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Vol. 281, Issue 1, 360-368, 1997
Division of Neurological Sciences, Department of Psychiatry, University of British Columbia, 2255 Wesbrook Mall, Vancouver, B.C., Canada
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Abstract |
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 Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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The role of dopamine (DA) D1 receptors in the regulation of acetylcholine (ACh) release in the striatum was studied using in vivo microdialysis in freely moving rats. Systemic administration of the full D1 DA receptor agonist A-77636 (4 µmol/kg) increased striatal ACh release by 53% above the base line and decreased DA release by 33%. Local application of A-77636 (10 and 100 µM) by reverse dialysis was without effect on either striatal ACh or DA release. Systemic administration of the D1 DA receptor antagonist SCH 23390 (0.74 µmol/kg) or SCH 39166 (1.42 µmol/kg) blocked the stimulation of striatal ACh release produced by systemic A-77636 (4 µmol/kg). Local perfusion of either SCH 23390 or SCH 39166 did not decrease basal ACh release. Furthermore, when applied locally via the dialysis probe, SCH 23390 (12 µM) or SCH 39166 (50 µM) failed to attenuate the stimulation of striatal ACh release produced by systemic A-77636. Similarly, d-amphetamine (5.42 µmol/kg)-induced increases in striatal ACh release were not modified by simultaneous local perfusion with SCH 39166 (50 µM). These findings are consistent with the hypothesis that D1 receptor activation stimulates ACh release in the striatum. However, because local application of D1 receptor agonists and antagonists fail to influence ACh release, the relevant D1 receptors are not located in the striatum. The use of unphysiological dialysis conditions (high concentrations of acetylcholinesterase (AChE) inhibitors, high Ca++ concentrations and an absence of Mg++ in the perfusion fluid) may account for some earlier suggestions that local D1 receptors regulate ACh release in the striatum.
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Introduction |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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The observations that dopamine
receptor agonists and muscarinic receptor antagonists ameliorate
symptoms of Parkinson's disease has provided the basis for the
hypothesis that DA and ACh have opposing actions on striatal function
(Lehmann and Langer, 1983
). Approximately 1% to 2% of striatal
neurons are cholinergic (Fibiger, 1982; Satoh et al., 1983),
and these neurons receive a direct input from dopaminergic neurons
located primarily in the pars compacta of the substantia nigra (Kubota
et al., 1987; Lehmann and Langer, 1983). Nearly all striatal
cholinergic neurons express D2 receptor mRNA, whereas estimates of the
extent to which these neurons also contain D1 receptor mRNA vary
considerably (20%-70%) (Guennoun and Bloch, 1992; Jongen-Relo
et al., 1995; Le Moine et al., 1990; Le Moine
et al., 1991).
In vitro studies using striatal slices have demonstrated
that D2 receptor agonists decrease ACh release (Herrting et
al., 1980; Stoof and Kebabian, 1982). Nonselective DA receptor
agonists decrease ACh turnover (Trabucchi et al., 1975) and
increase tissue concentrations of ACh (McGeer et al., 1974),
and this has been interpreted as indicating that these agents decrease
ACh release. On the other hand, D2 antagonists apparently enhance the
activity of striatal cholinergic neurons, as reflected by increased ACh release (Stadler et al., 1973) and turnover (Trabucchi
et al., 1975) and by reduced tissue concentrations (McGeer
et al., 1974). In vivo microdialysis studies have
confirmed that D2 receptor agonists reduce (Bertorelli and Consolo,
1990; Damsma et al., 1990a; De Boer et al.,
1990), whereas D2 receptor antagonists increase, striatal ACh release
(Bertorelli and Consolo, 1990; Damsma et al., 1990a). In
contrast, systemic administration of D1 receptor agonists increases
striatal ACh release (Damsma et al., 1990b), as does
systemic administration of indirect dopaminergic agonists such as
d-amphetamine, nomifensine (Consolo et al., 1992; Damsma et al., 1991; Florin et al., 1992) and
cocaine (Imperato et al., 1993). Interestingly, no
unequivocal evidence has yet been provided by in vitro
studies for a role of striatal D1 receptors in the control of ACh
release (Gorell and Czarnecki, 1986; Gorell et al., 1986).
Indeed, there is considerable evidence for the lack of a D1-mediated
regulation of [3H] ACh evoked release from striatal
slices (Dolezal et al., 1992; Login et al., 1995;
Scatton, 1982; Stoof and Kebabian, 1982; Stoof et al., 1992;
Tedford et al., 1992).
The anatomical locus of the D1-mediated stimulant effect on striatal
ACh neurotransmission in vivo is controversial. Evidence from some laboratories has pointed to a striatal location for these
receptors (Ajima et al., 1990; Anderson et al.,
1994; Consolo et al., 1992; Zocchi and Pert, 1993). In
contrast, others have failed to confirm a striatal location (Damsma
et al., 1991; De Boer et al., 1992; Johnson and
Bruno, 1993) and have suggested that D1 receptors in other brain
regions mediate these effects (Damsma et al., 1991; De Boer
and Abercrombie, 1994; De Boer et al., 1993).
The present experiments were undertaken to address further the question
of whether D1-mediated stimulation of striatal ACh release occurs by
actions at D1 receptors located within the striatum and to ascertain
whether the microdialysis conditions used to monitor striatal ACh
release can influence, either qualitatively or quantitatively, the
effects of dopaminergic drugs. To this end, we used the full DA D1
receptor agonist A-77636 (Kebabian et al., 1992), the
indirect dopaminergic agonist d-amphetamine and the two
dopamine D1 receptor antagonists SCH 23390 (Iorio et al.,
1983) and SCH 39166 (Chipkin et al., 1988). The first goal
was to study the effects of the local application of SCH 23390 and SCH
39166 on stimulated striatal ACh release produced by
systemic A-77636 or d-amphetamine. The second goal was to
test the hypothesis that striatal D1 receptors regulate
basal ACh release in this structure. This issue was
addressed by determining the effects of locally applied D1 receptor
agonists and antagonists on ACh release in the striatum. Finally, we
examined the extent to which differing dialysis conditions may have
contributed to earlier discrepant findings regarding the anatomical
locus of D1 receptors that regulate striatal ACh release.
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Materials and Methods |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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Animals. Male Wistar rats (275-300 g) were housed in groups of 2 to 3 per cage for at least 6 days before use and were maintained on a 12:00/12:00 h light/dark cycle (lights on at 7:30 A.M.) with food and water available ad libitum. After surgery the rats were housed individually in Plexiglas cages (35 × 35 × 25 cm) that also served as the experimental chamber, where they recovered for 36 to 48 h before the microdialysis procedure. Experiments were carried out between 9:00 A.M. and 4:00 P.M.
Surgery and microdialysis.
Rats were anesthetized with
sodium pentobarbital (60 mg/kg i.p.) and stereotaxically implanted with
a horizontal membrane passing through both striata (Imperato and Di
Chiara, 1985; Damsma et al., 1988). The coordinates,
measured from bregma, were AP = +1.5 mm, DV = 
4.75 mm
according to Paxinos and Watson (1986). The membrane used was a
polyacrylonitrile/sodium methallyl sulfonate copolymer
(I.D. 0.22 mm, O.D. 0.31 mm; cutoff 40,000 D, AN 69 filtral 8, Hospal
Industrie, France).
INLET) connected to a 2.5-ml glass syringe
containing the perfusion solution. The perfusion flow was set at 5 µl/min, except for one experiment where the flow rate was set at 2 µl/min.
The first three dialysate samples were discarded. Samples were
collected every 10 min (50 or 20 µl/sample) into a sample loop of an
HPLC injector valve electrically operated by a digital valve sequence
programmer (model C10W, VICI, Valco Instruments Co., Houston, TX)
connected to the rat by polyethylene tubing (volume 50 or 20 µl, I.D.
0.28 mmOUTLET). The perfusion solution contained 125 mM NaCl, 3 mM
KCl, 1.3 mM CaCl2, 1 mM MgCl2 and 23 mM
NaHCO3 in aqueous potassium phosphate buffer (1 mM, pH = 7.4). To achieve consistently detectable amounts of ACh in the
dialysate, the reversible AChE inhibitor neostigmine bromide (0.1 µM)
(Sigma, St. Louis, MO), or in one experiment physostigmine sulfate (7 µM) (RBI, Natick, MA), was added to the perfusion solution. ACh was
assayed by HPLC-ECD in conjunction with an enzyme reactor (Damsma
et al., 1988). In the experiments in which DA and its
metabolites DOPAC and HVA were measured, the composition of the
perfusion solution was as follows: 148 mM NaCl, 3 mM KCl, 1.3 mM
CaCl2 and 1 mM MgCl2 in aqueous potassium
phosphate buffer (1.5 mM, pH = 7.4). In these experiments, an AChE
inhibitor was not included in the perfusion solution.
ACh and choline were separated on a reverse-phase Chromspher
C18 5-µm (Merck, Darmstad, FRG) column (75 × 2.1 mm) pretreated with lauryl sulfate. The mobile phase passed directly
through the enzyme reactor (10 × 2.1 mm) containing AChE (ED
3.1.1.7; type VI-S, Sigma) and choline oxidase (EC1.1.3.17; Sigma)
covalently bound to glutaraldehyde-activated Lichrosorb
10-NH2 (Merck, Darmstad, FRG). ACh and choline were
quantitatively converted into hydrogen peroxide, which was detected
electrochemically at a platinum working electrode set at 500 mV
vs. an Ag/AgCl reference electrode (LC-4B, BAS, Lafayette,
IN). The mobile phase was an aqueous potassium phosphate buffer (1.9 mM
K2HPO4, 0.2 mM tetramethyl ammonium hydroxide, pH = 8) delivered at a constant flow of 0.4 ml/min by an HPLC pump
(Pharmacia LKB, HPLC pump 2150, Piscataway, NJ). The chromatograms were
recorded on a chart recorder. The detection limit of the assay was
about 50 fmol/sample. Injections of an ACh standard (20 µl, 0.1 µM)
were made every 60 to 90 min in order to monitor changes in electrode
sensitivity, and sample concentrations were corrected accordingly. DA,
DOPAC and HVA were assayed by HPLC-ECD. The mobile phase was delivered
by an HPLC pump (Pharmacia LKB, HPLC pump 2150, Piscataway, NJ) at the
constant flow of 1.25 ml/min and consisted of 0.1 M sodium acetate
adjusted to pH 4.1 with acetic acid, 0.5 mM octanesulfonic acid
(Eastman Kodak Co., NY) 0.01 mM disodium EDTA and methanol 12% v/v.
DA, DOPAC and HVA were separated by reverse-phase liquid chromatography
(150 × 4.6 mm, Nucleosil 5 µm ODS C18). The
electrochemical detector (Coulochem II, ESA Inc., Bedford, MA) was set
as follows: guard cell +400 mV; oxidation electrode +400 mV and
reduction electrode 300 mV. The chromatograms were recorded on a
chart recorder. The detection limit of the assay was approximately 5 fmol/injection for DA and DOPAC and approximately 20 fmol/injection for
HVA.
Drugs.
A-77636
[(1R,3S)3-(1
-adamantyl)-1-aminomethyl-3,4-dihydro-5,6-dihydroxy-1H-2-benzopyran
hydrochloride] was dissolved in distilled water and injected s.c. in a
volume of 0.1 ml/100 g at a dose of 4 µmol/kg (1.46 mg/kg). When
applied locally by reverse dialysis, A-77636 was dissolved in a small
amount of distilled water and then diluted in the perfusion solution
containing neostigmine bromide (0.1 µM) to 10 and 100 µM
concentrations. d-Amphetamine sulfate (Sigma, St.
Louis, MO), dissolved in water, was injected in a volume of 0.1 ml/100
g, and the dose of 5.42 µmol/kg (2 mg/kg) refers to the salt.
SCH 23390 [R-(+)-8-chloro-2,3,4,5-tetrahydro-3-methyl-5-phenyl-1H-3-benzazepine-7ol)-maleate] (Schering-Plough, Bloomfield, NJ) or SCH 39166 {()-trans-6,7,7a,8,9,13b-exahydro-3-chloro-2-hydroxy-N-methyl-5H-benzo-[d]-naphtho-[2,1b]-azepine hydrochloride} (Schering-Plough, Milan, Italy) was dissolved in distilled water and injected s.c. in a volume of 0.1 ml/100 g at a dose
of 0.74 µmol/kg (0.3 mg/kg) or 1.42 µmol/kg (0.5 mg/kg), respectively. When applied locally through the dialysis membrane, SCH
23390 or SCH 39166 was dissolved in water and then diluted to 12, 24, 50 or 60 µM in perfusion solution containing neostigmine bromide (0.1 µM) or physostigmine sulfate (7 µM).
Statistics. One-way and two-way ANOVA, with time as the repeated measure, were used to analyze the treatment effects. Reported F values refer to the main group effect of the experimental treatment. The effects of local perfusion with A-77636, SCH 23390 and SCH 39166 were analyzed by one-way analysis of variance with Greenhouse-Geisser corrections for repeated measures.
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Results |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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In vitro recovery of A-77636. In order to determine the extent to which A-77636 diffuses across the dialysis membrane, in vitro recovery of A-77636 was measured using UV spectroscopy. This experiment was conducted in triplicate, and recovery of A-77636 was 35% ± 3% from a 100 µM solution of A-77636 when the flow rate was 5 µl/min.
Basal ACh, DA and DA-metabolite output. Basal ACh and DA (fmol/min), DOPAC and HVA (pmol/min) were calculated and defined as the average ± S.E.M. of the six pretreatment samples for each experimental group. The overall mean ± S.E.M. base-line ACh in the dialysate was 94 ± 5 fmol/min (n = 69) in the 0.1 µM neostigmine condition. The overall mean ± S.E.M. base line was (n = 11) 29 ± 1 fmol/min for DA, 1.3 ± 0.05 pmol/min for DOPAC and 0.7 ± 0.04 pmol/min for HVA. For all of the group comparisons made below, there were no significant between-group differences in the base-line values of ACh.
Effects of SCH 39166 and SCH 23390 on A-77636-induced stimulation
of striatal ACh release.
At a dose of 4 µmol/kg, A-77636
produced long-lasting (>3 h) increases in striatal ACh release (fig.
1, top panel) [F(1,11) = 13.97; P < .004] compared with the vehicle group. The effect on ACh release was
accompanied by behavioral stimulation characterized by locomotor
activity and sniffing. The dose of A-77636 (4 µmol/kg) was selected
because it has previously been demonstrated to be maximally effective
on either neurochemical (Acquas et al., 1994) or behavioral
measures (Kebabian et al., 1992). Systemic
administration of SCH 23390 (0.74 µmol/kg) and that of SCH 39166 (1.42 µmol/kg) blocked the effects of A-77636 on ACh release
[F(1,9) = 12.27; P < .008] for SCH 23390 (fig. 1,
middle panel) and [F(1,10) = 14.66; P < .004] for
SCH 39166 (fig. 1, bottom panel). Systemic administration of SCH 23390 or SCH 39166 also blocked the behavioral stimulation produced by
A-77636 (not shown). In contrast, local application of SCH 23390 or SCH
39166 by reverse dialysis failed to influence the effects of A-77636.
Thus the maximal stimulation of striatal ACh release produced by
A-77636 in combination with local application of SCH 23390 (12 µM)
did not differ significantly from that produced by A-77636 alone (fig.
2, top panel) [F(1,10) = 0.42; N.S.].
Similarly, local application of SCH 39166 (50 µM) [F(1,11) = 0.62; N.S.] (fig. 2, bottom panel) did not
modify the effects of A-77636.
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Effects of systemic A-77636 on striatal DA release.
The
effects of systemic administration of A-77636 (4 µmol/kg s.c.) on the
release of DA, DOPAC and HVA are shown in figure 3.
A-77636 significantly reduced striatal DA output to about 70% of
baseline [FG-G(1.8, 7.2) = 33.32; P < .0001], and this effect lasted for more than 3 h. Striatal output
of DOPAC and HVA was also slightly reduced by A-77636, and these
effects were statistically significant for HVA
[FG-G(1.8, 7.2) = 6.8; P < .05] but not
for DOPAC [FG-G(1.2, 5.04) = 3.2; N.S.].
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Effect of locally applied A-77636 on extracellular concentrations
of ACh and DA.
Local perfusion with A-77636 (10 and 100 µM) did
not significantly influence ACh output [FG-G(3,
12) = 0.73; N.S.] (fig. 4, top panel). Similarly, local
application of A-77636 (10 and 100 µM) did not significantly
influence the output of DA [FG-G(2.8, 14) = 2.9; N.S.] and its metabolites DOPAC
[FG-G(2.6, 13) = 2.5; N.S.] and HVA
[FG-G(3.6, 18) = 0.6; N.S.] (fig. 4, bottom
panel).
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Effects of locally applied SCH 23390 and SCH 39166.
Figure
5 shows that SCH 23390 (12 µM) did not significantly
modify ACh output [FG-G(2.3, 9.3) = 3.5;
N.S.]. Surprisingly, higher concentrations of SCH 23390 (24 µM and
60 µM) stimulated striatal ACh release
[FG-G(2.7, 10.8) = 4.2; P < .05] and
[FG-G(2.7, 10.8) = 5.1; P < .05],
respectively. In contrast, application of the more selective D1
antagonist SCH 39166 (50 µM), by reverse dialysis (fig. 5), did not
significantly alter striatal ACh release [FG-G(1.8, 5.4) = 1.1; N.S.]. ANOVA revealed
that this effect was significantly different from that produced by SCH
23390 (60 µM), [F(1,7) = 6.04; P < .04]. In a
result consistent with previous reports (Imperato and Di Chiara, 1988;
Damsma et al., 1991), local application of SCH 23390 increased DA release in a concentration-dependent manner (not shown).
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Effect of local application of SCH 39166 on
d-amphetamine-induced stimulation of striatal ACh
release.
In agreement with previous reports (Damsma et
al., 1991; Consolo et al., 1992; Florin et
al., 1992), d-amphetamine sulfate significantly
increased interstitial concentrations of ACh compared to vehicle
injections [F(1,11) = 17.25; P < .003] (fig.
6, top panel). Local application of SCH 39166 (50 µM)
(fig. 6, bottom panel) failed to reduce
d-amphetamine-induced stimulation of striatal ACh release
[F(1,10) = 0.04; N.S.].
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Effects of high AChE inhibition and high Ca++
concentrations.
In an attempt to replicate results reported by
Consolo et al. (1992), we performed a series of experiments
in which the dialysis conditions were modified so as to be as similar
as possible to those used by these authors. The composition of the
perfusion solution was as follows: 147 mM NaCl, 4 mM KCl and 2.2 mM
CaCl2, dissolved in double distilled water. The AChE
inhibitor physostigmine sulfate (7 µM) was added to the perfusion
solution, and these experiments were carried out 1 day after surgery at
a perfusion flow rate of 2 µl/min. As shown in figure
7, SCH 23390 (24 µM) failed to influence ACh output
[FG-G(2.5, 12.6) = 1.2; N.S.]; however,
compared with the dialysis conditions used in the other experiments
reported here, basal ACh levels were greatly increased to 1229 ± 18 fmol/min (n = 6). Analysis of variance comparing the
effects of SCH 23390 in the presence of high [Ca++] and
high AChE inhibition (fig. 7) with those used in the other experiments
(fig. 5) indicated that there were no significant differences between
the effects of the D1 receptor antagonist under these two conditions
[F(1,9) = 1.26; N.S.].
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Discussion |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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The present data confirm and extend previous reports indicating
that systemically administered D1 receptor agonists increase ACh
release in the striatum (Damsma et al., 1990b; Damsma
et al., 1991; Imperato et al., 1994; Zocchi and
Pert, 1993). Thus the selective D1 agonist A-77636 produced robust and
long-lasting increases in ACh release that were readily blocked by
pretreatment with systemically administered D1 receptor antagonists SCH
23390 or SCH 39166 (fig. 1). Although these data indicate that
stimulation of D1 receptors enhances ACh release in the striatum, they
provide no information about the anatomical locus of these receptors. Given the large number of D1 receptors in the striatum (Mansour et al., 1991; Yung et al., 1995), a striatal
location might well be anticipated. However, the data reported here
provide no support for such an organization. Thus, when the same D1
receptor antagonists were applied locally in the striatum,
via reverse dialysis, the A-77636-induced increases in
striatal ACh release were not affected (fig. 2). Furthermore, when
A-77636 itself was delivered locally to the striatum via
reverse dialysis, ACh release was not affected (fig. 4). The failure of
locally delivered compounds to influence ACh release was not due to
subthreshold quantities passing across the dialysis membrane. In the
case of SCH 23390, it has been previously demonstrated that local
application (10 µM) via reverse dialysis increases
extracellular concentrations of DA (Damsma et al., 1991; Imperato and Di Chiara, 1988) but fails to affect interstitial concentrations of ACh (Damsma et al., 1991; De Boer et
al., 1992; Johnson and Bruno, 1993). It is evident, therefore,
that 12 µM SCH 23390 does produce significant neurochemical effects
in the vicinity of the dialysis probe and that the lack of effects on striatal ACh release cannot be attributed to the failure of sufficient quantities of the compound to reach the local environment outside the
membrane. Similarly, local application of the D1 agonist CY 208-243 (10 µM), though it fails to stimulate ACh release in the striatum (Damsma
et al., 1991), has been shown to increase Fos immunoreactivity in the vicinity of the probe in 6-OHDA-denervated striatum (Robertson et al., 1992). Finally, we have recently
observed that A-77636 (10 µM), when applied by reverse dialysis under
the same conditions utilized in the present experiments, significantly increases extracellular concentrations of cyclic AMP in the striatum (Acquas and Fibiger, unpublished observations). This confirms that the
concentration of A-77636 delivered locally to the striatum was
sufficient to elicit a neurochemical response.
Local perfusion with SCH 23390 (12 µM) or SCH 39166 (50 µM) did not
alter basal striatal ACh release, whereas SCH 23390 (24 and 60 µM)
had a stimulant effect. The latter may have been due to nonspecific
(i.e., non-D1 receptor-mediated) effects of SCH 23390, because this compound has weak antagonist actions at D2 receptors
(Dolezal et al., 1992; Plantje et al., 1984).
This finding stands in contrast to a previous report that local
perfusion of SCH 23390 (20 µM) reduces basal ACh release in the
striatum (Consolo et al., 1992). The microdialysis
conditions used by Consolo et al. (1992) differed
substantially from those used here (2.2 mM Ca++, no
Mg++, 7 µM physostigmine, 2 µl/min and 1 day
postsurgery vs. 1.2 mM Ca++, 1.0 mM
Mg++, 0.1 µM neostigmine, 5 µl/min and 2 days
postsurgery). Because some of these variables can influence the nature
of striatal ACh microdialysis results both qualitatively and
quantitatively (Damsma et al., 1990a; De Boer et
al., 1990), we attempted to replicate the results of Consolo
et al. (1992) using their microdialysis conditions. As is
evident in figure 7, in contrast to the results of Consolo et
al. (1992), SCH 23390 failed to decrease ACh release in the
striatum. At present we can offer no explanation for this failure to
replicate, even though a slightly higher concentration (20%) of the D1
antagonist was used. However, the data in figure 7 are consistent with
the results of the other experiments reported here and elsewhere: that
local manipulations of the D1 receptors in the striatum fail to
influence ACh release (Damsma et al., 1991; De Boer et
al., 1992).
Despite the discrepant findings with locally applied D1 receptor
antagonists, there is general agreement that systemically administered
D1 receptor antagonists block d-amphetamine-induced increases in striatal ACh release (Damsma et al., 1991; De
Boer and Abercrombie, 1996; Imperato et al., 1993). However,
the increases in striatal ACh release produced by
d-amphetamine do not appear to be mediated by D1 receptors
in the striatum, because local perfusion with the D1 antagonist SCH
39166 (50 µM) did not affect the d-amphetamine-induced
increases. This finding stands in sharp contrast to a report that local
perfusion of SCH 23390 (10 µM) blocks the stimulant effects of
systemic d-amphetamine (2 mg/kg) and cocaine (10 mg/kg) on
striatal ACh release (Consolo et al., 1992), and again the
reasons for this discrepancy are not apparent. It is possible that
differences in the microdialysis conditions contributed to these
divergent results; however, this seems unlikely in view of the fact
that, even when we used their dialysis conditions, we were unable to
confirm the claim of Consolo et al. (1992) that SCH 23390 reduces basal ACh release in the striatum (fig. 7).
The results of the present study are not compatible with suggestions
that D1 receptors in the striatum regulate ACh release in this
structure (Ajima et al., 1990; Anderson et al.,
1994; Consolo et al., 1992; Zocchi and Pert, 1993). However,
our findings do not clarify the reasons for discrepancies that surround
this issue. Among other variables, the concentration of the AChE
inhibitor in the perfusion solution can markedly influence the effects
of various DA agonists or antagonists on striatal ACh release (Acquas and Fibiger, 1995; De Boer and Abercrombie, 1996). It is noteworthy in
this regard that the studies in which locally applied D1 agonists apparently had effects on ACh release used high concentrations of AChE
inhibitors (Ajima et al., 1990; Anderson et al.,
1994; Consolo et al., 1992; Sato et al., 1994;
Zocchi and Pert, 1993) high, unphysiological concentrations of
Ca++ and an absence of Mg++ (Ajima et
al., 1990; Consolo et al., 1992; Sato et
al., 1994; Zocchi and Pert, 1993) in the perfusion fluid. Our
consistent inability to show any effects of locally applied D1 agonists
or antagonists on striatal ACh release, while at the same time showing highly consistent effects of these agents when given systemically, points to a nonstriatal location of the relevant D1 receptors. This is
supported by the observation that d-amphetamine-induced increases in striatal ACh release remain intact in animals with unilateral 6-hydroxydopamine lesions that abolish
d-amphetamine-induced increases in DA release in the
ipsilateral striatum (Herrera-Marschitz et al., 1994). These
results indicate that d-amphetamine-induced increases in
striatal ACh release that are mediated by D1 receptors (Damsma et
al., 1991) are not dependent on local increases in striatal DA
release. A nonstriatal location of the relevant D1 receptors is also
supported by many in vitro studies that have failed to
obtain evidence for D1-mediated regulation of cholinergic function in
striatal slice preparations (Dolezal et al., 1992; Login
et al., 1995; Scatton, 1982; Stoof and Kebabian, 1982; Stoof et al., 1992; Tedford et al., 1992). The location
of the D1 receptors that regulate striatal ACh release therefore
remains to be determined. Preliminary evidence suggests that the
substantia nigra is one site at which such regulation may occur (De
Boer and Abercrombie, 1994).
It is noteworthy that systemic administration of A-77636 decreased
striatal DA release (fig. 3). This finding raises the possibility that
systemic A-77636, by decreasing DA release in the striatum, stimulates
ACh release at least in part by reducing inhibitory D2-mediated effects
of endogenous DA on cholinergic neurons. According to this formulation,
the failure of locally delivered A-77636 to influence striatal ACh
release is consistent with its lack of effect on DA when applied in
this manner (fig. 4). Finally, the fact that systemically applied, but
not locally applied, A-77636 decreased striatal DA output suggests that
D1 receptors outside the striatum mediate this effect. Although the
location of these receptors is not known, one possibility is that
activation of D1 receptors in the substantia nigra pars reticulata
increases GABA-mediated inhibition of nigral DA neurons (Timmerman and
Abercrombie, 1996).
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Acknowledgments |
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The authors thank Dr. R. A. Wall for the analyses of in vitro recovery of A-77636. A-77636 was kindly donated by Abbott Laboratories, Abbott Park, IL.
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Footnotes |
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Accepted for publication December 9, 1996.
Received for publication March 1, 1996.
1 Supported by a Group Grant from the Medical Research Council of Canada.
2 E. Acquas was supported by a fellowship from the Human Frontiers Science Program Organization. Current address: Department of Toxicology, University of Cagliari, V.le A. Diaz, 182, 09126-Cagliari, Italy.
Send reprint requests to: Dr. H. C. Fibiger, Division of Neurological Sciences, Department of Psychiatry, University of British Columbia, 2255 Wesbrook Mall, Vancouver, B.C. V6T 1Z3 Canada.
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Abbreviations |
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ANOVA, analysis of variance; DA, dopamine; HPLC-ECD, high-performance liquid chromatography with electrochemical detection; DOPAC, 3-4-dihydroxyphenylacetic acid; HVA, homovanillic acid.
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References |
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Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References
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) and of vehicle injections
(n = 6, 
) on striatal ACh release. Middle and bottom
panels: Effects of SCH 23390 (0.74 µmol/kg s.c.) (n = 4, middle panel) and SCH 39166 (1.42 µmol/kg s.c.) (n = 5, bottom panel) administered 30 min before A-77636 (4 µmol/kg
s.c.) on striatal ACh release. Values are expressed as percent of
baseline. Vertical bars represent S.E.M. Arrows indicate the first
postdrug treatment sample.
) and HVA (
) output
(n = 5). Values are expressed as percent of baseline.
Vertical bars represent S.E.M. Arrows indicate the first postdrug
treatment sample.
