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The Journal of Neuroscience, May 1, 2002, 22(9):3434-3444
Long-Term Depression Induced by Postsynaptic Group II
Metabotropic Glutamate Receptors Linked to Phospholipase C and
Intracellular Calcium Rises in Rat Prefrontal Cortex
S.
Otani1,
H.
Daniel1,
M.
Takita2, and
F.
Crépel1
1 Neurobiologie des Processus Adaptatifs,
Université de Paris VI, 75005 Paris, France, and
2 Neurobionics Group, National Institute of Applied
Industrial Science and Technology, Tsukuba 305, Japan
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ABSTRACT |
We have previously shown (Otani et al., 1999b ) that bath
application of
(2S,2'R,3'R)-2-(2',3'-dicarboxycyclopropyl)glycine (DCG IV), the agonist of group II metabotropic glutamate
receptors (mGluRs), induces postsynaptic
Ca2+-dependent long-term depression (LTD) of layer
I-II to layer V pyramidal neuron glutamatergic synapses of rat medial
prefrontal cortex. In the present study, we examined detailed
mechanisms of this DCG IV-induced LTD. First, the group II mGluR
antagonist (RS)- -methylserine-O-phosphate
monophenyl ester blocked DCG IV-induced LTD, and another group
II agonist
(2S,3S,4S)-CCG/(2S,1'S,2'S)-2-(carboxycyclopropyl)glycine-induced LTD, suggesting that LTD is indeed mediated by the activation of group
II mGluRs. Second, DCG IV-induced LTD was blocked by the NMDA receptor
antagonist AP-5, whereas DCG IV did not potentiate NMDA
receptor-mediated synaptic responses. Interruption of single test
stimuli during DCG IV application blocked DCG IV-induced LTD. These
results suggest that small NMDA receptor-mediated responses evoked by
single synaptic stimuli contribute to DCG IV-induced LTD. Third, DCG
IV-induced LTD was blocked or reduced by the following drugs:
phospholipase C inhibitor U-73122 (bath-applied or
postsynaptically injected), postsynaptically injected IP3
receptor blocker heparin, phospholipase D-linked mGluR blocker PCCG-13,
PKC inhibitor RO318220, postsynaptically injected PKC inhibitor
PKC(19-36), and PKA inhibitor KT-5720. Fourth, fluorescent
Ca2+ analysis techniques revealed that DCG IV
increases Ca2+ concentration in prefrontal
layer V pyramidal neurons. These Ca2+ rises and the
LTD were both blocked by postsynaptic heparin in the same cells. Taken
together, these results suggest that postsynaptic group II mGluRs,
linked to phospholipase C and probably also phospholipase D, induce LTD
through postsynaptic PKC activation and IP3
receptor-mediated postsynaptic increases of Ca2+ concentration.
Key words:
long-term depression; synaptic plasticity; prefrontal
cortex; group II metabotropic glutamate receptors; IP3
receptors; calcium release; phospholipase C; phospholipase D; protein
kinase C; protein kinase A
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INTRODUCTION |
It is well known that primate
dorsolateral prefrontal cortex (PFC) plays important role in attention-
and memory-guided behavior, such as spatial working memory
(Goldman-Rakic, 1995), selection and remembering of relevant stimuli
(Rainer et al., 1998), and remembering of contextually relevant,
cross-modal stimulus association (Fuster et al., 2000). In rats, these
functions may be performed by prelimbic area (Zhart et al., 1997;
Birrell and Brown, 2000), i.e., the medial aspect of frontal cortex,
which may be anatomically analogous to human-primate PFC (Kolb, 1984).
Several examples of plasticity of glutamatergic synapses in rat
prelimbic area (hereafter called rat PFC) have been reported (Hirsch
and Crepel, 1990; Law-Tho et al., 1995; Vickery et al., 1997; Gurden et
al., 1999; Morris et al., 1999; Takita et al., 1999; Blond et al.,
2002). We have recently shown that the induction of long-term
depression (LTD) in rat PFC is facilitated by dopamine, and that this
LTD induction depends on concurrent synaptic activation of groups I and
II metabotropic glutamate receptors (mGluRs) (Otani et al., 1998b,
1999b). We proposed that a mechanism for the cooperativity between
dopamine receptors (DA-Rs) and the mGluRs for LTD induction is
postsynaptic converging activation of mitogen-activated protein kinases
(MAPKs) by these receptors. Somewhat surprisingly, in this study (Otani
et al., 1999b), we also found that LTD can be induced solely by
bath-application (10-15 min) of the potent group II mGluR agonist
(2S,2'R,3'R)-2-(2',3'-dicarboxycyclopropyl)glycine (DCG IV) (Ishida et al., 1993; Brabet et al., 1998). DCG IV-induced LTD
was blocked by postsynaptic injection of the
Ca2+ chelator
bis-(o-aminophenoxy)-N,N,N',N'-tetra-acetic acid
(BAPTA). The source of critical Ca2+ for
the DCG IV-induced LTD is not a flow through voltage-activated Ca2+ channels, because DCG IV did not
depolarize the postsynaptic membrane or increase neuronal excitability
or synaptic responses (Otani et al., 1999b).
These DCG IV data are inconsistent with the view that group II mGluRs
are presynaptically located and inhibitory in the forebrain neurons
(Baskys and Malenka, 1991; Lovinger, 1991). However, an immunohistological study suggests that group II mGluRs exist in postsynaptic sites in the cortex (Petralia et al., 1996). Moreover, biochemical data show that DCG IV increases the activity of
phospholipase C (PLC) and phospholipase D (PLD) in hippocampal slices
(Klein et al., 1997), or enhances the turnover of phosphoinositides in neonatal rat cerebral cortex slices (Mistry et al., 1998). Indeed, the
brain-abundant PLC- can be activated by  subunits of
Gi/o-type G-protein (Rebecchi and Pentyala,
2000). Gi/o-type G-protein is associated with
group II mGluRs (Conn and Pin, 1997), and its subunit inhibits
adenylate cyclase (Nestler and Duman, 1994). Thus, the available data
point to the possibility that activation of group II mGluRs can lead to
postsynaptic Ca2+ concentration
([Ca2+]) rises through release from
internal Ca2+ stores. In the present
study, therefore, we tested whether the group II mGluR agonist DCG IV
induces LTD through its postsynaptic action on PLC and
IP3 receptors, and through consequential
postsynaptic protein kinase activation and
Ca2+ rises.
Some of the results have appeared in abstract form (Otani et al.,
1998a, 1999a).
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MATERIALS AND METHODS |
Slice preparation and intracellular recording. Male
Sprague Dawley rats (23- to 30-d-old) were decapitated. The brain was rapidly removed, and coronal slices (300 µm; 2.2-3.7 mm from bregma) were sectioned by the use of a Campden vibratome in chilled ( 0°C) oxygenated (95% O2 and 5%
CO2) artificial CSF (ACSF). The
composition of ACSF was as follows (mM): NaCl
124, KCl 2, NaHCO326,
KH2PO4 1.15, MgCl2 1, CaCl22, and
D-glucose 11. The slices were allowed to recover
for at least 2 hr at room temperature (20°C) in a container filled
with continuously oxygenated ACSF. For the experiments, a slice was
transferred to a submerged-type recording chamber where it was perfused
with warmed ACSF (28°C) at the rate of 1 ml/min.
The soma of layer V pyramidal neurons in the prelimbic area of the
medial frontal cortex was penetrated by sharp, glass micropipettes filled with 3 M K-acetate (80-120 M tip resistance).
Negative currents were initially injected by the use of an Axoclamp 2A amplifier (Axon Instruments, Foster City, CA), but after stabilization of the cells, most or all currents were removed. The cells had mean
resting membrane potential of  72 ± 0.4 mV (SEM) with
initial input resistance of 48 ± 1.5 M. Mean membrane
potential held during the experiments was 73 ± 0.4 mV. Cells
that had stable membrane potential more negative than 65 mV, a spike
height approximately  70 mV, and initial input resistance of at least
30 M were considered healthy, and the experiments were started. When
cells showed a sign of degradation (a constant decline in any of these
parameters reaching more than ~10% changes of the initial values),
the experiments were stopped. The mode of spike discharge was routinely
examined before the experiment by the application of a depolarizing
current step (500 msec) from resting membrane potential. The intensity of the depolarizing step was set so that a 30 msec application at that
intensity caused the cell to discharge one action potential. Of 137 cells tested, 51 cells (37%) were classified as regular spiking cell,
and 33 cells (24%) as bursting cell. Twenty-two cells (16%) showed
initial bursting followed by regular spiking typically with adaptation.
The remaining 31 cells (23%) showed initial repetitive, or rather
sporadic, spikes that abruptly ceased by a strong adaptation. As in our
previous studies (Otani et al., 1998b, 1999b), there was no correlation
between a discharge mode and synaptic plasticity induction.
A bipolar, Teflon-coated tungsten stimulating electrode (external
diameter, 125 µm) was placed on layer I-II of the prelimbic area
(immediately interior to pial surface). The EPSP of ~10 mV amplitude
was evoked at 0.033 Hz by the application of monophasic square voltage
pulses (100 µsec duration; Digitimer isolated stimulator). During a
typical experiment, at least a 20 min period of baseline collection was
followed by a drug application phase. Then, the EPSP was continuously
monitored until 45 min after the beginning of the drug washout. All
evoked responses were fed to an Axoclamp 2A amplifier at
current-clamp mode and were digitized at 5-10 kHz with a Labmaster
interface and stored in an on-line IBM computer for later analyses
(ACQUIS1 program; developed by Dr. G. Sadoc, Institut Alfred Fessard,
Centre National de la Recherche Scientifique, Gif-sur-Yvette, France).
All experiments were performed in the presence of GABA-A
antagonist bicuculline methiodide (1 µM) in the bathing medium.
For the analysis of the EPSP, initial rising slope (1 msec period from
its onset; in millivolts per millisecond), which contains only a
monosynaptic component (Hirsch and Crepel, 1990), was measured. To
express changes in the EPSP slope, we typically averaged responses from
the 10 min period just before a drug application (baseline), the final
2-3 min period of the drug application phase (to assess acute effects
of drugs), and the 35-45 min period after the beginning of drug
washout (to assess long-term effects of the drugs). We then calculated
percentage of changes of the initial slope from the baseline value. In
the text, the 35-45 min period will be referred to as "40 min after
drug washout." These percentage changes were compared between
different drug groups. Statistical analyses (two-tailed Student's
t test) were performed with p < 0.05 considered as significant. All values were expressed as mean ± SEM.
For morphological identification of the neurons, biocytin (1.5%;
Sigma, St. Louis, MO) was routinely included in recording electrodes and allowed to diffuse to postsynaptic cells. Immediately after the termination of the experiments, the slices were fixed in 4%
paraformaldehyde dissolved in potassium PBS (0.01 M)
at least overnight. They were then washed in the PBS solution three times (10 min each) and placed in 1 ml of 0.1% PBS-Triton X-100 solution containing 25 µl of solution A (Avadin) and solution B
(biotinylated horseradish peroxidase H), as provided by Vectastain Standard ABC kit (Vector Laboratories, Burlingame, CA), for up to 48 hr. The slices were washed again in PBS solution. They were then placed
in diaminobenzidine tetrahydrochloride (DAB) solution (Peroxidase
Substrate Kit, SK-4100; Vector Laboratories) for 10 min. The slices
were washed three times in PBS solution before being mounted on
microscope slides.
Ca2+ analysis with fluorescent
indicators and patch-clamp recording. For global analysis of
Ca2+ concentration
([Ca2+]) in prefrontal areas (cf. Takita
et al., 1997), cortical slices were first stained with fura-2 AM (10 µM with 0.001% Cremophore EL, a nontoxic
surface-active reagent) for 30 min, then incubated in normal solution
for at least 1 hr at room temperature. A stained slice was mounted on a
thin glass (0.15 mm) chamber (300 µl bath volume) located above a
raised silicon-intensified target video camera attached to an emission
filter (510 nm), and was perfused with ACSF at the rate of 2 ml/min at
32°C. Two types of excitation light (340 and 360 nm) were applied
alternately by an automatic filter changer. The angles for the
excitation lights were each at 45°-oblique arranged by a diagonally
set dual light fiber. Camera images of 340 and 360 nm were accumulated
consecutively from 64 video frames and recorded every 30 sec by a
calcium image processor (Argus-50/CA; Hamamatsu, Tokyo, Japan). The
analysis was performed on the basis of 340:360 nm ratio images.
For single-neuron [Ca2+] analysis and
patch-clamp recording, layer V pyramidal neurons were selected by
visual guidance with Nomarski optic through a 40× water immersion
objective. All experiments were performed with whole-cell configuration
achieved at somatic level in the voltage-clamp mode, using an AXOPATCH
1D amplifier (Axon Instruments). The patch pipettes (2-3.5 M tip
resistance) were filled with internal solution containing
(mM): KCl or potassium gluconate 140, NaCl 8, HEPES 10, ATP-Mg 2, and 100 µM Fluo-3 (final pH 7.3 with KOH, 300 mOsm/l). Before starting a Ca2+
fluorometric recording session, or a fluorometric session combined with
electrophysiological recording, the neurons were initially recorded in
current-clamp mode, and neuronal discharge was tested by applying a
depolarizing current step. Only neurons exhibiting at least a spike
height of ~70 mV from resting membrane potential were retained to
continue experiments. Throughout the experiments, the cells were
maintained at a holding potential of 80 mV, and the passive
electrical properties as well as the stability of access resistances
were continuously monitored by the application of 10 mV
hyperpolarizing voltage steps. As previously described (Daniel et al.,
1999), fluorescence measurements were performed with the high-affinity
Ca2+-sensitive indicator fluo-3 loaded to
postsynaptic cells via patch pipettes. The fluorometric recording
session started 20-30 min after whole-cell "break in." This period
was required to allow dye diffusion and to washout background
fluorescence in the surrounding tissue that occurs by dye leakage
before sealing. The Ca2+-sensitive dye was
excited by light from a 100 W Xenon lamp, and epifluorescence
excitation wavelength was at 485 ± 22 nm. Emitted light was
collected by a photometer through a barrier filter at 530 ± 30 nm, from the area (40 × 40 µm) centered on the soma. Because
this single wavelength method does not determine absolute free
Ca2+ levels, fluorescence changes of
fluo-3 were expressed as a ratio to the initial background-corrected
resting fluorescence. The fluorescence data were analyzed both on-line
and off-line by the use of the ACQUIS1 program. For the sessions
combining Ca2+ fluorometric and
electrophysiological measurements, the EPSCs were evoked at
0.067 Hz by the application of monophasic square voltage pulses (20 µsec; Digitimer isolated stimulator) through a monopolar stimulating
electrode placed on layer I-II. As for intracellular experiments, all
electrical recordings achieved in the patch-clamp experiments were
analyzed both on-line and off-line by the use of the ACQUIS1 program.
Drugs used were: DL-2-amino-5-phosphonopentanoic acid
(DL-AP-5; Tocris Cookson, Bristol, UK),
(RS)-1-aminoindan-1,5-dicarboxylic acid (AIDA; Tocris
Cookson), bicuculline methiodide (Tocris Cookson), bisindolylmaleimide
IX methanesulfonate (RO 31-8220; Alexis Biochemicals, Paris,
France),
(2R,1'S,2'R,3'S)-2-(2'-carboxy-3'-phenylcyclopropyl)glycine (PCCG-13; Alexis Biochemicals),
(2S,3S,4S)-CCG/(2S,1'S,2'S)-2-(carboxycyclopropyl)glycine (L-CCG-I; Tocris Cookson),
(2S,2'R,3'R)-2-(2',3'-dicarboxycyclopropyl)glycine (DCG IV; Tocris Cookson), heparin (Prolabo), KT5720 (Alexis
Biochemicals), 1-[6-((17-3-methoxyestra-1,3,5(10)-trien-17-yl)-amino)hexyl]-1H-pyrrole-2,5-dione (U-73122; Calbiochem, La Jolla, CA),
(RS)--methylserine-O-phosphate monophenyl
ester (MSOPPE; Tocris Cookson), and protein kinase C (19-36) (Alexis Biochemicals).
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RESULTS |
DCG IV acts on group II mGluRs to induce LTD
As we have previously shown (Otani et al., 1999b), bath
application of specific group II mGluR agonist DCG IV (50-100
nM, 15 min) acutely depressed the EPSP of layer V pyramidal
neurons evoked by the stimulation of layer I-II fibers (38 ± 5.7% at the end of the drug application; n = 9), which
was followed by a partial recovery and a subsequent plateau, i.e., LTD
(Fig. 1A). The
postsynaptic membrane potential and input resistance were stable
throughout the course of the experiments (Fig. 1A).
Mean percentage decrease of the slope of the EPSP at 40 min after DCG IV washout was 20 ± 2.8% (n = 9). We have
already concluded (Otani et al., 1999b) that this DCG IV-induced LTD is
not a result of an insufficient washout of DCG IV, because a late
application of specific group II mGluR antagonist MSOPPE did not
reverse the DCG IV-induced LTD. Also, postsynaptic presence of BAPTA
spared acute depression and selectively blocked LTD phase. In this
study, first, we verified that DCG IV indeed acts on group II mGluRs to
initiate LTD by the use of MSOPPE (200-300
µM). MSOPPE was applied in the bath 10 min
before DCG IV application until the end of the DCG IV application. As
shown in Figure 1B, in the presence of MSOPPE
(n = 5), the acute depression induced by DCG IV was smaller, by ~50%, than that seen in the absence of MSOPPE (22 ± 4.2 vs 38 ± 5.7%; p< 0.05). Furthermore, LTD
induction by DCG IV was completely blocked in the presence of MSOPPE
(9.2 ± 4.9% 40 min after drug washout; n = 5;
p < 0.0002 vs DCG IV alone group). Membrane properties did
not change significantly during the experiments (Fig.
1B). However, the acute effect of DCG IV, albeit much
smaller than normal, was still present under the MSOPPE condition (see also the result of Huang et al., 1999). Therefore, to further confirm
that the LTD is induced by group II mGluR stimulation, we tested the
effect of another group II agonist L-CCG-I
(10-20 µM; Brabet et al., 1998) on the
synaptic transmission. L-CCG-I was applied in the
bath for 15 min. As shown in Figure 1C,
L-CCG-I caused a large acute synaptic depression
(70 ± 10% at the end of the application. n = 6), which was not accompanied by membrane depolarization, and induced
LTD (24 ± 7.6% at 40 min after washout; n = 6). The amplitude of L-CCG-I-induced LTD was
comparable to that of DCG IV-induced LTD (20 ± 2.8%).
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Figure 1.
Agonist stimulation of group II mGluRs induces LTD
in rat prefrontal neurons. A, Bath-application of the
potent group II mGluR agonist DCG IV (50-100 nM) acutely
depressed the slope of the monosynaptic EPSP (38 ± 5.7%
decrease at the end of drug application; n = 9) and
induced LTD (20 ± 2.8% decrease 40 min after drug washout;
n = 9). These changes were not accompanied by
changes in postsynaptic membrane potential. Membrane input resistance
was also stable (initial value 57 ± 7.3 M, and the end value
58 ± 8.5 M). The large waveforms shown at the
top are superimposed averaged responses taken from the
periods just before DCG IV application (1) and
35-45 min after DCG IV washout (2). The smaller
waveforms are the same responses plotted over a longer time scale.
B, The presence of the group II mGluR antagonist MSOPPE
(200-300 µM) in the bath blocked DCG IV-induced LTD. The
EPSP slope change 40 min after washout of the drugs was 9.2 ± 4.9% (n = 5; p < 0.0002 vs
DCG IV alone group, depicted in A). Averaged responses
taken just before MSOPPE application (1) and
35-45 min after drug washout (2) are also shown.
Membrane potential (plotted) and membrane input resistance (initial
value 48 ± 8.5 M, and the value 45 ± 8.9 M) were
stable during the recording. C, Bath-application of
another group II mGluR agonist L-CCG-I (10-20
µM) also induced LTD (24 ± 7.6% 40 min after
washout; n = 6). Membrane potential (plotted) and
input resistance (initial value 48 ± 8.7 M, end value 48 ± 9.1 M) were stable during the experiments.
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DCG IV-induced LTD requires synaptic activation of NMDA receptors
but not group I mGluRs
The concentrations of DCG IV used in the present study (50-100
nM) are much lower than the concentrations at which the
drug was shown to act as a NMDA receptor agonist (>10
µM; Ishida et al., 1993; Wilsch et al., 1994). The above
results with MSOPPE and L-CCG-I also indicate that DCG IV
did not act on NMDA receptors to induce LTD. However, provided that
certain forms of LTD are NMDA-dependent (Dudek and Bear, 1992; Mulkey
and Malenka, 1992), it is possible that synaptically activated, small
NMDA receptor-mediated component contributes to DCG IV-induced LTD. To
test this possibility, the NMDA receptors were blocked by the
antagonist DL-AP-5 (100 µM) during DCG IV
application. As shown in Figure
2A, although DL-AP-5 did not affect DCG IV-induced acute
depression of the EPSP (49 ± 5.7%; n = 6;
p > 0.05 compared with DCG IV alone group), it blocked
DCG IV-induced LTD (3.6 ± 6.5% 40 min after drug washout, p < 0.02 compared with DCG IV alone group).
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Figure 2.
DCG IV-induced LTD requires synaptic activation of
NMDA receptors, but DCG IV does not potentiate NMDA responses.
A, The presence of NMDA receptor antagonist
DL-AP-5 (100 µM) blocked DCG IV-induced LTD.
The change of the EPSP slope 40 min after drug washout was 3.6 ± 6.5% (p < 0.02 compared with DCG IV alone
group depicted in Fig. 1A). The membrane
potentials during the course of the experiments are also plotted.
Membrane input resistance: initial value 47 ± 4.9 M, end value 49 ± 8.6 M.
B, However, the manner of NMDA receptor involvement in
DCG IV-induced LTD is not such that DCG IV potentiates NMDA component
of synaptic responses. The NMDA component was isolated by the addition
of CNQX (5 µM) and bicuculline (1 µM,
routine application) in 0 Mg2+ solution
(B.1; n = 3) or in normal solution
(B.2; n = 4). Stimulus intensity was
increased to visualize NMDA component clearly, particularly in the
latter case. In both conditions, DCG IV (100 nM) depressed
NMDA component of synaptic transmission and never potentiated it. The
traces are averaged responses from representative experiments.
C, Absence of the small NMDA-mediated responses during
DCG IV application by the interruption of the 0.033 Hz single test
stimuli blocked DCG IV-induced LTD. The test stimuli were stopped just
before DCG IV application until 30 min after the beginning of DCG IV
washout (n = 12). Under this condition, only two
cells showed LTD, and 10 cells showed no change or potentiation
(36 ± 26% mean change 40 min after washout;
n = 12). If LTD is defined as a 15% decrease at
40 min after DCG IV washout, the frequency of the LTD occurrence (2 of
12 cases) is significantly lower than that in DCG IV alone group (7 of
9 cases) (p < 0.01; Fisher's exact
probability test). A second application of DCG IV with test pulses
delivered induced LTD (18 ± 4.9%, taking the EPSP level before
the second DCG IV application as a new baseline; p > 0.7 compared with DCG IV alone group depicted in Fig.
1A). Membrane potential was stable during the
experiments. Membrane input resistance: initial value 42 ± 3.4 M, end value 42 ± 3.2 M.
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We then decided to verify that DCG IV does not potentiate NMDA
receptor-mediated synaptic responses. First, the NMDA responses were
isolated in nominally 0 Mg2+ medium by the
addition of 5 µM CNQX and 1 µM bicuculline
(routine application) to the bathing medium (n = 3). As
shown in Figure 2B.1, DCG IV depressed the NMDA
receptor-mediated synaptic transmission and did not potentiate it. It
was still possible, however, that DCG IV alters voltage dependence of
Mg2+ block on the NMDA receptors so that
net transmission through the receptors at resting membrane potential
increases in the presence of DCG IV. This was also found not to be the
case. The synaptic NMDA component was isolated in the presence of
Mg2+ by the addition of CNQX and
bicuculline (Fig. 2B.2). DCG IV still depressed the
NMDA responses under this condition (n = 4). Taken together, these results show that DCG IV does not potentiate NMDA component of the synaptic transmission: the drug generally depresses the synaptic responses irrespective of whether the response is mediated
by AMPA or NMDA receptors, perhaps through presynaptic mechanisms
(Huang et al., 1999).
The above results with AP-5 and with the isolated NMDA component
indicate that the small NMDA receptor-mediated synaptic transmission at
resting membrane potential, evoked by the 0.033 Hz single test stimuli,
contributes to LTD. If this is the case, the interruption of test
pulses during DCG IV application should block the induction of LTD. We
therefore performed another set of experiments in which the 0.033 Hz
test stimuli were stopped just before a 15 min DCG IV application until
30 min after the beginning of DCG IV washout. Of 12 neurons tested,
only two of them showed LTD when test stimuli were resumed (50% and
17% from baseline 40 min after DCG IV washout). Among the other 10 neurons, five showed no lasting changes (4.2 ± 1.9%), and the
other five showed variable degrees of potentiation (104 ± 49%).
In Figure 2C, we plotted mean changes calculated from all 12 neurons (36 ± 26% mean change 40 min after DCG IV washout;
n = 12). Because of the large variation, the mean value was only marginally different (p = 0.08) when
compared with LTD in the DCG IV alone group (i.e., 20 ± 2.8%
as depicted in Fig. 1A). However, if LTD is defined
as a 15% decrease or more from the baseline at 40 min after DCG IV
washout, the frequency of LTD induction in the test pulse-interruption
condition (2 of 12 cases) is significantly lower than that in the DCG
IV alone group (seven of nine cases, p < 0.01, Fisher's
exact probability test; Ichihara, 1990). Test pulse interruption itself
does not affect the amplitude of the synaptic responses (Otani et al.,
1999b). In these 12 neurons, we successively applied DCG IV with the
0.033 Hz test pulses continuously delivered. In this case, DCG IV
induced LTD (Fig. 2C). The LTD value is 18 ± 4.9%
from the period just before the second DCG IV application (no
difference from DCG IV-induced LTD depicted in Fig.
1A; p > 0.7). These results support
the possibility that synaptically activated NMDA receptors play role in
the induction of LTD by DCG IV and indicate that the DCG IV-induced LTD
is a homosynaptic type of LTD.
Another possibility was that synaptically activated group I mGluRs
contribute to DCG IV-induced LTD. This possibility was necessary to
consider, because (1) dopamine-facilitated LTD requires synaptic
activation of both group I and group II mGluRs (Otani et al., 1999b),
(2) DCG IV potentiates the effect of group I agonist (S)-3,5-dihydroxyphenylglycine (DHPG) on
phosphoinositide turnover in neonatal cortex slices (Mistry et al.,
1998), and (3) DCG IV potentiates the effects of DHPG on membrane
inward currents and postsynaptic [Ca2+]
augmentation in perirhinal cortex slices (Cho et al., 2000). To test
whether group I mGluR blockade blocks DCG IV-induced LTD, we
bath-applied specific group I mGluR antagonist AIDA (200 µM; Otani et al., 1999b) 10 min before DCG IV
application until the end of the 15 min application (n = 7; data not depicted). AIDA blocked neither the acute synaptic
depression by DCG IV (45 ± 4.5%; n = 7) nor
DCG IV-induced LTD (18 ± 7.5% 40 min after drug washout;
n = 5; p > 0.8; intracellular
recording of two cells was lost during experiment). Application of AIDA
alone for 25 min did not change baseline synaptic responses during the
40 min post-drug period (3.0 ± 6.3% 40 min after AIDA;
n = 5). We conclude that synaptic activation of group I
mGluRs is not required for the induction of LTD by DCG IV.
DCG IV-induced LTD requires activation of postsynaptic PLC,
postsynaptic IP3 receptors, and PLD
DCG IV-induced LTD requires postsynaptic increases of
[Ca2+] (Otani et al., 1999b), and the
evidence shows that group II mGluRs stimulate PLC (Klein et al., 1997;
Mistry et al., 1998). Therefore, we tested whether DCG IV-induced LTD
requires postsynaptic PLC activation. We used a PLC inhibitor U-73122,
which inhibits muscarinic acetylcholine receptor agonist-stimulated
phosphoinositide hydrolysis in human neuroblastoma cells (Thompson et
al., 1991) and in rat pancreatic acinar cells (Yule and Williams,
1992), with an IC50 value being 3.7 µM in one measure (Thompson et al., 1991). U-73122 has no
effect on secretin-stimulated cAMP formation in rat pancreatic acinar
cells (Yule and Williams, 1992). In the first series of experiment,
U-73122 (4 µM) was bath-applied 10 min before the application of DCG IV until the end of the 15 min application. As shown
in Figure 3A, U-73122 did not
affect the acute depression of the EPSP by DCG IV (41 ± 7.3%
at the end of DCG IV application; n = 7; p
> 0.05 compared with DCG IV alone group depicted in Fig. 1A) but blocked DCG IV-induced LTD. Percentage of
change of the EPSP slope 40 min after washout of the drugs (3.4 ± 6.8% from baseline; n = 7) is significantly different
from the same measure taken from DCG IV alone group (p
< 0.02). Next, we tested whether U-73122 itself has any effects
on the EPSP. As shown in Figure 3B, a 25 min application of
U-73122 (4 µM) only slightly increased the
slope of the EPSP (8.0 ± 5.3% at the end of the application and
5.5 ± 5.6% 40 min after drug washout; n = 7).
These results show that PLC activation is required for DCG IV-induced
LTD. In the next series of experiment, we injected U-73122 in
postsynaptic neurons to test the locus of PLC activation. We included
in recording electrodes 20 µM U-73122 (1%
DMSO) and allowed it to diffuse into the cells. As shown in Figure
3C, the postsynaptic injection of U-73122 totally blocked
DCG IV-induced LTD (6.8 ± 7.4% 40 min after DCG IV;
n = 5; p < 0.02 compared with DMSO
control, see below) without affecting acute depression by DCG IV
(39 ± 8.9%; n = 5; p > 0.05).
Identical postsynaptic injection of 1% DMSO alone did not change the
degree of DCG IV-induced LTD (19 ± 3.5% at 40 min;
n = 5; p > 0.05; data not shown). In
addition, neurons injected with U-73122 and 1% DMSO did not show any
signs of deterioration of the baseline EPSP during the equivalent
period of experiment (4.6 ± 9.7% change; n = 4).
We conclude that critical PLC activation for LTD occurs in postsynaptic
sites.
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Figure 3.
DCG IV-induced LTD requires the activation of
postsynaptic PLC and postsynaptic IP3 receptors.
A, Bath-application of PLC inhibitor U-73122 (4 µM) blocked DCG IV-induced LTD. The percentage change of
the EPSP slope 40 min after drug washout was 3.4 ± 6.8% from
baseline (n = 7; p < 0.02 compared with DCG IV alone group depicted in Fig.
1A). During the course of the experiments,
membrane potential was stable. Membrane input resistance: initial value
44 ± 3.8 M, end value 46 ± 5.5 M. B,
Bath-application of U-73122 (4 µM) alone did not primarily change the synaptic responses (8.0 ± 5.3%
at the end of the 25 min application and 5.5 ± 5.6% 40 min after
drug washout; n = 7). The membrane potential was
also stable. Membrane input resistance: initial value 48 ± 7.5 M, end value 50 ± 6.3 M. C, Postsynaptic
injection of U-73122 (20 µM in recording electrodes) also
completely blocked DCG IV-induced LTD (6.8 ± 7.4% change at 40 min; n = 5; p < 0.02 compared
with DMSO control, see Results). D, Postsynaptic
injection of the inositol trisphosphate IP3 receptor
blocker heparin (4 mg/ml in recording electrodes) also blocked DCG
IV-induced LTD. Percentage change of the EPSP slope 40 min after DCG IV
washout in this group was 0.5 ± 4.8% (n = 5; p < 0.025 compared with DCG IV alone group).
Membrane potential (plotted) and membrane input resistance (initial
value 44 ± 6.0 M, end value 44 ± 5.1 M) were
stable.
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A key messenger generated by PLC activation is inositol trisphosphate
(IP3), which stimulates IP3
receptors on endoplasmic reticulum and triggers
Ca2+ release from the internal stores
(Agranoff and Fisher, 1994). To test whether postsynaptic
IP3 receptor activation is important in DCG
IV-induced LTD, we postsynaptically injected IP3
receptor blocker heparin through recording electrodes (4 mg/ml). As
shown in Figure 3D, in the heparin-injected neurons,
baseline synaptic responses and the acute depression by DCG IV
(35 ± 5.3%; p > 0.05) were unaffected, but DCG
IV-induced LTD was blocked (0.5 ± 4.8% 40 min after DCG IV
washout; n = 5; p < 0.025). Thus,
postsynaptic IP3 receptors are required for DCG
IV-induced LTD.
DCG IV has been shown to stimulate PLD (Klein et al., 1997). Therefore,
we also used PCCG-13, a selective blocker against PLD activation by
certain mGluR agonists, with an IC50 value being 100 nM (Pellegrini-Giampietro et al., 1996). As in the case
of U-73122, PCCG-13 (2 µM) was present in the bath from
10 min before DCG IV application until the end of the application.
PCCG-13 did not affect acute EPSP depression by DCG IV (31 ± 5.2%; n = 6; p > 0.05) but blocked
DCG IV-induced LTD (Fig.
4A) (0.8 ± 5.7% 40 min after drug washout; n = 5;
p < 0.025 compared with DCG IV alone group).
Intracellular recording of one cell was lost 25 min after the beginning
of the drug washout, but the depression remaining in this cell was only
5.2%. PCCG-13 alone slightly increased the EPSP slope during
application (6.5 ± 5.0% at the end of 25 min application;
n = 6) (Fig. 4B), but this increase returned to the baseline level within 40 min after washout (0.1 ± 4.7%; n = 6).
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Figure 4.
DCG IV-induced LTD requires the activation of PLD.
A, PCCG-13 (2 µM), the inhibitor of PLD
activation by certain mGluR agonists, blocked DCG IV-induced LTD
(0.8 ± 5.7% change 40 min after drug washout;
n = 5; p < 0.025 compared with
DCG IV alone group depicted in Fig. 1A). Membrane
potential during the course of the experiments is also plotted.
Membrane input resistance: initial value 47 ± 6.2 M, end value
44 ± 6.6 M. B, PCCG-13 alone did not change the
slope of the EPSP (0.1 ± 4.7% from baseline 40 min after drug
washout; n = 6). Membrane potential (plotted) and
membrane input resistance (initial value 44 ± 4.2 M, end value
45 ± 4.3 M) were also stable.
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DCG IV-induced LTD requires activation of postsynaptic PKC
Another key second messenger activated after PLC and PLD
stimulation is PKC (Tanaka and Nishizuka, 1994; Klein et al., 1995). We
therefore tested PKC involvement in DCG IV-induced LTD. First, we used
the cell-permeable, specific and potent PKC inhibitor RO318220 (Davis
et al., 1989; Harris et al., 1996), which has already been shown to
block cerebellar LTD (Linden and Connor, 1991). RO318220 (0.2 µM) was bath-applied 10 min before DCG IV application
until the end of the 15 min application. As shown in Figure
5A, RO318220 did not affect
the acute EPSP depression by DCG IV (25 ± 7.1% at the end of
DCG IV application; n = 8; p > 0.05)
but blocked DCG IV-induced LTD (3.6 ± 5.1% 40 min after drug
washout; n = 8; p < 0.015). The effect
of RO318220 alone is depicted in Figure 5B. A 25 min
application of RO318220 had no large effects on the EPSP slope
(1.0 ± 6.3% at the end of application and 0.8 ± 4.5% 40 min after drug washout; n = 7).
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Figure 5.
DCG IV-induced LTD requires postsynaptic
activation of PKC. A, The cell-permeable, specific, and
potent PKC inhibitor RO318220 (0.2 µM) blocked DCG
IV-induced LTD (3.6 ± 5.1% change 40 min after drug washout;
n = 8; p < 0.015 compared with
DCG IV alone group depicted in Fig. 1A). Membrane
potential (plotted) and membrane input resistance (initial value
38 ± 2.7 M, end value 41 ± 4.6 M) were stable.
B, RO318220 (0.2 µM) alone did not
largely change synaptic responses (0.8 ± 4.5% change 40 min after drug washout; n = 7). Membrane potential
(plotted) and membrane input resistance (initial value 57 ± 8.0 M, end value 55 ± 7.2 M) were also stable.
C, Postsynaptic presence of PKC inhibitor
pseudosubstrate peptide PKC(19-36) (1-2 mM in recording
electrodes) significantly reduced DCG IV-induced LTD. The EPSP slope
change 40 min after DCG IV washout was 6.3 ± 5.0% from
baseline (n = 6) and significantly different from
DCG IV-induced LTD depicted in Figure 1A
(p < 0.05). Membrane potential during the
course of the experiments is also plotted. Membrane input resistance:
initial value 48 ± 3.6 M, end value 51 ± 6.4 M.
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To show postsynaptic locus of PKC activation for DCG IV-induced LTD, we
injected pseudosubstrate peptide PKC(19-36) to postsynaptic neurons
(Fig. 5C). PKC(19-36) (1-2 mM in
recording electrodes) was allowed to diffuse to postsynaptic sites for
at least 1 hr before DCG IV application (cf. Otani and Connor, 1998).
There was no significant shift in baseline responses during the
diffusion period. Postsynaptic PKC(19-36) did not affect acute EPSP
depression induced by DCG IV (45 ± 8.7%; n = 6; p > 0.05) but significantly reduced DCG IV-induced
LTD (Fig. 5C). Percentage change of the EPSP slope 40 min
after DCG IV washout in these cells is only 6.3 ± 5.0% from
baseline (n = 6), and this value is significantly different from DCG IV-induced LTD depicted in Figure
1A (p < 0.05).
Reid et al. (1996), Schoepp et al. (1996), and Sortino et al. (1996)
suggested that group II mGluRs can increase cAMP levels. Therefore
finally, in additional cells, we tested the effect of selective PKA
inhibitor KT5720. KT5720 shows a strong specificity to PKA over PKC and
PKG (Ki = 60 nM
for PKA, and Ki > 2000 nM for both PKC and PKG; Kase et al., 1987).
KT5720 (0.2 µM) was present in the bath 10 min
before DCG IV application until the end of the application. As shown in
Figure 6A, KT5720
significantly reduced DCG IV-induced LTD (6.4 ± 4.5%;
n = 6; p < 0.04 compared with DCG IV
alone group depicted in Fig. 1A). A 25 min
application of KT5720 alone slightly decreased the slope of the EPSP
(17 ± 8.6% at the end of the application; n = 6), but this decrease recovered to baseline level within 40 min
(1.3 ± 3.7%; n = 6) (Fig.
6B).
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Figure 6.
DCG IV-induced LTD requires PKA activation.
A, The potent and selective PKA inhibitor KT5720 (0.2 µM) reduced DCG IV-induced LTD. The percentage change of
the EPSP slope 40 min after drug washout was 6.4 ± 4.5% from
baseline (n = 6), and this value is significantly
different from DCG IV-induced LTD depicted in Figure 1A
(p < 0.04). Membrane potential (plotted)
and membrane input resistance (initial value 47 ± 7.2 M, end
value 48 ± 6.5 M) were stable. B, KT5720 (0.2 µM) application alone did not largely affect synaptic
responses (1.3 ± 3.7% from baseline 40 min after washout;
n = 6). During the course of the experiments,
membrane potential did not fluctuate significantly. Membrane input
resistance: initial value 56 ± 8.5 M, end value 55 ± 12 M.
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DCG IV augments Ca2+ concentration in layer V
pyramidal neurons by stimulating IP3 receptors
Together with our previous study (Otani et al., 1999b), the
results so far suggest that DCG IV acts on MSOPPE-sensitive mGluRs and
stimulates PLC and PLD, which leads to
IP3-mediated postsynaptic [Ca2+] increases and postsynaptic PKC
activation. To further show postsynaptic metabotropic action of DCG IV,
we analyzed [Ca2+] increases induced by
DCG IV in PFC neurons. As a pilot study, we first used the
cell-permeable fluorescent Ca2+ indicator
fura-2 AM to ratio-image areas in coronal brain slices (n = 5; data not shown). DCG IV application (100 nM, 10 min) rapidly increased
[Ca2+] in both deep and superficial
layers of prelimbic area (i.e., the area of our interest). Often
(n = 3), the rapid
[Ca2+] increases during DCG IV
application were followed by slower, oscillatory
[Ca2+] fluctuations during washout periods.
We then performed fluorescent Ca2+
analysis in single postsynaptic layer V pyramidal neurons. The cells
were filled with high-affinity Ca2+
indicator fluo-3 via patch pipettes attached to their soma and were
maintained in voltage-clamp mode at 80 mV. In the first series of
experiment (not depicted), the synaptic responses were not
simultaneously recorded. Nevertheless, DCG IV application (100 nM) induced transient increases in
[Ca2+] in postsynaptic cells, in the
absence and in the presence of 100 µM AP-5. Mean
amplitudes of relative fluorescence variation ( F/F) were 6.5 ± 1.0% in the
absence of DL-AP-5 (n = 4) and
8.0 ± 2.9% in the presence of DL-AP-5
(n = 4). We never observed inward depolarizing currents
associated with the [Ca2+] increases by
DCG IV, consistent with our observation using the sharp electrode
intracellular recording (Fig. 1A). In three separate cells, the effect of another group II mGluR agonist
L-CCG-I (20 µM) on
[Ca2+] was tested.
L-CCG-I also transiently increased postsynaptic [Ca2+]. Mean amplitude of fluorescence
changes with L-CCG-I was 8.2 ± 2.7%
(F/F) (n = 3). Across
the different drug groups, we noted that in 5 of these 11 cells,
immediate transient [Ca2+] changes were
followed by some oscillatory [Ca2+]
waves during washout periods of the drugs, reminiscent of those observed in the whole slice imaging study described above.
Based on these pilot studies, we conducted a new series of experiments
to correlate DCG IV-induced [Ca2+]
signals with LTD. Thus, the Ca2+ indicator
fluo-3 was identically injected to postsynaptic layer V neurons, and
simultaneously, layer I-II to layer V neuron synaptic responses were
collected under voltage-clamp mode (at 80 mV). First, as shown in the
top graph of Figure 7A, DCG IV
rapidly augmented postsynaptic [Ca2+]
(n = 6). There were no inward depolarizing currents
during these [Ca2+] rises. Time course
of the [Ca2+] rises differed among
cells, creating the large data variations during the increase phase, as
seen in the top graph. However, when peak
[Ca2+] amplitude from each cell was
taken, mean peak percentage of [Ca2+]
increase associated with the DCG IV application was 6.7 ± 0.3% (n = 6). Importantly, as shown in the bottom graph, the
[Ca2+] rises were accompanied by acute
DCG IV action on the synaptic responses followed by LTD (27 ± 3.8% 40 min after DCG IV washout; n = 6). We detected
no significant difference in peak [Ca2+]
increases between this synaptic input condition and the above no-stimulation condition (6.7 ± 0.3% vs 6.5 ± 1.0%). This
observation may indicate that synaptically activated NMDA receptors do
not potentiate DCG IV-induced Ca2+ signals
to induce LTD. However, this cannot be concluded until local
Ca2+ signals at stimulated distal
dendritic sites and spines are analyzed under the synaptic stimulation
condition.
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Figure 7.
DCG IV-induced LTD is accompanied by postsynaptic
increases in [Ca2+], and these increases are
dependent on postsynaptic activation of IP3 receptors.
A, Control condition: the top graph shows
mean percentage [Ca2+] increases in postsynaptic
layer V pyramidal neurons induced by DCG IV bath application (100 nM, 5 min, n = 6; see Results
for statistics), as revealed by [Ca2+] analysis
with fluorescent indicator fluo-3. The bottom graph
shows the time course of the changes of the EPSC slope simultaneously
recorded from the same six neurons. DCG IV induced acute depression and
a subsequent LTD of the synaptic responses (27 ± 3.8% 40 min
after DCG IV washout; n = 6). The
inset shows superimposed averaged EPSCs taken from the
indicated time points. B, Heparin-injected neurons: the
figure has the same configuration as in A. The
postsynaptic presence of the IP3 receptor blocker heparin
(1 mg/ml, diffused from the patch pipettes) totally blocked DCG
IV-induced [Ca2+] increases (n = 5; top graph; see Results for statistics). Heparin
also blocked DCG IV-induced LTD in the same neurons without affecting
acute synaptic depression by DCG IV. Mean change of the EPSC slope 40 min after DCG IV washout in these neurons is 0.3 ± 2.8%
(n = 5; p < 0.001).
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Next, we tested whether a blockade of postsynaptic
IP3 receptors blocks DCG IV-induced LTD (Fig.
3D) and DCG IV-induced [Ca2+]
rises in the same cells (n = 5). The
IP3 receptor blocker heparin (1 mg/ml) was added
in the fluo-3-loaded patch pipettes and was allowed to diffuse to
postsynaptic sites. Under this condition, first, DCG IV-induced
[Ca2+] rises were absent (Fig. 7B,
top graph). "Peak" amplitude of [Ca2+], i.e., top limit of
[Ca2+] fluctuation during DCG IV
application, was 1.0 ± 0.01% in the heparin-injected neurons
(p < 0.05 compared with the neurons depicted in
Fig. 7A). Second, in the same neurons, DCG IV-induced LTD
was blocked (Fig. 7B, bottom graph) (0.3 ± 2.8%
EPSP slope change at 40 min; n = 5; p < 0.001 compared with LTD depicted in Fig. 7A). This set of
experiments shows that IP3 receptor-mediated postsynaptic [Ca2+] rises are required
for DCG IV-induced LTD.
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DISCUSSION |
Our results show that DCG IV acts on MSOPPE-sensitive postsynaptic
mGluRs and induces LTD through a series of biochemical responses. These
include PLC and PLD activation, internal
[Ca2+] increases via
IP3 receptor stimulation, and PKC and PKA
activation (Fig.
8B).
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Figure 8.
Schematic figures to compare two different LTD
induction protocols we found in glutamatergic synapses of rat
prefrontal layer V pyramidal neurons. The coexistence of D1-like and
D2-like receptors and that of D2-like and glutamate receptors in the
same synapse are hypothetical. A shows our
"standard" LTD induction protocol. LTD is induced by the
application of 50 Hz tetanic stimuli to layer I-II glutamatergic axons
in the presence of dopamine (100 µM) in the bath (Otani
et al., 1998b). In this LTD, dopamine acts on both D1-like and D2-like
receptors. Induction of this type of LTD does not require NMDA
receptors, but it requires (1) postsynaptic depolarization during
tetanus, which dopamine facilitates, (2) postsynaptic increases of
Ca2+ concentration, (3) synaptic activation of
groups I and II mGluRs, and (4) activation of MAPKs (ERK1 and ERK2)
(Otani et al., 1998b, 1999b). Pharmacologically, this type of LTD is
mimicked by combined bath-application of dopamine and
1S-3R-ACPD (the groups I and II mGluR
agonist), or even of dopamine and DHPG (specific group I mGluR agonist)
(Otani et al., 1999b). Thus, when the mGluRs and DA-Rs are
pharmacologically costimulated, tetanic stimuli and the consequential
large postsynaptic depolarization can be omitted. In this type of LTD,
role of group II mGluRs is relatively small, because in the
pharmacological protocol, ACPD can be replaced by DHPG.
B, In contrast, strong pharmacological activation of
group II mGluRs by bath-application of potent agonist DCG IV (50-100
nM) induces LTD without combined application of dopamine
and synaptic stimulation of group I mGluRs (present study). DCG
IV-induced LTD is dependent on the activation of postsynaptic PLC, PKC,
and IP3 receptors. The major differences of DCG IV-induced
LTD from the LTD induced by coactivation of mGluRs and DA-Rs are: (1)
DCG IV-induced LTD requires concurrent synaptic activation of NMDA
receptors, and (2) DCG IV-induced LTD does not require postsynaptic
MAPK activation (19 ± 2.5% LTD was induced in MAPK
pseudosubstrate peptide-injected cells; n = 4),
although DCG IV activates MAPKs in prefrontal tissue (Otani et al.,
1999b). We do not know at this stage whether group II mGluRs and NMDA
receptors convergently activate intracellular factor or factors to
induce LTD.
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Accumulating evidence suggests that group II mGluRs are positively
coupled to the PLC and PLD pathways, in addition to the well known
downregulation of adenylate cyclase activity (Tanabe et al., 1992;
Mistry et al., 1998). For example, Klein et al. (1997) showed that DCG
IV (1-3 µM) increases the activity of PLC and PLD by
30-40% in hippocampal slices prepared from 8-d-old rats
(EC50 for PLD activation: 22 nM). The
increase of PLD activity was independent of previous stimulation of
adenylate cyclase by forskolin, suggesting that the DCG IV effect on
PLD is not secondary to inhibition of adenylate cyclase by DCG IV.
Second, Mistry et al. (1998) showed that DCG IV stimulates
phosphoinositide turnover in neonatal rat cerebral cortex slices. They
found also that DCG IV and another group II agonist
2R,4R-4-aminopyrrolidine-2,4-dicarboxylate (2R,4R-APDC) potentiate the effect
of group I mGluR agonist DHPG on the phosphoinositide turnover
(EC50: 0.28 µM). Third,
Schoepp et al. (1996) similarly found a potentiating effect of
2R,4R-APDC on the DHPG action on
phosphoinositide turnover in neonatal and adult hippocampal slices.
Fourth, in perirhinal cortex slices, DCG IV (0.5 µM) potentiated the effects of DHPG on membrane
inward currents and postsynaptic [Ca2+]
augmentation (Cho et al., 2000). The results reported in this study are
generally consistent with these previous studies. However, to our
knowledge, this is the first evidence that DCG IV alone stimulates
postsynaptic [Ca2+] mobilization via
IP3 receptor stimulation. This is also the first
demonstration that DCG IV stimulates postsynaptic PKC. Recently, L. J. Bindman, J. Keelan, and S. H. Morris (personal
communication) found that DCG IV increases
[Ca2+] in cultured rat PFC neurons
maintained in Ca2+-free solution,
consistent with our data.
Involvement of group II mGluRs in LTD induction has been shown
elsewhere. For example, Manahan-Vaughan (1997) showed that CA1 LTD by 1 Hz stimuli was blocked by group II mGluR antagonists MSOPPE and
(2S)--ethylglutamic acid. Huang et al. (1997)
showed that LTD in the dentate gyrus by 1 Hz stimuli was blocked by
another group II antagonist
2S,1S',2S'-2-methyl-2-(2'-carboxycyclopropyl)glycine. More recently, Huang et al. (1999) reported results clearly consistent to our present data. In the dentate gyrus, bath-application (20 min) of
DCG IV (200 nM to 2 µM)
or another group II agonist LY354740 (500 nM)
induced LTD, and this induction could be inhibited or blocked by
MSOPPE, AP-5, RO318220 and H-89, the PKA inhibitor. They did not
directly test the loci for DCG IV action and kinase activation. But, at
least the expression of the DCG IV-induced LTD was postsynaptic
(Kilbride et al., 1998; Huang et al., 1999). Postsynaptic locus of
group II mGluR-induced LTD was shown more clearly in lateral amygdala
by Heinbockel and Pape (2000). Thus, theta frequency stimulation
induced group II mGluR-dependent LTD, and this LTD was blocked by
postsynaptic injection of BAPTA. These results taken together, it
appears that similar LTD mechanisms involving postsynaptic group II
mGluRs exist in the dentate gyrus, the lateral amygdala, and the
prefrontal cortex. In some cases, group II mGluRs might induce LTD via
a potentiation of group I mGluR actions (Cho et al., 2000). An
exception is however striatal LTD; group II mGluR agonists induce LTD
in the stratum, but immunostaining indicates only presynaptic
localization of group II mGluRs in this structure (Kahn et al., 2001).
Recent results suggest the importance of PLC and PLC-coupled receptors
in various forms of LTD. In the hippocampus, Huber et al. (2000, 2001)
showed that bath-application of group I mGluR agonist DHPG (50-100
µM, 5 min) induces LTD and that this LTD was absent in
mice lacking functional mGluR5 (Huber et al., 2001). Also in the
hippocampus, Reyes-Harde and Stanton (1998) showed that LTD induction
by 1 Hz stimuli was blocked by postsynaptic injection of the PLC
inhibitor U-73122. In the visual cortex, PLC involvement in LTD
induction was extended to neuromodulatory systems. Thus, Kirkwood et
al. (1999) found that LTD by paired stimuli was facilitated by
carbachol, the agonist of the PLC-coupled muscarinic acetylcholine
receptors. The LTD was also facilitated by the agonist of 1
adrenergic receptors methoxamine, and the 1B
receptor is a class of PLC-coupled receptors (Weiner and Molinoff, 1994).
Another interesting observation made in our study was that the NMDA
receptor antagonist DL-AP-5 blocked DCG IV-induced LTD (cf.
Huang et al., 1999). The NMDA dependency is in contrast to other
examples of prefrontal LTD (Hirsch and Crepel, 1991; Otani et al.,
1998b), but is consistent with certain forms of LTD in the visual
cortex and the hippocampus (Dudek and Bear, 1992; Mulkey and Malenka,
1992; Kirkwood and Bear, 1994). Although DCG IV is a NMDA agonist at
high concentrations (>10 µM; Ishida et al., 1993; Wilsch
et al., 1994), we suggest for the following reasons that DCG IV does
not act on NMDA receptors to induce LTD. First, the DCG IV
concentrations used in this study (50-100 nM) are well below the concentrations at which DCG IV acts as a NMDA agonist. Second, another agonist L-CCG-I (20 µM),
which has no known action on NMDA receptors, induced LTD. Third, DCG IV
did not potentiate isolated synaptic NMDA responses. It is apparent
that even at resting membrane potential, the small synaptic
transmission through NMDA receptors evoked by single test pulses is
sufficient to contribute to LTD. Indeed, interruption of test stimuli
during DCG IV application blocked DCG IV-induced LTD. Exact mechanisms
underlying the NMDA-group II mGluRs interaction for LTD induction are
currently unknown. Mistry et al. (1998) described that their DCG IV
effect (<1 µM) on phosphoinositide turnover was blocked
by NMDA channel blocker MK801. In our case, test pulse application that
evokes NMDA currents in layer V neurons did not augment postsynaptic
[Ca2+] increases by DCG IV at least at
somatic levels. We, however, may have missed test pulse-induced
[Ca2+] potentiation occurring in distal
dendritic sites. The already deep locations of healthy neurons within
the slices prepared from rats of 23 d of age made it difficult to
visualize the fine distal dendrites of layer V pyramidal neurons.
In Figure 8, we summarized and compared two different LTD induction
protocols we found in rat prefrontal layer V neurons; LTD induced by
coactivation of mGluRs and DA-Rs (Otani et al., 1998b, 1999b), and LTD
induced by DCG IV (present study). The first type of LTD (Fig.
8A) is typically induced by the application of
afferent tetanic stimuli in the presence of dopamine in the bath, and
the induction is NMDA-independent. This LTD, however, requires synaptic
activation of group I and II mGluRs, and LTD was indeed mimicked by a
combined application of dopamine and 1-aminocyclopentane-1,3-dicarboxylic acid
(1S,3R-ACPD) (the groups I and II mGluR agonist).
This pharmacological protocol surpasses the requirement of postsynaptic
depolarization in the case of LTD induction by the tetani in the
presence of dopamine. Also, in this first type of LTD, role of group II
mGluRs is relatively small, because the induction could be mimicked
even when ACPD was replaced by DHPG, a specific group I mGluR agonist.
We suggested that an induction mechanism underlying this type of LTD is
converging postsynaptic activation of MAPKs by DA-Rs (D1 and D2) and
the mGluRs. In the second type of LTD (Fig. 8B),
strong pharmacological stimulation of postsynaptic group II mGluRs
cooperates with NMDA receptors. This LTD is dependent on the activation
of group II mGluR-associated PLC, PKC, and IP3
receptors. Furthermore, our recent observation suggests that the DCG
IV-induced LTD does not require postsynaptic activation of MAPKs: the
LTD was still induced (19 ± 2.5%, n = 4) in
the cells injected with MAPK pseudosubstrate peptide (1-2
mM in recording electrodes; see Otani et al.,
1999b). Thus, although DCG IV activates MAPKs in rat prefrontal tissue (Otani et al., 1999b), this activation is not necessary for the LTD
induction in the presence of DCG IV. At this stage, we do not know
whether group II mGluRs and NMDA receptors cooperatively activate other
downstream factor(s). Whatever the case, these results clearly suggest
that there are different parallel biochemical pathways that converge to
an LTD induction in rat prefrontal neurons. In the broad context, the
DCG IV-induced LTD adds another variation to the wealth of the examples
for receptor cross-talks underlying synaptic plasticity. These include
the interactions between group I and group II mGluRs (Schoepp et al.,
1997; Mistry et al., 1998; Cho et al., 2000), between groups I and II
mGluRs and DA-Rs (Otani et al., 1999b) (Fig. 8A),
between dopamine D1 and NMDA receptors (Gurden et al., 2000), between
NMDA receptors and MCPG-sensitive mGluRs (Otani and Connor, 1995), and
between mGluRs and AMPA-kainate receptors (Kemp and Bashir, 1999).
Complex, but important, molecular cooperativity underlies these
interactions among different postsynaptic receptors.
| |
FOOTNOTES |
Received Dec. 12, 2001; revised Feb. 19, 2002; accepted Feb. 22, 2002.
This work was financially supported by Biotech Grant CT96-0049. We
thank Drs. L. J. Bindman and S. J. Sara for their comments on
this manuscript.
Correspondence should be addressed to Dr. Satoru Otani, Neurobiologie
des Processus Adaptatifs, Université de Paris VI, Case 8, 7 Quai
St. Bernard, 75005 Paris, France. E-mail: satoru.otani{at}snv.jussieu.fr.
| |
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TOP
ABSTRACT
INTRODUCTION
