 |
 Previous Article | Next Article 
The Journal of Neuroscience, May 15, 2000, 20(10):3596-3605
Pituitary Adenylate Cyclase-Activating Polypeptide (PACAP), a
Neuron-Derived Peptide Regulating Glial Glutamate Transport and
Metabolism
Maciej
Figiel and
Jürgen
Engele
Anatomie und Zellbiologie, Universität Ulm, 89069 Ulm,
Germany
 |
ABSTRACT |
In the brain, glutamatergic neurotransmission is terminated
predominantly by the rapid uptake of synaptically released
glutamate into astrocytes through the Na+-dependent
glutamate transporters GLT-1 and GLAST and its subsequent conversion
into glutamine by the enzyme glutamine synthetase (GS). To date,
several factors have been identified that rapidly alter glial glutamate
uptake by post-translational modification of glutamate transporters.
The only condition known to affect the expression of glial glutamate
transporters and GS is the coculturing of glia with neurons. We now
demonstrate that neurons regulate glial glutamate turnover via
pituitary adenylate cyclase-activating polypeptide (PACAP). In the
cerebral cortex PACAP is synthesized by neurons and acts on the
subpopulation of astroglia involved in glutamate turnover. Exposure of
astroglia to PACAP increased the maximal velocity of
[3H]glutamate uptake by promoting the expression
of GLT-1, GLAST, and GS. Moreover, the stimulatory effects of
neuron-conditioned medium on glial glutamate transporter expression
were attenuated in the presence of PACAP-inactivating antibodies or the
PACAP receptor antagonist PACAP 6-38. In contrast to PACAP, vasoactive intestinal peptide promoted glutamate transporter expression only at
distinctly higher concentrations, suggesting that PACAP exerts its
effects on glial glutamate turnover via PAC1 receptors. Although PAC1
receptor-dependent activation of protein kinase A (PKA) was sufficient
to promote the expression of GLAST, the activation of both PKA and
protein kinase C (PKC) was required to promote GLT-1 expression
optimally. Given the existence of various PAC1 receptor isoforms that
activate PKA and PKC to different levels, these findings point to a
complex mechanism by which PACAP regulates glial glutamate transport
and metabolism. Disturbances of these regulatory mechanisms could
represent a major cause for glutamate-associated neurological and
psychiatric disorders.
Key words:
astrocytes; glutamate uptake; GLT-1; GLAST; glutamine
synthetase; PKA; PKC
| |
INTRODUCTION |
Glutamate is the major excitatory
neurotransmitter in the mammalian CNS and is known to be
involved in complex processes such as memory formation. Perturbation of
glutamatergic neurotransmission is regarded as the major cause for
several neurological and psychiatric disorders, including psychosis and
epilepsy (Carlson and Carlson, 1990 ; Olney, 1990). Further, excess
levels of extracellular glutamate are considered crucial for several
neurodegenerative disorders such as amyotrophic lateral sclerosis
(ALS), Alzheimer's disease, Huntington's disease, and Parkinson's
disease (for review, see Whetsell and Shapira, 1993). A major step in
glutamatergic neurotransmission is the rapid clearance of synaptically
released glutamate from the extracellular space by sodium-dependent
glutamate transport. Initially, a family of three high-affinity
sodium-dependent glutamate transporters that differ in their kinetic
properties was cloned from rodent brain: GLAST (Storck et al., 1992),
GLT-1 (Pines et al., 1992), and EAAC-1 (Kanai and Hediger, 1992).
Subsequently, homologous transporters have been identified in humans
and termed EAAT-1, EAAT-2, and EAAT-3, respectively (Arizza et al.,
1994). More recently, an additional transporter subtype, EAAT-4, was identified in the human and rodent cerebellum (Fairman et al., 1995;
Lin et al., 1998). Immunohistochemical as well as in situ hybridization studies of the rodent brain showed that EAAC-1 is localized exclusively to neurons and further revealed that GLAST and
GLT-1 are expressed predominantly by glia (Rothstein et al., 1994;
Lehre et al., 1995; Torp et al., 1997).
Astrocytes perform the majority of glutamate uptake in the brain
(Rothstein et al., 1996). Moreover, astrocytes, but not neurons, are
capable of metabolizing incorporated glutamate into glutamine by the
enzyme glutamine synthetase (GS; for review, see Sonnewald et al.,
1997). Downregulation of astrocytic glutamate transporter expression
with antisense oligonucleotides leads to neurodegeneration and
progressive paralysis (Rothstein et al., 1996). Despite the crucial
role of astrocytes in the onset of glutamate-associated neurological
diseases, our knowledge of extracellular signaling molecules regulating
glial glutamate uptake and metabolism is rather limited. Several
factors, including glutamate itself, biogenic amines, arachidonic acid,
and amyloid  -peptide, were found to rapidly affect glutamate uptake
by post-translational modification of glial glutamate transporters (for
review, see Gegelashvili and Schousboe, 1998). To date, the only
experimental condition found to affect the expression of glial
glutamate transporters and GS is the coculturing of glia with neurons,
an effect mimicked by the activation of cAMP/protein kinase A
(PKA)-dependent signaling pathways in glial cells (Hayashi et al.,
1988; Swanson et al., 1997; Schlag et al., 1998).
Pituitary adenylate cyclase-activating polypeptide (PACAP) is a member
of the vasoactive intestinal peptide (VIP)/secretin/glucagon family of
peptides and represents the most potent activator of cAMP-dependent
signaling pathways presently known. PACAP exists in two forms:
PACAP-38, the predominant PACAP form in the nervous system, and
PACAP-27, which comprises the 27 N-terminal amino acids of PACAP-38
(for review, see Arimura, 1998). To date, three PACAP receptors have
been described (for review, see Harmar et al., 1998). The PAC1
receptor, which exist in various splice variants (Spengler et al.,
1993), is a PACAP-preferring receptor and binds VIP only with low
affinity. VPAC1 and VPAC2 receptors show high-affinity binding for both
PACAP and VIP. In the nervous system PACAP acts as a multifunctional
peptide and is involved in such diverse processes as the regulation of
hormonal secretion (for review, see Rawlings and Hezareh, 1996), energy
metabolism (Magistretti et al., 1998), and neuronal survival
(Kienlen-Campard et al., 1997; Villalba et al., 1997; Takei et al.,
1998; Vaudry et al., 1998). In addition, PACAP is known to modulate
glutamate signaling profoundly (Martin et al., 1995; Stella and
Magistretti, 1996; Pellegri et al., 1998), probably by directly
interfering with glutamate receptors of the NMDA type (Liu and Madsen,
1997).
In the present study we provide evidence that PACAP acts as a
neuron-derived signal regulating the expression of the glial glutamate
transporters GLT-1 and GLAST as well as of the glutamate-converting enzyme GS. Moreover, we demonstrate that PACAP differentially affects
the expression of GLT-1 and GLAST via the PAC-1 receptor-dependent activation of protein kinase C (PKC) and/or PKA.
| |
MATERIALS AND METHODS |
Animals and collection of brain tissue. Brains were
obtained from postnatal day (P)1 rat (Sprague Dawley; Charles River,
Sulzfeld, Germany) or fos-lacZ transgenic mouse pups
(generously provided by Dr. J. Morgan, St. Jude Children's Research
Hospital, Memphis, TN). Cerebral hemispheres were dissected
under sterile conditions and were collected in ice-cold PBS. In some
experiments the cerebral hemispheres were obtained from embryonic day
(E)17 rat embryos (crown-rump length, 19-21 mm).
Cell cultures. Primary glial cultures were established from
P1 rat or mouse cerebral hemispheres by following a recently
established protocol (Franke et al., 1998). Dissected tissue pieces
were incubated for 20 min in Ca2+- and
Mg2+-free Dulbecco's PBS (Life
Technologies, Gaithersburg, MD) containing 0.1% trypsin and
0.02% EDTA. Trypsin action was terminated by transferring the tissue
pieces to HBSS (Life Technologies) supplemented with 10% fetal
calf serum. The tissue was dissociated gently by trituration through a
plastic pipette. Cell suspension was centrifuged at 400 × g for 5 min, and the pellet was resuspended in MEM
(Life Technologies) supplemented with 10% horse serum (Life
Technologies). Cells were plated onto 100 mm culture dishes (Costar,
Cambridge, MA) coated with poly-D-ornithine (0.1 mg/ml; molecular weight, 30-70 kDa; Sigma, Deisenhofen, Germany). On
reaching confluency the cultured cells were trypsinized and replated.
After the third passage the cells were seeded into either 48-well
cluster plates (uptake experiments, fos assay; Costar) or
100 mm culture dishes (immunoblot, RT-PCR analysis; Costar) and were
maintained further with serum-free N2 medium additionally
supplemented with PACAP-38 (from 10 7 to
1011 M;
Calbiochem, Schwalbach, Germany), VIP (from
107 to
1011 M;
Calbiochem), dibutyryl cyclic AMP (dbcAMP;
104 M; Sigma), H89
(105 M;
Calbiochem), Gö6976 (106
M; Calbiochem), fibroblast growth factor-2
(FGF-2; 25 ng/ml; Life Technologies), or a combination of these factors
as specified in the text. In some experiments the cultures were treated
with neuron-conditioned medium in the presence of anti-PACAP-38
antiserum (final dilution, 1:1000; Peninsula Laboratories, Heidelberg,
Germany), the PACAP receptor antagonist PACAP-(6-38) (3 µM; Bachem, Heidelberg, Germany), or anti-goat
antiserum (final dilution, 1:1000; Vector Labs, Peterborough, UK).
Neuronal cultures were established from E17 cerebral hemispheres at
300,000 cells/cm2 and were maintained with
a modified serum-free N2 medium (Engele, 1998) for up to 4 d.
RT-PCR analysis. Primers for PACAP, GLT-1, GLAST, and
-actin were designed with Oligo software. PACAP primers recognize a sequence in the PACAP precursor mRNA. The sequences of the primers and
the sizes of the reaction products are given in Table
1. Total RNA was isolated from primary
glial cultures by using the PeqGold isolation kit (Peqlab)
according to the manufacturer's instructions. Total RNA concentration
was measured by spectrophotometric absorbance at 260 nm. A total of 20 µg of RNA was reverse-transcribed by using 200 U per µl of M-MLV
(Promega, Madison, WI) and 2 µg of random hexamer primers
(Interactiva, Ulm, Germany). Obtained templates were amplified
in a final volume of 50 µl. To increase the stringency of primer
binding, we additionally supplemented the reaction mix with
2.5% DMSO. If not stated otherwise, amplification was performed with
30 PCR cycles of 50°C for 1 min in the presence of 20 pmol of the
respective primers. Reaction products were separated in an agarose gel
and visualized with ethidium bromide. For quantitative analysis, target
mRNA was coamplified with -actin mRNA as an internal reference as
described previously (Pesce et al., 1996). Reaction was
performed with 20 pmol of primers for the target mRNA and 2 pmol of
primers for the -actin mRNA. The obtained reaction products were
separated in a 1.5% agarose gel, and optical densities of the bands
were determined by fluorescent image scanning. The ratio of optical
densities was calculated and taken as a measure of the respective
target mRNA.
Fos assay and immunocytochemistry. PACAP-responsive cells
were identified in glial cultures of fos-lacZ transgenic
mice as described previously (Engele and Schilling, 1996). Cultures
were stimulated for 3 hr with PACAP (107
M) and fixed with 2% paraformaldehyde for 30 min. -Galactosidase activity was visualized by incubating the
cultures for 24 hr at 37°C with X-gal (1 mg/ml; Bachem).
For phenotypic characterization of -galactosidase-positive cells,
cultures were incubated for 24 hr at 4°C with antibodies to either
glial fibrillary acidic protein (GFAP; 1:1000; Accurate Chemicals,
Westbury, NY) or GS (1:2000; Biogenesis, Sandown, NH). The
immunoreaction was detected with the Vectastain ABC kit (Vector Labs)
by using the appropriate biotinylated secondary antibodies (1:400;
Vector Labs) and 3,3'-diaminobenzidine as a chromogen. Labeled cells
were counted under microscopical observation at 200× within the
diameter of a culture well, corresponding to a total area of 4 mm2. Analysis was performed on a total of
12 culture wells from two independent experiments.
Glutamate uptake. Glutamate uptake studies were performed in
either sodium- or lithium-supplemented Tris buffer (Garlin et al.,
1995) containing (in mM) 5 Tris base, 10 HEPES, 140 NaCl or
LiCl, 2.5 KCl, 1.2 CaCl2, 1.2 MgCl2, 1.2 K2HPO4, 10 dextrose, and
the GS inhibitor methionine sulfoximine (1 mM; Sigma).
Radiolabeled glutamate (1 µCi/ml; specific activity, 63 Ci/mmol;
Amersham, Braunschweig, Germany) and unlabeled glutamate were mixed to
obtain a total glutamate concentration of 960 µM. The
stock solution was diluted further with the respective uptake buffer to
yield a glutamate concentration of 320, 160, 80, and 40 µM and added to third passage glial cultures (250 µl/well). Uptake was terminated by removing the radioactive solution
and rinsing the cultures three times with ice-cold lithium-containing
Tris buffer. Cells were lysed in 0.1 M NaOH, and the amount
of incorporated glutamate was determined by liquid scintillation
counting of the cell lysate. Sodium-dependent glutamate uptake was
defined to be the difference of the amount of radioactivity
incorporated by glia in the presence of sodium- and lithium-containing
buffer and was referred to the amount of protein determined in sister
cultures (see below).
Cell lysates and membrane fractions. For immunoblot analysis
the cultured glia were lysed by ultrasonification in 60 mM
Tris-HCl containing 2% SDS and 10% sucrose. For treatment of glia
with neuronal membranes the membrane fractions were prepared from
cultured E17 neurons on day 4 of cultivation. Cells were lysed in 0.25 M sucrose buffer at 4°C, and the lysate was centrifuged
at 1000 × g for 10 min. The supernatant was collected,
and membranes were pelleted at 100,000 × g for 1 hr at
4°C. The pellet was resuspended in N2 medium to obtain a final
protein concentration of 1 mg/ml. Protein contents of both cell lysates
and membrane fractions were determined with the BCA protein estimation
kit (Pierce, Rockford, IL).
Neuron-conditioned medium. To obtain neuron-conditioned
medium (CM), we incubated high-density cultures of the E17 cortex (300,000 cells/cm2) with serum-free N2
medium on day 2 of cultivation. After 48 hr the medium was collected
and centrifuged at 3000 × g to remove cells and
membrane fragments. The CM was aliquoted and stored at  70°C.
Western blot analysis. Cell lysates were diluted 1:1 in
sample buffer (250 mM Tris-HCl, pH 6.8, containing 4% SDS,
10% glycerol, and 2% -mercaptoethanol) and denatured at 95°C for
5 min. Proteins (5 µg/lane) were separated by SDS-10% PAGE and
transferred to nitrocellulose by electroblotting. Nonspecific binding
sites were blocked with 5% nonfat milk for 30 min, and then the blots
were incubated overnight at 4°C with one of the following antibodies: anti-GLT-1 (1:4000; Chemicon, Temecula, CA), anti-GLAST (1:1000; Chemicon), or anti-GS (1:2000). The immunoreaction was detected with
the enhanced chemiluminescence kit (Amersham). In all experiments, protein loading was controlled by staining the blots with actin antibodies (1:1000; Santa Cruz Biotechnologies, Santa Cruz, CA).
| |
RESULTS |
Neurons are the major source for PACAP in the neocortex
The synthesis of PACAP by CNS neurons has been demonstrated
repeatedly (for example, see Koves et al., 1991; Kivipelto et al.,
1992; Mikkelsen et al., 1994; Nielsen et al., 1998; Waschek et al.,
1998). Whether PACAP also is provided by CNS glia is presently unknown.
To address this issue, we initiated dissociated cell cultures from the
E17 rat cortex, where 95% of the cells represent microtubule-associated protein-2 (MAP-2)-immunoreactive (IR) neurons (Engele, 1998). In addition, cultures were initiated from the P1 rat
cortex; these cultures were passaged three times. We have demonstrated
that such "third passage cultures" predominantly consist of various
glial cell types and are virtually devoid of neurons (Franke et al.,
1998). Approximately 90% of the cells represent type-1 astrocytes; a
smaller number (1%) represent type-2 astrocytes; the remaining cells
are glial precursors and oligodendrocytes. RT-PCR analysis resulted in
the detection of PACAP mRNA in neuronal cultures, but not in glial
cultures maintained with several different culture media (Fig.
1). These included serum-free N2 medium,
MEM containing 10% horse serum, and N2 medium supplemented with FGF-2 (25 ng/ml). Whereas serum promotes glial proliferation, serum-free medium induces morphological differentiation of astrocytes. FGF-2 exerts a dual effect on glia: it is a potent mitogen for glial precursors and induces morphological differentiation of newly generated
cells (Engele and Bohn, 1992). Because cultured glia developed in the
virtual absence of neurons, we further considered the possibility that
the presence of neurons is required to induce PACAP synthesis in glia.
Glial cultures were maintained for 48 hr either with CM derived from
high-density (300,000 cells/cm2) cultures
of E17 rat cortical neurons or with membrane fractions prepared from
these neuronal cultures (1 mg of protein/ml). Both treatments failed to
induce PACAP synthesis in cultured cortical glia (data not shown).
Together, these findings suggest that neurons are the sole source for
PACAP in the neocortex.
View larger version (48K):
[in this window]
[in a new window]
|
Figure 1.
RT-PCR analysis allowed for the detection of mRNA
encoding PACAP in 3-d-old cultures of E17 cortical neurons (lane
5). In contrast, PACAP signal was undetectable in the third
passage glia of P1 rat cortical hemispheres maintained for 3 d
with serum-free N2 medium (lane 2), N2 medium
supplemented with FGF-2 (25 ng/ml; lane 3), or MEM
supplemented with 10% horse serum (lane 4).
Lane 1 shows a 100 bp ladder. In all cases the analysis
was performed with 30 PCR cycles. The experiments were repeated three
times with similar results.
|
|
PACAP acts on astroglia involved in glutamate turnover
Although glial cells are an established target for PACAP in the
CNS (Tatsuno and Arimura, 1994; Tatsuno et al., 1996; Magistretti et
al., 1998; Moroo et al., 1998), both the number and the nature of
PACAP-sensitive glia are presently not well defined. To characterize these targets, we have taken advantage of the fact that the initial genomic response of cells to a variety of extracellular stimuli consists in the rapid and transient expression of immediate early genes, most prominent among them c-fos (Schilling et al.,
1991). PACAP-induced c-fos expression was monitored in
cultures derived from a fos-lacZ transgenic mouse line
(Smeyne et al., 1992). This experimental approach allows for the
selective detection of c-fos expression (Schilling et al.,
1991) and further favors the easy and rapid phenotypic characterization
of c-fos-positive cells by the use of cell type-specific
antibodies (Engele and Schilling, 1996). Third passage glial cultures
were established from the cortex of P1 transgenic mouse pups, and
confluent cultures were stimulated for 3 hr with PACAP
(107 M); this
stimulation protocol leads to maximal transgene expression (Schilling
et al., 1991; Engele and Schilling, 1996). Histochemical staining for
-galactosidase revealed that a major portion (96 ± 2%,
mean ± SD; n = 12 culture wells) of the cultured
cells showed transgene expression and thus responded to PACAP (Fig.
2A). A similar portion
of cells responded to PACAP with -galactosidase expression in
subconfluent glial cultures (data not shown). This further demonstrates
that c-fos expression results from the direct activation of
the respective PACAP receptor(s) and does not involve an intermediate
signal (Engele and Schilling, 1996). Independent of the culture
conditions, -galactosidase staining was basically absent from
untreated controls (Fig. 2B). Subsequent double
labeling of PACAP-stimulated cultures with antibodies against the
astrocytic marker GFAP demonstrated that 92 ± 3%
(n = 12) of the -galactosidase-positive cells in
culture were astrocytes (Fig. 2A). In the intact
brain the expression of glutamate transporters is seen predominantly in
those astrocytes located in the vicinity of glutamatergic nerve terminals (Rothstein et al., 1994; Lehre et al., 1995). This functional difference seems to persist in vitro because only a
subpopulation of cultured astrocytes expresses the glial glutamate
transporters GLT-1 and GLAST as well as the enzyme GS (Hallermayer and
Hamprecht, 1984; Schlag et al., 1998). On the basis of these
observations we sought to determine whether PACAP acts on astroglia
involved in glutamate turnover. Third passage glial cultures were
initiated from fos-lacZ transgenic mice and stimulated for
3 hr with PACAP (107
M). Subsequent staining for -galactosidase and
GS revealed that 83 ± 2% (n = 12) of all GS-IR
cells showed -galactosidase activity (Fig.
3). Together, these findings demonstrate
that PACAP acts on the major portion of CNS glia, including those
involved in glutamate turnover.
View larger version (67K):
[in this window]
[in a new window]
|
Figure 2.
PACAP induces c-fos expression in
astrocytes. A, Third passage glial cultures were
initiated from the cerebral hemispheres of P1 fos-lacZ
transgenic mice. Cultures were stimulated for 3 hr with PACAP
(107 M) and processed for
-galactosidase histochemistry and GFAP immunocytochemistry.
B, Transgene expression in unstimulated control
cultures. Magnification, 500×. Note that the major portion of GFAP-IR
astrocytes (brown) responds to PACAP with transgene
expression (blue).
|
|
View larger version (114K):
[in this window]
[in a new window]
|
Figure 3.
Double labeling of PACAP-stimulated
(107 M; 3 hr) fos-lacZ
transgenic mouse glia for -galactosidase activity
(blue) and GS immunoreactivity (brown)
demonstrates that PACAP acts on astroglia involved in glutamate
turnover. Magnification, 500×.
|
|
Neuronal influences on glial glutamate uptake are mediated
by PACAP
The demonstration of PACAP as a neuron-derived peptide that acts
on the subpopulation of cortical glia involved in glutamate turnover
prompted us to determine whether PACAP is the physiological mediator of
the effects of neurons on glial glutamate transporter expression.
Corroborating previous studies (Schlag et al., 1998), the treatment of
rat glial cultures with neuron-CM for 2 d increased GLT-1 protein
levels (Fig. 4). These stimulatory
effects were abolished in the presence of PACAP-38 antiserum or the
PACAP receptor antagonist PACAP-(6-38). Similar inhibitory effects were
absent in the presence of equal concentrations of an unrelated
(anti-goat) control antiserum or with heat-inactivated (45 min at
100°C) PACAP-38 antiserum (Fig. 4). Together, these findings
demonstrate that PACAP regulates the expression of GLT-1, the glutamate
transporter subtype previously found to perform >90% of total
glutamate re-uptake in the brain (Tanaka et al., 1997). In contrast to
GLT-1, neuron-CM promoted the expression neither of GLAST nor of GS.
Presently, the most plausible explanation for this failure is that both
GLAST and GS expression are affected by PACAP at a concentration
distinctly higher than that present in the CM (see also Fig. 9).
View larger version (56K):
[in this window]
[in a new window]
|
Figure 4.
Influences of neuron-CM on glial glutamate
transporter expression are mediated by PACAP. Neuron-CM
(NCM) was prepared from high-density cultures of
E17 cortical neurons as described under Materials and Methods. Third
passage glia were initiated from P1 rat cortical hemispheres and
treated with either NCM alone or in combination with anti-PACAP-38
antibodies (PAb), anti-goat control antiserum
(CAb), heat-inactivated PACAP-38 antibodies
(PAbi), or PACAP-(6-38) [P-(6-38)].
After 3 d the GLT-1 expression levels were determined by
immunoblot analysis. In each lane 5 µg of total protein was loaded.
Loading was controlled additionally by staining the blots with actin
antiserum. The experiments were repeated three times with similar
results.
|
|
PACAP promotes glutamate uptake and metabolism in astroglia
To analyze further the effects of PACAP on glial glutamate
turnover, we maintained third passage glia of rat cortical hemispheres for 72 hr with PACAP-38 (107
M) and subsequently tested them for sodium-dependent uptake
of radiolabeled glutamate. All uptake studies were performed in the presence of the GS inhibitor methionine sulfoximine (1 mM);
this approach allowed us to study PACAP effects on glutamate transport mechanism(s) independent of PACAP effects on intracellular enzymatic glutamate cleavage. PACAP effects were compared with those of dbcAMP,
which previously was found to promote glial glutamate uptake (Swanson
et al., 1997; Schlag et al., 1998). A representative uptake experiment
is shown in Figure 5. For untreated
astrocytes the average Vmax value, as
determined from three independent experiments, was 33 ± 8 nmol/min per mg of protein; the average
Km value was 63 ± 13 µM. PACAP resulted in an increase of the
apparent Vmax (52 ± 7 nmol/min
per mg of protein; p = 0.02; unpaired Student's t test) and Km value
(146 ± 8 µM; p < 0.001).
Similar increases in the apparent Vmax
(46 ± 2 nmol/min per mg of protein; p = 0.05) and
Km (123 ± 20 µM; p = 0.005) of the uptake
process were present in dbcAMP-treated cultures. With both PACAP and
dbcAMP the effects on the uptake process were detectable only after
prolonged treatment ( 2 d). Currently, no specific inhibitors
are available that would allow us to discern between GLT-1 and
GLAST-mediated glutamate uptake. Although dihydrokainate has been shown
to act as a specific inhibitor for GLT-1 expressed in a heterologous
system (Pines et al., 1992; Arizza et al., 1994), it fails to affect
GLT-mediated glutamate uptake in primary glia (Schlag et al.,
1998).
View larger version (20K):
[in this window]
[in a new window]
|
Figure 5.
A, Effects of PACAP and dbcAMP on
the kinetic parameters of glial glutamate uptake. Third passage
cortical glia were maintained for 3 d in the absence or presence
of PACAP (107 M) or dbcAMP
(104 M), and sodium-dependent
glutamate uptake was determined by incubating the cultures with the
indicated concentrations of tritiated glutamate, as described under
Materials and Methods. Incubation was terminated after 10 min, a time
point within the linear phase of glial glutamate uptake (see
B). Then the cells were lysed, and incorporated
radioactivity was determined by liquid scintillation counting. Linear
regression analysis of the data was performed with the Hanes
transformation. Untreated control, apparent
Vmax = 23 nmol/min per mg of protein;
apparent Km = 57 µM;
r2, 0.99. With PACAP, apparent
Vmax = 47 nmol/min per mg of protein;
apparent Km = 142 µM; r2, 0.96. With
dbcAMP, apparent Vmax = 48 nmol/min per
mg of protein; apparent Km = 124 µM; r2, 0.97. Data
represent the mean ± SD (n = 12 wells).
B, Time course of sodium-dependent glutamate
incorporation into glia, demonstrating that glial glutamate uptake is
linear for at least 20 min. Cultures were treated with PACAP and dbcAMP
as described in A and were incubated with a final
glutamate concentration of 160 mM. Data represent the
mean ± SD (n = 12 wells).
|
|
To determine whether PACAP increased astrocytic glutamate uptake by
affecting GLAST and/or GLT-1, we studied expression levels of both
transporters in cultured rat glia by immunoblot analysis, using GLT-1
and GLAST-specific antibodies (Fig. 6).
In freshly prepared cell lysates the GLT-1 and GLAST antiserum each
recognized a single protein with apparent molecular weights of 71 and
66 kDa, respectively. Freezing the samples before the analysis
sometimes produced a second immunoreactive band of higher molecular
weight. In accordance with previous reports (Swanson et al., 1997;
Schlag et al., 1998), untreated third passage glia usually contained only low levels of GLAST and somewhat higher levels of GLT-1 (Fig. 6).
Prolonged treatment (72 hr) of the cultures with PACAP-38 (107 M) resulted in robust
increases of both GLT-1 and GLAST protein levels (Fig. 6).
Densitometric analysis of the immunoblots from three independent
experiments showed that this increase was 2.4 ± 0.6-fold for
GLT-1 and 2.7 ± 0.9-fold for GLAST (p  0.01). In dbcAMP-treated cultures (104
M; 72 hr) the GLT-1 and GLAST protein levels
increased 3.7 ± 0.9-fold and 3.4 ± 0.5-fold, respectively
(p 0.01). Because expression of glutamate
transporters seems to be regulated at both the transcriptional and
translational level (for review, see Gegelashvili and Schousboe, 1998),
we further examined whether PACAP affects levels of glutamate
transporter mRNAs. RT-PCR analysis demonstrated that a 72 hr treatment
with PACAP-38 (107
M) stimulates the expression of mRNAs encoding
GLT-1 and GLAST (Fig. 7). The average
increase was 1.8 ± 0.3-fold and 1.3 ± 0.1-fold for GLT-1
mRNA and GLAST mRNA, respectively (n = 3;
p 0.05). Similar increases were present in
dbcAMP-treated cultures (GLT-1 mRNA, 2.1 ± 0.5-fold; GLAST mRNA,
1.6 ± 0.2-fold; p 0.05).
View larger version (68K):
[in this window]
[in a new window]
|
Figure 6.
PACAP promotes the expression of glial glutamate
transporters. Third passage cortical glia were maintained for 3 d
in the absence or presence of PACAP (107
M) or dbcAMP (104 M) and
immunoblotted with anti-GLT-1 antibodies (1:4000; A) or
anti-GLAST antibodies (1:1000; B). In each lane 5 µg
of total protein was loaded. Loading was controlled by staining the
blots with actin antiserum.
|
|
View larger version (3317K):
[in this window]
[in a new window]
|
Figure 7.
RT-PCR analysis of PACAP-treated cortical glia for
GLT-1 (A) and GLAST (B)
mRNA levels. Total mRNA was isolated from third passage cortical glia
maintained for 3 d with either PACAP (107
M) or dbcAMP (104 M).
Transporter and -actin mRNAs were coamplified by 30 PCR cycles in
the presence of different primer concentrations and separated on a
1.5% agarose gel. Graphs show the ratios of PACAP and -actin RT-PCR
products taken as a measure of transporter mRNA levels.
C, Demonstration that, under the PCR conditions that
were used, increasing numbers of PCR cycles led to a linear increase in
the amount of the reaction products. PCR analysis was performed with
total RNA isolated from untreated cortical glia in the presence of
primers for GLT-1, GLAST, or -actin.
|
|
In the next set of experiments we asked whether PACAP also affects the
expression of the glutamate-converting enzyme GS. To follow up this
possibility, we maintained third passage glial cultures of rat cerebral
hemispheres for 72 hr with PACAP-38 (107
M) or dbcAMP (104
M) and examined them for GS expression by immunoblot
analysis. GS antibodies labeled a single protein band with an apparent
molecular weight of 45 kDa. In both PACAP- and dbcAMP-treated cultures, GS protein levels clearly were increased as compared with untreated control (Fig. 8). For PACAP-treated
cultures the average increase was 2.9 ± 0.4-fold, and for
dbcAMP-treated cultures the increase was 5.1 ± 1.5-fold
(n = 3; p 0.01). This demonstrates
that, in addition to affecting glial glutamate uptake, PACAP also
promotes glutamate metabolism in CNS glia.
View larger version (59K):
[in this window]
[in a new window]
|
Figure 8.
Immunoblot analysis of PACAP-treated cortical glia
for GS expression levels. Third passage cortical glia were maintained
for 3 d in the absence or presence of PACAP
(107 M) or dbcAMP
(104 M) and immunoblotted with anti-GS
(1:1000). In each lane 5 µg of protein was loaded. Loading was
controlled by stripping off the GS staining and reprobing the blots
with actin antiserum.
|
|
PACAP affects glial glutamate turnover via type-1
binding sites
Two PACAP binding sites can be distinguished pharmacologically.
Type-1 binding sites, corresponding to the PAC1 receptor (PAC1-R; see
Discussion), show high-affinity binding for PACAP and bind VIP only
with low affinity (for review, see Arimura, 1998). Type-2 binding sites
(corresponding to VPAC1 and VPAC2 receptors) show high-affinity binding
for both PACAP and VIP. To determine which of these binding sites
(receptors) mediates the effects of PACAP on glial glutamate
transporter expression, we initiated third passage glia from the
cortical hemispheres of P1 rat pups and maintained them for 3 d
with serial dilutions of PACAP-38 and VIP. Subsequent testing of the
cultures for effects on glutamate transporter and GS expression by
immunoblot analysis revealed that PACAP increases protein levels of
GLT-1 at concentrations as low as 1010
M (Fig. 9A). A
distinctly higher concentration of PACAP
(109 M) was
necessary to induce the expression of both GLAST and GS (Fig.
9B; data not shown). This is consistent with our previous notion that PACAP concentrations in neuron-CM are not sufficiently high
to affect GLAST and GS expression. Maximal increases in GLT-1, GLAST,
and GS levels were present with PACAP at 108 M. VIP
promoted the expression of both GLT-1 and GLAST only at concentrations
of 108 M
(Fig. 9A,B). In addition, the effects of PACAP on glial
glutamate transporter expression were sensitive to PACAP-(6-38) (data
not shown), an antagonist for both PAC1 and VPAC1 receptors (Harmar et
al., 1998). Together, these findings suggest that PACAP exerts its
effects on glial glutamate turnover via type-1 binding sites (PAC1-R).
View larger version (55K):
[in this window]
[in a new window]
|
Figure 9.
Dose-response curve of PACAP and VIP on glial
glutamate transporter expression. Third passage glia were maintained
for 72 hr with the indicated PACAP or VIP concentrations and analyzed
by immunoblotting for GLT-1 (A) and GLAST
(B) expression levels. In each lane 5 µg of
total protein was loaded. Loading of the gels was controlled by
additionally staining the blots with actin antiserum. The experiment
was repeated three times with similar results. Note that different
PACAP concentrations are required to promote GLT-1 and GLAST
expression. Further note that, in contrast to PACAP, VIP is less potent
in inducing glial glutamate transporter expression.
|
|
PAC1 receptors use different signaling pathways to affect the
expression of GLT-1 and GLAST
The PAC1-R is positively coupled to both adenylate cyclase (AC)
and phospholipase C (PLC). The events downstream of AC and PLC include
the activation of PKA and PKC, respectively. PKA has been shown to
mediate the effect of PACAP on neuronal survival, whereas PKC mediates
the effects of PACAP on neurite outgrowth in PC12 cells
(Kienlen-Campard et al., 1997; Villalba et al., 1997; Lazarovici et
al., 1998; Vaudry et al., 1998). To determine the role of PKA and PKC
in the effects of PACAP on glial glutamate transporter expression, we
maintained third passage glia for 3 d with a combination of
PACAP-38 and the PKA inhibitor H89 (105
M) or the PKC inhibitor Gö6976
(106 M). H89 almost
completely abolished the PACAP-induced expression of GLAST and also
decreased, although to a lesser extent, GLT-1 expression levels in
PACAP-treated glia (Fig. 10). The
presence of Gö6976 did not interfere with the effects of PACAP on
GLAST expression but resulted in a robust inhibition of PACAP-induced GLT-1 expression (Fig. 10). Together, these findings reveal that PACAP
differentially affects the expression of GLAST and GLT-1 via PKA and
PKC.
View larger version (58K):
[in this window]
[in a new window]
|
Figure 10.
PACAP differentially uses PKA and PKC to affect
the expression of glutamate transporters. Third passage glia were
treated for 72 hr with PACAP (107 M)
in combination with either H89 (105 M)
or Gö6976 (106 M). Levels of
GLT-1 (A) and GLAST(B) were
determined by immunoblot analysis. In each lane 5 µg of total protein
was loaded. The experiment was repeated three times with similar
results.
|
|
| |
DISCUSSION |
In the brain, termination of glutamatergic neurotransmission is
achieved predominantly by rapid uptake of synaptically released glutamate into astrocytes through the sodium-dependent glutamate transporters GLT-1 and GLAST and its subsequent conversion to glutamine
by the enzyme GS (Rothstein et al., 1996; Sonnewald et al., 1997). To
date, several factors, including glutamate itself, have been identified
that rapidly alter the activity of the glutamate uptake process by
post-translational modification of glutamate transporters (for review,
see Gegelashvili and Schousboe, 1998). However, the factor or
factors regulating the expression of glial glutamate transporter as
well as of GS are still unknown. Pronounced increases in glial
expression levels of GLT-1, GLAST, and GS have been observed in
coculture systems with neurons (Hayashi et al., 1988; Swanson et al.,
1997; Schlag et al., 1998). Although originally it had been suggested
that these effects involve glutamate signaling, recent work by Schlag
et al. (1998) demonstrated that neuronal influences on the expression
of glial glutamate transporters are not abolished by various glutamate
receptor antagonists. Interestingly, these studies further revealed
that the effects of neurons on glial glutamate transporter expression
are mimicked by the activation of cAMP-dependent signaling pathways
(Swanson et al., 1997; Schlag et al., 1998).
Several of our present findings provide compelling evidence that
neurons affect glial glutamate turnover via PACAP, the most potent
activator of cAMP-dependent signaling pathways known to date. First,
consistent with such a regulatory role, we observed that PACAP is
synthesized exclusively by cortical neurons, but not by glia, as shown
by RT-PCR analysis of neuronal and glial cultures for PACAP mRNA
expression. It is of note that the lack of PACAP synthesis in cultured
glia cannot be attributed to the absence of neurons in this culture
system as judged from the observation that treatment of glial cultures
with either neuron-CM or neuronal membrane fractions failed to induce
PACAP synthesis in glial cells. Although it cannot be dismissed
completely that the differentiation process of glia in vitro
might differ from that in vivo, we would like to emphasize
that, in line with our present in vitro findings, all
in vivo studies currently available point to neurons as the source for PACAP in the CNS (for example, see Koves et al., 1991; Kivipelto et al., 1992; Mikkelsen et al., 1994; Nielsen et al., 1998;
Waschek et al., 1998). Second, further corroborating the role of PACAP
as the physiological mediator of the effects of neurons on glial
glutamate turnover, we found that the stimulatory effects of neuron-CM
on glial GLT-1 expression were attenuated in the presence of
inactivating PACAP antibodies or the PACAP receptor antagonist
PACAP-(6-38). Moreover, the exposure of glia to PACAP robustly induced
the expression of the glutamate-converting enzyme GS as well as of the
glutamate transporters GLAST and GLT-1. The PACAP-induced increase in
glutamate transporter levels correlated with an increase in the maximal
velocity of the glutamate uptake. In addition, PACAP also increased the
Km of the uptake process. Similar
increases in the Km of glial glutamate
uptake have been reported previously in studies with dbcAMP and have
been attributed to an overestimation of the
Km value that may occur when enhanced glutamate transport would lower glutamate concentrations in the vicinity of the transporters (Schlag et al., 1998). Finally, using PACAP-induced c-fos expression as a readout for functional
signal transduction (Engele and Schilling, 1996) revealed that PACAP affects glial glutamate turnover via the direct and specific activation of glial PACAP receptors.
It is of note that PACAP affected the various components involved in
glial glutamate turnover with different potencies. Whereas stimulatory
effects of PACAP on GLT-1 expression were already detectable in the
pico to nanomolar range, the regulation of GLAST and GS expression
required ~10 times higher PACAP concentrations. This points to the
intriguing possibility that, depending on its extracellular
concentration, PACAP allows for a stepwise or graded activation of
glial glutamate turnover. Accordingly, moderate increases in
extracellular PACAP levels (up to 109
M) would promote the expression of GLT-1
preferentially, whereas increases beyond this concentration would, in
addition, enhance the expression of GLAST and GS.
To date, three PACAP receptors, termed PAC1-R, VPAC1-R and VPAC2-R,
have been cloned (for review, see Rawlings and Hezareh, 1996). All
receptors bind PACAP with high affinity; however, they differ with
respect to their affinity for VIP. PAC1-R is the PACAP-preferring receptor and shows an up to 1000-fold lower affinity for VIP. VPAC1-R
and VPAC2-R bind PACAP38/27 and VIP with approximately equal nanomolar
affinities. We revealed that PACAP, but not VIP, induced the expression
of GLT-1 and GLAST in the pico to nanomolar range. In addition, we
demonstrated that the effects of PACAP on glial glutamate transporter
expression were attenuated in the presence of PACAP-(6-38), a
nonspecific PACAP antagonist that binds to PAC1-R and VPAC1-R (Harmar
et al., 1998). Together, these observations imply that the effects of
PACAP on glial glutamate turnover are mediated via PAC1-R. PAC1-R are
positively coupled to both AC and PLC. The only exception is the PAC1-R
TM4 subtype that functions as an activator of L-type
Ca2+ channels (Chatterjee et al., 1996).
Previous studies suggested that PAC1-R TM4 is expressed by type-2, but
not by type-1, astrocytes (Tatsuno and Arimura, 1994), the glial cell
type predominantly present in our glial cultures (Franke et al.,
1998).
Two crucial events downstream of AC and PLC are the activation of PKA
and PKC, respectively. Both of these signaling proteins have been found
to act as distinct mediators of the effects of PACAP on neuronal
survival and neurite outgrowth (Kienlen-Campard et al., 1997; Villalba
et al., 1997; Lazarovici et al., 1998; Vaudry et al., 1998). We
observed that PACAP differentially signals via PKC and/or PKA to affect
the glial glutamate uptake process. PACAP induced expression of GLAST
via activation of PKA-dependent signaling pathways only, but it
affected the expression of GLT-1 via both PKA and PKC-dependent
signaling pathways. The diverse role of PKA and PKC in the effects of
PACAP on glial glutamate transporter expression is of special interest
given the fact that, in addition to PAC1-R TM4, a number of other
PAC1-R mRNA splice variants exist. These include a short (PAC1-R s) as
well as a very short (PAC1-R vs) form that lacks 21 amino acids in the
N-terminal extracellular domain (Pantaloni et al., 1996). Other splice
variants contain either one or two additional cassettes, termed
"hip" and "hop1/2" (Spengler et al., 1993). When expressed in
the renal cell line LLC PK1, these splice variants induce cAMP and
inositol phosphates to different levels, probably because they interact with different G-proteins (Spengler et al., 1993). Direct functional consequences of the differential expression of the various PAC1-R isoforms have been demonstrated recently with primary neuronal precursors (Lu et al., 1998). Sympathetic neuroblasts, which express the "hop" receptor isoform, respond to PACAP by proliferation, whereas cerebral neuroblasts, expressing PAC1-R s, cease to divide in
the presence of PACAP. By analogy, one could imagine a scenario in
which, depending on the astrocytic PAC1-R make-up, PACAP would affect
the expression of GLT-1 and GLAST differentially, thus allowing for a
modulation or fine tuning of PACAP effects on astrocytic glutamate
uptake. Whether in addition to regulating the expression of glial
glutamate transporters PACAP also would affect the activity of glial
glutamate uptake by post-translational modification of the transporters
remains to be established. It is, however, of note that PACAP
cooperates with glutamate to induce the release of arachidonic acid
(Stella and Magistretti, 1996), a signaling molecule known to alter
GLT-1 and GLAST-mediated glutamate uptake rapidly (Zerangue et al.,
1995).
A close correlation between hyper- or hypoactivity of glial glutamate
turnover and distinct glutamate-associated diseases has been suggested
repeatedly. Currently, the loss of GLT-1 and subsequent increases in
extracellular glutamate are viewed as a major cause for the
neurodegenerative processes underlying sporadic ALS (Bristol and
Rothstein, 1996). In line with this assumption the inhibition of
glutamate transporter expression in vivo was found to induce
neurodegeneration and progressive paralysis (Rothstein et al., 1996).
On the other hand, increased glutamate uptake eventually leads to
glutamatergic hypofunction, a mechanism implied in schizophrenia and
other psychoses (Carlson and Carlson, 1990) The present identification of PACAP as a neuronal-derived peptide with potent effects on the
expression of glial glutamate transporters and GS points to a crucial
role of this neuropeptide in the pathophysiology of glutamate-associated psychiatric and neurological diseases.
| |
FOOTNOTES |
Received Sept. 30, 1999; revised Feb. 2, 2000; accepted Feb. 22, 2000.
This work was supported by the state of Baden-Württemberg
(Landesforschergruppe) and the Deutsche Forschungsgemeinschaft. We
thank Drs. C. Pilgrim and K. Schilling for critical comments on this manuscript.
Correspondence should be addressed to Dr. Jürgen Engele,
Universität Ulm, Anatomie und Zellbiologie, 89069 Ulm, Germany. E-mail: juergen.engele{at}medizin.uni-ulm.de.
| |
REFERENCES |
-
Arimura A
(1992)
Pituitary adenylate cyclase-activating polypeptide (PACAP): discovery and current status of research.
Regul Pept
37:287-303[ISI][Medline].
-
Arimura A
(1998)
Perspectives on pituitary adenylate cyclase-activating polypeptide (PACAP) in the neuroendocrine, endocrine, and nervous system.
Jpn J Physiol
48:301-331[ISI][Medline].
-
Arizza JL,
Fairman WA,
Wadliche JI,
Murdoch GH,
Kavanaugh MP,
Amara SG
(1994)
Functional comparison of three glutamate transporter subtypes cloned from human motor cortex.
J Neurosci
14:5559-5569[Abstract].
-
Bristol LA,
Rothstein JD
(1996)
Glutamate transporter gene expression in amyotrophic lateral sclerosis motor cortex.
Ann Neurol
39:676-686[ISI][Medline].
-
Carlson M,
Carlson A
(1990)
Interactions between glutamatergic and monoaminergic systems within the basal ganglia
 implications for schizophrenia and Parkinson's disease.
Trends Neurosci
13:272-276[ISI][Medline]. -
Chatterjee TK,
Sharma RV,
Fisher RA
(1996)
Molecular cloning of a novel variant of the pituitary adenylate cyclase-activating polypeptide (PACAP) receptor that stimulates calcium influx by activation of L-type calcium channels.
J Biol Chem
271:32226-32232[Abstract/Free Full Text].
-
Engele J
(1998)
Spatial and temporal growth factor influences on developing midbrain dopaminergic neurons.
J Neurosci Res
53:405-414[Medline].
-
Engele J,
Bohn C
(1992)
Effects of acidic and basic fibroblast growth factors (aFGF, bFGF) on glial precursor cell proliferation: age dependency and brain region specificity.
Dev Biol
152:363-372[ISI][Medline].
-
Engele J,
Schilling K
(1996)
Growth factor-induced c-fos expression defines distinct subsets of midbrain dopaminergic neurons.
Neuroscience
73:397-406[ISI][Medline].
-
Fairman WA,
Vandenberg RJ,
Arriza JL,
Kavanaugh MP,
Amara SG
(1995)
An excitatory amino acid transporter with properties of a ligand-gated chloride channel.
Nature
375:599-603[Medline].
-
Franke B,
Figiel M,
Engele J
(1998)
CNS glia are targets for GDNF and neurturin.
Histochem Cell Biol
110:595-601[Medline].
-
Garlin AB,
Sinor AD,
Sinor JD,
Jee SH,
Grinspan JB,
Robinson MB
(1995)
Pharmacology of sodium-dependent high-affinity L-[3H]glutamate transport in glial cultures.
J Neurochem
64:2572-2580[ISI][Medline].
-
Gegelashvili G,
Schousboe A
(1998)
Cellular distribution and kinetic properties of high-affinity glutamate transporters.
Brain Res Bull
45:233-238[ISI][Medline].
-
Hallermayer K,
Hamprecht B
(1984)
Cellular and functional heterogeneity in primary cultures of brain cells revealed by immunocytochemical localization of glutamine synthetase.
Brain Res
295:1-11[ISI][Medline].
-
Harmar AJ,
Arimura A,
Gozes I,
Journot L,
Laburthe M,
Pisegna JR,
Rawlings SR,
Robberecht P,
Said SI,
Sreedharn SP,
Wank SA,
Waschek JA
(1998)
International Union of Pharmacology. XVIII. Nomenclature of receptors for vasoactive intestinal peptide and pituitary adenylate cyclase-activating polypeptide.
Pharmacol Rev
50:265-270[Abstract/Free Full Text].
-
Hayashi M,
Hayashi R,
Tanii H,
Hashimoto K,
Patel AJ
(1988)
The influence of neuronal cells on the development of glutamine synthetase in astrocytes in vitro.
Dev Brain Res
41:37-42.
-
Kanai Y,
Hediger MA
(1992)
Primary structure and functional characterization of a high-affinity glutamate transporter.
Nature
360:467-471[Medline].
-
Kienlen-Campard P,
Crochemore C,
Rene F,
Monnier D,
Koch B,
Loeffler JP
(1997)
PACAP type 1 receptor activation promotes cerebellar neuronal survival through the cAMP/PKA signaling pathway.
DNA Cell Biol
16:323-333[ISI][Medline].
-
Kivipelto L,
Absood A,
Arimura A,
Sundler F,
Hakason R,
Panula P
(1992)
The distribution of pituitary adenylate cyclase-activating polypeptide-like immunoreactivity is distinct from helodermin- and helospectin-like immunoreactivities in the rat brain.
J Chem Neuroanat
5:85-94[ISI][Medline].
-
Koves K,
Arimura A,
Gorcs TG,
Somogyvari-Vigh A
(1991)
Comparative distribution of immunoreactive pituitary adenylate cyclase-activating polypeptide and vasoactive intestinal polypeptide in rat forebrain.
Neuroendocrinology
54:159-169[ISI][Medline].
-
Lazarovici P,
Jiang H,
Fink Jr D
(1998)
The 38-amino-acid form of pituitary adenylate cyclase-activating polypeptide induces neurite outgrowth in PC12 cells that is dependent on protein kinase C and extracellular signal-regulated kinase, but not on protein kinase A, nerve growth factor receptor tyrosine kinase, p21ras G-protein, and pp60c-src cytoplasmic tyrosine kinase.
Mol Pharmacol
54:547-558[Abstract/Free Full Text].
-
Lehre KP,
Levy LM,
Ottersen OP,
Storm-Mathisen J,
Danbolt NC
(1995)
Differential expression of two glial glutamate transporters in the rat brain: quantitative and immunocytochemical observations.
J Neurosci
15:1835-1853[Abstract].
-
Lin C-LG,
Tzingounis AV,
Jin L,
Furuta A,
Kavanaugh M,
Rothstein JD
(1998)
Molecular cloning and expression of the rat EAAT4 glutamate transporter subtype.
Mol Brain Res
63:174-179[Medline].
-
Liu GJ,
Madsen BW
(1997)
PACAP-38 modulates activity of NMDA receptors in cultured chick cortical neurons.
J Neurophysiol
78:2231-2234[Abstract/Free Full Text].
-
Lu N,
Zhou R,
DiCocco-Bloom E
(1998)
Opposing mitogenic regulation of PACAP in sympathetic and cerebral cortical precursors correlates with differential expression of PACAP receptor (PAC1-R) isoforms.
J Neurosci Res
53:651-662[Medline].
-
Magistretti PJ,
Cardinaux J-R,
Martin J-L
(1998)
VIP and PACAP in the CNS: regulators of glial energy metabolism and modulators of glutamatergic signaling.
Ann NY Acad Sci
865:213-225[Abstract/Free Full Text].
-
Martin J-L,
Gasser D,
Magistretti PJ
(1995)
Vasoactive intestinal peptide and pituitary adenylate cyclase-activating polypeptide potentiate c-fos expression induced by glutamate in cultured cortical neurons.
J Neurochem
65:1-9[ISI][Medline].
-
Mikkelsen JD,
Hannibal J,
Larsen PJ,
Fahrenkrug J
(1994)
Pituitary adenylate cyclase-activating peptide (PACAP) mRNA in the rat neocortex.
Neurosci Lett
171:121-124[Medline].
-
Moroo I,
Tatsuno I,
Uchida D,
Tanaka T,
Saito J,
Saito Y,
Hirai A
(1998)
Pituitary adenylate cyclase-activating polypeptide (PACAP) stimulates mitogen-activated protein kinase (MAPK) in cultured rat astrocytes.
Brain Res
795:191-196[Medline].
-
Nielsen HS,
Hannibal J,
Fahrenkrug J
(1998)
Embryonic expression of pituitary adenylate cyclase-activating polypeptide in sensory and autonomic ganglia and in the spinal cord of the rat.
J Comp Neurol
394:403-415[Medline].
-
Olney JW
(1990)
Excitotoxic amino acids and neuropsychiatric disorders.
Annu Rev Pharmacol Toxicol
30:47-71[ISI][Medline].
-
Pantaloni C,
Brabet P,
Bilanges B,
Dumuis A,
Housami S,
Spengler D,
Bockaert J,
Journot L
(1996)
Alternative splicing in the N-terminal extracellular domain of the pituitary adenylate cyclase-activating polypeptide (PACAP) receptor modulates receptor selectivity and relative potencies of PACAP-27 and PACAP-38 in phospholipase C activation.
J Biol Chem
271:22146-22151[Abstract/Free Full Text].
-
Pellegri G,
Magistretti PJ,
Martin J-L
(1998)
VIP and PACAP potentiate the action of glutamate on BDNF expression in mouse cortical neurones.
Eur J Neurosci
10:272-280[ISI][Medline].
-
Pesce AM,
Cibati M,
Dell'Anna L,
Fiorilli M,
Carbonari M
(1996)
Optimization of quantitative co-amplification of beta-globin and HIV-1 sequences.
Trends Genet
12:447-448[Medline].
-
Pines G,
Danbolt NC,
Bjoras M,
Zhang Y,
Bendahan A,
Eide L,
Koepsell H,
Strom-Mathisen J,
Seeberg E,
Kanner BI
(1992)
Cloning and expression of a rat L-glutamate transporter.
Nature
360:464-467[Medline].
-
Rawlings S,
Hezareh M
(1996)
Pituitary adenylate cyclase-activating polypeptide (PACAP) and PACAP/VIP receptors: actions on the anterior pituitary gland.
Endocr Rev
17:4-29[ISI][Medline].
-
Rothstein JD,
Martin L,
Levey AI,
Dykes-Hoberg M,
Jin L,
Wu D,
Nash N,
Kuncl RW
(1994)
Localization of neuronal and glial glutamate transporters.
Neuron
13:713-725[ISI][Medline].
-
Rothstein JD,
Dykes-Hoberg M,
Pardo CA,
Bristol LA,
Jin L,
Kuncl RW,
Kanai Y,
Hediger MA,
Wang Y,
Schielke JP,
Welty DF
(1996)
Knockout of glutamate transporters reveals a major role for astroglial transport in excitotoxicity and clearance of glutamate.
Neuron
16:675-686[ISI][Medline].
-
Schilling K,
Luk D,
Morgan JI,
Curran T
(1991)
Regulation of fos-lacZ fusion gene: a paradigm for quantitative analysis of stimulus transcription coupling.
Proc Natl Acad Sci USA
88:5665-5669[Abstract/Free Full Text].
-
Schlag BD,
Vondrasek JR,
Munir M,
Kalandadze A,
Zelenaia OA,
Rothstein JD,
Robinson MB
(1998)
Regulation of glial Na+-dependent glutamate transporters by cyclic AMP analogs and neurons.
Mol Pharmacol
53:355-369[Abstract/Free Full Text].
-
Smeyne RJ,
Schilling K,
Robertson L,
Luk D,
Oberdick J,
Curran T,
Morgan JI
(1992)
Fos-lacZ transgenic mice: mapping sites of gene induction in the central nervous system.
Neuron
8:13-23[ISI][Medline].
-
Sonnewald U,
Westergaard N,
Schousboe A
(1997)
Glutamate transport and metabolism in astrocytes.
Glia
21:56-63[ISI][Medline].
-
Spengler D,
Waeber C,
Pantaloni C,
Holsboer F,
Bockaert J,
Seeburg PH,
Journot L
(1993)
Differential signal transduction by five splice variants of the PACAP receptor.
Nature
365:170-175[Medline].
-
Stella N,
Magistretti PJ
(1996)
Vasoactive intestinal peptide (VIP) and pituitary adenylate cyclase-activating polypeptide (PACAP) potentiate the glutamate-evoked release of arachidonic acid from mouse cortical neurons. Evidence for a cAMP-independent mechanism.
J Biol Chem
271:23705-23710[Abstract/Free Full Text].
-
Storck T,
Schulte S,
Hofmann S,
Stoffel W
(1992)
Structure, expression, and functional analysis of a Na+-dependent glutamate/aspartate transporter from rat brain.
Proc Natl Acad Sci USA
89:10955-10959[Abstract/Free Full Text].
-
|
TOP
ABSTRACT
INTRODUCTION
