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The Journal of Neuroscience, October 1, 2002, 22(19):8379-8390
Group I Metabotropic Glutamate Receptor Signaling via
G q/G11 Secures the Induction of Long-Term Potentiation in the
Hippocampal Area CA1
Masami
Miura1,
Masahiko
Watanabe2,
Stefan
Offermanns3,
Melvin I.
Simon4, and
Masanobu
Kano1
1 Department of Physiology, Kanazawa University School
of Medicine, Takara-machi, Kanazawa 920-8640, Japan,
2 Department of Anatomy, Hokkaido University School of
Medicine, Sapporo 060-8635, Japan, 3 Pharmakologisches
Institut, Abteilung Molekulare Pharmakologie, Universität
Heidelberg, 69120 Heidelberg, Germany, and 4 Division of
Biology, California Institute of Technology, Pasadena, California 91125
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ABSTRACT |
Heterotromeric G-proteins of the Gq family are thought to transduce
signals from group I metabotropic glutamate receptors (mGluRs) in
central neurons. We investigated roles of this cascade in hippocampal
long-term potentiation (LTP) by using null-mutant mice lacking the  subunit of Gq (Gq) or G11 (G11). We found no obvious
abnormalities in the morphology, layer structure, expression of NMDA
receptors, and basic parameters of excitatory synaptic transmission in
the hippocampus of Gq mutant mice. We used theta burst stimulation
(TBS) (3-10 burst trains at 5 Hz; each train consisted of five stimuli
at 100 Hz) to induce LTP at Schaffer collateral to CA1 pyramidal cell
synapses. Conventional TBS with 10 burst trains induced robust LTP in
wild-type, Gq mutant, and G11 mutant mice. Weak TBS with three
burst trains consistently induced LTP in wild-type mice. In contrast,
the same weak TBS was insufficient to induce LTP in Gq and G11
mutant mice. In wild-type mice, the LTP by weak TBS was abolished by
inhibiting group I mGluR or protein kinase C (PKC) but not by blocking
muscarinic acetylcholine receptors. Prior activation of group I mGluR
by an agonist significantly enhanced the LTP by weak TBS in wild-type mice. However, this priming effect was absent in Gq mutant mice. These results indicate that the signaling from group I mGluR to PKC
involving Gq/G11 does not constitute the main pathway for LTP,
but it secures LTP induction by lowering its threshold in the
hippocampal area CA1.
Key words:
long-term potentiation; hippocampus; metabotropic
glutamate receptor; G-protein; protein kinase C; mouse
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INTRODUCTION |
Long-term potentiation (LTP) and
long-term depression (LTD) in the hippocampal area CA1 are widely
thought to be cellular bases for certain forms of learning and memory
(Bliss and Collingridge, 1993 ; Bear and Malenka, 1994; Nicoll and
Malenka, 1995; Bear and Abraham, 1996). Several previous studies
suggest that metabotropic glutamate receptors (mGluRs) are involved in
the processes of LTP or LTD in the CA1. The mGluRs consist of eight
different subtypes, from mGluR1 to mGluR8, and are classified into
groups I, II, and III (Nakanishi, 1994; Conn and Pin, 1997). The group
I mGluR consists of mGluR1 and mGluR5 and couples to the Gq family
heterotrimeric G-protein and phospholipase C (PLC) , leading to
triggering of inositol-1,4,5-trisphosphate
(IP3)-mediated Ca2+
release and to activation of protein kinase C (PKC) (Masu et al., 1991;
Abe et al., 1992). Although several studies have addressed the
involvement of group I mGluR in LTP or LTD in the CA1, the results
remain controversial. For example, several researchers report that an
antagonist of group I/II mGluRs,
(R,S)-amino-methyl-4-carboxylphenylglycine (MCPG), inhibits
LTP induction (Bashir et al., 1993; Riedel and Reymann, 1993;
Bortolotto et al., 1994; Richter-Levin et al., 1994), whereas others
found no effect (Chinestra et al., 1993; Manzoni et al., 1994; Selig et
al., 1995; Thomas et al., 1995).
CA1 pyramidal cells strongly express mGluR5 that is densely
concentrated at the perisynaptic region of the dendritic spines facing
the excitatory synaptic terminals (Luján et al., 1996; Luján et al., 1997). In contrast, mGluR1 is not found on their dendrites (Shigemoto et al., 1997), indicating that mGluR5 is a major
receptor at CA1 excitatory synapses that activates the Gq-PLC
cascade. It is reported that the null-mutant mice lacking mGluR5 have a
partial impairment in NMDA receptor-dependent LTP (Lu et al., 1997).
Several previous studies have suggested an involvement of PKC in LTP.
Postsynaptic activation of PKC is required for the induction of LTP
(Wang and Feng, 1992). Tetanic stimulation that induces LTP increases
the activation of PKC (Klann et al., 1993) and the phosphorylation of
PKC substrates (Ramakers et al., 1999). Furthermore, LTP is impaired in
PKC mutant mice (Abeliovich et al., 1993). However, maximal
activation of postsynaptic G-protein does not occlude the induction of
LTP in area CA1 (Goh and Pennefather, 1989; Katsuki et al., 1992).
These observations raise a question of whether and how the signaling
from mGluR5 to PKC is involved in the induction of LTP in the area CA1.
To address this issue, we used the null-mutant mice lacking the subunit of Gq (Gq) or G11 (G11) (Offermanns et al., 1997;
Offermanns and Simon, 1998), members of the heterotrimeric Gq family
that are shown to transduce signals from group I mGluR in central
neurons (Masu et al., 1991; Abe et al., 1992). Our results suggest that
the group I mGluR (presumably mGluR5) to PKC cascade does not
constitute the main pathway for LTP at Schaffer collateral to CA1
pyramidal cell synapses, but that this cascade facilitates LTP
induction by significantly lowering its threshold.
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MATERIALS AND METHODS |
Morphological and immunohistochemical studies. Under
deep anesthesia by pentobarbital (100 mg/kg body weight, i.p.),
wild-type and Gq mutant mice were perfused transcardially with 4%
paraformaldehyde in 0.1 M sodium phosphate
buffer, pH 7.2. Parasagittal paraffin sections (5 µm in thickness)
were prepared from fixed brains and processed for histological
(hematoxylin) and immunohistochemical stainings. Before
immunohistochemical incubations, sections were treated at 37°C for 10 min with 1 mg/ml pepsin (Dako, Carpinteria, CA) in 0.2N HCl, as
reported previously (Watanabe et al., 1998). After blocking with 10%
normal goat serum, sections were incubated with primary antibodies (0.5 µg/ml) against mouse NMDA receptor subunit GluR 1 (anti-GluR1C),
GluR2 (anti-GluR2N), or GluR 1 (anti-GluR1C) (Watanabe et
al., 1998; Yamada et al., 2001) at room temperature overnight, with
biotinylated goat anti-rabbit IgG at room temperature for 2 hr, and
with avidin-peroxidase complex at room temperature for 30 min, using a
Histofine SAB-PO Kit (Nichirei Corp., Tokyo, Japan). The anti-GluR1C
was directed against the C2 exon cassette. Immunoreaction was
visualized with diaminobenzidine.
Hippocampal slice preparation. Hippocampal slices were
prepared from Gq mutant, G11 mutant, and wild-type mice using
standard procedures (Manabe et al., 1993). In brief, young adult mice
(6-12 weeks of age) were anesthetized and decapitated. Hippocampi were dissected free and cut with tissue slicer (VT1000S; Leica, Nussloch, Germany) in ice-cold medium composed of (in mM):
20 glucose, 120 choline-Cl, 3 KCl, 1.1 NaH2PO4, 8 MgCl2, and 26 NaHCO3, pH
7.4 (Tsubokawa et al., 2000). In the priming experiment, area CA3 was
removed by a manual knife cut to prevent the slow onset potentiation induced by mGluR agonists (Bortolotto and Collingridge, 1992; Chinestra
et al., 1993). Slices (300 and 500 µm thick; used for whole-cell
recording and field recording, respectively) were transferred to an
incubation chamber and allowed to recover for  1 hr before recording.
During recording, a slice was placed into a submerged chamber and
perfused continuously (1.5-2 ml/min, 30°C) with artificial CSF
(ACSF) composed of (in mM): 20 glucose, 125 NaCl,
2.5 KCl, 1.25 NaH2PO4, 26 NaHCO3, 2 CaCl2, and 1 MgSO4, bubbled with 95% O2-5% CO2, pH 7.4.
Field recording. Field EPSPs (fEPSPs) were recorded by using
an Axoclamp 2B amplifier (Axon Instruments, Foster City, CA) with glass
electrodes (filled with ACSF; resistance, 3-6 M ) placed in the
stratum radiatum of the area CA1. Field EPSPs were evoked by
stimulating the Schaffer collateral/commissural pathway with short
current pulses (50 µsec duration; 0.033 Hz) by using the Teflon-coated tungsten bipolar electrode that was placed 1 mm apart
from the recording electrode. Protocols for the induction of LTP were
theta burst stimulation (TBS) (3-10 trains/0.5 Hz; each train contains
five pulses/100 Hz) for the CA1 region and tetanic stimulation (100 pulses/100 Hz) for the CA3 region.
Whole-cell recording and Ca2+
imaging. Whole-cell recording was made from a visually
identified pyramidal neuron under the upright microscope with a
×40 water immersion objective (Axioskop; Zeiss, Jena, Germany). The
whole-cell voltage-clamp recording was performed using cesium-based
solutions (for experiments in Fig. 2C,D) composed of (in
mM): 120 CsCl, 20 TEA-Cl, 5 BAPTA, 10 HEPES, 5 MgCl2, 5 N-(2,6-dimethylphenylcarbamoyl-methyl)triethylammonium
bromide, 4 Na2-ATP, and 0.3 Na-GTP, pH
7.25 (adjusted with CsOH). The Ca2+
imaging and whole-cell current-clamp recordings were made from a single
neuron with a potassium-based solution (for experiments in Fig. 7)
composed of (in mM): 120 K-gluconate, 20 KCl, 10 HEPES, 1 MgCl2, 4 Na2-ATP,
and 0.3 Na-GTP, pH 7.25 (adjusted with KOH). A calcium indicator dye,
fura-2 (200 µM), was loaded to the neuron through the whole-cell pipette, and the ratio of emission intensities at the two excitation wavelengths (340 and 380 nm) was measured using a
cooled CCD camera system (IMAGO; T.I.L.L. Photonics GmbH, Martinsried, Germany).
Data are expressed as mean ± SEM. Student's t test
was used to determine whether there was a significant difference in the mean between the two sets of data.
Materials. Chelerythrine was obtained from Calbiochem
(Nottingham, UK). MCPG,
(±)-1-aminocyclopentane-trans-1,3-dicarboxylic acid (ACPD),
and aminophosphonovalerate (AP-5) were obtained from Tocris Cookson
(Bristol, UK). Fura-2 was obtained from Dojindo (Kumamoto, Japan). All
other reagents were obtained from Wako Pure Chemicals Industries
(Osaka, Japan).
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RESULTS |
Morphology and NMDA receptor expression of the Gq
mutant hippocampus
Gq is expressed in CA1 pyramidal cells of the mouse hippocampus
(Milligan, 1993; Friberg et al., 1998; Tanaka et al., 2000). We began
by examining whether the genetic deletion of Gq causes any change in
the morphology of the hippocampus. As reported previously, the gross
anatomy of the CNS was apparently normal in Gq mutant mice
(Offermanns et al., 1997; Hashimoto et al., 2000). The hippocampus of
Gq mutant mice at 2 months of age had similar morphology to that of
wild-type mice at the same age (Fig.
1A,E). The shape, size,
cellular arrangement, and laminar organization of the CA1 and dentate
gyrus were normal in hematoxylin staining (Fig.
1A,E). We then assessed the expression and
distribution of NMDA receptor subunits, because the decrease in NMDA
receptor-mediated synaptic currents significantly attenuates the
magnitude of LTP in the area CA1 (Sakimura et al., 1995; Kiyama et al.,
1998). We examined immunohistochemical distribution of three NMDA
receptor subunits, GluR1 (Fig. 1B,F),
GluR2 (Fig. 1C,G), and GluR1 (Fig.
1D,H). In both strains of mice, distinct
laminar distribution was evident for each subunit, but no significant
differences by the genotypes were noted in the distribution and
intensity within the hippocampus. The highest immunostaining was
detected in neuropils of the strata radiatum and oriens in the CA1
region. In contrast, cell bodies of pyramidal cells and stem apical
dendrites were almost immunonegative. These morphological results
suggest that the deletion of the Gq gene caused no
gross abnormalities in histology and NMDA receptor subunit
expression.
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Figure 1.
Histology and distributions of NMDA receptor
subunits are normal in the Gq mutant hippocampus.
A-D, Wild-type mice; E-H, Gq
mutants. A, E, Hematoxylin staining. B,
F, GluR1 subunit. C, G, GluR2 subunit.
D, H, GluR1 subunit. CA1, CA1 region;
DG, dentate gyrus; Gr, granule cell
layer; LM, stratum lacunosum-moleculare;
Mo, molecular layer; Or, stratum oriens;
Py, pyramidal cell layer; Ra, stratum
radiatum. Scale bars, 100 µm.
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Excitatory synaptic transmission is normal in Gq
mutant hippocampus
We subsequently examined whether the basic property of excitatory
synaptic transmission is normal in Gq mutant mice. We recorded fEPSPs by stimulation of the Schaffer collateral-commissural pathway in hippocampal slices prepared from 6- to 11-week-old wild-type and
mutant mice. We measured the initial slope of fEPSP to quantify the
strength of the synaptic response. The input-output relationship in
Gq mutant mice was similar to that of wild-type mice (Fig. 2A). In the area CA1,
paired stimulation with short intervals usually causes paired-pulse
facilitation (PPF). The extent of PPF of Gq mutant mice was
identical to that of wild-type mice, with an interpulse interval of
25-500 msec (Fig. 2B).
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Figure 2.
Basic properties of excitatory synaptic
transmission of Gq mutant are normal. A, The
input-output relationships of fEPSPs in wild-type ( ;
n = 7) and Gq mutant ( ; n = 5) mice. The fEPSPs were evoked by single stimulation of the Schaffer
collateral. Insets are typical responses. Calibration: 2 mV, 5 msec. B, Paired-pulse ratio of fEPSPs in wild-type
(; n = 5) and Gq mutant (;
n = 5) mice. The initial slope of the fEPSP was
measured to quantify the strength of the synaptic response. The ratio
of the second to the first response is plotted against the
interstimulus interval. Calibration: 1 mV, 20 msec. C,
The ratio of amplitudes of the NMDA EPSC (recorded at a holding
potential of +40 mV) to those of the AMPA EPSC (recorded at a holding
potential of  70 mV) in wild-type (open column;
n = 10) and Gq mutant (filled
column; n = 7) mice. The NMDA EPSC was
recorded in the presence of CNQX (25 µM). Sample traces
are shown in the top panel. Calibration: 20 pA, 20 msec.
D, The current-voltage relationship of NMDA synaptic
currents in wild-type (; n = 8) and Gq mutant
(; n = 6) mice. The amplitude of the EPSC is
normalized to the value obtained at 30 mV.
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To evaluate the NMDA receptor functions of Gq mutant mice, the ratio
of the NMDA to AMPA receptor-mediated component of EPSC was measured
with whole-cell recording techniques in the presence of a
GABAA receptor antagonist, bicuculline (25 µM). AMPA receptor-mediated EPSCs were recorded at a
membrane potential of 70 mV in a voltage-clamp mode. NMDA
receptor-mediated EPSCs were then measured at the same stimulus
strength in the presence of 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX)
(10 µM), a non-NMDA receptor antagonist, at +40 mV to
relieve the voltage-dependent Mg2+ block
of the NMDA receptor channel (Mayer et al., 1984; Nowak et al., 1984).
The ratio of NMDA to AMPA EPSC amplitudes of Gq mutant mice
(38.7 ± 3.3%; n = 7) was identical to that of
wild-type mice (39 ± 4.1%; n = 10) (Fig.
2C). Furthermore, the current-voltage (I-V) relationships for the NMDA component of
wild-type and Gq mutant mice were almost identical (Fig.
2D), suggesting that the voltage-dependent
Mg2+ block of the NMDA receptor is not
altered in Gq mutant mice. These results indicate that excitatory
synaptic transmission and functions of NMDA receptors are normal in CA1
pyramidal cells of Gq mutant mice.
Elevated threshold for LTP induction in Gq
mutant hippocampus
We then examined whether LTP in the CA1 and the CA3 is altered in
Gq mutant mice. Conventional TBS applied to the Schaffer collateral-CA1 synapses (10 burst trains repeated at 5 Hz; each burst
consisted of five stimuli at 100 Hz) induced a robust and stable LTP
lasting >60 min in both Gq mutant and wild-type mice (Fig.
3A). The average increase in
the fEPSP slope (50-60 min after TBS) was 40.8 ± 4.3%
(n = 10) for wild-type mice and 35.4 ± 3.1%
(n = 10) for Gq mutant mice (Fig. 3A),
showing no significant difference. Two excitatory synapses onto CA3
neurons, associational/commissural (A/C)-CA3 synapses and mossy fiber
(mo)-CA3 synapses, display LTP with distinct mechanisms (Salin et al.,
1996). Thus, we examined whether LTP at these two types of synapses is
altered in Gq mutant mice. Conventional tetanic stimulation (100 Hz
for 1 sec) of the A/C-CA3 synapses induced robust and stable LTP in
both Gq mutant and wild-type mice (Fig. 3B). Furthermore,
tetanic stimulation (100 Hz for 1 sec) of the mo-CA3 synapses also
caused stable LTP in both strains of mice (Fig. 3C). The
average fEPSP (the last 10 min of recording) at these two types of
synapses showed no significant differences between the Gq mutant and
wild-type mice (Fig. 3B,C). These results indicate that LTP
can be induced normally in both the CA1 and CA3 regions of Gq mutant
mice by conventional stimulation protocols. In the rest of the present
study, we focused on the issue of whether and how the group I mGluR
signaling involving Gq contributes to LTP induction at the Schaffer
collateral-CA1 synapses.
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Figure 3.
Normal LTP induced by conventional
stimulation protocols in the Gq mutant hippocampus.
A, The averaged time course of LTP induced by 10 trains
of TBS in the area CA1 of wild-type (n = 10) and
Gq mutant (n = 10) mice. Initial EPSP slopes
were measured, and the values were normalized in each experiment using
the averaged slope value measured during the control period (time, 10
to 0 min). The TBS was applied at time 0 (downward
arrow). In the following figures, the averaged time course of
LTP is illustrated similarly. B, The averaged time
course of LTP induced by tetanic stimulation (100 Hz, 1 sec) at the
associational/commissural (asoc/com)-CA3 synapses in
wild-type (n = 10) and Gq mutant
(n = 8) mice. C, The averaged time
course of LTP induced by tetanic stimulation (100 Hz, 1 sec) at the
mo-CA3 synapses in wild-type (n = 9) and Gq
mutant (n = 8) mice. Records were taken in the
presence of AP-5 (25 µM) to block NMDA receptors. Mossy
fibers were stimulated via a bipolar electrode placed in the dentate
hilus.
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The lack of the effect of Gq deletion on LTP induction (Fig.
3A) could be attributable to the fact that the conventional TBS with 10 burst trains may be well above the threshold for LTP induction. To detect subtle differences that may exist between wild-type and Gq mutant mice, we used a weaker TBS that consisted of
three burst trains. This weak TBS applied to the Schaffer collateral produced a stable LTP in wild-type mice
(Figs. 4, 5C) (19.8 ± 2.1%; n = 13; measured at 50-60 min after TBS). In
contrast, the same TBS caused a short-term potentiation during the
initial 10 min but failed to induce LTP in Gq mutant mice (Figs. 4,
5C) (6.3 ± 1.9%; n = 9; measured at
50-60 min after TBS). The difference between wild-type and mutant mice
was significant (p < 0.01). These results
indicate that the threshold for LTP induction is significantly elevated
in the CA1 of Gq mutant mice.
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Figure 4.
The threshold for LTP induction is
elevated in the area CA1 of Gq mutant mice. A weak TBS (3 trains)
applied at time 0 (downward arrows) induced a clear LTP in
wild-type (n = 13) but not Gq mutant
(n = 9) mice. **p < 0.01.
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Figure 5.
The threshold for LTP induction is
elevated in the area CA1 of G11 mutant mice. A, A TBS
with 10 burst trains (downward arrow) induced a robust and
stable LTP in both wild-type (n = 7) and G11
mutant (n = 8) mice. B, A weak TBS
of three trains (downward arrow) induced a clear LTP in
wild-type (n = 10) but not G11 mutant
(n = 10) mice; **p < 0.01. C, The average increase in initial slopes of fEPSPs
(50-60 min after TBS); **p < 0.01.
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Induction of LTP in the CA1 region is known to require elevation of
[Ca2+]i in
pyramidal cells. We examined whether there is any difference in
Ca2+ transients during the weak TBS
between the wild-type and Gq mutant mice. We recorded the
[Ca2+]i and EPSPs
simultaneously from single CA1 pyramidal neurons under whole-cell
current-clamp recording mode. The calcium indicator dye fura-2 was
loaded to the neurons by diffusion from whole-cell recording pipettes,
and the fluorescence ratio [ (F340/F380)] was measured at the soma
and the dendrites in response to the weak TBS. We could not detect any
significant difference in the Ca2+
transients in the soma and dendrites between the two mouse strains (data not shown). These results suggest that the elevated threshold for
LTP induction in the Gq mutant hippocampus is not likely caused by
the alteration in the Ca2+ transients
during the weak TBS.
Another member of the Gq family, G11, is also expressed in CA1
pyramidal cells of the mouse hippocampus (Milligan, 1993; Friberg et
al., 1998; Tanaka et al., 2000). Because both Gq and G11 are
thought to transduce signals from group I mGluR, it is possible that
G11 has a facilitatory effect on LTP induction similar to Gq.
Therefore, we examined null-mutant mice lacking G11. The morphology
of the hippocampus and other CNS regions appeared normal in G11
mutant mice. We found that the TBS with 10 burst trains induced robust
and stable LTP in both G11 mutant and wild-type mice (Fig.
5A). The average increase in the fEPSP slope (50-60 min
after TBS) was 34.7 ± 7.7% (n = 7) for wild-type mice and 32 ± 12.7% (n = 8) for G11 mutant
mice (Fig. 5A), showing no significant difference. In
contrast, the weak TBS with three burst trains induced a clear LTP in
wild-type mice but not G11 mutant mice (Fig. 5B). The
average magnitude of LTP (50-60 min after TBS) was 18.9 ± 3.3%
(n = 10) for wild-type mice and 0.3 ± 4.7%
(n = 10) for G11 mutant mice (Fig. 5B,C),
showing a significant difference (p < 0.01).
These results indicate that Gq and G11 have a similar
facilitatory effect on LTP induction at Schaffer collateral-CA1 synapses.
mGluR signaling involving Gq/G11 facilitates
LTP induction
CA1 pyramidal cells express group I mGluRs (primarily mGluR5) (Lu
et al., 1997) and muscarinic acetylcholine receptors (M1) (Tsubokawa
and Ross, 1997; Tsubokawa et al., 2000) that functionally couple to
Gq/G11. To examine which type of the receptors exerts the
facilitatory effect on LTP induction, an mGluR antagonist, MCPG, or a
muscarinic receptor antagonist, atropine, was bath applied during weak
TBS. In the presence of MCPG (500 µM), the weak TBS
caused a short-term potentiation during the initial 10 min but failed
to induce LTP (Fig.
6A,C) (control: 18 ± 3.4%, n = 7; MCPG: 1.5 ± 2.3%,
n = 6), which is very similar to the results seen in
Gq or G11 mutant mice (Figs. 4, 5B,C). In
contrast, the same weak TBS readily induced LTP in the presence of
atropine (1 µM) (Fig. 6B,C)
(control: 18 ± 3.4%, n = 7; atropine: 17 ± 10.8%, n = 5). In addition, atropine significantly
enhanced the short-term potentiation during the first 20 min after the
weak TBS (Fig. 6B).
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Figure 6.
LTP induced by the weak TBS in the area
CA1 is abolished by MCPG but not by atropine. A, The
weak TBS (downward arrow) induced LTP in the area CA1 in
control saline (n = 7). MCPG bath applied before
and during the TBS (500 µM, horizontal
bar) abolished LTP (n = 6);
**p < 0.01. B, Atropine (1 µM, horizontal bar) bath applied before
and during the TBS (downward arrow) enhanced post-tetanic
potentiation but did not affect the level of LTP. n = 7 for control; n = 5 for atropine.
C, The average increase in initial slopes of fEPSPs
(50-60 min after TBS); **p < 0.01.
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It has been reported previously that previous activation of mGluRs by
bath-applied ACPD facilitates the induction of LTP (Cohen and Abraham,
1996). Because ACPD is an agonist for both group I and II mGluRs, this
priming effect may be attributable to activation of group I mGluR in
CA1 pyramidal cells. Thus, we examined whether the priming effect by
ACPD is altered in Gq mutant mice. In this experiment, we applied
TBS with five burst trains to Gq mutant pyramidal cells to induce
LTP comparable with that induced in wild-type pyramidal cells by TBS
with three burst trains. The mean magnitude of LTP in wild-type mice
was 22.1 ± 6.6% (Fig. 7A,C) (control,
n = 6) and that in Gq mutant mice was 26.6 ± 3.3% (Fig. 7B,C) (Gq mutant, n = 6).
Bath-applied ACPD (20 µM) caused transient
depression of fEPSP in both genotypes (Fig. 7A,B, ACPD).
However, the priming effect was clearly observed in wild-type mice
(41.3 ± 5.4%) (Fig. 7A,C, ACPD; n = 7) but was deficient in Gq mutant mice (22.4 ± 5.6%) (Fig.
7B,C, ACPD; n = 6).
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Figure 7.
The ACPD-induced priming effect is
deficient in Gq mutant mice. A, Bath application of
ACPD (20 µM, 10 min, horizontal bars)
enhanced the subsequent LTP induced by the weak TBS of three trains
(downward arrow) in wild-type mice (control,
n = 6; ACPD, n = 7).
B, A TBS of five trains (downward arrow)
induced LTP in Gq mutant mice (control, n = 6).
Bath application of ACPD (20 µM, 10 min,
horizontal bars) did not enhance LTP (ACPD,
n = 6). C, The average increase in
initial slopes of fEPSPs (50-60 min after TBS).
**p < 0.01.
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A PKC inhibitor abolishes LTP by weak TBS
Because the group I mGluR signaling pathway including Gq leads to
activation of PKC, we assessed whether the facilitatory effect on LTP
induction involves PKC. We tested whether a PKC inhibitor,
chelerythrine (2 µM), affects the LTP by weak TBS. In
wild-type mice, a TBS with three burst trains readily induced LTP in
the control saline (Fig.
8A,C) (control:
23.1 ± 5.7%; n = 9). Bath-applied chelerythrine
(2 µM) effectively blocked LTP (Fig.
8A,C) (chelerythrine: 5.5 ± 5.8%;
n = 9; **p < 0.01). In Gq
mutant mice, a TBS with five burst trains induced LTP in the control
saline (Fig. 8B,C) (control: 26.5 ± 10.8%;
n = 8) that was comparable with the LTP in wild-type
mice (Fig. 8A,C, control). However, bath-applied
chelerythrine (2 µM) had no blocking effect on
LTP in Gq mutant mice (Fig. 8B,C) (chelerythrine:
20.1 ± 6.2%; n = 9). These results indicate that
the facilitatory effect on LTP induction by the Gq cascade involves
activation of PKC.
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Figure 8.
LTP induced by the weak TBS is abolished
by a PKC inhibitor, chelerythrine. A, In wild-type mice,
a PKC inhibitor, chelerythrine (2 µM, bath applied during
the recoding period indicated with the horizontal bar),
abolished the LTP induced by the TBS of three trains (downward
arrow) in normal control saline (control, n = 9; chelerythrine, n = 9;
**p < 0.01). B, In Gq mutant
mice, chelerythrine had no blocking effect on the LTP induced by the
TBS of five trains (downward arrow) (control,
n = 8; chelerythrine, n = 9).
C, The average increase in initial slopes of fEPSPs
(50-60 min after TBS); **p < 0.01.
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DISCUSSION |
We show that the threshold for LTP induction in the CA1 is
significantly elevated in null-mutant mice lacking Gq or G11. Full-size LTP can be induced in the area CA1 of both Gq and G11 mutant mice with the TBS of 10 burst trains, a widely used LTP induction protocol. In contrast, a weak TBS that consistently induced
LTP in wild-type mice was subthreshold for LTP induction in Gq and
G11 mutant mice. The LTP by the weak TBS was abolished by inhibiting
group I mGluR or PKC but not by blocking muscarinic acetylcholine
receptors. Prior activation of group I mGluR by an agonist
significantly enhanced the LTP by weak TBS in wild-type mice but not
Gq mutant mice. These results suggest that the signaling from group
I mGluR to PKC involving Gq/G11 facilitates LTP induction by
lowering its threshold in the hippocampal area CA1.
Role of signal transduction pathway via Gq/G11 in
LTP induction
Gq and G11 are the major Gq family isoforms in the adult
brain (Strathmann and Simon, 1990; Simon et al., 1991) and are wildly
distributed in the dendritic spines of pyramidal neurons in area CA1
(Mailleux et al., 1992; Tanaka et al., 2000). We could not evaluate the
effect of total deletion of the Gq family on LTP, because Gq and
G11 double knock-out mice are embryonic lethal (Offermanns et al.,
1998). Because deletion of either Gq or G11 resulted in elevation
of the threshold for LTP induction to the same extent, both isoforms
appear to contribute to the facilitation of LTP induction. A previous
study indicates that Gq- or G11-deficient mice do not exhibit a
compensatory upregulation of the other isoform (Kleppisch et al.,
2001). This might be a reason that Gq and G11 cannot be mutually
complementary in facilitating LTP induction. In contrast to the weak
TBS, a conventional LTP induction protocol, such as TBS with 10 burst
trains, can produce full-size LTP in both Gq- and G11-deficient
mice that is indistinguishable from LTP in wild-type mice. In other
studies, postsynaptic injection of GTPS, a nonhydrolyzable
guanine nucleotide analog, does not occlude LTP in area CA1 (Goh
and Pennefather, 1989; Katsuki et al., 1992). These results suggest
that the signal transduction pathway involving Gq or G11 is
not essential but has a significant modulatory effect in the induction
of LTP.
Group I mGluR is linked to the Gq/G11 to PKC
signaling cascade
In the area CA1, mGluR5 is highly expressed and enriched
at the perisynaptic site of the postsynaptic membrane (Nusser et al.,
1994; Luján et al., 1996, 1997). Immunoreactivity of Gq/G11 is observed in postsynaptic extrajunctional membrane and colocalized with mGluR5 in the neuropil of hippocampal pyramidal neurons (Tanaka et
al., 2000). Mutant mice lacking mGluR5 reportedly exhibit partial reduction of LTP in CA1 (Liu and Simon, 1996). It has been shown previously that mGluR antagonists have inhibitory effects on LTP in
certain experimental situations (Bashir et al., 1993; Riedel and
Reymann, 1993; Bortolotto et al., 1994; Richter-Levin et al., 1994),
especially in those studies using weak stimulation protocols (Riedel et
al., 1996; Wilsch et al., 1998; Balschun et al., 1999). In the present
study, we show that LTP induced by weak TBS was abolished by an mGluR
antagonist, MCPG. Together, it is most likely that group I mGluR is the
major Gq-coupled receptor that is activated during the induction of LTP
in area CA1.
The heterotrimeric Gq family couples to a wide variety of seven
transmembrane receptors other than group I mGluR (Exton, 1996). These
include muscarinic (M1, M3, and M5) receptors (Wess et al., 1995),
dopamine (D2, D3, and D5) receptors, 1-adrenergic receptors (Docherty, 1998), and serotonin (5-HT1A,
5-HT1c, and 5-HT2)
receptors (Hoyer and Martin, 1997). Possible involvement of these
receptors in LTP has been investigated. Activation of muscarinic M1 and M3 receptors has no effect on the LTP in area CA1, whereas the agonist
of the M2 receptor, which couples to Gi/o, enhances the level of LTP
(Auerbach and Segal, 1994; Kaneko et al., 1997). Cholinergic
denervation does not attenuate the magnitude of LTP and short-term
potentiation induced by weak stimulation protocol (Jouvenceau et al.,
1996). Dopamine D2 antagonists prevent the maintenance of LTP (Frey et
al., 1990), but the role of D2 receptors in the induction of LTP is not
clear. Noradrenaline has little effect on LTP in CA1 and does not
enhance the level of LTP induced by weak TBS protocols (Katsuki et al.,
1997). Application of serotonin decreases the magnitude of LTP (Staubli
and Otaky, 1994), and depletion of serotonin does not reduce LTP
(Stanton and Sarvey, 1985). The selective 5-HT2A
antagonist facilitates the LTP in the area CA1 (Wang and Arvanov,
1998). Mutant mice lacking 5-HT2C exhibit normal
LTP of Schaffer collateral-CA1 and mo-CA3 synapses (Tecott et al.,
1998). In the present study, we show that LTP induced by weak TBS was
not abolished by a muscarinic acetylcholine receptor antagonist,
atropine. These results suggest that these Gq-coupled receptors, other
than group I mGluR, do not play significant modulatory roles in LTP.
What could be the reasons for the lack of the facilitatory effect of
muscarinic receptors? A recent study indicates that spatial proximity
of G-protein-coupled receptors and their transducing molecules in
"signaling microdomains" is critical for the specificity and
sensitivity of cellular responses (Delmas et al., 2002). In many
neurons, it is known that B2 bradykinin receptors (B2Rs) but not M1
muscarinic receptors mobilize Ca2+ from
internal stores, although both B2Rs and M1 receptors couple to the same
transducing proteins (Gq-PLC) (Cruzblanca et al., 1998). Delmas et
al. (2002) demonstrated that in sympathetic neurons, only
IP3 formed by B2Rs has the ability to activate
IP3 receptors, although both B2Rs and M1
receptors rapidly produce IP3 and diacylglycerol. This exclusive coupling results from spatially restricted complexes linking B2Rs to IP3 receptors. It is possible
that group I mGluR may constitute signaling microdomains in CA1
pyramidal cells for the facilitation of LTP induction, whereas
muscarinic receptors might be spatially apart and cannot participate in
the microdomains.
We show that a PKC inhibitor, chelerythrine, abolished LTP induced by
weak TBS in the wild-type mice. However, a slightly stronger TBS can
induce LTP in Gq-deficient pyramidal cells that was comparable with
LTP in wild-type pyramidal cells but insensitive to chelerythrine. This
result suggests that PKC activation can facilitate LTP induction but is
not essential for it. Together, we conclude that in CA1 pyramidal
cells, the group I mGluRs couple to Gq/11 to the PKC signaling
cascade and exert facilitatory effects on LTP.
Other effects of group I mGluR to Gq/G11 signaling on
synaptic plasticity
We show that the priming effect of bath-applied ACPD on subsequent
induction of LTP is absent in Gq mutant mice. A previous study shows
the involvement of PLC in the priming effect in area CA1 (Cohen et al.,
1998). These results indicate that the priming effect of ACPD is
through the group I mGluR-Gq/G11-PLC signaling cascade. The
priming effect lasts 20 min after the washout of ACPD. This indicates
that activation of group I mGluR does not itself cause potentiation of
synaptic responses but can prepare a condition in which LTP can be
induced with weaker stimulation than control condition. Such a
phenomenon has been referred to as "metaplasticity" (Abraham and
Bear, 1996). At the behavioral level, this mechanism could facilitate
learning and memory in response to certain stimuli that have been
applied repeatedly to the animal in a certain time window.
It was reported recently that Gq mutant mice lack mGluR-dependent
LTD in the hippocampal CA1 region (Kleppisch et al., 2001). We also
found that LTD induced by low-frequency stimulation (1 Hz, 15 min) is
deficient in Gq mutant mice (M. Miura, S. Offermanns, M. I. Simon, and M. Kano, unpublished observations). Interestingly, Kleppisch
et al. (2001) report that mGluR-dependent LTD is normal in G11
mutant mice. These results indicate that the activation of the group I
mGluR-Gq cascade can induce LTD instead of LTP when a different
stimulation protocol is adopted. It remains to be elucidated how the
switchover between LTP and LTD is regulated in CA1 pyramidal cells. The
results suggest that the group I mGluR-Gq signaling cascade is
involved in both establishment of LTD and facilitation of LTP induction
and thus plays an important role in the modulation of synaptic strength
in the hippocampal area CA1.
| |
FOOTNOTES |
Received March 8, 2002; revised July 9, 2002; accepted July 12, 2002.
This work was supported in part by grants-in-aid for Scientific
Research (M.M., M.W., and M.K.) and Special Coordination Funds for
Promoting Science and Technology (M.W. and M.K.) from the Ministry of
Education, Culture, Sports, Science, and Technology of Japan and by
grants from the Novartis Foundation (M.K.) and the Cell Science
Research Foundation (M.K.).
Correspondence should be addressed to Masanobu Kano, Department of
Cellular Neurophysiology, Graduate School of Medical Science, Kanazawa
University, 13-1 Takara-machi, Kanazawa 920-8640, Japan. E-mail:
mkano{at}med.kanazawa-u.ac.jp.
M. Miura's present address: Department of Autonomic Nervous System,
Tokyo Metropolitan Institute of Gerontology, Sakae-cho, Itabashi
173-0015, Japan.
| |
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ABSTRACT
INTRODUCTION
