BK Channel Activation by Brief Depolarizations Requires Ca2+ Influx Through L- and Q-Type Ca2+ Channels in Rat Chromaffin Cells

Murali Prakriya and Christopher J. Lingle

Department of Anesthesiology, Washington University School of Medicine, St. Louis, Missouri 63110


    ABSTRACT
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Prakriya, Murali and Christopher J. Lingle. BK channel activation by brief depolarizations requires Ca2+ influx through L- and Q-type Ca2+ channels in rat chromaffin cells. Ca2+- and voltage-dependent BK-type K+ channels contribute to action potential repolarization in rat adrenal chromaffin cells. Here we characterize the Ca2+ currents expressed in these cells and identify the Ca2+ channel subtypes that gate the activation of BK channels during Ca2+ influx. Selective Ca2+ channel antagonists indicate the presence of at least four types of high-voltage-gated Ca2+ channels: L-, N-, P, and Q type. Mean amplitudes of the L-, N-, P-, and Q-type Ca2+ currents were 33, 21, 12, and 24% of the total Ca2+ current, respectively. Five-millisecond Ca2+ influx steps to 0 mV were employed to assay the contribution of Ca2+ influx through these Ca2+ channels to the activation of BK current. Blockade of L-type Ca2+ channels by 5 µM nifedipine or Q-type Ca2+ channels by 2 µM Aga IVA reduced BK current activation by 77 and 42%, respectively. In contrast, blockade of N-type Ca2+ channels by brief applications of 1-2 µM CnTC MVIIC or P-type Ca2+ channels by 50-100 nM Aga IVA reduced BK current activation by only 11 and 12%, respectively. Selective blockade of L- and Q-type Ca2+ channels also eliminated activation of BK current during action potentials, whereas almost no effects were seen by the selective blockade of N- or P-type Ca2+ channels. Finally, the L-type Ca2+ channel agonist Bay K 8644 promoted activation of BK current by brief Ca2+ influx steps by more than twofold. These data show that, despite the presence of at least four types of Ca2+ channels in rat chromaffin cells, BK channel activation in rat chromaffin cells is predominantly coupled to Ca2+ influx through L- and Q-type Ca2+ channels.


    INTRODUCTION
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Elevations of cytosolic calcium ([Ca2+]i) mediated by influx through voltage-dependent Ca2+ channels participate in a multitude of cellular functions, including exocytosis, excitation-contraction coupling, synaptic plasticity, ion channel gating, gene expression, and the growth and death of neurons (Berridge 1998). An unresolved question is how, if at all, specificity in signaling may arise when multiple kinds of Ca2+ channels with comparable activation properties may all contribute to the average elevation of submembrane [Ca2+] within a cell. One possibility is that specificity in function of different Ca2+ signals may be encoded, in part, by the expression of different voltage-gated Ca2+ channels, each selectively coupled to particular Ca2+-dependent processes and each functionally optimized to provide a localized pattern of Ca2+ influx that is appropriate for a particular Ca2+-dependent process. As one step in addressing this issue, here we examine whether activation of large conductance Ca2+- and voltage-dependent K+ channels (BK channels) in rat chromaffin cells may be selectively coupled to particular subtypes of Ca2+ channels.

In rat chromaffin cells, >= 10-20% of BK channels appear to be sufficiently tightly coupled to Ca2+ channels that the activation of those BK channels during brief Ca2+ influx steps is resistant to high concentrations of intracellular EGTA (Prakriya et al. 1996). During Ca2+ influx, these BK channels appear to be driven to high open probabilities with [Ca2+]i in the vicinity of those BK channels reaching >= 60 µM. This coupling of a portion of the BK channels to Ca2+ channels is essential to allow the BK channels to participate in the rapid repolarization of membrane potential during action potentials in the rat chromaffin cells (Solaro et al. 1995). Because chromaffin cells express multiple subtypes of Ca2+ channels (Artalejo et al. 1994; Gandia et al. 1995; Hollins and Ikeda 1996), the observed functional coupling of BK channels to Ca2+ channels raises the question of whether BK current activation is dependent on Ca2+ influx through a particular subtype of Ca2+ channel.

We address two main issues. First, we confirm the identities of the various Ca2+ channel subtypes found in rat chromaffin cells (Gandia et al. 1995; Hollins and Ikeda 1996). Second, we examine their contribution in driving activation of BK channels. The results indicate that, of at least four classes of Ca2+ channels expressed in rat chromaffin cells, L-, N-, P-, and Q-type channels, BK current activation during brief Ca2+ influx steps characteristic of action potentials is coupled to Ca2+ influx predominantly through the L- and, when present, the Q-type channels. Because activation of BK current is important for the rapid termination of action potentials in rat chromaffin cells (Solaro et al. 1995), these results suggest that selective modulation of L- and Q-type Ca2+ channels by second messengers may affect the extent of BK current activation and hence cellular excitability.


    METHODS
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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
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Chromaffin cell culture

Adrenal glands were removed from Sprague-Dawley rats and enzymatically digested with an enzyme cocktail containing 3% collagenase, 2.4% hyaluronidase, and 0.2% DNAse as described earlier (Neely and Lingle 1992). Chromaffin cells were plated on collagen-coated dishes and maintained at 37°C and 5% CO2 in a medium composed of DMEM supplemented with 10% fetal bovine serum and 25 µl/ml ascorbic acid.

Electrophysiological methods

Whole cell recordings were performed at room temperature on cells 2-14 days after plating. In perforated patch-clamped cells, amphotericin was employed as the permeabilizing agent (Herrington et al. 1995). Whole cell currents were recorded with an Axopatch-1C amplifier (Axon Instruments; Foster City, CA) with a 500-MOmega feedback resistor. Whole cell voltage clamp was controlled with the Clampex program in the pClamp software package (Axon Instruments; Foster City, CA). Currents were obtained at a digitization rate of 2 kHz. Previous experiments (Prakriya et al. 1996) indicated that changing the sampling rate from 2 to 20 kHz produces only small effects on the estimates of the instantaneous BK current following the voltage step to +81 mV.

In some experiments involving Ca2+ channels, run-down of the Ca2+ current was noted. To prevent errors arising from run-down, only those cells were selected that satisfied the criteria that 1) Ca2+ currents exhibited stable responses during the control application of the Ba2+ solution, 2) the response to toxins displayed both a clear onset of block and an approximate exponential convergence toward a stable current level, and 3) recovery of response to reversible toxins such as nifedipine or brief applications of omega -CnTx MVIIC was complete.

Solutions

The standard extracellular solution contained (in mM) 140 NaCl, 5.4 KCl, 10 HEPES, 1.8 CaCl2, and 2.0 MgCl2 titrated to pH 7.4 with N-methylglucamine (NMG). In some experiments CaCl2 was excluded from the standard extracellular solution. The divalent concentration was kept constant by including 3.8 mM MgCl2 in this solution; 200 nM apamin was included in all experiments to block SK channels. For perforated patch-clamp experiments where both BK and Ba2+ currents were recorded from the same cell, the pipette saline contained (in mM) 120 K-aspartate, 30 KCl, 10 HEPES (H+), and 2 MgCl2 adjusted to pH 7.4 with NMG. To isolate IBa, the following extracellular solution was used: 10 BaCl2, 40 tetraethylammonium (TEA) chloride, 10 HEPES, and 90 NaCl with pH adjusted to 7.4 with NaOH. In experiments where only the Ba2+ currents were recorded, the composition of the internal saline was (in mM) 110 Cs-methane sulfonate, 14 phosphocreatine, 10 HEPES, 9 EGTA, 5 Mg-ATP, and 0.3 Tris-GTP. The pH was adjusted to 7.3 with CsOH. Osmolarity was measured by dew point (Wescor Osmometer) and adjusted between 290 and 310. Extracellular solution changes and drug applications were accomplished via a multibarrel perfusion system.

Drugs

Stock solutions of nifedipine (Sigma; St. Louis, MO) and Bay K 8644 (Bay K, Sigma) were prepared in ethanol at concentrations of 10 and 5 mM, respectively. omega -Conotoxin MVIIC (CnTx MVIIC), omega -conotoxin GVIA (CgTx GVIA) (both from RBI; Natick, MA), omega -Agatoxin IVA (Aga IVA, gift of Pfizer), and omega -Agatoxin TK (Aga TK, Peptide Institute; Japan) were dissolved in dH2O at stock solutions of 500, 500, 100, and 100 µM, respectively. Final concentrations are given in the legends. In some experiments, L-type Ca2+ current was isolated by blocking P-, N-, and/or Q-type Ca2+ currents by preincubating chromaffin cells with a cocktail containing omega -Aga IVA (100 nM), omega -CgTx GVIA (2 µM), and omega -CnTx MVIIC (2 µM) for >= 15 min before electrophysiological recordings. P-type Ca2+ current and/or N-type Ca2+ was also preblocked in some experiments by exposure to omega -Aga IVA (100 nM) and/or omega -CgTx GVIA (2 µM) for >= 15 ins before recording.


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ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Calcium current in rat chromaffin cells

Biophysical and pharmacological strategies were used to identify the various Ca2+ currents expressed in cultured rat chromaffin cells. Voltage-activated Ca2+ currents can be broadly classified into high-voltage-activated (HVA) and low-voltage-activated (LVA) currents De Waard et al. 1996). LVA currents display rapid voltage-dependent inactivation, require relatively mild voltage stimuli for activation, and completely inactivate at depolarized holding potentials in the range of -60 to -50 mV. HVA currents in contrast lack rapid voltage-dependent inactivation and require more positive potentials for activation (Artalejo et al. 1991; Scroggs and Fox 1992). Therefore the presence of LVA current can be detected by comparing the I-V relationship at negative holding potentials to that at more depolarized holding potentials (Artalejo et al. 1991; Scroggs and Fox 1992). Here Ca2+ current I-V relationships were obtained at two holding potentials, -85 and -50 mV, and the difference current at each depolarizing step was determined. A typical Ca2+ current I-V relationship obtained at holding potential of -60 mV in a rat chromaffin cell is shown in Fig. 1A. In 10 mM Ba2+, current activation occurred at voltages positive to -40 mV and peaked around 0 mV. The I-V relationship was very similar in 10 mM Ca2+ except for a slight (~5 mV) shift to the right of the peak of the response (n = 4 cells). As shown in Fig. 1B, when the holding potential was changed from -50 to -85 mV, the I-V relationship was unaltered at the more negative potentials, indicating minimal presence of LVA current in these cells (6/6 cells). Thus calcium current in the rat chromaffin cells studied here is predominantly of the HVA type.



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Fig. 1. Rat chromaffin cells express predominantly high-voltage-activated (HVA) Ca2+ currents A: current-voltage (I-V) relationship of Ca2+ current in a rat chromaffin cell in 10 mM Ba2+ and 10 mM Ca2+. The cell was held at -60 mV and depolarized for 100 ms in increments of 10 mV. The peak of the I-V in Ca2+ slightly right shifted compared with currents in equimolar Ba2+. Current traces elicited between -20 and +20 mV are shown below. B: changing the holding potential from -85 to -50 mV does not reveal any low-voltage-activated current. Same cell as in A. Currents elicited at the holding potential of -50 mV were subtracted from the currents at -80 mV. The resulting difference current peaked at approximately +3 mV. Standard whole cell method. Rs = 7 MOmega ; Cm = 6 pF; 60% compensated.

HVA Ca2+ current can arise from several subtypes of Ca2+ channels, including L-, N-, P-, Q-, and R-type channels (De Waard et al. 1996). These can be distinguished from one another based on differential selectivity to various inhibitors. L-type channels are sensitive to dihydropyridines (DHPs), N-type channels are irreversibly blocked by the snail toxin omega -CgTx GVIA, and P-type channels are blocked by low concentrations of omega -Aga IVA (for review see De Waard et al. 1996). Q-type channels can be blocked by high concentrations of omega -Aga IVA or by the snail toxin omega -CnTx MVIIC (McDonough et al. 1996; Randall and Tsien 1995).

Figure 2A illustrates the effects of sequential application of omega -CgTx GVIA, omega -Aga IVA, and nifedipine on the Ba2+ current (IBa) evoked at 0 mV. omega -CgTx GVIA (1-2 µM) and omega -Aga IVA (0.1 µM) produced irreversible inhibition of some IBa in most cells, indicative of blockade of N- and P-type Ca2+ channels, respectively. Nifedipine (5 µM) produced a rapid (<20 s), reversible block of IBa in all cells, indicating the presence of L-type Ca2+ channels. There was substantial variability in the extent of block produced by each drug. The mean irreversible block produced by 1-2 µM omega -CgTx GVIA applied for >= 90 s was 24 ± 3% (SE; n = 16 cells). omega -Aga IVA (0.1 µM) elicited only minor effects; the mean reduction of IBa by 0.1 µM omega -Aga IVA applied for >= 120 s was only 12 ± 3% (n = 5 cells). Nifedipine showed the most prominent reduction of IBa, with a mean percentage block of 33 ± 3% (n = 13 cells). A substantial fraction (30-40%) of the total IBa was unaffected by the combined actions of nifedipine, omega -CgTx GVIA, and 100 nM omega -Aga IVA, indicating the presence of other HVA currents.



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Fig. 2. Pharmacological analysis of HVA Ca2+ current reveals the presence of L- N-, P-, and Q-type Ca2+ current in rat chromaffin cells. A: N-, P-, and L-type Ca2+ currents in rat chromaffin cells. Ca2+ currents were recorded in the perforated patch-clamp mode by stepping to 0 mV for 15 ms from a holding potential of -60 mV every 10 s, and peak current amplitudes are plotted against time. The N-type antagonist omega -CgTx GVIA (1.6 µM), the P-type antagonist omega -Aga IVA (100 nM), and the L-type antagonist nifedipine (5 µM) were applied for the indicated durations. Standard whole cell method. Rs = 6 MOmega ; Cm = 9 pF; 80% compensated. B: omega -CnTx MVIIC blocks N-type Ca2+ current in a fast, fully reversible manner. Ca2+ currents were activated by stepping to 0 mV every 10 s for 15 ms. The toxin omega -CnTx MVIIC (2 µM) elicits 2 kinetically distinct blocking effects, a fast effect that is fully reversible and a very slow block that is largely irreversible in the time course of these experiments. The fast, reversible block is completely eliminated by blocking N-type current with omega -CgTx GVIA (1.5 µM). Standard whole cell method. Rs = 7 MOmega ; Cm = 12 pF; 80% compensated. C: slowly developing block by omega -CnTx MVIIC (2 µM) is present after blockade of P-type Ca2+ channels by omega -Aga IVA (100 nM), indicating the presence of Q-type Ca2+ current. N-type current was preblocked in this experiment by exposing the cells to 1 µM omega -CgTx GVIA for 15 min before recording. Perforated patch method. Rs = 12 MOmega ; Cm = 6 pF; 80% compensated. D: 2 µM omega -Aga IVA produces significant block of Ca2+ current consistent with effects on Q-type Ca2+ channels. Cell was preincubated with 100 nM omega -Aga IVA for 15 min before electrophysiological recording to block P-type Ca2+ current. Standard whole cell method. Rs = 6.5 MOmega ; Cm = 7 pF; 80% compensated.

omega -CnTx MVIIC is a calcium channel antagonist that blocks P-, Q-, and N-type calcium currents (McDonough et al. 1996; Randall and Tsien 1995). In CNS neurons, the onset of block of P- and Q-type current by omega -CnTx MVIIC is slow and only slowly reversible, whereas block of N-type current is fast and quickly reversible (McDonough et al. 1996). Figure 2B illustrates the effects of 2 µM omega -CnTx MVIIC on IBa elicited at 0 mV in 6 mM Ba2+. Effects of omega -CnTx MVIIC were evaluated in 6 mM Ba2+ rather than the 10 mM Ba2+ used in previous experiments because of the observation that higher concentrations of Ba2+ result in slower block of the P- or Q-type Ca2+ current by this toxin (McDonough et al. 1996). Two kinetically distinct components of blockade by omega -CnTx MVIIC could be detected, 1) a fast component (mean amplitude = 20 ± 3%; n = 14 cells) that was mostly complete within 40 s and was fully reversible and 2) a very slow component (mean = 27 ± 4%; n = 9 cells) that was largely irreversible over the time course of a typical experiment (Fig. 2B). When omega -CgTx GVIA was applied, the fast reversible effect of omega -CnTx MVIIC was consistently eliminated (6/6 cells), which suggested that it was mediated by N-type calcium channels. The slow component of omega -CnTx MVIIC block was similar to the block of P- and Q-type Ca2+ channels reported by McDonough et al. (1996). To examine if this arose solely from P-type Ca2+ channels or whether Q-type channels were also present, we next tested the efficacy of omega -CnTx MVIIC after preblocking N-type current by 1 µM omega -CgTx GVIA and P-type current by 100 nM omega -Aga IVA (Fig. 2C). Under these conditions, in 10 of 15 cells examined, omega -CnTx MVIIC produced an additional slowly developing block of some current, consistent with the presence of Q-type Ca2+ channels.

The presence of Q-type channels was also confirmed by omega -Aga IVA. This toxin blocks both P- and Q-type Ca2+ channels, although the relative affinities are widely different; P-type channels are maximally blocked by 100 nM omega -Aga IVA, whereas Q-type Ca2+ channels are blocked only at micromolar concentrations of omega -Aga IVA (Randall and Tsien 1995). Chromaffin cells were preincubated in 100 nM omega -Aga IVA for 15 min before electrophysiological recording, and the effect of 2 µM omega -Aga IVA was examined on the remaining Ba2+ current. In 8 of 11 cells tested, 2 µM omega -Aga IVA elicited a substantial block of the remaining IBa, indicating the presence of Q-type Ca2+ channels in these cells (Fig. 2D).

In some cells, omega -CgTx GVIA produced reversible block of a component of IBa (data not shown). The amplitude of this current could be substantially reduced by simultaneously applying nifedipine, suggesting that this was arising from L-type channels sensitive to omega -CgTx GVIA. We did not further characterize these currents. However, overlap between omega -CgTx GVIA and DHP inhibitors of L-type Ca2+ channels was reported in some cells (Kasai and Neher 1992), and it was suggested that the Ca2+ channels underlying this current may be L-type channels arising from the alpha 1D pore-forming subunit (Williams et al. 1992). A more recent study, however, indicates that the L-type Ca2+ channels in sympathetic neurons arising from the alpha 1D subunit are not omega -CgTx GVIA sensitive (Lin et al. 1996). Thus the identity of this current remains to be elucidated.

In sum, the previous experiments demonstrate that rat chromaffin cells express four major classes of HVA Ca2+ channels: L-, N-, P-, and Q-type channels. The average contributions of each type are summarized in Fig. 6. We also often observed a small residual Ca2+ current even in the combined presence of all the calcium antagonists mentioned previously (not shown). This current may be similar to the R-type current reported in previous studies that is insensitive to all the known Ca2+ channel toxins (De Waard et al. 1996).

BK current in rat chromaffin cells

Rat chromaffin cells express inactivating (BKi) or noninactivating (BKs) variants of BK current. Approximately 75% of the chromaffin cells express predominantly BKi current, and the rest express either noninactivating or a mixture of inactivating and noninactivating BK current (Ding et al. 1998; Solaro et al. 1995). All the data shown in this paper are from cells displaying BKi currents, although we observed no difference between the two cell types in the nature of BK-Ca2+ channel coupling.

Depolarizing steps that elicit Ca2+ influx through Ca2+ channels can robustly activate BK current in rat chromaffin cells (Solaro et al. 1995). Here BK current activation was studied in perforated patch-clamped cells by stepping the voltage to a potential that activates Ca2+ current followed by a test pulse to +81 mV where BK current activation was evaluated. Because minimal Ca2+ influx occurs at +81 mV, the effects of conditioning steps that activate Ca2+ influx can be easily distinguished from those that do not produce influx. Figure 3A shows the effect of stepping the voltage directly to +81 mV in the presence and absence of 1.8 mM [Ca2+]ext. Direct steps to +81 mV would be expected to only activate Ca2+-independent voltage-activated K+ currents (Solaro et al. 1995). Consistent with this, the current activated by a direct step to +81 mV in 1.8 mM [Ca2+]ext is identical to that elicited in 0 [Ca2+]ext. In contrast, a 5-ms step to 0 mV before the +81 mV test pulse produces Ca2+ influx through voltage-gated Ca2+ channels and results in substantial BK current activation at +81 mV (Fig. 3B).



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Fig. 3. Instantaneous and peak BK currents activated by Ca2+ influx in rat chromaffin cells. A: depolarizing steps to +81 mV activate voltage-dependent outward current. The cell was held at -69 mV and stepped to +81 mV in the presence and absence of the normal external Ca2+ (1.8 mM). Current in the absence of external Ca2+ is identical to current elicited in presence of external Ca2+, indicating that the direct step to +81 mV does not activate a Ca2+- and voltage-dependent K+ current. B: brief Ca2+ influx steps activate BK channels. A 5-ms step to 0 mV before the +81-mV test pulse produces Ca2+ influx through voltage-gated Ca2+ channels and activates BK current. There are 2 components in the current that are activated at +81 mV, an instantaneous current that is simply the tail at +81 mV of the BK current activated at 0 mV (arrow) and a slow, time-dependent increase in current caused by the increased open probability of BK channels at +81 mV. Same cell as in A. C: increasing the influx step duration to 150 ms increases the instantaneous and the peak BK currents activated at +81 mV. Same cell as in A. Perforated patch method. Rs = 12 MOmega ; Cm = 6 pF; 80% compensated.

A closer examination of the BK current at +81 mV reveals two current components. First, there is an instantaneous current, which is the ohmic increase in current resulting from the increased driving force on K+ ions passing through BK channels open at 0 mV (Fig. 3B, arrow) (for additional information about the instantaneous current see Prakriya et al. 1996). Second, there is a slower time-dependent increase in current that results from the activation of additional BK channels caused by the increased open probability of BK channels at +81 mV. The amplitudes of both these components of BK current increase as the duration of the influx step is increased (Fig. 3C). High concentrations of EGTA differentially affect these two components of BK current; the instantaneous current is unaffected by EGTA up to concentrations of 5 mM, whereas the slow component of BK current is eliminated by EGTA (Prakriya et al. 1996). These effects were interpreted to suggest the presence of two populations of BK channels at differing distances from Ca2+ channels, the instantaneous current possibly reflecting BK channels in close association with Ca2+ channels and exposed to high [Ca2+]i and the more slowly activating BK current reflecting channels at greater distances from sites of Ca2+ influx and exposed to the much lower bulk [Ca2+]i. In this study, the contribution of influx through various subtypes of Ca2+ channels found in chromaffin cells to the activation of BK channels by brief influx steps is examined. Ca2+ influx steps were confined to brief duration (5 ms) because brief steps will favor elevation of the [Ca2+]i in the immediate vicinity of the active Ca2+ channels while less significantly altering the global [Ca2+]i. Thus BK channels activated by brief Ca2+ influx steps are more likely to be driven by Ca2+ elevations in the vicinity of Ca2+ channels.

Selective blockade of L- but not N-type Ca2+ current affects BK current activation

The role of the various subtypes of Ca2+ channels toward BK current activation was next examined with the previous Ca2+ channel inhibitors. Figure 4 shows an example of the effects of 5 µM nifedipine and 2 µM omega -CnTx MVIIC on BK currents and Ba2+ currents activated by 5-ms Ca2+ influx steps. BK current was recorded in the standard external solution containing 1.8 mM [Ca2+], and Ba2+ current was recorded from the same cell by changing the standard external solution to one containing 10 mM Ba2+. Nifedipine caused a very substantial reduction in the amount of BK current activated by calcium influx. In contrast, applications of omega -CnTx MVIIC lasting 40-50 s resulted in only minor effects on BK current activation (Fig. 4). The average nifedipine-induced reduction in the amplitude of instantaneous BK current activated by calcium influx was 77 ± 2% (mean ± SE; n = 15 cells), whereas the nifedipine-sensitive Ba2+ current comprised 33 ± 3% of the total IBa. In contrast, omega -CnTx MVIIC reduced BK current activation by only 11 ± 3% (n = 9 cells), although the omega -CnTx MVIIC-sensitive Ba2+ current in these cells comprised 21 ± 3% of the total IBa. Even in cells with comparable amplitudes of nifedipine and CnTx MVIIC-sensitive Ba2+ currents, blockade of L-type Ca2+ channels by nifedipine evoked dramatically larger reductions in BK current than blockade of N-type Ca2+ channels by CnTx MVIIC. Thus these results suggest that BK current activation during brief Ca2+ influx steps primarily occurs via influx through L- but not N-type Ca2+ channels.



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Fig. 4. Selective blockade of L- but not N-type Ca2+ current inhibits influx-driven BK current activation. The effects of nifedipine (5 µM) and omega -CnTx MVIIC (2 µM) on BK and Ca2+ currents are compared in the same cell. Because application of omega -CnTx MVIIC was limited to 40 s, it should affect only N-type Ca2+ channels here. Top traces and plot show effects on BK current activation; bottom traces and plot show effects on Ba2+ currents from the same cell. BK current was activated by 5-ms influx step to 0 mV. Perforated patch method. Rs = 15 MOmega ; Cm = 9 pF; 80% compensated.

We also determined the effects of the irreversible N-type blocker omega -CgTx-GVIA. omega -CgTx-GVIA (1-2 µM) inhibited BK current by 20 ± 4% (n = 15 cells) and IBa by 24 ± 3% (n = 16 cells). These effects on BK current are larger than those elicited by block of N-type channels by omega -CnTx MVIIC. However, as pointed out earlier, omega -CgTx GVIA produced both irreversible and reversible effects on IBa in some cells, and much of the reversible effect could be blocked by nifedipine. Thus the larger effect of omega -CgTx GVIA on BK current relative to omega -CnTx MVIIC may result from the reversible block by omega -CgTx GVIA of a rarely occurring, novel Ca2+ channel variant that is susceptible to nifedipine blockade.

In separate experiments, any direct effects of Ca2+ channel inhibitors on BK current were assessed by introducing 10 µM [Ca2+]i into cells via the patch pipette to directly activate BK current. These experiments did not indicate any direct effects of the inhibitors on BK channels.

Blockade of Q- but not P-type Ca2+ channels affects BK current activation

The contribution of P-type channels toward BK current activation during calcium influx was evaluated with 100 nM omega -Aga IVA. Measurements of omega -Aga IVA-mediated inhibition of BK current activation and of the block of IBa were determined in different cells because of the irreversible nature of omega -Aga IVA block. Application of 100 nM omega -Aga IVA produced a small decrease in BK current activation in many cells (7/11 cells; no effect in 4 cells; Fig. 5A). The mean reductions in BK current and IBa were 14 ± 5% (n = 7 cells) and 12 ± 2% (n = 8 cells), respectively. These figures might be overestimates of the true contribution of P-type current because 100 nM Aga IVA would be expected to block Q-type Ca2+ current also. Thus these results indicate that the contribution of P-type Ca2+ channels to BK current activation is minor.



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Fig. 5. Blockade of P-type channels does not alter BK current activation, whereas Q-current blockade reduces BK current significantly. A: BK current activation was elicited by a 5-ms voltage step to 0 mV and followed by a step to +81 mV. Arrows point to the instantaneous current elicited at +81 mV by the 0-mV Ca2+ influx step. The trace shown here was obtained 150 s after the onset of drug application. Perforated patch method. Rs = 12.5 MOmega ; Cm = 8 pF; 80% compensated. B: block of Q-current by 2 µM omega -Aga IVA elicits a significant decrease in BK current activation. Same voltage protocol as in A. The cell was preincubated with 100 nM omega -Aga IVA for 15 min before electrophysiological recording. Perforated patch method. Rs = 15 MOmega ; Cm = 9 pF; 80% compensated.

In contrast, applications of 1.5-2 µM omega -Aga IVA produced substantially greater effects on both IBa and on BK current activation (Fig. 5B). After preblocking P-type Ca2+ channels by incubating the cells in 100 nM omega -Aga IVA for 15 min before the beginning of a recording, application of 2 µM omega -Aga IVA resulted in a mean reduction in BK current of 42 ± 4% (4/6 cells, no detectable effect in 2 cells). When IBa was examined, 1-2 µM omega -Aga IVA produced a mean block of 23 ± 4% (8/11 cells, no effect in 3 cells) after preblock with 100 nM omega -Aga IVA. It is unlikely that these effects of omega -Aga IVA result from a nonselective blockade of some L-type Ca2+ channels because several cells with substantial L-type currents were totally insensitive to 1-2 µM omega -Aga IVA. The true fraction of Q-type Ca2+ current and its contribution to BK current activation might be somewhat higher than these numbers indicate because preincubation with 100 nM omega -Aga IVA may by itself produce some block of Q-type Ca2+ current. Regardless of the exact amount of Q-current the results argue that, when Q-type channels are present, Ca2+ influx through these channels participates in initiating activation of BK channels.

Figure 6 summarizes the effects of all the Ca2+ channel antagonists used here on IBa and BK currents. Selective blockade of L-type Ca2+ channels had the greatest effect on BK current activation, whereas blockade of N- and P-type Ca2+ channels caused only minor effects. Blockade of Q-type Ca2+ channels by micromolar concentrations of omega -Aga IVA also reduced BK current activation significantly.



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Fig. 6. Summary of the pharmacological effects on BK and Ca2+ currents. BK current activation was elicited by 5-ms influx steps. Selective blockade or enhancement of L-type channels by nifedipine or Bay K 8644 have the greatest effects on BK current activation, whereas blockade of P-type channels by 100 nM omega -Aga IVA and N-type channels by omega -CgTx GVIA or by brief applications (<40 s) of omega -CnTx MVIIC produces only minor effects. Blockade of Q-type channels by 2 µM omega -Aga IVA also produces substantial reduction in BK current activation.

Blockade of L- and Q-type Ca2+ channels inhibits BK current activation during action potentials

We next examined the role of Ca2+ influx during action potential waveforms on BK current activation in perforated patch-clamped chromaffin cells. Currents were activated by an action potential voltage-clamp waveform that was generated by digitizing a chromaffin cell action potential recorded in the current-clamp mode. The ability of the previous Ca2+ channel blockers to inhibit the action potential-induced BK current was estimated by comparing K+ currents obtained in 0 [Ca2+]ext, which should block all the BK current induced by the action potential. Figure 7 shows typical examples of the effects of removing [Ca2+]ext and of the various Ca2+ channel blockers in perforated patch-clamped cells. In the majority of cells, a prominent shoulder or "hump" in the outward K+ current during the falling phase of the action potential is observed. When the external solution is replaced with a 0 [Ca2+]ext solution, the hump disappears, indicating that it arises because of the activation of BK current driven by Ca2+ influx during the action potential. In addition, the 0 [Ca2+]ext solution also reduces the peak outward K+ current in many cells, suggesting that BK current is also activated to some extent during the rising phase of the action potential.



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Fig. 7. Blockade of L- and Q-type Ca2+ current but not N- or P-type Ca2+ current reduces BK current that is activated during action potentials. Effects of Ca2+ channel blockers on BK current activation are compared with the effects elicited by removing [Ca2+]ext. Outward K+ currents were elicited by an action potential clamp waveform that was recorded in current clamp from a different cell. The difference between the control trace and the 0 [Ca2+]ext trace provides an estimate of the amplitude and time course of the BK current that is activated during the action potential. Note the prominent hump in the K+ current during the falling phase of the action potential (arrow). In A, 5 µM nifedipine was used to assay the effects of the block of L-type Ca2+ current. In B, a 40-s application of 2 µM CnTx MVIIC was used to block N-type Ca2+ current. In C and D, 100 nM and 2 µM Aga TK was applied to block P- and Q-type Ca2+ currents, respectively. Tetrodotoxin (500 nM) was present in all external solutions to block the inward sodium current. Nifedipine and 2 µM Aga TK elicit substantial reductions in the K+ current that is activated during the action potential, whereas CnTx MVIIC and 100 nM Aga TK produce only minor effects. Traces in A, C, and D were obtained from the same cell. Perforated patch method.

Analogous to results obtained from BK current measurements by 5-ms influx steps, block of L-type Ca2+ channels by nifedipine significantly reduced BK current activation during action potentials (Fig. 7A). In all cells (7/7), the peak outward K+ current was reduced, and the prominent hump in the K+ current was completely eliminated by nifedipine. In fact, the outward K+ current profile was very similar to that elicited in 0 [Ca2+]ext, indicating that nearly all BK current activation is prevented by the blockade of L-type Ca2+ channels during the action potential. In contrast, the same experiment done with transient (40-50 s) applications of omega -CnTx MVIIC to block N-type Ca2+ channels showed little or no effect in all cases (Fig. 7B). In these cells, the outward K+ currents were virtually identical to the control K+ currents activated in the normal [Ca2+]ext solution. In four of the six cells that were examined in this way, the amplitude of the N-type Ca2+ current was then determined by 40-s applications of 2 µM omega -CnTx MVIIC with 10 mM Ba2+ as the charge carrier. The mean amplitude of the omega -CnTx MVIIC-sensitive IBa was found to be 24% of the total IBa in these cells. Thus the lack of an effect by omega -CnTx MVIIC on BK current activation in these cells was not because of the lack of omega -CnTx MVIIC-sensitive Ca2+ channels.

The role of P- and Q-type Ca2+ channels toward BK current activation during action potentials was assayed by blocking these Ca2+ channels with Aga TK. Analogous to Aga IVA, low concentrations of Aga TK selectively block P-type Ca2+ currents, whereas higher concentrations have been also shown to block Q-type Ca2+ currents (Teramoto et al. 1995). We used 100 nM and 2 µM Aga TK to selectively block P- and Q-type Ca2+ currents, respectively (Fig. 7, C and D). Aga TK (100 nM) had little or no effect on the outward K+ current in all cells tested (5/5 cells), indicating that P-type Ca2+ currents do not contribute to BK current activation during action potentials. In contrast, 2 µM Aga TK elicited a substantial inhibition of the outward K+ current in four of five cells tested (Fig. 7D).

Collectively, these data are consistent with results obtained by 5-ms Ca2+ influx steps and show that blockade of L- and Q-type Ca2+ channels results in significant inhibition of BK current activation during action potentials, whereas selective blockade of N- and P-type Ca2+ channels produces little or no effect.

Bay K increases the BK current activated by calcium influx

The effects of the DHP agonist Bay K 8644 (Bay K), which is known to increase the amplitude of the ensemble Ca2+ current by favoring long-duration openings of L-type Ca2+ channels (Kokubun and Reuter 1984; Nowycky et al. 1985), were next examined on the depolarization-evoked Ca2+ and BK currents.

Bay K elicited a significant increase in the amplitude of the peak Ca2+ current (peak IBa increased ~143% of control; n = 10 cells). To examine if this is a consequence of an increase in the number of L-type Ca2+ channels or an increase in the Popen of L-type Ca2+ channels, we used noise analysis (Sigworth 1980) to estimate the number of Ca2+ channels and their average Popen (Fig. 8). In these experiments, the contribution of non-L-type Ca2+ channels to the Ba2+ current was minimized by preincubating chromaffin cells for >= 15 min with a cocktail of 100 nM omega -Aga IVA, 1 µM omega -CnTx GVIA, and 1 µM omega -CnTx MVIIC. As shown in Table 1, the primary effect of Bay K was to increase the peak mean current with no obvious effects on average single-channel conductance or channel number. Thus this result argues that the increase in peak Ca2+ current occurs mainly by an increase in the Popen of L-type Ca2+ channels.



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Fig. 8. Bay K 8644 enhances L-type Ca2+ channel open probability. Ensemble variance analysis was performed on a train of 100 Ba2+ current traces elicited at 0 mV every 6 s. Cells were exposed to 100 nM omega -Aga IVA, 1 µM omega -CgTx GVIA, and 1 µM omega -CnTx MVIIC for 15 min before electrophysiological recording to minimize the contribution of non-L-type Ca2+ channels. A and B: mean current and variance during the activation phase in control saline. D and E: same after application of 1 µM Bay K in the same cell. C and F: variance plotted against the mean current. ---------: fit of the relation sigma 2 = iI - I2/N + IBL, where i is the single-channel current, I is the mean current, N is the number of channels, and IBL is the baseline current at 0 variance. IBL is simply a small correction factor to take into account the presence of a nonzero variance at the 0 current level and might arise because of contaminating currents before and during the voltage pulse. Fit parameters: control saline: iCa = 0.41 pA; NCa = 5,001 channels; Bay K: iCa = 0.51 pA; NCa = 4781.


                              
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Table 1. Mean vs. variance analysis of Ca2+ channels

The consequences of the Bay K-mediated increase in L-type Ca2+ current on the BK current activated by brief influx steps were also examined. Bay K produced very large increases in the amplitude of BK current activated by brief Ca2+ influx steps (Fig. 9A). Although the maximal peak BK current activated by long-duration influx steps was the same in the presence or absence of Bay K (Fig. 9B), the instantaneous BK current activated by brief influx steps increased 2.2-fold on average (n = 5 cells). In these cells, IBa increased 1.38-fold on Bay K treatment. Thus this result indicates that, when L-type Ca2+ channel open probability is increased, the fraction of BK channels activated by Ca2+ influx during brief Ca2+ influx steps also increases significantly.



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Fig. 9. Bay K 8644 produces significant enhancement of BK current activated by influx. A: BK current was activated by 5-ms influx step to -9 mV. Top traces: effects of 2 µM Bay K on BK current; bottom traces: effects on Ba2+ current in the same cell. Perforated patch method. Rs = 14 MOmega ; Cm = 7 pF; 80% compensated. B: maximal BK current activated at +81 mV is not altered by Bay K. BK current activation was elicited by progressively increasing Ca2+ influx steps to 0 mV. Although the maximal value of the peak BK current activated at +81 mV does not change, the duration of Ca2+ influx required to reach the maximal BK current is greatly reduced in the presence of Bay K. Perforated patch-clamped cell. Rs = 11 MOmega ; Cm = 6 pF; 80% compensated.

We estimated the fraction of BK channels that can be activated by brief influx steps in the presence of Bay K by comparing the instantaneous BK current activated by 5-ms Ca2+ influx steps in the presence of Bay K with the total BK current present in the cell. For each cell, total current was estimated by measuring the peak BK current activated by 50 µM muscarine at +81 mV, which activates nearly all the BK channels in the cell (Prakriya et al. 1996). This procedure indicated that Bay K increased the fraction of BK channels activated by brief influx steps twofold, from 17.4 ± 3% to 36 ± 5% (n = 5 cells). Thus >= 30-40% of the BK channels in rat chromaffin cells are positioned sufficiently close to L-type Ca2+ channels so as to be influenced by Ca2+ influx through these Ca2+ channels during brief depolarizing steps.

Ca2+ influx through L- and Q-type Ca2+ channels is more effective than Ca2+ influx through other Ca2+ channels in driving BK current activation

The previous pharmacological experiments argue that BK channels are functionally associated with L- and Q-type but not the N- and P-type Ca2+ channels. How do these results compare with manipulations that do not discriminate among the various types of calcium channels but affect all of them? We examined this issue by lowering or raising [Ca2+]ext to determine the dependence of BK and Ca2+ current activation on the [Ca2+]ext (Fig. 10A). BK current at various [Ca2+]ext was then plotted against the Ca2+ current amplitude at the respective [Ca2+]ext (Fig. 10B). Note the sigmoidicity in the activation plot in Fig. 10B. This may represent the cooperative activation of BK channels by Ca2+.



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Fig. 10. Dependence of the amplitude of BK and Ca2+ current on Ca2+ influx. A: titration curves for BK and Ca2+ current activation plotted against the external [Ca2+] (0, 0.5, 1.0, 2.0, 4.0, and 8.0 mM). BK current was activated at +81 mV with a 5-ms Ca2+ influx step. Peak Ca2+ current was measured during a 10-ms depolarization to 0 mV. Currents were normalized for each cell to the 2 mM point and averaged. Each data point represents the average of 5-7 cells. The averaged data points were fit with a Hill equation (---------). The fit for the Ca2+ current was constrained by making n = 1. Fit parameters were as follows: BK current Imax = 1.4; EC50 =1.2 mM; n = 2.2; Ca2+ current: Imax = 2.65; EC50 = 3.28 mM. B: altering the Ca2+ current amplitude by nifedipine, Bay K, or high concentrations of omega -Aga IVA affects BK current activation to a much greater extent than altering the amplitude of the Ca2+ current by changing [Ca2+]ext. The data from A were redrawn here to plot the titration data for BK current activation against the titration data for Ca2+ current activation. The effects on Ca2+ and BK currents elicited by the various drugs were superimposed on this plot.

We found that, although omega -CnTx MVIIC, omega -CgTx-GVIA, and 100 nM omega -Aga IVA produced measurable reductions in BK current activation, these effects were not obviously different from those obtained by simply lowering the [Ca2+]ext to produce an equivalent reduction in the overall Ca2+ current. However, the selective blockade of L-type Ca2+ channels by nifedipine or Q-type Ca2+ channels by 1.5-2 µM omega -Aga IVA evoked reductions in BK current activation that were significantly greater than what could be produced by simply lowering the [Ca2+]ext to produce an equivalent reduction in the overall Ca2+ current. Similarly, enhancing the L-type Ca2+ current by Bay K produced an increase in BK current amplitude that was far in excess of the increase that could be produced by increasing the [Ca2+]ext to evoke a similar overall Ca2+ current. Thus the larger role of L-type Ca2+ current is not simply because this current comprises the largest Ca2+ current component. Instead BK current is more effectively activated when Ca2+ influx occurs through L- and Q-type Ca2+ channels than when it occurs through N- or P-type Ca2+ channels.


    DISCUSSION
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Multiple types of Ca2+ channels are frequently expressed in the same cellular compartment, and all contribute to the elevation of the average [Ca2+]i. Under such conditions, an unresolved question is whether there is specificity in Ca2+ signaling triggered by influx through the various subtypes of Ca2+ channels. We addressed this question with the Ca2+- and voltage-dependent BK-type channel on rat adrenal chromaffin cells and asked whether BK channels are specifically coupled to a particular Ca2+ channel subtype. Our results indicate, in fact, that BK channels appear to be preferentially activated by Ca2+ influx through L- and Q-type Ca2+ channels.

We assumed that the proportion of Ca2+ influx that occurs in the solutions used to record BK current (with 2 mM [Ca2+]) is comparable with the Ca2+ current amplitudes we measured with 10 mM Ba2+. In trying to relate the amount of influx that would occur in 2 mM [Ca2+]ext from the measured influx amounts in 10 mM [Ba2+]ext, two factors must be considered, 1) the increased permeability of HVA Ca2+ channels to Ba2+ over Ca2+ and 2) the saturable increase in the conductance of HVA Ca2+ channels as the divalent concentration is increased. If these effects occur in roughly the same proportion in all the HVA Ca2+ channel subtypes, the proportion of influx occurring at 10 mM [Ba2+]ext through a channel subtype can be assumed to be the same as that occurring in 2 mM [Ca2+]ext.

Examination of the Ba2+-Ca2+ permeability ratios of native L- and N-type channels from published studies show that these two currents do not differ significantly in their relative ability to conduct Ca2+ and Ba2+. The permeability ratio is roughly two- to threefold (Ba2+-Ca2+) in these channels (Fox et al. 1987; Kasai and Neher 1992; Smith et al. 1993). Moreover, the conductance dependence of native L- and N-type Ca2+ channels on the [divalent]ext at subsaturating concentrations appear to be comparable and show a roughly twofold increase as the divalent concentration is increased from 2 to 10 mM (McNaughton and Randall 1997; Smith et al. 1993; Zhou and Jones 1995). Detailed information on permeation and the divalent concentration dependence of the current is unavailable for the P-, Q-, and R-type Ca2+ channels. However, the Ba2+-Ca2+ ratio of the whole cell P-type current in Purkinje cells was reported to be ~2 (Regan 1991). Further, Bourinet et al. (1996) find that the Ba2+-Ca2+ conductance ratios of the cloned alpha 1A, alpha 1B, and alpha 1C channels, which may form the pore-forming subunits of the P-Q-, N-, and L-type Ca2+ channels (De Waards et al. 1996), are ~1.5, 1.5, and 2, respectively. Their study also showed that the [Ca2+]ext dependence of these channels is more or less similar. Collectively, these observations suggest that the relative amounts of influx through the L-, N-, P-, and Q-type Ca2+ channels may be similar in 2 mM [Ca2+]ext to that measured in 10 mM [Ba2+]ext. Although these are indirect arguments, there is no observation that requires us to reject this assumption.

Because blockade of L-type Ca2+ channels had the greatest effect on BK current activation, we also directly examined the fraction of Ca2+ current blocked by 5 µM nifedipine in 2 mM [Ca2+]ext. In two cells, ~30% of the Ca2+ current in 2 mM [Ca2+]ext was inhibited by nifedipine, which is virtually identical to the fraction of the DHP current in 10 mM Ba2+ (Fig. 6). On the basis of the previous arguments, this result suggests that the proportion of the remaining Ca2+ currents in 2 mM [Ca2+]ext may also be comparable with our measurements in 10 mM [Ba2+]ext. However, irrespective of the precise proportion of influx contributed by the different Ca2+ channels in 2 mM [Ca2+], it does not affect the central conclusion that BK current activation is affected more significantly by the blockade of L- and Q-type Ca2+ channels rather than N- and P-type Ca2+ channels.

Ca2+ currents in rat chromaffin cells

Our observations indicate that rat chromaffin cells express L-, N-, P-, and Q-type Ca2+ channels. The presence of each of these currents is generally consistent with previous reports (Gandia et al. 1995; Hollins and Ikeda 1996). L-type current was the largest component (~33%) of total Ca2+ current, whereas N-type current comprised ~20-25%. Q-type current was found in ~70% of rat chromaffin cells, consistent with Gandia et al. (1995), but differing from Hollins and Ikeda (1996). P-type current appears to be a minor contributor to total ICa in rat chromaffin cells.

We obtained no evidence of LVA current, contrasting with Hollins and Ikeda (1996), who found T-type current in ~25% of the cells they examined. It is possible that we did not sample enough cells to determine whether T-type currents are sometimes present. Alternatively, the Ca2+ currents present in the different strains of rats used in the two studies may differ.

Activation of BK current by L- and Q-type Ca2+ channels

Our results indicate that, although rat chromaffin cells express multiple types of HVA Ca2+ channels, Ca2+ influx through L- and Q-type channels dominates the activation of BK current. Although the precise physical mechanisms that mediate the specificity of this functional coupling will have to await future studies, in principle, it could arise if L- and Q-type Ca2+ channels are located much closer to BK channels than N- or P-type Ca2+ channels. Indeed the preferential targeting of ion channels to particular cellular locations was described in many cell types, and the underlying mechanisms may involve, at least in part, selective protein-protein interactions between ion channels and certain cytoskeletal proteins (Sheng and Wyszynski 1997). Analogous mechanisms may be at work in implementing the functional specificity that we observe between the BK and Ca2+ channels in rat chromaffin cells.

Selective functional association of Ca2+-activated K+ channels with particular Ca2+ channel subtypes was described in several types of neurons, and the specificity of the coupling appears to differ among different cell types. For example, in chick ciliary ganglion neurons, BK current activation has been shown to occur via Ca2+ influx through a L-type Ca2+ current but not the N-type Ca2+ current (Wisgirda and Dryer 1994). In contrast, in chick sympathetic ganglion neurons, the N-type current appears to dominate activation of BK current (Wisgirda and Dryer 1994). In rat superior cervical ganglion neurons, Ca2+ influx through L-type channels preferentially activates a BK-type current, whereas influx through N-type Ca2+ channels activates an SK-type current (Davies et al. 1996). In hippocampal neurons, BK channels are selectively coupled to N-type Ca2+ channels, whereas SK channels are selectively coupled to L-type Ca2+ channels (Marrion and Tavalin 1998). Finally, in rat dorsal motor vagus nucleus neurons, N-type Ca2+ channels are responsible for SK current activation, whereas BK current activation appears to be dependent on Ca2+ influx through omega -CgTx GVIA- and nifedipine-insensitive Ca2+ channels (Sah 1995).

In neurons, the complement of Ca2+ channels found in the various cellular compartments can be often markedly different. For example, N- and P-type Ca2+ channels are primarily localized to the dendrites and synaptic terminals (Westenbroek et al. 1992), whereas L channels are primarily localized to the soma (Hell et al. 1993). Similar differences in Ca2+ channel distributions occur in hippocampal neurons, in neurons of the cerebral cortex, and in the olfactory bulb neurons (Bischofberger and Schild 1995; Hell et al. 1993; Westenbroek et al. 1992). A consequence of this markedly different channel localization is that functional specificity in the association between Ca2+ and Ca2+-activated K+ channels may result, at least in part, simply because of segregation of channels to different membrane compartments. In contrast, rat chromaffin cells are spherical cells without complex morphological features such as dendrites or axons. BK channels can be detected in virtually all patches pulled from chromaffin cells, suggesting that these channels are present, at least, to some degree in all parts of the cell membrane (unpublished observations). However, the failure of N-and P-type channels to activate BK current during single action potentials implies that the [Ca2+]i elevations resulting from influx through these channels can be exquisitely localized even in simple spherical cells. Chromaffin cells may thus prove to be of considerable benefit for questions addressing the molecular basis for how specificity in coupling between Ca2+ channels and target proteins may occur.

Implications for cellular excitability

Ca2+ channels are known to be targets of numerous kinases, phosphatases, and G-proteins that modulate their properties and affect Ca2+ influx (Catterall 1997). Because BK current is the primary outward current involved in action potential repolarization in rat adrenal chromaffin cells (Solaro et al. 1995), an important implication of our results is that the properties of L- and Q-type Ca2+ channels might have important regulatory effects on action potential properties. Any second messengers that modulate the properties of L- and Q-type Ca2+ channels will also be able to dynamically regulate the extent of BK current activation and produce profound effects on cellular excitability. In fact, it is precisely because of the existence of selective coupling of particular Ca2+ channel variants to BK channel activation that modulation of Ca2+ current may be allowed to exert important effects on cellular excitability. If BK channel activation were not selectively coupled but influenced by the cumulative Ca2+ arising from all Ca2+ channel subtypes, regulation of any particular Ca2+ channel subtype would have only minimal consequences on both Ca2+ influx during action potentials and on any Ca2+-dependent process. Thus selective coupling may provide a key mechanism that enables specific modulation of certain Ca2+ channel subtypes to exert more profound physiological consequences. The advantage of employing multiple Ca2+ channel variants, in this case the L- and Q-type, which may be differentially modulated by differing signaling cascades, would be an ability to regulate cellular excitability over a wide range of environmental conditions.

Are the Ca2+ channels involved in BK current activation the same as those involved in secretion?

L- and Q-type Ca2+ channels, which we show here to be involved in BK current activation, were also implicated in the control of exocytosis in bovine and cat chromaffin cells (Artalejo et al. 1994; Lopez et al. 1994a,b). This finding raises the interesting possibility that the Ca2+ channels involved in BK current activation may also be involved in the control of secretion. In fact, in the presynaptic nerve terminals of the frog neuromuscular junction and in auditory hair cells, it was reported that Ca2+ and Ca2+-activated K+ channels are colocalized in such a way that the same Ca2+ signal that triggers transmitter release also activates BK channels (Roberts et al. 1990; Robittaile et al. 1993). Our finding that the Ca2+ channel subtypes involved in BK current activation may be the same as those implicated for catecholamine secretion raises the intriguing possibility that, analogous to these examples, Ca2+ and Ca2+-activated K+ channels may be colocalized at release sites to control exocytosis.


    ACKNOWLEDGMENTS

We thank S. Swanson for the chromaffin cell preparations and Drs. S. Mennerick, J. P. Ding, and J. H. Steinbach for helpful discussions and comments.

This work was supported by National Institute of Neurological Disorders and Stroke Grant NS-37671.


    FOOTNOTES

Address for reprint requests: C. J. Lingle, Dept. of Anesthesiology, Washington University School of Medicine, 660 S. Euclid Ave., St. Louis, MO 63110.

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

Received 12 November 1998; accepted in final form 10 February 1999.


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DISCUSSION
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0022-3077/99 $5.00 Copyright © 1999 The American Physiological Society