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The Journal of Neuroscience, April 1, 1998, 18(7):2475-2485
Multiple Signaling Pathways Regulate Cell Surface Expression and
Activity of the Excitatory Amino Acid Carrier 1 Subtype of Glu
Transporter in C6 Glioma
Karen E.
Davis1,
Dean
J.
Straff3,
Edward A.
Weinstein2,
Peter G.
Bannerman3,
Dana M.
Correale3,
Jeffrey D.
Rothstein4, and
Michael B.
Robinson2, 3
Departments of 1 Neuroscience,
2 Pharmacology, and 3 Pediatrics, Children's
Hospital of Philadelphia, Children's Seashore House, University of
Pennsylvania, Philadelphia, Pennsylvania 19104, and
4 Department of Neurology, The Johns Hopkins University,
Baltimore, Maryland 21287
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ABSTRACT |
Neuronal and glial sodium-dependent transporters are crucial for
the control of extracellular glutamate levels in the CNS. The
regulation of these transporters is relatively unexplored, but the
activity of other transporters is regulated by protein kinase C (PKC)-
and phosphatidylinositol 3-kinase (PI3K)-mediated trafficking to and
from the cell surface. In the present study the C6 glioma cell line was
used as a model system that endogenously expresses the excitatory amino
acid carrier 1 (EAAC1) subtype of neuronal glutamate transporter. As
previously observed, phorbol 12-myristate 13-acetate (PMA) caused an
80% increase in transporter activity within minutes that cannot be
attributed to the synthesis of new transporters. This increase in
activity correlated with an increase in cell surface expression of
EAAC1 as measured by using a membrane-impermeant biotinylation reagent.
Both effects of PMA were blocked by the PKC inhibitor
bisindolylmaleimide II (Bis II). The putative PI3K inhibitor,
wortmannin, decreased L-[3H]-glutamate
uptake activity by >50% within minutes. Wortmannin decreased the
Vmax of
L-[3H]-glutamate and
D-[3H]-aspartate transport, but it did
not affect Na+-dependent
[3H]-glycine transport. Wortmannin also decreased
cell surface expression of EAAC1. Although wortmannin did not block the
effects of PMA on activity, it prevented the PMA-induced increase in
cell surface expression. This trafficking of EAAC1 also was examined
with immunofluorescent confocal microscopy, which supported the
biotinylation studies and also revealed a clustering of EAAC1 at cell
surface after treatment with PMA. These studies suggest that the
trafficking of the neuronal glutamate transporter EAAC1 is regulated by
two independent signaling pathways and also may suggest a novel
endogenous protective mechanism to limit glutamate-induced
excitotoxicity.
Key words:
glutamate transport; EAAC1; excitatory amino acid; protein kinase C; phosphatidylinositol 3-kinase; trafficking; C6
glioma
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INTRODUCTION |
A major mechanism for the clearance
of glutamate from the synapse involves a family of sodium-dependent
high-affinity glutamate transporters, including the neuronal
transporters excitatory amino acid carrier 1 (EAAC1) (Kanai and
Hediger, 1992 ) and excitatory amino acid transporter 4 (EAAT4) (Fairman
et al., 1995), the glial transporters Glu-Asp transporter (GLAST)
(Storck et al., 1992) and Glu transporter-1 (GLT-1) (Pines et al.,
1992), and the recently identified retinal transporter EAAT5 (Arriza et
al., 1997). Several studies have suggested that these transporters play
a critical role in the prevention of glutamate-mediated excitotoxic
injury by tightly regulating the levels of extracellular glutamate
under normal circumstances (Rosenberg et al., 1992; Rothstein et al., 1996) (for review, see Robinson and Dowd, 1997). The dysfunction or
loss of these transporters may contribute to neurodegenerative diseases
such as amyotrophic lateral sclerosis (ALS) or hypoxic/ischemic insults
(Rothstein et al., 1995; Tanaka et al., 1997). Because these
transporters may play a critical role in maintaining glutamate homeostasis in the CNS, the cellular regulation of these transporters is of considerable interest.
Phorbol esters such as phorbol 12-myristate 13-acetate (PMA) stimulate
GLT-1-mediated transport activity. This stimulation has been attributed
to an increase in direct phosphorylation and a corresponding increase
in the catalytic rate of transporter activity by protein kinase C (PKC)
(Casado et al., 1993). In a recent study we developed evidence that PMA
rapidly upregulates EAAC1-mediated transport activity (Dowd and
Robinson, 1996). The rapid increase in glutamate uptake caused by PMA
suggests two possible mechanisms of regulation: an increase in the
catalytic rate of transporter activity and/or an increase in the number of transporters available on the cell surface to transport
glutamate.
Recent evidence indicates that the activity of several transporters is
regulated by second messenger-mediated trafficking to and from the cell
surface. Glucose transporters belong to an unrelated transporter
family, the activity of which is regulated by insulin and phorbol
esters. Treatment of adipocytes with PMA causes an approximately
twofold increase in glucose uptake activity, which is blocked by a PKC
inhibitor (Nishimura and Simpson, 1994) and by wortmannin, a fungal
metabolite that has been reported to inhibit phosphatidylinositol
3-kinase (PI3K) (Clarke et al., 1994; Navé et al., 1996) (for
review, see Nakanishi et al., 1995). Insulin and phorbol esters also
cause a redistribution of glucose transporters from a subcellular
compartment to the cell membrane, a phenomenon that is blocked by PKC
and PI3K inhibitors (Clarke et al., 1994; Holman and Cushman, 1994;
James and Piper, 1994; Nishimura and Simpson, 1994; Navé et al.,
1996). Recent studies of the serotonin and GABA neurotransmitter
transporters, which belong to a distinct gene family, indicate that
these transporters also are translocated to and from the cell surface
in response to treatment with phorbol esters and exhibit concomitant
changes in uptake activity (Qian et al., 1997; Quick et al., 1997). The effects of phorbol esters on these transporters are blocked by the PKC
inhibitors bisindolylmaleimide or staurosporine. Because PMA appears to
regulate the activity and trafficking of serotonin, glucose, and GABA
transporters in several different systems, it is possible that the
mechanisms of these effects may be conserved between transporter
families. The goal of the present study was to determine whether the
regulation of EAAC1 activity in C6 glioma is mediated by the PKC and/or
the PI3K pathways and whether this regulation involves changes in
trafficking of the transporter to and from the cell surface.
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MATERIALS AND METHODS |
Materials. DMEM, L-glutamine,
penicillin/streptomycin, and normal goat serum were purchased from Life
Technologies (Grand Island, NY). Fetal bovine serum was purchased from
HyClone (Logan, UT). Twelve-well tissue culture plates and 10 cm tissue
culture plates were manufactured by Corning (Corning, NY). All
radioisotopes were obtained from DuPont/New England Nuclear (Boston,
MA), and the specific activity was diluted with nonradioactive
L-Glu, D-Asp, or glycine from Sigma (St. Louis,
MO). Wortmannin, bisindolylmaleimide II, phorbol 12,13-dibutyrate, and
4 -phorbol were purchased from Calbiochem (La Jolla, CA). PMA,
diamidino-2-phenylindole dihydrochloride hydrate (DAPI), anti-actin
antibody, and dimethylsulfoxide (DMSO) were purchased from Sigma.
Sulfo-NHS-biotin and Immunopure Immobilized Monomeric Avidin were
purchased from Pierce (Rockford, IL). Fluorescent antibodies were
purchased from Jackson ImmunoResearch (West Grove, PA), and Vectashield
mounting medium was obtained from Vector Laboratories (Burlingame,
CA).
Measurement of Na+-dependent transport
activity. The transport assays in C6 glioma were performed as
described (Dowd and Robinson, 1996). C6 glioma cells were obtained from
American Type Culture Collection (Rockville, MD). Cells were grown in a
monolayer on 12-well plates in DMEM supplemented with 10% fetal bovine
serum, 2 mM glutamine, and penicillin (100 U/ml)/streptomycin (100 µg/ml) and maintained at 37°C in a 5%
CO2 incubator. After cells reached ~80% confluency,
drugs or vehicle was added to the medium, and the plates were returned
to the incubator until the assay was performed.
Assays were conducted in a 37°C water bath with the wells partially
submerged to maintain 37°C surrounding the cells. The wells were
rinsed twice with 1 ml of either warm sodium- or choline-containing buffer and then incubated with radioisotopes for 5 min (0.5 µM L-[3H]-Glu,
D-[3H]-Asp, or
[3H]-Gly). Radioactive uptake was stopped with
three rinses in ice-cold choline buffer. Then cells were solubilized in
1 ml of 0.1N sodium hydroxide, and 500 µl of lysate was analyzed for
radioactivity in a scintillation counter.
Na+-dependent uptake was defined as the difference
in radioactivity accumulated in Na+-containing
buffer and in choline-containing buffer. Under these conditions the
uptake is linear with time, >90% is Na+-dependent
at 0.5 µM glutamate, and <10% of the substrate is
accumulated. Protein content was measured to ensure that any treatments
applied to the wells were not altering the protein content of the wells (Lowry et al., 1951).
Biotinylation. Biotinylation of cell surface proteins was
performed as described in Qian et al. (1997) and Sargiacomo et al. (1989), with slight modifications. Briefly, C6 glioma cells were grown
in a monolayer on 10 cm tissue culture plates until they were at least
80% confluent. Plates were rinsed twice with warm PBS with 0.1 mM calcium and 1.0 mM magnesium added
(PBS-Ca/Mg). Then the plates were incubated with 2 ml of biotin
solution (sulfo-NHS-biotin, 1 mg/ml in PBS-Ca/Mg) for 20 min at
4°C with gentle shaking. The biotin solution was removed, and the
plates were washed twice with PBS-Ca/Mg containing 100 mM
glycine. The plates were incubated in PBS-Ca/Mg plus glycine for 45 min at 4°C with gentle agitation to quench any unbound biotin. Then
the cells were lysed by the addition of 1 ml of
radioimmunoprecipitation assay (RIPA)/lysis buffer with protease
inhibitors (100 mM Tris-HCl, pH 7.4, 150 mM
NaCl, 1 mM EDTA, 1% Triton X-100, 1% sodium deoxycholate,
0.1% sodium dodecyl sulfate, 1 µg/ml leupeptin, 250 µM
PMSF, 1 µg/ml aprotinin, 1 mg/ml trypsin inhibitor, and 1 mM iodoacetamide) for 1 hr at 4°C with vigorous
shaking.
Lysates were transferred to centrifuge tubes and centrifuged at
20,000 × g to sediment nucleic acids and debris.
Aliquots of the lysate were taken for Western analysis before the
lysate was incubated with avidin-conjugated beads (the "total cell
lysate" fraction). Equal volumes of avidin bead suspension were added to a volume of lysate (300 µl of bead suspension in 300 µl of lysate) and incubated for 1 hr at room temperature with occasional stirring. Then the avidin-lysate solution was centrifuged for 15 min
at 16,500 × g; the supernatant was removed and
discarded after samples were taken for Western analysis (the
"intracellular" fraction). The pellet that contained the
biotinylated cell surface proteins was washed four times with 1 ml of
RIPA/lysis buffer with protease inhibitors. The supernatant from the
fourth wash was analyzed by Western analysis and showed no EAAC1
immunoreactivity, so the remaining washes were not analyzed further.
The pellet was resuspended in 300 µl of Laemmli buffer (62.5 M Tris-HCl, pH 6.8, 2% SDS, 20% glycerol, and 5%
2-mercaptoethanol) for 30 min with occasional shaking to elute the
biotinylated proteins. The solution was centrifuged for 10 min at
16,500 × g, and the supernatant was removed and saved
for Western analysis as the "biotinylated" fraction. All samples
for Western analysis were diluted in equal volumes of loading buffer
(2% SDS, 10% 2-mercaptoethanol, 5% glycerol, 5% 1 M
Tris, pH 7.0, and 0.005% bromophenol blue) and frozen at  20°C
until analysis.
In initial experiments the effects of varying the amount of avidin
beads were examined. Equal volumes of cell lysate and bead suspension
(as provided by the manufacturer) resulted in the maximal recovery of
biotinylated protein. Similarly, we tested a higher concentration of
biotin and found that this did not increase the extent of biotinylation
of EAAC1.
Western analyses. Western analyses were performed as
described previously (Rothstein et al., 1994). Briefly, biotinylation samples that previously had been diluted in solubilizing buffer were
thawed and boiled for 5 min. Proteins then were electrophoresed on a
10% sodium dodecyl sulfate-polyacrylamide gel and transferred to
polyvinylidene fluoride membranes (Immobilon P, Millipore, Bedford,
MA). The membranes were immersed for 1 hr in blocking solution (0.5%
nonfat dry milk, 0.1% Tween 20, and 50 mM Tris-buffered saline) and probed with affinity-purified anti-EAAC1 (0.6 µg/ml), GLT-1 (0.034 µg/ml), GLAST (0.4 µg/ml), or EAAT4 (0.02 µg/ml) and
anti-actin (1:200) diluted in blocking solution for 1 hr. After
washing, the blots were exposed to horseradish peroxidase-conjugated donkey anti-rabbit IgG diluted 1:1000 in blocking solution for 1 hr.
Finally, the blots were washed and visualized with enhanced chemiluminescence (Amersham, Arlington Heights, IL).
Blots were quantitated by using films scanned by an Epson ES1200C
scanner with Adobe Photoshop (San Jose, CA) software and then analyzed
by National Institutes of Health Image Software. Actin was used to
control for equal protein loading and to determine whether the
biotinylation reagent labels proteins in the intracellular compartment.
The immunoblots consistently demonstrated bands at 46 kDa (actin), at
66 kDa (EAAC1), and two bands above 220 kDa. These high molecular
weight bands are consistent with homomultimers of EAAC1. Haugeto and
colleagues (1996) previously reported that glutamate transporters form
homomultimers, the formation of which can be prevented by treatment
with 30 mM DTT (Haugeto et al., 1996). We used the same
concentration of DTT in the lysis buffer of a biotinylation experiment,
but we were unable to prevent the formation of these larger molecular
weight bands and omitted DTT from further experiments.
EAAC1 immunoreactivity in each fraction (lysate, intracellular, and
biotinylated) was normalized to the corresponding amount of lysate
actin immunoreactivity. Data were expressed as a percentage of change
in the amount of normalized EAAC1 immunoreactivity observed under
control conditions for each fraction (i.e., lysate, intracellular, and
biotinylated fractions). The data were analyzed both as the 66 kDa
EAAC1 band alone and as the combination of the 66 kDa band with the
higher molecular weight EAAC1 immunoreactive bands. There was no
difference in the trends or statistical differences noted, so the data
were presented as the combined 66 kDa and higher molecular weight bands
for the sake of clarity.
Immunofluorescent confocal microscopy. C6 glioma were plated
at equal density on sterile glass coverslips in 35 mm dishes. Plates were pretreated with either 100 nM wortmannin or
vehicle for 5 min, and 100 nM PMA or vehicle was added for
30 min. Cells were washed twice in PBS and fixed in 4%
paraformaldehyde for 10 min. Cells were rinsed three times in
Tris-buffered saline and blocked in 5% normal goat serum and 0.1%
Triton X-100 for 30 min. Anti-EAAC1 primary antibody diluted 1:10 in
the blocking solution was added to the cells and incubated overnight at
4°C. Then the primary antibody was removed, and the cells were rinsed with blocking solution three times. The secondary antibody
(lissamine-rhodamine goat anti-rabbit IgG) was warmed at 37°C for 30 min and centrifuged at 100 × g for 5 min to remove any
crystal precipitate; then the cells were incubated with secondary
antibody for 2 hr. Cells were washed twice with blocking solution and
incubated with DAPI (2 µg/ml in PBS) for 10 min at room temperature.
After incubation the cells were rinsed three times with PBS, dehydrated
in 97% ethanol for 1 min, and dried. Coverslips were mounted on glass slides with Vectashield and sealed with clear nail polish.
Slides were examined by confocal microscopy with a Leica TCS confocal
microscope (Exton, PA) and a krypton-argon Omnichrome laser (Chino,
CA). Immunostained cultures were sectioned optically at 0.5 µm
intervals with a 100× oil objective at the following settings for (1)
EAAC1: krypton-argon laser power = 1, pinhole = 100, voltage = 677, and voltage offset = 3; (2) DAPI: argon laser power = 3, pinhole = 90, voltage = 585, and
voltage offset = 0. We chose sections through the center of the
cell by examining DAPI nuclear staining and selecting sections that
corresponded to the largest cross-sectional area of the nucleus. Images
were obtained on a Leica TCS software system and formatted in Adobe Photoshop.
Data analysis. Eadie-Hofstee transformations of the
concentration dependence of uptake were fit by linear regression
analysis and represent at least three independent experiments performed in triplicate. The concentration dependence of the effects of drugs was
assessed by nonlinear regression fitting of one-site inhibition curves
with Graph Pad Prism software. Statistical analyses were performed with
Statview 512+. Data are presented as the mean ± SEM of at least three independent experiments.
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RESULTS |
Endogenous expression of EAAC1 by C6 glioma
We have reported previously that the C6 glioma cell line
endogenously expresses EAAC1 immunoreactivity but lacks GLT-1 or GLAST
immunoreactivity (Dowd et al., 1996), and others have used RT-PCR to
provide additional evidence that C6 glioma express EAAC1, but not GLT-1
or GLAST (Palos et al., 1996). Since these studies were reported, an
antibody to EAAT4 has been developed (Furuta et al., 1997), so we
reexamined the expression of each of these four transporters in C6
glioma (Fig. 1). Extracts from brain
tissues enriched in each of the transporters also were used as positive controls. Although GLT-1, EAAT4, and GLAST immunoreactivities were
observed in the appropriate brain fractions, none of these transporters
was detected in C6 glioma. EAAC1 immunoreactivity was observed in both
C6 glioma and cortical membrane homogenates. As was observed
previously, the apparent molecular weight of EAAC1 immunoreactivity was
~6 kDa larger in C6 glioma than in cortical tissue (Dowd et al.,
1996). We have shown previously (Dowd et al., 1996) that treatment of
C6 glioma or cortical membrane protein with N-glycosidase F
results in EAAC1 bands of equivalent apparent molecular weights of 57 kDa, consistent with that predicted from the cDNA sequence (Kanai and
Hediger, 1992). The endogenous expression of only EAAC1 by an
immortalized cell line of CNS origin provides an ideal model system for
studying the cellular regulation of this transporter.
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Figure 1.
Western blot analysis of sodium-dependent
glutamate transporters endogenously expressed in C6 glioma. C6 glioma
were harvested, and 50 µg of protein was loaded in each lane
(lanes 2, 4, 6, 8). Membrane homogenates
from rat brain regions known to be enriched in a particular subtype of
transporter were used as positive controls. Rat cortex (5 and 50 µg)
was loaded in lanes 1 and 7,
respectively; 50 µg of rat cerebellum was loaded in lanes
3 and 5. The blots were probed with anti-GLT1
(lanes 1 and 2), anti-EAAT4 (lanes 3 and 4), anti-GLAST (lanes
5 and 6), and anti-EAAC1 (lanes
7 and 8). Only the EAAC1 subtype of glutamate
transporter is expressed in C6 glioma. The immunoblot is representative
of at least two independent experiments.
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Effects of PMA on EAAC1
L-[3H]-glutamate uptake activity
In an earlier study we reported that PMA incubation caused a
twofold increase in EAAC1 uptake activity in C6 glioma and that this
effect was blocked completely by an inhibitor of PKC (Dowd and
Robinson, 1996). As shown in Figure 2,
PMA produced an 80% ± 4% (mean ± SEM; n = 3)
increase in glutamate transport in C6 glioma. The inactive phorbol
ester, 4-phorbol, had no effect on uptake at similar concentrations,
whereas the PMA analog phorbol-12,13-dibutyrate produced a similar
increase in glutamate uptake. To provide further evidence that the
effects of PMA are mediated by the PKC pathway, we examined the effects
of the potent and selective competitive PKC inhibitor Bis II (Nixon et
al., 1992). As shown in Figure 3,
pretreatment with Bis II completely blocked the effects of PMA, but it
had no effect on glutamate transport when it was used alone. Bis II
inhibited the effects of PMA with an IC50 value of 804 nM. This compound, which competitively binds to the ATP binding site, inhibits PKC with an IC50 value of 13 nM in an in vitro assay (Toullec et al., 1991).
Other studies have reported IC50 values for related
bisindolylmaleimides in the range of 750-910 nM or
have used 1 µM concentrations of related compounds,
depending on the cell system used (Chew et al., 1997; Ubl and
Reiser, 1997; Zhu et al., 1997).
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Figure 2.
Effects of PMA and its analogs on
Na+-dependent
L-[3H]-glutamate uptake in C6 glioma
cells. Cells were treated with vehicle, 100 nM PMA, 1 µM phorbol-12,13-dibutyrate (PDBu), or 100 nM 4-phorbol (4) for 30 min before
measurement of Na+-dependent
L-[3H]-glutamate transport. PMA and
PDBu increased glutamate uptake significantly over vehicle and
4-treated cells. Data are the mean ± SEM of at least three
independent observations and were compared by ANOVA with a Fisher's
Protected Least Significant Difference (PLSD) post hoc
analysis (*p < 0.001).
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Figure 3.
Bisindolylmaleimide II-mediated inhibition of
Na+-dependent
L-[3H]-glutamate transport (0.5 µM) in vehicle-treated ( ) and PMA-treated ( ) C6
glioma. Cells were preincubated with Bis II for 5 min, and either
vehicle (DMSO) or PMA (100 nM) was added for 30 min before
the measurement of Na+-dependent
L-[3H]-glutamate transport.
L-[3H]-glutamate uptake was measured
and expressed as the percentage of baseline (no Bis II or PMA)
activity. Data points represent the mean ± SEM of
at least three independent experiments, each performed in triplicate.
Data for the component of activity that was sensitive to Bis II were
fit to a single site with Prism software. The IC50 value
was 804 nM.
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Effects of PMA on the cellular localization of EAAC1
PMA may enhance glutamate transport either via an increase in the
catalytic rate of the transporter or via an increase in cell surface
availability. To examine changes in the cell surface levels of EAAC1,
we used a cell membrane-impermeant biotinylation reagent to label cell
surface proteins selectively. Biotinylated proteins were separated from
nonbiotinylated "intracellular" proteins by using avidin-coated
beads. The blots were probed with anti-actin antibody and with rabbit
anti-EAAC1 antibody. Figure
4A shows a Western
analysis of a representative biotinylation experiment. The yield of
transporter immunoreactivity, defined as the sum of the
immunoreactivity in the intracellular and biotinylated fractions
divided by the immunoreactivity in the lysate, was 100% ± 14%
(n = 11). Under control conditions (vehicle), 51% ± 5% (n = 11) of the EAAC1 immunoreactivity appeared in
the biotinylated fraction, whereas only 14% ± 3% (n = 11) of the actin immunoreactivity was biotinylated. The biotinylation
of actin may be attributable to a low level of cell lysis during the
procedure. None of the treatment conditions that were examined caused a
change in the amount of biotinylated actin (data not shown).
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Figure 4.
Analysis of distribution of EAAC1 immunoreactivity
in C6 glioma after treatment with PMA. Cells were preincubated with
either vehicle (DMSO) or Bis II (10 µM) for 5 min,
followed by the addition of either vehicle or 100 nM PMA
for an additional 30 min. Then the cells were biotinylated as described
in Materials and Methods. A, Immunoblot of cell lysate,
intracellular, and biotinylated fractions of C6 glioma. Loaded in all
lanes was 50 µl of each sample, and blots were probed with anti-EAAC1
(66 kDa bands and bands above 220 kDa) and anti-actin (46 kDa band) to
determine the extent of intracellular protein labeling by the biotin
reagent. B, Quantitation of immunoblots demonstrating
the effects of Bis II and PMA alone and in combination. Films were
scanned and quantitated densitometrically, and EAAC1 immunoreactivity
values were normalized for actin in the lysate fraction. Data represent
the mean ± SEM from five individual experiments and are expressed
as a percentage of the vehicle treatment for each fraction. There were
no changes in EAAC1 levels between treatments in the total cell lysate
fraction, but in the intracellular fraction PMA caused a significant
decrease in EAAC1 levels, as compared with all other treatments by
ANOVA (**p < 0.005; DMSO vs PMA; Fisher's PLSD),
which was blocked by Bis II (p < 0.001; PMA
and Bis II vs PMA; Fisher's PLSD). In the biotinylated fraction, PMA
increased the cell surface expression of EAAC1 (*p < 0.05; DMSO vs PMA; Fisher's PLSD), and Bis II alone had no effect on
cell surface expression but blocked the effects of PMA on biotinylated
EAAC1 (p < 0.001; Bis and PMA vs PMA;
Fisher's PLSD). The levels of biotinylated EAAC1 immunoreactivity in
cells treated with both Bis II and PMA were not significantly different from control.
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Although PMA had no effect on the total amount of EAAC1 (Fig.
4B, total cell lysate), the nonbiotinylated
(intracellular) transporter levels decreased with PMA treatment to 40% ± 9% (n = 5) of control levels. A corresponding
increase in biotinylated (cell surface) EAAC1, with levels increasing
to 161% ± 37% (n = 5) of control, indicates that a
significant fraction of intracellular transporter moved to the cell
surface as a result of PMA treatment. The PKC inhibitor Bis II had no
effect on transporter distribution when it was used alone, but it
blocked the changes in cellular localization of EAAC1 induced by PMA
(Fig. 4B).
Effects of wortmannin on EAAC1-mediated
L-[3H]-glutamate transport
The effects of PMA and the PKC inhibitor bisindolylmaleimide II on
EAAC1 activity and cellular localization observed thus far resembled
those reported for glucose and GABA transporters (Nishimura and
Simpson, 1994; Quick et al., 1997). Because studies of glucose
transporters have implicated PI3K in the regulation of activity and
trafficking, we examined the effects of the putative PI3K inhibitor
wortmannin on L-[3H]-glutamate
transport. Wortmannin maximally inhibited Na+-dependent
glutamate transport to 35% of control levels (Fig. 5). The IC50 value was 14.9 nM, similar to the reported IC50 values for
PI3-kinase inhibition (for review, see Nakanishi et al., 1995). The
decrease in transport activity occurred within minutes (significant at
p < 0.005 within 5 min) and was maintained for a 90 min incubation period (data not shown).
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Figure 5.
Wortmannin-mediated inhibition of
Na+-dependent
L-[3H]-glutamate uptake (0.5 µM) in C6 glioma. Wortmannin was applied to cells for 30 min, and L-[3H]-glutamate uptake was
assayed in triplicate. Values are expressed as the mean ± SEM for
four independent experiments. Data for the component of activity that
was sensitive to wortmannin were fit to a single site, using Prism
software. The IC50 value for this sensitive component was
14.9 nM.
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We also attempted to block
L-[3H]-glutamate uptake with the new
PI3K inhibitor LY 294002, but inhibition was not observed consistently (at least seven independent observations). Although wortmannin also
inhibits mitogen-activated protein (MAP) kinase and myosin light chain
kinase, the IC50 values for inhibition of these kinases are
at least 10-fold higher than the IC50 values for inhibition of PI3K (Nakanishi et al., 1995; Yano et al., 1995) and the
IC50 value observed in the present study for inhibition of
glutamate transport. Preliminary studies using the selective MAP kinase inhibitor PD 98059 showed no inhibition of transporter activity (data
not shown), suggesting that MAP kinase is not a mediator of the effects
of wortmannin on transport.
To analyze further how wortmannin might be influencing EAAC1 transport
activity, we examined the effects on the concentration dependence of
Na+-dependent
L-[3H]-glutamate uptake. Wortmannin
decreased the Vmax of glutamate transport to
43% of control, but it did not change the Km
(Fig. 6A). To determine
whether these effects could be attributed to altered metabolism of
glutamate, we examined the effects of wortmannin on the transport of
D-aspartate, a nonmetabolizable analog of glutamate.
Wortmannin decreased the Vmax for
Na+-dependent
D-[3H]-aspartate transport to 47% of
control and also caused a slight but significant decrease in the
Km (by 17%) (Fig. 6B). This
suggests that the effects of wortmannin are not attributable to altered metabolism of L-glutamate. To determine whether wortmannin
produces a nonspecific change in the electrochemical gradients required for Na+-dependent transport, we also examined the effects
of wortmannin on Na+-dependent glycine transport
activity. Wortmannin had no effect on glycine transport activity (Fig.
6C), suggesting a selective effect of wortmannin on EAAC1
rather than a change in the electrochemical gradients of the cell.
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Figure 6.
Effect of wortmannin on the concentration
dependence of Na+-dependent
L-[3H]-glutamate uptake in C6 glioma.
A, Wortmannin (; 100 nM) or vehicle
() was added to cells for 30 min before uptake assay. Values are
expressed as the mean ± SEM of six independent experiments performed in triplicate. The
Km was 17.6 ± 1.2 µM for
controls and 15.0 ± 1.2 µM for wortmannin treatment
(no significant difference; p > 0.05). The
Vmax values were significantly different,
with a Vmax of 589 ± 95 pmol · mg 1 · min1 for
controls and 256 ± 40 pmol · mg1 · min1 for
wortmannin treatment (p < 0.01; unpaired
Student's t test). B, Effect of
wortmannin on the concentration dependence of
Na+-dependent
D-[3H]-aspartate uptake in C6. Cells
were incubated with 100 nM wortmannin () or vehicle
() for 30 min before uptake assay. Values are expressed as the
mean ± SEM of three independent experiments, each performed in
triplicate. The Vmax for controls was
719 ± 72 pmol · mg1 · min1 and
for wortmannin was 341 ± 19 pmol · mg1 · min1
(p < 0.01; unpaired Student's
t test). The Km for controls
was 7.1 ± 0.3 µM and for wortmannin treatment was
5.9 ± 0.2 µM (p < 0.05;
unpaired Student's t test). C, Effect of
wortmannin on Na+-dependent
L-[3H]-glycine uptake at 10 or 100 µM or 0.1 mM concentrations of glycine.
Wortmannin ( ; 100 nM) or vehicle ( ) was added to
cells 30 min before uptake assay. Values are the mean ± SEM of at
least three independent experiments performed in triplicate (no
significant effect by ANOVA).
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Effect of wortmannin on the PMA-induced stimulation of
EAAC1 transport
The effects of wortmannin on the PMA-induced increase in
L-[3H]-glutamate uptake activity were
examined (Fig. 7). As seen in previous
experiments, wortmannin alone decreased the Vmax
of glutamate transport to 42% of control. PMA alone produced a
2.6-fold increase in the Vmax of glutamate
transport activity. When cells were coincubated with wortmannin and
PMA, the Vmax of glutamate uptake was stimulated by absolute amounts similar to those when PMA was used alone, but this
stimulation originated from a reduced baseline level of transport (Fig.
7). No change in Km values was observed with the
treatments, suggesting that these treatments were not changing the
affinity of the transporter for glutamate. It thus appears that the
stimulatory effects of PMA were not blocked by wortmannin. This may
imply that the mechanisms of PMA stimulation and wortmannin inhibition
of uptake activity occur via independent intracellular cascades,
because wortmannin does not block the effects of PMA fully.
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Figure 7.
Effect of coincubation of wortmannin and PMA
on the concentration dependence of Na+-dependent
L-[3H]-glutamate uptake in C6 glioma.
Cells were preincubated for 5 min with either 100 nM
wortmannin or vehicle, and 100 nM PMA or vehicle was added
for 30 min before the measurement of
L-[3H]-glutamate uptake activity.
Values represent the mean ± SEM of five independent experiments,
each performed in triplicate. For control cells (), the
Vmax value was 567 ± 94 pmol · mg1 · min1, and
the Km value was 16.8 ± 2 µM. For PMA-treated cells (), the
Vmax value was 1480 ± 330 pmol · mg1 · min1,
and the Km value was 18.7 ± 2 µM. For wortmannin-treated cells (), the
Vmax value was 239 ± 48 pmol · mg1 · min1,
and the Km value was 19.1 ± 3 µM. For cells treated with both wortmannin and PMA
(), the Vmax value was
910 ± 190 pmol · mg1 · min1,
and the Km value was 21.2 ± 3 µM. The Vmax and
Km values of all treatments were compared by
ANOVA, and significant differences were found between the
Vmax values of control and PMA-treated cells
(p < 0.005; Fisher's PLSD) and between
wortmannin- and wortmannin and PMA-treated cells
(p < 0.05; Fisher's PLSD). No significant differences were found among the Km values
of any treatment conditions.
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|
Effects of wortmannin on the cellular localization of EAAC1
To determine whether the effects of wortmannin were attributable
to a change in catalytic efficiency, a change in the steady-state levels of EAAC1, or an alteration in cell surface availability of the
transporter, we examined the time course for changes in cell surface
expression by using biotinylation. The levels of EAAC1 did not change
in the lysate, but within 5 min there was a significant decrease in
cell surface expression of EAAC1 (Fig. 8). This loss of
surface EAAC1 increased with time. Therefore, the decrease in transport
activity was associated with a loss in cell surface expression of
EAAC1. Because the effects of PMA and wortmannin
on activity appeared to be independent, biotinylation was used to
examine the combined effects of these treatments on cell surface
expression of EAAC1. None of these treatments changed the amount of
EAAC1 in the lysate or intracellular fractions (Fig. 9A,B). As was observed in
earlier experiments, PMA increased EAAC1 levels at the cell surface by
42% ± 17% (n = 6), and wortmannin reduced the cell
surface levels of EAAC1 to 45% ± 8% (n = 6) of control (Fig. 9B). However, unlike the effects of the
combined treatments on transport activity, coincubation of wortmannin
and PMA did not increase EAAC1 cell surface expression above that observed with wortmannin alone.
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Figure 8.
Time course of the effects of wortmannin on the
cellular distribution of EAAC1. C6 glioma were preincubated with 100 nM wortmannin for 5, 15, or 30 min or with vehicle for 30 min before biotinylation. A, Immunoblot of EAAC1 (66 kDa
and bands above 220 kDa) and actin (46 kDa band) immunoreactivity in
cell lysate, intracellular, and biotinylated fractions. Actin was used
to examine the extent of biotinylation of intracellular proteins.
B, Quantitation of EAAC1 immunoreactivity, demonstrating
a decrease in biotinylated EAAC1 with increasing wortmannin
preincubation times. Films were scanned and quantitated
densitometrically, and values are expressed as the mean ± SEM of
four independent experiments. No significant differences between
preincubation times occurred in the lysate or intracellular fractions,
but in the biotinylated fraction, EAAC1 at each time point was
significantly lower than control (ANOVA; *p < 0.001; Fisher's PLSD), and differences between time points were
significant (ANOVA; 5 vs 30 min, p < 0.001; 5 vs
15 min, p < 0.01; and 15 vs 30 min,
p < 0.05; Fisher's PLSD).
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Figure 9.
Analysis of the distribution of EAAC1
immunoreactivity in C6 glioma after treatment with PMA and wortmannin
(Wort). Cells were preincubated with either vehicle or
100 nM wortmannin for 5 min, and either vehicle or PMA was
added for 30 min before biotinylation. A, Immunoblot of
cell lysate, intracellular, and biotinylated fractions of C6 glioma.
Sample (50 µl) was loaded in all lanes, and blots were probed with
anti-EAAC1 (66 kDa and bands above 220 kDa) and anti-actin (46 kDa
band) as a control. B, Quantitation of immunoblots
demonstrating the effects of wortmannin and PMA alone and in
combination. Films were scanned and quantitated densitometrically, and
all EAAC1 values were normalized for actin in the lysate fraction. Data
represent the mean ± SEM from six individual experiments and are
expressed as a percentage of the control treatment for each fraction.
The treatments had no significant effects on EAAC1 levels in the total
cell lysate or intracellular fractions. In the biotinylated fraction,
wortmannin and wortmannin with PMA both caused significant decreases in
cell surface expression of EAAC1 by ANOVA (**p < 0.005; *p < 0.05; Fisher's PLSD). PMA increased cell surface expression of EAAC1 as compared with control
(*p < 0.05; Fisher's PLSD). There was no
significant difference between Wort and Wort & PMA.
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Visualization of changes in EAAC1 localization via
confocal microscopy
To determine whether the changes in cellular distribution of EAAC1
could be visualized directly and correlated with the biotinylation studies, we used confocal microscopy to examine the changes in cell
surface expression of EAAC1 in response to incubation with PMA and
wortmannin. After the appropriate preincubation period, cells were
stained with DAPI to visualize nuclei and with anti-EAAC1. Images taken
through the midsection of the cell at the level of the largest nuclear
area demonstrate that, under control situations (Fig.
10A), the
distribution of EAAC1 shows punctate immunostaining throughout the
cytoplasm, with little transporter clustering at the cell surface. PMA
increased EAAC1 immunoreactivity at the periphery of the cell (Fig.
10B), causing significant transporter clustering
while decreasing punctate cytoplasmic staining. PMA also changed the
morphology of the cell, causing increased "ruffling" of the cell
membrane. Wortmannin, in marked contrast, elicited a redistribution of
the transporter into large vesicular compartments within the cell that
resembled localization into late endosomal or lysosomal compartments
(Fig. 10C). The combination of wortmannin and PMA caused a
mixed distribution pattern of EAAC1 immunoreactivity as well as a
morphological change in the cells (Fig. 10D). The transporter appeared intracellularly in a perinuclear distribution and
also in some small clusters both in the cytoplasm and at the cell
surface.
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Figure 10.
Effects of PMA and wortmannin on the cellular
distribution of EAAC1 as examined by immunofluorescent confocal
microscopy. Cells were treated with either DMSO
(Vehicle) or wortmannin for 5 min, followed by either
vehicle or PMA for 30 min. Cells were fixed and labeled with
rhodamine-conjugated anti-EAAC1 (red) and DAPI
(blue). Serial sections of 0.5 µm were obtained by
confocal microscopy at 100× magnification, and sections through the
center of the cell corresponding to the largest cross-sectional nuclear area were used for each treatment. These images were representative of
multiple fields examined for each treatment from two independent immunofluorescence experiments. In control (vehicle-treated) cultures (A), the cells exhibited dispersed, punctate
intracellular immunolabeling. In the presence of PMA
(B) there was a marked decrease in intracellular labeling, with a redistribution of transporter to clusters on the cell
surface (arrowheads) as well as a morphological change that resembled membrane ruffling. Wortmannin, in contrast to PMA, caused a redistribution of EAAC1 into dense vesicular-like perinuclear deposits (C, arrows). Combined treatment
with both wortmannin and PMA caused some morphological changes as well
as increased perinuclear immunostaining without the formation of large
vesicle-like structures (D). Scale bar, 10 µm.
|
|
| |
DISCUSSION |
The regulation of EAAC1 is of considerable interest in light of
the evidence that glutamate transporters may play a role in a variety
of neurological diseases. The loss or dysfunction of glial transporters
such as GLT-1 may contribute to the pathogenesis of some types of ALS
(Rothstein et al., 1995, 1996), and knock-out studies suggest that both
neuronal and glial transporters may play a role the prevention of
excitotoxicity and resultant sequelae such as paralysis and seizures
(Rothstein et al., 1996). The highest densities of the neuronal subtype
EAAC1 are in the cortex and the hippocampus, areas that have high
levels of glutamatergic synaptic transmission (Rothstein et al., 1994).
Interestingly, these areas are also extremely sensitive to excitotoxic
damage caused by stroke, ischemia, and head trauma (Palmer et al.,
1993; Greene and Greenamyre, 1996; Nilsson et al., 1996). EAAC1 may play a role in the protection of neurons in these areas from excess glutamate release during normal synaptic activity and pathological conditions.
Thus far, the mechanisms of regulation of glutamate transporters by
intracellular pathways are mainly unknown. Casado and colleagues
demonstrated that the GLT-1 transporter transfected into HeLa cells
undergoes direct phosphorylation when the cells are treated with
phorbol ester, a known PKC activator (Casado et al., 1993). This
increase in phosphorylation correlates with an increased rate of
glutamate uptake, implying that increased phosphorylation may increase
uptake activity. The precise mechanism of this increase in uptake
activity is not known and could represent an increase in the catalytic
rate of the transporter, an activation of silent transporters on the
cell surface, and/or an increase in transporter translocation to the
cell surface.
In the present study we demonstrated that the uptake activity and the
cell surface localization of the glutamate transporter EAAC1 in C6
glioma is increased by PMA. Phorbol esters activate PKC by mimicking
the effects of diacylglycerol (DAG), an endogenous activator of PKC.
Previously, we have shown that the increase in uptake activity induced
by PMA in C6 glioma cells is blocked by the noncompetitive PKC
inhibitor chelerythrine (Dowd and Robinson, 1996). This suggested that
the PKC pathway may mediate some of the effects of phorbol esters,
possibly via phosphorylation at a PKC consensus site on the EAAC1
transporter. To provide additional evidence that the effects of PMA
were mediated via activation of PKC, we used the competitive inhibitor
Bis II, which did not produce the cell toxicity observed when
chelerythrine was used at high concentrations. Bis II completely
blocked the PMA-induced stimulation of glutamate uptake but had no
effect on the basal level of glutamate uptake. Biotinylation with a
membrane-impermeant reagent was used to determine whether PMA alters
cell surface expression of EAAC1. Biotinylation has been used
successfully in the study of apical-basolateral trafficking and in the
identification of changes in cell surface expression of other
transporters (Sargiacomo et al., 1989; Qian et al., 1997). PMA caused
an increase in biotinylated EAAC1 and a concomitant decrease in
nonbiotinylated transporter, suggesting that PMA translocates the
transporter from an intracellular compartment to the cell surface. As
was observed for PMA-stimulated transport activity, this effect was
blocked completely by Bis II. Confocal microscopy provided further
evidence that PMA causes a redistribution of EAAC1 in C6 glioma. After
treatment with PMA, the cells showed a change in morphology that
resembled membrane "ruffling" or the formation of filamentous
microvilli (Von Zastrow and Kobilka, 1994). Rhodamine-labeled EAAC1
demonstrated a striking redistribution to the cell membrane and
appeared to form discrete clusters on the cell surface. These clusters
resemble those formed by PDZ domain-containing proteins such as Glu
receptor interacting protein (GRIP), which appears to cluster AMPA
receptors at excitatory synapses, or PSD-95, which appears to mediate
the clustering of NMDA receptors (Kim et al., 1996; Dong et al., 1997).
Interestingly, although EAAC1 appears to cluster after PKC activation,
NMDA receptors disperse on the membrane (Ehlers et al., 1995). These
images suggest that EAAC1 may interact with some cytoskeletal protein
in response to PKC activation.
Because there were some similarities between the PMA-induced regulation
of glutamate and glucose transporters (see the introductory remarks),
the effects of wortmannin were examined to determine whether another
signaling pathway might regulate EAAC1 activity and trafficking. A role
for PI3K in protein trafficking and vesicle secretion has been
suggested on the basis of homology with the yeast protein vps34,
mutations of which cause vacuole sorting defects (Kapeller and Cantley,
1994). Wortmannin rapidly (within minutes) decreased glutamate uptake
and EAAC1 cell surface expression when it was used alone, an effect not
observed with the PKC inhibitor. This suggests that wortmannin reduces
transport by blocking the activity of a constitutively active PI3K or a
PI3K that is activated by a signaling molecule present in the medium.
Because the IC50 value for wortmannin inhibition of
L-[3H]-glutamate transport is nearly
identical to the IC50 value for PI3K inhibition and no
other targets with similar sensitivity to wortmannin have been
identified to date, we assume that wortmannin is blocking a subtype of
PI3K, but we acknowledge the possibility of alternate targets of
wortmannin inhibition. The lack of effectiveness of LY 294002 may be
attributable to the nature of the competitive binding of LY 294002 to
the ATP binding site of the p85 subunit, as compared with the
irreversible interaction of wortmannin at the p110 catalytic subunit or
the existence of differential PI3K isoform sensitivity to these two
inhibitors. There are multiple isoforms of PI3K that are known, and
there appears to be differential sensitivity of these isoforms to
wortmannin, although the sensitivities of these isoforms to LY 294002 has not been analyzed specifically (for review, see Cheatham et al.,
1994; Nakanishi et al., 1995).
Although wortmannin did not appear to increase transporter in the
intracellular compartment in biotinylation experiments, confocal
microscopy demonstrated an internalization of EAAC1 into large
vesicular structures that were often perinuclear, a pattern characteristic of endosomal distribution (Sternini et al., 1996). We
assume that the inability to detect an increase in intracellular EAAC1
with biotinylation is related to limitations of this technique or
possibly to a loss of transporter to the viscous nuclear pellet that is
obtained after lysis of the cells. The observation that Na+-dependent glycine transport is unaffected by
wortmannin indicates that this effect is not a nonspecific endocytotic
event. Future studies will be needed to identify the specific cellular
compartment to which EAAC1 localizes.
The studies discussed to this point imply that the changes in transport
activity are mediated by changes in cell surface expression. Because
the effects of PMA and wortmannin on EAAC1 regulation were opposite, we
examined the effects of both treatments together to determine whether
they exert their effects via a common pathway. Although PMA stimulated
transport activity in both vehicle-treated and wortmannin-treated cells
by the same absolute amount, PMA increased cell surface expression only
in vehicle-treated cells, but not in wortmannin-treated cells. This
surprising result suggests at least two possible mechanisms to explain
the effects of PMA and wortmannin on EAAC1. It is possible that PMA has
effects on both the catalytic efficiency and cell surface expression of
EAAC1 and that wortmannin selectively blocks the effect of PMA on cell surface expression. Alternatively, it is possible that wortmannin alters the mechanism of action of PMA by altering crosstalk between the
PI3K and PKC pathways such that, in the absence of wortmannin, PMA
increases activity by increasing cell surface expression and, in the
presence of wortmannin, PMA increases the catalytic efficiency of
transport.
Although PI3K is a rather newly identified signaling molecule, there is
evidence for crosstalk between the PKC and PI3K pathways. It is known
that receptor tyrosine kinase activation leads to the increased
production of the metabolites DAG and IP3 by stimulating the activity of phospholipase C as well as the activation of PI3K (for
review, see Kapeller and Cantley, 1994). DAG and phorbol esters
activate PKC isoforms ,  ,  ,  ,  ,  , µ, and  ,
whereas the atypical PKC isoforms  and  are insensitive to
phorbol esters but are activated by the unique phospholipid products of
PI3K (Mizukami et al., 1997). PI3K may interact directly with the PKC , , and  isoforms, providing a physical link between the PKC and PI3-kinase pathways (Ettinger et al., 1996; Gomez et al., 1996;
Mizukami et al., 1997). C6 glioma cells express PKC , , , ,
and low levels of (Chen, 1993; Chen and Wu, 1995). It is possible
that the regulation of EAAC1 activity in C6 glioma may be regulated by
a combination of these isoforms, such that phorbol ester
(DAG)-sensitive isoforms may regulate catalytic activity and some
degree of trafficking to the cell surface, whereas PI3K-responsive
isoforms may mediate transporter internalization.
In summary, we have developed evidence that both PKC and PI3K regulate
cell surface expression and activity of the neuronal glutamate
transporter EAAC1. At present, the physiological significance of this
regulation is unclear, but preliminary studies from our laboratory
suggest that this regulation may occur in neuronal cultures, indicating
that this is not an artifact of the cell system used (Munir et al.,
1997). Trafficking of neurotransmitter transporters could have a
variety of physiological as well as pathophysiological consequences.
Parallel mechanisms appear to regulate both transporter trafficking and
neurotransmitter release. PKC increases cell surface expression of both
GABA and glutamate transporters and also increases
depolarization-evoked release of GABA and glutamate (Dekker et al.,
1991; Capogna et al., 1995). There is now evidence that at least some
proteins, such as SNAP-25, synaptobrevin, and syntaxin, are involved in
both vesicular release of neurotransmitter and transporter trafficking
(Quick et al., 1997). The finding that the EAAC1 subtype of glutamate
transporter is trafficked to and from the cell surface raises
interesting questions about the direction these transporters travel in
different physiological situations, such as during long-term
potentiation (LTP) or excitotoxic injury. For example, decreasing
glutamate transporters at the cell surface during LTP could enhance
synaptic efficacy. The ability to traffick transporters rapidly also
may represent an endogenous protective mechanism to limit excitotoxic damage by increasing cell surface expression of transporters and hence
to promote the clearance of extracellular glutamate. Alternatively, removal of transporters from the cell surface might reduce the reversal
of transport, which is thought to contribute to the rise in
extracellular glutamate that is observed during an excitotoxic insult
(for review, see Attwell et al., 1993; Levi and Raiteri, 1993). The
current studies suggest that there is a tightly regulated control
mechanism that moves transporters appropriately in response to changes
in the cellular environment.
| |
FOOTNOTES |
Received Nov. 17, 1997; revised Jan. 9, 1998; accepted Jan. 9, 1998.
This study was supported by National Institutes of Health (NIH) Grants
NS29868 and NS36465 to M.B.R., an NIH predoctoral fellowship MH11977 to
K.E.D., NIH Grant NS33958 to J.D.R., and Mental Retardation Research
Center Grant HD26979. We thank Drs. M. Munir, D. Lynch, and O. Zelenaia
for their helpful comments and review of this manuscript and Dr. J. Golden for his advice regarding the immunohistochemistry.
Correspondence should be addressed to Dr. Michael B. Robinson,
Neuroscience Research, Abramson Pediatric Research Center, Room 502, 34th and Civic Center Boulevard, Philadelphia, PA 19104.
| |
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RC9 - RC9.
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T. L. Whitworth, L. C. Herndon, and M. W. Quick
Psychostimulants Differentially Regulate Serotonin Transporter Expression in Thalamocortical Neurons
J. Neurosci.,
January 1, 2002;
22(1):
RC192 - RC192.
[Abstract]
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Top
Abstract
Introduction
