 |
 Previous Article | Next Article 
The Journal of Neuroscience, December 1, 1998, 18(23):9594-9600
Neuroprotection by Glial Metabotropic Glutamate Receptors Is
Mediated by Transforming Growth Factor-
V.
Bruno1,
G.
Battaglia1,
G.
Casabona1,
A.
Copani2,
F.
Caciagli3, and
F.
Nicoletti1, 2
1 Istituto Neurologico Mediterraneo Neuromed, 86077 Pozzilli, Italy, 2 Institute of Pharmacology, School
of Pharmacy, University of Catania, 95125 Catania, Italy, and
3 Department of Pharmacological Sciences, University of
Chieti, 66013 Chieti, Italy
 |
ABSTRACT |
The medium collected from cultured astrocytes transiently exposed
to the group-II metabotropic glutamate (mGlu) receptor agonists (2S,1'R,2'R,3'R)-2-(2,3-dicarboxycyclopropyl)glycine
(DCG-IV) or (S)-4-carboxy-3-hydroxyphenylglycine (4C3HPG) is
neuroprotective when transferred to mixed cortical cultures challenged
with NMDA (Bruno et al., 1997 ). The following data indicate that
this particular form of neuroprotection is mediated by transforming
growth factor- (TGF). (1) TGF1 and -2 were highly
neuroprotective against NMDA toxicity, and their action was less than
additive with that produced by the medium collected from astrocytes
treated with DCG-IV or 4C3HPG (GM/DCG-IV or GM/4C3HPG); (2) antibodies
that specifically neutralized the actions of TGF1 or -2 prevented the neuroprotective activity of DCG-IV or 4C3HPG, as well as the activity of GM/DCG-IV or GM/4C3HPG; and (3) a transient exposure of
cultured astrocytes to either DCG-IV or 4C3HPG led to a delayed increase in both intracellular and extracellular levels of TGF. We
therefore conclude that a transient activation of group-II mGlu
receptors (presumably mGlu3 receptors) in astrocytes leads to an
increased formation and release of TGF, which in turn protects neighbor neurons against excitotoxic death. These results offer a new
strategy for increasing the local production of neuroprotective factors
in the CNS.
Key words:
metabotropic glutamate receptors; glial cells; transforming growth factor-; neuroprotection; excitotoxic neuronal
death; astrocyte; cortical cultures
| |
INTRODUCTION |
Metabotropic glutamate (mGlu)
receptors form a family of eight subtypes (mGlu1-8), which have been
subdivided into three groups. Group-I includes mGlu1 and -5, which are
coupled to polyphosphoinositide (PI) hydrolysis as well as to various
classes of K+ channels via a Go or
Gq GTP binding protein (for review, see Pin and Duvoisin,
1995). Group-II (mGlu2 and -3) and group-III (mGlu4, -6, -7, -8)
receptors are coupled to a Gi-protein, and their activation
inhibits adenylyl cyclase activity in heterologous expression systems
(Tanabe et al., 1992, 1993). However, native group-II or group-III mGlu
receptors in the CNS are coupled to multiple transduction pathways,
including inhibition of voltage-sensitive Ca2+
channels, stimulation or inhibition of cAMP formation, stimulation of
PI hydrolysis, and activation of the mitogen-activated protein (MAP)
kinase pathway (Winder and Conn, 1992; Genazzani et al., 1994; for
review, see Pin and Duvoisin, 1995).
Recently, mGlu receptors have been considered a potential target for
neuroprotective drugs. In particular, activation of group-II or
group-III mGlu receptors protects neurons against excitotoxic death or
other forms of degeneration (for review, see Nicoletti et al., 1996).
However, the mechanism responsible for neuroprotection differs between
these two classes of mGlu receptor subtypes. mGlu4, -7, and -8 receptors are exclusively localized in neurons, and their activation
inhibits glutamate release (Shigemoto et al., 1997). Hence, group-III
mGlu receptor agonists are of potential value in the experimental
therapy of epilepsy or neurodegenerative disorders of excitotoxic
origin. In contrast, inhibition of glutamate release may contribute to,
but is not sufficient to explain, neuroprotection mediated by group-II
mGlu receptors. Accordingly, mGlu2 or -3 receptor agonists protect not
only against excitotoxic death but also against apoptosis induced by
-amyloid peptide or hypoxia combined with glucose deprivation in the
presence of a mixture of ionotropic receptor antagonists, i.e., under
conditions in which neurodegeneration develops in the absence of any
excitotoxic component (Buisson and Choi, 1995; Copani et al.,
1995). We recently showed that neuroprotection mediated by group-II
mGlu receptors involves a novel form of glial-neuronal interaction,
which is promoted by the activation of mGlu3 receptors present in
astrocytes (Bruno et al., 1997). The medium collected from cultured
astrocytes 2-20 hr after a brief exposure to mGlu3 receptor agonists
is highly neuroprotective against NMDA toxicity (Bruno et al., 1997,
1998). Neuroprotection is attenuated after treating the astrocytes with cycloheximide or after heating the medium, suggesting that astrocytes produce and release a proteic neuroprotective factor in response to
mGlu3 receptor activation (Bruno et al., 1997). This novel mechanism
may offer a new strategy to increase the local production of
neurotrophic factors in the CNS. We now demonstrate that
neuroprotection by glial mGlu3 receptors is mediated by transforming
growth factor-1 (TGF1) and TGF2, which are released from
astrocytes and exert a potent neuroprotective activity in in
vitro and in vivo models of excitotoxic death.
| |
MATERIALS AND METHODS |
Mixed cortical cultures. Mixed cortical cultures
containing both neurons and astrocytes were prepared from fetal mice at
14-16 d of gestation, as described by Rose et al. (1992). In brief, dissociated cortical cells were plated in 15 mm multiwell vessels (Falcon Primaria, Lincoln Park, NY) on a layer of confluent astrocytes [prepared as described by Rose et al. (1992)], using a plating medium
of MEM-Eagle's salts (supplied glutamine-free) supplemented with 5% heat-inactivated horse serum, 5% fetal bovine serum,
glutamine (2 mM), glucose (21 mM), and
NaHCO3 (25 mM). After 3-5 d in
vitro (DIV), non-neuronal cell division was halted by a 1-3 d
exposure to 10 µM cytosine arabinoside, and cultures were
shifted to a maintenance medium identical to plating medium but lacking
fetal bovine serum. Subsequent partial medium replacement was performed twice a week. Cultures at 13-14 DIV were used.
Glial cultures. Glial cell cultures were prepared from
postnatal mice (1-3 d after birth), as described previously (Rose et al., 1992). Dissociated cortical cells were grown in 15 mm multiwell vessels using a plating medium of MEM-Eagle's salts supplemented with
10% of heat-inactivated horse serum, 10% fetal bovine serum, 2 mM glutamine, sodium bicarbonate (25 mM), and
glucose (21 mM). Cultures were kept at 37°C in a
humidified CO2 atmosphere until they reached confluency
(7-14 DIV). Confluent cultures were then used for the experiments or
as a support for mixed cultures.
Assessment of neuronal death in culture. For induction of
excitotoxic death, mixed cultures were exposed to NMDA for 10 min at
room temperature in a HEPES-buffered salt solution containing (in
mM): 120 NaCl, 5.4 KCl, 0.8 MgCl2, 1.8 CaCl2, 20 HEPES, and 15 glucose. Afterward, the
cultures were extensively washed and incubated in MEM-Eagle's
(supplemented with 25 mM NaHCO3 and 21 mM glucose) (MS) at 37°C. In some experiments, glial
conditioned medium (GM) was added to the cultures immediately after the
NMDA pulse and maintained during the following 24 hr of incubation. GM
was prepared as follows. Glial cortical cultures were exposed for 10 min to group-II mGlu receptor agonists, and then drugs were washed out
and cultures were kept in MS (which does not contain serum) at 37°C
for the following 20 hr. At the end of this incubation, the medium was
collected and immediately transferred to mixed cultures.
Neuronal injury was estimated by examining the cultures with
phase-contrast microscopy 24 hr after the insult, when the process of
cell death was largely complete. Neuronal damage was quantitatively assessed by trypan blue staining. Stained neurons were counted from
three random fields per well. Neuronal injury was also assessed by
measuring the activity of lactate dehydrogenase (LDH) into the
extracellular medium, as described in Koh and Choi (1987).
Western blot analysis. Cultured astrocytes were harvested at
4°C in a 10 mM Tris buffer, pH 7.4, containing 5 mM EDTA, 1 mM PMSF, 25 µg/ml leupeptin, and
0.5% aprotinin. After sonication, samples were centrifuged at 8000 rpm
for 10 min, and an aliquot of the supernatants was processed for the
assessment of protein concentration by the Bredford method. Samples
were diluted in SDS-bromophenol blue buffer and boiled for 5 min before
loading. Electrophoresis was performed in 15% SDS-PAGE using 40 µg
of total protein per lane. After separation, proteins were transferred onto a nitrocellulose membrane (Hybond ECL) for 35 min using a Bio-Rad
transblot system (Bio-Rad, Munchen, Germany). After blocking, membranes
were incubated with primary antibodies for 1 hr at room temperature and
then repeatedly washed and exposed to horseradish peroxidase-conjugated
secondary antibodies for 1 hr at room temperature. Proteins were
visualized using the enhancing chemiluminescence detection system
(ECL). The following primary antibodies were used: rabbit polyclonal
TGF2 antibody (Santa Cruz Biotechnology, Tebu, France) (final
dilution: 500 ng/ml) and monoclonal anti-actin antibody (Sigma, St.
Louis, MO) (1:1000 dilution).
Measurement of TGF in the astrocyte medium. The amount of
TGF released from cultured astrocytes in the medium was measured by
using a sensitive bioassay based on the ability of TGF to reduce the
proliferation rate of mink lung cells. Mink lung cells were purchased
from American Type Culture Collection and plated in 15 mm multiwell
vessels (Falcon Primaria) using a plating medium of DMEM containing 0.1 mM nonessential amino acids, 1 mM sodium pyruvate, 2 mM glutamine, and 10% fetal bovine serum.
Twenty-four hours after plating, cells were exposed to GM in the
presence of 0.5 µCi/well of [methyl-3H]thymidine at
37°C for 24 hr. [Methyl-3H]thymidine incorporation has
been assessed as described by Ciccarelli et al. (1997). Standard curves
were constructed by using concentrations of human recombinant TGF1
or -2 ranging from 0.1 pg/ml to 10 ng/ml.
The amount of TGF1 present in the GM was also assessed by the
TGF1 Emax ELISA System (Promega) which is designed to
specifically detect biologically active TGF1.
Assessment of in vivo neuronal injury. Male
Sprague Dawley rats (250-300 gm, body weight) were anesthetized with
pentobarbital (50 mg/kg, i.p.) and infused with NMDA (100 nmol/0.5 µl
per 2 min) or NMDA + TGF1 or -2 (0.5 ng/0.5 µl) in the left
caudate nucleus, at +2.0 mm anteroposterior (AP), 2.6 mm lateral (L), and 5 mm ventral (V), according to the Pellegrino and Cushman (Pellegrino et al., 1992) atlas. The injection was repeated at a
second site (+1 mm AP, 2.6 mm L, and 5 mm V) to obtain a more consistent loss of striatal neurons. Animals were killed by
decapitation 7 d later. Neuronal toxicity was evaluated either by
histological examination or by measuring striatal glutamate
decarboxylase (GAD) activity as a marker for GABAergic neurons. For
histological analysis, the brains were removed, frozen rapidly in
isopentane at  40°C, and then stored at 80°C. Cryostat sections
(20 µm) were Nissl-stained and examined in light microscopy. For
measurements of GAD activity, the corpus striatum was dissected
bilaterally and homogenized in 5 mM imidazol buffer
containing 0.2% Triton X-100 and 10 mM dithiothreitol. An
aliquot of the homogenate was incubated in 400 µl of 10 mM phosphate buffer, pH 7.0, containing 10 mM
2-mercaptoethanol, 0.02 mM pyridoxalphosphate, and 1 µCi
of [3H]-glutamate (Amersham; specific
activity 46 Ci/mmol) for 1 hr at 37°C; the reaction was
stopped with 15 µl of ice-cold 11.8N HClO4. After
centrifugation in a microfuge at maximal speed, 10 µl of the
supernatant was diluted with 0.01N HCl and derivatized with
O-phthalaldehyde and mercaptoethanol for 1 min at room
temperature before injection into HPLC. The HPLC apparatus consisted of
a programmable solvent module 126 (Beckman Instruments, Fullerton CA),
an analytical C-18 reverse-phase column kept at 30°C (Ultrasphere ODS
5 µm spherical, 80 A pore, 2 mm × 15 cm; Beckman
Instruments), and an RF-551 spectrofluorometric detector (Shimadzu).
Excitation and emission were set at 360 and 450 nm, respectively. The
mobile phase consisted of (1) 50 mM sodium phosphate/10%
methanol, pH 7.2, and (2) 50 mM sodium phosphate/70%
methanol, pH 7.2. After 8 min of isocratic conditions with 98% (1) and
2% (2), (2) was increased up to 40% in 30 min and then to 98% in 1 min and maintained at 98% for 11 min before returning to the initial
conditions. The radioactivity coeluting with GABA was collected and
counted by scintillation spectrometry. Protein concentrations in the
original samples were determined by using a commercially available kit (Bio-Rad protein assay).
Materials. Ciliary neurotrophic factor (CNTF), glial-derived
neurotrophic factor (GDNF), basic fibroblast growth factor (bFGF), tumor necrosis factor- (TNF-), and human recombinant TGF1 or -2 were purchased from Sigma. Antibodies specific for TGF1
(catalog #sc-146) or TGF2 (catalog #sc-90) were purchased from Santa
Cruz Biotechnology. Both antibodies are reactive against human, rat, and mouse TGF1 or -2. DCG-IV, 4C3HPG,
L-2-amino-4-phosphonobutanoic acid (L-AP4), and
NMDA were purchased from Tocris Cookson.
| |
RESULTS |
TGF protects cultured neurons against excitotoxic death and
mediates neuroprotection by glial group-II mGlu receptors
A 10 min exposure of mixed cortical cultures to 100 µM NMDA produced the delayed degeneration of ~80% of
the neuronal population (Table 1). NMDA
toxicity was attenuated by the medium collected from pure cultures of
astrocytes (GM) 2 or 20 hr after a 10 min exposure to 1 µM DCG-IV (GM/DCG-IV) or 100 µM 4C3HPG
(GM/4C3HPG) [Table 1; see Bruno et al. (1997) for a more detailed
characterization]. We started the search for the neuroprotective agent
present in the GM/DCG-IV or GM/4C3HPG by screening a number of trophic
factor for their neuroprotective activity against NMDA toxicity.
Factors were either combined with NMDA for 10 min or applied
immediately after the NMDA pulse and then maintained in the medium for
the following 20 hr. Under both conditions, TGF1 and -2 displayed the highest neuroprotective activity, followed by that of bFGF. GDNF,
CNTF, and TNF- produced little, if any, neuroprotection (Fig.
1). We have not examined the effect of
nerve growth factor or other neurotrophins, because they are reported
not to affect or even amplify NMDA toxicity in mixed cortical cultures
(Koh et al., 1995).
View this table:
[in this window]
[in a new window]
|
Table 1.
Neuroprotection by the medium collected from glial cultures
2 or 20 hr after a transient exposure to group-II mGlu receptor
agonists
|
|
View larger version (50K):
[in this window]
[in a new window]
|
Figure 1.
Effect of trophic factors on NMDA toxicity in
mixed cultures of cortical cells. Factors were either combined with
NMDA (coadded) or applied to the cultures immediately
after the NMDA pulse and maintained in the medium during the following
20 hr (post). Values are means ± SEM of
four to six determinations from two different multiplates and were
calculated from the counts of neurons stained with trypan blue. Results
were virtually identical when calculated from the extracellular LDH
activity, which was always measured in parallel. In each multiplate,
the mean of values obtained from individual dishes treated with NMDA
alone, after subtracting the basal values, was considered as 100% or
NMDA toxicity. Each individual determination was expressed as
percentage of NMDA toxicity, always after subtracting the respective
basal values. The SD calculated from the original counts of neurons
stained with trypan blue was always <10% of the mean value for each
experimental group. *p < 0.01 (one-way ANOVA + Fisher PLSD), if compared with values obtained with NMDA alone.
|
|
TGF1 and -2 were equipotent as neuroprotectants against NMDA
toxicity, and their efficacy was essentially similar (Fig. 2). TGF1 or -2 did not produce any
further neuroprotection when combined with DCG-IV or 4C3HPG (Fig.
3A) or with GM/DCG-IV (Fig. 3B). In contrast, the neuroprotective activity of
L-AP4 (100 µM) was additive with that
produced by GM/DCG-IV (Fig. 3B).
View larger version (16K):
[in this window]
[in a new window]
|
Figure 2.
Concentration-dependent neuroprotection by TGF1
or -2 against NMDA toxicity in mixed cultures of cortical cells.
TGF1 or -2 were applied immediately after the NMDA pulse and
maintained in the medium during the following 20 hr. Values are
means ± SEM of four individual determinations and were calculated
from the counts of neurons stained with trypan blue, as described in
Figure 1.
|
|
View larger version (25K):
[in this window]
[in a new window]
|
Figure 3.
A, Lack of additive effects between
TGF1 or -2 and group-II mGlu receptor agonists on NMDA toxicity
in mixed cortical cultures. DCG-IV (1 µM) or 4C3HPG (100 µM) were applied in combination with NMDA, whereas
TGF1 or -2 (both at 1 ng/ml) were applied after the NMDA pulse.
Values are means ± SEM of four determinations. B,
The neuroprotective activity of TGF2 (1 ng/ml) is obliterated when
the factor is combined with the glial medium collected 20 hr after a 10 min exposure to 1 µM DCG-IV (GM/DCG-IV). Note that the
protective activity of L-AP4 (100 µM) is
instead additive to that produced by the medium of DCG-IV-treated
astrocytes. GM, Glial medium. Values are means ± SEM of four determinations. *p < 0.01 (one-way
ANOVA + Fisher PLSD) if compared with the respective controls. In
A and B, values were calculated from the
counts of neurons stained with trypan blue, as described in Figure
1.
|
|
We used antibodies specific for TGF1 or -2 (TGF1Ab or
TGF2Ab), which were able to neutralize the neuroprotective activity of exogenously applied TGF1 or -2 (Fig.
4A) but not that of bFGF (see legend of Fig. 4A). TGF1Ab or TGF2Ab
added to the GM/DCG-IV or GM/4C3HPG abolished neuroprotection, whereas
a neutralizing antibody against GDNF was inactive (Fig.
4B). Interestingly, TGF1Ab and TGF2Ab also
prevented the neuroprotective activity of group-II mGlu receptor
agonists applied in combination with NMDA (Fig. 4C).
View larger version (24K):
[in this window]
[in a new window]
|
Figure 4.
A, Antibodies (Ab)
specific for TGF1 or -2 (both at 100 ng/ml) abolish the
neuroprotective activity of TGF1 and -2 (both at 10 ng/ml) in
mixed cortical cultures. Each of the factors and the respective
antibody were added to the cultures immediately after the NMDA pulse
and maintained in the medium during the following 20 hr. The
concentration of antibodies was 100 ng/ml. Values are means ± SEM
of eight determinations from two different experiments.
*p < 0.01 (Student's t test), if
compared with the respective values obtained in the absence of the
antibody. TGF1Ab at least did not prevent neuroprotection induced by
bFGF applied after the NMDA pulse [bFGF, 10 ng/ml = 70 ± 3.5; bFGF + TGF1Ab (100 ng/ml) = 66 ± 4.2; TGF1Ab
alone = 92 ± 6.3; n = 4, expressed as percentage of NMDA
toxicity]. B, TGF1Ab and TGF2 Ab (both at 100 ng/ml) prevent the neuroprotective activity of the glial medium
collected 20 hr after treating cultured astrocytes with 1 µM DCG-IV (GM/DCG-IV) or 100 µM 4C3HPG
(GM/4C3HPG). Note that antibodies against GDNF
(GDNFAb, 100 ng/ml) are inactive. All antibodies were
applied to the glial medium before it was transferred to mixed cortical
cultures. Values are means ± SEM of eight determinations from two
different experiments; *p < 0.01 (one-way ANOVA + Fisher PLSD) if compared with the respective controls.
C, TGF1Ab and TGF2Ab (all at 100 ng/ml) reduce the
neuroprotective activity of group-II mGlu receptor agonists in mixed
cortical cultures. DCG-IV (1 µM) or 4C3HPG (100 µM) were applied to the cultures during the 10 min pulse
with NMDA. Antibodies were applied immediately after the pulse and
maintained in the medium during the following 20 hr. Values are
means ± SEM of four determinations. *p < 0.01 (one-way ANOVA + Fisher PLSD), if compared with the respective
controls. In A-C, values were calculated from the
counts of neurons stained with trypan blue, as described in Figure
1.
|
|
We therefore examined whether astrocytes treated with group-II mGlu
receptor agonists release TGF into the medium by using a highly
sensitive and specific bioassay, based on the ability of TGF to
reduce the proliferation rate of mink lung epithelial cells. The
control GM (i.e., the medium collected from astrocytes 20 hr after
simple addition of the buffer) showed an antiproliferative activity
corresponding to that produced by 5 pg/ml of authentic human TGF1 or
-2. This activity increased several-fold 20 hr after a 10 min
exposure to DCG-IV or 4C3HPG (Table 2).
These results were confirmed by measuring the extracellular levels of TGF1 by ELISA (medium from control astrocytes = 6.4 ± 0.32 pg/ml; medium from astrocytes treated with 4C3HPG = 38 ± 0.45 pg/ml).
View this table:
[in this window]
[in a new window]
|
Table 2.
A transient activation of group-II mGlu receptors increases
the extracellular levels of TGF in cultured astrocytes
|
|
Finally, we measured the intracellular levels of TGF2 in response to
group-II mGlu receptor activation in astrocytes. Immunoblots of
cultured astrocytes showed a single band of 24-25 kDa, corresponding to the dimeric form of TGF (Fig. 5).
In control astrocytes, the intensity of this band decreased from 2 to
10 hr after a 10 min treatment with buffer followed by incubation in
serum-free medium. The intracellular levels of dimeric TGF2 were
substantially higher 2 or 10 hr after treating the cultures with DCG-IV
(Fig. 6). A similar increase in TGF2
was induced by the A1 adenosine receptor agonist
2-chloro-N6-cyclopentyladenosine
(CCPA) (Fig. 5).
View larger version (55K):
[in this window]
[in a new window]
|
Figure 5.
Western blot analysis of TGF2 in protein
extracts from cultured astrocytes transiently exposed to 1 µM DCG-IV or to 100 nM CCPA.
CTRL, Control astrocyte cultures treated with buffer
alone for 10 min, and then incubated for 2 or 10 hr in serum-free
medium (see Materials and Methods); DCG-IV, cultures
treated for 10 min with 1 µM DCG-IV and then incubated
for 2 or 10 hr in serum-free medium; CCPA, cultures
treated for 10 min with CCPA and then incubated for 2 or 10 hr in
serum-free medium. Expression of -actin is shown in the same protein
extracts. Authentic monomeric human TGF2 is shown in the
first lane.
|
|
View larger version (114K):
[in this window]
[in a new window]
|
Figure 6.
A-F, Local infusion of TGF1 or
-2 protects against NMDA toxicity in the rat caudate nucleus. The
core of the lesion in animals injected with NMDA, NMDA + TGF1, and
NMDA + TGF2 is shown in A, B, and
C, respectively. The white arrow points
to a large area of necrosis, which is absent in B and
C. Neuronal degeneration present at the periphery of the
lesion in animals injected with NMDA is shown in D. The
corresponding regions in animals injected with NMDA + TGF1 and NMDA + TGF2 are shown in E and F. The small
areas indicated by the white arrowheads are also shown
at higher magnification. Note the greater number of spared neurons in
animals treated with TGF1 or -2. G, Striatal GAD
activity in animal locally infused with NMDA or with NMDA + TGF1 or
NMDA + TGF2. Results are expressed as percentage of the respective
contralateral unlesioned site for each individual determination.
GAD activity was calculated as counts per minute of authentic
[3H]GABA/µg of protein. *p < 0.05 (one-way ANOVA + Fisher PLSD) versus NMDA alone.
|
|
Neuroprotective activity of TGF against in
vivo excitotoxicity
In animals infused with NMDA alone (100 nmol/0.5 µl per 2 min;
double injection) in the left caudate nucleus, histological analysis
showed an extensive necrotic region at the injection sites and neuronal
loss, reactive gliosis, and edema in the surrounding tissue. In animals
coinfused with NMDA and 0.5 ng of TGF1 or -2, the extension of
the necrotic area was smaller, and the neuronal loss in the surrounding
tissue was substantially reduced (Fig. 6A-F).
We have quantified the protective activity of TGF1 or -2 by
measuring striatal GAD activity, which reflects the survival of
GABAergic projection neurons and interneurons. Infusion of TGF1 or
-2 prevented the reduction in striatal GAD activity induced by NMDA
(Fig. 6G). Intrastriatal infusion of TGF1 or -2 alone
did not produce significant changes in GAD activity after 7 d
(data not shown).
| |
DISCUSSION |
The novel selective group-II mGlu receptor agonist
LY354740 protects pure neuronal cultures against excitotoxic death, but only at concentrations higher than those sufficient to interact with
mGlu2 or -3 receptors (Kingston et al., 1977). This casts doubt on the
role of group-II mGlu receptors in neuroprotection, although several
reports show a clear-cut protective activity of mGluR2/3 receptor
agonists (for review, see Nicoletti et al., 1996). We suggest that it
is the presence of astrocytes that enables neuroprotection by group-II
mGlu receptor agonists. Accordingly, a brief exposure of glial cultures
to the mGlu2/3 agonists DCG-IV, 4C3HPG, or
(2S,1'S,2'S)-2-(carboxycyclopropyl)glycine,
or to the selective mGlu3 receptor agonist
-N-acetylaspartylglutamate renders the medium
neuroprotective against excitotoxic death (Bruno et al., 1997, 1998).
This protective activity is abolished after heating the medium or after
treating the astrocytes with the protein synthesis inhibitor
cycloheximide (Bruno et al., 1997). Hence, we have hypothesized that
astrocytes treated with mGlu3 receptor agonists produce and release a
proteic neuroprotective factor. Present results identify this factor
with TGF, although they cannot exclude the possibility that other
factors are produced, the activity of which depends on TGF.
TGF1 and -2 showed a substantial neuroprotective activity
in vitro and in vivo, which, unexpectedly, was
greater than that exhibited by established neurotrophic factors such as
GDNF or CNTF. The protective activity of TGF is in agreement with
several recent reports (Prehn et al., 1994, 1996; Prehn, 1996; Ren and Flanders, 1996; Buisson et al., 1997) [but see also Kane et al. (1996)]. Protection by TGF1 or -2 was obscured by the medium collected from astrocytes treated with DCG-IV, and not because the
response was saturated: the group-III mGlu receptor agonist L-AP4 could in fact further enhance the protective activity
of the glial medium.
Untreated astrocytes released a low amount of TGF into the medium
(~5 pg/ml), which was below the threshold for neuroprotection. However, astrocytes transiently exposed to DCG-IV or 4C3HPG released a
five- to sevenfold greater amount of TGF (TGF1, -2, or both), which may account for the protective activity of the glial medium. Finally, we proved that TGF was necessary for the neuroprotective activity of the glial medium by using antibodies against TGF1 or
-2. Each of these antibodies abolished neuroprotection when applied
to the medium collected from astrocytes treated with DCG-IV or 4C3HPG.
Because the two antibodies are specific for their respective TGF
isoforms, we conclude that the combination of TGF1 and -2 released in the glial medium reaches the threshold for neuroprotection or (more likely) that TGF is released as a 1/2 heterodimer.
The glial medium acquires its neuroprotective activity at least 2 hr
after a transient activation of mGlu3 receptors, and neuroprotection
vanishes after astrocytes are treated with the protein synthesis
inhibitor cycloheximide (Bruno et al., 1997). Hence, we have considered
the possibility that activation of glial mGlu3 receptors enhances the
de novo synthesis of TGF. TGF is synthesized as a
dimer from the cleavage of a high molecular weight precursor
(Massaguè et al., 1994: Flanders et al., 1998). A dimeric form of
TGF containing TGF2 was detectable by Western blot analysis in
cultured astrocytes, and its levels decreased with time after the
cultures were incubated in the absence of serum (as we generally did in
all experiments in which we collected the glial medium). Intracellular
dimeric TGF increased substantially after the cultures were treated
with DCG-IV, suggesting that activation of mGlu3 receptors enhances the
de novo synthesis of TGF. We cannot exclude the
possibility, however, that mGlu3 receptor activation inhibits the
degradation rate of TGF and that neuroprotection is
cycloheximide-sensitive because it requires the synthesis of a
different protein that is necessary for the accumulation and release of
TGF. It is noteworthy that an increase in intracellular TGF
levels was also induced after transient activation of A1 adenosine
receptors, which share with group-II mGlu receptors the coupling with
the Gi type of GTP binding proteins (for review, see Collis
and Hourani, 1994). The  subunits released in large amounts from
trimeric Gi-proteins exert pleiotropic effects, including
activation of adenylyl cyclase types II or IV, phospholipase C, or the
MAP kinase pathway (for review, see Sternweis, 1994; Morris and
Scarlata, 1997). Whether any of these intracellular pathways
contributes to the production and release of TGF in response to
mGlu3 receptor activation will be the subject of future investigation.
The protective activity of TGF1 or -2 against NMDA toxicity may
provide new insights into the mechanism of neuronal degeneration. Both
TGF and group-II mGlu receptor agonists protect not only against
excitotoxic death but also against other forms of neurodegeneration, including neuronal apoptosis induced by -amyloid peptide (Copani et
al., 1995; Prehn et al., 1996; Ren et al., 1997). One can therefore speculate that TGF prevents the execution of a pathway that is common to various forms of neuronal degeneration. TGF1 or -2 interacts with membrane receptors endowed with intrinsic
serine/threonine kinase activity. Activation of these receptors leads
to the phosphorylation of the latent transcription factor Smad2, which
after complexing with Smad4 migrates to the nucleus where it activates
gene expression (Massaguè et al., 1994, 1997). Established target
genes of TGF are the "check points" p27 and p21, which produce
growth arrest by inhibiting the activity of cyclin-dependent kinases
(Datto et al., 1995; Ravitz, 1996). This mechanism may be
relevant for the neuroprotective activity of TGF, because the
induction of an abortive mitotic cycle has been causally related to the
development of neuronal degeneration (Freeman et al., 1995; Herrup and
Busser, 1995; Park et al., 1997a,b). Alternatively, TGF may
act to inhibit the expression of cyclooxygenase-2 (Minghetti et
al., 1998; Pruzanski et al., 1998), an enzyme that is upregulated in
response to synaptic excitation or -amyloid peptide and is
implicated in the pathophysiology of neuronal degeneration (Yamagata et
al., 1993; Adams et al., 1996; Pasinetti, 1997).
In conclusion, activation of glial mGlu3 receptors may provide a
mechanism for increasing the local production of TGF in the brain,
thereby protecting neurons against various toxic insults. Through this
particular mechanism, selective mGlu3 receptor agonists are expected to
exert a wide-range neuroprotective effect without causing the side
effects associated with use of NMDA or AMPA receptor antagonists, such
as sedation, impairment of synaptic plasticity, ataxia, or
psychotomimetic effects.
| |
FOOTNOTES |
Received July 6, 1998; revised Sept. 8, 1998; accepted Sept. 10, 1998.
Correspondence should be addressed to Dr. Ferdinando Nicoletti,
Institute of Pharmacology, School of Pharmacy, University of Catania,
Viale AA Doria 6, 95125 Catania, Italy.
| |
REFERENCES |
-
Adams J,
Collaco-Moraes Y,
de Belleroche J
(1996)
Cyclooxygenase-2 induction in cerebral cortex: an intracellular response to synaptic excitation.
J Neurochem
66:6-13[ISI][Medline].
-
Bruno V,
Sureda FX,
Storto M,
Casabona G,
Caruso A,
Knopfel T,
Kuhn R,
Nicoletti F
(1997)
The neuroprotective activity of group-II metabotropic glutamate receptors requires new protein synthesis and involves a glial-neuronal interaction.
J Neurosci
17:1891-1897[Abstract/Free Full Text].
-
Bruno V,
Wroblewska B,
Wroblewska JT,
Fiore L,
Nicoletti F
(1998)
Neuroprotective activity of N-acetylaspartylglutamate in cultured cortical cells.
Neuroscience
3:751-757.
-
Buisson A,
Choi DW
(1995)
The inhibitory mGluR agonist, S-4-carboxy-3-hydroxyphenylglycine, selectively attenuates NMDA neurotoxicity and oxygen-glucose deprivation-induced neuronal death.
Neuropharmacology
34:1081-1087[ISI][Medline].
-
Buisson A,
Nicole O,
Nouvelot A,
MacKenzie ET,
Vivien D
(1997)
Reduction of NMDA-induced toxicity by transforming growth factor-1.
Soc Neurosci Abstr
23:897.
-
Ciccarelli R,
Sureda FX,
Casabona G,
Di Iorio P,
Caruso A,
Spinella F,
Condorelli DF,
Nicoletti F,
Caciagli F
(1997)
Opposite influence of the metabotropic glutamate receptors subtypes mGlu3 and -5 on astrocyte proliferation in culture.
Glia
21:390-398[ISI][Medline].
-
Collis MG,
Hourani SMO
(1993)
Adenosine receptor subtypes.
Trends Pharmacol Sci
14:360-366[Medline].
-
Copani A,
Bruno V,
Battaglia G,
Leanza G,
Pellitteri R,
Russo A,
Stanzani S,
Nicoletti F
(1995)
Activation of metabotropic glutamate receptors protects against apoptosis induced by -amyloid peptide.
Mol Pharmacol
47:890-897[Abstract].
-
Datto MB,
Li Y,
Panus JF,
Howe DJ,
Xiong Y,
Wang XF
(1995)
Transforming growth factor beta induces the cyclin-dependent kinase inhibitor p21 through a p53-independent mechanism.
Proc Natl Acad Sci USA
92:5545-5549[Abstract/Free Full Text].
-
Flanders KC,
Ren RF,
Lippa CF
(1998)
Transforming growth factor-betas in neurodegenerative disease.
Prog Neurobiol
54:71-85[ISI][Medline].
-
Freeman RF,
Estus S,
Johnson Jr EM
(1994)
Analysis of cell-related gene expression in postmitotic neurons: selective induction of cyclin D1 during programmed cell death.
Neuron
12:343-355[ISI][Medline].
-
Genazzani AA,
L'Episcopo MR,
Casabona G,
Shinozaki H,
Nicoletti F
(1994)
(2S,1'R,2'R,3'R)-2-(2,3-dicarboxycyclopropyl)glycine positively modulates metabotropic glutamate receptors coupled to polyphosphoinositide hydrolysis in rat hippocampal slices.
Brain Res
659:10-16[Medline].
-
Herrup K,
Busser JC
(1995)
The induction of multiple cell cycle events precedes target-related neuronal death.
Development
121:2385-2395[Abstract].
-
Kane CJ,
Brown GJ,
Phelan KD
(1996)
Transforming growth factor-2 increases NMDA receptor-mediated excitotoxicity in rat cerebral cortical neurons independently of glia.
Neurosci Lett
204:93-96[ISI][Medline].
-
Kingston AE,
Bales KR,
Monn JA,
Paul SM,
Pullar IA,
Schoepp DD
(1997)
Comparison of the neuroprotective effects of mGluR agonists: (RS)-3,5-dihydroxyphenylglycine, LY354740 and L-amino-4-phosphonobutyric acid on ionotropic glutamate receptor-induced excitotoxicity in rat cortical neurons.
Soc Neurosci Abstr
23:899.
-
Koh JY,
Choi DW
(1987)
Quantitative determination of glutamate-mediated cortical neuronal injury in cell culture by lactate dehydrogenase efflux assay.
J Neurosci Methods
20:83-90[ISI][Medline].
-
Koh JY,
Gwag BJ,
Lobner D,
Choi DW
(1995)
Potentiated necrosis of cultured cortical neurons by neurotrophins.
Science
268:573-575[Abstract/Free Full Text].
-
Massaguè J,
Attisano L,
Wraba JL
(1994)
The TGF- family and its composite receptors.
Trends Cell Biol
4:172-178.[Medline]
-
Massaguè J,
Hata A,
Liu F
(1997)
TGF- signalling through the Smad pathway.
Trends Cell Biol
7:187-192.
-
Minghetti L,
Polazzi E,
Nicolini A,
Levi G
(1998)
Opposite regulation of prostaglandin E2 synthesis by transforming growth factor-1 and interleukin 10 in activated microglial cultures.
J Neuroimmunol
82:31-39[ISI][Medline].
-
Morris AJ,
Scarlata S
(1997)
Regulation of effectors by G protein alpha-, and beta gamma-subunits. Recent insights from studies of the phospholipase C-beta isoenzymes.
Biochem Pharmacol
54:429-435[ISI][Medline].
-
Nicoletti F,
Bruno V,
Copani A,
Casabona G,
Knoepfel T
(1996)
Metabotropic glutamate receptors: a new target for the therapy of neurodegenerative disorders?
Trends Neurosci
19:267-271[ISI][Medline].
-
Park DS,
Levine B,
Ferrari G,
Greene LA
(1997a)
Cyclin-dependent kinase inhibitors and dominant negative cyclin-dependent kinase 4 and 6 promote survival of NGF-deprived sympathetic neurons.
J Neurosci
17:8975-8983[Abstract/Free Full Text].
-
Park DS,
Morris EJ,
Greene LA,
Geller HM
(1997b)
G1/S Cell cycle blockers and inhibitors of cyclin-dependent kinases suppress camptothecin-induced neuronal apoptosis.
J Neurosci
17:1256-1270[Abstract/Free Full Text].
-
Pasinetti GM (1997) Cyclooxygenases and inflammation in
Alzheimer's disease: experimental approaches and therapeutical
implications. Abstract of the 36th Meeting of the American College
of Neuropsychopharmacology (ACNP), Waikoloa, Hawaii, December.
-
Pellegrino JL,
Pellegrino SA,
Cushman JA
(1992)
In: A stereotaxic atlas of the rat brain. New York: Plenum.
-
Pin JP,
Duvoisin R
(1995)
The metabotropic glutamate receptors: structure and functions.
Neuropharmacology
34:1-26[ISI][Medline].
-
Prehn JH
(1996)
Marked diversity in the action of growth factors on N-methyl-D-aspartate-induced neuronal degeneration.
Eur J Pharmacol
306:81-88[ISI][Medline].
-
Prehn JH,
Bindokas VP,
Marcuccilli CJ,
Krajewski S,
Reed JC,
Miller RJ
(1994)
Regulation of neuronal Bcl-2 protein expression and calcium homeostasis by transforming growth factor type beta confers wide ranging protection on rat hippocampal neurons.
Proc Natl Acad Sci USA
91:12599-12603[Abstract/Free Full Text].
-
Prehn JHM,
Bindokas VP,
Jordan J,
Galindo MF,
Ghadge GD,
Roos RP,
Boise LH,
Thomson CB,
Krajewski SW,
Reed JC,
Miller RJ
(1996)
Protective effect of transforming growth factor-1 on -amyloid neurotoxicity in rat hippocampal neurons.
Mol Pharmacol
49:319-328[Abstract].
-
Pruzanski W,
Stefanski E,
Vadas P,
Kennedy BP,
van den Bosch H
(1998)
Regulation of the cellular expression of secretory and cytosolic phospholipase A2, and cyclooxygenase-2 by peptide growth factors.
Biochim Biophys Acta
1403:47-56[Medline].
-
Ravitz MJ
(1996)
Differential regulation of p27 and cyclin D1 by TGF2 and EGF in C3H10T1/2 mouse fibroblasts.
J Cell Physiol
168:510-520[Medline].
-
Ren RF,
Flanders KC
(1996)
Transforming growth factors- protect primary rat hippocampal neuronal cultures from degeneration induced by -amyloid.
Brain Res
732:16-24[ISI][Medline].
-
Ren RF,
Hawver DB,
Kim RS,
Flanders KC
(1997)
Transforming growth factor- protects human hNT cells from degeneration induced by -amyloid peptide: involvement of the TGF- type II receptor.
Brain Res Mol Brain Res
48:315-322[Medline].
-
Rose K,
Goldberg MP,
Choi DW
(1992)
Cytotoxicity in murine neocortical cell culture.
In: Methods in toxicology, Vol 1, in vitro biological systems (Tyson CA,
Frazier JM,
eds), pp 46-60. San Diego: Academic.
-
Shigemoto R,
Kinoshita A,
Wada E,
Nomura S,
Ohishi H,
Takada M,
Flor PJ,
Neki A,
Abe T
(1997)
Differential presynaptic localization of metabotropic glutamate receptor subtypes in the rat.
J Neurosci
17:7503-7522[Abstract/Free Full Text].
-
Sternweis PC
(1994)
The active role of beta gamma in signal transduction.
Curr Opin Cell Biol
6:198-203[ISI][Medline].
-
Tanabe Y,
Masu M,
Ishii I,
Shigemoto R,
Mizuno N,
Nakanishi S
(1992)
A family of metabotropic receptors.
Neuron
8:169-172[ISI][Medline].
-
Tanabe Y,
Nomura A,
Masu M,
Shigemoto R,
Mizuno N,
Nakanishi S
(1993)
Signal transduction, pharmacological properties, and expression patterns of two rat metabotropic glutamate receptors, mGluR3 and mGluR4.
J Neurosci
13:1372-1378[Abstract].
-
Winder DC,
Conn PJ
(1993)
Activation of metabotropic glutamate receptors increases cAMP accumulation in hippocampus by potentiating responses to endogenous adenosine.
J Neurosci
13:38-44[Abstract].
-
Yamagata K,
Andreasson KI,
Kaufmann WE,
Barnes CA,
Worley PF
(1993)
Expression of mitogen-inducible cyclooxygenase in brain neurons: regulation by synaptic activity and glucocorticoids.
Neuron
11:371-386[ISI][Medline].
Copyright © 1998 Society for Neuroscience 0270-6474/98/18239594-07$05.00/0
This article has been cited by other articles:
|
|
|
|
 
M. J. Fell, K. A. Svensson, B. G. Johnson, and D. D. Schoepp
Evidence for the Role of Metabotropic Glutamate (mGlu)2 Not mGlu3 Receptors in the Preclinical Antipsychotic Pharmacology of the mGlu2/3 Receptor Agonist (-)-(1R,4S,5S,6S)-4-Amino-2-sulfonylbicyclo[3.1.0]hexane-4,6-dicarboxylic Acid (LY404039)
J. Pharmacol. Exp. Ther.,
July 1, 2008;
326(1):
209 - 217.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. Harrison, L. Lyon, L. Sartorius, P. Burnet, and T. Lane
Review: The group II metabotropic glutamate receptor 3 (mGluR3, mGlu3, GRM3): expression, function and involvement in schizophrenia
J Psychopharmacol,
May 1, 2008;
22(3):
308 - 322.
[Abstract]
[PDF]
|
|
|
|
|
|
|
E. E. Benarroch
N-Acetylaspartate and N-acetylaspartylglutamate: Neurobiology and clinical significance
Neurology,
April 15, 2008;
70(16):
1353 - 1357.
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Corti, G. Battaglia, G. Molinaro, B. Riozzi, A. Pittaluga, M. Corsi, M. Mugnaini, F. Nicoletti, and V. Bruno
The Use of Knock-Out Mice Unravels Distinct Roles for mGlu2 and mGlu3 Metabotropic Glutamate Receptors in Mechanisms of Neurodegeneration/Neuroprotection
J. Neurosci.,
August 1, 2007;
27(31):
8297 - 8308.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R. Ciccarelli, I. D'Alimonte, P. Ballerini, M. D'Auro, E. Nargi, S. Buccella, P. Di Iorio, V. Bruno, F. Nicoletti, and F. Caciagli
Molecular Signalling Mediating the Protective Effect of A1 Adenosine and mGlu3 Metabotropic Glutamate Receptor Activation against Apoptosis by Oxygen/Glucose Deprivation in Cultured Astrocytes
Mol. Pharmacol.,
May 1, 2007;
71(5):
1369 - 1380.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. M. Rorick-Kehn, B. G. Johnson, J. L. Burkey, R. A. Wright, D. O. Calligaro, G. J. Marek, E. S. Nisenbaum, J. T. Catlow, A. E. Kingston, D. D. Giera, et al.
Pharmacological and Pharmacokinetic Properties of a Structurally Novel, Potent, and Selective Metabotropic Glutamate 2/3 Receptor Agonist: In Vitro Characterization of Agonist (-)-(1R,4S,5S,6S)-4-Amino-2-sulfonylbicyclo[3.1.0]-hexane-4,6-dicarboxylic Acid (LY404039)
J. Pharmacol. Exp. Ther.,
April 1, 2007;
321(1):
308 - 317.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. C. Vernon, V. Zbarsky, K. P. Datla, D. T. Dexter, and M. J. Croucher
Selective Activation of Group III Metabotropic Glutamate Receptors by L-(+)-2-Amino-4-phosphonobutryic Acid Protects the Nigrostriatal System against 6-Hydroxydopamine Toxicity in Vivo
J. Pharmacol. Exp. Ther.,
January 1, 2007;
320(1):
397 - 409.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. M. Dhandapani, F. M. Wade, V. B. Mahesh, and D. W. Brann
Astrocyte-Derived Transforming Growth Factor-{beta} Mediates the Neuroprotective Effects of 17{beta}-Estradiol: Involvement of Nonclassical Genomic Signaling Pathways
Endocrinology,
June 1, 2005;
146(6):
2749 - 2759.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. A. Sortino, M. Chisari, S. Merlo, C. Vancheri, M. Caruso, F. Nicoletti, P. L. Canonico, and A. Copani
Glia Mediates the Neuroprotective Action of Estradiol on {beta}-Amyloid-Induced Neuronal Death
Endocrinology,
November 1, 2004;
145(11):
5080 - 5086.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. M. Dhandapani, M. Hadman, L. De Sevilla, M. F. Wade, V. B. Mahesh, and D. W. Brann
Astrocyte Protection of Neurons: ROLE OF TRANSFORMING GROWTH FACTOR-{beta} SIGNALING VIA A c-Jun-AP-1 PROTECTIVE PATHWAY
J. Biol. Chem.,
October 31, 2003;
278(44):
43329 - 43339.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
Top
Abstract
Introduction
