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The Journal of Neuroscience, August 1, 2001, 21(15):5546-5558
Dopamine D1 Receptor-Dependent Trafficking of Striatal NMDA
Glutamate Receptors to the Postsynaptic Membrane
Anthone W.
Dunah and
David G.
Standaert
Department of Neurology, Massachusetts General Hospital and Harvard
Medical School, Boston, Massachusetts 02114
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ABSTRACT |
Recent work has shown substantial alterations in NMDA receptor
subunit expression, assembly, and phosphorylation in the
dopamine-depleted striatum of a rodent 6-hydroxydopamine model of
Parkinson's disease. These modifications are hypothesized to result
from the trafficking of NMDA receptors between subcellular
compartments. Here we show that in rat striatal tissues the NR2A and
NR2B subunits in the synaptosomal membrane, and not those in the light
membrane and synaptic vesicle-enriched compartments, are tyrosine
phosphorylated. The dopamine D1 receptor agonist SKF-82958 produces (1)
an increase in NR1, NR2A, and NR2B proteins in the synaptosomal
membrane fraction; (2) a decrease in NR1, NR2A, and NR2B proteins in
the light membrane and synaptic vesicle-enriched fractions; and (3) an
increase in the tyrosine phosphorylation of NR2A and NR2B in the
synaptosomal membrane compartment. The protein phosphatase inhibitor
pervanadate reproduces the alterations in subcellular distribution and
phosphorylation, whereas the effects of the dopamine D1 receptor
agonist are blocked by genistein, a protein tyrosine kinase inhibitor.
Dopamine D1 receptor agonist treatment does not change the subcellular
distribution of the AMPA receptor subunits GluR1 or GluR2/3 in the
striatum and has no effect on cortical or cerebellar NMDA receptor
subunits. These data reveal a rapid dopamine D1 receptor- and tyrosine
kinase-dependent trafficking of striatal NMDA receptors between
intracellular and postsynaptic sites. The subcellular trafficking of
striatal NMDA receptors may play a significant role both in the
pathogenesis of Parkinson's disease and in the development of adverse
effects of chronic dopaminergic therapy in parkinsonian patients.
Key words:
glutamate receptor; NMDA receptor; dopamine receptor; subcellular compartment; receptor trafficking; tyrosine
phosphorylation
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INTRODUCTION |
NMDA glutamate receptors are
heteromeric ligand-gated ion channels assembled from two subunit
families: NR1, which consists of eight recognized isoforms that are
generated from alternative splicing of a single gene, and NR2, composed
of NR2A, NR2B, NR2C, and NR2D, encoded by four distinct genes
(Dingledine et al., 1999 ). In the CNS the properties of NMDA
receptors are determined by their subunit composition, phosphorylation,
and cellular localization. The composition of NMDA receptors
substantially alters the pharmacology of the receptors, in particular
their affinities for agonists and antagonists (Laurie and Seeburg,
1994; Lynch et al., 1994; Williams et al., 1994; Lynch and Gallagher,
1996). Both NR1 and NR2 subunits are phosphorylated; the NR1 subunit
has several serine phosphorylation sites in the carboxy tail region
(Hisatsune et al., 1997; Tingley et al., 1997), whereas the NR2
subunits are phosphorylated at tyrosine residues (Moon et al., 1994;
Lau and Huganir, 1995; Dunah et al., 1998). Phosphorylation modulates the activation and deactivation kinetic properties of NMDA receptors as
well as other properties (Wang and Salter, 1994; Chen and Leonard, 1996). In the brain, NMDA receptors are found both in the cytoplasm of
neurons as well as at excitatory synapses (Petralia et al., 1994). At
the postsynaptic membrane, NMDA receptors interact with components of
the postsynaptic density, a large macromolecular complex containing
both anchoring and signaling elements (Kornau et al., 1995; Kim et al.,
1996; Wyszynski et al., 1997; Ziff, 1997; Lin et al., 1998). The
mechanisms regulating the subcellular localization and targeting of
glutamate receptors to postsynaptic sites are not well defined, but it
is clear that the subcellular distribution of the subunits can be
regulated by neuronal activity (Rao and Craig, 1997; Lissin et al.,
1998; Roche et al., 2000; Zukin et al., 2000; Vissel et al., 2001).
NMDA receptors expressed by neurons in the striatum play an important
role in the regulation of movement as they mediate the effects of
excitatory inputs from the cerebral cortex and thalamus and exhibit
physiologic interactions with dopaminergic input from the nigrostriatal
pathway (Di Chiara et al., 1994). In animal models of Parkinson's
disease, antagonists of NMDA receptors substantially potentiate the
short-term therapeutic effect of dopaminergic agents (Klockgether and
Turski, 1990; Morelli et al., 1992; Papa et al., 1993; Kaur and Starr,
1997) and are effective in attenuating the abnormal motor behaviors
produced by chronic dopaminergic treatment (Papa et al., 1995; Marin et
al., 1996; Blanchet et al., 1997). Recent evidence suggests that the
basis for the development of these abnormal motor behaviors may be that
long-term treatment with dopaminergic agents modifies the properties of
striatal NMDA receptors (Engber et al., 1994; Papa et al., 1995; Marin
et al., 1996; Papa and Chase, 1996; Chase et al., 1998).
Recently, we showed that in rats with unilateral 6-hydroxy-dopamine
(6-OHDA) lesions of the nigrostriatal pathway, which serves as a model
of Parkinson's disease, there is a selective reduction in NMDA
heteromers composed of NR1/NR2B subunits in the synaptosomal membranes
of the dopamine-depleted striatum (Dunah et al., 2000a). In addition,
the serine phosphorylation of NR1 and the tyrosine phosphorylation of
NR2B, but not NR2A, are decreased. The alterations were observed only
in membrane preparations and not in total striatal homogenate,
suggesting a redistribution of NMDA receptor subunits among subcellular
compartments. Chronic treatment of lesioned rats with levodopa
(L-3,4-dihydroxyphenylalanine) normalized the abundance of
the NMDA receptor subunits and increased the phosphorylation of NR1 and
NR2 subunits (Dunah et al., 2000a).
On the basis of these observations we hypothesized that the
dopamine-dependent phosphorylation of striatal NMDA receptors might be
the trigger signal for the trafficking of NMDA receptors from
intracellular compartments to the postsynaptic density. In the present
study, biochemical protein fractionation, quantitative immunoprecipitation, and immunoblot methods were used to examine the
distribution and phosphorylation of NMDA receptors in distinct subcellular compartments of acutely dissected rat striatum and the
effect of treatment with pharmacologic agents affecting dopamine receptors or protein phosphorylation.
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MATERIALS AND METHODS |
Antibodies and pharmacological agents. The
subunit-specific monoclonal NR1 (Luo et al., 1997), polyclonal NR2A
(Wang et al., 1995), and monoclonal NR2B (Wang et al., 1995) antibodies
were generous gifts from Dr. Barry B. Wolfe, Georgetown University (Washington, DC). The polyclonal  -actinin-2 antibody (Wyszynski et
al., 1997) was a kind donation from Dr. Morgan Sheng, Harvard Medical
School (Boston, MA). The following antibodies were obtained from
commercial sources: monoclonal PSD-95 (K28/43; Upstate Biotechnology, Lake Placid, NY); polyclonal NSF (N-ethylmaleimide-sensitive
fusion protein) rabbit serum (Synaptic Systems GmbH, Gottingen,
Germany); polyclonal GluR1 and GluR2/3 (Chemicon, Temecula, CA);
monoclonal syntaxin and synaptophysin (Sigma/RBI, St. Louis, MO/Natick,
MA); monoclonal calnexin (Santa Crux Biotechnology, Santa Cruz, CA); monoclonal anti-phosphotyrosine (PY20) and recombinant
anti-phosphotyrosine monoclonal (RC20) (Transduction Laboratories,
Lexington, KY); horseradish peroxidase-linked goat anti-rabbit and
horseradish peroxidase-linked goat anti-mouse (Jackson ImmunoResearch
Laboratories, West Grove, PA). The drugs used for treatment of striatal
tissues were purchased from the following sources: SKF-82958,
SKF-38393, and quinpirole, Sigma/RBI; genistein, Calbiochem; sodium
orthovanadate, Acros Organics (Geel, Belgium); hydrogen peroxide,
Fisher Scientific (Houston, TX).
Preparation and treatment of dissected rat brain tissues.
Experimental protocols involving the use of vertebrate animals
were approved by the Massachusetts General Hospital Subcommittee on Research Animal Care and met National Institutes of Health guidelines.
The brains of male Sprague Dawley rats weighing 150-200 gm were
removed after decapitation. The striata were dissected and cross-chopped at 200 µM into slices with a McIlwain
mechanical tissue chopper in Krebs' buffer [containing (in
mM) 118 NaCl, 4.7 KCl, 2 CaCl, 1.2 MgSO4, and 1.2 KH2PO4] that had been
equilibrated with 95% O2/5%
CO2. The striatal tissues were incubated in the absence (control) or presence (treatment) of SKF-82958 (50 µM), SKF-38393 (100 µM), quinpirole (100 µM), pervanadate (sodium orthovanadate; 200 µM), or genistein (100 µM) in Krebs'
buffer at 37°C for 10 min with gentle agitation. Tissues were
collected by centrifugation at 700 × g at 4°C and
were subjected to subcellular biochemical fractionation. A stock
solution of the pervanadate was prepared as described previously (Dunah
et al., 1998).
Subcellular fractionation of rat brain tissues. Biochemical
fractionation was performed as described previously (Lin et al., 1998;
Wyszynski et al., 1998) with minor modifications to allow for the
immunoprecipitation of tyrosine-phosphorylated proteins. Dounce
homogenates (H) of the pellets in ice-cold TEVP buffer [containing (in
mM) 10 Tris-HCl, pH 7.4, 5 NaF, 1 Na3VO4, 1 EDTA, and 1 EGTA] containing 320 mM sucrose was centrifuged at
1000 × g to remove nuclei and large debris (P1). The
supernatant (S1) was centrifuged at 10,000 × g to
obtain a crude synaptosomal fraction (P2) and subsequently was lysed
hypo-osmotically and centrifuged at 25,000 × g to
pellet a synaptosomal membrane fraction (LP1). Then the resulting
supernatant (LS1) was centrifuged at 165,000 × g to
obtain a synaptic vesicle-enriched fraction (LP2). Concurrently, the
supernatant (S2) above the crude synaptosomal fraction (P2) was
centrifuged at 165,000 × g to obtain a cytosolic
fraction (S3) and a light membrane/microsome-enriched fraction (P3;
hereafter referred to as light membrane). After each centrifugation the resulting pellet was rinsed briefly with ice-cold TEVP buffer before
subsequent fractionations to avoid possible crossover contamination.
Denaturing conditions of protein solubilization for
phosphorylation studies. The striatal extracts resulting from
subcellular fractionation were solubilized with 1% SDS in TEVP buffer
and centrifuged at 15,000 × g for 5 min in a
microcentrifuge. Protein concentrations in the supernatants were
determined with the Bio-Rad Protein Assay Kit (Hercules, CA) and used
for immunoblot and immunoprecipitation studies.
Precoupling antibodies to protein A-Sepharose. The
monoclonal anti-phosphotyrosine (PY20) antibody was incubated with
protein A-Sepharose beads at a concentration of 20 µg of antibody per 50 µl of hydrated protein A-Sepharose beads for 2 hr at room
temperature in 100 mM sodium borate, pH 8.0, with gentle
rotation. The beads were washed with 100 mM sodium borate,
pH 8.0, and used for immunoprecipitation.
Immunoprecipitation. The solubilized protein samples were
diluted 20-fold with immunoprecipitation buffer [containing (in mM) 150 NaCl, 50 Na3SO4, pH 7.2, and 2 EDTA,
plus 1% sodium deoxycholate and 1%Triton X-100]. The diluted samples
were incubated with 50 µl of the anti-phosphotyrosine
antibody-coupled protein A-Sepharose beads for each 100 µg of protein
for 3 hr in a cold room with gentle rotation. The immunoprecipitates
were washed three times with ice-cold immunoprecipitation buffer after
brief centrifugations and were resuspended in a suitable volume of
loading buffer (62.5 mM Tris-HCl, pH 6.8, 2% SDS, 50 mM DTT, and 7.5% glycerol). Samples were resolved on
SDS-PAGE and immunoblotted for NR1, NR2A, and NR2B proteins.
Gel electrophoresis, quantitative immunoblotting, and statistical
analysis. SDS-PAGE and the transfer of separated proteins to
polyvinylidene difluoride (PVDF) membrane were performed as described
previously (Wang et al., 1995; Dunah et al., 1996; Luo et al., 1996).
For protein separation, 7.5 and 12.5% polyacrylamide gels were used;
the concentration of antibodies used for immunoblotting was 1-2
µg/ml. For the quantification of proteins in subcellular fractionation experiments, equal amounts (10 µg) of protein from each
fraction were loaded into each lane of the gel. For analysis of
tyrosine phosphorylation, 5 µg of each input sample and 40 µg of
the corresponding precipitated pellet were loaded in adjacent lanes on
the same gel. Bands were visualized on film by enhanced chemiluminescence, and their net intensities were quantified via computer-assisted densitometry (Kodak 1-D System, Rochester, NY). The
net intensities of the bands were expressed as a percentage of that in
the control striatum. The resulting values were used to calculate group
means and reported as means ± SEM. Differences between groups
were analyzed by ANOVA with post hoc tests (Scheffe's). For
all of the analyses, statistical significance was taken to be
p < 0.05.
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RESULTS |
Characterization of subcellular compartments
A biochemical fractionation approach (Fig.
1A) was used to isolate
subcellular compartments from brain tissues, and the effectiveness of
the subcellular fractionation procedure was evaluated in the striatum
by the use of protein markers for subcellular compartments (Fig.
1B). Synaptophysin, a synaptic vesicle membrane
protein believed to participate in the fusion of synaptic vesicles to the presynaptic membrane (Devoto and Barnstable, 1987), was found to be
highly concentrated in the synaptic vesicle-enriched fraction (LP2, lane 9). This protein was also present at
lower levels in both the light membrane (P3, lane
5) and synaptosomal membrane (LP1, lane
7) fractions. Syntaxin, a protein that interacts with synaptotagmin and participates in the docking of synaptic vesicles (Bennett et al., 1992; Barinaga, 1993), was enriched in both the light
membrane (P3, lane 5) and synaptic
vesicle-enriched (LP2, lane 9) fractions, whereas
much lower levels were present in the synaptosomal membrane compartment
(LP1, lane 7). The calcium-binding protein
calnexin, known to interact with newly synthesized glycoproteins in
the endoplasmic reticulum (David et al., 1993), was present in the
light membrane compartment (P3, lane
5) but was not detected in the synaptosomal membrane
(LP1, lane 7) and/or synaptic
vesicle-enriched (LP2, lane 9) fractions.
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Figure 1.
Characterization of fractionated subcellular
compartments of the striatum. A, Schematic for the
biochemical fractionation. The procedure for the subcellular separation
of proteins as depicted in this schematic is described in Materials and
Methods. B, Characterization of subcellular
compartments. The isolated biochemical fractions from striatal tissues
were separated by SDS-PAGE, and the blots were probed with antibodies
against synaptophysin (top), syntaxin
(middle), and calnexin (bottom).
Synaptophysin is highly concentrated in the synaptic vesicle-enriched
fraction (LP2, lane 9); syntaxin is
enriched in the light membrane (P3, lane
5) and synaptic vesicle-enriched (LP2,
lane 9) fractions compared with the synaptosomal
membrane (LP1, lane 7); and
calnexin is found in the light membrane fraction (P3,
lane 5), but not in the synaptosomal membrane
(LP1, lane 7) nor synaptic
vesicle-enriched (LP2, lane 9)
fractions.
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Subcellular distribution of NMDA receptor proteins
The expression of NMDA receptor subunits in various subcellular
compartments was investigated in rat striatal tissues that were
homogenized immediately after dissection (Fig. 2). The NR1, NR2A, and
NR2B subunits were found in the light membrane (P3, lane 5), synaptosomal membrane (LP1, lane
7), and synaptic vesicle-enriched (LP2,
lane 9) fractions. As expected, these proteins were also present in the total homogenate (H, lane 1); cell
soma, nuclei, and nuclei-associated membrane (P1, lane
2); crude synaptosomal membrane (P2, lane
3); and the low-speed supernatant (S2, lane 4) fractions; S2 is the parent fraction from which P3 is
derived. However, the NMDA subunits were not detectable in the
cytosolic or soluble subcellular fractions (S3, LS1,
LS2; lanes 6, 8, 10, respectively). In a similar
experiment the subcellular distribution of NMDA receptors in the
cerebral cortex and cerebellum also was investigated (Fig.
2, see cortex and cerebellum). The
localization of NMDA receptor subunits NR1, NR2A, and NR2B in these rat
brain regions was similar to what was observed in the striatum (Fig. 2,
see striatum). As anticipated, the NR2B subunit was not detected in the
rat cerebellum, and this concurs with previous studies showing the
absence of NR2B expression in this region (Monyer et al., 1994; Wang et
al., 1995).
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Figure 2.
NMDA receptor subunits are distributed
differentially between subcellular compartments in the rat
brain. The tissue samples from the striatum, cortex, and cerebellum
were homogenized immediately after dissection, separated into different
biochemical fractions as described in Materials and Methods, and
resolved on SDS-polyacrylamide gels. Total protein (10 µg) from each
fraction was loaded in each lane. The blots were probed with anti-NR1,
anti-NR2A, anti-NR2B, anti-PSD-95, anti--actinin-2,
anti-phosphotyrosine (PY), and anti-NSF
antibodies. H, Total homogenate; P1,
nuclei and large debris; P2, crude synaptosomal
fraction; P3, light membrane fraction;
LP1, synaptosomal membrane fraction; LP2,
synaptic vesicle-enriched fraction. S2, S3, LS1, and
LS2 are supernatants from P2, P3, LP1,
and LP2, respectively. The positions and sizes of
molecular weight markers are indicated in kilodaltons.
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Using the same biochemical fractions, we also examined the subcellular
distribution of postsynaptic density-95 protein (PSD-95) and
-actinin-2, proteins that interact with NMDA receptors;
N-ethylmaleimide-sensitive fusion protein (NSF), a protein
that interacts with AMPA receptors; and total phosphotyrosine (PY)
proteins (Fig. 2). The PSD-95 protein and phosphotyrosine proteins were
confined to the crude extracts and the membrane compartments,
exhibiting a subcellular expression profile similar to the NMDA
subunits, except that PSD-95 and phosphotyrosine proteins were not
detected in the synaptic vesicle-enriched fraction (LP2,
lane 9). -Actinin-2 and NSF showed a wider subcellular distribution, because they were found in both the membrane and cytosolic subcellular fractions of the striatum (Fig. 2). In the cortex
and cerebellum PSD-95, -actinin-2, and NSF showed a subcellular distribution profile similar to that of the striatum (Fig. 2), except
that -actinin-2 expression was found to be very low in the
cerebellum and was detected only in the light membrane fraction (cerebellum; P3, lane 5).
Differential subcellular localization of tyrosine-phosphorylated
NMDA receptor subunits in the rat brain
The tyrosine phosphorylation of NMDA receptors in distinct
striatal compartments was investigated by immunoprecipitating
fractionated protein extracts with anti-phosphotyrosine antibodies and
by immunoblotting samples of the input and pellet for NMDA subunits
(Fig. 3). In accord with previous
studies, tyrosine phosphorylation of NR1 was not detected in any
subcellular compartment (Lau and Huganir, 1995; Dunah et al., 2000a).
However, tyrosine-phosphorylated striatal NR2A and NR2B subunits were
present in the total homogenate (H, lane 2),
nuclei and large debris (P1, lane 4),
crude synaptosomal membrane (P2, lane 6),
and synaptosomal membrane (LP1, lane 14) fractions. Interestingly, the NR2A and NR2B subunits present in the
light membrane (P3, lane 10) and synaptic
vesicle-enriched (LP2, lane 12) fractions of the
striatum did not exhibit detectable tyrosine phosphorylation, even with
longer exposure periods. Similar results were obtained in the cerebral
cortex and cerebellum, except that the NR2B subunit was not detectable
in the cerebellum (Fig. 3, see cortex and cerebellum).
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Figure 3.
NMDA receptors present in the synaptosomal
membrane fraction, but not those in the light membrane and synaptic
vesicle-enriched compartments, are tyrosine phosphorylated. Samples
from rat striatum (top), cortex (middle),
and cerebellum (bottom) were homogenized immediately
after dissection, fractionated, solubilized, and immunoprecipitated
with anti-phosphotyrosine antibody. The inputs (I;
lanes 1, 3, 5, 7, 9, 11, 13, 15, 17, 19; 5 µg) and
pellets (P; lanes 2, 4, 6, 8, 10, 12, 14, 16, 18, 20; 40 µg) were separated on SDS-PAGE gels, and the blots
were probed with anti-NR1, anti-NR2A, and anti-NR2B antibodies.
Tyrosine-phosphorylated NR2A and NR2B subunits were detected in LP1
(lane 13), but not in P3 (lane 10) and
LP2 (lane 18) fractions.
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A dopamine D1 receptor agonist alters the subcellular distribution
and phosphorylation of striatal NMDA receptors
The effect of dopamine receptor activation on the subcellular
localization of NMDA receptors was studied by treating rat striatal tissues with specific agonists. These experiments were performed on
tissues incubated in vitro with the pharmacologic agents for 10 min. This treatment time was selected on the basis of the earlier studies of Snyder et al. (1998). Similar results were obtained by using
a shorter 5 min incubation period (data not shown). The controls for
these experiments were tissues incubated under identical in
vitro conditions without the addition of pharmacologic agents. A
comparison of the data obtained from these control incubations with
those described above from tissues processed immediately after
dissection indicated that the incubation alone did not alter either the
subcellular distribution of the proteins that were examined or the
tyrosine phosphorylation of NR2A and NR2B.
Treatment with SKF-82958, a dopamine D1 receptor full agonist (Figs.
4, 5),
produced significant reductions in the abundance of NR1, NR2A, and NR2B
proteins in the light membrane (Figs. 4A, 5,
P3) fraction (NR1, 28 ± 5%; NR2A, 25 ± 4%;
NR2B, 9 ± 5%; all values expressed as a percentage of control)
and the synaptic vesicle-enriched (Figs. 4A, 5,
LP2) fraction (NR1, 27 ± 4%; NR2A, 32 ± 4%;
NR2B, 15 ± 7%). At the same time there was a marked increase in
NR1 (146 ± 5%), NR2A (150 ± 4%), and NR2B (158 ± 8%) subunits in the synaptosomal membrane (Figs. 4A,
5, LP1) fraction. There were no significant changes in the
relative levels of PSD-95, -actinin-2, and NSF in the different
compartments after SKF-82958 treatment, but there was an apparent
elevation of protein tyrosine phosphorylation, especially in the
synaptosomal membrane (LP1) fraction (Fig. 4A, Table
1).
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Figure 4.
The dopamine D1 receptor agonist SKF-82958
produces subcellular redistribution and an increase in the tyrosine
phosphorylation of striatal NMDA receptors. A,
Subcellular distribution. Samples from tissues that were incubated for
10 min under control conditions (C) or with 50 µM SKF-82958 (S) were subjected to
biochemical fractionation. The subcellular fractions were resolved by
SDS-PAGE, and the blots were probed with NR1, NR2A, NR2B, PSD-95,
-actinin-2, NSF, and anti-phosphotyrosine (PY)
antibodies. SKF-82958 decreased NR1, NR2A, and NR2B in P3 (lane
10) and LP2 (lane 18) fractions; it increased
these subunits in LP1 (lane 14), and it increased
phosphotyrosine proteins (PY). B1,
B2, Tyrosine phosphorylation. The subcellular-fractionated
samples from control (C) and SKF-82958-treated
(S) striatal tissues were immunoprecipitated with
anti-phosphotyrosine antibody and immunoblotted with anti-NR2A and
anti-NR2B. The inputs (I) and pellets
(P) for each biochemical fraction are indicated
across the top of the figure. SKF-82958 increased
tyrosine-phosphorylated NR2A and NR2B in H (lane
4), P1 (lane 8), P2 (lane
12), and LP1 (lane 28) fractions.
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Figure 5.
Densitometric quantification of NMDA receptor
subunit NR1, NR2A, and NR2B proteins in striatal tissues that were
treated with the dopamine D1 receptor agonist SKF-82958 (left
panels) and with a combination of the dopamine D1 receptor
agonist SKF-82958 and a protein tyrosine kinase inhibitor genistein
(right panels). The exposed films from the experiments
depicted in Figures 4A and
10A were scanned and analyzed as described in
Materials and Methods. Values on the ordinate represent
the relative levels of NR1, NR2A, and NR2B proteins given as a
percentage of the control samples. Data are means ± SEM obtained
from three rats. Asterisks indicate significant
differences between treatment and control samples
(p < 0.05, ANOVA). The alteration in the
subcellular distribution of NR1, NR2A, and NR2B subunits produced by
SKF-82958 was blocked by genistein.
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Table 1.
Quantitation of the relative amounts of NR1, NR2A, NR2B,
PSD-95, -actinin-2, and NSF in various subcellular compartments of
the striatum after treatment with pharmacologic agents
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The effect of SKF-82958 treatment on tyrosine phosphorylation of the
NMDA receptors present in the striatal compartments was determined by
precipitating phosphotyrosine proteins from isolated fractions and
probing them with NMDA receptor subunit-specific antibodies (Fig.
4B1,B2, Table
2). SKF-82958 produced an increase in
tyrosine-phosphorylated NR2A and NR2B subunits in the synaptosomal membrane (LP1, lanes 26, 28) compartment to
154 ± 5 and 161 ± 6%, respectively (values expressed as a
percentage of control). A similar increase in tyrosine-phosphorylated
NR2A and NR2B subunits was observed in the total homogenate
(H, lanes 2, 4), nuclei and large debris
(P1, lanes 6, 8), and crude synaptosomal membrane (P2, lanes 10, 12) fractions (Fig.
4B1, Table 2). Tyrosine-phosphorylated NR2A and
NR2B subunits were not detected in the light membrane (P3, lanes 18, 20) and synaptic vesicle-enriched
(LP2, lanes 34, 36) fractions (Fig.
4B1,B2).
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Table 2.
Quantitation of tyrosine-phosphorylated NMDA receptor
subunits NR2A and NR2B in striatal subcellular compartments after
treatment with pharmacologic agents
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Similar experiments were performed with rat cortical and cerebellar
tissues. Treatment of these tissues with SKF-82958 produced no apparent
alterations in the subcellular distribution of NR1, NR2A, or NR2B
subunits. The tyrosine phosphorylation of these NMDA subunits in the
various subcellular compartments of the cortex and cerebellum also was
unchanged after treatment with the dopamine D1 receptor agonist (data
not shown).
In another experiment SKF-38393, a partial agonist of the dopamine D1
receptor, was used to treat striatal tissues. With this pharmacologic
agent there was no alteration in the subcellular distribution (Table 1)
or tyrosine phosphorylation (Table 2) of striatal NMDA receptors.
Similarly, the effects of quinpirole, a dopamine D2 receptor agonist
also were examined, and quinpirole produced no significant changes in
the subcellular localization of NR1, NR2A, and NR2B receptors (Fig.
6A, Table 1) or the
phosphorylation of NR2A and NR2B subunits at tyrosine residues (Fig.
6B1,B2, Table 2).
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Figure 6.
The dopamine D2 receptor agonist quinpirole does
not alter the subcellular distribution and tyrosine phosphorylation of
striatal NMDA receptors. A, Subcellular distribution.
Samples from tissues that were incubated for 10 min under control
conditions (C) or with 100 µM
quinpirole (a dopamine D2 receptor agonist; Q) were
separated into subcellular fractions and subjected to electrophoresis
on SDS-polyacrylamide gels. The blots were probed with NR1, NR2A, NR2B,
PSD-95, -actinin-2, NSF, and anti-phosphotyrosine
(PY) antibodies. There were no significant
differences in the subcellular distribution of the analyzed proteins
between control and quinpirole-treated samples. B1, B2,
Tyrosine phosphorylation. Striatal tissues from control
(C) and quinpirole-treated
(Q) samples were solubilized and precipitated
with anti-phosphotyrosine antibody. The inputs
(I) and pellets (P)
are indicated across the top of the figure. The
resulting blots were immunoblotted for the NR2A and NR2B subunits.
Quinpirole had no apparent effect on the tyrosine phosphorylation of
NR2A and NR2B subunits.
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Dopamine D1 receptor agonist does not alter the subcellular
distribution or phosphorylation of striatal AMPA receptors
The effect of the dopamine D1 receptor agonist SKF-82958 on the
subcellular localization and phosphorylation of striatal AMPA receptor
subunits GluR1 and GluR2/3 was investigated (Fig.
7). In control tissues (Fig.
7A, lanes designated C) the AMPA receptor subunits exhibited a distribution profile similar to that of the NMDA
receptor subunits in that they were abundant in the synaptosomal membrane (LP1) but also were found in the light membrane (P3) and
synaptic vesicle-enriched (LP2) fractions (Fig. 7A). Like the NMDA receptors, the GluR1 and GluR2/3 subunits found in the synaptosomal membrane (LP1) fraction were tyrosine phosphorylated, whereas those present in the light membrane (P3) and synaptic vesicle-enriched (LP2) fractions were not phosphorylated (Fig. 7B1,B2). Interestingly, treatment with SKF-82958 produced no
alterations in either the subcellular distribution (Fig. 7A)
or the tyrosine phosphorylation of the GluR1 and GluR2/3 subunits (Fig.
7B1,B2).
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Figure 7.
The dopamine D1 receptor agonist SKF-82958 had no
effect on the subcellular distribution and tyrosine phosphorylation of
striatal AMPA receptors. A, Subcellular distribution.
Fractionated striatal tissues that were incubated for 10 min under
control conditions (C) or with 50 µM SKF-82958 (S) were resolved by
SDS-PAGE, and the blots were probed with antibodies specific for GluR1
and GluR2/3. SKF-82958 had no apparent effect on the subcellular
distribution of GluR1 and GluR2/3 subunits. B1, B2,
Tyrosine phosphorylation. The fractionated striatal samples were
precipitated with anti-phosphotyrosine antibody and immunoblotted for
GluR1 and GluR2/3. The inputs (I) and
pellets (P) are indicated across the
top of the figure. SKF-82958 produced no changes in the
tyrosine phosphorylation of GluR1 or GluR2/3.
|
|
Inhibition of protein phosphatases alters the subcellular
localization and phosphorylation of striatal NMDA receptors
To determine whether enhanced protein phosphorylation was
sufficient to produce a redistribution of NMDA receptor subunits among
subcellular compartments, we treated striatal tissues with pervanadate, a protein phosphatase inhibitor. Both control and treated
tissues were fractionated and immunoblotted for NMDA receptors as well
as for PSD-95, -actinin-2, NSF, and phosphotyrosine proteins (Fig.
8A). Pervanadate
produced marked reductions in the levels of NR1, NR2A, and NR2B found
in the light membrane (P3) fraction (NR1, 11 ± 6%; NR2A, 6 ± 5%; NR2B, 2 ± 4%) and synaptic vesicle-enriched (LP2)
fraction (NR1, 21 ± 5%; NR2A, 17 ± 6%; NR2B, 11 ± 5%) and a concomitant increase in NR1 (165 ± 5%), NR2A
(142 ± 4%), and NR2B (179 ± 5%) in the synaptosomal
membrane (LP1) fraction. There were no significant changes in the
subcellular distribution of PSD-95, -actinin-2, and NSF (Fig.
8A, Table 1).
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Figure 8.
The protein phosphatase inhibitor pervanadate
induces subcellular redistribution and an increase in tyrosine
phosphorylation of striatal NMDA receptors. A,
Subcellular distribution. Striatal samples from tissues that were
incubated for 10 min under control conditions (C)
or with 200 µM pervanadate (P) were
fractionated and resolved on SDS-PAGE gels. The blots were probed with
NR1, NR2A, NR2B, PSD-95, -actinin, NSF, and anti-phosphotyrosine
(PY) antibodies. Similar to the effects produced
by SKF-82958, pervanadate reduced the levels of NR1, NR2A, and NR2B in
P3 (lane 10) and LP2 (lane 18); it
increased the levels of these NMDA subunits in LP1 (lane
14) and markedly increased phosphotyrosine proteins
(PY). B1, B2, Tyrosine
phosphorylation. Samples from the subcellular-fractionated control
(C) and pervanadate-treated
(P) striatal tissues were immunoprecipitated with
anti-phosphotyrosine antibody. The inputs
(I) and pellets (P)
were electrophoresed and probed for NR2A and NR2B subunits. Tyrosine
phosphorylation of NR2A and NR2B was increased in H (lane
4), P1 (lane 8), P2 (lane
12), and LP1 (lane 28).
|
|
As shown in Figure 8B2 and Table 2, the treatment of
striatal tissues with pervanadate also produced an increase in the
tyrosine phosphorylation of the NR2A (183 ± 7%) and NR2B
(181 ± 5%) subunits present in the synaptosomal membrane (LP1)
fraction. However, even under this condition no tyrosine
phosphorylation of the NR2A and NR2B subunits remaining in the light
membrane (P3) and synaptic vesicle-enriched (LP2) fractions was
detected (Fig. 8B1,B2). This finding was particularly
striking when compared with the marked enhancement of tyrosine
phosphorylation of proteins other than the NR2A and NR2B subunits in
the P3 fraction (Fig. 8A, lane 10).
Blockade of the effects of dopamine D1 receptor activation
on NMDA receptors by a protein tyrosine kinase inhibitor
To examine the role of tyrosine phosphorylation in the subcellular
redistribution of NMDA receptors after treatment with the dopamine D1
receptor agonist SKF-82958, we pretreated striatal tissues with the
protein tyrosine kinase inhibitor genistein. Treatment of striatal
tissues with genistein alone produced an apparent decrease in protein
tyrosine phosphorylation, especially in the synaptosomal membrane
fraction (Fig. 9A, PY,
LP1). There was no alteration in the relative levels of NR1, NR2A,
or NR2B in the subcellular compartments that were examined (Fig.
9A, Table 1). There was, however, an apparent decrease in
the tyrosine phosphorylation of NR2A and NR2B in each of the
subcellular fractions that contained these subunits (Fig.
9B1,B2).
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Figure 9.
The protein tyrosine kinase inhibitor genistein
does not change the subcellular distribution of striatal NMDA receptors
but decreases the tyrosine phosphorylation of NR2A and NR2B.
A, Subcellular distribution. Fractions from striatal
tissues that were incubated for 10 min under control conditions
(C) or with 100 µM genistein
(G) were electrophoresed on
SDS-polyacrylamide gels, and the blots were probed with NR1, NR2A,
NR2B, PSD-95, -actinin-2, NSF, and anti-phosphotyrosine
(PY) antibodies. The subcellular localizations of
NMDA receptor subunits and the other proteins that were studied were
not changed by genistein, but there were reductions in total
phosphotyrosine proteins (PY). B1,
B2, Tyrosine phosphorylation. The fractionated samples from
control (C) and genistein-treated
(G) striatal tissues were immunoprecipitated by
using anti-phosphotyrosine antibody and were immunoblotted with
anti-NR2A and anti-NR2B antibodies. The inputs
(I) and pellets (P)
are indicated across the top of the figure. Genistein
decreased the tyrosine phosphorylation of NR2A and NR2B in H
(lane 4), P1 (lane 8), P2
(lane 12), and LP1 (lane 28).
|
|
In the striatal tissues that were treated with the dopamine D1 receptor
agonist SKF-82958 in the presence of genistein, the changes that were
observed in the subcellular distribution of NMDA subunits after
treatment with the dopamine D1 receptor agonist alone were no longer
apparent (Figs. 5,
10A). The abundance
of each of the NMDA subunits in the light membrane (P3), synaptosomal membrane (LP1), and synaptic vesicle-enriched (LP2) compartments was
identical in control samples and in the samples that were treated with
a combination of SKF-82958 and genistein (Fig. 10A, Table 1). In addition, genistein blocked the increase in tyrosine phosphorylation of NR2A and NB2B in each subcellular compartment that
was investigated (Fig. 10B1,B2, Table 2).
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Figure 10.
The dopamine D1 receptor agonist-induced
alterations in subcellular distribution and tyrosine phosphorylation of
striatal NMDA receptors are inhibited by the protein tyrosine kinase
inhibitor genistein. A, Subcellular distribution.
Samples from tissues that were incubated for 10 min under control
conditions (C) or with 50 µM
SKF-82958 and 100 µM genistein (B)
were subjected to subcellular fractionation. The proteins were
separated on SDS-PAGE, and the blots were probed with antibodies
against NR1, NR2A, NR2B, PSD-95, -actinin-2, NSF, and
phosphotyrosine proteins (PY). In the presence of
genistein, SKF-82958 produced no alteration in the distribution of NMDA
receptor subunits. B1, B2, Tyrosine phosphorylation.
Solubilized control (C) and treated samples
(B) were immunoprecipitated with
anti-phosphotyrosine antibody, and the blots were probed with NR2A and
NR2B antibodies. The inputs (I) and
pellets (P) are indicated across the
top of the figure. Genistein inhibited the increase in
tyrosine phosphorylation of NR2A and NR2B produced by the dopamine D1
receptor agonist SKF-82958.
|
|
| |
DISCUSSION |
The NR1, NR2A, and NR2B subunits in the striatum are confined to
biochemical fractions containing cellular membranes, particularly the
synaptosomal membrane (LP1), synaptic vesicle-enriched (LP2), and light
membrane (P3) compartments. Tyrosine-phosphorylated NR2A and NR2B
subunits are found only in the synaptosomal membrane fraction and not
in the light membrane and synaptic vesicle-enriched fractions. The
dopamine D1 receptor agonist produces a rapid alteration in the
distribution of NR1, NR2A, and NR2B proteins, with a reduction in these
subunits in the light membrane and synaptic vesicle-enriched compartments and an increase in the synaptosomal membranes. These changes in subcellular distribution are accompanied by an increase in
tyrosine phosphorylation of the NR2A and NR2B present in synaptosomal membranes. The alterations in the distribution and phosphorylation of
NMDA receptors produced by SKF-82958 are abolished by a protein tyrosine kinase inhibitor and mimicked by a protein phosphatase inhibitor. These observations reveal the existence of a rapid dopamine-dependent mechanism for intracellular trafficking of striatal
NMDA receptors and reveal that these effects are mediated via a
tyrosine kinase-dependent mechanism.
Subcellular distribution of NMDA receptors and associated
proteins in the striatum
In the rat striatum, cortex, and cerebellum the NMDA subunits NR1,
NR2A, and NR2B are present in three membrane-associated compartments
(LP1, LP2, and P3) and were undetected in cytosolic fractions. This is
consistent with anatomical studies showing that NMDA receptor proteins
are present both at postsynaptic sites and in intracellular locations,
where they often are associated with membranous structures (Petralia et
al., 1994). The LP1 fraction contains postsynaptic density, an
organized cytoskeletal structure located within the postsynaptic neuron
at sites of excitatory synapses that contain both NMDA and non-NMDA
glutamate receptors, and a variety of other proteins involved in
receptor anchoring, signaling, and modulation (Kennedy, 1993; Ziff,
1997). The LP2 contains synaptic vesicles and other vesicles that
function as trafficking organelles for several membrane proteins,
including neurotransmitter receptors (Sudhof, 1995; Takamori et al.,
2000), whereas P3 contains cellular organelles that include endoplasmic reticulum, Golgi apparatus, and synaptic mitochondria (Schapira, 1998).
The PSD-95, an integral component of the postsynaptic density, was
highly concentrated in the synaptosomal membrane (LP1) fraction but was
absent in the cytosolic and synaptic vesicle-enriched (LP2)
compartments. In contrast, -actinin-2 was found in both membrane-associated and cytosolic compartments. Both proteins are known
to link NMDA receptors physically and functionally to the postsynaptic
density (Kornau et al., 1995; Wyszynski et al., 1998), although our
recent report revealed that only a minor but perhaps functionally
significant fraction of the -actinin-2 present in rat striatum is
bound directly to NMDA receptors (Dunah et al., 2000b).
Trafficking of NMDA receptors from intracellular compartments to
the synaptic membrane
Mounting evidence suggests that the activities of the
striatum are regulated by complex interactions between dopamine and NMDA receptors (Di Chiara et al., 1994; Cepeda and Levine, 1998; Schoffelmeer et al., 2000). We found that the dopamine D1 receptor agonist SKF-82958 produced a rapid redistribution of NMDA subunits among subcellular compartments of the striatum. This process of receptor redistribution appears to be specific for the NMDA subunits, because the AMPA receptor subunits GluR1 and GluR2/3, as well as PSD-95
and -actinin-2, proteins that interact with NMDA receptors (Kornau
et al., 1995; Wyszynski et al., 1998), and NSF, a protein that binds to
AMPA receptors (Nishimune et al., 1998; Osten and Ziff, 1999), were not
altered. In addition, the effect of the dopamine D1 agonist on NMDA
receptor distribution and phosphorylation was not observed in either
the cerebral cortex or the cerebellum. This may result from the
existence of a lower density of D1 dopamine receptors in the cortex and
the virtual lack of expression of these receptors in the cerebellum (De
Keyser, 1993; Sealfon and Olanow, 2000). However, it is also possible
that there are unique anatomical and structural properties of striatal
neurons that are required for this interaction of glutamatergic and
dopaminergic transmission (Cepeda and Levine, 1998; Schoffelmeer et
al., 2000).
We propose that the alterations in subcellular distribution reflect the
dopamine D1 receptor-induced trafficking of NR1, NR2A, and NR2B
proteins from the light membrane and synaptic vesicle-enriched compartments to the synaptic membranes (Fig.
11). Because we analyzed only the total
receptor proteins in each compartment and did not follow individual
subunits directly over time, the involvement of a more complex
mechanism of subcellular redistribution of receptors cannot be
excluded. For instance, the observed changes could arise from enhanced
degradation of the NMDA receptors in the light membrane and synaptic
vesicle-enriched compartments, together with the insertion of receptors
into the synaptic membranes from other sources that are not
identifiable by the present experimental approach.
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Figure 11.
Model for the trafficking of NMDA receptors at
the corticostriatal synapse. Illustrated is a dendritic spine of a
striatal projection neuron receiving input from a cortical axon, using
glutamate as a transmitter (Glu) at the head of the
spine, and from a nigrostriatal axon, using dopamine
(DA) as a transmitter and forming a synapse on the shaft
of the spine. The effects of glutamate are mediated by NMDA, AMPA, and
metabotropic glutamate receptors (mGluR). These are
linked to each other and to additional signaling molecules via the
proteins of the postsynaptic density (PSD). Dopaminergic
inputs are mediated by the dopamine D1 and D2 receptors. These
receptors have reciprocal effects on the formation of cAMP by adenylyl
cyclase (AC), but most striatal neurons express a
preponderance of a single dopamine receptor type, depending on whether
they contribute to the direct or indirect pathways. In addition to the
NMDA receptors that are present at the excitatory synapse, our data
suggest that there is a pool of assembled receptors within
intracellular vesicular compartments. The vesicle-associated receptors
are characterized by the absence of tyrosine (Y)
phosphorylation of the NR2A and NR2B subunits. Activation of dopamine
D1 receptors leads (via mechanisms that are not well defined) to
tyrosine phosphorylation of the vesicular NMDA receptor subunits by a
tyrosine kinase [perhaps a member of the src family reported to
phosphorylate NMDA subunits at tyrosine residues (Suzuki and
Okumura-Noji, 1995)] and insertion of the receptors into the synaptic
membrane. There is also a tonically active tyrosine phosphatase, which
may be a member of the STEP family. The diagram also illustrates the
serine (S) phosphorylation of the NR1 subunit,
which is regulated both by the direct action of cAMP on protein kinase
A (PKA) as well as by the DARPP-32 pathway;
phosphorylation of DARPP-32 by PKA inhibits the dephosphorylation of
NR1 by protein phosphatase-1 (PP-1; Snyder et al.,
1998). Although protein kinase C has been reported to modulate the
trafficking of NMDA receptors (Lan et al., 2001), the precise role of
cAMP in the phosphorylation of NMDA subunits at tyrosine residues is
not known. At present it is also uncertain whether serine
phosphorylation plays a role in the trafficking of NMDA receptors at
the corticostriatal synapse.
|
|
Recent studies have provided ample evidence that redistribution is an
important mechanism for regulating AMPA receptors. Both synaptic
activity and the increased activity of calcium calmodulin-dependent protein kinase II can rapidly induce the trafficking of GFP-tagged GluR1 receptors to the postsynaptic membrane (Shi et al., 1999; Hayashi
et al., 2000). The recruitment of GluR1 receptors to the postsynaptic
density has been found to increase AMPA receptor-mediated synaptic
transmission in long-term potentiation (Hayashi et al., 2000).
Similarly, insulin causes GABAA receptors to
translocate rapidly from intracellular compartments to the plasma
membrane, an effect probably mediated by phosphorylation of the
receptors at tyrosine residues (Wan et al., 1997). Use-dependent
downregulation of NMDA receptors appears to involve a clathrin-mediated
process of endocytosis (Vissel et al., 2001), and activators of protein kinase C, including insulin, recruit new NMDA receptors to the cell
surface via a process involving vesicular trafficking (Lan et al.,
2001; Scott et al., 2001; Skeberdis et al., 2001).
Striatal NMDA receptor trafficking requires
tyrosine phosphorylation
Our findings directly implicate tyrosine phosphorylation in the
subcellular redistribution of striatal NMDA receptors. Consistent with
previous reports (Moon et al., 1994; Lau et al., 1995; Dunah et al.,
1998), the NR2A and NR2B subunits, but not NR1, in striatum were found
to be tyrosine-phosphorylated. After analysis of specific subcellular
compartments, tyrosine-phosphorylated NR2A and NR2B subunits in the
synaptosomal membrane, but not in the light membrane and synaptic
vesicle-enriched fractions, were detected. Treatment with the dopamine
D1 agonist SKF-82958 produced an increase in tyrosine-phosphorylated
NR2A and NR2B in the synaptosomal membrane fraction. This effect was
mimicked by pervanadate, a nonspecific inhibitor of protein
phosphatases, which also increased the tyrosine phosphorylation of many
membrane-associated proteins. Interestingly, even after a pharmacologic
blockade of protein phosphatases, tyrosine phosphorylation of NR2A or
NR2B in the light membrane or synaptic vesicle-enriched fractions was
not observed. The effects of SKF-82958 on both subcellular distribution
and tyrosine phosphorylation of NR2A and NR2B were blocked by
genistein, a protein tyrosine kinase inhibitor.
We suggest, therefore, that tyrosine phosphorylation of the pool of
NR2A and NR2B receptors in the light membrane and synaptic vesicle-enriched fractions functions as a trigger for the
redistribution of these subunits from intracellular compartments to the
synaptosomal membrane. This phenomenon would account for the rapidity
of subcellular redistribution of the receptors and the inability to
detect tyrosine-phosphorylated NR2A and NR2B in the light membrane and
synaptic vesicle-enriched fractions. The inhibition of protein
phosphatases with orthovanadate triggers redistribution, suggesting the
existence of a tonically active phosphatase activity. Interestingly,
genistein can block the effect of dopamine D1 receptor activation but
does not alter the basal distribution of the receptor subunits in the
10 min time period that was studied, suggesting that constitutive
trafficking of subunits to the synaptosomal membrane is either a much
slower process or uses a different tyrosine kinase-independent mechanism.
The regulatory steps between the activation of dopamine D1 receptors
and the tyrosine phosphorylation of NR2A and NR2B subunits are
understood incompletely. In other systems, however, members of the src
family of protein tyrosine kinases, in particular the fyn kinases, have
been shown to phosphorylate NMDA subunits (Gurd, 1985; Moon et al.,
1994; Suzuki and Okumura-Noji, 1995), and this resulted in increased
channel activity of the receptors (Köhr and Seeburg, 1996); fyn
kinase knock-out mice have been reported to be deficient in certain
forms of long-term potentiation (Grant et al., 1992). The striking
increase in NR2A and NR2B tyrosine phosphorylation with pervanadate
suggests tonic activity of a protein phosphatase in the striatum.
Potential candidates for this role are the striatal-enriched
phosphatases (STEP), which are abundant in striatal neurons and are
found in association with NMDA receptor subunits (Boulanger et al.,
1995).
There is evidence for a dopamine-regulated phosphorylation of the NR1
subunit at serine residues regulated by the phosphoprotein DARPP-32
(dopamine and cAMP-regulated phosphoprotein; Snyder et al., 1998).
Phosphorylation at serine890, but not at
serine896 or
serine897, produced a redistribution of
NR1 receptors from intracellular sites to the cell surface (Tingley et
al., 1997). Thus, serine phosphorylation of the NR1 subunit in these
receptor complexes may have a role in the trafficking of striatal NMDA
receptors, but the ability of genistein to block receptor
redistribution suggests that tyrosine phosphorylation is essential to
this phenomenon.
NMDA receptor trafficking and parkinsonism
The present findings complement earlier studies of
dopamine-dependent modifications of NMDA receptors from our laboratory and others (Oh et al., 1998; Dunah et al., 2000a). In a previous study
we analyzed the biochemical properties of striatal NMDA receptors in a
rat model of unilateral 6-OHDA depletion. At 14 d postlesion we
found significant reductions in NR1 and NR2B in the synaptosomal
membranes, and treatment with levodopa for 21 d normalized both
subunits (Dunah et al., 2000a). Although this in vivo study
was performed over a longer time period, both the magnitude and
direction of subcellular distribution of NMDA receptors are comparable
with the results that have been described in the present study.
Dopamine-dependent alterations in NMDA subunits, particularly the
increased association of these receptors with corticostriatal synapses,
may underlie the adverse motor effects that have been observed in
patients with Parkinson's disease treated with dopaminergic drugs,
which are the primary sources of ongoing disability in this
neurodegenerative disease. The development of approaches targeted at
modifying the trafficking of NMDA receptors in the striatum may prove
to be useful in the treatment of Parkinson's disease.
| |
FOOTNOTES |
Received March 19, 2001; revised May 8, 2001; accepted May 15, 2001.
This work was supported by National Institutes of Health Grant NS34361
(D.G.S.) and a grant from The National Parkinson Foundation (A.W.D.).
We thank Dr. Barry B. Wolfe for the generous gifts of NR1, NR2A, and
NR2B antibodies; Dr. Morgan Sheng for the kind donation of
-actinin-2 antibody; and Dr. Michael Wyszynski for very helpful
comments on this manuscript.
Correspondence should be addressed to Dr. David G. Standaert,
Massachusetts General Hospital, CNY B114-2000, Charlestown, MA
02129-4404. E-mail: standaert{at}helix.mgh.harvard.edu.
| |
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pl8 - pl8.
[Abstract]
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L. Chen and C. R. Yang
Interaction of Dopamine D1 and NMDA Receptors Mediates Acute Clozapine Potentiation of Glutamate EPSPs in Rat Prefrontal Cortex
J Neurophysiol,
May 1, 2002;
87(5):
2324 - 2336.
[Abstract]
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TOP
ABSTRACT
INTRODUCTION
