 |
 Previous Article | Next Article 
The Journal of Neuroscience, November 1, 2002, 22(21):9185-9193
Dopamine D4 Receptors Modulate GABAergic Signaling in
Pyramidal Neurons of Prefrontal Cortex
Xun
Wang,
Ping
Zhong, and
Zhen
Yan
Department of Physiology and Biophysics, State University of New
York at Buffalo, School of Medicine and Biomedical Sciences, Buffalo,
New York 14214
 |
ABSTRACT |
Dopaminergic neurotransmission in the prefrontal cortex (PFC) plays
an important role in regulating cognitive processes and emotional
status. The dopamine D4 receptor, which is highly enriched in the PFC, is one of the principal targets of antipsychotic drugs. To
understand the cellular mechanisms and functional implications of
D4 receptors, we examined the impact of D4
receptors in PFC pyramidal neurons on GABAergic inhibition, a key
element in the regulation of "working memory." Application of the
D4 agonist N-(methyl)-4-(2-cyanophenyl)piperazinyl-3-methylbenzamide
maleate caused a reversible decrease in postsynaptic
GABAA receptor currents; this effect was blocked by the
D4 antagonist
3-[(4-[4-chlorophenyl]piperazine-1-yl)methyl]-[1H]-pyrrolo[2,3-b]pyridine but not by the D2 antagonist sulpiride, suggesting
mediation by D4 receptors. Application of PD168077 also
reduced the GABAA receptor-mediated miniature IPSC
amplitude in PFC pyramidal neurons recorded from slices. The
D4 modulation of GABAA receptor currents was
blocked by protein kinase A (PKA) activation and occluded by PKA
inhibition. Inhibiting the catalytic activity of protein phosphatase 1 (PP1) also eliminated the effect of PD168077 on GABAA
currents. Furthermore, disrupting the association of the PKA/PP1
complex with its scaffold protein Yotiao significantly attenuated the
D4 modulation of GABAA currents, suggesting
that Yotiao-mediated targeting of PKA/PP1 to the vicinity of
GABAA receptors is required for the dopaminergic signaling.
Together, our results show that activation of D4 receptors in PFC pyramidal neurons inhibits GABAA channel functions
by regulating the PKA/PP1 signaling complex, which could underlie the
D4 modulation of PFC neuronal activity and the actions of
antipsychotic drugs.
Key words:
dopamine receptors; GABAA receptor channels; protein kinase A; protein phosphatase 1; Yotiao; inhibitor-1
| |
INTRODUCTION |
The prefrontal cortex (PFC), a brain
region highly associated with cognitive and emotional processes
(Goldman-Rakic, 1995 ; Miller, 1999), receives a major dopaminergic
input from the ventral tegmental area (Lewis et al., 1986; Berger et
al., 1988). Regional depletion of dopamine in the PFC of monkeys
produces impairments in working memory performance (Brozoski et al.,
1979), suggesting that PFC dopaminergic transmission plays a key role
in cognitive functions. Disorders in dopaminergic signaling are thought
to underlie the etiology of many neuropsychiatric disorders, including schizophrenia and depression (Desimone, 1995), and almost all effective
antipsychotic drugs target dopamine receptors (Lidow and Goldman-Rakic,
1994; Seeman and Van Tol, 1994). Dopamine can have both inhibitory and
excitatory functions in neuronal networks through the coupling of
different dopamine receptors to distinct ion channels (for review, see
Nicola et al., 2000). These receptors have been classified as either
D1-like (D1,
D5) or D2-like
(D2, D3,
D4), based on their sequence homology,
pharmacological profiles, and distinct downstream signal transduction
pathways. Although considerable evidence suggests that
D1 receptors are critically involved in
regulating the working memory functions of the PFC (Sawaguchi and
Goldman-Rakic, 1991; Williams and Goldman-Rakic, 1995), little is known
about the cellular mechanisms and functional consequences of
D2-like receptor-mediated signaling in the PFC.
Among the D2-like receptors,
D4 receptor is expressed at the highest level in
PFC pyramidal principal neurons and GABAergic interneurons (Mrzljak et
al., 1996; Wedzony et al., 2000). Given its high affinity for atypical
antipsychotic drugs that constitute a major improvement in the
treatment of schizophrenia (Van Tol et al., 1991; Kapur and Remington,
2001), D4 receptor has been suggested to play an
important role in PFC cognitive functions and therefore to be involved
in the pathophysiology of neuropsychiatric disorders (for review, see
Oak et al., 2000). In agreement with this, D4
receptor antagonists have been found to alleviate stress-induced working memory deficits in monkeys (Murphy et al., 1996) and to ameliorate the cognitive deficits exhibited by monkeys after long-term treatment with the psychotomimetic drug phencyclidine (Jentsch et al.,
1997, 1999). Moreover, altered cortical excitability and reduced
exploration of novel stimuli have been shown in
D4 receptor-deficient mice (Dulawa et al., 1999;
Rubinstein et al., 2001), and significantly elevated
D4 receptors have been demonstrated in patients
with schizophrenia (Seeman et al., 1993). To better understand the functional role of D4 receptors under normal and
pathological conditions, it is important to determine cellular
substrates of D4 receptors that are involved in
the modulation of PFC neuronal activity and cognitive processes.
Recent evidence indicates that GABAergic inhibition in the PFC plays a
key role in working memory by sculpting the temporal profile of
activation of the neurons during cognitive operations and
thereby shaping the temporal flow of information (Constantinidis et al., 2002). Computational models of the dopaminergic modulation of
working memory processing predict that dopamine-mediated alterations in
GABAA currents in PFC pyramidal neurons are
critical for maintaining the specificity and stability of delay-period
activity (Durstewitz et al., 2000). Therefore, understanding how the
D4 receptor modulates GABAergic inhibition would
provide important insights into its role in cognitive functions
associated with the PFC.
| |
MATERIALS AND METHODS |
Acute-dissociation procedure. PFC neurons from young
adult (3-5 weeks postnatal) rats were acutely dissociated using
procedures similar to those described previously (Yan and Surmeier,
1996; Feng et al., 2001; Cai et al., 2002). All experiments were
performed with the approval of the State University of New York at
Buffalo Animal Care Committee. In brief, rats were anesthetized by
inhaling 2-bromo-2-chloro-1,1,1-trifluoroe-thane (1 ml/100 gm;
Sigma, St. Louis, MO) and decapitated; the brains were quickly
removed, iced, and then blocked for slicing. The blocked tissue was cut
in 400 µm slices with a Vibratome while bathed in a low
Ca2+ (100 µM),
HEPES-buffered salt solution containing (in mM):
140 Na isethionate, 2 KCl, 4 MgCl2, 0.1 CaCl2, 23 glucose, 15 HEPES, 1 kynurenic acid, pH
7.4, 300-305 mosm/l. Slices were then incubated for 1-6 hr at room
temperature (20-22°C) in an NaHCO3-buffered saline containing (in mM): 126 NaCl, 2.5 KCl, 2 CaCl2, 2 MgCl2, 26 NaHCO3, 1.25 NaH2PO4, 10 glucose, 1 pyruvic acid, 0.05 glutathione, 0.1 NG-nitro-L-arginine,
1 kynurenic acid, pH 7.4, 300-305 mosm/l, and bubbled with 95%
O2 and 5% CO2. All
reagents were obtained from Sigma.
Slices were then removed into the low Ca2+
buffer, and regions of the PFC were dissected and placed in an
oxygenated Cell-Stir chamber (Wheaton, Inc., Millville, NJ) containing
pronase (1-3 mg/ml) in HEPES-buffered HBSS (Sigma) at 35°C.
After 30 min of enzyme digestion, tissue was rinsed three times in the
low Ca2+, HEPES-buffered saline and
mechanically dissociated with a graded series of fire-polished Pasteur
pipettes. The cell suspension was then plated into a 35 mm Lux Petri
dish, which was then placed on the stage of a Nikon (Tokyo, Japan)
inverted microscope.
Whole-cell recordings. Whole-cell recordings of currents
used standard voltage-clamp techniques (Hamill et al., 1981; Yan and
Surmeier, 1997). Electrodes were pulled from Corning (Corning, NY) 7052 glass and fire-polished before use. The internal solution (Yan and
Surmeier, 1997) consisted of (in mM): 180 N-methyl-D-glucamine, 40 HEPES,
4 MgCl2, 0.5 BAPTA, 12 phosphocreatine, 2 Na2ATP, 0.2 Na3GTP, 0.1 leupeptin, pH 7.2-7.3, 265-270 mosm/l. The external solution
consisted of (in mM): 135 NaCl, 20 CsCl, 1 MgCl2, 10 HEPES, 5 BaCl2,
10 glucose, 0.001 TTX, pH 7.3-7.4, 300-305 mosm/l.
Recordings were obtained with an Axon Instruments (Union City, CA) 200B
patch-clamp amplifier that was controlled and monitored with an IBM
personal computer running pClamp (version 8) with a DigiData 1320 series interface. Electrode resistances were typically 2-4 M in the
bath. After seal rupture, series resistance (4-10 M) was
compensated (70-90%) and periodically monitored. Care was exercised
to monitor the constancy of the series resistance; recordings were
terminated whenever a significant increase (>20%) occurred. The cell
membrane potential was held at 0 mV. The application of GABA (50 µM) evoked a partially desensitizing outward current with
the decay rate fitted by a single or double exponential. Peak values
were measured for generating the plot as a function of time and drug
application. GABA was applied for 2 sec every 30 sec to minimize a
desensitization-induced decrease in current amplitude. Drugs were
applied with a gravity-fed "sewer pipe" system. The array of
application capillaries (~150 µm inner diameter) was
positioned a few hundred micrometers from the cell under study. Solution changes were effected by the SF-77B fast-step solution stimulus delivery device (Warner Instruments, Hamden, CT).
Dopamine receptor ligands
N-(methyl)-4-(2-cyanophenyl)piperazinyl-3-methybenzamide
maleate (PD168077) maleate,
3-[(4-[4-chlorophe-nyl]piperazine-1-yl)methyl]-[1H]-pyrrolo[2,3-b]pyridine trihydrochloride (L-745870) (Tocris, Ballwin, MO),
R,S-(±)-sulpiride and clozapine (Sigma), as well as the
second messenger reagents chlorophenylthio-cAMP (cpt-cAMP),
PKC19-36, and PKI[5-24] (Calbiochem, San
Diego, CA), microcystin, okadaic acid (OA), and okadaic acid methyl
ester (OAE) (Sigma/RBI, Poole, UK) were made up as concentrated stocks
in water or DMSO and stored at  20°C. The final DMSO concentration
in all applied solutions was <0.1%. No change on
GABAA currents has been observed with this
concentration of DMSO. Stocks were thawed and diluted immediately
before use. The amino acid sequence for the phosphorylated I-1 peptide
pThr35I-1[7-39] is
PRKIQFTVPLLEPHLDPEAAEQIRRRRP(pT)PATL. The amino acid sequence for the
PKA anchoring inhibitory peptide Yotiao[1440-1457] is
LEEEVAKVIVSMSIAFAQ. The amino acid sequence for the protein phosphatase
1 (PP1) anchoring inhibitory peptide Gm[63-75] is GRRVSFADNFGFN.
Data analyses were performed with AxoGraph (Axon Instruments),
Kaleidagraph (Albeck Software, Reading, PA), Origin 6 (OriginLab Co.,
Northampton, MA), and Statview (Abacus Concepts, Calabasas, CA). For
analysis of statistical significance, Mann-Whitney U tests
were performed to compare the current amplitudes in the presence or
absence of agonists. ANOVA tests were performed to compare the
differential degrees of current modulation between groups subjected to
different treatments.
Electrophysiological recordings in slices. To evaluate the
regulation of miniature IPSCs (mIPSCs) by
D4 receptors in PFC slices, the whole-cell patch
technique was used for voltage-clamp recordings using patch electrodes
(5-9 M) filled with the following internal solution (in
mM): 130 Cs-methanesulfonate, 10 CsCl, 4 NaCl, 10 HEPES, 1 MgCl2, 5 EGTA, 12 phosphocreatine, 5 MgATP, 0.2 Na3GTP, 0.1 leupeptin, pH 7.2-7.3,
265-270 mosm/l. The slice (300 µm) was placed in a perfusion chamber
attached to the fixed-stage of an upright microscope (Olympus Optical,
Tokyo, Japan) and submerged in continuously flowing oxygenated
artificial CSF. Cells were visualized with a 40× water-immersion lens
and illuminated with near infrared (IR) light and the image was
detected with an IR-sensitive CCD camera (Olympus Optical). A
Multiclamp 700A amplifier was used for these recordings (Axon
Instruments). Tight seals (2-10 G) from visualized pyramidal
neurons were obtained by applying negative pressure. The membrane was
disrupted with additional suction and the whole-cell configuration was
obtained. The access resistances ranged from 13 to 18 M and were
compensated 50-70%. Cells were held at 0 mV for the continuous
recording of mIPSCs. The Mini Analysis Program (Synaptosoft, Leonia,
NJ) was used to analyze synaptic activity. For each different
treatment, mIPSCs of 1 min were used for analysis. Statistical
comparisons of the synaptic currents were made using the
Kolmogorov-Smirnov (K-S) test.
| |
RESULTS |
Activation of D4 receptors reduces GABAA
receptor currents in prefrontal cortical pyramidal neurons
To test the potential impact of D4 dopamine
receptors on postsynaptic GABAA receptor channels
in PFC, we first examined the effect of PD168077, a potent and highly
selective D4 receptor agonist (Glase et al.,
1997), on GABAA receptor-mediated currents in
dissociated pyramidal neurons located in the intermediate and deep
layers (III-VI) of the rat PFC. Acutely isolated PFC pyramidal neurons
were readily distinguished from GABAergic interneurons by their
distinct morphological features: a pyramidal-shaped soma and a
prominent apical dendrite. A representative example is shown in Figure
1A. GABA (50 µM) was applied to these neurons, which were
voltage-clamped using whole-cell techniques. The application of GABA
evoked a partially desensitizing outward current that could be
completely blocked by the GABAA receptor
antagonist bicuculline (30 µM, data not shown),
confirming mediation by the GABAA receptor.
View larger version (26K):
[in this window]
[in a new window]
|
Figure 1.
Application of the D4
agonist PD168077 reversibly reduced GABAA receptor currents
in PFC pyramidal neurons. A, Photomicrograph of an
acutely isolated PFC pyramidal neuron. B, Current
traces recorded from the neuron shown in
A. The D4 agonist PD168077
(PD; 20 µM) reduced GABA-evoked (50 µM) currents in the cell. C, Plot of peak
GABAA current as a function of time and agonist application
in a sample of dissociated PFC pyramidal neurons (n = 45).
|
|
As shown in Figure 1B, application of PD168077 (20 µM) caused a reduction in the amplitudes of
GABAA currents in PFC pyramidal neurons. The
modulation was not accompanied by changes in current decay kinetics.
The PD168077-induced reduction of GABAA currents was reversible, and it had rapid-onset kinetics, taking 1-2 min to
stabilize (Fig. 1C). In a sample of neurons we examined,
PD168077 (20 µM) reduced the amplitude of
GABA-evoked (50 µM) currents by 15.4 ± 0.6% (n = 86; p < 0.01; Mann-Whitney
U test). After recovery from the first application, a second
application of PD168077 resulted in a similar response (93.2 ± 2.4% of first response; n = 18). This PD168077-induced
inhibition of GABAA currents did not result from
an agonist-independent rundown of the current, because no significant
decrease in the current was observed in the absence of PD168077.
Similar modulation was observed when different concentrations (25 µM, 100 µM, and 1 mM) of GABA were applied or membrane potentials
were held at different levels (40 mV, 20 mV, and 0 mV) (data not
shown). In contrast to the inhibitory effect on GABA-evoked currents,
PD168077 (20-50 µM) had no effect on
glutamate-evoked (1 mM) currents in dissociated
PFC pyramidal neurons tested (n = 10; data not shown).
To verify that D4 receptors were mediating the
modulation seen with PD168077, we examined the ability of L-745870, a
highly selective D4 antagonist (Kulagowski et
al., 1996; Patel et al., 1997), to prevent the action of PD168077.
Dissociated neurons were treated with L-745870 for 15 min before the
examination of the PD168077 effect. As shown in Figure
2A and B, in
the presence of the D4 antagonist L-745870 (20 µM), PD168077 failed to modulate GABAA currents. In contrast, the PD168077-induced
reduction of GABAA currents was still intact in
neurons treated with the D2 receptor antagonist
sulpiride (20 µM). Because the atypical
antipsychotic clozapine has higher affinity to D4
receptors compared with D2 receptors (Van Tol et
al., 1991), we also examined the effect of clozapine on PD168077
modulation of GABAA currents. As shown in Figure
2C, treating neurons with clozapine (20 µM) blocked the PD168077-induced reduction of
GABAA currents. The percentage modulation of
GABAA currents by PD168077 in the absence or
presence of various antagonists is summarized in Figure
2D. PD168077 had little effect on
GABAA currents in neurons treated with L-745870 (4.2 ± 1.8%; n = 24; p > 0.05;
Mann-Whitney U test) or clozapine (3.6 ± 0.4%;
n = 10; p > 0.05; Mann-Whitney
U test), which was significantly different from the effect
of PD168077 on control cells (15.3 ± 1.1%; n = 36; p < 0.005; ANOVA) or sulpiride-treated neurons
(14.8 ± 2.6%; n = 11; p < 0.005; ANOVA). The pharmacological profile of these responses thus
identifies D4 as the receptor underlying the
PD168077-induced inhibition of GABAA
currents.
View larger version (36K):
[in this window]
[in a new window]
|
Figure 2.
The effect of PD168077 on GABAA
receptor currents was mediated by D4 receptors.
A, Plot of peak GABAA current as a function
of time and agonist application in an L-745870-treated neuron
(L-745; diamonds) and a sulpiride-treated
neuron (circles). The selective D4
antagonist L-745870 (20 µM) but not the D2
antagonist sulpiride (20 µM) blocked PD168077-induced
reduction of GABAA currents. B,
Representative current traces taken from the records
used to construct A (at time points denoted by #).
C, Plot of peak GABAA current as a function
of time and agonist application in a clozapine-treated (20 µM) neuron (triangles) and a nontreated
control neuron (circles). D, Cumulative
data (means ± SEM) showing the percentage modulation of
GABAA currents by PD168077 in the absence
(n = 36) or presence of L-745870
(n = 24), sulpiride (n = 11),
or clozapine (n = 10). *p < 0.005; ANOVA.
|
|
Activation of D4 receptors decreases GABAA
receptor-mediated synaptic transmission in prefrontal cortex
We then examined the effect of PD168077 on
GABAA receptor-mediated IPSCs, indicative of the
impact of D4 receptors on GABAergic synaptic
transmission. PFC slices were exposed to TTX (1 µM), and
mIPSCs were recorded in PFC pyramidal neurons to better isolate the
postsynaptic effect of D4 receptors. Application
of bicuculline (30 µM) blocked the mIPSCs
(n = 5), indicating that these synaptic currents are
mediated by GABAA receptors. As shown in Figure
3A-C, bath application of
PD168077 to the PFC slice caused a significant and reversible leftward
shift on the distribution of mIPSC amplitudes (p < 0.001; K-S test), but not the distribution of mIPSC frequencies, indicating that PD168077 reduced postsynaptic responses to GABA. In a
sample of PFC pyramidal neurons we examined, PD168077 decreased the
mean amplitude of mIPSCs by 21.1 ± 1.1% (Fig. 3D)
(means ± SEM; n = 27; p < 0.01;
Mann-Whitney U test), whereas the frequency of mIPSCs
recorded from PFC pyramidal neurons in slices was not significantly
changed by PD168077 (Fig. 3D) (6.4 ± 4.1%;
n = 27; p > 0.05; Mann-Whitney
U test). These results suggest that activation of
D4 receptors could downregulate
GABAA receptor functions by a postsynaptic
mechanism.
View larger version (35K):
[in this window]
[in a new window]
|
Figure 3.
Activation of D4 receptors reduced the
amplitude of mIPSCs recorded from pyramidal neurons in PFC slices.
A, Cumulative plots of the amplitude of mIPSCs in a PFC
pyramidal neuron. Note that PD168077 (PD; 20 µM) caused a reversible leftward shift on the
distribution of mIPSC amplitudes, indicative of a reduction in the
sizes of mIPSCs by PD168077. B, Cumulative plots of the
frequency of mIPSCs in the same cell demonstrating that the
distribution of mIPSC frequency was not changed by PD168077 (20 µM). C, Representative
traces of mIPSCs recorded from the cell before (control,
ctl), during bath application of PD168077, and
after washout of the agonist. D, Cumulative data
(means ± SEM) showing the percentage modulation of mIPSC
amplitude and mIPSC frequency by PD168077 in a sample of PFC pyramidal
neurons (n = 27).
|
|
D4 modulation of GABAA currents is
dependent on the inhibition of protein kinase A
We subsequently examined the signal transduction pathways
mediating the modulation of GABAA currents by
D4 receptors. GABAA channels are thought to be heteropentameric structures, composed of
different subunits (Macdonald and Olsen, 1994). PKA phosphorylation of
GABAA receptor subunits exerts a powerful impact
on recombinant and native GABAA channels (Porter
et al., 1990; Moss et al., 1992a,b). Activation of
D4 receptors can inhibit adenylate cyclase and
cAMP formation in transfected cell lines (Chio et al., 1994). This led
us to speculate that the D4 reduction of
GABAA currents is through the inhibition of PKA.
If that is the case, then the effect of D4
receptors on GABAA receptor currents should be
blocked by stimulating PKA and occluded by inhibiting PKA. To test
this, we applied selective PKA activators and inhibitors.
As shown in Figure 4A
and B, application of the membrane-permeable cAMP analog
cpt-cAMP (200 µM) caused a small increase in basal GABAA currents. In the presence of
cpt-cAMP, PD168077 failed to reduce GABAA
currents. Removing cpt-cAMP restored the ability of PD168077 to inhibit
GABAA currents. To further confirm the involvement of PKA in D4 modulation of
GABAA currents, we dialyzed neurons with the
specific PKA inhibitory peptide PKI[5-24] (Knighton et al., 1991).
The PKC inhibitory peptide PKC19-36 (20 µM) was used as a control. After ~5 min of
dialysis to allow the peptide to enter the cell to inhibit kinase
activity, the effect of the subsequent application of PD168077 on
GABAA currents was examined. As shown in Figure
4C-E, the PD168077-induced reduction of
GABAA currents was largely abolished in neurons
dialyzed with PKI[5-24] but was almost intact in neurons loaded with
PKC19-36. Figure 4F compares
the effects of PD168077 in the absence or presence of various kinase
activators and inhibitors. PD168077 reduced peak
GABAA currents by 4.3 ± 0.8% in the
presence of cpt-cAMP (n = 12; p > 0.05; Mann-Whitney U test) and 4.8 ± 0.8% in the presence of PKI[5-24] (n = 8; p > 0.05; Mann-Whitney U test), both of which were
significantly smaller than the effect of PD168077 in the absence of
these agents (16.2 ± 1.0%; n = 13;
p < 0.005; ANOVA) or in the presence of
PKC19-36 (14.8 ± 1.6%; n = 14; p < 0.005; ANOVA). These results indicate that
reduction of GABAA currents by PD168077 depends
on the inhibition of PKA.
View larger version (35K):
[in this window]
[in a new window]
|
Figure 4.
The effect of PD168077 on GABAA
currents was blocked by PKA activation and occluded by PKA inhibition.
A, Plot of peak GABAA currents as a function
of time and drug application. In the presence of the membrane-permeable
cAMP analog cpt-cAMP (200 µM), PD168077
(PD; 20 µM) failed to reduce
GABAA currents. After washing off cpt-cAMP, the effect of
PD168077 emerged. B, Representative current
traces taken from the records used to construct
A (at time points denoted by #). C, Plot
of peak GABAA currents as a function of time and drug
application in neurons dialyzed with PKI[5-24] or
PKC19-36. The specific PKA inhibitory peptide PKI[5-24]
(20 µM), but not the PKC inhibitory peptide
PKC19-36 (20 µM), eliminated
PD168077-induced reduction of GABAA currents. D,
E, Representative current traces taken from the
records used to construct C (at time points denoted by
#). F, Cumulative data (means ± SEM) showing the
percentage modulation of GABAA currents by PD168077 in the
absence (n = 13) or presence of cpt-cAMP
(n = 12), PKI[5-24] (n = 8).
or PKC19-36 (n = 14).
*p < 0.005; ANOVA. ctl,
Control.
|
|
D4 modulation of GABAA currents requires
the activation of protein phosphatase 1
The D4-induced inhibition of PKA could
directly modulate GABAA currents through
decreased phosphorylation of GABAA receptor  subunits on the PKA sites (Moss et al., 1992a,b; McDonald et al., 1998;
Cai et al., 2002). Alternatively, the inhibition of PKA could cause the
disinhibition of PP1 via decreased phosphorylation of the inhibitory
protein I-1 (Ingebritsen and Cohen, 1983), leading to the increased
dephosphorylation of GABAA receptor subunits and
downregulation of GABAA currents. To test which
is the potential signaling mechanism, we examined the effect of
PD168077 on GABAA currents in the presence of
phosphatase inhibitors.
As shown in Figure 5A and
B, bath application of the PP1/2A inhibitor OA (0.5 µM) eliminated the ability of PD168077 to
inhibit GABAA currents. After washing off OA, the
D4 modulation emerged. To further confirm the
involvement of PP1/2A in D4 modulation of
GABAA currents, we dialyzed cells with
microcystin (5 µM), another structurally
different and potent PP1/2A inhibitor. In most cells tested, the basal
GABAA currents showed a time-dependent increase
(9.5 ± 1.7%; n = 7) at the initial dialysis
period (~5 min), probably attributable to the inhibition of
constitutively active PP1/2A by microcystin. After the basal
GABAA currents became stabilized, subsequent
application of PD168077 failed to reduce GABAA
currents (Fig. 5C,D). On the contrary, injecting with OAE, a
compound with a structure similar to OA but lacking the ability to
inhibit PP1/2A, did not affect the PD168077-induced inhibition of
GABAA currents (Fig. 5C,E). The effect
of PD168077 on GABAA currents in the presence of
phosphatase inhibitors or their inactive analog is summarized in Figure
5F. PD168077 caused little reduction of
GABAA currents in the presence of OA (4.8 ± 0.8%; n = 13; p > 0.05; Mann-Whitney
U test) or in the presence of microcystin (3.7 ± 0.5%; n = 9; p > 0.05; Mann-Whitney
U test), both of which were significantly different from the
effect of PD168077 in the presence of OAE (15.4 ± 1.1%;
n = 10; p < 0.005; ANOVA), suggesting the PP1 or PP2A activation is required in the D4
regulation of GABAA receptors.
View larger version (34K):
[in this window]
[in a new window]
|
Figure 5.
The effect of PD168077 (PD) on
GABAA currents was blocked by phosphatase inhibition.
A, Plot of peak GABAA currents as a function
of time and drug application. In the presence of the membrane-permeable
PP1/2A inhibitor OA, PD168077 (20 µM) failed to reduce
GABAA currents. Washing off OA led to recovery of the
effect of PD168077. B, Representative current
traces taken from the records used to construct
A (at time points denoted by #). C, Plot
of peak GABAA currents as a function of time and drug
application in neurons dialyzed with microcystin
(triangle) or OAE (circles). The PP1/2A
inhibitor microcystin (5 µM) but not the inactive agent
OAE (1 µM) eliminated the PD168077-induced reduction of
GABAA currents. D, E, Representative current
traces taken from the records used to construct
C (at time points denoted by #). F,
Cumulative data (means ± SEM) showing the percentage modulation
of GABAA currents by PD168077 in the absence
(n = 11) or presence of OA (n = 13), OAE (n = 10), or microcystin
(n = 9). *p < 0.005; ANOVA.
ctl, Control.
|
|
We then tried to determine the identity of the phosphatase involved in
the D4 regulation of GABAA
currents. I-1, once it is phosphorylated by PKA at
Thr35, acts as a specific inhibitor of PP1
(Ingebritsen and Cohen, 1983). To test the role of PP1 in
D4 modulation of GABAA
currents, we dialyzed PFC pyramidal neurons with the phosphorylated I-1 peptide pThr35I-1[7-39], derived from
the PP1 interaction region. Biochemical analysis demonstrated that the
phospho-I-1 peptide pThr35I-1[7-39]
potently inhibited PP1 catalytic activity with an
IC50 at the nanomolar range, whereas the
dephospho-I-1 peptide I-1[7-39], was much less effective (Hemmings
et al., 1990; Kwon et al., 1997). As shown in Figure
6A and B,
dialysis with the active
pThr35I-1[7-39] peptide (40 µM) but not the inactive control peptide I-1[7-39] (40 µM) abolished the ability of
PD168077 to modulate GABAA currents. In summary,
in cells dialyzed with the
pThr35I-1[7-39] peptide, PD168077
reduced GABAA currents by 2.3 ± 0.8% (n = 18; p > 0.05; Mann-Whitney
U test), which was significantly smaller than the effect of
PD168077 in cells dialyzed with the inactive I-1[7-39] control
peptide (13.2 ± 2.5%; n = 7; p < 0.005; ANOVA). These results indicate direct involvement of PP1,
which links D4 receptor activation to a reduction
of GABAA currents.
View larger version (23K):
[in this window]
[in a new window]
|
Figure 6.
The effect of PD168077 (PD) on
GABAA currents was blocked by I-1 inhibition of PP1
activity. A, Plot of peak GABAA currents as
a function of time and drug application in neurons dialyzed with the
phosphorylated I-1 peptide pThr35I-1[7-39] or the
dephosphorylated I-1[7-39] control peptide. The constitutively
active peptide pThr35I-1[7-39] (40 µM) but not the inactive control peptide I-1[7-39] (40 µM) blocked PD168077 modulation of GABAA
currents. B, Representative current
traces taken from the records used to construct
A (at time points denoted by #).
|
|
D4 modulation of GABAA currents requires
the Yotiao-mediated anchoring of protein kinase A/ protein
phosphatase 1 complex
Emerging evidence has shown that signaling enzymes with broad
substrate selectivity, such as PKA and PP1, achieve the efficacy and
specificity of signal transduction through anchoring protein-mediated subcellular targeting to their substrates in central neurons (Colledge and Scott, 1999). Previous studies have found that the multivalent scaffold protein Yotiao binds PP1 and PKA, allowing the two enzymes to
regulate their substrates dynamically, like NMDA receptors (Westphal et al., 1999). We subsequently examined whether Yotiao is
involved in D4 modulation of
GABAA channels in PFC pyramidal neurons. If
Yotiao is responsible for targeting the PKA/PP1 complex to
GABAA receptors and allowing the kinase and
phosphatase to regulate the phosphorylation state of these substrates
effectively, then disrupting the complex should lead to the removal of
PKA/PP1 from GABAA receptors, thereby attenuating
the regulation of these channels.
Previous biochemical studies have found that a peptide encompassing
residues 1440-1457 of Yotiao blocked PKA binding in vitro (Westphal et al., 1999). Based on this result, we synthesized a
peptide, Yotiao[1440-1457], dialyzed neurons with it, and then examined the effects of D4 on
GABAA currents. As shown in Figure 7A and B, dialysis
with Yotiao[1440-1457] (10 µM) significantly attenuated the ability of PD168077 to modulate
GABAA currents. In contrast, a control peptide
with a scrambled amino acid sequence, sYotiao[1440-1457], had no
effect on D4 regulation of
GABAA currents. As summarized in Figure
7C, in a sample of PFC neurons dialyzed with the peptide
Yotiao[1440-1457], PD168077 reduced GABAA
currents by 5.9 ± 0.6% (n = 12;
p > 0.05; Mann-Whitney U test), which was significantly smaller than the effect of PD168077 in neurons dialyzed with the control peptide sYotiao[1440-1457] (17.2 ± 1.1%;
n = 7; p < 0.005; ANOVA).
View larger version (37K):
[in this window]
[in a new window]
|
Figure 7.
The D4 modulation of GABAA
receptor currents required anchoring of the PKA/PP1 complex to the
channel by Yotiao. A, Plot of peak GABAA
current as a function of time and agonist application with the PKA
anchoring inhibitory peptide Yotiao[1440-1457] (10 µM,
diamonds) or the control (ctl)
peptide sYotiao[1440-1457] (10 µM,
circles) in the recording pipette. B,
Representative current traces taken from the records
used to construct A (at time points denoted by #).
C, Cumulative data (means ± SEM) showing the
percentage modulation of GABAA currents by PD168077
(PD; 20 µM) in the presence of
Yotiao[1440-1457] peptide (n = 12) or the
scrambled control peptide sYotiao[1440-1457] (n = 7). *p < 0.005; ANOVA. D, Plot of
peak GABAA current as a function of time and agonist
application with the PP1 anchoring inhibitory peptide Gm[63-75] (10 µM, triangles) or the control peptide
sGm[63-75] (10 µM, circles) in the
recording pipette. E, Representative current
traces taken from the records used to construct
D (at time points denoted by #). F,
Cumulative data (means ± SEM) showing the percentage modulation
of GABAA currents by PD168077 (20 µM) in the
presence of Gm[63-75] peptide (n = 14) or the
scrambled control peptide sGm[63-75] (n = 8).
*p < 0.005; ANOVA.
|
|
Because the PD168077-induced reduction of GABAA
currents requires the activation of PP1, we also examined whether
blocking the binding of PP1 to Yotiao affected the
D4 modulation of GABAA currents. Previous studies have found that the PP1 targeting inhibitor peptide Gm[63-75] (Egloff et al., 1997) could disrupt PP1 binding to
Yotiao (Westphal et al., 1999), so we dialyzed PFC pyramidal neurons
with the Gm[63-75] peptide. As shown in Figure 7D,E,
dialysis with Gm[63-75] (10 µM) almost
eliminated the ability of PD168077 to modulate
GABAA currents. On the contrary, a control
peptide with a scrambled amino acid sequence, sGm[63-75], had no
effect on the D4 regulation of
GABAA currents. As summarized in Figure 7F, in a sample of PFC neurons dialyzed with the peptide
Gm[63-75], PD168077 reduced GABAA currents by
4.3 ± 0.7% (n = 14; p > 0.05; Mann-Whitney U test), which was significantly smaller than
the effect of PD168077 in neurons dialyzed with the control peptide sGm[63-75] (16.5 ± 1.2%; n = 8;
p < 0.005; ANOVA). Collectively, these data suggest
that D4 reduction of GABAA
currents requires the Yotiao-mediated anchoring of the PKA/PP1 complex.
| |
DISCUSSION |
Despite the well recognized association of
D4 receptors with schizophrenia, attention
deficit hyperactivity disorder, and other mental disorders (Oak
et al., 2000), the cellular mechanisms by which
D4 receptors modulate PFC neuronal functions
remain elusive. Anatomical studies have found that
D4 receptors are enriched in PFC (Mrzljak et al.,
1996; Ariano et al., 1997). Unlike D1 receptors that are concentrated at the dendritic spines of pyramidal neurons (Smiley et al., 1994), D4 receptors are localized
predominantly on the periphery of the cell body and dendritic processes
(Wedzony et al., 2000). Because GABAA receptors
exhibit a compartmentalized distribution on postsynaptic domains of
GABAergic synapses on the soma and proximal dendrites (Nusser et al.,
1996), it suggests that most D4 receptors may be
localized in the vicinity of GABAA receptors in
PFC pyramidal neurons.
In this study, we demonstrated that activation of
D4 receptors in PFC pyramidal neurons
significantly reduced GABAA receptor-mediated currents, indicating that the postsynaptic GABAA
receptor is one of the key cellular substrates of
D4 receptors in the PFC. Because GABAergic
inhibition in the frontal cortex is critical for controlling the timing
of neuronal activities during the thought process, which is fundamental
for processing ongoing information and planning appropriate actions at
a future time (Constantinidis et al., 2002), the
D4 modulation of GABAergic signaling could be one
of the mechanisms underlying the involvement of
D4 receptors in PFC cognitive functions. It is
conceivable that dysregulation of GABAergic inhibition by D4 receptors could contribute to the PFC
cognitive deficits associated with schizophrenia. This notion is
supported by the discovery that, in addition to elevated
D4 receptors (Seeman et al., 1993), selective
alterations in GABAA receptors, GABA content, and
GABAergic local circuit neurons have been discovered in the PFC of
patients with neuropsychiatric disorders (Benes et al., 1996; Dean et
al., 1999; Ohnuma et al., 1999; Lewis, 2000). Although it has been suggested that D4 receptors function as an
inhibitory modulator of glutamate activity in the PFC (Rubinstein et
al., 2001), D4 receptors could exert both
excitatory and inhibitory influences on the activity of neurons in the
PFC by targeting different channels (Werner et al., 1996; Wilke et al.,
1998), similar to the multifunctional feature of
D1 receptors (for review, see Nicola et al.,
2000).
The effect of dopamine on GABAergic synaptic transmission in the PFC is
complex and dependent on the receptors activated. Recent studies have
shown that dopamine produces temporally biphasic effects on GABAergic
IPSCs, which are mediated by D1 and
D2 receptors (Seamans et al., 2001).
Changes in the excitability of GABAergic interneurons, the
probability of release at GABAergic terminals, as well as the
properties of postsynaptic GABAA receptors, have been suggested as the underlying mechanisms for the
D1 and D2 modulation of
GABAergic transmission (Seamans et al., 2001). The present study has
revealed that D4 receptors also produce a
significant reduction of the mIPSC amplitude in pyramidal neurons of
PFC slices, suggestive of a D4 receptor-mediated
downregulation of postsynaptic GABAA receptor
sensitivity or conductance. This is consistent with the
D4 receptor-mediated reduction of whole-cell
GABAA receptor currents found in acutely
dissociated PFC pyramidal neurons.
The mechanism underlying the D4 receptor-mediated
reduction of GABAA receptor currents has been
investigated in this study. Several lines of evidence show that the
D4 receptor-mediated suppression of
GABAA receptor currents is through a signaling
pathway mediated by the inhibition of PKA and subsequent activation of
PP1. The activity of PP1 is controlled by PKA through the regulatory
protein I-1. I-1, after phosphorylation by PKA at
Thr35, becomes a potent inhibitor of PP1
(Ingebritsen and Cohen, 1983). Previous studies have found that
GABAA receptor currents are enhanced in response
to elevated PKA activation in hippocampal dentate granule cells and
neostriatal cholinergic interneurons (Kapur and Macdonald, 1996; Yan
and Surmeier, 1997), presumably because of the increased PKA
phosphorylation of GABAA receptor 3 subunits (McDonald et al., 1998). In the present study, tonic PKA activity, along with the inhibited PP1, may keep GABAA
receptors in PFC pyramidal neurons at a relatively high phosphorylation
state, in which many of the 3 subunits are phosphorylated. The
D4 receptor-mediated suppression of PKA activity,
along with the disinhibited PP1, switches GABAA
receptors to a lower phosphorylation state, in which 3 subunits are
dephosphorylated, therefore leading to the reduction of
GABAA receptor currents.
Because both PKA and PP1 have broad substrate selectivity, a crucial
issue in channel regulation is to control the specificity of their
actions. Subcellular targeting through association with anchoring
proteins has emerged as an important mechanism by which signaling
enzymes achieve precise substrate recognition and enhanced efficacy of
signal transduction (Rosenmund et al., 1994; Pawson and Scott, 1997;
Yan et al., 1999; Feng et al., 2001). Yotiao, an NMDA
receptor-associated protein (Lin et al., 1998), binds both PKA and PP1
(Feliciello et al., 1999; Westphal et al., 1999). This targeting
protein is present in the cortex and is localized at somatodendritic
regions (Lin et al., 1998). Recent studies have revealed the key role
played by Yotiao in mediating the assembly of a macromolecular
signaling complex and the dynamic regulation of NMDA receptor channels
and the slow outward potassium channels (Westphal et al., 1999; Marx et
al., 2002). To test whether the targeting of activated PKA/PP1 to
GABAA receptors via Yotiao may allow these
enzymes to regulate the phosphorylation state of
GABAA receptors effectively in vivo,
we examined the involvement of Yotiao in D4
modulation of GABAA currents in PFC neurons.
Dialysis with a Yotiao-derived peptide that can specifically disrupt
the interaction between Yotiao and PKA (Westphal et al., 1999)
significantly attenuated the D4 modulation of
GABAA currents. The same was true when a peptide
that can disrupt the interaction between Yotiao and PP1 was dialyzed.
These data suggest that the D4 regulation of
GABAA receptors requires the Yotiao-anchored pool
of the PKA/PP1 complex, and that changing the subcellular targeting of
these signaling enzymes leads to disruption of this regulation. It
remains to be determined whether Yotiao is directly associated with
GABAA receptor subunits or acts only to recruit
the PKA/PP1 signaling complex to the proximity of
GABAA receptors and thus facilitate the
compartmentalized regulation of these substrates.
Together, our results show that the activation of
D4 receptors decreased the postsynaptic
GABAA receptor function in PFC pyramidal neurons
via the regulation of the Yotiao-anchored PKA/PP1 signaling complex.
Key signaling components engaged in D4 modulation
of GABAA receptors provide the potential targets
for novel pharmacological agents with greater therapeutic potential and
fewer side effects in the treatment of neuropsychiatric disorders in
which D4 receptors are highly involved.
| |
FOOTNOTES |
Received July 9, 2002; revised Aug. 16, 2002; accepted Aug. 16, 2002.
This work was supported by National Institutes of Health Grant MH63128
(Z.Y.), National Science Foundation Grant IBN-0117026 (Z.Y.), and
Howard Hughes Medical Institute Biomedical Research Support Program
Grant 53000261 (State University of New York at Buffalo). We thank Dr.
Jian Feng for critically reading this manuscript.
Correspondence should be addressed to Dr. Zhen Yan, Department of
Physiology and Biophysics, State University of New York at Buffalo, 124 Sherman Hall, Buffalo, NY 14214. E-mail: zhenyan{at}buffalo.edu.
| |
REFERENCES |
-
Ariano MA,
Wang J,
Noblett KL,
Larson ER,
Sibley DR
(1997)
Cellular distribution of the rat D4 dopamine receptor protein in the CNS using anti-receptor antisera.
Brain Res
752:26-34[Web of Science][Medline].
-
Benes FM,
Vincent SL,
Marie A,
Khan Y
(1996)
Up-regulation of GABAA receptor binding on neurons of the prefrontal cortex in schizophrenic subjects.
Neuroscience
75:1021-1031[Web of Science][Medline].
-
Berger BS,
Trottier C,
Verney P,
Gaspar P,
Alvarez C
(1988)
Regional and laminar distribution of the dopamine and serotonin innervation in the macaque cerebral cortex: a radioautographic study.
J Comp Neurol
273:99-119[Web of Science][Medline].
-
Brozoski TJ,
Brown RM,
Rosvold HE,
Goldman PS
(1979)
Cognitive deficit caused by regional depletion of dopamine in prefrontal cortex of rhesus monkey.
Science
205:929-932[Abstract/Free Full Text].
-
Cai X,
Flores-Hernandez J,
Feng J,
Yan Z
(2002)
Activity-dependent bi-directional regulation of GABAA receptor channels by serotonin 5-HT4 receptors in pyramidal neurons of the prefrontal cortex.
J Physiol (Lond)
540:743-759[Abstract/Free Full Text].
-
Chio CL,
Drong RF,
Riley DT,
Gill GS,
Slightom JL,
Huff RM
(1994)
D4 dopamine receptor-mediated signaling events determined in transfected Chinese hamster ovary cells.
J Biol Chem
269:11813-11819[Abstract/Free Full Text].
-
Colledge M,
Scott JD
(1999)
AKAPs: from structure to function.
Trends Cell Biol
9:216-221[Web of Science][Medline].
-
Constantinidis C,
Williams GV,
Goldman-Rakic PS
(2002)
A role for inhibition in shaping the temporal flow of information in prefrontal cortex.
Nat Neurosci
5:175-180[Web of Science][Medline].
-
Dean B,
Hussain T,
Hayes W,
Scarr E,
Kitsoulis S,
Hill C,
Opeskin K,
Copolov DL
(1999)
Changes in serotonin2A and GABA(A) receptors in schizophrenia: studies on the human dorsolateral prefrontal cortex.
J Neurochem
72:1593-1599[Web of Science][Medline].
-
Desimone R
(1995)
Neuropsychology: is dopamine a missing link?
Nature
376:549-550[Medline].
-
Dulawa SC,
Grandy DK,
Low MJ,
Paulus MP,
Geyer MA
(1999)
Dopamine D4 receptor-knock-out mice exhibit reduced exploration of novel stimuli.
J Neurosci
19:9550-9556[Abstract/Free Full Text].
-
Durstewitz D,
Seamans JK,
Sejnowski TJ
(2000)
Dopamine-mediated stabilization of delay-period activity in a network model of prefrontal cortex.
J Neurophysiol
83:1733-1750[Abstract/Free Full Text].
-
Egloff MP,
Johnson DF,
Moorhead G,
Cohen PT,
Cohen P,
Barford D
(1997)
Structural basis for the recognition of regulatory subunits by the catalytic subunit of protein phosphatase 1.
EMBO J
16:1876-1887[Web of Science][Medline].
-
Feliciello A,
Cardone L,
Garbi C,
Ginsberg MD,
Varrone S,
Rubin CS,
Avvedimento EV,
Gottesman ME
(1999)
Yotiao protein, a ligand for the NMDA receptor, binds and targets cAMP-dependent protein kinase II(1).
FEBS Lett
464:174-178[Web of Science][Medline].
-
Feng J,
Cai X,
Zhao JH,
Yan Z
(2001)
Serotonin receptors modulate GABAA receptor channels through activation of anchored protein kinase C in prefrontal cortical neurons.
J Neurosci
21:6502-6511[Abstract/Free Full Text].
-
Glase SA,
Akunne HC,
Georgic LM,
Heffner TG,
MacKenzie RG,
Manley PJ,
Pugsley TA,
Wise LD
(1997)
Substituted [(4-phenylpiperazinyl)-methyl]benzamides: selective dopamine D4 agonists.
J Med Chem
40:1771-1772[Web of Science][Medline].
-
Goldman-Rakic PS
(1995)
Cellular basis of working memory.
Neuron
14:477-485[Web of Science][Medline].
-
Hamill OP,
Marty A,
Neher E,
Sakmann B,
Sigworth FJ
(1981)
Improved patch-clamp techniques for high resolution current recording from cells and cell-free membrane patches.
Pflügers Arch
391:85-100[Web of Science][Medline].
-
Hemmings Jr HC,
Nairn AC,
Elliott JI,
Greengard P
(1990)
Synthetic peptide analogs of DARPP-32 (Mr 32,000 dopamine- and cAMP-regulated phosphoprotein), an inhibitor of protein phosphatase-1: phosphorylation, dephosphorylation, and inhibitory activity.
J Biol Chem
265:20369-20376[Abstract/Free Full Text].
-
Ingebritsen TS,
Cohen P
(1983)
Protein phosphatases: properties and role in cellular regulation.
Science
221:331-338[Abstract/Free Full Text].
-
Jentsch JD,
Redmond Jr DE,
Elsworth JD,
Taylor JR,
Youngren KD,
Roth RH
(1997)
Enduring cognitive deficits and cortical dopamine dysfunction in monkeys after long-term administration of phencyclidine.
Science
277:953-955[Abstract/Free Full Text].
-
Jentsch JD,
Taylor JR,
Redmond Jr DE,
Elsworth JD,
Youngren KD,
Roth RH
(1999)
Dopamine D4 receptor antagonist reversal of subchronic phencyclidine-induced object retrieval/detour deficits in monkeys.
Psychopharmacology
142:78-84[Medline].
-
Kapur J,
Macdonald RL
(1996)
Cyclic AMP-dependent protein kinase enhances hippocampal dentate granule cell GABAA receptor currents.
J Neurophysiol
76:2626-2634[Abstract/Free Full Text].
-
Kapur S,
Remington G
(2001)
Atypical antipsychotics: new directions and new challenges in the treatment of schizophrenia.
Annu Rev Med
52:503-517[Web of Science][Medline].
-
Knighton DR,
Zheng JH,
Ten Eyck LF,
Xuong NH,
Taylor SS,
Sowadski JM
(1991)
Structure of a peptide inhibitor bound to the catalytic subunit of cyclic adenosine monophosphate-dependent protein kinase.
Science
253:414-420[Abstract/Free Full Text].
-
Kulagowski JJ,
Broughton HB,
Curtis NR,
Mawer IM,
Ridgill MP,
Baker R,
Emms F,
Freedman SB,
Marwood R,
Patel S,
Patel S,
Ragan CI,
Leeson PD
(1996)
3-((4-(4-chlorophenyl)piperazin-1-yl)-methyl)-1H-pyrrolo-2,3-b-pyridine: an antagonist with high affinity and selectivity for the human dopamine D4 receptor.
J Med Chem
39:1941-1942[Web of Science][Medline].
-
Kwon YG,
Huang HB,
Desdouits F,
Girault JA,
Greengard P,
Nairn AC
(1997)
Characterization of the interaction between DARPP-32 and protein phosphatase 1 (PP-1): DARPP-32 peptides antagonize the interaction of PP-1 with binding proteins.
Proc Natl Acad Sci USA
94:3536-35341[Abstract/Free Full Text].
-
Lewis DA
(2000)
GABAergic local circuit neurons and prefrontal cortical dysfunction in schizophrenia.
Brain Res Brain Res Rev
31:270-276[Medline].
-
Lewis DA,
Campbell MJ,
Foote SL,
Morrison JH
(1986)
The monoaminergic innervation of primate neocortex.
Hum Neurobiol
5:181-186[Medline].
-
Lidow MS,
Goldman-Rakic PS
(1994)
A common action of clozapine, haloperidol, and remoxipride on D1- and D2-dopaminergic receptors in the primate cerebral cortex.
Proc Natl Acad Sci USA
91:4353-4356[Abstract/Free Full Text].
-
Lin JW,
Wyszynski M,
Madhavan R,
Sealock R,
Kim JU,
Sheng M
(1998)
Yotiao, a novel protein of neuromuscular junction and brain that interacts with specific splice variants of NMDA receptor subunit NR1.
J Neurosci
18:2017-2027[Abstract/Free Full Text].
-
Macdonald RL,
Olsen RW
(1994)
GABAA receptor channels.
Annu Rev Neurosci
17:569-602[Web of Science][Medline].
-
Marx SO,
Kurokawa J,
Reiken S,
Motoike H,
D'Armiento J,
Marks AR,
Kass RS
(2002)
Requirement of a macromolecular signaling complex for beta adrenergic receptor modulation of the KCNQ1-KCNE1 potassium channel.
Science
295:496-499[Abstract/Free Full Text].
-
McDonald BJ,
Amato A,
Connolly CN,
Benke D,
Moss SJ,
Smart TG
(1998)
Adjacent phosphorylation sites on GABAA receptor beta subunits determine regulation by cAMP-dependent protein kinase.
Nat Neurosci
1:23-28[Web of Science][Medline].
-
Miller EK
(1999)
The prefrontal cortex: complex neural properties for complex behavior.
Neuron
22:15-17[Web of Science][Medline].
-
Moss SJ,
Doherty CA,
Huganir RL
(1992a)
Identification of the cAMP-dependent protein kinase and protein kinase C phosphorylation sites within the major intracellular domains of the beta 1, gamma 2S, and gamma 2L subunits of the gamma-aminobutyric acid type A receptor.
J Biol Chem
267:14470-14476[Abstract/Free Full Text].
-
Moss SJ,
Smart TG,
Blackstone CD,
Huganir RL
(1992b)
Functional modulation of GABAA receptors by cAMP-dependent protein phosphorylation.
Science
257:661-665[Abstract/Free Full Text].
-
Mrzljak L,
Bergson C,
Pappy M,
Huff R,
Levenson R,
Goldman-Rakic PS
(1996)
Localization of dopamine D4 receptors in GABAergic neurons of the primate brain.
Nature
381:245-248[Medline].
-
Murphy BL,
Arnsten AF,
Goldman-Rakic PS,
Roth RH
(1996)
Increased dopamine turnover in the prefrontal cortex impairs spatial working memory performance in rats and monkeys.
Proc Natl Acad Sci USA
93:1325-1329[Abstract/Free Full Text].
-
Nicola SM,
Surmeier J,
Malenka RC
(2000)
Dopaminergic modulation of neuronal excitability in the striatum and nucleus accumbens.
Annu Rev Neurosci
23:185-215[Web of Science][Medline].
-
Nusser Z,
Sieghart W,
Benke D,
Fritschy JM,
Somogyi P
(1996)
Differential synaptic localization of two major gamma-aminobutyric acid type A receptor alpha subunits on hippocampal pyramidal cells.
Proc Natl Acad Sci USA
93:11939-11944[Abstract/Free Full Text].
-
Oak JN,
Oldenhof J,
Van Tol HH
(2000)
The dopamine D(4) receptor: one decade of research.
Eur J Pharmacol
405:303-327[Web of Science][Medline].
-
Ohnuma T,
Augood SJ,
Arai H,
McKenna PJ,
Emson PC
(1999)
Measurement of GABAergic parameters in the prefrontal cortex in schizophrenia: focus on GABA content, GABA(A) receptor alpha-1 subunit messenger RNA and human GABA transporter-1 (HGAT-1) messenger RNA expression.
Neuroscience
93:441-448[Web of Science][Medline].
-
Patel S,
Freedman S,
Chapman KL,
Emms F,
Fletcher AE,
Knowles M,
Marwood R,
Mcallister G,
Myers J,
Curtis N,
Kulagowski JJ,
Leeson PD,
Ridgill M,
Graham M,
Matheson S,
Rathbone D,
Watt AP,
Bristow LJ,
Rupniak NM,
Baskin E
(1997)
Biological profile of L-745,870, a selective antagonist with high affinity for the dopamine D4 receptor.
J Pharmacol Exp Ther
283:636-647[Abstract/Free Full Text].
-
Pawson T,
Scott JD
(1997)
Signaling through scaffold, anchoring, and adapter proteins.
Science
278:2075-2080[Abstract/Free Full Text].
-
Porter NM,
Twyman RE,
Uhler MD,
Macdonald RL
(1990)
Cyclic AMP-dependent protein kinase decreases GABAA receptor current in mouse spinal neurons.
Neuron
5:789-796[Web of Science][Medline].
-
Rosenmund C,
Carr DW,
Bergeson SE,
Nilaver G,
Scott JD,
Westbrook GL
(1994)
Anchoring of protein kinase A is required for modulation of AMPA/kainate receptors on hippocampal neurons.
Nature
368:853-856[Medline].
-
Rubinstein M,
Cepeda C,
Hurst RS,
Flores-Hernandez J,
Ariano MA,
Falzone TL,
Kozell LB,
Meshul CK,
Bunzow JR,
Low MJ,
Levine MS,
Grandy DK
(2001)
Dopamine D4 receptor-deficient mice display cortical hyperexcitability.
J Neurosci
21:3756-3763[Abstract/Free Full Text].
-
Sawaguchi T,
Goldman-Rakic PS
(1991)
D1 dopamine receptors in prefrontal cortex: involvement in working memory.
Science
251:947-950[Abstract/Free Full Text].
-
Seamans JK,
Gorelova N,
Durstewitz D,
Yang CR
(2001)
Bidirectional dopamine modulation of GABAergic inhibition in prefrontal cortical pyramidal neurons.
J Neurosci
21:3628-3638[Abstract/Free Full Text].
-
Seeman P,
Van Tol HH
(1994)
Dopamine receptor pharmacology.
Trends Pharmacol Sci
15:264-270[Medline].
-
Seeman P,
Guan HC,
Van Tol HH
(1993)
Dopamine D4 receptors elevated in schizophrenia.
Nature
365:441-445[Medline].
-
Smiley JF,
Levey AI,
Ciliax BJ,
Goldman-Rakic PS
(1994)
D1 dopamine receptor immunoreactivity in human and monkey cerebral cortex: predominant and extrasynaptic localization in dendritic spines.
Proc Natl Acad Sci USA
91:5720-5724[Abstract/Free Full Text].
-
Van Tol HH,
Bunzow JR,
Guan HC,
Sunahara RK,
Seeman P,
Niznik HB,
Civelli O
(1991)
Cloning of the gene for a human dopamine D4 receptor with high affinity for the antipsychotic clozapine.
Nature
350:610-614[Medline].
-
Wedzony K,
Chocyk A,
Mackowiak M,
Fijal K,
Czyrak A
(2000)
Cortical localization of dopamine D4 receptors in the rat brain: immunocytochemical study.
J Physiol Pharmacol
51:205-221[Web of Science][Medline].
-
Werner P,
Hussy N,
Buell G,
Jones KA,
North RA
(1996)
D2, D3, and D4 dopamine receptors couple to G protein-regulated potassium channels in Xenopus oocytes.
Mol Pharmacol
49:656-661[Abstract].
-
Westphal RS,
Tavalin SJ,
Lin JW,
Alto NM,
Fraser ID,
Langeberg LK,
Sheng M,
Scott JD
(1999)
Regulation of NMDA receptors by an associated phosphatase-kinase signaling complex.
Science
285:93-96[Abstract/Free Full Text].
-
Wilke RA,
Hsu SF,
Jackson MB
(1998)
Dopamine D4 receptor mediated inhibition of potassium current in neurohypophysial nerve terminals.
J Pharmacol Exp Ther
284:542-548[Abstract/Free Full Text].
-
Williams GV,
Goldman-Rakic PS
(1995)
Modulation of memory fields by dopamine D1 receptors in prefrontal cortex.
Nature
376:572-575[Medline].
-
Yan Z,
Surmeier DJ
(1996)
Muscarinic (m2/m4) receptors reduce N- and P-type Ca2+ currents in rat neostriatal cholinergic interneurons through a fast, membrane-delimited, G-protein pathway.
J Neurosci
16:2592-2604[Abstract/Free Full Text].
-
Yan Z,
Surmeier DJ
(1997)
D5 dopamine receptors enhance Zn2+-sensitive GABA(A) currents in striatal cholinergic interneurons through a PKA/PP1 cascade.
Neuron
19:1115-1126[Web of Science][Medline].
-
Yan Z,
Hsieh-Wilson L,
Feng J,
Tomizawa K,
Allen PB,
Fienberg AA,
Nairn AC,
Greengard P
(1999)
Protein phosphatase 1 modulation of neostriatal AMPA channels: regulation by DARPP-32 and spinophilin.
Nat Neurosci
2:13-17[Web of Science][Medline].
Copyright © 2002 Society for Neuroscience 0270-6474/02/22219185-09$05.00/0
This article has been cited by other articles:
|
|
|
|
 
N. M. Graziane, E. Y. Yuen, and Z. Yan
Dopamine D4 Receptors Regulate GABAA Receptor Trafficking via an Actin/Cofilin/Myosin-dependent Mechanism
J. Biol. Chem.,
March 27, 2009;
284(13):
8329 - 8336.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. Y. Yuen and Z. Yan
Dopamine D4 Receptors Regulate AMPA Receptor Trafficking and Glutamatergic Transmission in GABAergic Interneurons of Prefrontal Cortex
J. Neurosci.,
January 14, 2009;
29(2):
550 - 562.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. L. Tierney, A. M. Thierry, J. Glowinski, J. M. Deniau, and Y. Gioanni
Dopamine Modulates Temporal Dynamics of Feedforward Inhibition in Rat Prefrontal Cortex In Vivo
Cereb Cortex,
October 1, 2008;
18(10):
2251 - 2262.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Baufreton and M. D. Bevan
D2-like dopamine receptor-mediated modulation of activity-dependent plasticity at GABAergic synapses in the subthalamic nucleus
J. Physiol.,
April 15, 2008;
586(8):
2121 - 2142.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Trantham-Davidson, S. Kroner, and J. K. Seamans
Dopamine Modulation of Prefrontal Cortex Interneurons Occurs Independently of DARPP-32
Cereb Cortex,
April 1, 2008;
18(4):
951 - 958.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Ramanathan, T. Tkatch, J. F. Atherton, C. J. Wilson, and M. D. Bevan
D2-Like Dopamine Receptors Modulate SKCa Channel Function in Subthalamic Nucleus Neurons Through Inhibition of Cav2.2 Channels
J Neurophysiol,
February 1, 2008;
99(2):
442 - 459.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. A. Gray and B. L. Roth
Molecular Targets for Treating Cognitive Dysfunction in Schizophrenia
Schizophr Bull,
September 1, 2007;
33(5):
1100 - 1119.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. F. T. Arnsten
Catecholamine and Second Messenger Influences on Prefrontal Cortical Networks of "Representational Knowledge": A Rational Bridge between Genetics and the Symptoms of Mental Illness
Cereb Cortex,
September 1, 2007;
17(suppl_1):
i6 - i15.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Demiralp, C. S. Herrmann, M. E. Erdal, T. Ergenoglu, Y. H. Keskin, M. Ergen, and H. Beydagi
DRD4 and DAT1 Polymorphisms Modulate Human Gamma Band Responses
Cereb Cortex,
May 1, 2007;
17(5):
1007 - 1019.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Kroner, L. S. Krimer, D. A. Lewis, and G. Barrionuevo
Dopamine Increases Inhibition in the Monkey Dorsolateral Prefrontal Cortex through Cell Type-Specific Modulation of Interneurons
Cereb Cortex,
May 1, 2007;
17(5):
1020 - 1032.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. B. Floresco and M. T. Tse
Dopaminergic Regulation of Inhibitory and Excitatory Transmission in the Basolateral Amygdala-Prefrontal Cortical Pathway
J. Neurosci.,
February 21, 2007;
27(8):
2045 - 2057.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
W.-J. Gao
Acute Clozapine Suppresses Synchronized Pyramidal Synaptic Network Activity by Increasing Inhibition in the Ferret Prefrontal Cortex
J Neurophysiol,
February 1, 2007;
97(2):
1196 - 1208.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. Hernandez, O. Ibanez-Sandoval, A. Sierra, R. Valdiosera, D. Tapia, V. Anaya, E. Galarraga, J. Bargas, and J. Aceves
Control of the Subthalamic Innervation of the Rat Globus Pallidus by D2/3 and D4 Dopamine Receptors
J Neurophysiol,
December 1, 2006;
96(6):
2877 - 2888.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Asaumi, H. Hasuo, and T. Akasu
Dopamine Presynaptically Depresses Fast Inhibitory Synaptic Transmission via D4 Receptor-Protein Kinase A Pathway in the Rat Dorsolateral Septal Nucleus
J Neurophysiol,
August 1, 2006;
96(2):
591 - 601.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
N. Kobori and P. K. Dash
Reversal of brain injury-induced prefrontal glutamic acid decarboxylase expression and working memory deficits by D1 receptor antagonism.
J. Neurosci.,
April 19, 2006;
26(16):
4236 - 4246.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Trantham-Davidson, L. C. Neely, A. Lavin, and J. K. Seamans
Mechanisms Underlying Differential D1 versus D2 Dopamine Receptor Regulation of Inhibition in Prefrontal Cortex
J. Neurosci.,
November 24, 2004;
24(47):
10652 - 10659.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Z. Gu and Z. Yan
Bidirectional Regulation of Ca2+/Calmodulin-Dependent Protein Kinase II Activity by Dopamine D4 Receptors in Prefrontal Cortex
Mol. Pharmacol.,
October 1, 2004;
66(4):
948 - 955.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Terunuma, I.-S. Jang, S. H. Ha, J. T. Kittler, T. Kanematsu, J. N. Jovanovic, K. I. Nakayama, N. Akaike, S. H. Ryu, S. J. Moss, et al.
GABAA Receptor Phospho-Dependent Modulation Is Regulated by Phospholipase C-Related Inactive Protein Type 1, a Novel Protein Phosphatase 1 Anchoring Protein
J. Neurosci.,
August 11, 2004;
24(32):
7074 - 7084.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R.-M. Shin, M. Masuda, M. Miura, H. Sano, T. Shirasawa, W.-J. Song, K. Kobayashi, and T. Aosaki
Dopamine D4 Receptor-Induced Postsynaptic Inhibition of GABAergic Currents in Mouse Globus Pallidus Neurons
J. Neurosci.,
December 17, 2003;
23(37):
11662 - 11672.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
X. Wang, P. Zhong, Z. Gu, and Z. Yan
Regulation of NMDA Receptors by Dopamine D4 Signaling in Prefrontal Cortex
J. Neurosci.,
October 29, 2003;
23(30):
9852 - 9861.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. Azdad, R. Piet, D. A. Poulain, and S. H. R. Oliet
Dopamine D4 Receptor-Mediated Presynaptic Inhibition of GABAergic Transmission in the Rat Supraoptic Nucleus
J Neurophysiol,
August 1, 2003;
90(2):
559 - 565.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
G. K. Carnegie and J. D. Scott
A-kinase anchoring proteins and neuronal signaling mechanisms
Genes & Dev.,
July 1, 2003;
17(13):
1557 - 1568.
[Full Text]
[PDF]
|
|
|
|
|
|
|
X.-H. Ma, P. Zhong, Z. Gu, J. Feng, and Z. Yan
Muscarinic Potentiation of GABAA Receptor Currents Is Gated by Insulin Signaling in the Prefrontal Cortex
J. Neurosci.,
February 15, 2003;
23(4):
1159 - 1168.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
TOP
ABSTRACT
INTRODUCTION
Compound via MeSH
