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The Journal of Neuroscience, December 15, 2000, 20(24):8987-8995
D2 Dopamine Receptors in Striatal Medium Spiny
Neurons Reduce L-Type Ca2+ Currents and Excitability via a
Novel PLC 1-IP3-Calcineurin-Signaling
Cascade
Salvador
Hernández-López1,
Tatiana
Tkatch1,
Enrique
Perez-Garci2,
Elvira
Galarraga2,
José
Bargas2,
Heidi
Hamm3, and
D. James
Surmeier1, 3
1 Department of Physiology and 3 Institute
for Neuroscience, Northwestern University Medical School, Chicago,
Illinois 60611, and 2 Instituto de Fisiologia Celular, UNAM
Apartado Postal 70-253, Mexico DF 4510
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ABSTRACT |
In spite of the recognition that striatal D2 receptors
are critical determinants in a variety of psychomotor disorders, the cellular mechanisms by which these receptors shape neuronal activity have remained a mystery. The studies presented here reveal that D2 receptor stimulation in enkephalin-expressing medium
spiny neurons suppresses transmembrane Ca2+ currents
through L-type Ca2+ channels, resulting in
diminished excitability. This modulation is mediated by
G  activation of phospholipase C,
mobilization of intracellular Ca2+ stores, and
activation of the calcium-dependent phosphatase calcineurin. In
addition to providing a unifying mechanism to explain the apparently divergent effects of D2 receptors in striatal medium spiny
neurons, this novel signaling linkage provides a foundation for
understanding how this pivotal receptor shapes striatal excitability
and gene expression.
Key words:
neostriatum; patch clamp; dopamine; neuromodulation; medium spiny neuron; basal ganglia; electrophysiology; single-cell
RT-PCR; ion channel; calcium
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INTRODUCTION |
Disruptions in striatal dopaminergic
signaling are thought to underlie a variety of psychomotor disorders
including drug abuse, schizophrenia, Tourette's syndrome, and
Parkinson's disease (Hornykiewcz, 1973 ; Meltzer and Stahl,
1976; Sandor, 1993; Nestler and Aghajanian, 1997). In spite of the
recognition that alterations in dopaminergic signaling are the basis of
these psychomotor disorders, the cellular mechanisms by which dopamine
affects striatal function have remained something of a mystery. This is
particularly true of D2 receptors. These
receptors are expressed at high levels by several groups of neurons in
the striatum, including GABAergic medium spiny neurons that project to
the globus pallidus and express enkephalin (Gerfen, 1992; Surmeier et
al., 1996).
The prevailing model of the striatum (Gerfen, 1992) suggests that
D2 receptor stimulation suppresses the activity
of enkephalin-expressing striatal medium spiny neurons. This inference
is based primarily on two indirect observations. First,
dopamine-depleting lesions increase striatal expression of enkephalin,
a peptide released by medium spiny neurons expressing
D2 receptors (Gerfen, 1992). Second, neuroleptic
blockade of D2 receptors increases striatal expression of immediate early genes and glutamic acid decarboxylase (Chesselet et al., 1998). These changes are taken as evidence of
D2 receptor-mediated suppression of neural
activity and gene transcription. However, there are a number of
observations that are difficult to reconcile with this model. For
example, D2 receptor stimulation in striatal
slices increases the activity of a
Ca2+-dependent protein phosphatase
(calcineurin) and of Ca2+-dependent
mitogen-activated protein (MAP) kinase (Nishi et al., 1997; Yan et al.,
1999). D2 receptor stimulation also is necessary for the induction of synaptic plasticity in the striatum (Calabresi et
al., 1992). These studies argue that D2 receptor
stimulation increases, rather than decreases, activity and
intracellular Ca2+ levels in striatal
medium spiny neurons.
Direct measurements of neuronal activity have not provided a means of
explaining these seemingly contradictory findings. Because the
transcriptional and biochemical events at the heart of the signaling
discrepancy are Ca2+ dependent, a key
question is whether D2 receptors can directly influence intracellular Ca2+ levels. An
obvious way this might happen is via the modulation of transmembrane
ion channels capable of carrying Ca2+ ions
into the cytoplasm. One potential target of this type of modulation is
the L-type Ca2+ channel, a channel that
has a privileged association with transcriptional regulators in many
neurons (Bading et al., 1993; Graef et al., 1999). Although they
can be enhanced by several mechanisms (Viard et al., 1999), in medium
spiny neurons L-type Ca2+ currents are
increased by D1 receptor stimulation of adenylyl cyclase and protein kinase A (Surmeier et al., 1995). Because the
best-described effect of striatal D2 receptors is
inhibition of adenylyl cyclase (Sibley, 1995), D2
receptor activation should, in principle, reduce L-type currents.
The studies described here were intended to test this hypothesis. They
show that indeed D2 receptor stimulation
suppresses L-type Ca2+ currents in
enkephalin-expressing medium spiny neurons. But, the suppression is not
mediated by inhibition of adenylyl cyclase. Rather,
D2 receptor stimulation mobilizes intracellular
Ca2+ stores via
G activation of a
phospholipase C 1 pathway, leading to a calcineurin-dependent
reduction in L-type currents. This novel signaling linkage establishes
a mechanism by which D2 receptors can suppress
spike activity and Ca2+-dependent gene
transcription but activate Ca2+-dependent
intracellular enzymes.
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MATERIALS AND METHODS |
Electrophysiology. Whole-cell recordings from acutely
isolated rat striatal neurons were obtained using previously published techniques (Surmeier et al., 1995; Mermelstein et al., 1999). The
pipette solution consisted of (in mM): 180 N-methyl-D-glucamine (NMG), 40 HEPES,
4 MgCl2, 0-20 BAPTA, 12 phosphocreatine, 2 Na2ATP, 0.2 Na2GTP, and 0.1 leupeptin, pH 7.2-7.3 with
H2SO4, 265-270 mOsm/l. The
external solution consisted of (in mM): 135 NaCl, 20 CsCl, 1 MgCl2, 10 HEPES, 0.001 TTX, 5 BaCl2, and 10 glucose, pH 7.4 with NaOH, 300-305
mOsm/l. All reagents were obtained from Sigma (St. Louis, MO) except
ATP and GTP (Boehringer Mannheim, Indianapolis, IN) and BAPTA,
calcineurin autoinhibitory peptide, and leupeptin (Calbiochem, La
Jolla, CA). All drugs were prepared according to the manufacturer's
specifications and applied with a "sewer pipe" capillary array
(Surmeier et al., 1995; Mermelstein et al., 1999). C terminus of adrenergic receptor kinase 1 (ARK-C) peptide (ARK-Cp) is
comprised of residues 548-671 of the rat homolog of ARK. ARK-Cp
(4.9 mg/ml) was dialyzed against the recording internal solution. This
solution was diluted in the recording internal solution for a final
concentration of 1 mg/ml.
Intracellular recordings were performed on rat dorsal neostriatal
slices maintained in vitro as reported previously
(Hernandez-Lopez et al., 1997). Recording was done in a submerged-type
chamber superfused with saline of the same composition (34-36°C).
Sharp microelectrodes filled with 3 M K-acetate
and 1% biocytin were used. Rectangular current pulses of varying
strengths and durations were used to evoke spike activity. Records were
obtained with an active bridge electrometer (Neuro Data, Cygnus
Technology, Inc., Delaware Water Gap, PA), digitized, and saved
on video tapes (40 kHz) for off-line analysis with a personal
computer. Neurons were injected with biocytin as described previously.
All neurons were medium spiny projection neurons. Experiments were
paired, so that records in the presence and absence of bath-applied
drugs were compared in the same neuron.
Fluorometry. For combined patch clamp and fluorometry,
neurons were loaded with fura-2 pentapotassium salt (100 µM; Molecular Probes, Eugene, OR) through the patch
pipette in a chelator-free recording internal solution (see above).
Concomitant fluorometry and patch-clamp recording used
Ba2+ as the charge carrier to eliminate
transmembrane flux as a contributor to the fluorometric signal. For
fluorometry without patch recording, neurons were incubated in buffer
containing fura-2 AM (5 µM; Molecular Probes) for
25 min at 37°C in the dark. After loading, neurons were rinsed with
saline and equilibrated for 20 min at room temperature. Changes in
cytoplasmic Ca2+ concentration were
determined by measuring the fluorescence ratio (510 nm) after
excitation with 340 and 380 nm wavelength light. Emission ratios were
corrected for background fluorescence. Measurements were obtained with
a Nikon Diaphot equipped with a DeltaScan fluorometry system (Photon
Technology International) running proprietary software.
Single-cell reverse transcription-PCR protocol.
Protocols similar to those described previously were used (Baranauskas
et al., 1999; Mermelstein et al., 1999). The PCR primers were developed from GenBank sequences using OLIGO software (National Biosciences). The
primers used for enkephalin and substance P cDNA amplification have
been published previously (Surmeier et al., 1996). The primers for
phospholipase C 1 (PLC1) cDNA (GenBank accession number M20636)
were 5'-AAA GGG AAG GTT AGT GAG GAC AG-3' and 5'-TTC AGG CTA AGG GAT
GTT TCT C-3'. The predicted product length was 253 bp. The
primers for PLC2 cDNA (GenBank accession number AJ011035) were
5'-ATC CAA GCC ATG ACC AAA GTC-3' and 5'-GTC TCC CAT TTC TGC CTT
ATG TG-3'. The predicted product length was 547 bp. The primers for
PLC3 cDNA (GenBank accession number M99567) were 5'-AGC GCA ACA ACA
GCA TCT CAG A-3' and 5'-CTC TTG CTC CGC CAG TTC AAA G-3'. The predicted
product length was 420 bp. The primers for PLC4 cDNA (GenBank
accession number L15556) were 5'-GGC AAT GAA GCA GTC GAA AGA-3' and
5'-GGC GTG ATC CTC TGG TGT TCT AT. The predicted product
lengths were 209 and 246 bp.
Statistical procedures. Data analysis was performed with
SYSTAT (version 5.2; SPSS, Inc., Chicago, IL). Sample statistics are given as means ± SEs. Box plots were used for graphic
presentation of the data because of the small sample sizes.
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RESULTS |
D2 receptor activation reduces
Ca2+ currents
Whole-cell Ba2+ currents through
Ca2+ channels were reversibly inhibited by
the D2-class receptor agonists ( )-quinpirole
(Fig. 1) and
R()-propylnorapomorphine (NPA) in ~65% of the acutely isolated medium-sized striatal neurons tested. At saturating agonist concentrations (10 µM), the mean reduction in
peak current evoked by a voltage step to 10 mV was 28 ± 2%
(n = 5) for quinpirole and 26 ± 3% for NPA
(n = 4). Lower agonist concentrations produced smaller,
qualitatively similar modulations (0.50-5 µM;
n = 6). Previous studies have shown that
D2 receptors, like other
Gi/o-coupled receptors, inhibit N- and P/Q-type
Ca2+ channels but typically do not
modulate L-type Ca2+ channels (Yan et al.,
1997). However, in medium spiny neurons, the L-type channel antagonist
nifedipine significantly reduced the modulation produced by quinpirole,
suggesting that L-type channels were a major target of the
D2 receptor pathway (Fig. 2A,B). The mean
modulation in the absence of nifedipine was 29% (n = 8), whereas it was only 10% (n = 6) in the presence of
nifedipine (p < 0.05, Kruskal-Wallis).
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Figure 1.
D2-class receptor agonists decrease
whole-cell Ba2+ current through
Ca2+ channels in acutely isolated striatal neurons.
A, Plot of peak Ba2+ currents evoked
by a step to 10 mV from a holding potential of 80 mV. Quinpirole
(10 µM) reversibly decreased peak currents.
B, Representative currents used to construct
A. Voltage protocol is shown at the top.
Inset, A box plot summary of the percent reduction in
peak current produced by quinpirole (n = 5). The central line of the box is the
median of the distribution. The edges of the box
are the interquartiles. The lines running from the
edge of the box show the extremes of the
distribution, excluding outliers.
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Figure 2.
D2-class receptor agonists decrease
currents through L-type Ca2+ channels.
A, Plot of peak Ba2+ current evoked
by a voltage ramp (see B). Nifedipine (5 µM) reduced evoked currents and occluded the effects of
quinpirole (10 µM); washing nifedipine off restored the
quinpirole modulation. Inset, A box plot summary of the
modulation in the presence and absence (control) of nifedipine
(n = 6). The asterisk is an
outlier, defined as a point that is either greater than three halves
the interquartile range above the upper interquartile or less than
three halves the interquartile range below the lower interquartile
(Tukey, 1977). B, Representative currents used to
construct A. Voltage protocol is shown at the
top. C, Plot of tail current amplitude
evoked by the protocol shown in D and measured at the
dashed vertical line in D. BAYK 8644 increased tail amplitudes; NPA reversibly reduced the amplitude.
Inset, A box plot summary of the percent reduction in
tail current amplitude produced by NPA (n = 13). The filled circle is an outlier.
D, Representative current traces used to
construct C.
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Another way of testing the involvement of L-type
Ca2+ channels is via use of the
dihydropyridine agonists such as
()-1,4-dihydro-2,6-dimethyl-5-nitro-4-[2-(trifluoromethyl)-phenyl]-3-pyridine carboxylic acid methyl ester (BAYK) 8644 and
2,5-dimethyl-4-[2-(phenylmethyl)benzoyl]-1H-pyrrole-3-carboxylic acid
methyl ester (FPL) 64176 (Rampe et al., 1993). These agonists slow the deactivation of L-type Ca2+
channels during repolarization of the membrane; this selective slowing
provides a convenient way of isolating currents through L-type
channels. NPA reversibly reduced the slowly deactivating tail current
attributable to L-type Ca2+ channels (see
Fig. 2C,D). As shown in Figure 2C,
inset box plot, the median reduction in the amplitude of the
slow tail current by NPA (10 µM) was just
>20% in responsive neurons (n = 13).
To verify the involvement of D2-class receptors
in the response, the ability of ()-sulpiride to antagonize the
response was examined. Sulpiride (5 µM) (Weiss et al.,
1985) had no effect of its own on the BAYK-enhanced L-type currents but
blocked the effect of NPA (10 µM) on both step and tail
currents; the effect of NPA reemerged when sulpiride was washed off the
cell (Fig. 3A,B). In six
neurons, the median NPA-induced modulation of the slow tail current was
22% in the absence of sulpiride and 2% in its presence (see Fig.
3A, inset; p < 0.05, Kruskal-Wallis). The modulation of the current evoked during the
depolarizing step also was antagonized by sulpiride (n = 6; median modulation = 4%; p < 0.05, Kruskal-Wallis).
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Figure 3.
The modulation is dependent on D2
receptors. A, A plot of Ba2+ current
tail amplitudes as a function of time (see Fig. 2D).
Sulpiride (5 µM) blocked the effects of NPA (10 µM); washing sulpiride off restored the NPA
modulation. Inset, A box plot summary of the modulation
in the presence and absence (NPA) of sulpiride (n = 6) is shown. The filled circle is an outlier.
B, Representative currents used to construct
A are presented. Voltage protocol is shown at the
top. C, NPA modulated
Ba2+ currents only in neurons shown by scRT-PCR to
express enkephalin (n = 6). Inset,
The gel shows the presence of enkephalin (ENK)
and absence of substance P (SP) amplicons in this cell.
D, Neurons expressing substance P, but not enkephalin,
did not respond to NPA (n = 3).
Inset, The gel shows the SP amplicon
derived from this neuron.
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There are three D2-class receptors
(D2, D3, or
D4) with a high affinity for NPA, quinpirole, and
sulpiride. Although the D2 receptor is the
predominant striatal isoform, previous studies have identified a
substantial subset of medium spiny neurons that express
D3 receptors (Surmeier et al., 1996). To
determine which of these D2-class receptors was
responsible for the modulation, whole-cell recordings were followed by
a single-cell reverse transcription (scRT)-PCR analysis. Because the
dopamine receptor mRNAs appear to be of relatively low abundance and
difficult to detect after whole-cell recording, the scRT-PCR
experiments focused on two high-abundance peptide mRNAs that are
strongly correlated with receptor expression. D2
receptor expression is limited to medium spiny neurons expressing the
releasable peptide enkephalin (Gerfen, 1992; Surmeier et al., 1996). On
the other hand, D3 receptor expression is limited
to a subpopulation of medium spiny neurons expressing substance P in
the dorsal striatum (Surmeier et al., 1996). In neurons expressing
enkephalin, the modulation of L-type Ca2+
channels was robust (Fig. 3C; n = 6;
median modulation = 19%), whereas neurons that only expressed
substance P failed to exhibit a significant response (Fig.
3D; n = 3; median modulation = 0%), clearly implicating D2 receptors in the modulation.
The D2 receptor modulation is not dependent on
inhibition of adenylyl cyclase
The activation of D2 receptors inhibits
adenylyl cyclase activity, reducing cytosolic cAMP levels and protein
kinase A (PKA) activity (Sibley, 1995). PKA can enhance L-type
Ca2+ channel currents in medium spiny
neurons (Surmeier et al., 1995). To test directly whether
D2 receptors reduced L-type currents by
inhibiting adenylyl cyclase, three experiments were performed. First,
adenylyl cyclase was stimulated by incubating neurons in forskolin (1 µM) before NPA exposure. If inhibition of adenylyl cyclase were a key element in the signaling mechanism, forskolin stimulation should increase the absolute magnitude of the NPA modulation (Battaglia et al., 1985). It did not. Although forskolin significantly enhanced tail currents in the absence of BAYK 8644 (control median = 45 pA; n = 13; forskolin
median = 74 pA; n = 6; p < 0.05, Kruskal-Wallis), the absolute modulation of BAYK 8644-enhanced tail
currents was indistinguishable from that seen in control neurons (Fig.
4A; n = 5; median reduction = 20%; p > 0.05, Kruskal-Wallis). The D2 receptor modulation of
currents evoked by the test step were unaltered as well
(n = 5; median reduction = 20%; p > 0.05, Kruskal-Wallis). A cyclase-dependent mechanism also predicts
that blocking the degradation of cAMP should attenuate the
D2 modulation. But, the phosphodiesterase inhibitor IBMX (5 µM) did not affect the
D2 modulation of slow tail currents
(n = 6; median modulation = 19%;
p > 0.05, Kruskal-Wallis) or step currents
(n = 6; median modulation = 19%;
p > 0.05, Kruskal-Wallis). Lastly, blocking the
access of cAMP to PKA should blunt the D2 modulation. However, as shown in Figure 4B, dialysis
with a competitive inhibitor of cAMP, the Rp isomer of cyclic adenosine
monophosphothioate (Rp-cAMPS; 10 µM), did not
affect the ability of D2 receptors to modulate
the slow tail current (n = 4; median modulation = 22%; p > 0.05, Kruskal-Wallis) or step currents
(n = 4; median modulation = 20%;
p > 0.05, Kruskal-Wallis). These observations, taken
together with the fact that D2 receptor
activation effectively modulated currents in the absence of
receptor-mediated stimulation of adenylyl cyclase, clearly suggest that
D2 receptors were working by another
mechanism.
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Figure 4.
The D2 receptor modulation is
independent of alterations in adenylyl cyclase activity.
A, Preincubation of cells in forskolin (1 µM) failed to alter the NPA (5 µM)
modulation of BAYK 8644-enhanced tail currents or the modulation of
currents evoked by the test step to 10 mV. Voltage protocol is shown
at the top. Inset, Box plots of the tail
modulation in control (NPA; n = 10), forskolin
(FSK; n = 5), and IBMX
(n = 6) solutions are shown. The
asterisk is an outlier. These data were not significantly
different. B, Cellular dialysis with the cAMP antagonist
Rp-cAMPS also failed to alter the NPA modulation of BAYK 8644-enhanced
tail currents. Inset, A box plot summary of the tail
modulation in control (n = 10) and Rp-cAMPS
(n = 4)-dialyzed neurons is shown. These
data were not significantly different.
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D2 receptors mobilize intracellular
Ca2+ via a phospholipase C pathway
If D2 receptors were not acting via adenylyl
cyclase and PKA, then how were they working? A number of studies have
shown that L-type Ca2+ currents can be
suppressed by elevations of the intracellular Ca2+ concentration (Chad and Eckert, 1986;
Armstrong et al., 1991; Lukyanetz et al., 1998). In cells dialyzed with
high concentrations of the fast Ca2+
chelator BAPTA (20 mM), a concentration sufficient to
"clamp" the free Ca2+ concentration at
a low nanomolar level, quinpirole had little or no effect on the
BAYK-enhanced tail currents (Fig.
5A). Although quinpirole
failed to modulate the slow tails in these neurons, it continued to
reduce the peak current (although to a lesser extent), suggesting that
the modulation of non-L-type channels was intact (n = 5; median modulation = 11%). Because BAPTA can have effects
unrelated to Ca2+ buffering (Bernheim et
al., 1991), cytosolic [Ca2+] was
measured directly with fluorometric techniques in voltage-clamped neurons dialyzed with fura-2 (100 µM). These
experiments revealed that in neurons in which the slow BAYK tail
currents were modulated, NPA also induced a rapid and reversible
elevation in cytosolic Ca2+. This
elevation occurred in the absence of external
Ca2+ and with the cell's membrane held at
80 mV (n = 4) (Fig. 5B), implicating
release from intracellular stores. NPA failed to alter intracellular
Ca2+ levels in those neurons in which the
slow BAYK tail currents were unmodulated (n = 3). To
test this linkage further, medium spiny neurons were loaded with fura-2
AM and D2 agonists applied in the presence and
absence of extracellular Ca2+.
Fluorometric measurements were taken in these neurons without concomitant patch-clamp recording. NPA evoked a calcium transient in
70% of these neurons regardless of whether external
Ca2+ was present or not (14/20; data not
shown).
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Figure 5.
D2 receptor modulation depends on the
release of intracellular Ca2+ via a PLC-dependent
mechanism. A, Dialysis with BAPTA (20 mM)
blocked the D2 modulation of tail currents but not peak
currents (n = 5). Voltage protocol is shown at the
top. Inset, A box plot summarizes the
modulations seen with BAPTA internals (n = 5) and
matched controls (n = 10). B, NPA
(10 µM) reduced BAYK tail currents and increased
intracellular Ca2+ levels in the same cells.
Inset, The ratio of 510 nm fura-2 emission after
excitation at 340 and 380 nm in the same neuron is shown. Measurements
were taken while the cell was clamped at 80 mV and in the absence of
external Ca2+. C, NPA failed to
modulate slow tail currents in enkephalin-expressing neurons dialyzed
with the PLC inhibitor U-73122 (n = 9).
Inset, The recorded neuron expressed enkephalin but not
substance P. D, Top, The gel shows RT-PCR amplicons for
PLC1-4 in pooled striatal mRNA. Bottom, The gel
shows representative amplicons from four ENK-positive
medium spiny neurons. Only PLC1 mRNA was detected in
ENK neurons (n = 20).
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The best-described mechanism for receptor-mediated mobilization of
intracellular Ca2+ stores is via
activation of PLC isoforms (Sternweis and Smrcka, 1992). PLC catalyzes
the hydrolysis of phosphatidylinositol 4,5-biphosphate, yielding
1,2-diacylglycerol and inositol 1,4,5-triphosphate
(IP3). Cytosolic IP3 binds
to its cognate receptor, releasing Ca2+
from intracellular pools. To determine whether D2
receptors relied on a similar mechanism, neurons were dialyzed with the
PLC inhibitor U-73122 (10 µM) before
D2 receptor stimulation. U-73122 blocked the
ability of NPA to reduce the slow, BAYK-enhanced tail currents in
enkephalin-expressing neurons (Fig. 5C; n = 9; median modulation = 0%; p < 0.05, Kruskal-Wallis). In contrast, non-L-type currents evoked by the
depolarizing voltage step continued to be reduced by NPA (Fig.
5C; n = 9; median modulation = 19%; p < 0.05, Kruskal-Wallis). Dialysis with the
inactive analog U-73343 (10 µM) failed
to alter the D2 modulation of the tail currents
(n = 4; median modulation = 21%;
p > 0.05, Kruskal-Wallis). PLC isoforms are
generally thought to mediate receptor-driven responses like the ones
observed here (Sternweis and Smrcka, 1992). The involvement of other
PLC isoforms, like PLC , or tyrosine kinase itself
(Diverse-Pierluissi et al., 1997) seems unlikely because of the
inability of the tyrosine kinase inhibitor genistein (50 µM) to reduce the D2
receptor modulation (n = 3; p > 0.05, Kruskal-Wallis) (Lajiness et al., 1993; Rhee and Bae, 1997). There are
four isoforms of PLC (1-4) that have been cloned (Exton, 1997). All
four isoforms were expressed in pooled striatal tissue (Fig.
5D, top); however, when the RT-PCR analysis was
limited to neurons expressing enkephalin mRNA, only the PLC1 isoform
was detected (Fig. 5D, bottom).
These findings are consistent with the hypothesis that
D2 receptors activate PLC1. PLC1, like the
other PLC isoforms, is capable of being activated by
G subunits (Exton,
1997; Morris and Scarlata, 1997). To test whether
D2 receptors activated PLC1 in this way,
neurons were dialyzed with an inhibitor of G signaling (ARK-C
peptide; 1 mg/ml) (Koch et al., 1994). ARK-Cp effectively inhibited
the NPA modulation of the BAYK-enhanced, L-type tail currents, as well
as the peak current, in enkephalin-expressing neurons (Fig.
6A). The median
modulation of the slow tail currents in the presence of ARK-Cp was
6% (Fig. 6B, inset; n = 5; p < 0.05, Kruskal-Wallis). The NPA modulation of
the currents evoked by the depolarizing voltage step was also 6%
(n = 5; p < 0.05, Kruskal-Wallis). In
the same ARK-Cp-dialyzed neurons, Gq -linked
M1 muscarinic receptors continued to reduce both peak and slow tail
currents (Fig. 6B, inset) (Howe and
Surmeier, 1995).
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Figure 6.
Inhibitors of G and
calcineurin signaling attenuate the D2 receptor modulation
of L-type channels. A, Dialysis with ARK-C peptide
(20 µM) blocked the NPA (10 µM) modulation
of BAYK (1 µM)-enhanced tail currents as well as peak
evoked currents in enkephalin-expressing medium spiny neurons.
Inset, The gel from the scRT-PCR profile is shown. The
median modulation of the tail currents in enkephalin-expressing neurons
(n = 4) was 4% (see B,
inset box plot). B, In the same neuron
depicted in A, muscarine (Mus; 1 µM) continued to modulate both currents evoked by the
step to 10 mV and slow tail currents. Inset, The
median muscarinic modulation of the tail currents was 20% in the
presence of ARK-C. This was very similar to that seen previously
(Howe and Surmeier, 1995) and indistinguishable from the D2
modulation (see box plot; the asterisk is an
outlier). Previous work has shown that these neurons express
high levels of the Gq-linked M1 receptor.
C, Dialysis with the calcineurin autoinhibitory peptide
(25 µM) blocked the NPA modulation of the slow tail
currents in enkephalin-expressing neurons but not that of the peak
currents (n = 4). Inset, The gel
shows ENK but not SP amplicons derived
from the recorded neuron. Voltage protocol is shown at the
top.
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Inhibition of calcineurin blocks the D2 receptor
modulation of L-type Ca2+ currents
PLC isoforms regulate intracellular
Ca2+ levels via the production of
IP3. Dialysis with competitive antagonists of
IP3 (heparin, 10 mg/ml; n = 6;
xestospongin, 1 µM; n = 13)
(Simpson et al., 1995; Gafni et al., 1997) antagonized NPA effects on
L-type channels in enkephalin-expressing neurons
(p < 0.05, Kruskal-Wallis). Lastly, caffeine
(10 mM; externally applied), which is known to
promote the release from ryanodine-sensitive
Ca2+ stores and inhibit
IP3-mediated Ca2+
release (Simpson et al., 1995), induced an elevation in cytosolic Ca2+ levels and occluded the effects of
quinpirole on FPL 64176-enhanced tail currents (n = 10;
p < 0.05, Kruskal-Wallis). One potential means by
which elevations in cytosolic Ca2+ levels
could suppress L-type Ca2+ currents is via
the Ca2+-dependent phosphatase calcineurin
(Chad and Eckert, 1986). To test this possibility, neurons were
dialyzed with a peptide inhibitor of calcineurin (25 µM) (Hashimoto et al., 1990). As shown in
Figure 6C, the calcineurin inhibitor significantly reduced
the NPA modulation of the BAYK-enhanced tail currents in
enkephalin-expressing neurons (n = 4; median
modulation = 5%; p < 0.05, Kruskal-Wallis)
without blocking the modulation of non-L-type currents (median
modulation = 15%; p < 0.05, Kruskal-Wallis).
In contrast, inhibition of protein phosphatase 1 and 2A with okadaic
acid (1 µM) had no effect on the ability of
D2 agonists to suppress the BAYK-enhanced tail current (n = 2; median modulation = 20%;
p > 0.05, Kruskal-Wallis).
D2 receptor activation suppresses spike activity evoked
from depolarized membrane potentials
L-type Ca2+ currents are important
determinants of evoked spike activity in medium spiny neurons
(Hernandez-Lopez et al., 1997). The influence of these currents can be
seen by holding medium spiny neurons at a depolarized level, close to
that seen in the upstate in vivo. At this potential, a brief
current pulse is capable of triggering a prolonged depolarization
(hundreds of milliseconds) that occasionally results in spike
generation. This type of response was seen in approximately two-thirds
of all trials with a given neuron; in the other trials, the membrane
potential decayed passively back to the "resting" potential. In the
presence of the L-type channel agonist BAYK 8644, this quasibistable
response was enhanced in duration and probability (Fig.
7A). Spikes become a much more common event in this situation as well. On the other hand, in the
presence of the L-type channel antagonist nicardipine (5 µM), the bistable behavior was almost entirely
abolished, resulting in passive membrane responses in the vast majority
of trials (Hernandez-Lopez et al., 1997). D2
receptor stimulation also suppressed the bistable behavior. In the
presence of quinpirole (10 µM), the probability of evoking a sustained depolarization dropped significantly
(n = 6; p < 0.05, Kruskal-Wallis),
even in the presence of BAYK 8644 (Fig. 7A).
View larger version (35K):
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|
Figure 7.
D2 receptor stimulation suppresses
evoked activity in medium spiny neurons recorded in brain slices.
A, At depolarized membrane potentials mimicking the
upstate in medium spiny neurons, a brief current pulse (see protocol
below the traces) evokes a sustained
depolarization in the presence of BAYK 8644 (2.5 µM). The
depolarization was significantly shortened by the addition of
quinpirole (10 µM). Similar results were seen in all six
cells tested. B, Intracellular recordings from medium
spiny neurons in the presence of TEA (20 mM) are shown.
Cells were maintained near 60 mV. Top, Quinpirole (10 µM) shortened the duration of the TEA spike (median
reduction = 25%; n = 3).
Bottom, In the presence of nicardipine (5 µM), the TEA spike was of shorter duration. The addition
of quinpirole had little or no effect in the presence of nicardipine
(median reduction = 2%; n = 3).
C, Activity evoked by intracellular current injection
from a depolarized (approximately 65 mV) membrane potential was
suppressed by quinpirole. Left, Records evoked by
increasing current steps (300 msec in duration) in control conditions
are shown. Right, Records taken from the same cell after
the addition of quinpirole (10 µM) are shown. Note that
in the presence of quinpirole, the discharge frequency decreased for
similar current steps. D, Plots of discharge frequency
as a function of injected current for the neuron in C
are shown. Top, The plot is the frequency (reciprocal of
first interspike interval) in the presence and absence of quinpirole
(10 µM). Bottom, The average of the last
four interspike intervals in the evoked train in the presence and
absence of quinpirole is shown. Similar results were obtained in five
other responsive neurons.
|
|
D2 receptor stimulation also shortened the
duration of tetraethylammonium (TEA)-enhanced
Ca2+ spikes in medium spiny neurons. When
held at 60 mV in the presence of TEA (20 mM), a brief
current stimulus evoked an all-or-none Ca2+ spike in medium spiny neurons (Kita
et al., 1985; Bargas et al., 1989). In this recording situation, the
duration of the Ca2+ spike was 210 ± 35 msec (mean ± SD; n = 40). If nicardipine (5 µM) or nitrendipine (5 µM) were added, the
Ca2+ spike was reduced in duration to
150 ± 40 msec (n = 15). As with the L-type
channel antagonists, quinpirole (10 µM) reduced
the duration of the TEA-induced Ca2+ spike
in all three cells tested (mean duration = 160 ± 30 msec) (Fig. 7B, top). In the presence of nicardipine (5 µM), quinpirole failed to exert any further
reduction of the Ca2+ spike in three of
five neurons (Fig. 7B, bottom).
By providing a sustained depolarizing influence, L-type
Ca2+ currents enhance repetitive activity
evoked from depolarized membrane potentials in medium spiny neurons
(Hernandez-Lopez et al., 1997). D2
receptor-mediated suppression of these currents should diminish evoked
spiking. Intracellular recordings from medium spiny neurons in tissue
slices confirmed this conjecture. Neurons were slightly depolarized
(approximately 65 mV) by steady current injection, and then
repetitive activity was evoked by current steps. From these
"upstate" membrane potentials, quinpirole (10 µM)
diminished evoked spiking in 6 of 10 neurons (Fig. 7C). The
suppression of repetitive activity was particularly evident with small
current injections that come close to mimicking in vivo
conditions (Fig. 7D, top). But, the reduction in
firing frequency induced by quinpirole was evident via the whole
intensity- frequency plot (Fig. 7D). In
quinpirole-responsive neurons, the half-maximum frequency was reduced
from 45 ± 10 to 33 ± 12 Hz by quinpirole (n = 6; p < 0.05, Kruskal-Wallis). The ability of
quinpirole to alter evoked activity was suppressed by blockade of
L-type channels with nicardipine (5 µM;
n = 3). Taken together, these results clearly argue
that D2 receptor modulation of L-type
Ca2+ channels results in a suppression of
repetitive spiking evoked from depolarized potentials in medium spiny neurons.
| |
DISCUSSION |
D2 receptors in striatal medium spiny neurons activate
a PLC-IP3-calcineurin cascade
The results presented show that activation of
D2 receptors reduces currents through L-type
Ca2+ channels, leading to a suppression of
evoked spike activity in enkephalin-expressing striatal medium spiny
neurons. Even though nearly all striatal effects of
D2 receptor activation are ascribed to the
inhibition of adenylyl cyclase activity (Sibley, 1995), this signaling
linkage was not responsible for the modulation of L-type
Ca2+ channels. Manipulation of adenylyl
cyclase activity, cAMP metabolism, and dialysis with a competitive
inhibitor of cAMP had no effect on the modulation. Rather, the
D2 receptor modulation depended on
G protein activation
of a PLC1-signaling cascade, mobilization of intracellular
Ca2+, and activation of calcineurin. This
conclusion is based on five observations. First, the
D2 receptor suppression of L-type currents was
blocked by inhibition of
G signaling. Second,
medium spiny neurons expressed readily detectable levels of PLC1
mRNA (but not that of other PLC isoforms), and the modulation was blocked by inhibitors of PLC1. Third, D2
receptor stimulation induced the release of
Ca2+ from intracellular stores. Fourth,
disruption of IP3 signaling or chelation of
intracellular Ca2+ blocked the modulation.
Lastly, inhibition of the Ca2+-dependent
phosphatase calcineurin blocked the modulation. Dephosphorylation by
calcineurin has been shown to mediate reductions in L-type Ca2+ currents in a variety of cell types
(Chad and Eckert, 1986; Armstrong et al., 1991; Lukyanetz et al.,
1998). In an intact preparation, the D2
receptor-triggered activation of calcineurin may act cooperatively with
a direct Ca2+-calmodulin-mediated
inactivation process (Imredy and Yue, 1994; Peterson et al., 1999) to
suppress currents through L-type Ca2+
channels further.
Although previous biochemical studies of striatal slices have not
reported D2 receptor stimulation of PLC (Gupta
and Mishra, 1990; Rubinstein and Hitzemann, 1990), striatal cellular
heterogeneity complicates the interpretation of these studies.
Indiscriminate activation of striatal D2
receptors can be expected to have two opposing effects. One is
activation of PLC in enkephalinergic medium spiny neurons. The other is
diminished acetylcholine release (Drukarch et al., 1990) and a
reduction in M1 muscarinic receptor stimulation of PLC in medium spiny
neurons (Akins et al., 1990; Bernard et al., 1992). Hence, there may be
no net change in striatal PLC activity after global
D2 receptor activation. Although they have not
provided a clear picture of the signaling mechanism, studies using
heterologous expression systems have shown that D2 receptors are capable of stimulating PLC and
mobilizing intracellular Ca2+ pools
(Vallar et al., 1990; MacKenzie et al., 1994; Yang et al., 1995).
The ability of striatal D2 receptors to mobilize
intracellular Ca2+ stores, reduce L-type
Ca2+ channel currents, and suppress evoked
activity effectively reconciles an apparently divergent set of
observations. On one hand, D2 receptor activation
is known to increase striatal calcineurin and MAP kinase activity via
Ca2+-dependent mechanisms (Nishi et al.,
1997; Yan et al., 1999). On the other hand, blockade of
D2 receptors or diminished
D2 receptor tone is known to increase striatal
immediate early gene (IEG) and peptide expression (Chesselet et al.,
1998). D2 receptor activation also is necessary
for certain forms of striatal use-dependent synaptic plasticity
(Calabresi et al., 1992). Our results directly demonstrate calcineurin
activation by D2 receptors and provide a
mechanism for Ca2+-dependent MAP kinase
activation. Calcineurin-mediated suppression of L-type
Ca2+ currents will reduce
glutamate-induced CRE-binding protein phosphorylation and IEG induction
(Rajadhyaksha et al., 1999). By the same token, this
D2 receptor-signaling pathway provides a ready
alternative to disinhibition of adenylyl cyclase (Ward and Dorsa, 1999)
in explaining the ability of D2 receptor
antagonists to increase sharply striatal IEG induction after cortical
stimulation (Berretta et al., 1999).
D2 receptor activation selectively suppresses activity
in enkephalin-expressing medium spiny neurons
In addition to reconciling these more recent observations, our
results provide the first direct evidence for one of the oldest conjectures about dopaminergic regulation of striatal activity, namely,
that D2 receptor activation selectively
suppresses the activity of enkephalin-expressing medium spiny neurons
(Albin et al., 1989). This conjecture has served as a cornerstone of basal ganglia models and treatment strategies for Parkinson's disease
for over a decade. Yet, the evidence for this conjecture has been
indirect or inconclusive (Nicola et al., 2000).
Our results show that D2 receptor stimulation
inhibits activity evoked from relatively depolarized membrane
potentials mimicking the upstate produced by excitatory cortical
or thalamic inputs (Wilson and Kawaguchi, 1996). In vivo,
medium spiny neurons move between this depolarized upstate in which
they generate spikes and a hyperpolarized "downstate" in which they
are quiescent. Although other voltage-dependent channel types are
modulated in concert (Surmeier et al., 1992; Surmeier and Kitai, 1993;
Waszczak et al., 1998), the D2 receptor
suppression of L-type Ca2+ currents is
critical to this inhibition of activity. Why? Unlike N- and P/Q-type
voltage-dependent Ca2+ channels in medium
spiny neurons, L-type channels are active in the subthreshold potential
range of the upstate (Bargas et al., 1994; Song and Surmeier, 1996).
This property allows them to exert an important influence on the
membrane potential near spike threshold, pushing the membrane potential
closer or pulling it farther away from spike generation. Medium spiny
neurons expressing D1 receptors use this property
of L-type Ca2+ currents to enhance evoked
activity in the presence of dopamine (Surmeier et al., 1995;
Hernandez-Lopez et al., 1997). In contrast, activation of
D2 receptors in enkephalin-expressing neurons
should reduce both the magnitude and duration of the response to
cortical or thalamic excitatory synaptic input, as predicted over a
decade ago by Albin et al. (1989). Moreover, by targeting a
Ca2+ channel with privileged access to
transcriptional regulation (Bading et al., 1993; Graef et al., 1999;
Mermelstein et al., 2000), D2 receptors exert a
proximal control over gene expression tied to extrinsically driven
activity. This proximal coupling may prove to be very important to
long-term striatal adaptations triggered by alterations in dopaminergic
signaling in Parkinson's disease, prolonged neuroleptic treatment, and
drug abuse (Hornykiewcz, 1973; Meltzer and Stahl, 1976; Nestler and
Aghajanian, 1997).
| |
FOOTNOTES |
Received July 25, 2000; revised Sept. 15, 2000; accepted Sept. 21, 2000.
This work was supported by National Institutes of Health Grants NS
34696, DA 12958, and TW 01214 to D.J.S. and EY 10291 to H.H. Additional
support was provided by Consejo Nacional de Ciencia y Tecnologia Grant
25812N to J.B. and E.G. We thank Sasha Ulrich for assistance with the
RT-PCR experiments.
Correspondence should be addressed to Dr. D. James Surmeier, Department
of Physiology, Northwestern University Institute for Neuroscience, Northwestern University Medical School, 320 East Superior Street, Chicago, IL 60611. E-mail:
j-surmeier{at}northwestern.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
