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Modulatory role of dopamine on excitatory amino acid receptors
Pmg. NeumPsycho~-
&Bid.
Psych&t Cowaght
1996, Vol. 20. pp. 659-671 8 1996 E1sevte.r 6dence
PIintedIntheush
0276~5646/96
ELSEVIER
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Aurtghts$32.00
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MODUTGRY
ROLE OF DOPAMINE ON EXCITATORY AMINO ACID RECEPTORS
OTTAVIO
GANDOLFI
and ROSSELLA
DALL’OLIO
Department of Pharmacology, University of Bologna, Italy
(Final form, February 1996)
Gandolfi Ottavio and Rossella Dall’Olio: Modulatory role of dopamine on excitatory amino acid receptors. F’rog.Neuro-Psychopharmacol. & Biol Psychiat. 1996 20, pp. 659-671 1. In extensively washed synaptic membrane preparations from rat prefrontal cortex, the “in vitro” addition of either the Dl (SKF 38393) or the D2 (LY 171555) specific agonists markedly decreased the apparent affinity of the NMDA receptor antagonist [3H]-MK801 specific binding. In the same membrane preparation, the concentration of L-glutamate required to produce half maximal enhancement of [3H]-MK801 binding was approximately the same both in the presence or in the absence of dopaminergic drugs. 2. I.c.v. administration of the neurotoxin 6-OHDA resulted in a dramatic reduction of dopamine (DA) prefrontal cortex levels, whilst repeated administrations (21 consecutive days) with either the Dl (SCH 23390) or the D2 (YM 09151-2) selective antagonist failed to change DA and DOPAC contents. 3. Repeated administrations with the Dl receptor blocker SCH 23390 selectively increased the Bmax values of [3H]-SCH 23390 binding while [3H]-spiroperidol binding was increased both by repeated administrations of YM 09151-2 and by i.c.v. injection of 6-OHDA. 4. Although both chronic D2 blockade and 6-OHDA lesions consistentely increased D2 receptor number, in extensively washed synaptic plasma membranes (SPM) of rats repeatedly administered with YM 09151-2 but not with 6-OHDA, the [3H]-MK801 binding was increased. 5. It is concluded that the effects of NMDA receptor activation could not be directely mediated by stimulation of DA release, but are highly dependent upon the presence of DA axon terminals. Kevwor&: catecholamines content, N-methyl-D-aspartate, administrations, specific dopamine receptors.
neurotoxic
lesion,
rats, repeated
. . Ddopamine (DA), 3,4-dihydroxyphenylacetic acid (DOPAC), excitatory amino acid (EAA), beta,gamma-imidoguanosine-5’-tryphosphate (Gpp(NH),), N-methyl-D-aspartate (NMDA), 6-hydroxydopamine (COHDA), synaphic plasma membrane (SPM).
Recently, the full comprehension of the molecular mechanisms underlying the interactions between dopamine (DA) and excitatory amino acidis (EAA) represents a scientific and clinical goal 659
660
0.
Gandolft and R Dall’Olio
since abnormalities in these neurotransmitter actions have been implicated in the clinical symptoms of Parkinson disease and schizophrenia (Carlsson and Carlsson, 1990, Deutch et al., 1989; Kim et al., 1980). Several biochemical studies focused on the modulatory effects of NMDA-sensitive glutamate receptors on DA release in tissue slices (Asencio et al., 1991; Bowyer et al., 1992; Dwoskin et al., 1992; Jhmandas and Marien, 1987; Marien et al., 1983; Ohmori et al., 1992; Roberts and Sharif, 1978; Roberts and Anderson, 1979; Snell and Johnson, 1986) and in dissociated cell cultures of rat mesencephalon (Mount et al., 1990). Extra-cellular levels of DA evaluated by microdyalisis studies did not generate univocal results: intrastriatal infusions with NMDA increased (Muck et al., 1992; Morari et al., 1993) or did not modify (Imperato et al., 1990) extra-cellular DA levels, and in our laboratory, D-cycloserine (3 mg/kg i.p.), a partial agonist of the strichnine-insensitive
glycine recognition site failed to change
either DA and DOPAC extra-cellular output twenty-four hours after the implantation
of the
transstriatal probe in freely moving rat striatal dialysates (Gandolfi et al., 1994). Electrophysiologic studies obtained with quantitative single-unit recording, show that in rat the NMDA uncompetitive receptor antagonist MK801 produces dose-dependent increases both in the burst firing of ventral tegmental Ato DA neurons and in dopaminergic tone within mesolimbicmesocortical regions (French et al., 1993). Behavioral studies in rodents show that MK801 antagonizes dopamine D2 receptor mediated catalepsy induced by different DA receptor antagonists (Papa et al., 1993; Schmidt et al., 1991) activates dopaminergic transmission (Hiramatsu et al., 1989; Liljequist et al., 1991; Rao et al., 1990) and induces hypermotility either in rats (Dall’Olio et al., 1995) or in monoamine-depleted mice (Carlsson and Carlsson, 1989). In this bulk of evidences, that not always generated consistent results, the authors planned biochemical experiments to evaluate the modulation of NMDA-sensitive glutamate receptors in two different experimental conditions: i) prolonged Dt or D2 receptor blockade-induced receptor super-sensitivity, and ii) DA receptor supersensitivity following specific neurotoxin (6-OHDA) lesions. The authors followed such dual approach in the light of strengthening
information
that
comparing the two experimental models, rats withdrawn from repeated treatments with DA blockers show the same degree of D2 receptor supersensitivity as rats lesioned with 6-OHDA which distroys most of DA axon terminals. The authors planned “ex vivo” [3H]- MK801 radiolingand binding studies, serving as an index of functional activation of NMDA receptors (Loo et al. 1986, Fagg 1987, Foster and Wong 1987), in well washed synaptic plasma membrane preparation (SPM) from the prefrontal cortex of tats either repeatedly treated with Dt/D2 blockers or in 6-OHDA lesioned animals. Other [3H]-MK801 radiolingad binding experiments after the “in vitro” addition of different DA agonists, or drugs acting at the G-protein level (Gpp(NH)p) were undertaken to evaluate whether DA-ergic drugs, at least in this simplified system could interfere by simply direct interaction with NMDA-sensitive glutamate receptor complex.
DA-NMDA
661
Interaction in CNS
Male Sprague Dawley rats (150-175 g, Charles River Italia SpA, Como, Italy) were housed in groups of four under controlled conditions of light (07:OOa.m. - 07:OO p.m.), temperature (22 rt 2’C) and humidity (65%) and were allowed free access to standard laboratory diet and tap water. Experimental protocols were approved by a local bioethical committee while the procedures and the animal confort were controlled by the University Veterinary Service.
[3H]-MK801 (15 Ci/mmol), [3H]-SCH 23390 (70 Ci/mmol) and [3H]-spiroperidol (15 Ci/mmol) were obtained from NEN, Boston, MA, USA. (+)-Butaclamol HCl, (+)-SCH 23390 ((R)-(+)-8chloro-2,3,4,5-tetrahydro-3-methyl-5-phenyl-lH-3-benzazepine-7-maleate),
MK801 (dizocilpine)
and SKP 38393 (2,3,4,5-tetrahydro-7,8-dihydroxy-l-phenyl-lH-benzazepine)
were from RBI,
Natick, MA, USA. YM 09151-2 (Cis-N-(benzyl-2-metylpyrrolidin-3-yl)-5-chloro-2-methoxy-4methylamino-benzamide)
from Yamanouchi,
Tokyo, Japan. LY 171555 (Trans-(-)-4a-R-4-
,4a,5,6,7,8,8a,9-octahydro-5-propyl-2H-pyrazolo-(3,4)-quinoline Indianapolis,
IN, USA. G,(NH),
dihydroxy-phenyl-ethyl-amine),
HCl),
(beta, gamma-imidoguanosine-5, DOPAC
(3,4dihydroxyphenylacetic
from
Eli
Lilly
Co.,
triphosphate), DA (3,4acid),
6-OHDA
(6-
hydroxydopamine), (-)-sulpiride, L-glutamate and haloperidol, were from Sigma, St.Louis, MO, USA. ed
Drup Treatme-
Group of animals (n= I/group) received daily injections for 21 consecutive days of the following pharmacological treatments: the Dl dopamine receptor blocker SCH 23390 (0.05 mg/kg S.C.twice daily), the Dz specific antagonist YM 09151-2 (0.02 mg/kg i.p.), the “atypic neuroleptic” (-)sulpiride (20 mg/kg i.p.), haloperidol (0.125 mg/kg i.p.), or saline. Three days after the withdrawal of 21-day repeated administrations when behavioral supersensitivity to a subthreshold dose of apomorphine was observed (Dall’Olio et al., 1990) rats were killed by decapitation, the brains removed, rinsed in ice-cold isotonic saline, and frontal cortices dissected over ice were stored at -80°C until assays. $-HvdrQ.g&pamme (6-OHDA) - Lesiom
Groups of rats (n= lo/group) were anesthetized with pentobarbital. Lesions were produced by injecting 6-OHDA (200 pg) stereotaxically in the lateral ventricle. Sham-lesioned animals were given i.c.v. injections of the vehicle solution, 0.01% (wt/vol) ascorbic acid in saline. Animals of both groups were injected intraperitoneally with desmethylimipramine
(25 mg/kg) 40 minutes
before the injection of neurotoxin (or vehicle) to prevent the uptake of the neurotoxin into noradrenergic axons and thus minimize the degeneration of these terminals. Lesioned and shamlesioned rats were killed by decapitation 24 days after surgery, the brains were removed and prefrontal cortices dissected over ice were stored at -80°C until assays.
662
0. GandoIfi and R. Dall’Olio
.
.
Dopamine (DA) and Dihydroxvahenvlacehc acrd (DOPAC) Determinatiotg The concentrations and Salama
of DA and DOPAC in rat frontal cortices were measured according
(1984) using high-performance-liquid
detector (HPLC-ED). homogenates
centrifuged
the HPLC-ED
system. The mobile-phase
(pH 4.0-4.3) consisted
0.1 mM ethylendiamine
were carried out with minor modifications
buffer pH 7.4, the homogenates
resuspended,
and the homogenates
pellets were resuspended
together with different spiroperidol
according
were centrifuged
receptor
to Billard et al. (1984) and
with Polytron in ice-cold 50 mM
(30,000 x g, 10 min), pellets were
in 50 mM Tris-HCl buffer containing of membrane
concentrations
120 mM NaCl, 5 mM KCl, 2 mM
suspensions
were incubated
(30 min, 37°C)
of [3H]-SCH 23390 (ranging from 0.25 to 6 nM) or [3H]-
through Watman GF/C filters. The specific
between
the total binding
and the binding
were determined
in the presence
respectively
under by the
of a specific
for [3H]-SCH 23390 and
binding.
The [3H]-MK801
binding assays were carried out according to Stirling et al. (1989). Prefrontal
were homogenized
homogenizer.
bindings
remaining
1 pM cold SCH 23390 or 1 pM (+)-butaclamol
[3H]-spiroperidol
cortices
to Dl and D2 dopamine
(ranging from 0.02 to 0.5 nM). The reaction was stopped by rapid filtration
pressure
displacer,
column (C-
were pelleted twice in the same buffer. The final membrane
CaC12 and 1 mM MgC12. Aliquots
difference
on a reverse-phase
detector (Waters M-460) was operated at +0.65 mV.
and Langer (1978). Briefly, cortices were homogenized
negative
to
Bindin-
respectively,
Tris-HCl
acid, the
were applied diictely
of 70 mM NaI-IzPOd, 0.65 mM
The binding assays for [3H]-SCH 23390 and [3H]-spiroperidol
Briley
to electrochemical
tetracetic acid (EDTA), 0.035 M citric acid and
Separation of DA and DOPAC was accomplished
18; 25 cm) and the electrochemical &g&&and
coupled
in 0.1 M perchloric
and samples (20 pl) of the resulting supematant
sodium octyl sulphate, 35% acetonitrile.
chromatography
Briefly, prefrontal cortices were homogenized
to Saller
The
in 10 vol ice-cold 0.32 M sucrose using a motor-driven
homogenate
sucrose, and centrifuged
again. The supematants
pellets. These were resuspended pellets were resuspended
was centrifuged
glass-teflon
at 1,000 x g, the pellet resuspended were pooled, centrifuged
in 0.32 M
at 45,000 x g to yield P2
in 20 vol 5 mM Tris-HCl pH 7.7 at 4°C and centrifuged.
in ice-cold distilled water and centrifuged.
This procedure
The
was repeated
three times and the pellets were frozen at -80°C for at least 18 hours. On the day of the assay pellets were thawed, centrifuged Tris-HCl
suspended
in 20 volumes
of 5 mM Tris-HCl
pH 7.7 at 4”C, homogenized
at 30,000 x g. This wash step was repeated four more times in 100 volumes buffer and the final suspension
was incubated at room temperature
centrifugation
at 30,000 x g. The final pellets were resuspended
concentration
of 0.8-l mg/ml. Aliquots of synaptic plasma membranes
prefrontal
cornices
were incubated with different concentrations
to 100 nM). In some experiments,
membranes
concentrations
5 mM
for 20 min prior to
in the same buffer to give a protein @PM) prepared
from the
of [3H]-MK801
(ranging from 2
were incubated with [3H]-MK801
(25 nM) and Dl
agonist SKF 38393, the D2 agonist LY 171555 (both 100 pM) either in the presence absence of different
and
of L-glutamate
or in the
(ranging from lo-lo to 10” M). In different
DA-NMDA Interaction in CNS
663
series of experiments, [3H]-MK801 (25 nM) specific binding was run in the presence of the non hydrolizable GTP analogue G&NH&
(100 pM) to activate the G-protein coupler of adenylate
cyclase system. The specific binding was determined between the total binding and the binding left in the presence of 1 uM cold MK801. After incubation for 2 hr at 25°C (equilibrium), the mixture was rapidly filtered through Watman GF/C filters presoaked in 0.05% polyethyleneimine radioactivity remaining on the filters was counted by liquid scintillation
and the
spectrometry using
Atomlight (NEN, Boston, MA, USA). The kinetic characteristics of the specific binding were analyzed according to the method of Scatchard (1949) using the program of Munson and Rodbard (1980). Proteins were measured using BSA as standard according to Lowry et al. (1951). Data a42.lM
Radioligand binding data were analysed by Students t test, and the concentrations of DA and DOPAC
were analysed by means of ANOVA followed by single comparisons of the means.
In extensively washed SPM from rat frontal cortex, [3H]-MK801 labeled a single population of sites (Bmax = 6.92 f 0.67 pmol/mg prot) with good affinity (Kd = 19.5 f 2.1 nM). The “in vitro” addition of either the Dl receptor agonist SKF 38393 or the D2 agent LY 171555 (both 100 JIM) markedly decreased the affinity of [3H]-MK801 binding (Table 1) while failed to change the maximum number of binding sites. Lower DI or D2 agonists concentrations did not show any statistically different changes in the kinetic characteristics of [3H]-MK801 specific binding (data not shown). Table 1
Influence of DI and D2 DA Agonists “in vitro” Addition, on the Kinetic Characteristics of [3H]MK801 Specific Binding to Extensively Washed Rat Prefrontal Cortex Membranes. Bmax (pmol/mg prot) 6.9240.67
Control SKF 38393
100 FM
5.86M.51
( LY 171555
100 PM
6.15k0.49
Kd (nM) 19.5dz2.1 47.6&3.6*
38.4+2.7* [3H]-MK801 binding was performed either in the absence of any drug (control) and in the presence of 100 pM SKF 38393 or 100 pM LY 171555. Mean values f SEM are reported. The apparent Kd values following the “in vitro” addition of either agonists were significantly different (*p c.05 Student r-lest) from those obtained in control.
In
the same preparation, [3H]-MK801 (25 nM) specific binding has been enhanced by the
addition of L-glutamate (10-a - 1O-4M). Figure 1 shows that in the presence of maximally active concentration of L-glutamate (10m4M) the [3HJ-MK801 specific binding was increased by about
664
0. Gandolfi
and R Dall’Olio
300%. The interactions of the D2 agent LY 171555 with [3H]-MK801 binding sites were of uncompetitive nature; increasing concentrations of L-glutamate did not alter the inhibitory effect of the DA-ergic agent on [3H]-MK801 binding in extensively washed SPM prepared from rat prefrontal cortex. The concentration of L-glutamate required to produce half maximal enhancement of [3H]-MK801 binding was approximately the same both in the presence (EC50 = 0.9 pM) or in the absence (EC50 = 0.7 pM) of LY 171555.
. :: 0-1 0
/
-a
I
-7
-6
L-Glutamate
-5
-4
-3
[M]
Fig 1. Basal [3H]-MK801 specific bindings (25 nM) in the absence (*) and in the presence (0) of LY 171555 (100 @I) were 2.4 f 0.18 (SEM) and 1.2 f 0.08 @EM) pmol/mg prot respectively. Specific binding was over 70% of total binding in basal conditions and was greater than 80% of total binding under conditions of maximal stimulation. Comparable results have been obtained in at least three separate experiments.
The ability of the G-protein non-hydrolysable activator G,(NH),
(10e4 M) to modulate the [3H]-
MK801 (25 nM) specific binding to SPM preparations is shown in Table 2. The “in vitro” addition of the stimulating G protein nucleotide inhibited by more than 50% [3H]-MK801 specific binding. Maximally active concentrations of L-glutamate, although dramatically increasing [3H]-MK801 binding were unable to reverse guanine nucleotide-induced inhibition. Table 2. Inhibition of ]3H]-MK801 (25 nM) Specific Binding by the Non Hydrolizable GTP Analogue to Extensively Washed SPM prepared from Rat Prefrontal Cortex
Basal G,(NH), (to(J@0 Resultsare expressedas mean f SEM
[3H]-MK 801 specific binding (25 nM) (pmol/mg pro0 -L-Glut. + 100 pM L-Glut. 8.=.6* 2.5M. 18 3.4k0.2* l.kbO.07
values from at least three experiments each performed in triplicate. *p 1.05 (Student r-test) when compared to the respective basal value.
DA-NMDA
.
Interaction in CNS
665
.
Neurotomc Lesron and Repeated Drue Administrations
Table 3 shows that the i.c.v. injection of neurotoxin 6-OHDA resulted in a dramatic reduction of DA and DOPAC levels in rat prefrontal cortex. Consistent decreases (70-80%) of [3HJ-DA uptake by cortical synaptosomes (not shown) used as a further index of the degree of neurotoxic lesion were found. In contrast, consistently with Finlay et al. (1987) and Essig and Kilpatrick (1991) DA and DOPAC cortical levels were not modified by repeated administrations of Dl or D2 blockers. Consistenly with previous results (Cmese and Chen 1985, Gandolfi et al. 1988, Duncan et al. 1993, Giorgi et al. 1993), Scatchard analysis of the saturation data of [3H]-SCH 23390 and [3H]spiroperidol bindings to SPM prepared from repeatedly treated rats showed that the D, blocker increased (about 30%) the number but not the apparent affinity values of Dl binding sites labelled by [3H]-SCH 23390. The same repeated treatment with the Dt receptor blocker failed to modify the kinetic characteristics of [3H]spiroperidol specific binding to SPM. The kinetic characteristics of [3H]-Spiroperidol binding to SPM of rats repeatedly administered with YM 09151-2 revealed large increases in Bmax values (about 48%) while Dl receptors were unaffected. Table 3 shows also that in SPM prepared from the 6-OHDA lesioned rats there is a statistically significant increase (about 40%) in the maximum number (Bmax) of [3H]-spiroperidol specific binding, while the kinetic characteristics of [3H]-SCH 23390 binding to Dl receptors did not change. Table 3 Effects of 6-OHDA or Repeated Administrations with Either Dl and D2 Dopamine Receptor Blockers on DA and DOPAC Cortical Levels and on the Kinetic Characteristics of DI and D2 Receptors in SPM. DA (pmol/w) Non-lesioned 6-OHDA
62W2 4w*
DGPAC (pmdmg) 72k3 g&0.8*
[3H]-SCH 23390
[ 3HI-spiroperidol Bmax(fmol/mg) Kd(nM)
Kd(nM)
Billax (fmol/mg)
0.9fo.03
396+17
0.16M.01
1lm.6
1.2M.05
42W3 1
0.15~.01
16W.l*
SCH 23390
596&68
68f5
l.lXl.04
53X27**
0.17+0 - .01
103*4.1
YM 09151-2
65 lzh66
83s
0.8M.04
352&20
0.21fl.03
177&9**
DA and DOPAC levels, like c3H]-SCH 23390and [3Hj-spiroperidol specific bindings were determined following a 72 hr washout period from rats repeatedly treated (21 days) with SCH23390 (0.05 mg/kg i.p. twice daily) or with YM 09151-2 (0.02 mg/kg i.p.) or 24 days following 6-OHDA (200 pg i.c.v.) administration. *~.05 when compared to sham-lesioned rats **~.05 significantly different from repeatedly saline-treated rats
Figure 2 shows the normalized data transformed to % control of [3H]-MK801 specific binding to extensively washed SPM. Statistically significant increase of [3H]-MK801 binding was found only following repeated administrations of either YM 09151-2 (3389 f 174 fmol/mg Vs 2394f 102 fmol/mg pc.05 Student’s t test) or haloperidol (3009 f 178 fmol/mg p<.O2 Student’s t test). Repeated administrations either of SCH 23390 or the atypic neuroleptic (-) sulpiride failed to change [3H]-MK801 specific binding (pannel B).
666
0. GandolB
Although
in SPM of either repeatedly
there are consistent prepared
increases
from DA depleted
and R. DaU’Olfo
YM 09151-2 treated rats or 60HDA-lesioned
of D2receptor
binding (Table 3), in prefrontal
rats no changes in [3H]-MK801
Moreover in the same membrane preparation
binding were observed
from DA-depleted
animals
cortex membranes (Pannel A).
animals the “in vitro”, addition of
high doses of DA (10 PM) failed to modify [3H]-MK801 specific binding.
A
l3
0
control
@j
6-OHDA
c]
control
•j
SCH
23390
YM
09151-2
i.c.v.
q 6-DHDA
+
DA
=I-sulp
@halo
10“H 100
/
-
0
-_ i ** *
Fig 2. [3Hj-MK801
specific binding (25 nM) to extensively-washed SPM prepared from rat prefrontal cortex was performed as described in “Radiolingand Binding Studies”. Animals were killed either 72 hr following repeated (21 days) administration of SCH 23390 (0.05 mg/kg i.p. twice daily), (-)-sulpiride (2Omg/kg i.p.), YM 09151-2 (0.02 mg/kg i.p.), haloperidol (0.125 mg/kg i.p.) or saline (Part B), or 24 days following 6-GHDA (200 pg i.c.v.) (Part A). The results are expressed as % change of control [3H]-MK801 specific binding. Non transformed data were: control=2394 f102 fmol/mg; YMO9151-2=3389+174 fmol/mg; haloperidol =3OfI9*178 fmobmg. Bach value represents the means of at least three experiments done in triplicate. SEM were less than 10%. *p<.O5 (Student’s ttest) when compared to control. **p<.O2 (Student’s t-test) when compared to control.
In this study, the L-glutamate the general hypothesis
enhancement
that the non-competitive
activated state of the NMDA receptor-cation serving as an index of functional Loo et al. (McDonald
1986).
induced
enhancements different
This
et al. 1987)
linked ion channel binding
of [3H]-MK801 binding gives supportive evidence to
receptor,
by repeated
antagonist
MK801 binds to an
(Wong et al., 1986) and therefore
activation of the receptor (Fagg, 1987; Foster and Wong, 1987;
interpretation, that MK
NMDA receptor
channel complex
taken
together
with
electro-physiological
evidencies
801 is an open channel blocker that binds within the NMDA-
allows us to assume that at equilibrium administrations
increases
with YM 09151-2 or haloperidol
of [3H]-MK801 are indicative
of
in NMDA receptor function. These results agree with other data obtained both with
ligands ([3H]-TCP)
or with quantitative
autoradiography
techniques
NMDA receptor function following repeated haloperidol or eticlopride
showing
administrations
increased (Byrd et al.
1987; Ulas et al., 1994) but are at variance with others (Creese et al. 1994; Lang et al. 1992).
DA-NMDA Interaction in CNS
Different
techniques
(autoradiography
vs radioreceptor binding
667
studies), labels, membrane
preparation procedures, doses, times and washout periods could be responsible for this apparent discrepancy. Interuretation of “ex vivo” Radioliand
Bindi@&&
The present data show that in rat prefrontal cortex, a cerebral area having one of the highest concentrations of DA-ergic nerve fibers, there is an enhancement of [3H]-MK801 binding only in SPM prepared from D2 supersensitive rats following D2 receptor blockade. In 6-OHDA-lesioned animals where DA axon terminals are almost completely absent, the increase in D2 receptor number did not parallel the increase [3H]-MK801 specific binding. It is unlike that the DA paucity following 6-OHDA lesion (about 10%) is insufficient to activate D2 receptors and to increase [3H]MK801 specific binding, since the “in vitro” addition of DA-ergic drugs (10-S M) in SPM of shamlesioned rats decreased [3H]-MK801 binding, while in synaptic membranes of rats lesioned with 6OHDA DA failed to affect [3H]-MK801 binding. Intremetation qf “in vitro” Radio&gmd Bind& &&Q
The D2 agent LY 171555 produced similar inhibitions of [3H]-MK801 specific binding either in the absence or in the presence of different concentrations of L-glutamate, theoretically suggesting that the interactions between NMDA and DA receptors, non mediated via the NMDA recognition site, could be of uncompetitive nature. In contrast to our “ex vivo” results showing [3H]-MK801 binding increases in rats repeatedly administered with D2 blockers, the “in vitro” addition of high (but not low) doses of DA-ergic agents decreases affinity (Kd values increases) of [3H]-MK801 specific binding in well washed SPM of untreated animals suggesting that, at least in this system, DA-ergic drugs could modify glutamatergic function. This effect however was not abserved when DA was added in SPM prepared from 6-OHDA lesioned rats. To verify whether the failure of DAergic drugs to modify [3H]-MK801 binding in 6-OHDA lesioned rats could be due to the uncoupling of DA receptors with the G protein following the lesion, the authors performed “in vitro” [3H]-MK801 binding studies after activation of G protein by the non-hydrolizable analogue G,,(NH),.
GTP
Our results indicated that the inhibiting effet of this drug on [3H]-MK801
binding is unrelated to a direct effect of guanine nucleotides on the NMDA-glutamate recognition site since the inhibition of [3H]-MK801 binding failed to change after the addition of 10-d M Lglutamate. Other studies (Baron et al. 1989) that showed that guanine nucleotides reduced both antagonists ([3H]-CPP) and agonist ([3H]-glutamate) binding sites are inconsistent with all we know about GTP-binding protein-linked receptors where guanine nucleotides selectively decrease agonist but not antagonist
binding sites by converting high affinity to low affinity sites
(Sokolovsky et al. 1980) and suggest that the inhibition of [3H]-MK801 binding could not be related to the activation of GTP binding proteins. All these data taken together suggest that the DA-elicited modulation of NMDA receptors could not be simply a function of DA release from nerve terminals at this site. Endogenous DA, via presynaptic action on supersensitive receptors, through asso-assonic interaction could modulate glutamate or another substance (peptide) release from a DA-controlled neuron that appears to play
668
0.
Gandolfi and R Dall’Olio
an important role in modulating the NMDA receptor function. However, when DA neurons are absent, the lack of DA-ergic terminals could not induce the DA-controlled (glutamate ?) neuron to activate and therefore to increase [3H]-MK801 specific binding.
All these results taken together with other data showing the incapacity of MK801 and other glutamatergic drugs (cycloserine) to modulate extracellular levels of DA (Gandolfi et al. 1992, 1994) indicate that the effects of NMDA receptor activation could not be directely mediated by stimulation of DA release, however this response is highly dependent upon the presence of DA axon terminals, subserving therefore the complex modulatory role of dopamine in EAA receptor activation. The present results rather suggest trans-synaptic mechanisms, and do not allow to assume a direct or a G-protein mediated control of DA-ergic agonists on NMDA receptor function. The exact mechanisms of this interaction is still obscure; electrophysiological
studies utilizing
membrane patch techniques could represent the most suitable approach to examine the regulation of NMDA responses in both experimental conditions of Dz-receptor supersensitivity.
The present work was supported by Grants of Italian Ministry for University. The authors thank Mr. R. Laghetti and Mrs. C. Cappelletti for typing the manuscript.
ASENCIO H., BUSTOS G., GYSLING K. and LABARCA R. (1991) N-methyl-D-aspartate receptors and release of newly synthesized [3H]-dopamine in nucleus accumbens slices and its relationship with neocortical afferences. Prog. Neuropsychopharmacol. Biol. Psychiatry fi, 663676.
BARON B.M., DUDLEY M.W., MCCARTY D.R., MILLER F.P., REYNOLDS J. and SCHMIDT C.J. (1989) Guanine nucleotides are competitive inhibitors of N-methyl-D-aspartate at its receptor site both in vitro and in vivo. J. Pharmacol. Exp. Ther. a, 162-169. BILLARD W., RUPERTO V., GROSBY G., IORIO L.C. and BARNETT A. (1984) Characterization of the binding of [3H]-SCH 23390, a selective Dl receptor antagonist ligand, in rat striatum. Life Sci. & 18851893. BOWYER J.F., NEWPORT G.D., LIPE G.W. and FRAME L.T. (1992) A further evaluation of the effects of K+ depolarization on glutamate-evoked [3H]-dopamine release from striatal slices. J. Pharmacol. Exp. Ther. U,72-80.
BRILEY M. and LANGER S.Z. (1978) Two binding sites for 3H-Spiroperidol on rat striatal membranes. Eur. J. Pharmacol. a, 283-284. BYRD J.C., BYKOV V. and ROTHMAN R. (1987) Chronic haloperidol treatment up-regulates rat brain PCP receptors. Eur. J. Pharmacoi. j,& 121-122. CARLSSON M. and CARLSSON A. (1989) The NMDA antagonist MK 801 causes marked locomotor stimulation in monoamine-depleted mice. J. Neural Transm. z, 221-226. CARLSSON M. and CARLSSON A. (1990) Interaction between glutamatergic and monoaminergic system within the basal ganglia - implications for schizophrenia and Parkinson’s disease. Trends Neurosci. u, 272-276.
DA-NMDA
Interaction in CNS
669
CREESE I. and CHEN A. (1985) Selective D1 dopamine receptor increase following chronic treatment with SCH 23390. Eur. J. Pharmacul. m, 127-128.
CREESE I., TARAZI F.I. and FLORIJN W.J. (1994) Regulation of glutamate receptor binding following chronic neuroleptic treatment. Sot. Neurosci. Abs.a. DALL’OLIO R., GANDOLFI O., RONCADA P., VACCHERI A. and MONTANARO N. (1990) Repeated treatment with (-)-Sulpiride plus a low dose of SCH 23390 displays wider neuroleptic activity without inducing dopaminergic supersensitivity. Psychopharmacology m, 560-562. DALL’OLIO R., RIMONDINI R. and GANDOLFI 0. (1995) The competitive NMDA antagonists CGP 43487 and APV potentiate dopaminergic function. Psychopharmacology us, 3 1O-315. DEUTSCH S.I., MASTROPAOLO J., SCHWARTZ B.L., ROSSE R.N. and MORIHISA J.M.A. (1989) “A glutamatergic hypothesis” of schizophrenia. Clin. Neurophannacol. 12, I- 13. DUNCAN G.E., BREESE G.R., CRISWELL H.E., JOHNSON K.B., SCHAMBRA U.B., MUELLER R.A., CARON M.G. and FRIMEAN R.T. Jr. (1993) D1 dopamine receptor binding and mRNA levels are not altered after neonatal 6-hydroxydopamine treatment: evidence against dopamine-mediated induction of D1 dopamine receptors during postnatal development. J. Neurochem. 41, 1255- 1262.
DWOSKIN L.P., JEWELL A.L., BUXTON S.T. and CARNEY J.M. (1992) Phencyclidineinduced desensitization of striatal dopamine release. Neuropharmacology a, 1033-1039. ESSIG E.C. and KILPATRICK I.C. (1991) Influence of acute and chronic haloperidol treatment on dopamine metabolism in the rat caudate-putamen, prefrontal cortex and amygdala. Psychopharmacology m, 194-200. FAGG G.E. (1987) Phencyclidine and related drugs bind to the activated N-methyl-D-aspartate receptor - channel complex in rat brain membranes. Neurosci. Lett. %,221-227. FINLAY J.M., JAKUBOVIC A., FU D.S. and FIBIGER H.C. (1987) Tolerance to haloperidolinduced increases in dopamine metabolism: fact or artifact ? Eur. J. Pharmacol. m, 117- 12 1. FOSTER A.C. and WONG E.H.F. (1987) The novel anticonvulsant MK-801 binds to the activated state of the N-methyl-D-aspartate receptor in rat brain. Br. J. Pharmacol. fi, 403-409. FRENCH E.D., MURA A. and WANG T. (1993) MK-801, phencyclidine (PCP) and PCP-like drugs increase burst firing in rat A10 dopamine neurons: comparison to competitive NMDA antagonists. Synapse u, 108-l 16. GANDOLFI O., DALL’OLIO R., VACCHERI A., RONCADA P. and MONTANARO N. (1988) Responses to selective D, and D, agonists after repeated treatment with selective D1 and D2 antagonists. Pharmacol. Biochem. Behav. aa, 463-469. GANDOLFI O., RIMONDINI R. and DALL’OLIO R. (1992) The modulation of dopaminergic transmission in the striatum by MK-801 is independent of presynaptic mechanisms. Neuropharmacology a.1 1 11- 1114. GANDOLFI O., RIMONDINI R. and DALL’OLIO R. (1994) D-cycloserine decreases both D1 and D2 dopamine receptors number and their function in rat brain. Pharmacol. Biochem. Behav. &j, 351-356.
GIORGI O., PIBIRI M.G., LO1 R. and CORDA M.C. (1993) Chronic treatment with SCH 23390 increases the production rate of dopamine D1 receptors in the nigro-striatal system of the rat. Eur. J. Pharmacol. Sect. m. 139-145. HIRAMATSU M., CHO A.K. and NABESHIMA T (1989) Comparison of the behavioral and biochemical effects of the NMDA receptor antagonist, MK 801 and phencyclidine. Eur. J. Pharmacol. lfjfj, 359-366.
IMPERATO A., CROCCO M.G., BACCHI S. and ANGELUCCI L. (1990) NMDA receptors and in vivo dopamine release in the nucleus accumbens and caudatus. Eur. J. Pharmacol. Iflz, 555556.
JHAMANDAS K. and MARIEN M. (1987) Glutamate-evoked release of endogenous brain dopamine: inhibition by an excitatory amino acid antagonist and an enkephalin analogue. Br. J. Pharmacd. B, 641-650.
670
0. Gandolfi and R. Dall’Oho
KIM J.S., KORNHUBER H.H., SCHMIDT-BURGK W. and HOLZMULLER B. (1980) Low cerebrospinal fluid glutamate in schizophrenic patients and a new hypothesis on schizophrenia. Neurosci. Lett. 2Q, 379-382. LANG A., VASAR E., SOOSAAR A. and HARRO J. (1992) The involvement of sigma and phencyclidine receptors in the action of antipsychotic drugs. Pharmacol. Toxicol. u, 132-138. LILJEQUIST S., OSSOWSKA K. and GRABOWSKA-ANDEN N.E. (1991) Effect of the NMDA receptor antagonist, MK 801, on locomotor activity and on the metabolism of dopamine in various brain areas of mice. Eur. J. Pharmacol. && 55-61. LOO P., BRAUNWALDER A., LEHMANN J. and WILLIAMS M. (1986) Radioligand binding to central phencyclidine recognition sites is dependent on excitatory amino acid receptor agonists. Eur. J. Pharmacol. m, 467-468. LOWRY O.H., ROSENBROUGH N.J., FARR A.L. and RANDALL R.J. (1951) Protein measurement with the folin phenol reagent. J. Biol. Chem. m, 265275. MAREK P., CHAPMAN CD. and HOWARD S. (1992) The effect of phencyclidine and dl-2amino-5phosphovaleric acid on N-methyl-D-aspartic acid induced changes in extracellular concentration of dopamine and DOPAC in the rat neostriatum. Neurophatmacology a, 123-127. MARIEN M., BRIEN J.F. and JHAMANDAS K. (1983) Regional release of [3H]-dopamine from rat brain in vitro: effects of opioids on release induced by potassium, nicotine and L-glutamic acid. Can. J. Physiol. Pharmacol. fl,43-60. MC DONALD J.F., MILJKOVIC, Z. and PENNEFATHER P. (1987) Use-dependent block of excitatory amino acid currents in cultured neurons by ketamine. J. Neurophysiol. s, 25 1-256. MORARI M., O’CONNOR W.T., UNGERSTEEDT U. AND FUXE K. (1993) N-methyl-Daspartic acid differentially regulates extra-cellular dopamine, GABA, and glutamate levels in the dorso-lateral neostriatum of the alotane-anaesthetized rats: an in vivo microdyalisis study. J. Neurochem. 6Q, 1884- 1893. MOUNT H., QUIRION R., CLAUDEIU I. and BOKSA P. (1990) Stimulation of dopamine release from cultured rat mesencephalic cells by naturally occurring excitatory amino acids: Involvement of both N-methyl-D-aspartate (NMDA) and non-NMDA receptor subtypes. J. Neurochem. s, 268-275. MUNSON P.J. and RODBARD D.L. (1980) Ligand: a versatile computerized approach for characterization of ligand binding systems. Anal. Biochem. m, 220-239. OHMORI T., KOYAMA T., NAKAMURA F., WANG P. and YAMASHITA I. (1992) Effect of phencyclidine on spontaneous and N-methyl-D-aspartate (NMDA)-induced efflux of dopamine from superfused slices of rat striatum. Neurophamacology a, 461-467. PAPA S.M., ENGBER T.M., BOLDY R.C. and CHASE T.N. (1993) Opposite effects of NMDA and AMPA receptor blockade on catalepsy induced by dopamine receptor antagonists. Eur. J. Pharmacol. m, 247-253. RAO T.S., KIM H.S., LEHMANN J., MARTIN L.L. and WOOD P.L. (1990) Selective activation of dopaminergic pathways in the mesocortex by compounds that act at the phencyclidine (PCP) binding site: Tentative evidence for PCP recognition sites not coupled to N.methyl-D-aspartate (NMDA) receptors. Neurophatmacology a, 225-230. ROBERTS P.J. and SHARIF N.A. (1978) Effects of L-glutamate and related amino acids upon the release of [3H]-dopamine from rat striatal slices. Brain Res. m,391-395. ROBERTS P.J. and ANDERSON SD. (1979) Stimulatory effect of L-glutamate and related amino acids on [3H]-dopamine release from rat striatum: an in vitro model for glutamate action. J. Neurochem. &$,1539-1545. SALLER CF. and SALAMA A.I. (1984) Rapid automated analysis of biogenic amines and their metabolites using reverse-phase high-performance liquid chromatography with electrochemical detection. J. Chromatogr. m, 287-298. SCATCHARD G. (1949) The attraction of proteins for small molecules and ions. Ann. N.Y. Acad. Sci. a, 660-672. SCHMIDT W.J., ZADOW B., KRETSCHMER B.D. and HAUBER W. (1991) nticataleptic potencies of glutamate-antagonists. Amino Acids 1,225-237.
DA-NMDAInteraction in CNS SNELL L.D. and JOHNSON K.M. (1986) Characterization of the inhibition of excitatory amino acid - induced neuro-transmitter release in the rat striatum by phencyclidine-like drugs. J. Pharmacol. Exp. Ther. =,938-946.
SOKOLOVSKY M., GURWMZ D. and GALZON R. (1980) Muscarinic receptor binding in mouse brain: regulation by guanine nucleotides. Biochem. Biophys. Res. Commun. H,487-492. STIRLING J.M., CROSS A.J. and GREEN A.R. (1989) The binding of [3H]-thienyl cyclohexylpiperidine ([3H]-TCP) to the NMDA phencyclidine receptor complex. Neuropharmacology 28, -7.
ULAS J., WEIHMULLER F.B., O’DELL S.J., MARSHALL J.F. and COTMAN C.W. (1994) Chronic blockade of dopamine receptors affects binding to NMDA receptors in rat cortex. Sot. Neurosci. Abs..
WONG E.H.F., KEMP J.A., PRlESTLEY T., KNIGHT A.R. and WOODRUFF G.N. (1986) The anticonvulsant MK-801 is a potent N-methyl-D-aspartate antagonist. Proc. Natl. Acad. Sci. USA &j, 7104-7108.
Inquires and reprint requests should be addressed to: Prof. Ottavio Gandolfi Department of Pharmacology University of Bologna Via Imerio, 48 I-40 126 Bologna, Italy Fax: +39.51.248862
671
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1996, Vol. 20. pp. 659-671 8 1996 E1sevte.r 6dence
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MODUTGRY
ROLE OF DOPAMINE ON EXCITATORY AMINO ACID RECEPTORS
OTTAVIO
GANDOLFI
and ROSSELLA
DALL’OLIO
Department of Pharmacology, University of Bologna, Italy
(Final form, February 1996)
Gandolfi Ottavio and Rossella Dall’Olio: Modulatory role of dopamine on excitatory amino acid receptors. F’rog.Neuro-Psychopharmacol. & Biol Psychiat. 1996 20, pp. 659-671 1. In extensively washed synaptic membrane preparations from rat prefrontal cortex, the “in vitro” addition of either the Dl (SKF 38393) or the D2 (LY 171555) specific agonists markedly decreased the apparent affinity of the NMDA receptor antagonist [3H]-MK801 specific binding. In the same membrane preparation, the concentration of L-glutamate required to produce half maximal enhancement of [3H]-MK801 binding was approximately the same both in the presence or in the absence of dopaminergic drugs. 2. I.c.v. administration of the neurotoxin 6-OHDA resulted in a dramatic reduction of dopamine (DA) prefrontal cortex levels, whilst repeated administrations (21 consecutive days) with either the Dl (SCH 23390) or the D2 (YM 09151-2) selective antagonist failed to change DA and DOPAC contents. 3. Repeated administrations with the Dl receptor blocker SCH 23390 selectively increased the Bmax values of [3H]-SCH 23390 binding while [3H]-spiroperidol binding was increased both by repeated administrations of YM 09151-2 and by i.c.v. injection of 6-OHDA. 4. Although both chronic D2 blockade and 6-OHDA lesions consistentely increased D2 receptor number, in extensively washed synaptic plasma membranes (SPM) of rats repeatedly administered with YM 09151-2 but not with 6-OHDA, the [3H]-MK801 binding was increased. 5. It is concluded that the effects of NMDA receptor activation could not be directely mediated by stimulation of DA release, but are highly dependent upon the presence of DA axon terminals. Kevwor&: catecholamines content, N-methyl-D-aspartate, administrations, specific dopamine receptors.
neurotoxic
lesion,
rats, repeated
. . Ddopamine (DA), 3,4-dihydroxyphenylacetic acid (DOPAC), excitatory amino acid (EAA), beta,gamma-imidoguanosine-5’-tryphosphate (Gpp(NH),), N-methyl-D-aspartate (NMDA), 6-hydroxydopamine (COHDA), synaphic plasma membrane (SPM).
Recently, the full comprehension of the molecular mechanisms underlying the interactions between dopamine (DA) and excitatory amino acidis (EAA) represents a scientific and clinical goal 659
660
0.
Gandolft and R Dall’Olio
since abnormalities in these neurotransmitter actions have been implicated in the clinical symptoms of Parkinson disease and schizophrenia (Carlsson and Carlsson, 1990, Deutch et al., 1989; Kim et al., 1980). Several biochemical studies focused on the modulatory effects of NMDA-sensitive glutamate receptors on DA release in tissue slices (Asencio et al., 1991; Bowyer et al., 1992; Dwoskin et al., 1992; Jhmandas and Marien, 1987; Marien et al., 1983; Ohmori et al., 1992; Roberts and Sharif, 1978; Roberts and Anderson, 1979; Snell and Johnson, 1986) and in dissociated cell cultures of rat mesencephalon (Mount et al., 1990). Extra-cellular levels of DA evaluated by microdyalisis studies did not generate univocal results: intrastriatal infusions with NMDA increased (Muck et al., 1992; Morari et al., 1993) or did not modify (Imperato et al., 1990) extra-cellular DA levels, and in our laboratory, D-cycloserine (3 mg/kg i.p.), a partial agonist of the strichnine-insensitive
glycine recognition site failed to change
either DA and DOPAC extra-cellular output twenty-four hours after the implantation
of the
transstriatal probe in freely moving rat striatal dialysates (Gandolfi et al., 1994). Electrophysiologic studies obtained with quantitative single-unit recording, show that in rat the NMDA uncompetitive receptor antagonist MK801 produces dose-dependent increases both in the burst firing of ventral tegmental Ato DA neurons and in dopaminergic tone within mesolimbicmesocortical regions (French et al., 1993). Behavioral studies in rodents show that MK801 antagonizes dopamine D2 receptor mediated catalepsy induced by different DA receptor antagonists (Papa et al., 1993; Schmidt et al., 1991) activates dopaminergic transmission (Hiramatsu et al., 1989; Liljequist et al., 1991; Rao et al., 1990) and induces hypermotility either in rats (Dall’Olio et al., 1995) or in monoamine-depleted mice (Carlsson and Carlsson, 1989). In this bulk of evidences, that not always generated consistent results, the authors planned biochemical experiments to evaluate the modulation of NMDA-sensitive glutamate receptors in two different experimental conditions: i) prolonged Dt or D2 receptor blockade-induced receptor super-sensitivity, and ii) DA receptor supersensitivity following specific neurotoxin (6-OHDA) lesions. The authors followed such dual approach in the light of strengthening
information
that
comparing the two experimental models, rats withdrawn from repeated treatments with DA blockers show the same degree of D2 receptor supersensitivity as rats lesioned with 6-OHDA which distroys most of DA axon terminals. The authors planned “ex vivo” [3H]- MK801 radiolingand binding studies, serving as an index of functional activation of NMDA receptors (Loo et al. 1986, Fagg 1987, Foster and Wong 1987), in well washed synaptic plasma membrane preparation (SPM) from the prefrontal cortex of tats either repeatedly treated with Dt/D2 blockers or in 6-OHDA lesioned animals. Other [3H]-MK801 radiolingad binding experiments after the “in vitro” addition of different DA agonists, or drugs acting at the G-protein level (Gpp(NH)p) were undertaken to evaluate whether DA-ergic drugs, at least in this simplified system could interfere by simply direct interaction with NMDA-sensitive glutamate receptor complex.
DA-NMDA
661
Interaction in CNS
Male Sprague Dawley rats (150-175 g, Charles River Italia SpA, Como, Italy) were housed in groups of four under controlled conditions of light (07:OOa.m. - 07:OO p.m.), temperature (22 rt 2’C) and humidity (65%) and were allowed free access to standard laboratory diet and tap water. Experimental protocols were approved by a local bioethical committee while the procedures and the animal confort were controlled by the University Veterinary Service.
[3H]-MK801 (15 Ci/mmol), [3H]-SCH 23390 (70 Ci/mmol) and [3H]-spiroperidol (15 Ci/mmol) were obtained from NEN, Boston, MA, USA. (+)-Butaclamol HCl, (+)-SCH 23390 ((R)-(+)-8chloro-2,3,4,5-tetrahydro-3-methyl-5-phenyl-lH-3-benzazepine-7-maleate),
MK801 (dizocilpine)
and SKP 38393 (2,3,4,5-tetrahydro-7,8-dihydroxy-l-phenyl-lH-benzazepine)
were from RBI,
Natick, MA, USA. YM 09151-2 (Cis-N-(benzyl-2-metylpyrrolidin-3-yl)-5-chloro-2-methoxy-4methylamino-benzamide)
from Yamanouchi,
Tokyo, Japan. LY 171555 (Trans-(-)-4a-R-4-
,4a,5,6,7,8,8a,9-octahydro-5-propyl-2H-pyrazolo-(3,4)-quinoline Indianapolis,
IN, USA. G,(NH),
dihydroxy-phenyl-ethyl-amine),
HCl),
(beta, gamma-imidoguanosine-5, DOPAC
(3,4dihydroxyphenylacetic
from
Eli
Lilly
Co.,
triphosphate), DA (3,4acid),
6-OHDA
(6-
hydroxydopamine), (-)-sulpiride, L-glutamate and haloperidol, were from Sigma, St.Louis, MO, USA. ed
Drup Treatme-
Group of animals (n= I/group) received daily injections for 21 consecutive days of the following pharmacological treatments: the Dl dopamine receptor blocker SCH 23390 (0.05 mg/kg S.C.twice daily), the Dz specific antagonist YM 09151-2 (0.02 mg/kg i.p.), the “atypic neuroleptic” (-)sulpiride (20 mg/kg i.p.), haloperidol (0.125 mg/kg i.p.), or saline. Three days after the withdrawal of 21-day repeated administrations when behavioral supersensitivity to a subthreshold dose of apomorphine was observed (Dall’Olio et al., 1990) rats were killed by decapitation, the brains removed, rinsed in ice-cold isotonic saline, and frontal cortices dissected over ice were stored at -80°C until assays. $-HvdrQ.g&pamme (6-OHDA) - Lesiom
Groups of rats (n= lo/group) were anesthetized with pentobarbital. Lesions were produced by injecting 6-OHDA (200 pg) stereotaxically in the lateral ventricle. Sham-lesioned animals were given i.c.v. injections of the vehicle solution, 0.01% (wt/vol) ascorbic acid in saline. Animals of both groups were injected intraperitoneally with desmethylimipramine
(25 mg/kg) 40 minutes
before the injection of neurotoxin (or vehicle) to prevent the uptake of the neurotoxin into noradrenergic axons and thus minimize the degeneration of these terminals. Lesioned and shamlesioned rats were killed by decapitation 24 days after surgery, the brains were removed and prefrontal cortices dissected over ice were stored at -80°C until assays.
662
0. GandoIfi and R. Dall’Olio
.
.
Dopamine (DA) and Dihydroxvahenvlacehc acrd (DOPAC) Determinatiotg The concentrations and Salama
of DA and DOPAC in rat frontal cortices were measured according
(1984) using high-performance-liquid
detector (HPLC-ED). homogenates
centrifuged
the HPLC-ED
system. The mobile-phase
(pH 4.0-4.3) consisted
0.1 mM ethylendiamine
were carried out with minor modifications
buffer pH 7.4, the homogenates
resuspended,
and the homogenates
pellets were resuspended
together with different spiroperidol
according
were centrifuged
receptor
to Billard et al. (1984) and
with Polytron in ice-cold 50 mM
(30,000 x g, 10 min), pellets were
in 50 mM Tris-HCl buffer containing of membrane
concentrations
120 mM NaCl, 5 mM KCl, 2 mM
suspensions
were incubated
(30 min, 37°C)
of [3H]-SCH 23390 (ranging from 0.25 to 6 nM) or [3H]-
through Watman GF/C filters. The specific
between
the total binding
and the binding
were determined
in the presence
respectively
under by the
of a specific
for [3H]-SCH 23390 and
binding.
The [3H]-MK801
binding assays were carried out according to Stirling et al. (1989). Prefrontal
were homogenized
homogenizer.
bindings
remaining
1 pM cold SCH 23390 or 1 pM (+)-butaclamol
[3H]-spiroperidol
cortices
to Dl and D2 dopamine
(ranging from 0.02 to 0.5 nM). The reaction was stopped by rapid filtration
pressure
displacer,
column (C-
were pelleted twice in the same buffer. The final membrane
CaC12 and 1 mM MgC12. Aliquots
difference
on a reverse-phase
detector (Waters M-460) was operated at +0.65 mV.
and Langer (1978). Briefly, cortices were homogenized
negative
to
Bindin-
respectively,
Tris-HCl
acid, the
were applied diictely
of 70 mM NaI-IzPOd, 0.65 mM
The binding assays for [3H]-SCH 23390 and [3H]-spiroperidol
Briley
to electrochemical
tetracetic acid (EDTA), 0.035 M citric acid and
Separation of DA and DOPAC was accomplished
18; 25 cm) and the electrochemical &g&&and
coupled
in 0.1 M perchloric
and samples (20 pl) of the resulting supematant
sodium octyl sulphate, 35% acetonitrile.
chromatography
Briefly, prefrontal cortices were homogenized
to Saller
The
in 10 vol ice-cold 0.32 M sucrose using a motor-driven
homogenate
sucrose, and centrifuged
again. The supematants
pellets. These were resuspended pellets were resuspended
was centrifuged
glass-teflon
at 1,000 x g, the pellet resuspended were pooled, centrifuged
in 0.32 M
at 45,000 x g to yield P2
in 20 vol 5 mM Tris-HCl pH 7.7 at 4°C and centrifuged.
in ice-cold distilled water and centrifuged.
This procedure
The
was repeated
three times and the pellets were frozen at -80°C for at least 18 hours. On the day of the assay pellets were thawed, centrifuged Tris-HCl
suspended
in 20 volumes
of 5 mM Tris-HCl
pH 7.7 at 4”C, homogenized
at 30,000 x g. This wash step was repeated four more times in 100 volumes buffer and the final suspension
was incubated at room temperature
centrifugation
at 30,000 x g. The final pellets were resuspended
concentration
of 0.8-l mg/ml. Aliquots of synaptic plasma membranes
prefrontal
cornices
were incubated with different concentrations
to 100 nM). In some experiments,
membranes
concentrations
5 mM
for 20 min prior to
in the same buffer to give a protein @PM) prepared
from the
of [3H]-MK801
(ranging from 2
were incubated with [3H]-MK801
(25 nM) and Dl
agonist SKF 38393, the D2 agonist LY 171555 (both 100 pM) either in the presence absence of different
and
of L-glutamate
or in the
(ranging from lo-lo to 10” M). In different
DA-NMDA Interaction in CNS
663
series of experiments, [3H]-MK801 (25 nM) specific binding was run in the presence of the non hydrolizable GTP analogue G&NH&
(100 pM) to activate the G-protein coupler of adenylate
cyclase system. The specific binding was determined between the total binding and the binding left in the presence of 1 uM cold MK801. After incubation for 2 hr at 25°C (equilibrium), the mixture was rapidly filtered through Watman GF/C filters presoaked in 0.05% polyethyleneimine radioactivity remaining on the filters was counted by liquid scintillation
and the
spectrometry using
Atomlight (NEN, Boston, MA, USA). The kinetic characteristics of the specific binding were analyzed according to the method of Scatchard (1949) using the program of Munson and Rodbard (1980). Proteins were measured using BSA as standard according to Lowry et al. (1951). Data a42.lM
Radioligand binding data were analysed by Students t test, and the concentrations of DA and DOPAC
were analysed by means of ANOVA followed by single comparisons of the means.
In extensively washed SPM from rat frontal cortex, [3H]-MK801 labeled a single population of sites (Bmax = 6.92 f 0.67 pmol/mg prot) with good affinity (Kd = 19.5 f 2.1 nM). The “in vitro” addition of either the Dl receptor agonist SKF 38393 or the D2 agent LY 171555 (both 100 JIM) markedly decreased the affinity of [3H]-MK801 binding (Table 1) while failed to change the maximum number of binding sites. Lower DI or D2 agonists concentrations did not show any statistically different changes in the kinetic characteristics of [3H]-MK801 specific binding (data not shown). Table 1
Influence of DI and D2 DA Agonists “in vitro” Addition, on the Kinetic Characteristics of [3H]MK801 Specific Binding to Extensively Washed Rat Prefrontal Cortex Membranes. Bmax (pmol/mg prot) 6.9240.67
Control SKF 38393
100 FM
5.86M.51
( LY 171555
100 PM
6.15k0.49
Kd (nM) 19.5dz2.1 47.6&3.6*
38.4+2.7* [3H]-MK801 binding was performed either in the absence of any drug (control) and in the presence of 100 pM SKF 38393 or 100 pM LY 171555. Mean values f SEM are reported. The apparent Kd values following the “in vitro” addition of either agonists were significantly different (*p c.05 Student r-lest) from those obtained in control.
In
the same preparation, [3H]-MK801 (25 nM) specific binding has been enhanced by the
addition of L-glutamate (10-a - 1O-4M). Figure 1 shows that in the presence of maximally active concentration of L-glutamate (10m4M) the [3HJ-MK801 specific binding was increased by about
664
0. Gandolfi
and R Dall’Olio
300%. The interactions of the D2 agent LY 171555 with [3H]-MK801 binding sites were of uncompetitive nature; increasing concentrations of L-glutamate did not alter the inhibitory effect of the DA-ergic agent on [3H]-MK801 binding in extensively washed SPM prepared from rat prefrontal cortex. The concentration of L-glutamate required to produce half maximal enhancement of [3H]-MK801 binding was approximately the same both in the presence (EC50 = 0.9 pM) or in the absence (EC50 = 0.7 pM) of LY 171555.
. :: 0-1 0
/
-a
I
-7
-6
L-Glutamate
-5
-4
-3
[M]
Fig 1. Basal [3H]-MK801 specific bindings (25 nM) in the absence (*) and in the presence (0) of LY 171555 (100 @I) were 2.4 f 0.18 (SEM) and 1.2 f 0.08 @EM) pmol/mg prot respectively. Specific binding was over 70% of total binding in basal conditions and was greater than 80% of total binding under conditions of maximal stimulation. Comparable results have been obtained in at least three separate experiments.
The ability of the G-protein non-hydrolysable activator G,(NH),
(10e4 M) to modulate the [3H]-
MK801 (25 nM) specific binding to SPM preparations is shown in Table 2. The “in vitro” addition of the stimulating G protein nucleotide inhibited by more than 50% [3H]-MK801 specific binding. Maximally active concentrations of L-glutamate, although dramatically increasing [3H]-MK801 binding were unable to reverse guanine nucleotide-induced inhibition. Table 2. Inhibition of ]3H]-MK801 (25 nM) Specific Binding by the Non Hydrolizable GTP Analogue to Extensively Washed SPM prepared from Rat Prefrontal Cortex
Basal G,(NH), (to(J@0 Resultsare expressedas mean f SEM
[3H]-MK 801 specific binding (25 nM) (pmol/mg pro0 -L-Glut. + 100 pM L-Glut. 8.=.6* 2.5M. 18 3.4k0.2* l.kbO.07
values from at least three experiments each performed in triplicate. *p 1.05 (Student r-test) when compared to the respective basal value.
DA-NMDA
.
Interaction in CNS
665
.
Neurotomc Lesron and Repeated Drue Administrations
Table 3 shows that the i.c.v. injection of neurotoxin 6-OHDA resulted in a dramatic reduction of DA and DOPAC levels in rat prefrontal cortex. Consistent decreases (70-80%) of [3HJ-DA uptake by cortical synaptosomes (not shown) used as a further index of the degree of neurotoxic lesion were found. In contrast, consistently with Finlay et al. (1987) and Essig and Kilpatrick (1991) DA and DOPAC cortical levels were not modified by repeated administrations of Dl or D2 blockers. Consistenly with previous results (Cmese and Chen 1985, Gandolfi et al. 1988, Duncan et al. 1993, Giorgi et al. 1993), Scatchard analysis of the saturation data of [3H]-SCH 23390 and [3H]spiroperidol bindings to SPM prepared from repeatedly treated rats showed that the D, blocker increased (about 30%) the number but not the apparent affinity values of Dl binding sites labelled by [3H]-SCH 23390. The same repeated treatment with the Dt receptor blocker failed to modify the kinetic characteristics of [3H]spiroperidol specific binding to SPM. The kinetic characteristics of [3H]-Spiroperidol binding to SPM of rats repeatedly administered with YM 09151-2 revealed large increases in Bmax values (about 48%) while Dl receptors were unaffected. Table 3 shows also that in SPM prepared from the 6-OHDA lesioned rats there is a statistically significant increase (about 40%) in the maximum number (Bmax) of [3H]-spiroperidol specific binding, while the kinetic characteristics of [3H]-SCH 23390 binding to Dl receptors did not change. Table 3 Effects of 6-OHDA or Repeated Administrations with Either Dl and D2 Dopamine Receptor Blockers on DA and DOPAC Cortical Levels and on the Kinetic Characteristics of DI and D2 Receptors in SPM. DA (pmol/w) Non-lesioned 6-OHDA
62W2 4w*
DGPAC (pmdmg) 72k3 g&0.8*
[3H]-SCH 23390
[ 3HI-spiroperidol Bmax(fmol/mg) Kd(nM)
Kd(nM)
Billax (fmol/mg)
0.9fo.03
396+17
0.16M.01
1lm.6
1.2M.05
42W3 1
0.15~.01
16W.l*
SCH 23390
596&68
68f5
l.lXl.04
53X27**
0.17+0 - .01
103*4.1
YM 09151-2
65 lzh66
83s
0.8M.04
352&20
0.21fl.03
177&9**
DA and DOPAC levels, like c3H]-SCH 23390and [3Hj-spiroperidol specific bindings were determined following a 72 hr washout period from rats repeatedly treated (21 days) with SCH23390 (0.05 mg/kg i.p. twice daily) or with YM 09151-2 (0.02 mg/kg i.p.) or 24 days following 6-OHDA (200 pg i.c.v.) administration. *~.05 when compared to sham-lesioned rats **~.05 significantly different from repeatedly saline-treated rats
Figure 2 shows the normalized data transformed to % control of [3H]-MK801 specific binding to extensively washed SPM. Statistically significant increase of [3H]-MK801 binding was found only following repeated administrations of either YM 09151-2 (3389 f 174 fmol/mg Vs 2394f 102 fmol/mg pc.05 Student’s t test) or haloperidol (3009 f 178 fmol/mg p<.O2 Student’s t test). Repeated administrations either of SCH 23390 or the atypic neuroleptic (-) sulpiride failed to change [3H]-MK801 specific binding (pannel B).
666
0. GandolB
Although
in SPM of either repeatedly
there are consistent prepared
increases
from DA depleted
and R. DaU’Olfo
YM 09151-2 treated rats or 60HDA-lesioned
of D2receptor
binding (Table 3), in prefrontal
rats no changes in [3H]-MK801
Moreover in the same membrane preparation
binding were observed
from DA-depleted
animals
cortex membranes (Pannel A).
animals the “in vitro”, addition of
high doses of DA (10 PM) failed to modify [3H]-MK801 specific binding.
A
l3
0
control
@j
6-OHDA
c]
control
•j
SCH
23390
YM
09151-2
i.c.v.
q 6-DHDA
+
DA
=I-sulp
@halo
10“H 100
/
-
0
-_ i ** *
Fig 2. [3Hj-MK801
specific binding (25 nM) to extensively-washed SPM prepared from rat prefrontal cortex was performed as described in “Radiolingand Binding Studies”. Animals were killed either 72 hr following repeated (21 days) administration of SCH 23390 (0.05 mg/kg i.p. twice daily), (-)-sulpiride (2Omg/kg i.p.), YM 09151-2 (0.02 mg/kg i.p.), haloperidol (0.125 mg/kg i.p.) or saline (Part B), or 24 days following 6-GHDA (200 pg i.c.v.) (Part A). The results are expressed as % change of control [3H]-MK801 specific binding. Non transformed data were: control=2394 f102 fmol/mg; YMO9151-2=3389+174 fmol/mg; haloperidol =3OfI9*178 fmobmg. Bach value represents the means of at least three experiments done in triplicate. SEM were less than 10%. *p<.O5 (Student’s ttest) when compared to control. **p<.O2 (Student’s t-test) when compared to control.
In this study, the L-glutamate the general hypothesis
enhancement
that the non-competitive
activated state of the NMDA receptor-cation serving as an index of functional Loo et al. (McDonald
1986).
induced
enhancements different
This
et al. 1987)
linked ion channel binding
of [3H]-MK801 binding gives supportive evidence to
receptor,
by repeated
antagonist
MK801 binds to an
(Wong et al., 1986) and therefore
activation of the receptor (Fagg, 1987; Foster and Wong, 1987;
interpretation, that MK
NMDA receptor
channel complex
taken
together
with
electro-physiological
evidencies
801 is an open channel blocker that binds within the NMDA-
allows us to assume that at equilibrium administrations
increases
with YM 09151-2 or haloperidol
of [3H]-MK801 are indicative
of
in NMDA receptor function. These results agree with other data obtained both with
ligands ([3H]-TCP)
or with quantitative
autoradiography
techniques
NMDA receptor function following repeated haloperidol or eticlopride
showing
administrations
increased (Byrd et al.
1987; Ulas et al., 1994) but are at variance with others (Creese et al. 1994; Lang et al. 1992).
DA-NMDA Interaction in CNS
Different
techniques
(autoradiography
vs radioreceptor binding
667
studies), labels, membrane
preparation procedures, doses, times and washout periods could be responsible for this apparent discrepancy. Interuretation of “ex vivo” Radioliand
Bindi@&&
The present data show that in rat prefrontal cortex, a cerebral area having one of the highest concentrations of DA-ergic nerve fibers, there is an enhancement of [3H]-MK801 binding only in SPM prepared from D2 supersensitive rats following D2 receptor blockade. In 6-OHDA-lesioned animals where DA axon terminals are almost completely absent, the increase in D2 receptor number did not parallel the increase [3H]-MK801 specific binding. It is unlike that the DA paucity following 6-OHDA lesion (about 10%) is insufficient to activate D2 receptors and to increase [3H]MK801 specific binding, since the “in vitro” addition of DA-ergic drugs (10-S M) in SPM of shamlesioned rats decreased [3H]-MK801 binding, while in synaptic membranes of rats lesioned with 6OHDA DA failed to affect [3H]-MK801 binding. Intremetation qf “in vitro” Radio&gmd Bind& &&Q
The D2 agent LY 171555 produced similar inhibitions of [3H]-MK801 specific binding either in the absence or in the presence of different concentrations of L-glutamate, theoretically suggesting that the interactions between NMDA and DA receptors, non mediated via the NMDA recognition site, could be of uncompetitive nature. In contrast to our “ex vivo” results showing [3H]-MK801 binding increases in rats repeatedly administered with D2 blockers, the “in vitro” addition of high (but not low) doses of DA-ergic agents decreases affinity (Kd values increases) of [3H]-MK801 specific binding in well washed SPM of untreated animals suggesting that, at least in this system, DA-ergic drugs could modify glutamatergic function. This effect however was not abserved when DA was added in SPM prepared from 6-OHDA lesioned rats. To verify whether the failure of DAergic drugs to modify [3H]-MK801 binding in 6-OHDA lesioned rats could be due to the uncoupling of DA receptors with the G protein following the lesion, the authors performed “in vitro” [3H]-MK801 binding studies after activation of G protein by the non-hydrolizable analogue G,,(NH),.
GTP
Our results indicated that the inhibiting effet of this drug on [3H]-MK801
binding is unrelated to a direct effect of guanine nucleotides on the NMDA-glutamate recognition site since the inhibition of [3H]-MK801 binding failed to change after the addition of 10-d M Lglutamate. Other studies (Baron et al. 1989) that showed that guanine nucleotides reduced both antagonists ([3H]-CPP) and agonist ([3H]-glutamate) binding sites are inconsistent with all we know about GTP-binding protein-linked receptors where guanine nucleotides selectively decrease agonist but not antagonist
binding sites by converting high affinity to low affinity sites
(Sokolovsky et al. 1980) and suggest that the inhibition of [3H]-MK801 binding could not be related to the activation of GTP binding proteins. All these data taken together suggest that the DA-elicited modulation of NMDA receptors could not be simply a function of DA release from nerve terminals at this site. Endogenous DA, via presynaptic action on supersensitive receptors, through asso-assonic interaction could modulate glutamate or another substance (peptide) release from a DA-controlled neuron that appears to play
668
0.
Gandolfi and R Dall’Olio
an important role in modulating the NMDA receptor function. However, when DA neurons are absent, the lack of DA-ergic terminals could not induce the DA-controlled (glutamate ?) neuron to activate and therefore to increase [3H]-MK801 specific binding.
All these results taken together with other data showing the incapacity of MK801 and other glutamatergic drugs (cycloserine) to modulate extracellular levels of DA (Gandolfi et al. 1992, 1994) indicate that the effects of NMDA receptor activation could not be directely mediated by stimulation of DA release, however this response is highly dependent upon the presence of DA axon terminals, subserving therefore the complex modulatory role of dopamine in EAA receptor activation. The present results rather suggest trans-synaptic mechanisms, and do not allow to assume a direct or a G-protein mediated control of DA-ergic agonists on NMDA receptor function. The exact mechanisms of this interaction is still obscure; electrophysiological
studies utilizing
membrane patch techniques could represent the most suitable approach to examine the regulation of NMDA responses in both experimental conditions of Dz-receptor supersensitivity.
The present work was supported by Grants of Italian Ministry for University. The authors thank Mr. R. Laghetti and Mrs. C. Cappelletti for typing the manuscript.
ASENCIO H., BUSTOS G., GYSLING K. and LABARCA R. (1991) N-methyl-D-aspartate receptors and release of newly synthesized [3H]-dopamine in nucleus accumbens slices and its relationship with neocortical afferences. Prog. Neuropsychopharmacol. Biol. Psychiatry fi, 663676.
BARON B.M., DUDLEY M.W., MCCARTY D.R., MILLER F.P., REYNOLDS J. and SCHMIDT C.J. (1989) Guanine nucleotides are competitive inhibitors of N-methyl-D-aspartate at its receptor site both in vitro and in vivo. J. Pharmacol. Exp. Ther. a, 162-169. BILLARD W., RUPERTO V., GROSBY G., IORIO L.C. and BARNETT A. (1984) Characterization of the binding of [3H]-SCH 23390, a selective Dl receptor antagonist ligand, in rat striatum. Life Sci. & 18851893. BOWYER J.F., NEWPORT G.D., LIPE G.W. and FRAME L.T. (1992) A further evaluation of the effects of K+ depolarization on glutamate-evoked [3H]-dopamine release from striatal slices. J. Pharmacol. Exp. Ther. U,72-80.
BRILEY M. and LANGER S.Z. (1978) Two binding sites for 3H-Spiroperidol on rat striatal membranes. Eur. J. Pharmacol. a, 283-284. BYRD J.C., BYKOV V. and ROTHMAN R. (1987) Chronic haloperidol treatment up-regulates rat brain PCP receptors. Eur. J. Pharmacoi. j,& 121-122. CARLSSON M. and CARLSSON A. (1989) The NMDA antagonist MK 801 causes marked locomotor stimulation in monoamine-depleted mice. J. Neural Transm. z, 221-226. CARLSSON M. and CARLSSON A. (1990) Interaction between glutamatergic and monoaminergic system within the basal ganglia - implications for schizophrenia and Parkinson’s disease. Trends Neurosci. u, 272-276.
DA-NMDA
Interaction in CNS
669
CREESE I. and CHEN A. (1985) Selective D1 dopamine receptor increase following chronic treatment with SCH 23390. Eur. J. Pharmacul. m, 127-128.
CREESE I., TARAZI F.I. and FLORIJN W.J. (1994) Regulation of glutamate receptor binding following chronic neuroleptic treatment. Sot. Neurosci. Abs.a. DALL’OLIO R., GANDOLFI O., RONCADA P., VACCHERI A. and MONTANARO N. (1990) Repeated treatment with (-)-Sulpiride plus a low dose of SCH 23390 displays wider neuroleptic activity without inducing dopaminergic supersensitivity. Psychopharmacology m, 560-562. DALL’OLIO R., RIMONDINI R. and GANDOLFI 0. (1995) The competitive NMDA antagonists CGP 43487 and APV potentiate dopaminergic function. Psychopharmacology us, 3 1O-315. DEUTSCH S.I., MASTROPAOLO J., SCHWARTZ B.L., ROSSE R.N. and MORIHISA J.M.A. (1989) “A glutamatergic hypothesis” of schizophrenia. Clin. Neurophannacol. 12, I- 13. DUNCAN G.E., BREESE G.R., CRISWELL H.E., JOHNSON K.B., SCHAMBRA U.B., MUELLER R.A., CARON M.G. and FRIMEAN R.T. Jr. (1993) D1 dopamine receptor binding and mRNA levels are not altered after neonatal 6-hydroxydopamine treatment: evidence against dopamine-mediated induction of D1 dopamine receptors during postnatal development. J. Neurochem. 41, 1255- 1262.
DWOSKIN L.P., JEWELL A.L., BUXTON S.T. and CARNEY J.M. (1992) Phencyclidineinduced desensitization of striatal dopamine release. Neuropharmacology a, 1033-1039. ESSIG E.C. and KILPATRICK I.C. (1991) Influence of acute and chronic haloperidol treatment on dopamine metabolism in the rat caudate-putamen, prefrontal cortex and amygdala. Psychopharmacology m, 194-200. FAGG G.E. (1987) Phencyclidine and related drugs bind to the activated N-methyl-D-aspartate receptor - channel complex in rat brain membranes. Neurosci. Lett. %,221-227. FINLAY J.M., JAKUBOVIC A., FU D.S. and FIBIGER H.C. (1987) Tolerance to haloperidolinduced increases in dopamine metabolism: fact or artifact ? Eur. J. Pharmacol. m, 117- 12 1. FOSTER A.C. and WONG E.H.F. (1987) The novel anticonvulsant MK-801 binds to the activated state of the N-methyl-D-aspartate receptor in rat brain. Br. J. Pharmacol. fi, 403-409. FRENCH E.D., MURA A. and WANG T. (1993) MK-801, phencyclidine (PCP) and PCP-like drugs increase burst firing in rat A10 dopamine neurons: comparison to competitive NMDA antagonists. Synapse u, 108-l 16. GANDOLFI O., DALL’OLIO R., VACCHERI A., RONCADA P. and MONTANARO N. (1988) Responses to selective D, and D, agonists after repeated treatment with selective D1 and D2 antagonists. Pharmacol. Biochem. Behav. aa, 463-469. GANDOLFI O., RIMONDINI R. and DALL’OLIO R. (1992) The modulation of dopaminergic transmission in the striatum by MK-801 is independent of presynaptic mechanisms. Neuropharmacology a.1 1 11- 1114. GANDOLFI O., RIMONDINI R. and DALL’OLIO R. (1994) D-cycloserine decreases both D1 and D2 dopamine receptors number and their function in rat brain. Pharmacol. Biochem. Behav. &j, 351-356.
GIORGI O., PIBIRI M.G., LO1 R. and CORDA M.C. (1993) Chronic treatment with SCH 23390 increases the production rate of dopamine D1 receptors in the nigro-striatal system of the rat. Eur. J. Pharmacol. Sect. m. 139-145. HIRAMATSU M., CHO A.K. and NABESHIMA T (1989) Comparison of the behavioral and biochemical effects of the NMDA receptor antagonist, MK 801 and phencyclidine. Eur. J. Pharmacol. lfjfj, 359-366.
IMPERATO A., CROCCO M.G., BACCHI S. and ANGELUCCI L. (1990) NMDA receptors and in vivo dopamine release in the nucleus accumbens and caudatus. Eur. J. Pharmacol. Iflz, 555556.
JHAMANDAS K. and MARIEN M. (1987) Glutamate-evoked release of endogenous brain dopamine: inhibition by an excitatory amino acid antagonist and an enkephalin analogue. Br. J. Pharmacd. B, 641-650.
670
0. Gandolfi and R. Dall’Oho
KIM J.S., KORNHUBER H.H., SCHMIDT-BURGK W. and HOLZMULLER B. (1980) Low cerebrospinal fluid glutamate in schizophrenic patients and a new hypothesis on schizophrenia. Neurosci. Lett. 2Q, 379-382. LANG A., VASAR E., SOOSAAR A. and HARRO J. (1992) The involvement of sigma and phencyclidine receptors in the action of antipsychotic drugs. Pharmacol. Toxicol. u, 132-138. LILJEQUIST S., OSSOWSKA K. and GRABOWSKA-ANDEN N.E. (1991) Effect of the NMDA receptor antagonist, MK 801, on locomotor activity and on the metabolism of dopamine in various brain areas of mice. Eur. J. Pharmacol. && 55-61. LOO P., BRAUNWALDER A., LEHMANN J. and WILLIAMS M. (1986) Radioligand binding to central phencyclidine recognition sites is dependent on excitatory amino acid receptor agonists. Eur. J. Pharmacol. m, 467-468. LOWRY O.H., ROSENBROUGH N.J., FARR A.L. and RANDALL R.J. (1951) Protein measurement with the folin phenol reagent. J. Biol. Chem. m, 265275. MAREK P., CHAPMAN CD. and HOWARD S. (1992) The effect of phencyclidine and dl-2amino-5phosphovaleric acid on N-methyl-D-aspartic acid induced changes in extracellular concentration of dopamine and DOPAC in the rat neostriatum. Neurophatmacology a, 123-127. MARIEN M., BRIEN J.F. and JHAMANDAS K. (1983) Regional release of [3H]-dopamine from rat brain in vitro: effects of opioids on release induced by potassium, nicotine and L-glutamic acid. Can. J. Physiol. Pharmacol. fl,43-60. MC DONALD J.F., MILJKOVIC, Z. and PENNEFATHER P. (1987) Use-dependent block of excitatory amino acid currents in cultured neurons by ketamine. J. Neurophysiol. s, 25 1-256. MORARI M., O’CONNOR W.T., UNGERSTEEDT U. AND FUXE K. (1993) N-methyl-Daspartic acid differentially regulates extra-cellular dopamine, GABA, and glutamate levels in the dorso-lateral neostriatum of the alotane-anaesthetized rats: an in vivo microdyalisis study. J. Neurochem. 6Q, 1884- 1893. MOUNT H., QUIRION R., CLAUDEIU I. and BOKSA P. (1990) Stimulation of dopamine release from cultured rat mesencephalic cells by naturally occurring excitatory amino acids: Involvement of both N-methyl-D-aspartate (NMDA) and non-NMDA receptor subtypes. J. Neurochem. s, 268-275. MUNSON P.J. and RODBARD D.L. (1980) Ligand: a versatile computerized approach for characterization of ligand binding systems. Anal. Biochem. m, 220-239. OHMORI T., KOYAMA T., NAKAMURA F., WANG P. and YAMASHITA I. (1992) Effect of phencyclidine on spontaneous and N-methyl-D-aspartate (NMDA)-induced efflux of dopamine from superfused slices of rat striatum. Neurophamacology a, 461-467. PAPA S.M., ENGBER T.M., BOLDY R.C. and CHASE T.N. (1993) Opposite effects of NMDA and AMPA receptor blockade on catalepsy induced by dopamine receptor antagonists. Eur. J. Pharmacol. m, 247-253. RAO T.S., KIM H.S., LEHMANN J., MARTIN L.L. and WOOD P.L. (1990) Selective activation of dopaminergic pathways in the mesocortex by compounds that act at the phencyclidine (PCP) binding site: Tentative evidence for PCP recognition sites not coupled to N.methyl-D-aspartate (NMDA) receptors. Neurophatmacology a, 225-230. ROBERTS P.J. and SHARIF N.A. (1978) Effects of L-glutamate and related amino acids upon the release of [3H]-dopamine from rat striatal slices. Brain Res. m,391-395. ROBERTS P.J. and ANDERSON SD. (1979) Stimulatory effect of L-glutamate and related amino acids on [3H]-dopamine release from rat striatum: an in vitro model for glutamate action. J. Neurochem. &$,1539-1545. SALLER CF. and SALAMA A.I. (1984) Rapid automated analysis of biogenic amines and their metabolites using reverse-phase high-performance liquid chromatography with electrochemical detection. J. Chromatogr. m, 287-298. SCATCHARD G. (1949) The attraction of proteins for small molecules and ions. Ann. N.Y. Acad. Sci. a, 660-672. SCHMIDT W.J., ZADOW B., KRETSCHMER B.D. and HAUBER W. (1991) nticataleptic potencies of glutamate-antagonists. Amino Acids 1,225-237.
DA-NMDAInteraction in CNS SNELL L.D. and JOHNSON K.M. (1986) Characterization of the inhibition of excitatory amino acid - induced neuro-transmitter release in the rat striatum by phencyclidine-like drugs. J. Pharmacol. Exp. Ther. =,938-946.
SOKOLOVSKY M., GURWMZ D. and GALZON R. (1980) Muscarinic receptor binding in mouse brain: regulation by guanine nucleotides. Biochem. Biophys. Res. Commun. H,487-492. STIRLING J.M., CROSS A.J. and GREEN A.R. (1989) The binding of [3H]-thienyl cyclohexylpiperidine ([3H]-TCP) to the NMDA phencyclidine receptor complex. Neuropharmacology 28, -7.
ULAS J., WEIHMULLER F.B., O’DELL S.J., MARSHALL J.F. and COTMAN C.W. (1994) Chronic blockade of dopamine receptors affects binding to NMDA receptors in rat cortex. Sot. Neurosci. Abs..
WONG E.H.F., KEMP J.A., PRlESTLEY T., KNIGHT A.R. and WOODRUFF G.N. (1986) The anticonvulsant MK-801 is a potent N-methyl-D-aspartate antagonist. Proc. Natl. Acad. Sci. USA &j, 7104-7108.
Inquires and reprint requests should be addressed to: Prof. Ottavio Gandolfi Department of Pharmacology University of Bologna Via Imerio, 48 I-40 126 Bologna, Italy Fax: +39.51.248862
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