmicside to the external side of the membrane and vice versa foranions.

Solutions. The standard external solution (in the pipette) facing the extracellular surface of the patch contained 145 mM KCl, 1 mM CaCl₂,10 mM HEPES, and 10 mM glucose adjusted to pH 7.40 with KOH. Theinternal solution (in the bath) facing the cytoplasmic surfaceof the patch was the same as that in the pipette except that theconcentration of CaCl₂ was below 1 mM. When the Ca²⁺ concentration was below 10 µM, it was adjusted with EGTA on thebasis of calculations made using the program EqCal (Biosoft) accordingto the stability constants from Owen (20). Most experimentswere done with excised inside-out patches and with these solutions,unless otherwisenoted.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

SA channels in cultured myocytes. Figure 1 shows typical examples of five different types of SA single-channel currents recorded from separate inside-out patches.As shown, negative pressures in the pipette caused P_o to increasewithout apparent adaptation in every case. We first categorizedthe channels on the basis of their conductances as determinedfrom current-voltage (I-V) relations under two different ionicconditions: 1) 145 mM KCl in the pipette and 145 mM KCl in thebath, or 2) 145 mM NaCl in the pipette and 145 mM KCl in the bath.With 145 mM KCl saline in the pipette and the bath, we identifiedfour types of SA channels with conductances of ~25 pS (Fig. 1,A and B), 50 pS (Fig. 1C), 100 pS (Fig. 1D), and 200 pS (Fig.1E). The 25-pS type was further separated into two subtypes, aK⁺-selective channel (Fig. 1B), with a permeability ratio of Na⁺ to K⁺ (P_Na/P_K) of 0.10, and a nonselective cation channel (Fig. 1A),with a P_Na/P_K of 1.0. The 50-, 100-, and 200-pS channels wereK⁺ selective (P_Na/P_K = 0.08, 0.05, and 0.03, respectively). Theseresults are roughly in line with the earlier report of Ruknudinet al. (23). Because the activity of the 200-pS channel predominatedin most patches observed, we focused on this type and characterizedits biophysical and pharmacological properties. Interestingly,as shown by the following results, this channel was voltage dependentand strongly activated by Ca²⁺ from the cytoplasmic side of the membrane, which suggests thatit is a big K_Ca channel.

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Fig. 1. Typical records of single-channel currents of 5 different types of stretch-activated (SA) channels. Identification of SA channels was made through pressure sensitivity of channels. A: 25-pS SA channel (nonselective) at $-$ 80 mV. -C, closed level of channel. B: 25-pS SA channel (K⁺ selective) at +120 mV. C: 50-pS SA channel (K⁺ selective) at +80 mV. D: 100-pS SA channel (K⁺ selective) at +40 mV. E: 200-pS SA channel (K⁺ selective) at +30 mV. All traces were obtained from excised inside-out patches with symmetrical 145 mM KCl solutions except for trace in A, where pipette contained 145 mM NaCl and bath contained 145 mM KCl. Arrows at baselines indicate application time of suction.

Channel density of 200-pS channel. Channel frequencies in 100 patches were 4 channels for nonselective 25-pS type, 22 channels for K⁺-selective 25-pS type, 21 channels for 50-pS type, 39 channelsfor 100-pS type, and 245 channels for 200-pS type. The frequenciesfor 25-pS (nonselective), 25-pS (K⁺ selective), 50-pS, and 100-pS channel types were somewhat similarto those reported by Ruknudin et al. (23); however, our frequencyfor 200-pS channel was much higher than that reported by Ruknudinet al. The reason for this difference may be that they used cell-attachedpatches with intracellular surfaces exposed to a lower Ca²⁺ concentration than that (0.35-1.0 µM) used for our inside-outpatches. The estimated intracellular Ca²⁺ concentration in our preparation was 0.1-0.35 µM (see Fig. 7D).The membrane area of the patch could be estimated to be 2-5 µm², based on the geometric measurements obtained using high-powervideomicroscopy (26). Therefore, the channel densities of the200-pS channel seemed to be in the range of 0.5-1.2 channels/µm².

Ion selectivity. The ion selectivity of the 200-pS channel was estimated from I-V curves for inside-out patches by exposing the cytoplasmicsurface of the membrane to 145 mM KCl, 72.5 mM KCl, 145 mM NaCl,or 72.5 mM CaCl₂ solutions. Figure 2A shows single-channel activitiesof a 200-pS channel in an excised inside-out patch at the indicatedmembrane potentials. Figure 2B shows I-V relationships under thesevarious ionic conditions. With symmetrical 145 mM KCl solutions(n = 22), a nearly linear I-V relationship with a reversal potentialnear zero and a mean slope conductance of 199.8 pS was obtained.In inside-out patches with 145 mM NaCl in the bath (n = 8), therewas a positive shift in the reversal potential and the I-V curvebecame sublinear and was well fitted by the Goldman-Hodgkin-Katzcurrent equation (Fig. 2B). The permeability ratio P_Na/P_K wascalculated using the equation P_Na/P_K = ([K⁺]_o/[Na⁺]_i) exp( $-$ E_revF/RT), where E_rev is the reversal potential, F isFaraday's constant, R is the gas constant, T is absolute temperature(°K), [Na⁺]_i is the bath (cytoplasmic surface) concentration of Na⁺, and [K⁺]_o is the pipette (extracellular surface) concentration of K⁺. The calculated P_Na/P_K was 0.033 (n = 6), a value consistentwith those for K_Ca,ATP channels from other preparations.

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Fig. 2. Voltage-dependent behavior of single-channel currents of 200-pS K⁺ channel. A: single-channel activities in an inside-out patch in symmetrical 145 mM KCl solutions at indicated membrane potentials. B: current-voltage (I-V) relationships for 200-pS SA channels from inside-out patches with symmetrical 145 mM KCl (

), 145 mM KCl in pipette and 145 mM NaCl in bath (

), 145 mM KCl in pipette and 72.5 mM KCl in bath (

), and 72.5 mM CaCl₂ in pipette and 145 mM KCl in bath ( $open circle$ ). Data points represent averages from 8, 7, 6, and 5 patches, respectively. Curves are drawn according to Goldman-Hodgkin-Katz current equation. V, membrane potential.

Similarly, P_Ca/P_K was calculated using the equation P_Ca/P_K = [K⁺]_i exp( $-$ E_revF/RT)[1 + exp( $-$ E_revF/RT)]/4[Ca²⁺]_o, where [K⁺]_i is the bath concentration of K⁺ and [Ca²⁺]_o is the pipette concentration of Ca²⁺. With 72.5 mM CaCl₂ in the pipette and 145 mM KCl in the bath,P_Ca/P_K was 0.025 (n = 7). P_Cl/P_K was calculated as 0.026 fromthe measurement of the reversal potential with 72.5 mM KCl inthe bath and 145 mM KCl in the pipette (n = 7). This value iscomparable to that of a K_Ca channel from rat brain synaptosomalmembranes as reported by Nomura et al. (19).

Effects of K⁺-channel blockers. In general there are two types of channel blockers, fast and slow blockers. Fast blockers induce a graded decrease of thesingle-channel currents, whereas slow blockers make "all-or-none"types of gaps in the open-channel currents, which sometimes arehard to discriminate from channel closing. To avoid this difficulty,we used a high Ca²⁺ concentration (1 mM) in the bath to keep the channel open formost of the time over a wide potential range. First, we testedthe effect of charybdotoxin (CTX), a specific blocker for bigK_Ca channels (2), on the 200-pS channel using the backfillprocedure (3), in which 145 mM KCl solution containing 20 nMCTX was backfilled. Figure 3A shows time-dependent changes inthe channel activities at +30 mV, which reflect gradual diffusionof the drug to the patch membrane. The P_o of the 200-pS channelwas significantly decreased 5 min after the start of the backfilland almost completely disappeared after an additional 15 min.

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Fig. 3. Pharmacological properties of 200-pS SA channel. A: blockade of a 200-pS SA channel by charybdotoxin (CTX). Blockade occurred without significant reduction in current amplitude. Traces were obtained at indicated times after start of backfilling of pipette. Pipette tip was first filled with 145 mM KCl and then backfilled with same solution containing 20 nM CTX; bath contained 145 mM KCl and 1 mM CaCl₂. Membrane potential was held at +30 mV under a suction of $-$ 10 mmHg in pipette. B: blockade of a 200-pS SA channel by 20 µM gadolinium (Gd) using backfill procedure. Method and conditions were same as in A. Blockade occurred without significant reduction in current amplitude. C: time courses of open probability (P_o) of control group (n =16), CTX group (n =9), and Gd group (n =10). Time was measured from start of backfill of solutions. Membrane potentials were held at +30 mV in all groups. D: blockade of a 200-pS SA channel by 1 mM tetraethylammonium (TEA). TEA reduced current amplitude in a dose-dependent manner. Conditions were same as in A except that pipette was backfilled with 145 mM KCl containing 1 mM TEA.

The effect of 20 µM gadolinium (Gd³⁺), a potent blocker of SA channels, was also examined using the same method. As shown inFig. 3B, a slow blockade of the 200-pS channel became visibleat 5 min, and complete blockade was apparent 15 min after thebackfill. Although the kinetics of this Gd³⁺ blockade were not systematically investigated in the presentstudy, its qualitative features seemed to be similar to the Gd³⁺ blockade of the endogenous SA cation channels in Xenopus oocytes(31). Figure 3C shows time courses of P_o from the control, CTX,and Gd³⁺ groups. Using the backfill procedure, we tested the effect ofextracellular Mg²⁺ (3 mM) and found that the P_o of the channel was not changed (control68.3% vs. Mg²⁺ 66.1%, n = 3). We also tested the effect of intracellular Mg²⁺ and again observed no significant change in P_o (70.5% vs. 68.1%,n =3).

Fast blocking of the 200-pS channel by externally applied tetraethylammonium (TEA) using the backfill procedure is shown inFig. 3D. In contrast to the all-or-none type of blockade describedabove, TEA decreased the mean single-channel current in a dose-dependentmanner and increased the open-channel current noise of the 200-pSchannel. This type of "flickery block" is characteristic of ablocking process with relatively fast kinetics. The single-channelconductance was 151 pS with 0.1 mM TEA, 126 pS with 0.3 mM TEA,and 62 pS with 0.8 mM TEA backfilled in the pipette, thus yieldingan estimated dissociation constant (K_d) of ~0.4 mM. These dataare in accordance with the TEA-induced reduction of the single-channelconductance in a variety of big K_Ca channels (hereafter, we referto K_Ca channels byname).

Calcium and voltage dependencies. The effect of intracellular Ca²⁺ on the channel activity was studied by exposing the cytoplasmic side of the patch to a rangeof various Ca²⁺ concentrations ([Ca²⁺]_b). Figure 4A demonstrates Ca²⁺ activation of the 200-pS channel in an inside-out patch withvarious [Ca²⁺]_b at a membrane potential of +30 mV in a symmetrical 145 mM KClsolution. Although P_o was extremely low (0.1%) at 0.1 µM [Ca²⁺]_b, P_o increased with the increase in [Ca²⁺]_b. Ca²⁺ dependency of the open and closed times was estimated from thedwell-time histograms. The histograms of open-time distributionwere well fitted by single-exponential functions, whereas thoseof closed times were fitted by double-exponential functions (Fig.4B). Ca²⁺ dependency of P_o and the mean open and closed times are summarizedin Fig. 4C, in which the mean long closed time decreased and themean open time increased with the increase in [Ca²⁺]_b, whereas short closed time showed little change. This typeof [Ca²⁺]_b dependency, with a decrease in long closed time and an increasein open time with an increase in [Ca²⁺]_b, was also seen in other preparations (25).

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Fig. 4. Ca²⁺ dependency of 200-pS SA channel. A: single-channel current traces of 200-pS channel in an inside-out patch at various Ca²⁺ concentrations in bath ([Ca²⁺]_b). P_o of channel in an inside-out patch increased as [Ca²⁺]_b increased. Membrane potential was held at +30 mV. Pipette and bath contained 145 mM KCl. B: dwell-time histograms of open (OT), long closed (lCT), and short closed times (sCT) for patch in A at 0.35 µM [Ca²⁺]_b. OT histogram could be fitted by a single-exponential function, and lCT and sCT histograms could be fitted by a double-exponential function with time constants indicated. C: plot of P_o vs. [Ca²⁺]_b. Data (

) were taken from patch in A. Dotted line was drawn according to a Boltzmann-type function. [Ca²⁺]_b dependence of OT, lCT, and sCT are also indicated. In response to a change in [Ca²⁺]_b, lCT decreased from 514.24 ms at 0.1 µM [Ca²⁺]_b to 1.91 ms at 0.8 µM [Ca²⁺]_b, whereas OT increases from 2.12 to 11.83 ms.

Figure 5A shows representative recordings of the 200-pS channel currents at various membrane potentials in a symmetrical 145mM KCl solution with a 0.35 µM [Ca²⁺]_b. As the membrane potential was made more positive, the meanopen time of the channel became longer. In Fig. 5A, a few briefchannel openings are visible at $-$ 20 mV, whereas at higher voltagesP_o increases accordingly, and even second channel openings becomeapparent at +50 mV. An example of dwell-time histograms at $-$ 20and +50 mV are shown in Fig. 5B. The voltage dependence of P_ois demonstrated in Fig. 5C, in which the data points are wellfitted by a Boltzmann function of the form

<IT>P</IT><SUB>o</SUB> = 1/{1 + exp[−<IT>K</IT> (<IT>V</IT> − <IT>V</IT><SUB>0</SUB>)]}

(1)

where V is a given membrane potential, V₀ is the voltage at half-maximal P_o, and K is the logarithmic potential sensitivityindicating an e-fold increase in membrane potential. For thisparticular data set, V₀ was 39.2 mV and K¹ was 14.7. Figure 5C shows the voltage dependence of the meanopen and closed times, where the mean open time increases andthe mean long closed time decreases with voltage, whereas themean short closed time remains unchanged. A similar tendency wasreported in other preparations (6, 7, 25).

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Fig. 5. Voltage dependency of 200-pS SA channel. A: single-channel current traces in an inside-out patch at indicated membrane potentials. Pipette and bath contained 145 mM KCl and 0.35 µM [Ca²⁺]_b. B: dwell-time histograms of OT and lCT at 2 different membrane potentials for patch in A. OT histograms were fitted by a single-exponential function, and lCT histograms were fitted by a double-exponential function, with time constants indicated. Dotted lines drawn in lCT histograms were fitted to time region longer than 2 ms. C: plot of P_o vs. membrane potential. Data (

) were taken from patch in A. Dotted line was drawn according to Boltzmann function: P_o = 1/{1 + exp[ $-$ K(V $-$ V₀)]}, with V₀ = 39.2 mV and K¹ = 14.7, where V is a given membrane potential, V₀ is voltage at half-maximal P_o, and K is logarithmic potential sensitivity. Voltage dependence of mean OT, mean lCT, and mean sCT are also indicated. As membrane potential increases, lCT decreases from 133.52 ms at $-$ 20 mV to 35.66 ms at +30 mV and then decreases further to 10.89 ms at +50 mV, whereas OT increases from 1.98 ms at $-$ 20 mV to 3.56 ms at +30 mV and 9.90 ms at +50 mV.

Figure 6 shows P_o as a function of membrane potential at various [Ca²⁺]_b from 45 separate inside-out patches. P_o increased with depolarizationat all [Ca²⁺]_b tested, and the data set for each [Ca²⁺]_b was reasonably fitted by Eq. 1. The value for K¹ was 18.07 ± 0.72 (n = 5).

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Fig. 6. Voltage dependence of P_o at different [Ca²⁺]_b. Dotted lines were drawn according to Boltzmann equation (see Eq. 1 in text). Data points represent means ± SE.

The theoretical activation curves in Fig. 6 give P_o values at membrane potentials of $-$ 20, $-$ 10, 0, +10, +20, and +30 mV withvarious Ca²⁺ concentrations, from which we could obtain Hill plots. Hill coefficientswere 4.34 ± 0.17 mV (n =6).

From the above results [i.e., high unitary conductance (200 pS) and sensitivity to Ca²⁺, voltage, TEA, and CTX], we concluded that the 200-pS SA channelwas a Ca²⁺-activated K⁺ channel (K_Cachannel).

Pressure dependency. We next investigated SA properties of the K_Ca channel. In both inside-out and cell-attached patches in cultured chick cardiaccells, the activity of the K_Ca channel was increased by the applicationof negative pressure in the patch pipette. Figure 7A shows typicalcurrent traces of responses to the pressure in the pipette. Typically,membrane stretch by negative pressure was applied in a stepwisefashion with a 10-mmHg increment, and the response of the channelactivity lagged behind the pressure change by only a few seconds.Positive pressure in the pipette also activated the K_Ca channelin a way similar to negative pressure within 20 mmHg. However,positive pressure as low as 20 mmHg frequently deteriorated orsometimes broke the seal in 10-15 s, preventing us from obtaininggood results.

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Fig. 7. Pressure dependence of Ca²⁺-activated K⁺ (K_Ca) channel. A: single-channel activity of K_Ca channel at different pressures. Negative pressures in pipette progressively increased channel activity. Values at left indicate pressure. Pipette contained 145 mM KCl and 1 mM CaCl₂, and bath contained 145 mM KCl and 0.35 µM CaCl₂. Membrane potential was held at +30 mV. B: dwell-time histograms of OT and lCT at 0 and 50 mmHg for patch in A. lCT decreased from 331.53 ms at 0 mmHg to 52.09 ms at 50 mmHg, whereas OT increased from 4.22 to 10.89 ms. C: plots of pressure dependency of P_o, mean OT, mean sCT, and mean lCT for patch in A. D: pressure dependency of P_o at 2 different [Ca²⁺]_b from inside-out patches, P_o with no Ca²⁺ on either side of membranes from inside-out patches, and P_o from cell-attached patches. Data points represent means ± SE calculated from 11 experiments with 0.1 µM [Ca²⁺]_b, 12 experiments with 0.35 µM [Ca²⁺]_b, 4 experiments with no Ca²⁺ on either side of membranes, and 8 experiments from cell-attached patches.

The effect of membrane stretch on the open-close kinetics was analyzed on the basis of open- and closed-time distributions.Dwell-time histograms of those times at 0 and 50 mmHg of negativepressure are shown in Fig. 7B. For this channel, a double-exponentialfunction was required to fit the closed-time distribution, anda single-exponential function was enough to fit the open-timedistribution, suggesting that there are at least two closed states(C1 and C2) and one open state (O1). Such a property is similarto the results reported in other types of SA channels (9, 12).With this particular patch, the mean long closed time decreasedand the mean open time increased with membrane stretch (Fig. 7C).The change in open time was much smaller than that in long closedtime, suggesting that suction in the pipette increased P_o primarilyby decreasing the mean long closed time of the channel. This isalso similar to the findings in the previously mentioned reports(9, 12). Five additional patches showed basically a similartendency. With the assumption of a simple linear kinetics model(C1 $left-right-arrow$ C2 $left-right-arrow$ O1), only the transition from C1 to C2 is stretchdependent.

We also examined the effect of membrane stretch on the K_Ca channel in cell-attached patches. Membrane stretch activated theK_Ca channels in a similar manner, although there was a high degreeof variability in their responses. Figure 7D summarizes the datafrom excised inside-out patches with 0.1 (n = 11) or 0.35 µM (n= 12) [Ca²⁺]_b, from excised inside-out patches with no Ca²⁺ in the pipette or bath (n = 4), and from cell-attached patches(n = 8). From these results, the intracellular Ca²⁺ concentration in our preparations could be estimated between0.1 and 0.35 µM, a reasonable range for the resting heart cell.In the apical membrane of cultured medullary thick ascending limbcells, the activation of K_Ca channels by membrane stretch wasreported to be attributed to some indirect processes, such asCa²⁺ influx mediated by SA cation channels or volume-induced Ca²⁺ releases from cytoplasmic stores (9, 28). However, we observedstretch-dependent channel activation with 0 mM CaCl₂ and 4 mMEGTA in the pipette and bath (Fig. 7D). To rule out the possibilityof Ca²⁺ crossing from the patch pipette into a nonstirred layer at thecytoplasmic surface of the membrane patch, we performed a setof cell-attached experiments with 0 mM CaCl₂ and 4 mM EGTA inthe patch and bath solutions. Under these conditions, we stillobserved an increase of P_o by negative pressure in the pipette(data notshown).

ATP dependency. Because Robertson et al. (22) have shown that K_Ca channels in pulmonary arterial smooth muscle cells isolated from ratscan be activated by Mg²⁺-ATP, we also tested the effect of ATP on our K_Ca channel in inside-outpatches. Aliquots of concentrated ATP solution were successivelyadded to the bath to give various final concentrations at thecytoplasmic side ([ATP]_b). Figure 8A shows typical current tracesdemonstrating progressive activation of the K_Ca channel by thisdose protocol. ATP dependency of P_o and the mean open and closedtimes are shown in Fig. 8B. P_o was extremely low without ATP butincreased steeply with an increase of ATP. The mean long closedtime decreased and the mean open time increased with an increaseof ATP. The changes in long closed time and open time are consistentwith the changes in P_o. Similar to the effect of membrane stretch,the primary effect of ATP on the gating kinetics seems to be areduction of the mean long closed time. The observed sensitivityto ATP suggested that the channel should be designated as a K_Ca,ATPchannel. Figure 8C shows ATP dependency of P_o from eight separatepatches. In the absence of Ca²⁺ in the pipette and bath, 1 mM ATP applied to the cytosolic surfaceof inside-out patches also increased the P_o of the K_Ca,ATP channelfrom 0.051 to 42.2%. Albarwani et al. (1) have reported thatthe K_Ca,_ATP channel in pulmonary arterial smooth muscle cellsfrom the rat was maximally activated with 1 mM Mg-ATP. The K_Ca,ATPchannel in this study required a little more ATP to be maximallyactivated. The Hill coefficient calculated from a range of 0.5to 1.75 mM [ATP]_b in this study was ~5.0, whereas that in thestudy of Albarwani et al. between 10 µM and 1 mM [ATP]_b was ~1.2.Our K_Ca,ATP channel is more sensitive to changes in [ATP]_b.

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Fig. 8. Effect of ATP on single-channel activity of K_Ca channel. A: records of K_Ca-channel openings at several concentrations of intracellular ATP. Pipette contained 145 mM KCl and 1 mM CaCl₂, and bath contained 145 mM KCl and 0.1 µM CaCl₂. Membrane potential was maintained at +30 mV. B: plot of P_o vs. ATP. Data (

) were taken from patch in A. Dotted line was drawn according to a Boltzmann-type function. ATP dependency of OT, lCT, and sCT are also indicated. C: ATP dependency of P_o. Data points represent means ± SE calculated from 8 inside-out patches. Dotted line represents a fit of data points to a Boltzmann-type function. K_Ca channels reached half-maximal P_o at a concentration of 0.78 mM. D: voltage dependence of P_o at different bath concentrations of ATP ([ATP]_b; in mM) from a single inside-out patch. At a given [ATP]_b, voltage causes a marked increase in P_o, as observed in effect of [Ca²⁺]_b on voltage dependency (see Fig. 6).

We also examined interaction between ATP and voltage (membrane potential) in the activation of the K_Ca,ATP channel. The resultsfrom a single K_Ca,ATP channel are shown in Fig. 8D. Increasesin [ATP]_b shift the curve to left, which is similar to the effectof [Ca²⁺]_b on P_o. Two other separate patches gave similarresults.

Effects of other nucleotides. We examined the effect of other nucleotides on the K_Ca,ATP channel in inside-out patches. Concentrated nucleotide solutionswere directly added to the bath, as was done with Ca²⁺ and ATP, and negative pressure ( $-$ 20 mmHg) was applied in thepipette. ADP and AMP activated the K_Ca,ATP channels but with lessereffects than ATP. Table 1 summarizes the effects of various agentson the K_Ca,ATP channel.

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Table 1. Effect of other chemicals on K_Ca,ATP channel

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In the present study, we have revealed the presence of five distinct types of SA channels in cultured chick ventricular myocytesby using the patch-clamp technique. Among them, a K⁺ channel with the largest conductance predominated and was identifiedas a K_Ca channel on the basis of several characteristics, includinghigh K⁺ selectivity, a large unitary conductance, voltage and Ca²⁺ dependencies, and sensitivities to TEA and CTX. The K_Ca channelsin this study were also activated by application of ATP to theintracellular surface of inside-out patches. The channel couldtherefore be identified as a stretch-, Ca²⁺-, and ATP-activated K⁺ (SA K_Ca,ATP)channel.

Calcium and voltage dependencies. The gating of the K_Ca channels in chick cardiac myocytes was sensitive to changes in [Ca²⁺]_b between 0.1 and 1.0 µM (Fig. 4). A K_Ca channel with a similarsensitivity to [Ca²⁺]_b (<0.1 µM) was reported in smooth muscle cells (25), whereaschannels with higher sensitivity (activation at <0.01 µM) in pituitarycells (30) and lower sensitivity (1-10 µM activation range)in cultured rat muscle cells (4) have been reported. The Hillcoefficient of our K_Ca channel in cardiac myocytes was between4.0 and 5.0. For other preparations the values have been determinedto be 2.87 in cultured rat skeletal muscle (4), 2.82 in ratpulmonary arterial smooth muscle cells (1), and 1.63 in ratbrain synaptosomal cells (19). Most of the values from mammalianskeletal muscle have been reported to be between 1.5 and 3.0.

A comparison of the voltage sensitivity of the present K_Ca channels with those in various preparations may be made by usingthe inverse slope of the plot of the natural logarithm of theratio [P_o/(1 $-$ P_o)] versus membrane potential. Our channel hadan inverse slope of 14.8-18.5 mV, a value determined over a rangeof membrane potential between $-$ 80 and +80 mV and [Ca²⁺]_b between 0.25 and 0.70 µM. For other preparations the valuesfor the inverse slope have been determined to be 9 mV in clonalanterior pituitary cells (30), 15-16 mV in cultured rat skeletalmuscle (4), 11.3 mV for smooth muscle cells of the guinea pigtaenia coli (11), and 15-20 mV for canine colonic myocytes (6).Thus the inverse slope of most K_Ca channels consistently liesbetween 10 and 20 mV, suggesting that the voltage-sensing mechanismof K_Ca channels, including ours, seems to be well conserved. TheCa²⁺ and voltage dependencies of our K_Ca channel lie in the rangeof those of previously reported K_Cachannels.

Activation by membrane stretch. An interesting aspect of the K_Ca channel in cardiac myocytes described in this study is its mechanosensitive property, a directactivation by membrane stretch. Stretch activation of some K_Cachannels, however, has been ascribed to other mechanisms ratherthan to stretch itself, e.g., increases of intracellular Ca²⁺ concentration by Ca²⁺ influx through a SA cation channel that permits an influx ofCa²⁺ or volume-induced release of Ca²⁺ from cytoplasmic stores (21). Although we cannot completelypreclude such mechanisms in our channel, we have observed stretchactivation of the K_Ca channels under conditions designed to eliminatechanges in Ca²⁺ concentration in the pipette and bath solutions. In cell-attachedpatches with 0 mM Ca²⁺ in the patch pipette and the bath, membrane stretch by suctionalso increased the P_o of the K_Ca channel in a manner similar tothat in excised patches, suggesting that the stretch activationof our K_Ca channel does not require any intracellular messengers.These results strongly suggest that the channel is activated directlyby membranestretch.

Ruknudin et al. (23) have reported that one of five SA channels found in their study had a large conductance (190 pS), avalue similar to ours (23). However, our channel is much morepermeable to K⁺ over Na⁺ than their channel, and their channel had no clear voltage dependence.At present, without other data to compare, we cannot completelyconclude whether our channel is different fromtheirs.

Activation mechanism by ATP. In the present study, we found that the K_Ca channel is activated by physiological levels of ATP from the cytoplasmic sideof the membrane. It is possible that ATP activation of the K_Cachannel involves protein phosphorylation that requires ATP. Activationof K_Ca channels by cAMP-dependent phosphorylation has been reportedin a variety of cells (8, 14, 24). We tested the involvementof such a cAMP-dependent protein phosphorylation by using dibutyrylcAMP, a membrane-permeable cAMP analog, which had no significanteffect when applied to the inside-out patch (see Table 1). Wealso tested the effect of cAMP on the channel in the intact cellto check whether there is a cAMP-dependent intracellular mechanismthat could modulate the channel activity. However, even in cell-attachedpatches, extracellular application of dibutyryl cAMP up to 1 mMhad no effect on the channel activation. It is unlikely that activationof the K_Ca channel involves cAMP-dependent protein phosphorylation.What is puzzling is that adenosine 5'-O-(3-thiotriphosphate) (ATP $gamma$ S)had no effect on the K_Ca channel (see Table 1). At present wedo not know whether the channel discriminates the difference betweenATP and ATP $gamma$ S or whether ATP hydrolysis is involved in the ATPactivation. However, the latter mechanism seems to be unlikelybecause Mg²⁺ required for ATP hydrolysis had no effect on the ATPactivation.

On the other hand, it is known that muscarinic K⁺ channels in atrial myocytes of guinea pig hearts are directly activated byGTP and guanosine 5'-O-(3-thiotriphosphate) (GTP $gamma$ S) in the absenceof agonists such as acetylcholine (11). We applied GTP $gamma$ S (1mM) to the cytoplasmic surface of inside-out patches, but littleactivation of the K_Ca channels was detected. Thus G protein-mediatedsignal transduction systems may not play a major role in the activationof our K_Cachannel.

Recently, Lemos and Takeda (15) have reported that application of 10 µM ATP to the external solution containing a normalconcentration of Ca²⁺ caused a large increase in K_Ca-channel activity in cell-attachedpatches. This is due to the ATP-induced increase in Ca²⁺ concentration from both Ca²⁺ release from internal stores and influx from the extracellularsolution. In the present study, external solutions that containedATP did not activate K_Ca channels in cell-attached patches (datanot shown), and when ATP was in the bath, there was no differencein P_o with or without Ca²⁺ in the pipette in excised inside-out patches (data not shown).Therefore, it is not likely that the activation of our K_Ca,ATPchannel by ATP involves an ATP-induced increase in intracellularCa²⁺ concentration or [Ca²⁺]_b (15). These results strongly suggest that the ATP-activationof our K_Ca channel is mediated by a direct interaction of ATPwith thechannel.

It is known that, under physiological conditions, the intracellular ATP concentration is a few millimoles per liter. However,we observed in cell-attached patches that the activity of theK_Ca,ATP channels was extremely low, whereas in inside-out patches,1 mM ATP at the cytoplasmic surface caused a significant activation.It is possible that in cell-attached patches some kind of cytosolicfactors may suppress the ATP-induced activation of the K_Ca,ATPchannel.

Physiological role of SA K_Ca,ATP channels. In this study we used only embryonic heart cells; therefore, it may be too early to discuss the physiological role of theK_Ca,ATP channel. Taking this limitation into account, we offersome speculation on the possible functions of this channel intheheart.

Intracellular Ca²⁺ concentration in heart cells under physiological conditions is roughly 0.10 µM in the diastolic phase and1.0 µM in the systolic phase. The corresponding membrane potentialsare roughly $-$ 80 and +30 mV. Intracellular ATP concentration inheart cells is suggested to be 4-5 mM in both phases. With a 0.10µM [Ca²⁺]_b at $-$ 80 mV, P_o of the K_Ca,ATP channel in this study proved tobe quite low (Fig. 6), and ATP is not likely to increase P_o atthis potential (Fig. 8). On the other hand, with a 1.0 µM [Ca²⁺]_b at +30 mV, corresponding to the systolic phase, P_o increasedto the maximal level even with no ATP (Fig. 6). Thus ATP may notaffect the K_Ca,ATP channel under normalconditions.

Under pathological conditions, e.g., during ischemia, intracellular Ca²⁺ concentration is suggested to be 0.8-1.0 µM in the diastolicphase and 1.3-1.5 µM in the systolic phase. Intracellular ATPconcentration during ischemia decreases to 25-30% of its normallevel, namely, 1.0-1.3 mM, in both phases. With a 0.8 µM [Ca²⁺]_b at $-$ 80 mV, P_o of the channel seems to be >30% (Fig. 6). A 1mM [ATP]_b does not seem to affect the P_o at this potential (Fig.8D). The channel may be fully activated in the systolic phaseduring ischemia, as under normal conditions. Thus, under pathologicalconditions in both phases, the channel would remain at a highlyactivated level, contributing to hyperpolarization of the membranepotential and reduction of the excitability. The effect of ATPon the channel under both conditions is not clear, because [Ca²⁺]_b seems to dominate in controlling the voltage dependence ofthe channel. ATP may contribute to a more subtle regulation ofthe K_Ca,ATP-channel activity. On the other hand, membrane stretchseems to increase the P_o of the channel (Fig. 7D) and to acceleratethe hyperpolarizingprocess.

Albarwani et al. (1) have suggested that K_Ca,ATP channels in pulmonary arterial smooth muscle cells isolated from the ratare involved in controlling pulmonary vascular tone under hypoxicconditions. After hypoxia, the sensitivity of K_Ca,ATP channelsto intracellular Ca²⁺ concentration, and therefore to voltage, is reduced as a consequenceof reduced intracellular ATP concentration. The activity of thesechannels is therefore reduced, exerting a depolarization, whichwould potentially favor Ca²⁺ influx through voltage-gated Ca²⁺ channels, ultimately increasing pulmonary vascular tone. Thismay also mean that activation of K_Ca,ATP channels causes dilationof pulmonary arteries. Taguchi et al. (27) have suggested thatdilation of cerebral arteries in response to increases in theintracellular concentration of cAMP is mediated by activationof K_Ca channels. Brayden and Nelson (5) also indicated thatactivation of K_Ca channels by any means could lead to vasodilationof myogenic arteries. Thus one important role of K_Ca channelsmight be to exert vasodilation. Kume et al. (13) have suggestedthat $beta$ -adrenergic stimulation of K_Ca channels may cause relaxationof tone in airway smooth muscle, namely, bronchodilation by cAMP-dependentand membrane-delimited pathways. Likewise, K_Ca,ATP channels inthe heart may be involved in dilation or relaxation of the heart.However, it remains to be determined whether the K_Ca,ATP channelis expressed in matured heart cells and how the K_Ca,ATP channelis involved in the heart under physiological and pathologicalconditions.

	ACKNOWLEDGEMENTS

This work was partly supported by Grants-in-Aid 09044283 and 09257220 for scientific research (to M. Sokabe) from the Ministryof Education, Science and Culture of Japan, a grant (to M. Sokabe)from the Japan Space Forum, and a grant (to M. Sokabe) fromCREST.

	FOOTNOTES

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests and other correspondence: M. Sokabe, Dept. of Physiology II, Nagoya University School of Medicine, 65 Tsuruma-cho, Showa-ku, Nagoya 466-8550, Japan (E-mail: msokabe{at}med.nagoya-u.ac.jp).

Received 29 June 1998; accepted in final form 14 January 1999.

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