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INTRODUCTION |
In the nervous system, A-type K+ current (IA) plays an important role in the control of excitability, synaptic input, and neurotransmitter release (Cull-Candy et al. 1989
; Dye 1991
; Mei et al. 1995
; Sheng et al. 1993
). IA may be responsible for the initial repolarization of the action potential, contribute to afterhyperpolarization, promote pacemaker activity, and facilitate neuronal firing (Bouskila and Dudek 1995
; Chandler et al. 1994
; Connor and Stevens 1971
; Dekin 1993
; Ducreux and Puizillout 1995
; Grolleau and Lapied 1995
; MacDermott and Weight 1982
). IA has been studied in a variety of mammalian nervous tissues including sympathetic ganglia (Galvan and Sedlmeier 1984), hypothalamus and hippocampal brain slices (Bouskila and Dudek 1995
; Greene et al. 1990
; Zbicz and Weight 1985
), neonatal supraoptic nucleus neurons (Cobbett et al. 1989
), and embryonic hypothalamus neurons (Muller et al. 1992
). Electrophysiologically, IA can be identified by its unique voltage-dependent activation, fast kinetics of inactivation, and steady-state inactivation. Pharmacologically, IA is aminopyridine sensitive and has been shown to be modulated by acetylcholine, glutamate, adenosine, and
-aminobutyric acid (Akins et al. 1990
; Hay and Lindsley 1995
; Mei et al. 1995
; Saint et al. 1990
). The cloned K+ channels from rat brain, RCK4 (Kv1.4) and Raw3 (Kv3.4), have been demonstrated to give rise to A-like currents (Pongs 1992
; Schroter et al. 1991
; Stuhmer et al. 1989
).
Our previous work demonstrated that angiotensin II (Ang II), by activation of the angiotensin type 1 (AT1) receptor subtype, caused a reversible and concentration-dependent decrease in delayed rectifier K+ current (IK) in rat cultured neurons from hypothalamus and brain stem (Kang et al. 1992
; Sumners et al. 1996
). Using a brain slice preparation, Nagatomo et al. (1995)
reported that Ang II decreased the IA amplitude by 21.3 ± 3.1% (mean ± SE) in supraoptic neurons, whereas Li and Ferguson (1996)
demonstrated that by activation of AT1 receptors, Ang II reduced IA by 31.0 ± 4.1% in paraventricular nucleus cells.
The single K+ channel that underlies IA in cultured neurons has been characterized by several groups (Cooper and Shrier 1985
; Kasai et al. 1986
; Solc et al. 1987
). Cooper and Shrier (1985)
reported that in rat nodose sensory neurons A-type K+ channel conductance was ~22 pS and ensemble averaged single-channel currents had similar inactivation kinetics to that of IA. Kasai et al. (1986)
observed a 20-pS A-type K+ channel in guinea pig dorsal root ganglion cells. The conductance of single A-type K+ channels in mammalian cultured neurons was greater than that of Drosophila neurons (5-8 pS) (Solc et al. 1987
) and of cloned A-type K+ channels (4.7-14 pS) (Stuhmer et al. 1989
; Vega-Saenz de Miera et al. 1994
). To date, Ang II regulation of the single channel underlying neuronal IA has not been studied, although such modulation forms the basis for its action on whole cell currents and plays a role in modulating action potential firing patterns (see companion paper).
In this study, for the first time, we characterize a 4-aminopyridine (4-AP)-sensitive IA and the single channel underlying it in rat cultured neurons with the use of the whole cell, outside-out, and cell-attached configurations of the patch-clamp technique. Furthermore, we demonstrate that the actions of Ang II on IA and single A-type K+ channel currents are mediated through the AT1 receptor.
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METHODS |
Materials
One-day-old Sprague-Dawley rats were obtained from our breeding colony, which originated from Charles River Farms (Wilmington, MA). Losartan potassium was generously provided by Dr. Ronald D. Smith of Du Pont-Merck (Wilmington, DE). PD 123319 (AT2 receptor blocker) was purchased from Research Biochemicals (Natick, MA). Dulbecco's modified Eagle's medium (DMEM) was obtained from GIBCO (Grand Island, NY). Crystallized trypsin (xl) was from Cooper Biomedical (Malvern, PA). Plasma-derived horse serum (PDHS), cytosine arabinoside (ARC), DNase I, poly-L-lysine (molecular weight 150,000), Ang II, ATP, guanosine 5
-triphosphate, tetraethylammonium chloride (TEA), 4-AP, tetrodotoxin (TTX), CdCl2, and N-2-hydroxyethylpiperazine-N
-2-ethanesulfonic acid (HEPES) were purchased from Sigma Chemical (St. Louis, MO). All other chemicals were purchased from Fisher Scientific (Pittsburgh, PA).
Preparation of neuronal cultures
Neuronal cocultures were prepared from the brain stem and a hypothalamic block of 1-day-old Sprague-Dawley rats as described previously (Kang et al. 1992
). Trypsin (375 U/ml)- and DNase I (496 U/ml)-dissociated cells were resuspended in DMEM containing 10% PDHS and plated on poly-L-lysine-precoated 35-mm Nunc plastic tissue culture dishes. After cells were grown for 3 days at 37°C in a humidified incubator with 95% air-5% CO2, they were exposed to 1 µM ARC for 2 days in fresh DMEM containing 10% PDHS. Then ARC was removed and the cells were incubated with DMEM (10% PDHS) for a further 9-12 days before use. At the time of use, cultures consisted of 90% neurons and 10% astrocyte glia, as determined by immunofluorescent staining with antibodies against neurofilament proteins and glial fibrillary acidic proteins (Sumners et al. 1990
).
Electrophysiological recordings
Macroscopic and single-channel currents were recorded with the use of the whole cell, outside-out, and cell-attached patch-clamp configurations of the patch-clamp technique (Hamill et al. 1981
). Experiments were performed at room temperature (22-23°C) with the use of an Axopatch-200A amplifier and Digidata 1200A interface (Axon Instruments, Burlingame, CA). Cells were bathed in Tyrode's solution containing (in mM) 140 NaCl, 5.4 KCl, 2.0 CaCl2, 2.0 MgCl2, 0.3 NaH2PO4, 10 HEPES, and 10 dextrose, pH adjusted to 7.4 with NaOH. Neurons in the culture dish (volume 1.5 ml) were superfused at a rate of 2-4 ml/min. The patch electrodes (Kimax-5.1, Kimble Glass, Toledo, OH) had resistances of 3-4 M
when filled with an internal pipette solution containing (in mM) 140 KCl, 2 MgCl2, 5 ethylene glycol-bis(
-aminoethyl ether)-N,N,N
,N
-tetraacetic acid (EGTA), 4 ATP, 0.1 guanosine 5
-triphosphate, 10 dextrose, and 10 HEPES, pH adjusted to 7.2 with KOH. Cell-attached patches were formed by sealing the patch electrode to the cell body. Single-channel activity was recorded from patches with a seal resistance >5 G
. The whole cell configuration was formed by applying negative pressure to the patch electrode. For whole cell recordings, cell capacitance was canceled electronically and the series resistance (<10 M
) was compensated by 75-80%. Outside-out patches were formed by slowly elevating the patch electrode away from the cell body after formation of the whole cell configuration. A junction potential of
10 mV was corrected for all command potentials.
Sodium current (INa) was blocked by TTX (100 nM). Calcium current (ICa) was blocked by CdCl2 (100 µM). Ca2+-activated K+ current (IK,Ca) was reduced to insignificant levels by omitting CaCl2 from the pipette solution, blocking ICa with CdCl2, and buffering intracellular free Ca2+ with EGTA. In most of the experiments, IK was blocked by extracellular TEA (140 mM), which replaced the NaCl (140 mM).
To evaluate the steady-state inactivation of IA, a depolarizing test pulse to +42.5 mV (200 ms in duration) was preceded by conditioning prepulses from
102.5 to
5 mV in 7.5-mV steps (1 s in duration). IA was measured as the peak current amplitude elicited by the depolarizing test pulses and expressed as the membrane conductance [gA = IA/(VM
VE], where VM is membrane potential and VE is the K+ equilibrium potential (
82 mV) determined from the concentration gradient with the assumption that intracellular K+ was equal to pipette potassium (140 mM). In some cases, IA was converted to conductance values (nS).
In outside-out patch-clamp experiments, single A-type K+ channel activity was elicited with the use of pulses from
100 mV to various test potentials (0 to +40 mV). In cell-attached patch-clamp experiments, A-type K+ channel activity was elicited either with the use of voltage steps from +40 mV to various test potentials (
100 to 0 mV) when patch pipettes were filled with Tyrode's solution (5.4 mM KCl) or by pulses from
100 mV to various test potentials (+20 to +100 mV) when patch pipettes were filled with 140 mM KCl. For convenience, the current-voltage relationship for single-channel currents obtained from cell-attached patches was constructed by plotting single-channel current amplitude as a function of driving force (the pipette potential minus the average resting potential,
60 mV when the bath contained normal Tyrode's solution and
20 mV when the bath contained 140 mM TEA).
Data acquisition and analysis were performed with the use of pCLAMP 6.03. Whole cell currents were filtered at 1 kHz (frequency filter
3 dB) and digitized at 2 kHz. Single-channel currents were filtered at 2 kHz (frequency filter
3 dB) and digitized at 10 kHz. By convention, outward current is depicted as upward deflections of current.
Data analysis
Results are expressed as means ± SE. Statistical significance was evaluated with the use of paired t-test. Differences were considered significant at P < 0.05; n corresponds to the number of cells examined. Open probability (NPo) for single A-type K+ channels was obtained during 100-ms depolarizing pulses.
 |
RESULTS |
Neurons used for the experiments had an oval- or triangular-shaped cell body with two or three small and short processes that did not form a network with adjacent cells. The maximum diameter of the neurons was ~15-25 µm. The passive membrane input resistance of the cells was 301.4 ± 21.7 M
(n = 45). The average cell capacitance was 51.15 ± 2.1 pF (n = 73). Typical neuronal action potentials, either spontaneous or stimulated, were present in these cells (see companion paper). There were at least four transmembrane currents that underlie the depolarization and repolarization of the action potential. These are defined as 1) TTX-sensitive INa, 2) Cd2+-sensitive ICa, 3) TEA-sensitive IK, and 4) 4-AP-sensitive transient K+ current (IA). The present work focuses on the 4-AP-sensitive IA.
Isolation of IA
In normal Tyrode's solution, when INa and ICa were blocked by TTX (100 nM) and Cd2+ (100 µM), respectively, a voltage-dependent total outward current was recorded (Fig. 1A). The total outward current could be pharmacologically dissected into at least two components. When TEA (140 mM) was bath applied, significant inhibition of a delayed-rectifier-like K+ current was observed (Fig. 1B). Subtracting the current traces in Fig. 1B from those in Fig. 1A reveals an outward K+ current that is defined as a voltage-dependent, TEA-sensitive IK similar to that of the Kv class of K+ channel (Fig. 1C). The second component of outward current was sensitive to 4-AP. Bath application of 4-AP (5 mM) significantly reduced the transient portion of the outward current (Fig. 1D). Subtracting the current traces in Fig. 1D from those in Fig. 1B reveals a voltage-dependent, transient outward K+ current that was defined as a TEA-resistant and 4-AP-sensitive IA (Fig. 1E). IA activated rapidly and inactivated within 40 ms. The conductance-voltage relationship for IA is presented in Fig. 1F (n = 14).

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| FIG. 1.
Isolation of neuronal A-type K+ current (IA). Sodium current (INa) and calcium current (ICa) were blocked by tetrodotoxin (TTX, 100 nM) and Cd2+ (100 µM), respectively. Cell membrane potential was held at 90 mV. A: total outward current traces elicited by 200-ms depolarizing pulse from 35 to +42.5 mV in 7.5-mV steps following 1-s prehyperpolarizing pulse to 110 mV. B: current traces recorded in presence of external tetraethylammonium chloride (TEA, 140 mM). C: TEA-sensitive difference current [A B, mainly delayed rectifier K+ current (IK)]. D: current traces recorded in presence of TEA and 4-aminopyridine (4-AP, 5 mM). E: TEA-resistant, 4-AP-sensitive transient difference current (IA) obtained by subtracting currents recorded in presence of 4-AP from currents recorded in absence of 4-AP (i.e., B D). F: conductance-voltage relationship (current amplitude was measured as peak current during depolarizing pulse) of IA. These results are representative of 14 cells.
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| FIG. 2.
Voltage-dependent steady-state inactivation of IA. Cell membrane potential was held at 90 mV. Experiments were performed in presence of TTX (100 nM), Cd2+ (100 µM), and TEA (140 mM) in bath solution. A: representative current traces were elicited by 200-ms repetitive depolarizing pulses to +42.5 mV, which were preceded by 1-s conditioning prepulses from 102.5 to 5 mV in 7.5-mV steps in absence of 4-AP. B: current traces recorded in presence of 4-AP (5 mM). C: TEA-resistant, 4-AP-sensitive IA (A B). D: steady-state inactivation curve of IA for 14 neurons. Points: normalized mean peak conductance of IA at each test potential. Solid line is obtained by fitting mean data with Boltzmann function.
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Biophysical properties of IA
Steady-state inactivation of IA was studied in a total of 14 neurons. The steady-state inactivation current traces of IA (Fig. 2) were obtained with the use of the voltage paradigms described in the METHODS section. The peak amplitude of IA elicited by repetitive depolarizing pulses (+42.5 mV) began to decrease at conditioning potentials of
80 to
70 mV (Fig. 3, A and C). When the conditioning potential was more positive than
65 mV, steady-state inactivation became accelerated and complete inactivation occurred at a conditioning potential of
27.5 mV. The averaged steady-state inactivation data were fit with the following Boltzmann function
where gA/gA(max) is the conductance normalized to its maximum value, V is the membrane potential, V1/2 is the membrane voltage at which IA is half-maximum, and k is the Boltzmann slope factor. The averaged data, when fit with a Boltzmann function, revealed a half-steady-state inactivation potential (V1/2) of
52.2 mV and a voltage-sensitive slope factor (k) of
6.5 mV.

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| FIG. 3.
Activation and inactivation time constants of IA. A: representative IA trace ( ) elicited by depolarizing pulse from 110 to +42.5 mV. Dashed lines are obtained by fitting rising (activation) and decay phases (inactivation) of current trace with 1st-order exponential equation. B: mean data showing voltage dependence for activation time constant (n = 8). C: mean data showing voltage dependence for inactivation time constant (n = 8).
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The activation and inactivation (decay during a voltage step) time constants of the 4-AP-sensitive IA were studied in eight neurons. Figure 3A shows a representative trace of IA during a 200-ms depolarizing voltage step from
110 to +42.5 mV. The activation (rising) and the inactivation (decaying) phases of the current were fit best by a single-exponential equation
where I is the amplitude of IA at time t, Imax is the peak IA at time 0, and
is the time constant for activation or inactivation. In this experiment, activation and decay time constants were 1.4 and 14.3 ms, respectively. The mean values of activation and inactivation time constants for a depolarizing pulse to +20 mV were 2.1 ± 0.3 ms and 13.6 ± 1.9 ms, respectively.
The time to reach peak activation of IA was voltage dependent (Fig. 3B). The greater the depolarization, the faster IA activated. For example,
was equal to 4.0 ± 0.6 ms during a depolarizing pulse to +5 mV but was only 1.1 ± 0.1 ms during a voltage step to +42.5 mV. In comparison, the inactivation (decay) time constant of IA was voltage dependent only when the depolarizing potential was more negative than 0 mV. When the depolarizing test potential was more positive than 0 mV, the decay time constant showed little voltage dependence (Fig. 3C).

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| FIG. 4.
A-type K+ channel activity in physiological K+ gradient obtained from cell-attached patches. A: single-channel currents recorded from patch in physiological external K+ solution [concentration of K+ in the pipette ([ K+]pip) = extracellular K+ concentration ([K+]o) = 5.4 mM]. Experiments were performed in presence of TTX (100 nM), Cd2+ (100 µM), and TEA (140 mM) in bath solution. Currents were activated by depolarizations to different potentials (as indicated), which were preceded by 1-s hyperpolarizing pulses to 100 mV. B: current-voltage relationship from 4 patches. Chord conductance was measured by linear regression through data. , single-channel conductance.
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Single-channel characteristics of 4-AP-sensitive IA
Single neuronal A-type K+ channel currents were recorded from both cell-attached and outside-out patches. In a physiological external K+ solution [K+ concentration in the pipette ([K+]pip) = extracellular K+ concentration ([K+]o) = 5.4 mM], A-type K+ channel activity occurred when the patch of membrane was depolarized to a potential more positive than
40 mV (Fig. 4A). Under these conditions, the single-channel conductance was 15.8 ± 1.3 pS(n = 4) and the extrapolated reversal potential was
85.2 ± 1.7 mV (n = 4, Fig. 4). This is close to the predicted equilibrium potential of K+ calculated with the use of the Nernst equation. Figure 5 illustrates biophysical and pharmacological fingerprints of single A-type K+ channel currents recorded from outside-out patches. During a voltage step from
100 to +40 mV, rapidly activating and inactivating channels were observed. The current trace illustrated in Fig. 5A is an ensemble average of 30 traces. The inactivation time constant of the ensemble averaged single-channel currents in this experiment was 16.7 ms and the average was 16.1 ± 4.2 ms (n = 4), which was similar to the decay time constant of IA at +42.5 mV (15.3 ± 3.4 ms, Fig. 3). To pharmacologically fingerprint these inactivating channels, 4-AP (5 mM) was added to the bathing solution. 4-AP significantly decreased the activity of A-type K+ channels without affecting the single-channel current amplitude (Fig. 5B). On the basis of the above biophysical and pharmacological data, it is concluded that the activity of these 4-AP-sensitive, rapidly activating and inactivating single K+ channels underlies IA.

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| FIG. 5.
Voltage-dependent activation and 4-AP sensitivity of single A-type K+ channels in outside-out patches. Patches were bathed in solution containing TTX (100 nM), Cd2+ (100 µM), and TEA (140 mM) and held at potential of 60 mV. A: ensemble average currents of single A-type K+ channels activated by depolarizing step from 100 to 42.5 mV. This is representative of 5 cells. B: single-channel activities in an outside-out patch, which was elicited by voltage step to +20 mV in absence (left) and presence (right) of 4-AP (5 mM). Recordings were from same cell. This is representative of 5 cells.
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Ang II regulation of IA
We next examined the pharmacological regulation of IA by Ang II in the presence of the AT2 receptor antagonist PD 123319 (1 µM). PD 123319 had no effect on baseline K+ current or channel activity. Ang II, when superfused into the recording chamber, significantly reduced IA in a dose-dependent manner (Fig. 6, A and B, asterisk: P < 0.01, n = 12 for Ang II (100 nM), n = 5 for the other concentrations). Therefore we chose to use a maximum effective dose of Ang II, 100 nM, in the rest of our experiments. Ang II (100 nM) reduced peak IA and shifted the activation curve to the right in eight neurons tested (Fig. 7). Figure 7A shows a representative experiment in which Ang II decreased the peak amplitude of IA elicited by depolarizing test pulses from a holding potential of
110 mV to +20 mV. The effect of Ang II was reversed by addition of the selective AT1 receptor antagonist losartan (1 µM) to the superfusate solution. The mean data for the Ang II-mediated decrease in IA are illustrated in Fig. 7, B and C. Ang II caused a decrease of ~20% in IA at +20 mV (Fig. 7B). Ang II also shifted the IA conductance-voltage relationship ~8-15 mV to the right (Fig. 7C).

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| FIG. 6.
Dose-dependent effect of angiotensin II (Ang II) on IA. A: IA recorded from neuron in presence of TTX (100 nM), Cd2+ (100 µM), and TEA (140 mM) in Tyrode's solution. Traces 1-4: control and superfusion of 1, 10, and 100 nM Ang II, respectively. B: graph showing mean data for Ang II-mediated, dose-dependent decrease in peak IA from 5 neurons. Asterisk: P < 0.01.
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| FIG. 7.
Effect of Ang II on current-voltage relationship of IA. A: IA recorded from neuron in presence of TTX (100 nM), Cd2+ (100 µM), and TEA (140 mM). Ang II (100 nM) decreased IA during voltage step from 110 mV to +20 mV. B: mean effect of Ang II and losartan (1 µM) on IA density. C: Ang II shifts conductance-voltage relationship of IA ~8-15 mV to right (n = 8).
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Cell-attached patches were used to evaluate the ability of Ang II to modulate the activity of A-type K+ channels. Figure 8 shows representative single-channel current traces and ensemble averaged currents of A-type K+ channels recorded in the absence and presence of Ang II (100 nM). Single-channel activity was elicited by a voltage step of +100 mV (Vpip
VM = 100 mV). There were two A-type K+ channels in this patch that activated at the beginning of the step and inactivated after ~40 ms (Fig. 8, left). Ang II markedly reduced the activity of A-type K+ channels without affecting the single-channel current amplitude (Fig. 8, middle). Similar to the effects on IA, the actions of Ang II were reversed either on washout (Fig. 8, right) or by addition of losartan (1 µM) to the superfusate solution (data not shown). The ensemble averaged current is illustrated below the single-channel current traces and reflects control, application of Ang II, and washout, respectively. The ensemble averaged data are markedly similar to those data for Ang II regulation of IA illustrated in Fig. 7. Similar results were observed in four other cell-attached patches. Figure 9 illustrates the effects of Ang II on single-channel NPo. The data in Fig. 9 were used to generate amplitude histograms and calculate NPo. Under control conditions, in the presence of Ang II (100 nM), and after washout, NPo was 0.21, 0.10, and 0.16, respectively. The mean values for NPo under these conditions were 0.22 ± 0.04, 0.10 ± 0.08, and 0.17 ± 0.11, respectively (n = 4).

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| FIG. 8.
Effects of Ang II on single IAs recorded from cell-attached patches. Experiments were performed under same conditions as Fig. 4. Currents were activated by driving force of +100 mV (Vpip membrane potential = +100 mV). Left: control single-channel currents and ensemble average current. Middle: effects of bath application of Ang II (100 nM) on single-channel activity and ensemble average current. Right: recovery on washout of Ang II. This is representative of 4 experiments.
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| FIG. 9.
Ang II decreases open probability (NPo) of A-type K+ channels. Single-channel analysis was performed on recordings from Fig. 8. NPo in control, in presence of Ang II (100 nM), and after washout was 0.21, 0.10, and 0.16, respectively. Note that Ang II did not alter single-channel amplitude of A-type K+ channels.
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DISCUSSION |
The transient outward K+ current reported here was defined as a TEA-resistant, 4-AP-sensitive A current (IA). This conclusion was based on the following criteria. First, under our experimental conditions, INa, ICa, IK, and IK,Ca were blocked by TTX, Cd2+, TEA, and internal EGTA, (5 mM) respectively. Second, the voltage dependence and the kinetics of activation and inactivation of IA were similar to previously published results (Figs. 1-3) (Bouskila and Dudek 1995
; Mei et al. 1995
). Finally, the single-channel conductance demonstrated for channels that underlie IA was similar to that reported for other neuronal preparations (Figs. 4 and 5) (Cooper and Shrier 1985
; Kasai et al. 1986
).
This study also demonstrated that Ang II, via activation of AT1 receptors, reduced IA and decreased the activity of a 15-pS, rapidly inactivating, 4-AP-sensitive K+ channel (Figs. 8 and 9). Our previous studies showed that hypothalamus and brain stem neuronal cocultures contained ~70% AT2 and ~30% AT1 receptors (Sumners and Raizada 1993
; Sumners et al. 1991
, 1994
). We previously determined that activation of AT1 receptors by Ang II decreases net outward current via inhibiting IK and stimulating ICa, which was dependent on protein kinase C activation (Sumners et al. 1996
). Our recent study also showed that intracellular injection of a 25-amino-acid peptide corresponding to the third intracellular loop of the cloned AT1a receptor (AT1a/i3) elicited changes in IK and ICa that were similar to those obtained with application of Ang II via AT1 receptors. By contrast, injection of a 19-amino-acid peptide corresponding to the second intracellular loop did not modulate IK or ICa. Importantly, our data elucidated that the modulation of neuronal IK and ICa by AT1a/i3 involves protein kinase C, inositol-(1,4,5)-trisphosphate (IP3), and intracellular Ca2+, similar to the AT1 receptor modulation of IK and ICa by Ang II (Zhu et al. 1997
). These effects are consistent with the increases in neuronal activity observed following AT1 receptor activation (Ambuhl et al. 1992
; Yang et al. 1992
). Combined with our present findings, we suggest that by potentiating ICa and diminishing IK and IA, Ang II increases the excitability of neurons from the hypothalamus and brain stem. This too is consistent with our recent observation that Ang II increases the spontaneous firing rate of the cultured neurons (see companion paper).
Ang II produced three important biophysical, physiological, and pharmacological effects. First, similar to its effects on IK (Sumners et al. 1996
), Ang II decreased IA by ~25%. One explanation for this result may be that there are a number of different A-type K+ channels in which one type is sensitive to Ang II. This is possible, because multiple K+ channel transcripts representing rapidly inactivating K+ channels have been found in the brain (e.g., Kv1.4, Kv4.1-4.3, Vega-Saenz de Miera et al. 1994
). Second, Ang II shifted the IA conductance-voltage relationship in the rightward direction. This would cause an increased amplitude of the neuronal action potential as well as altering firing patterns (see companion paper). These two effects would allow more net calcium influx into the nerve and could produce an increase in neurotransmitter release. The hypothalamus/brain stem is important in the central regulation of blood pressure. In these cocultures Ang II has been shown to increase norepinephrine release (Sumners et al. 1990
, 1991
, 1994
). Therefore an increase in central norepinephrine release would play a significant role in the regulation of fluid volume and therefore blood pressure. Third, Ang II decreased IA single-channel activity without affecting single-channel conductance. The physiological significance of this in the CNS would be similar to shifting the conductance-voltage relationship to the right: an increase neuronal firing patterns. The peripheral significance in cells that contain an A current and Ang II receptors (i.e., vascular smooth muscle) would be an increase in vascular smooth muscle tone and peripheral resistance.
Biophysically and pharmacologically, we have also characterized IA and single A-type K+ channels from these neurons. IA and single A-type K+ channels showed voltage-dependent activation and steady-state inactivation parameters similar to those reported previously (Bouskila and Dudek 1995
; Cooper and Shrier 1985
; Kasai et al. 1986
; Mei et al. 1995
). However, IA and single A-type K+ channels recorded in this study displayed different inactivation kinetics when compared with the results of Cooper and Shrier (1985)
and Kasai et al. (1986)
. Our present results show that IA and single A-type K+ channels had time constants of inactivation of 14 ms (Fig. 3) and 15 ms (Fig. 5), respectively. Data from Cooper and Shrier (1985)
and Kasai et al. (1986)
show that IA and single A-type K+ channels had inactivation time constants of 30 and 100 ms, respectively. The similarity in steady-state inactivation and differences in inactivation kinetics during a voltage step in different neuronal preparations may be due to specific molecular mechanisms involving the coexistence of N-type and C-type inactivation mechanisms in A-type K+ channels (Armstrong and Bezanilla 1977
; Baukrowitz and Yellen 1995
; Choi et al. 1991
; Grissmer and Cahalan 1989
; Yellen et al. 1994
; Zagotta et al. 1990
).
The conductance of single A-type K+ channels recorded under the cell-attached configuration is related to the transmembrane potassium gradient. It is well accepted that the A-type K+ channels have a small conductance (~15-20 pS, Fig. 4) (Rudy 1988
) in a physiological K+ gradient ([K+]pip = 5.4 mM). Finally, pharmacologically IA and single A-type K+ channels from neurons of the hypothalamus and brain stem resemble other neurons in their 4-AP sensitivity. Kasai et al. (1986)
reported that 4-AP blocked A-type K+ channels from the inside of the cell by diffusing through the membrane. We also observed that bath application of 4-AP could inhibit IA (Fig. 1) and single A-type K+ channel activity recorded in outside-out patches (Fig. 5).
In summary, we have characterized a TEA-resistant, 4-AP-sensitive IA and the single channel underlying it in rat cultured neurons with the use of whole cell, outside-out patch, and cell-attached patch configurations. We have also shown that Ang II, through activation of AT1 receptors, inhibits IA and single A-type K+ channels. The Ang II regulation of neuronal IA is one of the bases for its physiological actions through changes in action potential firing patterns in the brain. Future experiments will include the elucidation of the signal transduction mechanism(s) involved in Ang II regulation of IA.