 |
 Previous Article | Next Article 
The Journal of Neuroscience, March 15, 1998, 18(6):2231-2238
Alterations in Dopamine Release But Not Dopamine Autoreceptor
Function in Dopamine D3 Receptor Mutant Mice
Timothy E.
Koeltzow1,
Ming
Xu2,
Donald C.
Cooper1,
Xiu-Ti
Hu1,
Susumu
Tonegawa2,
Marina E.
Wolf1, and
Francis J.
White1
1 Department of Neuroscience, Finch University of
Health Sciences, Chicago Medical School, North Chicago, Illinois
60064-3095, and 2 Howard Hughes Medical Institute, Center
for Learning and Memory, Center for Cancer Research, and Department of
Biology, Massachusetts Institute of Technology, Cambridge,
Massachusetts 02139
 |
ABSTRACT |
Dopamine (DA) autoreceptors expressed along the somatodendritic
extent of midbrain DA neurons modulate impulse activity, whereas those
expressed at DA nerve terminals regulate both DA synthesis and release.
Considerable evidence has indicated that these DA autoreceptors are of
the D2 subtype of DA receptors. However, many
pharmacological studies have suggested an autoreceptor role for the DA
D3 receptor. This possibility was tested with mice lacking
the D3 receptor as a result of gene targeting. The basal firing rates of DA neurons within both the substantia nigra and ventral
tegmental area were not different in D3 receptor
mutant and wild-type mice. The putative D3
receptor-selective agonist R(+)-trans-3,4,4a,10b-tetrahydro-4-propyl-2H,5H-(1)benzopyrano(4,3-b) 1,4-oxazin-9-ol (PD 128907) was equipotent at inhibiting the activity of both populations of midbrain DA neurons in the two groups of mice. In the
 -butyrolactone (GBL) model of DA autoreceptor function, mutant and
wild-type mice were identical with respect to striatal DA synthesis and
its suppression by PD 128907. In vivo microdialysis studies of DA release in ventral striatum revealed higher basal levels
of extracellular DA in mutant mice but similar inhibitory effects of PD
128907 in mutant and wild-type mice. These results suggest that the
effects of PD 128907 on dopamine cell function reflect stimulation of
D2 as opposed to D3 receptors. Although D3 receptors do not seem to be significantly involved in DA
autoreceptor function, they may participate in postsynaptically
activated short-loop feedback modulation of DA release.
Key words:
D3 receptors; mutant mice; dopamine
autoreceptors; dopamine receptors; dopamine neurons; dopamine release; dopamine synthesis
| |
INTRODUCTION |
Discovery of the dopamine (DA)
D3 receptor (Sokoloff et al., 1990 ) generated considerable
excitement regarding possible physiological and behavioral functions
mediated by this member of the DA D2 receptor subfamily
(D2, D3, and
D4). Among the speculated roles for the
D3 receptor was that of an autoreceptor, the receptors expressed by DA neurons to provide feedback regulatory control. Initial
characterization of the cloned D3 receptor identified several D3 receptor-preferring ligands that had been
regarded previously as DA autoreceptor-selective (Svensson et al.,
1986). In addition, D3 receptor gene transcripts were
detected by PCR in the rat ventral tegmental area (VTA) and substantia
nigra (SN) and were absent after selective destruction of DA neurons
with 6-hydroxydopamine, suggesting localization to DA neurons (Sokoloff et al., 1990). However, more recent studies have either failed to
detect D3 receptor mRNA in the rat midbrain (Landwehrmeyer et al., 1993; Meador-Woodruff et al., 1994; Richtand et al., 1995; Healy and Meador-Woodruff, 1996) or have demonstrated low and very
restricted expression to lateral regions of the SN and VTA, with only a
portion of these cells also expressing tyrosine hydroxylase (Bouthenet
et al., 1991; Diaz et al., 1995).
Functionally, three classes of DA autoreceptors can be defined (for
review, see Wolf and Roth, 1987). The soma and dendrites of midbrain DA
neurons express autoreceptors that modulate rates of impulse activity
(Bunney et al., 1973; Aghajanian and Bunney, 1977). Nerve terminals of
these neurons express autoreceptors that modulate DA synthesis (Kehr et
al., 1972) and DA release (Farnebo and Hamberger, 1971). Each of these
three autoreceptors exhibits pharmacological characteristics of the
D2 receptor subfamily (for review, see Clark and White,
1987; Wolf and Roth, 1987), and conclusive anatomical evidence
indicates that DA neurons express D2 receptor mRNA
(Meador-Woodruff et al., 1989; Mengod et al., 1989; Mansour et al.,
1995). Despite the limited anatomical evidence of the expression of
D3 receptor mRNA in DA neurons (above), many pharmacological studies have suggested that D3
autoreceptors modulate DA impulse flow (Devoto et al., 1995; Kreiss et
al., 1995; Lejeune and Millan, 1995; Gobert et al., 1996; Tepper et
al., 1997), DA synthesis (Meller et al., 1993; Ahlenius and Salmi,
1994; Aretha et al., 1995; Gobert et al., 1995; Pugsley et al., 1995),
and DA release (Damsma et al., 1993; Gainetdinov et al., 1994, 1996; Rivet et al., 1994; Gilbert et al., 1995; Pugsley et al., 1995; Gobert
et al., 1996; Routledge et al., 1996; Tepper et al., 1997). With
notable exceptions (Tang et al., 1994; Nissbrandt et al., 1995; O'Hara
et al., 1996; Tepper et al., 1997), most of these studies inferred a
role for D3 receptors based on (1) correlations between DA
agonist potency and relative binding affinities at cloned
D2 and D3 receptors expressed in various cell
lines, (2) comparisons between regional differences in DA agonist
potency and relative expression of D2 and D3
receptors, or (3) antagonism of agonist effects by putative
D3 receptor-selective antagonists. These approaches are not
conclusive because serious questions exist with respect to the
selectivity of D3 receptor ligands (Chio et al., 1994;
Large and Stubbs, 1994; Potenza et al., 1994; Burris et al., 1995;
Gonzalez and Sibley, 1995; Sautel et al., 1995).
To test possible autoreceptor roles for D3 receptors more
directly, we have used homologous recombination in embryonic stem cells
to generate mice lacking the intact D3 receptor gene (Xu et
al., 1997). We used well characterized in vivo models of DA autoreceptor function to compare the D3 receptor mutant
mice with their wild-type littermates with respect to DA cell firing
rates, DA synthesis, and DA release and inhibition of these functions by the putative D3 receptor-selective agonist
R(+)-trans-3,4,4a,10b-tetrahydro-4-propyl-2H,5H-(1)benzopyrano(4,3-b)1,4-oxazin-9-ol (PD 128907) (Sokoloff and Schwartz, 1995). We reasoned that if D3 receptors serve autoreceptor functions, then the basal
firing rates of DA neurons, as well as levels of DA synthesis and
release, should be altered in D3 receptor mutant mice and
that autoreceptor-mediated effects of PD 128907 should be absent or
reduced in D3 mutant mice. Our results fail to support an
autoreceptor role for D3 receptors but suggest that
postsynaptic D3 receptors may regulate DA release via
short-loop feedback mechanisms.
| |
MATERIALS AND METHODS |
Mice. Mice were generated as detailed in Xu et al.
(1997). They were shipped to the Chicago Medical School by commercial
carrier. Mice were housed in like groups of three to four animals and
were allowed 7-8 d to acclimate to the vivarium before use. All
experimental procedures were conducted at the Chicago Medical School.
All procedures were performed in strict accordance with the
National Research Council Guide for the Care and Use of
Laboratory Animals (1996) and were approved by our Institutional
Animal Care and Use Committee.
Extracellular single-unit recordings. All methods for
extracellular single-cell recordings were similar to those previously reported (White et al., 1995), although modified somewhat for the mouse
(Xu et al., 1994). Briefly, mice were anesthetized with chloral hydrate
(400 mg/kg, i.p.) and mounted in a standard stereotaxic apparatus with
a specialized adapter for the mouse. Body temperature was maintained at
36-37.5°C with a thermostatically controlled heating pad. A 28 gauge
(3/8 inch) hypodermic needle was placed in a lateral tail vein through
which additional anesthetic (as required) and drugs of study were
administered. A burr hole was drilled in the skull, and the dura was
retracted from the area overlying the VTA and SN, 0.4-1.3 mm anterior
to lambda and 0.2-1.0 mm lateral to the midline. Recording electrodes
were made by pulling glass tubing [outer diameter (o.d.), 2.0 mm],
which was prefilled with fiberglass, and by breaking the tip back to a
diameter of 1-2 µm. Electrodes were filled with 2 M NaCl
saturated with 1% (w/v) fast green dye and typically exhibited
in vitro impedances of 1-3 M (at 135 Hz). Electrode
potentials were passed through a high impedance amplifier/filter and
displayed on an oscilloscope. Individual action potentials were
discriminated electronically and monitored with an audio amplifier.
Integrated rate histograms, generated by the output of the window
discriminator, were plotted by a polygraph recorder, whereas digitized
counts of cellular activity were obtained for off-line analysis.
Electrodes were lowered to a point 0.5 mm above the VTA and SN and then
slowly advanced with a hydraulic microdrive through the DA cell regions (3.2-5.0 mm ventral to the cortical surface). DA cells were identified by standard physiological criteria (Bunney et al., 1973; Wang, 1981;
Sanghera et al., 1984) and were recorded for 3-6 min to establish a
baseline firing rate. To determine the sensitivity of
impulse-modulating somatodendritic autoreceptors, we administered PD
128907 to each mouse through the tail vein, using a cumulative dose
regimen in which each dose doubled the previous dose, at 60-90 sec
intervals. After agonist-induced inhibition, the D2-class receptor antagonist eticlopride was administered (0.1-0.2 mg/kg) to
reverse the effect and confirm receptor mediation. At the end of each
experiment, the cell location was marked by ejecting fast green dye,
and the spot was verified by routine histological assessment (described
below).
-Butyrolactone experiments. The L-aromatic
amino acid decarboxylase inhibitor NSD 1015 was administered 30 min
before death (100 mg/kg, i.p.). -Butyrolactone (GBL) was
administered (750 mg/kg, i.p.) 5 min before NSD 1015 to eliminate
impulse flow in DA neurons (Walters and Roth, 1976). PD 128907 was
injected 5 min before GBL. Mice were killed by decapitation, and the
brains were quickly removed. Dorsal and ventral striatum were dissected on a chilled glass plate with the aid of a mouse brain matrix designed
to allow coronal sections to be cut rapidly and reproducibly (Activational Systems, Warren, MI). Two slices (2 mm each) were taken,
beginning at the rostral boundary of the olfactory tubercle. The most
anterior slice was the source of ventral striatum, whereas both slices
were used to obtain dorsal striatum. The ventral striatum was dissected
with angular cuts originating at the lateral olfactory tracts and
ending at the midline (average weight, 18.5 mg). The remainder of the
striatal region from that slice as well as the similar region from the
more caudal slice was considered the dorsal striatum (average weight,
35.8 mg). Tissues were kept at 80°C. To measure tissue catechols,
we weighed frozen tissues and then sonically disrupted them in a
homogenization solution consisting of 100 mM
HClO4, 5 mM
Na2S2O5, and  -methyl
dopa, an internal standard. After centrifugation (25,000 × g for 10 min), aliquots of the supernatant were processed by
alumina extraction as described previously (Galloway et al., 1986). The
3,4-dihydroxyphenylalanine (DOPA) content of samples was determined
using an HPLC system consisting of a Bioanalytical Systems (BAS) Phase
II ODS 3 µm column (100 × 3.2 mm), a BAS LC4C electrochemical
detector, and a Scientific Systems model 222C HPLC pump. The mobile
phase consisted of 0.1 M
NaH2PO4, 1 mM EDTA, 0.2 mM 1-octane-sulfonic acid, and 3% methanol, adjusted to pH
2.7 with phosphoric acid. DOPA content was quantified based on both
internal and external standards.
In vivo microdialysis experiments. Mice used for
dialysis experiments weighed 28-35 gm. Concentric microdialysis probes
were constructed as described previously, with fused-silica inlet and outlet lines (Wolf et al., 1994). Dialysis membrane (molecular weight
cutoff, 6000; o.d., 250 µm) was obtained from Spectrum (Los Angeles,
CA). Data were not corrected for in vitro probe recovery
because probes may suffer differential alterations during insertion.
Consistent with this assumption, data sets corrected for recovery often
exhibit greater variability than do those that are uncorrected (Xue et
al., 1996). Probes were stereotaxically implanted under sodium Brevital
(8 mg/kg, i.p.). Stereotaxic coordinates were, relative to bregma,
anterior, 1.5 mm; lateral, 1.5 mm; and ventral, 2.7-4.7 mm. Ventral
coordinates indicate exposed regions of dialysis membrane (2 mm). After
surgery, mice were placed in Plexiglas cages (23 × 46 mm) and
allowed to recover overnight. Food and water were available ad
libitum. Dialysis cages were equipped with balance arms (Instech,
Plymouth Meeting, PA), and homemade liquid swivels and tethers were
constructed from plastic syringes and tubing. These were used because
commercially available swivels were too heavy for use with mice. Probes
were perfused overnight at 0.3 µl/min with artificial CSF (aCSF)
consisting of (in mM): 2.7 KCl, 140 NaCl, 1.2 CaCl2, 1 MgCl2, 0.3 NaH2PO4, and 1.7 Na2HPO4, pH 7.4. The next morning, the
perfusion rate was increased to 2 µl/min for 2-3 hr before the
experiment was begun. Experiments consisted of 1 hr of perfusion with
control aCSF to determine basal DA efflux, 1 hr of perfusion with aCSF containing PD 128907, and a 1 hr recovery period during which control
aCSF was perfused. Thus, administration of PD 128907 occurred ~20 hr
after probe implantation. Fractions were collected every 20 min. After
each experiment, mice were anesthetized and perfused intracardially
with normal saline followed by 10% formalin. Probe placement was
examined in sections stained with cresyl violet. Only data from mice
with verified probe placements were included in the analysis.
Dialysates were analyzed for DA content using the HPLC system described
for GBL experiments. Chromatographic conditions were optimized for
early elution of DA to obtain maximum sensitivity. The mobile phase
consisted of 0.1 M NaH2PO4,
0.5 mM EDTA, 2 mM 1-octane-sulfonic acid, and
16% methanol, adjusted to pH 4.9. Peaks were recorded using a
dual-channel chart recorder and were quantified by comparison with the
peak heights of external standards run with every experiment.
Drugs. PD 128907, 7-hydroxy-2-(di-n-propylamino)tetralin (7-OH-DPAT),
quinpirole, and eticlopride were obtained from Research Biochemicals
(Natick, MA). GBL was obtained from VWR Scientific (Chicago, IL). NSD
1015 and alumina for column chromatography were obtained from Sigma
(St. Louis, MO).
Statistics. Two-way repeated measures ANOVA (groups and
dose) was used to analyze the electrophysiological and DOPA synthesis results when PD 128907 was administered. In both cases, dose was the
repeated measure. Planned comparisons were made with Dunnett's test.
Results from basal DOPA synthesis measures were analyzed with a two-way
ANOVA (groups and treatment) with the treatments being NSD 1015 and NSD
1015 plus GBL. Basal levels of extracellular DA obtained with
microdialysis were compared with a one-way ANOVA. Because of the
significant difference between the two groups of mice on this measure,
we used two-way (groups × fraction) repeated measures (fraction)
analysis of covariance (ANCOVA) with basal DA as the covariate to
compare the effects of PD 128907 on DA release.
| |
RESULTS |
Lack of evidence of impulse-modulating DA
D3 autoreceptors
PD 128907 produced a potent, dose-dependent suppression of firing
of DA neurons in both the VTA and SN and did so equally well in mutant
and wild-type mice (Fig. 1). Similar
experiments conducted with other putative D3
receptor-selective agonists, 7-OH-DPAT and quinpirole, produced
identical results (data not shown). We also observed no difference in
the basal firing rates of DA neurons recorded in the two groups of
mice. Such a difference might be expected if D3 receptors
exert a tonic inhibitory influence on neuronal activity. These findings
indicate that inhibition of DA cell activity by putative D3
receptor-selective agonists is not mediated by stimulation of
D3 receptors and thus must be mediated by D2
receptors. Because in situ hybridization histochemistry indicates restricted expression of D3 mRNA in lateral
portions of the rat SN and VTA (Diaz et al., 1995), we determined the
sites of our recorded DA neurons using routine histological procedures and confirmed that DA neurons from these regions of the midbrain were
included in our samples (Fig. 2).
View larger version (20K):
[in this window]
[in a new window]
|
Figure 1.
Similar inhibition of midbrain DA neurons by PD
128907 in D3 receptor mutant and wild-type mice.
A, Cumulative dose-response curves showing the
significant dose-dependent suppression of VTA DA neuronal activity by
PD 128907 (F6,120 = 62.5;
p < 0.001) and the lack of difference between the
wild-type and mutant mice with respect to this effect. There was also
no significant difference between the groups with respect to basal
firing rates, 4.3 ± 0.6 spikes/sec (mean ± SEM) in
wild-type mice (n = 12) and 4.3 ± 0.5 spikes/sec in the mutant mice (n = 10). Eticlopride
reversed the inhibition to 85-110% of the basal firing rate in every
cell tested. B, Similar dose-response curves indicating
dose-dependent inhibition of SN DA neurons by PD 128907 (F6,138 = 51.5; p < 0.001) and the lack of difference between wild-type and mutant mice
with respect to this effect. There was also no significant difference
in the basal firing rates for SN DA neurons in wild-type (4.1 ± 0.6 spikes/sec; n = 12) and mutant (4.4 ± 0.4 spikes/sec; n = 13) mice. Eticlopride reversed the
agonist-induced inhibition to 82-112% of the basal firing rate in
every cell tested. Each point represents the mean ± SEM.
|
|
View larger version (29K):
[in this window]
[in a new window]
|
Figure 2.
Recording sites for DA neurons within the mouse
midbrain. Approximate recording sites (filled
circles) for DA neurons within the ventral tegmental area
(VTA) and substantia nigra (SN) of wild-type (left) and D3 receptor mutant
(right) mice. Coordinates are expressed as anterior to
lambda. RN, Red nucleus.
|
|
Regulation of DA synthesis is unaltered in D3 receptor
mutant mice
We used the GBL model to determine whether the D3
receptor null mutation altered control of DA synthesis by nerve
terminal autoreceptors. In this model, GBL is used to inhibit impulse
flow in DA neurons. Under these conditions, DA agonists can inhibit DA
synthesis only via nerve terminal autoreceptors and not via long-loop
feedback pathways or stimulation of somatodendritic impulse-modulating
DA autoreceptors (Walters and Roth, 1976). Accumulation of the DA
precursor DOPA was measured after administration of the
L-aromatic amino acid decarboxylase inhibitor NSD 1015 to
prevent conversion of DOPA to DA. DOPA accumulation was used as an
index of the rate of tyrosine hydroxylation, the rate-limiting step in
DA biosynthesis. Studies were performed in both dorsal and ventral
striatum (including nucleus accumbens, olfactory tubercles, and islands
of Calleja) because of reported differences in D3 receptor
expression in these terminal fields (for review, see Sokoloff and
Schwartz, 1995).
Administration of GBL (with NSD 1015) increases DOPA formation in DA
terminal fields because of a reduction in impulse-dependent DA release
from nerve terminals and a resultant reduction in DA autoreceptor
stimulation. The magnitude of the GBL-induced increase in DOPA
formation therefore provides a measure of the magnitude of ongoing
(tonic) suppression of DA synthesis by synthesis-modulating DA
autoreceptors. We found that the magnitude of the GBL-induced increase
in DOPA formation did not differ between D3 receptor mutant
and wild-type mice in either the dorsal or ventral striatum (Fig.
3). This argues strongly against a
contribution of D3 receptors to tonic autoreceptor-mediated
modulation of DA synthesis. Furthermore, PD 128907 was equally potent
at reversing GBL-induced DOPA formation in the mutant and wild-type
mice (Fig. 4), indicating that PD 128907 does not inhibit DA synthesis by stimulating D3
autoreceptors but must do so via D2 autoreceptors. In fact,
at the highest dose tested, PD 128907 appeared somewhat more potent in
the mutant compared with the wild-type mice (Fig. 4).
View larger version (32K):
[in this window]
[in a new window]
|
Figure 3.
Similar GBL-induced increase in striatal DOPA
formation in D3 receptor mutant and wild-type mice. Basal
levels of DOPA, measured after inhibition of L-aromatic
amino acid decarboxylase with NSD 1015, did not significantly differ in
wild-type and D3 receptor mutant mice in either the ventral
or dorsal striatum. GBL significantly increased DOPA formation in both
ventral (F1,20 = 58.58;
p < 0.001) and dorsal
(F1,19 = 261.79; p < 0.001) striatum, as a result of the cessation of impulse-dependent DA
release and the relief of tonic autoreceptor-mediated inhibition of
tyrosine hydroxylase activity. Again, there were no significant
differences in the GBL-induced increase in the two groups of mice.
Error bars indicate SEM. Sample size is six for all groups except for
the NSD alone group (dorsal striatum in mutants) where
n = 5.
|
|
View larger version (31K):
[in this window]
[in a new window]
|
Figure 4.
Similar inhibition of GBL-induced striatal DOPA
formation by PD 128907 in D3 receptor mutant and wild-type
mice. A, Reversal of GBL-induced DOPA synthesis by PD
128907 (F3,57 = 29.97; p < 0.001) in the ventral striatum was not significantly different in
D3 receptor mutant and wild-type mice. Data are presented
as the percent of DOPA levels measured in mice administered GBL plus NSD without PD 128907 (wild type, 2.51 µg/gm/30 min; mutant, 2.53 µg/gm/30 min). Sample sizes for the 0, 0.05, 0.1, and 0.5 mg/kg doses
of PD 128907 are 16, 4, 6, and 6 for the mutant and 19, 3, 5, and 6 for
the wild-type mice, respectively. B, Reversal of
GBL-induced DOPA synthesis by PD 128907 (F3,57 = 25.23; p < 0.001) in the dorsal striatum was also not significantly different in
the two groups of mice; basal levels were 3.26 ng/gm/30 min for the
wild-type and 3.40 ng/gm/30 min for the mutant mice. Error bars
indicate SEM. Sample sizes for the 0, 0.05, 0.1, and 0.5 mg/kg doses of
PD 128907 are 21, 4, 6, and 6 for the mutant and 14, 3, 5, and 5 for
the wild-type mice, respectively. Note that the effect of the highest
dose of PD 128907 on DA synthesis within the dorsal striatum was
actually significantly greater in the mutant than in the wild-type mice
(*p < 0.05; Dunnett's test).
|
|
Regulation of DA release, but not PD 128907-induced suppression of
DA release, is altered in D3 receptor mutant mice
Extracellular DA levels were measured using in vivo
microdialysis in the ventral striatum of freely moving mice. A
representative probe placement is shown in Figure
5. To determine basal levels of DA
efflux, we collected baseline samples of DA for 1 hr before administration of PD 128907. Basal DA efflux was consistently and
significantly higher in mutant mice (Fig.
6A). After collection of baseline samples, PD 128907 was applied by reverse dialysis for 1 hr, followed by a 1 hr recovery period. Initial experiments in
wild-type mice indicated a small (15%), although statistically significant, decrease in DA efflux during perfusion with 100 nM PD 128907 (data not shown); however, to maximize our
ability to detect potential differences between the wild-type and
mutant mice, we used a higher concentration of PD 128907 (1 µM). At
this concentration, PD 128907 significantly decreased DA efflux in both
mutant and wild-type mice, as determined by comparisons of fractions
during drug infusion to the weighted mean of three baseline fractions
(Fig. 6A). When these data were expressed as the
percent of basal DA release (Fig. 6B), an apparent
group difference was observed. To determine whether this was
attributable to the difference in basal DA efflux or to a blunting of
the inhibitory effects of PD 128907 in mutant mice, we performed an
analysis of covariance with basal DA as the covariate. The results
confirmed the significant difference in basal DA levels but indicated
that when this covariate was controlled, there was no significant
difference between mutant and wild-type mice with respect to the
suppression of DA release by PD 128907, i.e., the absolute decrease in
DA release produced by the agonist was not different in the two groups
of mice. Nevertheless, it is apparent that there was a lag in the onset
of the drug-induced suppression in the mutant mice; thus, marked
decreases in DA efflux were observed during the first 20 min of PD
128907 application in the wild-type mice, whereas no effect was
observed during this period in the mutants (Fig. 6).
View larger version (116K):
[in this window]
[in a new window]
|
Figure 5.
Localization of microdialysis probe in the ventral
striatum. In this coronal section of the mouse forebrain, the
tract left by the microdialysis probe can be seen
traversing the ventral striatum. Only the bottom 2 mm of
the probe (located between the arrowheads) consisted of
open dialysis membrane. NAc, Nucleus accumbens;
CPu, caudate-putamen; LV, lateral
ventricle; ICj, island of Calleja; ac,
anterior commisure; cc, corpus callosum.
|
|
View larger version (20K):
[in this window]
[in a new window]
|
Figure 6.
Regulation of basal DA efflux, but not PD
128907-induced suppression of DA release, is altered in D3
receptor mutant mice. A, After 2-3 hr of perfusion,
three baseline fractions (20 min each) were collected (0-60 min).
Basal DA efflux was significantly higher in mutant mice
(F1,9 = 26.9; p = 0.0008).
Values for basal levels in wild-type mice were ~13 nM,
which is comparable with values obtained in our previously published
studies of rat NAc (e.g., see Wolf et al., 1994). PD 128907 was applied
for 60 min (horizontal bar), beginning after
collection of the third baseline fraction. PD 128907 significantly
reduced DA efflux in both wild-type and mutant mice
(F1,10 = 7.798; p = 0.019).
Asterisks indicate points that differ significantly
(p < 0.01; Dunnett's test) when compared with
the weighted mean of the three predrug baseline values. B,
When the results shown in A are expressed as percent of
basal DA efflux, the inhibitory effect of PD 128907 appears blunted in
the mutant mice. However, ANCOVA indicated that this apparent effect
was solely attributable to the initial differences in basal DA efflux,
i.e., there was no difference between the two groups with respect to
the release-suppressing effects of PD 128097 when basal DA levels were
controlled as a covariate. Results are expressed as mean ± SEM
(n = 6/group).
|
|
| |
DISCUSSION |
Autoreceptor regulation of impulse flow and DA synthesis is
mediated primarily by DA D2 receptors
Our results indicate that D3 receptors may be involved
in the regulation of DA release but not via autoreceptor mechanisms. Moreover, D3 receptors do not seem to contribute
significantly to functional pools of either somatodendritic
impulse-modulating or nerve terminal synthesis- or release-modulating
DA autoreceptors. The putative D3 receptor-selective
agonist PD 128907 was equally potent at inhibiting DA cell firing and
decreasing DA synthesis in D3 receptor mutant mice and
their wild-type littermates. Therefore, the ability of PD 128907 and
other putative D3 receptor-selective ligands to regulate DA
neuronal activity and DA synthesis, demonstrated by many laboratories
(see introductory remarks), could not have been by activation of
D3 receptors but must have been mediated by the
well-accepted D2 autoreceptor population. With respect to
impulse-regulating DA autoreceptors, our findings are consistent with a
recent report indicating a complete loss of autoreceptor-mediated hyperpolarization and suppression of activity of midbrain DA neurons in
mice lacking the DA D2 receptor gene (Mercuri et al.,
1997). Taken together, these findings demonstrate the power of the gene knock-out approach in the identification of functions mediated by
individual members of a receptor family.
Our findings stand in contrast to recent reports in which antisense
oligodeoxynucleotides have been used to reduce D3 receptor expression (Nissbrandt et al., 1995; Tepper et al., 1997). Nissbrandt and colleagues (1995) found that intracerebroventricular administration of a D3 receptor antisense oligodeoxynucleotide enhanced
basal levels of DA synthesis in the nucleus accumbens but failed to affect the suppression of synthesis by the nonselective DA receptor agonist apomorphine. More recently, Tepper and coworkers (1997) reported a nearly equivalent (50%) reduction in the inhibitory effects
of apomorphine on the activity of rat SN DA neurons after intra-SN
infusion of antisense oligodeoxynucleotides complementary to the
initial coding region of either the DA D2 or D3
receptor. Despite considerably greater expression of D2
than of D3 receptors in the SN, Tepper et al. (1997) argued
that D3 receptor coupling to transduction events may be
more efficient such that D2 and D3 receptors
play equivalent functional roles as DA autoreceptors.
The results of these antisense oligodeoxynucleotide studies raise the
possibility that in our D3 receptor mutant mice,
D2 receptors had compensated for the loss of D3
receptors and thereby masked any functional loss in our assays. If this
is true, then it is interesting that the reciprocal does not seem to be
true, i.e., that D3 receptors are not able to compensate
for the loss of D2 receptors (Mercuri et al., 1997). This
would suggest that D2 receptors are capable of
autoregulation independently, whereas D3 receptor
autoregulatory activity would be dependent on concurrent D2
autoreceptor stimulation. Although there are no definitive findings
that eliminate the possibility of compensation of D3 receptor function by D2 autoreceptors, we think that this
explanation is unlikely because of the following: (1) such compensation
would have to be precise given the almost identical effects observed in
the mutant and wild-type mice during electrophysiological and neurochemical experiments, (2) such compensation would have to be
specific to certain receptor functions given that differences between
mutant and wild-type mice were observed in basal DA efflux and in
certain behavioral measures (Accili et al., 1996; Xu et al., 1997), (3)
there are no increases in D2 receptor binding densities
caused by the D3 receptor mutation (Accili et al., 1996; Xu
et al., 1997), (4) knock-out of the DA D2 receptor leads to a complete loss of autoreceptor function in the SN (Mercuri et al.,
1997), and (5) there have been no documented cases of compensatory upregulation of related receptor subtypes after deletion of G-protein coupled receptors (for review, see Tecott et al., 1996).
It is also possible that the difference between findings from antisense
knock-down and genetic knock-out studies reflects differences between
mice and rats with respect to D3 receptor contributions to
autoregulation. However, there does not seem to be a difference in the
levels of D3 receptors expressed in the midbrain of these
two species (Mercuri et al., 1997). Moreover, recent studies have
demonstrated that putative D3 autoreceptor effects in rats
are in fact caused by D2 receptors, including hyperpolarization and suppression of DA neuron activity (Bowery et al.,
1996). Given the low abundance and highly restricted expression of
D3 mRNA by DA neurons (Diaz et al., 1995), it is certainly possible that a small number of DA neurons express functional D3 autoreceptors. However, any autoreceptor role occurring
in such a small neuronal population is unlikely to exert significant impact on the in vivo activity of the mesotelencephalic DA
systems as a whole, unless such a role is accomplished by low levels of D3 receptors the mRNA of which is below the detection limit
of current in situ hybridization (Bouthenet et al., 1991;
Diaz et al., 1995), reverse transcriptase-PCR (Valerio et al., 1994), and ribonuclease protection (Richtand et al., 1995) assays. Although we
cannot exclude this possibility and the findings of Tepper et al.
(1997) certainly support it, we believe the bulk of the evidence argues
that D2 receptors are primarily responsible for autoregulation of DA neuronal function.
D3 receptors may contribute to local regulation of
DA release
Our microdialysis studies indicated a significant increase in
basal DA efflux in the ventral striatum of D3 receptor
mutant mice compared with their wild-type littermates. Although
"no-net flux" dialysis studies are often needed to quantify
differences in basal transmitter efflux in vivo (for review,
see Justice, 1993), the difference between D3 receptor
mutant and wild-type mice was quite robust, with all but one mutant
mouse showing higher basal DA efflux than any of the wild-type mice.
Increased basal DA efflux might be expected if nerve terminal
D3 autoreceptors normally exert a tonic inhibitory
influence on DA release. However, the results obtained with PD 128907 are incompatible with this simple interpretation because this putative
D3 receptor-selective agonist inhibited DA release by the
same absolute amount in D3 receptor mutant and wild-type
mice. Thus, no reduction of DA autoreceptor modulation occurred as a
result of the D3 receptor mutation. Although the percent
decrease caused by PD 128907 was smaller in the mutant mice, this
effect was attributable to their higher basal DA levels, a factor known
to reduce the ability of DA agonists to suppress DA release (Cubeddu
and Hoffman, 1982; Dwoskin and Zahniser, 1986; for review, see Wolf and
Roth, 1987).
An alternative explanation for our findings is that DA release is
normally modulated both by D2 release-modulating
autoreceptors and by negative feedback pathways engaged by postsynaptic
D3 (and other D2-class) receptors. Loss of
D3 receptor-mediated inhibitory feedback would explain
increased basal DA efflux, whereas activation of D2
release-modulating autoreceptors by PD 128907 would explain the normal
inhibitory effects on DA release. This model is consistent with the
D3 mRNA findings indicating that D3 receptors
are distributed primarily within target neurons of the ascending DA
systems. In ventral striatal terminal fields where the D3
receptor is most highly expressed (nucleus accumbens shell, olfactory
tubercle, and islands of Calleja), there is good agreement between
levels of D3 receptor mRNA and D3 receptor
binding sites (Diaz et al., 1995), suggesting that most D3
receptors exist on dendrites, soma, or local terminals of intrinsic
neurons. If postsynaptic D3 receptors are coupled to
feedback pathways that normally exert an inhibitory influence on DA
release, the loss of such feedback might lead to increased basal DA
efflux but leave D2 autoreceptor-mediated effects
intact.
Negative feedback pathways engaged by postsynaptic D3
receptors might involve retrograde messengers, short-loop paths (either mono- or multisynaptic) terminating on DA terminals, or
striatomesencephalic (long-loop) projections regulating impulse flow at
the level of DA cell bodies and thereby influencing impulse-dependent
DA release from nerve terminals. We do not favor the latter mechanism
because (1) we observed no differences in basal firing rates of DA
neurons in mutant and wild-type mice, and (2) previous work has shown that local application of DA agonists by reverse dialysis inhibits DA
release via local mechanisms and not via long-loop feedback effects on
DA impulse flow (Timmerman et al., 1990). As for the first two
possibilities, it has long been known that intrinsic striatal
neurotransmitters (e.g., acetylcholine, GABA, enkephalin, and substance
P) as well as corticostriatal afferents (e.g., glutamate) may modulate
DA release (for review, see Chesselet, 1984), and similar effects of
the retrograde messenger nitric oxide have recently been demonstrated
(Lonart et al., 1993). DA agonists, when applied locally by reverse
dialysis, could conceivably engage such local mechanisms, in addition
to exerting effects via nerve terminal DA autoreceptors. Indeed, the
slower onset of the PD 128907-induced suppression of DA release in the
mutants suggests that at least two processes, one of which is faster
and involves D3 receptors, are responsible for this effect
in the wild-type mice.
Conclusions
Our findings are incongruent with recent claims that
D3 receptors function as DA autoreceptors. D3
receptors may contribute to regulation of DA release, but the mechanism
may involve postsynaptically activated feedback as opposed to nerve
terminal autoreceptors. If so, then D3 receptors would not
only be subject to anterograde regulation by unknown factors released
by DA neurons (Lévesque et al., 1995) but might also engage
feedback mechanisms to control DA release. In conclusion, the results
obtained with D3 mutant mice support a large body of
earlier work suggesting that D2 receptors constitute the
vast majority of DA autoreceptors and that the ability of
D3-preferring ligands to alter these functions in
vivo, as demonstrated by numerous studies in normal rats (see
introductory remarks), reflects their lack of selectivity for
D3 receptors and must be attributed to stimulation of
D2 receptors.
| |
FOOTNOTES |
Received Sept. 30, 1997; revised Dec. 22, 1997; accepted Dec. 31, 1997.
This work was supported by United States Public Health Service Grants
DA07735 (M.E.W.) and DA04093 (F.J.W.) and by the Shionogi Institute for
Medical Sciences (S.T.). F.J.W. is a recipient of a Research Scientist
Development Award DA00207 from the National Institute on Drug Abuse.
T.E.K. (DA 05815) and D.C.C. (DA 05794) are supported by National
Research Service awards from the National Institute on Drug Abuse. We
thank Lorinda Baker and Chang-Jiang Xue for excellent technical
assistance.
Correspondence should be addressed to Dr. Francis J. White, Finch
University of Health Sciences, Chicago Medical School, Department of
Neuroscience, 3333 Green Bay Road, North Chicago, IL 60064-3095.
Dr. Xu's present address: Department of Cell Biology, Neurobiology,
and Anatomy, University of Cincinnati College of Medicine, 231 Bethesda
Avenue, Cincinnati, OH 45267-0521.
| |
REFERENCES |
-
Accili D,
Fishburn CS,
Drago J,
Steiner H,
Lachowicz JE,
Park BH,
Gauda EB,
Lee EJ,
Cool MH,
Sibley DR,
Gerfen CR,
Westphal H,
Fuchs S
(1996)
A targeted mutation of the D3 dopamine receptor gene is associated with hyperactivity in mice.
Proc Natl Acad Sci USA
93:1945-1949[Abstract/Free Full Text].
-
Aghajanian GK,
Bunney BS
(1977)
Dopamine "autoreceptors": pharmacological characterization by microiontophoretic single unit recording studies.
Naunyn Schmiedebergs Arch Pharmacol
297:1-7[Web of Science][Medline].
-
Ahlenius S,
Salmi P
(1994)
Behavioral and biochemical effects of the dopamine D3 receptor-selective ligand, 7-OH-DPAT, in the normal and the reserpine-treated rat.
Eur J Pharmacol
260:177-181[Web of Science][Medline].
-
Aretha CW,
Sinha A,
Galloway MP
(1995)
Dopamine D3-preferring ligands act at synthesis modulating autoreceptors.
J Pharmacol Exp Ther
274:609-613[Abstract/Free Full Text].
-
Bouthenet M-L,
Souil E,
Martres M-P,
Sokoloff P,
Giros B,
Schwartz J-C
(1991)
Localization of dopamine D3 receptor mRNA in the rat brain using in situ hybridization histochemistry: comparison with dopamine D2 receptor mRNA.
Brain Res
564:203-219[Web of Science][Medline].
-
Bowery BJ,
Razzaque Z,
Emms F,
Patel S,
Freedman S,
Bristow L,
Kulagowski J,
Seabrook GR
(1996)
Antagonism of the effects of (+)-PD 128907 on midbrain dopamine neurones in rat brain slices by a selective D2 receptor antagonist L-741,626.
Br J Pharmacol
119:1491-1497[Web of Science][Medline].
-
Bunney BS,
Walters JR,
Roth RH,
Aghajanian GK
(1973)
Dopaminergic neurons: effect of antipsychotic drugs and amphetamine on single cell activity.
J Pharmacol Exp Ther
185:560-571[Abstract/Free Full Text].
-
Burris KD,
Pacheco MA,
Filtz TM,
Kung M-P,
Kung HF,
Molinoff PB
(1995)
Lack of discrimination by agonists for D2 and D3 dopamine receptors.
Neuropsychopharmacology
12:335-345[Web of Science][Medline].
-
Chesselet M-F
(1984)
Presynaptic regulation of neurotransmitter release in the brain: facts and hypothesis.
Neuroscience
12:347-375[Web of Science][Medline].
-
Chio CL,
Lajiness ME,
Huff RM
(1994)
Activation of heterologously expressed D3 dopamine receptors: comparison with D2 dopamine receptors.
Mol Pharmacol
45:51-60[Abstract].
-
Clark D,
White FJ
(1987)
Review: D1 dopamine receptor-the search for a function: a critical evaluation of the D1/D2 dopamine receptor classification and its functional implications.
Synapse
1:347-388[Web of Science][Medline].
-
Cubeddu LX,
Hoffman IS
(1982)
Operational characteristics of the inhibitory feedback mechanism for regulation of dopamine release via presynaptic receptors.
J Pharmacol Exp Ther
223:497-501[Free Full Text].
-
Damsma G,
Bottema T,
Westerink BHC,
Tepper PG,
Dijkstra D,
Pugsley TA,
Mackenzie RG,
Heffner TG,
Wikström H
(1993)
Pharmacological aspects of R-(+)-7-OH-DPAT, a putative dopamine D3 receptor ligand.
Eur J Pharmacol
249:R9-R10[Web of Science][Medline].
-
Devoto P,
Collu M,
Muntoni AL,
Pistis M,
Serra G,
Gessa GL,
Diana M
(1995)
Biochemical and electrophysiological effects of 7-OH-DPAT on the mesolimbic dopaminergic system.
Synapse
20:153-155[Web of Science][Medline].
-
Diaz J,
Lévesque D,
Lammers CH,
Griffon N,
Martres M-P,
Schwartz J-C,
Sokoloff P
(1995)
Phenotypical characterization of neurons expressing the dopamine D3 receptor in the rat brain.
Neuroscience
65:731-745[Web of Science][Medline].
-
Dwoskin LP,
Zahniser NR
(1986)
Robust modulation of [3H]dopamine release from rat striatal slices by D-2 dopamine receptors.
J Pharmacol Exp Ther
239:442-453[Abstract/Free Full Text].
-
Farnebo L-O,
Hamberger B
(1971)
Drug-induced changes in the release of 3H-monoamines from field stimulated rat brain slices.
Acta Physiol Scand Suppl
371:35-44[Medline].
-
Gainetdinov RR,
Grekhova TV,
Sotnikova TD,
Rayevsky KS
(1994)
Dopamine D2 and D3 receptor preferring antagonists differentially affect striatal release and metabolism in conscious rats.
Eur J Pharmacol
261:327-331[Web of Science][Medline].
-
Gainetdinov RR,
Sotnikova TD,
Grekhova TV,
Rayevsky KS
(1996)
In vivo evidence for preferential role of dopamine D3 receptor in the presynaptic regulation of dopamine release but not synthesis.
Eur J Pharmacol
308:261-269[Web of Science][Medline].
-
Galloway MP,
Wolf ME,
Roth RH
(1986)
Regulation of dopamine synthesis in the medial prefrontal cortex is mediated by release modulating autoreceptors: studies in vivo.
J Pharmacol Exp Ther
236:689-698[Abstract/Free Full Text].
-
Gilbert DB,
Millar J,
Cooper SJ
(1995)
The putative dopamine D3 agonist, 7-OH-DPAT, reduces dopamine release in the nucleus accumbens and electrical self-stimulation to the ventral tegmentum.
Brain Res
681:1-7[Web of Science][Medline].
-
Gobert A,
Rivet JM,
Audinot V,
Cistarelli L,
Spedding M,
Vian J,
Peglion JL,
Millan MJ
(1995)
Functional correlates of dopamine D3 receptor activation in the rat in vivo and their modulation by the selective antagonist, (+)-S 14297. 2. Both D2 and "Silent" D3 autoreceptors control synthesis and release in mesolimbic, mesocortical and nigrostriatal pathways.
J Pharmacol Exp Ther
275:899-913[Abstract/Free Full Text].
-
Gobert A,
Lejeune F,
Rivet JM,
Cistarelli L,
Millan MJ
(1996)
Dopamine D3 (auto) receptors inhibit dopamine release in the frontal cortex of freely moving rats in vivo.
J Neurochem
66:2209-2212[Web of Science][Medline].
-
Gonzalez AM,
Sibley DR
(1995)
[3H]7-OH-DPAT is capable of labeling dopamine D2 as well as D3 receptors.
Eur J Pharmacol
272:R1-R3[Web of Science][Medline].
-
Healy DJ,
Meador-Woodruff JH
(1996)
Differential regulation, by MK-801, of dopamine receptor gene expression in rat nigrostriatal and mesocorticolimbic systems.
Brain Res
708:38-44[Web of Science][Medline].
-
Justice Jr JB
(1993)
Quantitative microdialysis of neurotransmitters.
J Neurosci Methods
48:263-276[Web of Science][Medline].
-
Kehr W,
Carlsson A,
Lindqvist M,
Magnusson T,
Atack C
(1972)
Evidence for a receptor-mediated feedback control of striatal tyrosine hydroxylase activity.
J Pharm Pharmacol
24:744-746[Web of Science][Medline].
-
Kreiss DS,
Bergstrom DA,
Gonzalez AM,
Huang K-X,
Sibley DR,
Walters JR
(1995)
Dopamine receptor agonist potencies for inhibition of cell firing correlate with dopamine D3 receptor binding affinities.
Eur J Pharmacol
277:209-214[Web of Science][Medline].
-
Landwehrmeyer B,
Mengod G,
Palacios JM
(1993)
Differential visualization of dopamine D2 and D3 receptor sites in rat brain. A comparative study using in situ hybridization histochemistry and ligand binding autoradiography.
Eur J Neurosci
5:145-153[Web of Science][Medline].
-
Large CH,
Stubbs CM
(1994)
The dopamine D3 receptor: Chinese hamsters or Chinese whispers.
Trends Pharmacol
15:46-47[Medline].
-
Lejeune F,
Millan MJ
(1995)
Activation of dopamine D3 autoreceptors inhibits firing of ventral tegmental dopaminergic neurones in vivo.
Eur J Pharmacol
275:R7-R9[Web of Science][Medline].
-
Lévesque D,
Martres M-P,
Diaz J,
Griffon N,
Lammers CH,
Sokoloff P,
Schwartz J-C
(1995)
A paradoxical regulation of the dopamine D3 receptor expression suggests the involvement of an anterograde factor from dopamine neurons.
Proc Natl Acad Sci USA
92:1719-1723[Abstract/Free Full Text].
-
Lonart G,
Cassels KL,
Johnson KM
(1993)
Nitric oxide induces calcium-dependent [3H]dopamine release from striatal slices.
J Neurosci Res
35:192-198[Web of Science][Medline].
-
Mansour A,
Meador-Woodruff JH,
Bunzow JR,
Civelli O,
Akil H,
Watson SJ
(1990)
Localization of dopamine D2 receptor mRNA and D1 and D2 receptor binding in the rat brain and pituitary: an in situ hybridization-receptor autoradiographic analysis.
J Neurosci
10:2587-2600[Abstract].
-
Meador-Woodruff JH,
Mansour A,
Bunzow JR,
Van Tol HHM,
Watson SJ,
Civelli O
(1989)
Distribution of D2 dopamine receptor mRNA in rat brain.
Proc Natl Acad Sci USA
86:7625-7628[Abstract/Free Full Text].
-
Meador-Woodruff JH,
Damask SP,
Watson Jr SJ
(1994)
Differential expression of autoreceptors in the ascending dopamine systems of the human brain.
Proc Natl Acad Sci USA
91:8297-8301[Abstract/Free Full Text].
-
Meller E,
Bohmaker K,
Goldstein M,
Basham DA
(1993)
Evidence that striatal synthesis-inhibiting autoreceptors are dopamine D3 receptors.
Eur J Pharmacol
249:R5-R6[Web of Science][Medline].
-
Mengod G,
Martinez-Mir MI,
Vilaro MT,
Palacios JM
(1989)
Localization of the mRNA for the dopamine D2 receptor in the rat brain by in situ hybridization histochemistry.
Proc Natl Acad Sci USA
86:8560-8564[Abstract/Free Full Text].
-
Mercuri NB,
Saiardi A,
Bonci A,
Picetti R,
Calabresi P,
Bernardi G,
Borrelli E
(1997)
Loss of autoreceptor function in dopaminergic neurons from dopamine D2 receptor deficient mice.
Neuroscience
79:323-327[Web of Science][Medline].
-
Nissbrandt H,
Ekman A,
Eriksson E,
Heilig M
(1995)
Dopamine D3 receptor antisense influences dopamine synthesis in rat brain.
NeuroReport
6:573-576[Web of Science][Medline].
-
O'Hara CM,
Uhland-Smith A,
O'Malley KL,
Todd RD
(1996)
Inhibition of dopamine synthesis by dopamine D2 and D3 but not D4 receptors.
J Pharmacol Exp Ther
277:186-192[Abstract/Free Full Text].
-
Potenza MN,
Graminski GF,
Schmauss C,
Lerner MR
(1994)
Functional expression and characterization of human D2 and D3 dopamine receptors.
J Neurosci
14:1463-1476[Abstract].
-
Pugsley TA,
Davis MD,
Akunne HC,
Mackenzie RG,
Shih YH,
Damsma G,
Wikstrom H,
Whetzel SZ,
Georgic LM,
Cooke LW,
Demattos SB,
Corbin AE,
Glase SA,
Wise LD,
Dijkstra D,
Heffner TG
(1995)
Neurochemical and functional characterization of the preferentially selective dopamine D3 agonist PD 128907.
J Pharmacol Exp Ther
275:1355-1366[Abstract/Free Full Text].
-
Richtand NM,
Kelsoe JR,
Segal DS,
Kuczenski R
(1995)
Regional quantification of D1, D2, and D3 dopamine receptor mRNA in rat brain using a ribonuclease protection assay.
Mol Brain Res
33:97-103[Medline].
-
Rivet J-M,
Audinot V,
Gobert A,
Peglion J-L,
Millan MJ
(1994)
Modulation of mesolimbic dopamine release by the selective dopamine D3 receptor antagonist, (+)-S 14297.
Eur J Pharmacol
265:175-177[Web of Science][Medline].
-
Routledge C,
Thorn L,
Ashmeade T,
Taylor S
(1996)
Elucidation of D3 receptor function in vivo: do D3 receptors mediate inhibition of dopamine neuronal activity?
Biochem Soc Trans
24:199-201[Web of Science][Medline].
-
Sanghera MK,
Trulson ME,
German DC
(1984)
Electrophysiological properties of mouse dopamine neurons: in vivo and in vitro studies.
Neuroscience
12:793-801[Web of Science][Medline].
-
Sautel F,
Griffon N,
Lévesque D,
Pilon C,
Schwartz J-C,
Sokoloff P
(1995)
A functional test identifies dopamine agonists selective for D3 versus D2 receptors.
NeuroReport
6:329-332[Web of Science][Medline].
-
Sokoloff P,
Schwartz J-C
(1995)
Novel dopamine receptors half a decade later.
Trends Pharmacol
16:270-275[Medline].
-
Sokoloff P,
Giros B,
Martres M-P,
Bouthenet M-L,
Schwartz J-C
(1990)
Molecular cloning and characterization of a novel dopamine receptor (D3) as a target for neuroleptics.
Nature
347:146-151[Medline].
-
Svensson K,
Johansson AM,
Magnusson T,
Carlsson A
(1986)
(+)-AJ 76 and (+)-UH 232: central stimulants acting as preferential dopamine autoreceptor antagonists.
Naunyn Schmiedebergs Arch Pharmacol
334:234-245[Web of Science][Medline].
-
Tang L,
Todd RD,
O'Malley KL
(1994)
Dopamine D2 and D3 receptors inhibit dopamine release.
J Pharmacol Exp Ther
270:475-479[Abstract/Free Full Text].
-
Tecott LH,
Brennan TJ,
Guh L
(1996)
Gene targeting approaches to analyze neurotransmitter receptor function.
Semin Neurosci
8:145-152.
-
Tepper JM,
Sun BC,
Martin LP,
Creese I
(1997)
Functional roles of dopamine D2 and D3 autoreceptors on nigrostriatal neurons analyzed by antisense knockdown in vivo.
J Neurosci
17:2519-2530[Abstract/Free Full Text].
-
Timmerman W,
De Vries JB,
Westerink BHC
(1990)
Effects of D-2 agonists on the release of dopamine: localization of the mechanism of action.
Naunyn Schmiedebergs Arch Pharmacol
342:650-654[Web of Science][Medline].
-
Valerio A,
Belloni M,
Gorno ML,
Tinti C,
Memo M,
Spano P
(1994)
Dopamine D2, D3, and D4 receptor mRNA levels in rat brain and pituitary during aging.
Neurobiol Aging
15:713-719[Web of Science][Medline].
-
Walters JR,
Roth RH
(1976)
Dopaminergic neurons: an in vivo system for measuring drug interactions with presynaptic receptors.
Naunyn Schmiedebergs Arch Pharmacol
296:5-14[Web of Science][Medline].
-
Wang RY
(1981)
Dopaminergic neurons in the rat ventral tegmental area. I. Identification and characterization.
Brain Res Rev
3:123-140.
-
White FJ,
Hu X-T,
Zhang X-F,
Wolf ME
(1995)
Repeated administration of cocaine or amphetamine alters neuronal responses to glutamate in the mesoaccumbens dopamine system.
J Pharmacol Exp Ther
273:445-454[Abstract/Free Full Text].
-
Wolf ME,
Roth RH
(1987)
Dopamine autoreceptors.
In: Dopamine receptors (Creese I,
Fraser CM,
eds), pp 45-96. New York: Liss.
-
Wolf ME,
White FJ,
Hu X-T
(1994)
MK-801 prevents alterations in the mesoaccumbens dopamine system associated with behavioral sensitization to amphetamine.
J Neurosci
14:1735-1745[Abstract].
-
Xu M,
Hu X-T,
Cooper DC,
Moratalla R,
Graybiel AM,
White FJ,
Tonegawa S
(1994)
Elimination of cocaine-induced hyperactivity and dopamine-mediated neurophysiological effects in dopamine D1 receptor deficient mice.
Cell
79:945-955[Web of Science][Medline].
-
Xu M,
Koeltzow TE,
Santiago GT,
Moratalla R,
Cooper DC,
Hu X-T,
White NM,
Graybiel AM,
White FJ,
Tonegawa S
(1997)
Dopamine D3 receptor mutant mice exhibit increased behavioral sensitivity to concurrent stimulation of D1 and D2 receptors.
Neuron
19:838-848.
-
Xue CJ,
Ng JP,
Li Y,
Wolf ME
(1996)
Acute and repeated systemic amphetamine administration: effects on extracellular glutamate, aspartate, and serine levels in rat ventral tegmental area and nucleus accumbens.
J Neurochem
67:352-363[Web of Science][Medline].
Copyright © 1998 Society for Neuroscience 0270-6474/98/1862231-08$05.00/0
This article has been cited by other articles:
|
|
|
|
 
A. Zapata, B. Kivell, Y. Han, J. A. Javitch, E. A. Bolan, D. Kuraguntla, V. Jaligam, M. Oz, L. D. Jayanthi, D. J. Samuvel, et al.
Regulation of Dopamine Transporter Function and Cell Surface Expression by D3 Dopamine Receptors
J. Biol. Chem.,
December 7, 2007;
282(49):
35842 - 35854.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
V. Davila, Z. Yan, L. C. Craciun, D. Logothetis, and D. Sulzer
D3 Dopamine Autoreceptors Do Not Activate G-Protein-Gated Inwardly Rectifying Potassium Channel Currents in Substantia Nigra Dopamine Neurons
J. Neurosci.,
July 2, 2003;
23(13):
5693 - 5697.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
N. Lindgren, A. Usiello, M. Goiny, J. Haycock, E. Erbs, P. Greengard, T. Hokfelt, E. Borrelli, and G. Fisone
Distinct roles of dopamine D2L and D2S receptor isoforms in the regulation of protein phosphorylation at presynaptic and postsynaptic sites
PNAS,
April 1, 2003;
100(7):
4305 - 4309.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Narita, K. Mizuo, H. Mizoguchi, M. Sakata, M. Narita, L. F. Tseng, and T. Suzuki
Molecular Evidence for the Functional Role of Dopamine D3 Receptor in the Morphine-Induced Rewarding Effect and Hyperlocomotion
J. Neurosci.,
February 1, 2003;
23(3):
1006 - 1012.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Schmitz, C. Schmauss, and D. Sulzer
Altered Dopamine Release and Uptake Kinetics in Mice Lacking D2 Receptors
J. Neurosci.,
September 15, 2002;
22(18):
8002 - 8009.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. M. Mottola, J. D. Kilts, M. M. Lewis, H. S. Connery, Q. D. Walker, S. R. Jones, R. G. Booth, D. K. Hyslop, M. Piercey, R. M. Wightman, et al.
Functional Selectivity of Dopamine Receptor Agonists. I. Selective Activation of Postsynaptic Dopamine D2 Receptors Linked to Adenylate Cyclase
J. Pharmacol. Exp. Ther.,
June 1, 2002;
301(3):
1166 - 1178.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. Rouge-Pont, A. Usiello, M. Benoit-Marand, F. Gonon, P. V. Piazza, and E. Borrelli
Changes in Extracellular Dopamine Induced by Morphine and Cocaine: Crucial Control by D2 Receptors
J. Neurosci.,
April 15, 2002;
22(8):
3293 - 3301.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. B. Bunney, S. B. Appel, and M. S. Brodie
Electrophysiological Effects of Cocaethylene, Cocaine, and Ethanol on Dopaminergic Neurons of the Ventral Tegmental Area
J. Pharmacol. Exp. Ther.,
April 12, 2001;
297(2):
696 - 703.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
R. D. Mayfield and N. R. Zahniser
Dopamine D2 Receptor Regulation of the Dopamine Transporter Expressed in Xenopus laevis Oocytes Is Voltage-Independent
Mol. Pharmacol.,
January 1, 2001;
59(1):
113 - 121.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
G. D. Stanwood, R. P. Artymyshyn, M.-P. Kung, H. F. Kung, I. Lucki, and P. McGonigle
Quantitative Autoradiographic Mapping of Rat Brain Dopamine D3 Binding with [125I]7-OH-PIPAT: Evidence for the Presence of D3 Receptors on Dopaminergic and Nondopaminergic Cell Bodies and Terminals
J. Pharmacol. Exp. Ther.,
December 1, 2000;
295(3):
1223 - 1231.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
J. Diaz, C. Pilon, B. Le Foll, C. Gros, A. Triller, J.-C. Schwartz, and P. Sokoloff
Dopamine D3 Receptors Expressed by All Mesencephalic Dopamine Neurons
J. Neurosci.,
December 1, 2000;
20(23):
8677 - 8684.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Marinelli and F. J. White
Enhanced Vulnerability to Cocaine Self-Administration Is Associated with Elevated Impulse Activity of Midbrain Dopamine Neurons
J. Neurosci.,
December 1, 2000;
20(23):
8876 - 8885.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
Y. Wang, R. Xu, T. Sasaoka, S. Tonegawa, M.-P. Kung, and E.-B. Sankoorikal
Dopamine D2 Long Receptor-Deficient Mice Display Alterations in Striatum-Dependent Functions
J. Neurosci.,
November 15, 2000;
20(22):
8305 - 8314.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Reavill, S. G. Taylor, M. D. Wood, T. Ashmeade, N. E. Austin, K. Y. Avenell, I. Boyfield, C. L. Branch, J. Cilia, M. C. Coldwell, et al.
Pharmacological Actions of a Novel, High-Affinity, and Selective Human Dopamine D3 Receptor Antagonist, SB-277011-A
J. Pharmacol. Exp. Ther.,
September 1, 2000;
294(3):
1154 - 1165.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
M. J. Millan, A. Gobert, A. Newman-Tancredi, F. Lejeune, D. Cussac, J.-M. Rivet, V. Audinot, T. Dubuffet, and G. Lavielle
S33084, a Novel, Potent, Selective, and Competitive Antagonist at Dopamine D3-Receptors: I. Receptorial, Electrophysiological and Neurochemical Profile Compared with GR218,231 and L741,626
J. Pharmacol. Exp. Ther.,
June 1, 2000;
293(3):
1048 - 1062.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
C. Schmauss
Dopamine Receptors: Novel Insights from Biochemical and Genetic Studies
Neuroscientist,
April 1, 2000;
6(2):
127 - 138.
[Abstract]
[PDF]
|
|
|
|
|
|
|
M. J. Millan, F. Lejeune, and A. Gobert
Reciprocal autoreceptor and heteroreceptor control of serotonergic, dopaminergic and noradrenergic transmission in the frontal cortex: relevance to the actions of antidepressant agents
J Psychopharmacol,
March 1, 2000;
14(2):
114 - 138.
[Abstract]
[PDF]
|
|
|
|
|
|
|
M. J. Millan, A. Gobert, A. Newman-Tancredi, F. Lejeune, D. Cussac, J.-M. Rivet, V. Audinot, A. Adhumeau, M. Brocco, J.-P. Nicolas, et al.
S18327 (1-{2-[4-(6-Fluoro-1,2-benzisoxazol-3-yl)piperid-1-yl]ethyl}3-phenyl imidazolin-2-one), a Novel, Potential Antipsychotic Displaying Marked Antagonist Properties at alpha 1- and alpha 2-Adrenergic Receptors: I. Receptorial, Neurochemical, and Electrophysiological Profile
J. Pharmacol. Exp. Ther.,
January 1, 2000;
292(1):
38 - 53.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
S. Yamada, M. Harano, N. Annoh, and M. Tanaka
Dopamine D3 Receptors Modulate Evoked Dopamine Release from Slices of Rat Nucleus Accumbens Via Muscarinic Receptors, But Not from the Striatum
J. Pharmacol. Exp. Ther.,
December 1, 1999;
291(3):
994 - 998.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
M.-Y. Jung and C. Schmauss
Decreased c-fos Responses to Dopamine D1 Receptor Agonist Stimulation in Mice Deficient for D3 Receptors
J. Biol. Chem.,
October 8, 1999;
274(41):
29406 - 29412.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. V. Kuzhikandathil and G. S. Oxford
Activation of Human D3 Dopamine Receptor Inhibits P/Q-Type Calcium Channels and Secretory Activity in AtT-20 Cells
J. Neurosci.,
March 1, 1999;
19(5):
1698 - 1707.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
V. Audinot, A. Newman-Tancredi, A. Gobert, J.-M. Rivet, M. Brocco, F. Lejeune, L. Gluck, I. Desposte, K. Bervoets, A. Dekeyne, et al.
A Comparative In Vitro and In Vivo Pharmacological Characterization of the Novel Dopamine D3 Receptor Antagonists (+)-S 14297, Nafadotride, GR 103,691 and U 99194
J. Pharmacol. Exp. Ther.,
October 1, 1998;
287(1):
187 - 197.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
M. J. Millan, A. Gobert, A. Newman-Tancredi, V. Audinot, F. Lejeune, J.-M. Rivet, D. Cussac, J.-P. Nicolas, O. Muller, and G. Lavielle
S 16924 ((R)-2-{1-[2-(2,3-Dihydro-Benzo[1,4] Dioxin-5-Yloxy)-Ethyl]-Pyrrolidin-3yl}-1-(4-Fluoro-Phenyl)-Ethanone), a Novel, Potential Antipsychotic with Marked Serotonin (5-HT)1A Agonist Properties: I. Receptorial and Neurochemical Profile in Comparison with Clozapine and Haloperidol
J. Pharmacol. Exp. Ther.,
September 1, 1998;
286(3):
1341 - 1355.
[Abstract]
[Full Text]
|
|
|
|
|
|
|
Z. U. Khan, L. Mrzljak, A. Gutierrez, A. de la Calle, and P. S. Goldman-Rakic
Prominence of the dopamine D2 short isoform in dopaminergic pathways
PNAS,
June 23, 1998;
95(13):
7731 - 7736.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
Top
Abstract
Introduction
