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The Journal of Neuroscience, May 1, 2002, 22(9):3404-3413
Selective Coupling of T-Type Calcium Channels to SK Potassium
Channels Prevents Intrinsic Bursting in Dopaminergic Midbrain
Neurons
Jakob
Wolfart and
Jochen
Roeper
Medical Research Council, Anatomical Neuropharmacology Unit,
Department of Pharmacology, Oxford University, Oxford OX1 3TH, United
Kingdom
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ABSTRACT |
Dopaminergic midbrain (DA) neurons display two principal activity
patterns in vivo, single-spike and burst firing, the
latter coding for reward-related events. We have shown recently
that the small-conductance calcium-activated potassium channel SK3 controls pacemaker frequency and precision in DA neurons of the substantia nigra (SN), and previous studies have implicated SK channels
in the transition to burst firing. To identify the upstream calcium
sources for SK channel activation in DA SN neurons, we studied the
sensitivity of SK channel-mediated afterhyperpolarization (AHP)
currents to inhibitors of different types of voltage-gated calcium
channels in perforated patch-clamp recordings. Cobalt-sensitive AHP
currents were not affected by L-type and P/Q-type calcium channel
inhibitors and were reduced slightly (26%) by the N-type channel
inhibitor  -conotoxin-GVIA. In contrast, AHP currents were blocked
substantially (85-94%) by micromolar concentrations of nickel
(IC50, 33.75 µM) and mibefradil
(IC50, 4.83 µM), indistinguishable from the nickel and mibefradil sensitivities of T-type calcium currents
(IC50 values, 33.86 and 4.59 µM,
respectively). These results indicate that SK channels are activated
selectively via T-type calcium channels in DA SN neurons. Consequently,
SK currents displayed use-dependent inactivation with similar time
constants when compared with those of T-type calcium currents and
generated a transient rebound inhibition. Both SK and T-type channels
were essential for the stability of spontaneous pacemaker activity, and, in some DA SN neurons, T-type channel inhibition was sufficient to
induce intrinsic burst firing. The functional coupling of SK to T-type
channels has important implications for the temporal integration of
synaptic input and might help to understand how DA neurons switch
between pacemaker and burst-firing modes in vivo.
Key words:
dopamine; substantia nigra (A9); electrophysiology; apamin; nifedipine; agatoxin-TK; FTX-3.3; amphotericin; cyclopiazonic
acid (CPA)
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INTRODUCTION |
Dopaminergic midbrain (DA) neurons
are important for voluntary movement, cognition, and reward and are
implicated in major disorders such as schizophrenia and Parkinson's
disease (Dunnett and Bjorklund, 1999 ; Goldman-Rakic, 1999; Carlsson et
al., 2000; Wise, 2000). In vivo, DA neurons show two
principal patterns of activity: they either fire in regular or
irregular single-spike mode or discharge bursts of action potentials
(Wilson et al., 1977; Grace and Bunney, 1984a,b; Sanghera et al., 1984;
Freeman et al., 1985). Burst-firing episodes code for the unpredicted rewarding aspects of environmental stimuli and thus might constitute a
mechanism for reward-based learning (Schultz, 2000; Reynolds et al.,
2001). During burst firing, dopamine release is increased phasically in
striatal (Gonon and Buda, 1985) and cortical (Bean and Roth, 1991)
target areas of DA neurons, whereas tonic release during pacemaker
firing controls the background of dopamine levels that, among other
functions, regulates the intensity of the phasic burst-firing signal
(Grace, 1991; Overton and Clark, 1997). Because changes in the degree
and/or pattern of dopamine signaling have been implicated in the
pathophysiology of Parkinson's disease and schizophrenia (Dunnett and
Bjorklund, 1999; Grace, 2000; Svensson, 2000), it is critical to
understand better the cellular mechanisms that control the transition
between pacemaker and burst firing in DA neurons.
Unlike thalamic neurons (Huguenard, 1998), DA neurons show only
pacemaker spiking and no spontaneous burst firing in in
vitro preparations (Sanghera et al., 1984; Kita et al., 1986;
Grace and Onn, 1989; Wolfart et al., 2001). Thus, it generally is
assumed that a particular type of synaptic activity, which is present only in vivo, is necessary for DA neurons to switch into
burst mode. In this context NMDA receptor activation (Johnson et al., 1992), GABAA receptor-mediated disinhibitory
processes (Paladini and Tepper, 1999), and modulation of postsynaptic
conductances (Kitai et al., 1999) have been proposed as candidate
mechanisms. In particular, apamin-sensitive, small-conductance,
calcium-activated potassium (SK) channels (Blatz and Magleby, 1987;
Kohler et al., 1996; Sah, 1996) have been reported to facilitate
synaptically mediated burst induction (Seutin et al., 1993; Johnson and
Seutin, 1997) or, in some cases, to be sufficient to induce bursting
in vitro (Shepard and Bunney, 1988, 1991; Gu et al., 1992;
Ping and Shepard, 1996). Furthermore, we have shown recently that SK3
channels control the frequency and precision of pacemaker spiking in DA neurons of the substantia nigra (SN), but not in a subpopulation of DA
neurons in the ventral tegmental area (Wolfart et al., 2001).
SK channels form a signaling complex with calmodulin as a calcium
detector, and channel opening depends solely on submembrane changes of
the intracellular calcium concentration (Xia et al., 1998). All major
classes of voltage-gated calcium (Cav) channels (Nowycky et al., 1985; Llinas et al., 1989; Ertel et al., 2000) are
present in DA SN cells (Kang and Kitai, 1993b; Stea et al., 1994;
Williams et al., 1994; Cardozo and Bean, 1995; Craig et al., 1999;
Talley et al., 1999; Takada et al., 2001) and could, in principle,
contribute to SK channel activation. However, preferential coupling of
SK channels to particular Cav channels has been
reported to be present in other neurons (Wisgirda and Dryer, 1994;
Marrion and Tavalin, 1998; Sah and Davies, 2000; Bowden et al., 2001). In addition, calcium signals generated by Cav
channels might be amplified by secondary calcium release from
intracellular stores, which also has been shown to activate SK channels
in various cell types (Yoshizaki et al., 1995; Davies et al., 1996;
Tanabe et al., 1998; Cordoba-Rodriguez et al., 1999). Indeed, in DA
neurons SK channels can be activated by intracellular calcium release evoked via metabotropic glutamate receptors (Morikawa et al., 2000;
Seutin et al., 2000). Because there is increasing evidence that the
functional pool of SK channels in DA neurons controls pacemaker
stability and potentially is involved in the still elusive burst
transition (Shepard and Bunney, 1988, 1991; Gu et al., 1992; Ping and
Shepard, 1996; Wolfart et al., 2001), in the present study we aimed to
characterize the upstream regulation of SK channel activity in DA SN neurons.
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MATERIALS AND METHODS |
Slice preparation. Procedures involving animals were
conducted in accordance with the Animals (Scientific Procedures) Act, 1986 (UK) and with the Society for Neuroscience policy on the use of
animals in research. C57BL/6J mice (Charles River, Margate, UK; 10-14
postnatal d old) were killed by cervical dislocation. Brains were
removed quickly, immersed in ice-cold artificial CSF (ACSF), and then
blocked for sectioning. Thin (250 µm) coronal midbrain slices were
collected with a Vibroslice (Campden Instruments, London, UK) in
ice-cold ACSF containing (in mM) 125 NaCl, 25 NaHCO3, 2.5 KCl, 1.25 NaH2PO4, 2 CaCl2, 2 MgCl2, and 25 glucose, oxygenated with a mixture of 95% O2/5%
CO2. After sectioning, midbrain slices were
maintained submerged in oxygenated ACSF and were allowed to recover for
>30 min before the experiment. Midbrain slices containing a clearly
defined substantia nigra pars compacta (SN) at the level of the rostral
interpeduncularis nucleus and the caudal mamillary nucleus were used
for the experiments.
Electrophysiological recordings. For patch-clamp recordings
the midbrain slices were transferred to a recording chamber and perfused continuously at 2-4 ml/min with oxygenated ACSF at room temperature (22-24°C, except see below). Recordings were made from
SN neurons visualized by infrared differential interference contrast
video microscopy with a Newvicon camera (C2400; Hamamatsu, Hamamatsu
City, Japan) mounted to an upright microscope (Axioskop FS; Zeiss,
Oberkochen, Germany). Records were digitized at 2-5 kHz and low-pass
filtered before acquisition (Bessel characteristic of 1 kHz cutoff
frequency). Patch pipettes were pulled from borosilicate glass
(GC150TF/F; Harvard Apparatus, UK) with tip resistances between 2 and 5 M when filled with patch solution. For perforated patch-clamp
recordings the patch pipettes were tip filled with a solution
containing (in mM) 140 KMeSO4, 5 KCl,
10 HEPES, 0.1 EGTA, and 2 MgCl2, pH 7.35, and
backfilled with the same solution containing amphotericin B (0.4 mg/ml). For current- and hybrid-clamp (Pennefather et al., 1985)
recordings the perforated whole-cell configuration was used (except see
below). After G seal formation the perforation was monitored until a
stable level of action potential (AP) amplitudes was reached. To elicit
and record afterhyperpolarization (AHP) currents under voltage-clamp
conditions, we used short (20 msec) unclamped ("hybrid")
depolarizations (from  10 to +100 mV; holding and recording potential,
60 mV). For the AHP current recordings shown in Figure 3A,
the conditions described previously were used (Wolfart et al., 2001).
Current-clamp recordings were conducted either at 22-24°C or at
36-37°C, and no difference in spiking pattern was found, except that
AP frequencies were increased (see Table 1). Therefore, data recorded
in both temperatures were pooled for the apamin plus nickel treatment
shown in Figure 5. For extracellular local (<50 µm)
application of drugs, the cells were perfused at a flow rate of 50-100
µl/min under visual control with the use of a quartz pipette (inner
tip diameter, 0.25 mm) attached to a second manipulator and a syringe
pump system (World Precision Instruments, Sarasota, FL). Switching
between control and drug-containing solutions was controlled by an
automated application system (AutoMate Scientific, Oakland, CA). The
application solution for perforated patch recordings contained (in
mM) 145 NaCl, 2.5 KCl, 10 HEPES, 2 CaCl2, 2 MgCl2, and 25 glucose plus 50 µM picrotoxin and 50 µM kynurenic acid, pH 7.4. For the recording of
low voltage-activated calcium (LVA) currents the standard whole-cell configuration was used, and patch pipettes were filled with a solution
containing (in mM) 140 TEA-Cl, 10 HEPES, 10 EGTA,
and 2 MgCl, pH 7.35. Uncompensated series resistances were 8-20 M in recordings for kinetic analysis. Dopaminergic SN neurons were identified by their characteristic low frequency firing by using either
the cell-attached or the whole-cell patch-clamp configuration. The
application solution for LVA calcium current recordings contained (in
mM) 145 TEA-Cl, 2.5 CsCl, 10 HEPES, 2 CaCl2, 2 MgCl2, 25 glucose, and 4 4-aminopyridine plus (in µM) 50 picrotoxin, 50 kynurenic acid, 0.5 tetrodotoxin, 10 nifedipine, and 10 nM -conotoxin-GVIA. The holding potential was
100 mV, and the test pulse for drug applications was 50 mV. No leak
subtraction was used in these recordings. The steady-state membrane
potential of half-maximal activation
(V1/2act) was determined by 1-sec-long
voltage steps (5 mV) from 80 to 30 mV from a holding potential of
100 mV. The steady-state membrane potential of half-maximal
inactivation (V1/2inact) was determined by
a 3-sec-long conditioning voltage step from 120 to 40 mV and a test
pulse to 50 mV. The tail current protocol used to characterize
deactivation contained a prepulse pulse to 50 mV and test potentials
from 120 to 80 mV. Lipophilic substances (cyclopiazonic acid,
amphotericin, picrotoxin, kynurenic acid, and nifedipine) were
dissolved in DMSO and diluted 1:1000 to final concentrations.
Nifedipine, -conotoxin-GVIA, agatoxin-TK, FTX-3.3, and cyclopiazonic
acid were obtained from Alomone Labs (Jerusalem, Israel). Mibefradil
was a gift from Roche (Basel, Switzerland). All other substances were
obtained from Sigma (Dorset, UK). The EPC-9 patch-clamp amplifier and
program package PULSE+PULSEFIT (HEKA Electronics, Lambrecht, Germany) were used for data acquisition.
Data analysis. For analysis and plotting, the software
IgorPro (WaveMetrics, Lake Oswego, OR) was used. Time constants of AHP
and LVA current inactivation were determined by fitting mono- or
double-exponential functions to 1- to 5-sec-long current traces, respectively. Steady-state activation and inactivation parameters were
obtained by fitting Boltzmann functions to the data. Coefficients of
variation (CVs) were obtained by dividing the SD of the interspike interval (ISI) distribution (fit to a Gaussian function) by the mean
ISI and expressed as a percentage. Drug sensitivities of AHP currents
were determined as the average response of three to five steady-state
traces in comparison to the average control amplitudes (3-5 traces).
Drug sensitivities of transient LVA currents were determined either as
above (stable recordings) or by prediction of rundown via linear
regression fits (LVA currents with linear rundown kinetics). To
determine the dose-response relationships for nickel and mibefradil as
well as the degrees of residual drug-insensitive components, we fit the
respective mean data to Hill equations. For spiking pattern analysis a
burst detecting algorithm was programmed that compared all ISIs of a
5-min-long recording trace with its mean spiking rate and detected the
coincidence of a short ISI (<0.5 × mean rate) with a long ISI
(>1.25 × mean rate) within two to seven consecutive spikes and
marked it as a "burst" (Grace and Bunney, 1984b). Intervals within
the burst were validated additionally by a Poisson surprise mechanism
that compared ISIs with the Poisson distribution of all ISIs of a
recording (Legendy and Salcman, 1985). Spikes within bursts were summed
up and normalized to the total number of spikes in the trace (bursting
in percentage values). The outcome of the burst analysis was optimized
until only unambiguous burst-firing patterns resulted in values above 75% bursting and thus were well separated from irregular firing with
occasional burst-like events. AHP current traces (see Figs. 1-3)
represent averages from three to five filtered (300 Hz) traces. To
evaluate statistical significance (*p < 0.05;
**p < 0.05; ***p < 0.0005), we
subjected the data to paired or unpaired Student's t tests
in Microsoft Excel. Numbers, symbols, and
columns with error bars represent means ± SEM.
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RESULTS |
SK channel-mediated AHP currents are activated preferentially by
calcium channels with high nickel and mibefradil sensitivities
DA neurons recorded in the SN showed slow pacemaker firing (1-3.5
Hz) with single APs followed by large AHPs, consistent with our
previous recordings from tyrosine hydroxylase-immunopositive SN cells
(Wolfart et al., 2001) and the biophysical fingerprint of DA SN neurons
(Grace and Onn, 1989; Richards et al., 1997). Similar to our previous
study, SK-mediated AHP currents were evoked by hybrid-clamp
depolarizations (Wolfart et al., 2001), using the perforated
patch-clamp configuration to preserve physiological calcium handling.
AHP currents evoked by 20 msec hybrid pulses to approximate single APs
were small sized (Fig. 1; 27 ± 1.8 pA; range, 9-80 pA; n = 58) but
stable throughout the experiment and decayed monoexponentially with a
time constant of 75-208 msec (123 ± 4 msec; n = 58). As shown previously, these AHP currents were inhibited by the bee
venom toxin apamin, which is a selective blocker of SK channels (Blatz
and Magleby, 1987; Kohler et al., 1996; Wolfart et al., 2001) (residual
current in 300 nM apamin, 12 ± 3%;
n = 8; data not shown). In contrast, slow AHPs after 5-sec-long depolarizations (to mean potentials between 15 and +6 mV)
that included multiple APs were not affected by 300 nM apamin (n = 6; data not
shown).
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Figure 1.
Sensitivity of hybrid-clamp-evoked SK
channel-mediated AHP currents (I-AHP) to inhibitors of
Cav channels recorded in the perforated whole-cell
configuration. A, Low micromolar concentrations (100 µM) of nickel (T-type) reversibly inhibited most of the
cobalt-sensitive I-AHP. B, -Conotoxin-GVIA
(conotoxin; 1 µM) reversibly reduced a
minor part of the cobalt-sensitive I-AHP. C,
Nifedipine (10 µM) did not affect I-AHPs.
D, FTX-3.3 (1 µM) had no effect on I-AHPs.
E, The summary of experiments in A-D
shows that cobalt-sensitive I-AHPs were activated preferentially via
calcium channels sensitive to low micromolar nickel (100 µM; 85 ± 9%; n = 13;
***p < 0.0005) and mibefradil (mib; 10 µM; 94 ± 10%; n = 6;
**p < 0.005), whereas only a small component was
sensitive to 1 µM -conotoxin-GVIA
(cono; 26 ± 3%; n = 4;
**p < 0.005). Nifedipine (nif; 10 µM) did not affect I-AHPs (residual current, 102 ± 6%; n = 6; p > 0.05). Similarly, 1 µM FTX-3.3 (FTX; residual current, 97 ± 5%; n = 5; p > 0.05) and 0.1 µM agatoxin-TK (aga; residual current,
101 ± 1%; n = 3; p > 0.05) had
no effect on I-AHPs. Current amplitudes were normalized to
cobalt-sensitive I-AHP in each individual experiment except for
mibefradil, in which the mean value of cobalt block was used (1 mM; residual current, 29 ± 4%; n = 29). Calibration: A-D, 0.2 sec, 10 pA.
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We used a panel of established selective and nonselective inhibitors of
Cav channels to define which of the different
types (L-, P/Q-, N-, R-, and T-type) of neuronal
Cav channels were involved in SK channel
activation (Nowycky et al., 1985; Llinas et al., 1989; Zhang et al.,
1993; Tsien et al., 1995; Randall, 1998; Miller, 2001). AHP currents
evoked by 20 msec hybrid pulses were inhibited by 1 mM
cobalt (Fig. 1A-D; residual current, 29 ± 4%;
n = 29), indicating that activation of
Cav channels is essential for the recruitment of
SK channels in DA SN neurons. Consistent with our previous results
(Wolfart et al., 2001), the presence of a residual cobalt-insensitive
AHP current suggests that a minor part of the AHP current is
independent of hybrid pulse-mediated calcium influx via
voltage-activated calcium channels. To focus on the role of voltage-activated calcium influx for SK channel activation, we normalized the effects of Cav inhibitors to the
cobalt-sensitive component of the AHP current amplitude in each
individual experiment. Nickel is an nonselective inhibitor of calcium
channels, but transient low voltage-activated (LVA) T-type (Perez-Reyes
et al., 1998; Perchenet et al., 2000) and high voltage-activated (HVA)
R-type (Soong et al., 1993; Schneider et al., 1994)
Cav channels are particularly sensitive
(IC50, <50 µM), whereas
other HVA Cav channels (L-, P/Q-, and N-type) are
less sensitive (IC50, >90
µM) (Zhang et al., 1993; Randall, 1998). Figure
1A shows a recording of hybrid-evoked AHP currents
during control and nickel (100 µM) application
and subsequent cobalt (1 mM) application. The
main component of the cobalt-sensitive AHP current was blocked by low
micromolar concentrations of nickel. Most of the AHP current was also
sensitive to mibefradil (Fig. 1E; 10 µM), a drug that inhibits T-type calcium
channels in low micromolar concentrations (Martin et al., 2000;
Perchenet et al., 2000). Thus, cobalt-sensitive AHP currents were
blocked almost completely either by 100 µM
nickel (Fig. 1E; residual current, 15 ± 4%;
n = 13) or 10 µM mibefradil
(Fig. 1E; residual current, 6 ± 10%;
n = 6). In contrast, the snail toxin -conotoxin-GVIA (ctx-GVIA; 1 µM), an N-type calcium channel
inhibitor (Williams et al., 1992a; Randall, 1998), reduced the AHP
current only to a small degree (Fig. 1B,E; residual
current, 77 ± 2%; residual cobalt-sensitive current, 74 ± 3%; n = 4), indicating a possible minor role for
N-type channels in SK channel activation. AHP currents were completely
unaffected by 10 µM nifedipine, a
dihydropyridine that inhibits L-type channels (Tanabe et al., 1987;
Williams et al., 1992b; Randall, 1998) (Fig. 1C,E; residual
current, 102 ± 6%; n = 6). Previous studies have
shown that nifedipine indeed does inhibit L-type currents and affects
AP discharge or high voltage-activated depolarizations in DA neurons
(Kang and Kitai, 1993a,b; Nedergaard et al., 1993; Mercuri et al.,
1994; Cardozo and Bean, 1995; Ping and Shepard, 1999; Shepard and
Stump, 1999). Funnel web spider toxins that block P/Q-type channels
(Mori et al., 1991; Randall, 1998), such as FTX-3.3 (Dupere et al.,
1996) (Fig. 1D,E; 1 µM;
residual current, 97 ± 5%; n = 5), as well as agatoxin-TK (Teramoto et al., 1993) also had no effect on AHP currents
(Fig. 1E; residual current, 101 ± 1%;
n = 3).
Because there is evidence that receptor-mediated calcium release from
intracellular stores activates SK channels in DA neurons (Morikawa et
al., 2000; Seutin et al., 2000) and other types of cells (Yoshizaki et
al., 1995; Davies et al., 1996; Tanabe et al., 1998; Cordoba-Rodriguez
et al., 1999), we assessed the contribution of calcium released from
intracellular stores to AHP currents evoked by hybrid pulse-mediated
activation of plasmalemmal Cav channels.
Cyclopiazonic acid (CPA; 10 µM), an agent used to block intracellular calcium release by inhibiting endoplasmatic reticulum calcium ATPases (Taylor and Broad, 1998), reduced AHP currents by
77 ± 7% (n = 4; data not shown). Thus the
inhibition of intracellular calcium release and the inhibition of
Cav channels reduced AHP currents to a similar
degree. These results suggest that intracellular calcium release acts
downstream of plasmalemmal Cav channels and amplifies their calcium signal. In summary, our data demonstrate a
selective role for calcium channels with high nickel and mibefradil sensitivity in SK channel activation in DA SN neurons.
SK channel-mediated AHP currents and T-type calcium channels
possess almost identical nickel and mibefradil sensitivities in DA SN
neurons
The pharmacological profile of AHP currents indicated that T-type
Cav channels might be the primary calcium source
for SK channel activation after an action potential. Consequently,
T-type calcium currents should possess similar nickel and mibefradil sensitivities compared with those of SK currents. To elicit T-type currents, we applied voltage step protocols from hyperpolarized holding
potentials in the standard whole-cell configuration while blocking
other calcium and potassium channels (see Materials and Methods). These
protocols elicited typical LVA T-type calcium currents (Figs.
2C,D,
3B) (Kang and Kitai, 1993b; Perez-Reyes et al., 1998) that activated at negative membrane potentials (rise time, 23.3 ± 0.9 msec, n = 51;
V1/2act, 56.3 mV, slope = 4.9, n = 18; V1/2inact, 78.3
mV, slope = 5.3, n = 12; data not shown), had
amplitudes in the range of 50-750 pA (268 ± 23 pA;
n = 51), and inactivated with major fast (45.0 ± 2.0 msec; n = 51) and minor slow time constants
(30.0 ± 2.6%; 242 ± 14 msec; n = 51). Deactivation time constants were in the range of 4-7 msec, as determined by tail current protocols (120 mV, 4.7 ± 0.6 msec; 100 mV, 5.9 ± 0.6 mV; 80 mV, 7.0 ± 0.9 msec;
n = 9; data not shown) (see Materials and Methods).
These results are consistent with the transient LVA calcium currents
previously reported in rat DA neurons (Kang and Kitai, 1993b) and the
biophysical properties of native and recombinant T-type channels
(Huguenard, 1996; Perez-Reyes et al., 1998; Lee et al., 1999; McRory et
al., 2001).
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Figure 2.
SK-mediated AHP and T-type-mediated low
voltage-activated calcium currents (I-LVA; see Results)
possessed almost identical nickel and mibefradil sensitivities in
dopaminergic neurons. A, Nickel reduced AHP currents
(I-AHP; evoked by 20 msec hybrid-clamp depolarizations)
in a concentration-dependent manner. The mean dose-response
relationship for nickel I-AHP inhibition was described by a Hill
function, with an IC50 of 33.75 µM, a Hill
coefficient of 1.30 (n = 19), and a relative fitted
residual I-AHP component (42%; dotted line).
B, Mibefradil inhibited a major component of the I-AHP
irreversibly. The mean dose-response relationship for mibefradil I-AHP inhibition was described
by a Hill function, with an IC50 of 4.83 µM
(Hill coefficient, 2.16; n = 10) and a relative
fitted residual I-AHP component of 20% (dotted line).
C, T-type-mediated LVA currents evoked by
depolarizations to 50 mV from a holding potential of 100 mV were
recorded by using standard whole-cell recordings (see Results and
Materials and Methods). Nickel reduced the I-LVA in a
concentration-dependent manner. The mean dose-response relationship
for nickel I-LVA inhibition was described by a Hill function, with an
IC50 of 33.86 µM (Hill coefficient, 0.85;
n = 16). D, Mibefradil inhibited the
I-LVA irreversibly. The mean dose-response for mibefradil I-LVA
inhibition was described by a Hill function, with an IC50
of 4.59 µM (Hill coefficient, 2.27; n = 14). Calibration: A, B, 0.2 sec, 10 pA;
C, 0.2 sec, 300 pA; D, 0.2 sec, 60 pA.
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The mean dose-response relationship for nickel inhibition was almost
identical between AHP currents (Fig. 2A;
IC50, 33.75 µM; Hill
coefficient, 1.30; n = 19) and T-type currents (Fig. 2C; IC50, 33.86 µM; Hill coefficient, 0.85; n = 16). Likewise, the mean dose-response curve for mibefradil inhibition
was also very similar between AHP currents (Fig. 2B;
IC50, 4.83 µM; Hill coefficient, 2.16; n = 10) and T-type currents (Fig.
2D; IC50, 4.59; Hill
coefficient, 2.27; n = 14). The fitted nickel- or
mibefradil-insensitive components of the AHP current (Fig.
2A,B, dotted line; nickel, 42%;
mibefradil, 20%) were in a range comparable with the
cobalt-insensitive AHP current component (29 ± 4%; Fig. 1). This
suggests that most of the flux through Cav
channels involved in SK channel activation was indeed nickel- and
mibefradil-sensitive. The pharmacological profile of AHP currents was
not sufficient to rule out a contribution of R-type calcium channels.
However, the striking similarity of quantitative nickel and mibefradil
sensitivities between biophysically identified native T-type currents
and AHP currents strongly suggests that T-type calcium channels are
coupled selectively to SK channels in DA SN neurons.
SK currents closely follow the temporal profile of
T-type currents
One predicted consequence of the functional coupling of SK
channels to T-type channels was that SK currents should follow the
characteristic gating behavior of T-type channels such as use-dependent
inactivation (Huguenard, 1996; Perez-Reyes et al., 1998). In agreement
with this prediction, we noted that hybrid-clamp-evoked AHP currents
showed a use-dependent inactivation when successive voltage steps were
applied (Fig. 3A). In
contrast, apamin-sensitive AHP currents in SN neurons with an
electrophysiological profile typical of GABAergic neurons (Richards et
al., 1997; Liss et al., 1999) did not exhibit this use dependency
(first/sixth AHP amplitude, 0.93 ± 0.04; n = 15;
data not shown). Use-dependent inactivation is a typical feature of
channels that possess inactivation gating, including T-type channels
(Huguenard, 1996; Perez-Reyes et al., 1998), but has not been reported
to be an intrinsic property of SK channels (Kohler et al., 1996; Xia et
al., 1998; Hirschberg et al., 1999). Accordingly, SK channels can be
activated tonically in DA SN neurons by 1-EBIO (>0.5
mM), a compound that increases the open
probability of SK channels (Xia et al., 1998), inducing long-lasting
hyperpolarizations (Wolfart et al., 2001). We tested use-dependent
inactivation of AHP and T-type currents by eliciting trains of step
potentials (holding potential, 80 mV; 100 msec pulses to +60 mV at 1 Hz) in both AHP and T-type current recording conditions (see Materials
and Methods). The time constants of use-dependent inactivation for AHP
and T-type currents were not significantly different [AHP current
(Fig. 3A,D): 0.98 ± 0.06 sec, n = 10;
T-type (Fig. 3B,D): 0.80 ± 0.07 sec, n = 10; p > 0.05]. We studied the functional
implications of this cumulative inactivation for the temporal
integration of neuronal activity by using perforated patch-clamp
recordings in current-clamp mode (Fig. 3C). Consistent with
our voltage-clamp data, AHP amplitudes cumulatively decreased in
response to prolonged positive current injections from hyperpolarized
membrane potentials. This cumulative decrease of AHP amplitudes had
similar time constants when compared with those of AHP currents and
T-type currents (Fig. 3C; 1.08 ± 0.12 sec,
n = 8; p > 0.05) and was blocked by
nickel (Fig. 3C,E; initial/steady-state AHP: control,
2.0 ± 0.1, n = 8; 250 µM
nickel, 1.1 ± 0.1, n = 8; p < 0.0005). Thus in DA SN neurons the SK currents inactivated cumulatively
in a physiologically relevant frequency range and closely followed the
inactivation kinetics of their major upstream calcium source, the
T-type calcium channel. This affects the rebound behavior of DA SN
neurons because the functional coupling of T-type to SK channels
generates a transient rebound inhibition.
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Figure 3.
Use-dependent inactivation of SK and T-type
currents displayed similar kinetics. A, AHP currents
(I-AHPs) evoked with hybrid-clamp depolarizations (100 msec, +60 mV) at a frequency of 1 Hz by using the standard whole-cell
configuration (recording potential, 80 mV). Successive AHP currents
decreased, reaching a steady-state level at 38% of the initial
amplitude. The time constant of cumulative inactivation was 1.26 sec.
B, Recording of T-type-mediated low voltage-activated
calcium currents (I-LVA; see Results) evoked by the same
voltage pulse protocol as in A, using the standard
whole-cell configuration and calcium channel recording solutions.
Successive activation at 1 Hz led to a decrease of I-LVAs, reaching a
steady-state level of 42%. The time constant of use-dependent
inactivation was 0.77 sec. C, Perforated current-clamp
recording of a train of APs evoked by injections of 10 pA for 4 sec
from a hyperpolarized membrane potential of 80 mV. At the onset of
depolarization the AHPs were large but decreased with successive APs.
Application of nickel (250 µM) decreased the AHP
amplitudes and abolished the effect of cumulative inactivation. Note
that the control rate of cumulative AHP inactivation ( = 1.10 sec) was similar to the time constants determined for I-AHPs and
I-LVAs. D, Time constants () of cumulative
inactivation determined by experiments in A and
B. LVA and AHP currents both had cumulative inactivation
time constants in the range of 1 sec: I-LVA, 0.80 ± 0.07 sec
(n = 10); I-AHP, 0.98 ± 0.06 sec
(n = 10; p > 0.05).
E, The summary of experiments in D shows
that AHPs were reduced twofold under control conditions (2.0 ± 0.1; n = 8), whereas the effect was abolished by
nickel application (1.1 ± 0.1; n = 8;
***p < 0.0005). Calibration:
A, 0.5 sec, 50 pA; B, 0.5 sec, 200 pA;
C, 0.5 sec, 10 mV.
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|
The functional coupling of T-type and SK channels maintains
pacemaker precision in DA SN neurons
Next we studied whether the functional coupling of T-type channels
to SK channels is operative during spontaneous pacemaker activity. In
particular, we were interested in how the functional pairing of T-type
and SK channels is involved in the regulation of pacemaker spiking,
because we have shown previously that pacemaker frequency and precision
strongly depend on SK channel activity in DA SN neurons (Wolfart et
al., 2001). To quantify the role of T-type channels in pacemaker
precision, we analyzed the CV of ISIs during continuous perforated
patch-clamp recordings in the current-clamp configuration (Fig.
4). Consistent with previous studies,
pacemaker spiking was highly precise at 22-24°C (Fig. 4A,D; CV, 14 ± 2%, n = 11)
(Wolfart et al., 2001) and at 36-37°C (14 ± 1%,
n = 15; p > 0.4; data not shown)
(Shepard and Bunney, 1988). Application of 100 µM nickel slowed the spiking frequency (control: 2.13 ± 0.14 Hz, n = 11; nickel:
1.79 ± 0.19 Hz, n = 11; p < 0.005) and rendered the pacemaker more irregular (Fig. 4B,D; CV, 27 ± 5%, n = 11;
p < 0.005) in such a way that was similar to the
effect of apamin application on spiking regularity (Fig. 4C,D; CV, 26 ± 4%, n = 11;
p < 0.005). Thus, inhibition of T-type and SK channels
reduced the precision of the intrinsic pacemaker to a similar extent
(p > 0.8), demonstrating that T-type channels are the essential calcium source for SK channels also during
spontaneous pacemaker activity in DA SN neurons.
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Figure 4.
Nickel-sensitive T-type and apamin-sensitive SK
channels maintained the high precision of pacemaker spiking in
dopaminergic neurons. A-C, Perforated current-clamp
recordings during control (A), 100 µM nickel (B), and 300 nM apamin (C) application.
Left panels show a 4 sec recording trace representative
of a 5 min recording for each condition. Interspike interval
(ISI) frequency distributions are displayed in
the right panels for each recording. As a measure of
pacemaker precision the coefficient of variation
(CV) was calculated from the Gaussian fit of ISI
histograms. APs were truncated at 20 mV. A, During
control conditions pacemaker spiking was relatively regular, with a CV
of 15%. B, Application of 100 µM nickel
reversibly rendered pacemaker spiking to be more irregular (CV of
38%). C, Application of 300 nM apamin did
increase the irregularity of pacemaker spiking to a similar degree (CV
of 35%). D, The summary of experiments in
A-C shows that nickel (100 µM) and apamin
(300 nM) decreased the pacemaker precision
(**p < 0.005, respectively) to a similar
extent (p > 0.8). Mean CVs: control,
14 ± 2% (n = 11); nickel, 27 ± 5%
(n = 11); apamin, 26 ± 4%
(n = 11). Calibration: A-C, 0.5 sec, 10 mV. Dotted line in A-C, 50
mV.
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|
Coupling of T-type and SK channels prevents intrinsic burst firing
in DA SN neurons
T-type currents are known to promote bursting in many central
neurons (Huguenard, 1996, 1998). However, the present results indicate
that, in DA SN neurons, T-type channels might have an opposite role
because of their functional coupling to SK channels. As shown in Figure
4, the activity of T-type channels stabilizes single-spike pacemaker
firing. Indeed, application of 100 µM nickel alone led to
an unequivocal burst-like pattern in a minor subset (3 of 27) of DA SN
neurons recorded via the perforated
patch-clamp technique (Fig. 5B; see
Table 1 for comparison of burst
parameters with those described in the literature). The bursting
pattern consisted mainly of AP doublet bursts (range, 2-6; mean,
2.3 ± 0.1 APs/burst; mean intra-burst interval, 151 ± 5 msec) followed by prolonged, large hyperpolarizations (mean inter-burst
interval, 2.39 ± 0.31 sec), which were not inhibited by the
additional application of 300 nM apamin
(n = 2; data not shown). A comparable switch in spiking
pattern was never observed during apamin application in this study nor
in our previous 10-min-long perforated patch recordings in apamin
(Wolfart et al., 2001). As described by Grace and Bunney (1984b), the
degree of bursting was quantified as APs involved in bursts per
treatment (percentage of bursting; see Materials and Methods). No
significant degree of bursting was detected in control and apamin
recordings in this study (Fig. 5D; control: 0% bursting,
n = 30; 300 nM apamin: 3 ± 2%, n = 19) as well as in recordings of previously
published data (control: 0% bursting, n = 11; 300 nM apamin: 5 ± 3% bursting,
n = 10; data not shown) (Wolfart et al., 2001). In
contrast, 100 µM nickel was sufficient to
increase the mean bursting values significantly (Fig. 5D;
12 ± 7% bursting, n = 27; p < 0.05) and, indeed, induced robust bursting (>84% bursting) in three
cells. Most effective in the induction of bursting was the combination
of T-type and SK channel inhibition. It strongly increased the degree
of bursting (Fig. 5D; 34 ± 10%, n = 16; p < 0.0005) and induced robust bursting in five
cells (>86% bursting).
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Figure 5.
Inhibition of T-type channels evoked bursting in a
subpopulation of dopaminergic midbrain neurons. A-C,
Perforated current-clamp recordings during control
(A), nickel (B), and
washout (C) conditions. A 20 sec recording trace
representative of a 5 min recording is shown for each condition. As a
measure of pacemaker precision the coefficient of variation (CV) was
calculated from Gaussian fits of ISI histograms (insets).
A, No bursting (0%) was detected during control
application. Note that this neuron showed pacemaker spiking at the
lower end of firing precision (CV of 20%; compare with Fig. 4).
B, Application of 100 µM nickel switched the firing pattern from pacemaker to
bursting, with two to three closely spaced APs alternating with long
inter-burst intervals. C, With the washout of nickel the
firing pattern returned to (irregular) pacemaker spiking.
D, Firing patterns during perforated patch-clamp
recordings were assessed by a burst evaluation program (spikes/burst
per trace = bursting in percentage values; e.g., 85% bursting for
the recording shown in B). Under control conditions the
bursting value was 0% (n = 30). Application of 300 nM apamin did not change the bursting value (3 ± 2%;
n = 19) significantly, although one cell showed an
increased value (45%) because of short periods of "burst-like"
pattern. Inhibition of T-type channels with 100 µM nickel
significantly increased the bursting value to 12 ± 6%
(n = 27; p < 0.05), and three
cells displayed bursting values above 84%. The combination of nickel
and apamin application (ni+apa) was most effective in
switching from pacemaker to bursting behavior, increasing the mean
bursting value to 34 ± 10% (n = 16;
p < 0.0005), with five neurons reaching bursting
values of >86%. E, Differential effects of T-type
channel inhibition on firing patterns were associated to pacemaker
precision under control conditions. Control CV values were correlated
with the effect of nickel and apamin application on firing patterns of
respective cells. Neurons that were converted to bursting had
significantly higher CV values (25 ± 4%; n = 6) compared with cells that became irregular with nickel (or nickel + apamin) application (14 ± 1%; n = 22;
***p < 0.0005). Calibration:
A-C, 1 sec, 10 mV. Dotted lines in
A-C, 50 mV. Dotted line in
D, 75% bursting.
|
|
We also noted that the degree of bursting was predicted by the degree
of pacemaker precision under control conditions. Cells that fired in
bursts after nickel (100 µM) or after nickel and apamin
(300 nM) application had significantly higher control CV values (Fig. 5E; 25 ± 4%, n = 6)
compared with cells that fired irregularly only with the inhibition of
T-type channels or T-type and SK channels (Fig. 5E; 14 ± 1%, n = 22; p < 0.0005). In
summary, T-type calcium channels stabilized pacemaker firing and in
addition prevented the switch to an intrinsic burst-firing mode in DA
SN neurons.
| |
DISCUSSION |
On the basis of our pharmacological and biophysical analysis of
AHP and T-type currents, we conclude that SK channels are activated
almost exclusively via T-type channels in mouse DA SN neurons. Although
various subtypes of Cav channels are known to be
present at the mRNA (Soong et al., 1993; Stea et al., 1994; Craig et
al., 1999; Talley et al., 1999), protein (Williams et al., 1994; Craig
et al., 1999; Takada et al., 2001), and functional levels (Kang and
Kitai, 1993a; Nedergaard et al., 1993; Mercuri et al., 1994; Cardozo
and Bean, 1995; Ping and Shepard, 1999; Shepard and Stump, 1999), SK
currents were not affected by established L-type and P/Q-type channel
blockers (Zhang et al., 1993; Tsien et al., 1995; Randall, 1998;
Miller, 2001). In contrast, between 85 and 94% of SK currents
activated by voltage-activated calcium influx were blocked selectively
in a dose-dependent manner by nickel and mibefradil, respectively, in a
concentration range that is likely to block T-type channels (Martin et
al., 2000; Perchenet et al., 2000). Although we cannot exclude a minor
role for N-type channels in SK channel activation, the reversible
inhibition by -conotoxin-GVIA also might be an effect on native
T-type channels (McCleskey et al., 1987). Although nickel and
mibefradil also have been reported to affect HVA R-type channels
(Bezprozvanny and Tsien, 1995; Randall and Tsien, 1997), the identical
quantitative pharmacological profiles of SK and biophysically
identified T-type currents, as well as their very similar use-dependent
inactivation, strongly suggest that T-type channels constitute the
selective calcium source for SK channel activation in DA SN neurons. In comparison to previous studies in other cell types (Wisgirda and Dryer,
1994; Davies et al., 1996; Marrion and Tavalin, 1998; Tanabe et al.,
1998; Sah and Davies, 2000; Shah and Haylett, 2000; Bowden et al.,
2001), this selective coupling of SK to T-type channels in SN DA
neurons appears to be unique and might have important functional implications.
During phasic activation from relatively hyperpolarized membrane
potentials, T-type channel activation does not lead to rebound excitation, as seen in thalamocortical neurons (Huguenard, 1996, 1998).
Instead, T-type channel function is inverted by activating SK channels,
thereby generating a transient rebound inhibition. The coupling of SK
channels to T-type channel gating might explain why SK channels do not
contribute to frequency adaptation in DA SN neurons (Shepard and
Bunney, 1991), which is an important function of SK channels in many
other types of neurons (Sah, 1996; Bond et al., 1999; Sah and Davies,
2000). Similar to sino-atrial pacemaker cells (Hagiwara et al., 1988;
Huser et al., 2000), T-type channels in DA SN neurons were active
during spontaneous pacemaker activity. Our data provide evidence that
the functional pairing of T-type and SK channels maintains the
precision and stability of the single-spike pacemaker. Previous studies
have showed that the inhibition of SK channels alone can induce
intrinsic bursting in rat DA neurons recorded in vitro
(Shepard and Bunney, 1988, 1991; Gu et al., 1992; Ping and Shepard,
1996). We did not detect robust bursting in apamin alone, but bursting
occurrence in most previous studies was low (<50% of neurons), and
other studies also have failed to evoke intrinsic bursting by SK
channel inhibition alone (Seutin et al., 1993; Johnson and Seutin,
1997). In marked contrast to the role of T-type channels in other types
of neurons (Huguenard, 1996, 1998), the inhibition of T-type channels
alone switched the firing pattern of some DA SN neurons to an intrinsic
burst-firing mode. Thus in DA SN neurons the role of T-type channels
corresponds to that described for SK channels alone (Shepard and
Bunney, 1988, 1991; Gu et al., 1992; Ping and Shepard, 1996), because
T-type currents are translated into SK currents by their functional
coupling. Although burst firing was not evoked by SK channel inhibition alone, burst occurrence was increased significantly when SK channels were blocked in addition to T-type channels. This indicates that the
burst switch is regulated by several converging conductances as
suggested by a recent burst-modeling study (Goldman et al., 2001).
Our results support the notion that DA SN neurons possess an intrinsic
bursting mechanism (Shepard and Bunney, 1988) that might be
"unmasked" synaptically (Kitai et al., 1999) and sustained by a
combination of intrinsic and synaptic mechanisms (Johnson et al., 1992;
Kitai et al., 1999; Paladini and Tepper, 1999). Differences between
in vivo bursting (Grace and Bunney, 1984b) and in
vitro bursting induced by NMDA (Johnson et al., 1992), apamin
(Shepard and Bunney, 1991), and/or nickel further suggest that a
combination of intrinsic and synaptic mechanisms is responsible for the
transition from pacemaker to burst firing in DA SN neurons in
vivo (see Table 1).
We can only speculate about the molecular organization of the
functional coupling between SK and T-type channels. We have reported
previously that hybrid pulse-evoked AHP currents are reduced
significantly by millimolar concentrations (10 mM) of the
slow calcium buffer EGTA, arguing against a very close spatial coupling
of T-type and SK channels in DA neurons (Wolfart et al., 2001). This is
in contrast to the tight spatial coupling of SK channels to nicotinic
acetylcholine receptors in outer hair cells (<10 nm) (Oliver et al.,
2000). Our results also show that release from intracellular stores
significantly amplifies the calcium signal for SK channel activation.
As described previously for other cell types (Yoshizaki et al., 1995;
Tanabe et al., 1998; Cordoba-Rodriguez et al., 1999; Huser et al.,
2000), our data suggest that T-type channel-mediated calcium influx
during pacemaker firing acts as a "calcium spark," triggering
secondary calcium-induced calcium release that subsequently activates
SK channels in DA SN neurons. We did not detect SK channel activation
during nickel-induced bursting or after long depolarizations,
conditions that are likely to lead to the recruitment of HVA calcium
channels in DA neurons (Kang and Kitai, 1993b; Nedergaard et al., 1993;
Mercuri et al., 1994; Cardozo and Bean, 1995). Consequently, we
hypothesize that T-type channels, calcium stores, and SK channels might
be colocalized selectively, possibly forming a specialized calcium
signaling complex (Marrion and Tavalin, 1998; Husi et al., 2000; Bowden et al., 2001) in DA neurons. This functional signaling complex could
provide a new framework for the temporal integration of synaptic input
in DA SN neurons, which might help us to understand how and why DA
neurons switch between pacemaker and burst-firing mode in
vivo, thus contributing to reward-based learning (Schultz, 2000;
Reynolds et al., 2001).
| |
FOOTNOTES |
Received Dec. 18, 2001; revised Feb. 14, 2002; accepted Feb. 15, 2002.
This work was supported by the Medical Research Council. J.R. holds the
Monsanto Senior Research Fellowship at Exeter College, Oxford
University. We thank Dr. Ian Jones and Dr. Peter Magill for critically
reading this manuscript.
Correspondence should be addressed to Dr. Jochen Roeper, Medial
Research Council Anatomical Neuropharmacology Unit, Oxford University,
Mansfield Road, Oxford OX1 3TH, UK. E-mail:
jochen.roeper{at}pharm.ox.ac.uk.
| |
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TOP
ABSTRACT
INTRODUCTION
