INTRODUCTION

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

Motor cells such as stomatal guard cells or flexors and extensors of the leaf-moving organs (pulvini) increase their volume and turgor mainly due to the uptake of K⁺ and Cl. Signals causing the motor cell swelling and increase of turgor activate the plasma membrane H⁺ pump, leading to hyperpolarization in guard cells (Assmann et al., 1985) and in pulvini (Racusen and Satter, 1975; Kim et al., 1992, 1993), and to the acidification of the apoplast in guard cells (Shimazaki et al., 1985; Edwards et al., 1988) and in pulvini (Iglesias and Satter, 1983; Erath et al., 1988; Lee and Satter, 1989; Starrach and Meyer, 1989). The swelling signals and the hyperpolarization also activate K⁺ influx in guard cells (Humble and Rashke, 1971; Blatt, 1985; Bowling, 1987) and in pulvini (Lowen and Satter, 1989; Starrach and Meyer, 1989; Kim et al., 1992, 1993). The influx of K⁺ occurs via K⁺-selective, inward-rectifying K channels activated by hyperpolarization (K_in, or K_H channels) in guard cells (Schroeder et al., 1987; Schroeder, 1988; Blatt, 1992; Ilan et al., 1996) and in pulvini (Moran, 1990).

The function and regulation of K_H (K_in) channels in guard cells has been described extensively (Schroeder, 1988, 1995; Fairley-Grenot and Assmann, 1992b, 1993). They are activated by acidification (Blatt, 1992; Ilan et al., 1996; Dietrich et al., 1998), blocked by Ca²⁺ (Schroeder and Hagiwara, 1989; Blatt, 1992; Fairley-Grenot and Assmann, 1992a; Lemtiri-Chlieh and MacRobbie, 1994; Kelly, 1995; Dietrich et al., 1998; Grabov and Blatt, 1999), and they depend on external K⁺ (Schroeder, 1988; Blatt, 1992). These are by far the best characterized native plant K channels. The characterization of these K_H (K_in) channels includes their molecular identification with the widely studied KAT1 channel and its close homologs (Schachtman et al., 1992; Cao et al., 1995; Hoshi, 1995; Nakamura et al., 1995; Becker et al., 1996; Hoth et al., 1997b; Ichida et al., 1997; Li et al., 1998; Uozumi et al., 1998; Baizabal-Aguirre et al., 1999; Bruggemann et al., 1999; Tang et al., 2000; for review, see Czempinski et al., 1999; Dreyer et al., 1999; Zimmermann and Sentenac, 1999).

In contrast to guard cells, there is no comparable information (except for a brief report; see Moran, 1990) on the K⁺ influx channels of the pulvinar motor cells. On the contrary, various attempts to activate them in Mimosa pudica failed (H. Stoeckel, personal communication). Neither have any records been published as yet of inward K⁺ currents in the Phaseolus pulvini. We are presenting here the first characterization of K⁺ influx channels from motor cells of pulvini of the legume Samanea saman, of the Mimosa family. In accordance with the presumably identical roles of K⁺ influx channels in the swelling of the motor cells (for review, see Satter and Galston, 1981; Freudling et al., 1988; Moran, 1990), we expected the K_H channels in both cell types to behave similarly. However, in a surprising contrast to guard cell K_H channels activated by extracellular acidification, the K_H channels of S. saman pulvini were inhibited by external protons. These contrasting results emphasize the importance of studying channels in a variety of model systems, in preference to focusing on a single cell type.

	RESULTS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

Instantaneous versus Time-Dependent Currents

Voltage Dependence of Inward Currents

View larger version (48K): [in this window] [in a new window]   Figure 1.   Two types of inward currents at two concentrations of external K+. A, Pulse protocol (top) elicited inward currents from a flexor cell at the indicated [K+]O (superimposed records, middle and bottom). Numbers at the right are the membrane potentials during the corresponding pulses. (f), Pipette solution. B, I-EM relationships of the time-dependent currents (mean ± SE) from extensors (E) and flexors (F). At [K+]O of 40 mM, the mean values of current at 170 mV were 53 ± 9 (± SE, n = 6) in E and 64 ± 16 pA (n = 5) in F; at 200 mM, 203 ± 31 pA (n = 11) in E and 229 ± 36 (n = 12) in F. Note the much smaller error bars due to the normalization procedure (if not seen, the errors are smaller than the symbols; see "Materials and Methods" for details). The following combinations of bath/pipette solutions were used (see "Materials and Methods" for details): bath: 40 mM K+ (solution b)/pipette: (solution f), or (h) or (g), or bath: 200 mM K+ (solution c)/pipette: (f). C, I-EM relationships of the instantaneous currents from individual cells of B.

Selectivity

View larger version (12K): [in this window] [in a new window]   Figure 2.   Reversal potentials of the inward currents. Mean values (± SE) of Erev and EL, the reversal potentials of the time-dependent and the instantaneous currents, versus K+O, K+ activity in the bath. K+O was calculated from the external K+ concentrations using activity coefficients from (Robinson and Stokes, 1965). When not seen, the error bars are smaller than the symbols. Data are from four extensors (E) at [K+]O of 5 mM, five extensors, and eight flexors (F) at 40 mM and from 10 extensors and 11 flexors at 200 mM. The dotted line represents the calculated EK, the Nernst potential of K+ (Eq. 2). Solutions were distributed as follows: bath: 5 mM K+ (solution a)/pipette: (f); bath: 40 mM K+ (solution b)/pipette: (f) (four extensors and six flexors), or (g) (one flexor), or (h) (one extensor and one flexor); bath: 200 mM K+ solution c)/pipette: (f).

Effects of Tetraethylammonium (TEA) and Cs⁺ on the Inward Currents

View larger version (15K): [in this window] [in a new window]   Figure 3.   The effect of Cs+. Top, Voltage pulse protocol. Bottom, Whole-cell current traces (superimposed) recorded from a flexor cell in the absence (Cs+) and in the presence (+Cs+) of Cs+ added to the bath to a final concentration of 10 mM. Note the contrast between the inward current block at 140 mV and the lack of any effect on the outward current at 60 mV (except of the initial phase, representing the different contributions of the "tail currents" resulting from the preceding pulse). Solutions: bath (c)/pipette (f).

Correlation between the Two Types of Conduits

K@170

K@170

View larger version (22K): [in this window] [in a new window]   Figure 4.   Correlation between leak and KH channels. A through D, Correlation between currents. Symbols: paired values of IK at steady state and IL, determined in the same cells at 170 mV. The data were grouped separately according to the cell type (E, extensors; F, flexors) and the [K+]O (as indicated; 30 cells in each category). Lines, Linear regressions to the data. E and F, Correlation between conductances. Symbols: GL and GK@170 values, determined as described in "Materials and Methods" and paired by the cell of origin, as in A through D, were also grouped according to the cell type and [K+]O. Lines, Linear regressions to the data. The regression slopes and correlation coefficients were, respectively, as follows: in flexors at 5 mM, 0.16, 0.68, P < 0.0001 (n = 30); in extensors at 5 mM, 0.02, 0.24, P < 0.2 (n = 30); in extensors at 40 mM, 0.7, 0.28, P < 0.14 (n = 30); in flexors at 40 mM, 0.6, 0.14, P < 0.47 (n = 30); extensors at 200 mM, 0.24, 0.67, P < 0.02 (n = 12); and flexors at 200 mM, 0.30, 0.79, P < 0.0005 (n = 15). Solutions: b/f, b/h, c/f, or c/h.

Single Channels

View larger version (30K): [in this window] [in a new window]   Figure 5.   Single channels underlying the inward currents. A, Representative traces with unitary currents from an outside-out extensor patch bathed in solution (b) during steps (arrows) to the indicated membrane potentials, lasting 5 s. The inter-pulse-interval was 30 s. Solutions: (b)/(f). Note the downward deflections signifying channel opening. B, An average of 10 traces of current evoked by a repeated step to 170 mV in the patch of A. Note the gradually increasing inward current similar to the time-dependent whole-cell current in Figure 1A. The dash at the left indicates the closed-channel current. C and D, The same patch as in A, now bathed in solution (e). Note the similar pattern of activity (as in A and B). Pipette solution: (f). E, Single-channel activity at 110 mV (left), and a corresponding all-points amplitude histogram presented at the same current scale (right), to illustrate the complicated multilevel appearance of the unitary events. Dotted line and C, the closed-channels current level. Solutions: (c)/(f).

K_H Channel Gating

K@170

K@170

View larger version (23K): [in this window] [in a new window]   Figure 6.   The effect of [K+]O on KH channel gating. GK-EM relationships (mean ± SE) of six extensors (E) and five flexors (F) at [K+]O of 40 mM and from eight extensors and nine flexors at 200 mM. Lines are Boltzmann functions fitted to the averaged (GK-EM) data, with the best fit parameters listed in Table I (see "Materials and Methods" for details of averaging). Arrows indicate the E1/2 values. Solutions as in Figure 1B.

Effects of Extracellular pH

To test the effect of pH, we used 200 mM K⁺ in the bath because these conditions yielded increased inward currents (Fig. 5). Lowering the external pH from 7.8 to 5.0 decreased I_K, and this effect appeared reversible (Fig. 7, A-D). The same was true for G_K@170, but in contrast, it appeared that G_L was not affected by acidification (Fig. 7, E and F). In fact, each wash was accompanied by an increase in G_L. To resolve the effect of acidification on the steady-state K_H channel gating, we again fitted G_K-E_M relationships with the Boltzmann equation (Eq. 3; Fig. 8). In both extensors and flexors, acidification markedly decreased G_max (Table II). It is interesting that although restoring pH 7.8 also restored the G_max, E_1/2 in flexors became more negative than at pH 7.8_I (P < 0.02; Fig. 8; Table II).

View larger version (37K): [in this window] [in a new window]   Figure 7.   The effect of external pH on membrane conductance at [K+]O of 200 mM (pipette solution: f). A, Inward currents in a flexor cell at the indicated pHs. Pulse protocol as in Figure 1A. Numbers at the right are the membrane potentials during the corresponding pulses. B, I-EM relationships of the time-dependent current records in A during consecutive treatments at pH 7.8 (7.8I), then at pH 5.0 and again at pH 7.8 (7.8II). C and D, I-EM relationships of the time-dependent currents (mean ± SE), compared at the two pHs in the same cells: four extensors and five flexors (see "Materials and Methods" for details of averaging). The mean (±SE) values of the extensors and flexors currents at pH 7.8 and 170 mV, used for the normalization and "restoration," were 219 ± 55 pA and 153 ± 29 pA, respectively. E and F, Comparison of conductances (mean ± SE, n), GK at 170 mV (GK@170) and GL (between 80 and 170 mV), in the extensors and flexors of C and D, at the different pHs. Prior to averaging, GK@170 at each pH was normalized to GK@170 at pH 7.8I. The mean values used for normalization were 1.1 ± 0.2 nS in extensors and 0.8 ± 0.2 nS in flexors.

View larger version (24K): [in this window] [in a new window]   Figure 8.   The effect of external pH on KH channel gating. GK-EM relationships (mean ± SE) of A, four extensors, and B, five flexors at [K+]O of 200 mM at the indicated pHs. Lines are Boltzmann functions fitted to the averaged (GK- EM) data, with the best fit parameters listed in Table II (see "Materials and Methods" for details of averaging). Arrows indicate E1/2 values. Note the progressive shift of E1/2 to more negative values. Solutions: bath: (c) or (d)/pipette: (f).

	DISCUSSION

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

Identification of the S. saman K_H Channels

The dependence of single-channel activity on hyperpolarization (Fig. 5), the similarity of the time course of single channels recruitment to the time course of activation of whole-cell currents (Figs. 5B and 1A), and the insensitivity to drastic changes in the chloride Nernst potential (Fig. 5, A and C) all indicated that the single channels we observed included K_H channels. We were unable, however, to distinguish between K_H and leak channels. To our surprise, all the records from all the outside-out patches exhibited single-channel activity with an extremely wide range of unitary amplitudes. This is very different from the relatively uniform appearance of the inward-rectifying unitary currents via the K_H channels in patches from oocytes expressing KAT1-type channels (Zei and Aldrich, 1998), or AKT2/3 channels (Marten et al., 1999; Lacombe et al., 2000). Even the unitary currents of native, inward-rectifying, plant channels described to date were much more uniform in appearance, such as those in outside-out patches from guard cell protoplasts with KAT1-type channels of broad bean (Vicia faba; Schroeder et al., 1987; Wu and Assmann, 1994; Ilan et al., 1996), or of potato (Solanum tuberosum; Dietrich et al., 1998), or even in an outside-out patch from a coleoptile vasculature protoplast, presumed to exhibit the activity of ZMKT2, an AKT2-like channel (Bauer et al., 2000). The same pattern of multilevel openings was also apparent in our records filtered at 500 Hz and sampled at 2 kHz (data not shown). Further work is required to resolve whether specific cytosolic components or intactness of the membrane are required for a more uniform amplitude of the unitary currents in S. saman, and/or whether this complicated pattern of activity reflects two populations of channels.

Another important difference between the guard cell and the pulvinar K_H channels revealed in this report is their opposite dependence on external acidification: In guard cells, channel activity was enhanced (Blatt, 1992; Ilan et al., 1996), whereas in pulvinar cells, channel activity was inhibited (Figs. 7 and 8). A similar difference was demonstrated between the guard cell KAT1-type channels (expressed in oocytes), which were activated by external acidification (Hoshi, 1995; Mueller-Roeber et al., 1995; Very et al., 1995; Hoth et al., 1997a) and the AKT2-type channels (also expressed in oocytes), which were inhibited by external acidification (Marten et al., 1999; Philippar et al., 1999; Lacombe et al., 2000). These contrasting findings suggest that the K_H channels revealed in electrophysiological experiments in guard cells and in pulvinar cells may have different molecular identity. In their pH dependency, the pulvinar K_H channels resemble the ZMK2-like channels in maize (Zea mays) coleoptiles (described in the first account of anin planta AKT2-like channel, Bauer et al., 2000 [published simultaneously with the completion of the present work]). Our recent cloning of two members of the AKT2 subfamily from whole pulvini (accession nos. AF099095 and AF145272) and the demonstration of their expression in the extensor and flexor tissues (Becker et al., 1998; M. Moshelion, D. Becker, and N. Moran, unpublished data) lend support to this notion.

The Instantaneous and Time-Dependent Currents: A Single Interconverting Channel or Two Separate Conduits?

Recent reports on the inward voltage-dependent K⁺ currents via AKT2 channels expressed in oocytes, as well as on the ZMK2-like channel of maize, attributed the instantaneous and the time-dependent currents to the same channel (Marten et al., 1999; Philippar et al., 1999; Lacombe et al., 2000). The report on ZMK2-like channels in maize cells followed suit, adopting a similar approach (Bauer et al., 2000). Because of the danger inherent to heterologous expression systems of evoking endogenous activity, we decided to reexamine the issue in the S. saman model.

Biophysical and pharmacological approaches support the notion that the leak pathway contains a K⁺ conduit, similar to the K_H channel. In our experiments, the reversal potential of the instantaneous currents, E_L, was significantly lower than the calculated reversal potential of the "seal leak" (i.e. the liquid junction potential of 0 mV between the pipette and the bath solutions; see Fig. 2). Only an increased membrane conductance to one (or both) of the cations K⁺ and Mg²⁺, with negative equilibrium potentials, would be capable of shifting E_L away from 0 mV at [K⁺]_O of 5 and 40 mM. While G_L was of the same order of magnitude as the seal conductance (0.1-1 S), perfectly K⁺-selective channels would have to constitute well over one-half of the total leak conductance to shift E_L from 0 to 17 mV (calculated based on the equivalent circuit model [Hille, 1992]) and E_K of 30 mV. Indeed, the leak pathway was largely blocked by Cs⁺ (Fig. 3).

Does only one interconverting molecule underlie both K⁺ conductances? Two lines of evidence indicate that leak channels (I_L and G_L) and K_H channels (I_K and G_K) might be separate. G_L and G_K were not correlated in three cases: in extensors and flexors at 40 mM and in extensors at 5 mM (Fig. 4). G_K decreased significantly with acidification, whereas G_L did not (Fig. 7, E and F). However, this lack of G_L susceptibility to pH could be only apparent; for example, it could be due to an increasing fraction of nonspecific leak resulting from the worsening of pipette seal with each bath wash (inexplicably, this was pronounced more in flexors than in extensors).

An argument in favor of the single-molecule hypothesis in the case of S, saman is the remarkable increase of both I_K and I_L with [K⁺]_O (Fig. 1 and text). However, such a correlation is expected for K channels.

Another piece of evidence suggesting that I_L and I_K, or G_K and G_L, represent the same channel is the correlation between the two types of pathways in cells grouped by type and concentration (in three out of six cases examined: in flexors at 5 mM external [K⁺], and in extensors and flexors at 200 mM; Fig. 4). However, this correlation may simply reflect the activity of a regulatory mechanism common to these pathways, even if they are distinct.

Finally, the "same channel" notion is favored by a similarity in the pharmacological effects: Not only were I_L and I_K blocked similarly by Cs⁺, but they were also (at least in flexors) similarly insensitive to TEA, a rather uncommon behavior of K channels. Taken together, all of these results suggest that an important component of the leak in S. saman motor cells may consist of modified, voltage-independent, K_H channels.

Physiological Relevance: Both K_H Channels and Leak Pathways Are Probably Important for K⁺ Influx

K⁺ influx channels are presumed to play the same roles in the swelling of cells in the flexor and extensor parts of the pulvinus, although they are regulated by different signaling cascades (Kim et al., 1993, 1996; Suh et al., 2000). In our experiments with isolated protoplasts in a whole-cell configuration, no significant differences between inward currents have been found between both cell types, and therefore we have not separated them in our discussion.

We base our estimate of the transmembranal K⁺ flux in the pulvini on the osmolarity differences between the swollen and contracted states in flexors and extensors in situ of approximately 350 and approximately 400 mOsm, respectively (Gorton, 1987). Attributing it all in roughly equal parts to K⁺ and Cl (Satter and Galston, 1981) means that [K⁺] fluctuations in the cells are within about 200 mM. Based on an average diameter of a motor cell protoplast of 30 µm (Moran et al., 1988) and extrapolating to an intact pulvinus, this amounts to roughly 3 pM K⁺ exchanged across the cellular membrane during pulvinar movement.

Can K_H Channels Alone Mediate All of the K⁺ Uptake Necessary for the Swelling of S. saman Motor Cells?

pH Effect

K_H Channels in Guard Cells and Pulvinar Cells: The Two Models Compared

In rather similar conditions, i.e., at pH close to 8 and [K⁺]_O of 11 mM, G_L of guard cells was similar to that in pulvini; normalized to surface area, they were both about approximately 40 µS cm². In contrast to the similarity in G_L, the two cell types were greatly dissimilar in their G_K values. In guard cells, G_K was about 100-fold larger than G_L (normalized to surface area, G_K was 4.5 mS cm²; Ilan et al., 1996). In pulvini, G_K was at least 2- to 4-fold smaller than G_L (Fig. 4, E and F). The large G_K in guard cells appears to stem from the activity of KAT1 and KAT2 twin channels (Pilot et al., 2001), with an unknown contribution of other channels (Szyroki et al., 2001). In pulvinar cells, unless similar channels are revealed in different experimental conditions, the much smaller G_K may reflect the activity of AKT2-like channels alone. The inhibition of these pulvinar K_H channels by protons (as well as by Cs⁺, but not by TEA) provides an important characteristic trait that will be used in the quest for their molecular identification.

In conclusion, the guard cell paradigm of swelling needs to be modified for the pulvinar motor cells to include the inhibitory effect of pH on K_H channels, and the more than probable participation of the leak channels as K⁺ influx conduits.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION RESULTS DISCUSSION MATERIALS AND METHODS LITERATURE CITED

Plant Material

Samanea saman Merr. trees (referred to also as Pithecellobium saman Benth. [Little and Wadsworth, 1964], or as "saman," one of its common names throughout Latin America, or as "Samanea," in earlier physiological literature) were grown in a greenhouse or in a growth chamber under 16-h-light/8-h-dark schedule. The day illumination in the greenhouse (supplemented by Fluora lamps, Osram, Munich) was 300 to 700 µmol m² s¹, the temperature ranged between 18°C and 50°C, and the humidity was 60% to 90%. In the growth chamber the illumination was 50-100 µmol m² s¹, the temperature was 28°C to 30°C, and the humidity was 75% to 85%. Data from plants grown in both environments were pooled together.

Preparation of Protoplasts

Terminal secondary pulvini were harvested from the second and third mature leaves, counting from the top, within 3 h before or after dawn (in the growth chamber or the greenhouse, respectively). Protoplasts were isolated separately from the extensor and flexor regions of the pulvinus about 5 h following the harvest. The isolation procedure (Moran et al., 1988; Moran, 1996) was modified as follows: The freshly chopped tissue pieces were rinsed on a 20-µm mesh filter with solution containing 0.1% (w/v) polyvinylpyrrolidone to neutralize the possible effects of endogenous phenolics, the osmolarity of the enzyme solution was increased with sorbitol to 780 mOsm, and the osmolarity of protoplast incubation solution was maintained at 720 mOsm. The isolated protoplasts were kept on ice for up to 10 h under constant low-level illumination (approximately 2 µmol m² s¹) until use.

Patch-Clamp Procedure

The experiments were conducted at room temperatures between 23°C and 25°C, with 1°C variation during a single experiment. Application of the patch-clamp methodology (Hamill et al., 1981) to S. saman protoplast was described by Satter and Moran (1988). Patch-clamp pipettes were prepared from borosilicate glass (catalog no. BF150-86-10, Sutter Instrument Company, Novato, CA) by two-stage pull and fire polishing, yielding tips with resistances between 5 and 10 M (measured with an internal pipette solution and a 5 mM K⁺ external solution in the bath, solution a). The protoplasts were added into an approximately 300-µL chamber, allowed to settle on the glass bottom for 10 to 15 min, and flushed with 4 mL of solution a, used to promote protoplast-pipette sealing. The seal resistance was between 1 and 10 G. After attaining a "whole-cell" configuration and a few test records (approximately 10 min), the chamber was perfused with a 40 or 200 mM K⁺-external solution (solution b or c) aimed at eliciting inward current. The bridge of the reference electrode was filled with the same solution as the external recording solution chosen for prolonged recording in the particular experiment. All experiments were performed in a voltage-clamp mode (with an Axopatch B-1 amplifier, Axon Instruments, Foster City, CA) and were under computer control using a software-hardware system from Axon Instruments (pClamp program package software, version 5.5.1, and the TL1- TM-100 Labmaster A/D and D/A peripherals). Membrane potential was varied according to preprogrammed pulse protocols (detailed below).

The holding potential, restored between pairs of pulses, depended on the external solutions used: It was 80 mV with 5 mM K⁺ outside, 40 or 30 mV with 40 mM K⁺ outside, and between 30 and 0 mV with 200 mM K⁺ outside. Two pulse sequences were used during the experiments. To monitor the voltage and time dependence of the inward-rectifying K⁺ channels (the K_H channels), a series of increasingly hyperpolarizing single square pulses was applied at 25-s intervals between start of pulses (Fig. 1A, top). Each of the 8-s-long pulses, ranging between 50 and 155 or 170 mV, at 15-mV steps, were followed by a depolarization to +50 mV to enhance the deactivation of hyperpolarization-activated channels. To identify the selectivity of the channels, E_rev was determined by a "tail current" method consisting of a series of paired pulses (a constant main prepulse and a variable test pulse, denoted c and d, respectively, in Fig. 9, top), applied at 25-s intervals. The main prepulse, aimed to open the hyperpolarization-activated channels, was always the same for a given series (4 s, 170 mV), whereas the test pulses ranged from 60 to 15 mV with 40 mM K⁺ in the bath, or from 30 to 15 mV with 200 mV K⁺ (usually aimed at the vicinity of the presumed reversal potential). To obtain the "leak" current (reflecting the conductance of channels open at the holding potentials, as well as nonspecific conductances), each main prepulse was preceded by a brief pulse of the same amplitude as the corresponding test pulse, before any channel has had the chance to open (Fig. 9a). The currents were filtered via a 4-pole Bessel filter of the patch-clamp amplifier, with a 3dB point of 50 Hz, sampled at a frequency of 250 Hz.

View larger version (26K): [in this window] [in a new window]   Figure 9.   Determination of reversal potentials by the "tail current" method. A, Pulse protocol (top) elicited inward currents from a flexor cell at [K+]O of 40 and 200 mM (superimposed records, middle and bottom). a and d, Varying pre- and test- pulses; b, holding potential; c, the main prepulse. Numbers at the right are the membrane potentials during the corresponding test pulses. Arrows mark the level of current at the reversal potential. Solutions used: bath, b or c with pipette f. B and C, I-EM relationships of the instantaneous (inst.) currents in A, sampled during a () and the zero-time tail current sampled at the onset of d (), at the indicated [K+]O. Arrows mark the reversal potential of the time-dependent current, Erev, 24 mV at 40 mM and +5 mV at 200 mM.

Single-channel currents were recorded in an "outside-out" configuration, similarly filtered at 50 Hz and sampled at 250 Hz (Fig. 5, A-D), or filtered at 500 Hz and sampled at 2 kHz (Fig. 5E). The record of Figure 5E was subsequently filtered for display (software Gauss filter) at 200 Hz.

Corrections

On-Line

On-Line: Holding Current Subtraction

Off-Line

Analysis

Whole-Cell Currents

IK Averaging

E_rev and G_K

(1)

(2)

(3)

(4)

G_K Averaging

Statistics

Means are presented with their standard errors (±SE, unless otherwise indicated), with n as the number of cells averaged. Differences between means were deemed significant if, using a two-sided Student t test, P < 0.05. Higher levels of significance are indicated in the text.

Solutions

The external solution contained D-sorbitol, adjusting the osmolarity from 700 to 730 mOsm, and in addition, one of the following combinations: (a) 5 mM KOH, 1 mM CaCl₂, and 9.5 mM MES [2-(N-morpholino)-ethanesulfonic acid], pH 6.0; (b) 1 mM KOH, 39 mM KCl, 0.3 mM CaCl₂, and 10 mM HEPES [4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid], pH 7.8; (c) 2 mM KOH, 198 mM KCl, 0.3 mM CaCl₂, 10 mM HEPES, and 6 mM N-methyl-D-glucamine, pH 7.8; (d) 2 mM KOH, 198 mM KCl, 0.3 mM CaCl₂, and 16 mM MES, pH 5.0; and (e) 1 mM KOH, 2 mM KCl, 37 mM K-Glu, 0.3 mM CaCl₂, and 10 mM HEPES, pH 7.8. The internal solution contained 125 mM KCl, 1 mM MgCl₂, 20 mM HEPES, and 8 mM N-methyl-D-glucamine, at pH 7.8, D-sorbitol, adjusting the osmolarity to 750 mOsm, and in addition: (f) 2 mM ATP-K₂ and 2 mM 1,2-bis(o-aminophenoxy)ethane-N;N;N;N-tetraacetic acid (BAPTA)-K₄, or (g) 4 mM ATP-K₂ and 2 mM BAPTA-K₄, or (h) 4 mM ATP-K₂ and 6 mM BAPTA-K₄.

Based on the assumption that the internal solution was contaminated with <10 µM total Ca²⁺, the calculated activity of free Ca²⁺ in all the internal solutions was approximately 10 to 30 nM. The calculated free Mg²⁺ activity was approximately 200 µM, and the activity of free ATP was approximately 20 to 30 µM. These calculations were performed using the "Geochem" program (Parker et al., 1995) with the following log of absolute stability constants of ATP complexes at 21°C: ATP-Ca²⁺, 4.0, 1.8; ATP-Mg²⁺, 4.3 and 2.7; ATP-H⁺, 7.1, 4.2, 1.0, and 1.0; and ATP-K⁺, 0.9 (Fabiato, 1988), and log of apparent stability constant of BAPTA-Ca²⁺: 6.7 (at pH 7, ionic strength 0.1 M, and in the presence of 1 mM Mg, Pehtig et al., 1989).

BABTA-K₄ was from Molecular Probes (Eugene, OR) and other chemicals were from Sigma (St. Louis) or MERCK (Rahway, NJ) and were of analytical grade.