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The Journal of Neuroscience, June 15, 2002, 22(12):5239-5249
NMDA Receptors and L-Type Voltage-Gated Calcium Channels
Contribute to Long-Term Potentiation and Different Components of Fear
Memory Formation in the Lateral Amygdala
Elizabeth P.
Bauer*,
Glenn E.
Schafe*, and
Joseph E.
LeDoux
W. M. Keck Foundation Laboratory of Neurobiology, Center for
Neural Science, New York University, New York, New York 10003
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ABSTRACT |
Long-term potentiation (LTP) at sensory input synapses to the
lateral amygdala (LA) is a candidate mechanism for memory storage during fear conditioning. We evaluated the effect of L-type
voltage-gated calcium channel (VGCC) and NMDA receptor (NMDAR)
blockade in LA on LTP at thalamic input synapses induced by two
different protocols in vitro and on fear memory
in vivo. When induced in vitro by pairing
weak presynaptic stimulation with strong (spike eliciting) postsynaptic
depolarization, LTP was dependent on VGCCs and not on NMDARs, but, when
induced by a form of tetanic stimulation that produced prolonged
postsynaptic depolarization (but not spikes), LTP was dependent on
NMDARs and not on VGCCs. In behavioral studies, bilateral infusions of
NMDAR antagonists into the LA impaired both short-term and long-term
memory of fear conditioning, whereas VGCC blockade selectively impaired
long-term memory formation. Collectively, the results suggest that two
pharmacologically distinct forms of LTP can be isolated in the LA
in vitro and that a combination of both contribute to
the formation of fear memories in vivo at the cellular level.
Key words:
fear conditioning; APV; ifenprodil; verapamil; LTP; amygdala
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INTRODUCTION |
Neural plasticity in the lateral
amygdala (LA) is believed to underlie the acquisition and retention of
Pavlovian fear conditioning, including auditory fear conditioning in
which a tone [conditioned stimulus (CS)] is paired with foot shock
[unconditioned stimulus (US)] (Davis, 1992 ; Fanselow and LeDoux,
1999; LeDoux, 2000). The LA receives sensory information from both the
auditory thalamus and cortex, and CS and US inputs converge onto
individual cells in the LA (Romanski et al., 1993). Furthermore,
pairing of CS and US inputs during fear conditioning leads to
long-lasting alterations in synaptic transmission and neuronal activity
in the LA (McKernan and Shinnick-Gallagher, 1997; Quirk et al., 1995,
1997; Rogan et al., 1997; Repa et al., 2001).
One candidate mechanism for the plasticity seen in the LA during fear
conditioning is associative long-term potentiation (LTP), an
experience-dependent form of synaptic plasticity widely believed to
underlie many learning processes (Malenka and Nicoll, 1993, 1999;
Milner et al., 1998). In support of this hypothesis, LTP has been
demonstrated in each of the major sensory input pathways to the LA
(Clugnet and LeDoux, 1990; Chapman and Bellavance, 1992; Rogan and
LeDoux, 1995), and neural activity in the LA is altered during auditory
fear conditioning in a manner that is similar to artificial LTP
induction (McKernan and Shinnick-Gallagher, 1997; Rogan et al., 1997).
Moreover, LTP in the LA and fear conditioning are sensitive to the same
stimulus contingencies (Bauer et al., 2001) and share similar
biochemical mechanisms (Huang et al., 2000; Schafe and LeDoux, 2000;
Schafe et al., 2000).
Associative LTP requires calcium entry into postsynaptic cells, which
triggers a cascade of intracellular processes and, if sufficiently
strong, ultimately leads to gene expression and protein synthesis
(Milner et al., 1998; Malenka and Nicoll, 1999; Sweatt, 1999). In the
CA1 region of the hippocampus, in which LTP has been studied most
extensively, calcium can enter the postsynaptic cell through several
channels, including NMDA receptors (NMDARs) and voltage-gated calcium
channels (VGCCs), and LTP can be induced in such a way as to involve
either or both channels. For example, LTP induction protocols that
involve high-frequency tetanization (>200 Hz) or pairing of
presynaptic and postsynaptic inputs require VGCCs (Grover and Teyler,
1990; Magee and Johnston, 1997). Conversely, those that use
lower-frequency tetanus protocols ( 30 Hz) require NMDARs but not
VGCCs (Cavus and Teyler, 1996), whereas those tetanus protocols that
fall in the middle (100-200 Hz) can involve both types of channel
(Cavus and Teyler, 1996; Morgan and Teyler, 1999).
In the LA, calcium influx through L-type VGCCs is necessary for LTP at
thalamic input synapses in the LA induced in vitro by
pairing presynaptic stimulation with postsynaptic depolarizations (Weisskopf et al., 1999). This same LTP is insensitive to blockade of
NMDARs (Weisskopf et al., 1999). However, calcium entry through NMDARs
is required for LTP induced by tetanization of the cortical pathway to
LA (Huang and Kandel, 1998). Furthermore, behavioral studies have shown
that blockade of NMDARs in the LA impairs fear conditioning, suggesting
that an NMDAR-dependent plasticity in the LA underlies fear memory
formation (Miserendino et al., 1990; Maren et al., 1996; Lee and Kim,
1998; Rodrigues et al., 2001). The contribution of VGCCs to fear
memory, however, has not been tested.
In the present study, we examined the role of L-type VGCCs and NMDARs
in thalamo-LA LTP and fear memory formation. We first compared the
effects of VGCC and NMDAR blockade on LTP induced by protocols tailored
to recruit either VGCCs (pairing presynaptic stimulation with strong
postsynaptic depolarization) or NMDARs (a tetanus). We then compared
the effects of NMDAR and VGCC blockade in LA on the acquisition and
formation of auditory fear conditioning. Collectively, the results
suggest that both NMDARs and L-type VGCCs contribute to the synaptic
plasticity that underlies fear memory formation but in unique ways.
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MATERIALS AND METHODS |
Slice electrophysiology. Electrophysiological
experiments in amygdala slices were conducted as documented previously
(for a detailed description, see Weisskopf et al., 1999). Briefly, male
Sprague Dawley rats (3-5 weeks old) were deeply anesthetized with
halothane, and the brain was rapidly removed and transferred to
ice-cold artificial CSF (ACSF) containing (in
mM): 115 NaCl, 3.3 KCl, 1 MgSO4, 2 CaCl2, 25.5 NaHCO3, 1.2 NaH2PO4, 5 lactic acid, and
25 glucose (equilibrated with 95% O2-5%
CO2). Coronal slices (400-µm-thick) containing
the amygdala were cut and recovered in a holding chamber at 32-34°C
for 30 min and were then allowed to return to room temperature for at
least another 30 min before recording. An upright microscope equipped
with infrared differential interference contrast optics (Olympus
Optical, Tokyo, Japan) was used to perform whole-cell patch
recordings under visual guidance. Electrodes were filled with (in
mM): 130 K-gluconate, 0.6 EGTA, 2 MgCl2, 5 KCl, 10 HEPES, 2 Mg-ATP, and 0.3 Na3-GTP. The electrodes typically had resistances
of 4-8 M . All cells were allowed to remain at their resting
potentials. Whole-cell recordings were made from 71 neurons in the LA.
All of these showed various degrees of spike frequency adaptation and
had relatively broad action potentials, typical of excitatory cells in
the amygdala (Rainnie et al., 1991; McDonald 1992; Paré et al.,
1995). The average ± SD resting membrane potential, input
resistance, and membrane time constant were  69.4 ± 2.7 mV,
138 ± 45.4 M, and 16.1 ± 4.8 msec, respectively.
For in vitro experiments, stimuli (150 µsec duration) were
delivered through bipolar stainless steel electrodes placed in the
ventral striatum, just medial to LA (see Fig. 1A,
left). This stimulating protocol activates fibers that
originate, at least in part, in the auditory thalamus (Weisskopf et
al., 1999). For each cell, we measured the initial slope of the EPSP
during the first 2-3 msec after the onset of the response. Confounds
introduced by polysynaptic responses were controlled for by keeping the
stimulation intensity at a minimum to produce a reliable EPSP without
also recruiting polysynaptic responses or spiking, by computing
percentage of increase of the initial slope of the EPSP and by
excluding any data that demonstrated a change in EPSP latency after LTP induction. Baseline responses were monitored at 0.1 Hz. After stabilization of baseline responses, LTP was induced by one of two
protocols. The first consisted of pairing trains of 10 stimuli at 30 Hz
with 1 nA, 5 msec depolarizations given 5-10 msec after the onset of
each EPSP in the train. This pattern of stimulation yields an action
potential at the peak of each EPSP of the train. This pairing was given
15 times at 10 sec intervals. The second induction protocol consisted
of a 30 Hz tetanus (100 stimuli, given twice with a 20 sec interval).
For each cell, the stimulation intensity for LTP induction was the same
as that used to elicit baseline EPSPs.
Picrotoxin (75 µM) was included in the bath in all
experiments to block fast GABAergic transmission but was not observed
to produce epileptiform bursting in the amygdala. Drugs were made up in
DMSO stock solution and diluted 1000 times into the superfusing ACSF,
yielding a final concentration of 50 µM verapamil or
D-2-amino-5-phosphonopentanoic acid (APV) and 10 µM ifenprodil. Drugs used were D-APV,
methoxy-()-verapamil, picrotoxin, and ifenprodil (all from Sigma, St.
Louis, MO). Drugs were washed onto the slice between 10 and 30 min
before LTP induction and washed off the slices 10-15 min after LTP
induction in each experiment.
After LTP induction, test stimuli were presented once every 10 sec (0.1 Hz) for a total of 30 min. For analysis, values were binned into 1 min
intervals and expressed as a percentage of baseline. The values
recorded during the last 5 min of the recording session (minutes
25-30) were averaged into a single score for each cell. The amount of
potentiation was analyzed by comparing preinduction values (5 min
before induction) with those collected 25-30 min after LTP induction.
Significance of potentiation relative to baseline was tested with a
paired Student's t test. Comparison of the amount of
potentiation between groups (drug treatment vs vehicle) was tested with
a two-tailed, independent Student's t test. Differences
were considered significant if p < 0.05.
Behavioral procedures. Behavioral procedures were conducted
as described previously (Schafe and LeDoux, 2000; Schafe et al., 2000).
Under Nembutal anesthesia (45 mg/kg, i.p.), rats were first implanted
bilaterally with 26 gauge stainless steel guide cannulas aimed at the
LA. The guide cannulas were fixed to screws in the skull using a
mixture of acrylic and dental cement, and a 33 gauge dummy cannula was
inserted into each guide to prevent clogging. Rats were given at least
5 d to recover before experimental procedures. All surgical
procedures were conducted in accordance with the National Institutes of
Health Guide for the Care and Use of Experimental Animals
and were approved by the New York University Animal Care and Use Committee.
In the first experiment, we evaluated the effects of different doses of
the L-type VGCC blocker verapamil on auditory fear conditioning. Rats
were habituated to dummy cannula removal and to the conditioning
chamber for a minimum of 10-15 min. On the following day, rats were
given an intra-LA infusion of either 0.5 µl of
dH2O (vehicle) or one of three different doses of
verapamil-HCl (0.04, 0.4, or 4.0 µg/side in 0.5 µl of
dH2O; 0.25 µl/min). Distilled water was used as
a vehicle in these experiments because we were unable to dissolve
verapamil in ACSF or NaCl at the highest concentration (8.0 µg/µl).
Injectors remained in the cannulas for 1 min after drug infusion to
allow diffusion of the drug from the tip. Ten to 15 min after drug
infusions, rats were trained with two conditioning trials consisting of
a 20 sec, 5 kHz, 75 dB tone that coterminated with a 0.5 sec, 1.0 mA
foot shock (intertrial interval of 120 sec). Testing for
auditory fear conditioning took place ~24 hr later. For this test,
rats were placed in a distinctive environment (for details, see Schafe
et al., 2000) and exposed to eight CS tones (5 kHz, 75 dB, 30 sec)
without foot shocks. Total seconds of freezing during each CS
presentation was scored for each rat, and this number was expressed as
a percentage of the total CS presentation time. For analysis, scores
from each trial were averaged and treated as a single score. All data
were analyzed with ANOVA and Tukey's honestly significant
difference post hoc t tests. Differences were
considered significant if p < 0.05.
In the second experiment, we evaluated the effects of intra-LA infusion
of verapamil on memory consolidation of auditory fear conditioning.
Rats were habituated as before. On the conditioning day, rats were
given intra-LA infusion of 0.5 µl of dH2O
(vehicle), 4.0 µg of verapamil, or 5.0 µg of the NMDAR antagonist
APV (0.5 µl/side; 0.25 µl/min). Ten to 15 min after drug infusions,
rats were trained with three conditioning trials (20 sec, 5 kHz, 75 dB
tone paired with 1.0 mA, 0.5 sec foot shock). After conditioning, rats
were tested for auditory fear conditioning at 1, 3, 6, and 24 hr after
conditioning (three tones for each test; 5 kHz, 20 sec, 75 dB).
Freezing scores across trials were averaged into a single score and
analyzed using ANOVA as in the first experiment.
At the end of each behavioral experiment, rats were killed by an
overdose of chloral hydrate (600 mg/kg) and perfused with 10% buffered
formalin. Nissl staining and light microscopy were used to verify the
location of the cannula tips within the amygdala.
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RESULTS |
Pairing induces a VGCC-dependent, NMDAR-independent LTP at thalamic
input synapses in the LA
In the LA, LTP can be induced at thalamic input synapses by using
a pairing protocol in which weak presynaptic stimulation of
thalamo-amygdala afferents is presented concurrently with brief depolarization of the postsynaptic cell by current injection
(Weisskopf et al., 1999; Schafe et al., 2000; Bauer et al., 2001).
This type of LTP induction protocol produces action potentials in the
soma of the recorded neuron, which backpropagates into the dendrites (Magee and Johnston, 1997; Markram et al., 1997; Nishiyama et al.,
2000). It has been proposed that these backpropagating action potentials (BPAPs) invade the dendrites during pairing and interact with EPSPs, leading to calcium entry through VGCCs (Magee and Johnston,
1997; Stuart et al., 1997; Johnston et al., 1999; Stuart and Hausser,
2001). Consistent with this notion, we showed that application of
nifedipine, an L-type VGCC blocker, prevents the induction of LTP
induced by pairing (Weisskopf et al., 1999). However, nifedipine is
poorly suited for use in behavioral studies of fear conditioning
because it cannot be dissolved into a suitable concentration in aqueous
solution for infusion into the LA. Verapamil-HCl is a more soluble
L-type VGCC blocker that can be used in behavioral studies, but the
effects of verapamil on LTP in the LA have not been studied previously.
We therefore examined the ability of verapamil to block pairing-induced
LTP in amygdala brain slices. Specifically, we induced LTP by pairing
trains of 10 stimuli at 30 Hz delivered to the thalamic inputs to LA
with 1nA, 5 msec depolarizations of the postsynaptic LA cell (Fig.
1A, right). This pairing was given 15 times at 10 sec intervals.
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Figure 1.
Pairing-induced LTP at thalamic input synapses in
the LA is L-type VGCC dependent and NMDAR independent.
A, Left, Schematic of the amygdala slice
preparation, showing placement of stimulating and recording electrodes.
Afferent fibers from the auditory thalamus enter the LA medially,
coursing through the ventral most part of the striatum just above the
central nucleus. Recordings were made just below the site of
termination of auditory thalamic fibers terminating in the LA.
CE, Central nucleus of amygdala; B, basal
nucleus of amygdala; IC, internal capsule;
OT, optic tract; EC, external capsule.
Right, Example of the response of one cell to 10 stimuli delivered at 30 Hz paired with 1 nA, 5 msec depolarizations.
This pairing was given 15 times at 10 sec intervals to induce LTP.
B, Mean ± SE percentage of EPSP slope (relative to
baseline) in cells treated with ACSF vehicle (n = 6; squares) or 50 µM verapamil
(n = 5; triangles) before and after
LTP induction by pairing at time 0. Traces (averages of
10 responses) from individual experiments before and 30 min after LTP
induction are shown below. C, Mean ± SE percentage
of EPSP slope (n = 5; squares) and
amplitude (n = 4; triangles)
relative to baseline before and after treatment with 50 µM verapamil at time 0. Traces (averages
of 10 responses) are taken from an individual experiment before and 20 min after verapamil application. Inset, Mean ± SE
integral under evoked EPSP (AUC) relative to baseline before and
20 min after verapamil application (n = 5).
D, Mean ± SE percentage of EPSP slope (relative to
baseline) in cells treated with ACSF vehicle (n = 8; squares) or 50 µM APV
(n = 8; triangles) before and after
LTP induction by pairing at time 0. Traces (averages of
10 responses) from individual experiments before and 30 min after LTP
induction are shown below.
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VGCCs and pairing-induced LTP
Application of 50 µM verapamil blocked the induction
of LTP induced by pairing (Fig. 1B). The control
group showed 166 ± 23% potentiation, which was
significantly different from baseline (t(5) = 2.83; p < 0.05). The verapamil group showed 104 ± 16% potentiation, which
was not significantly different from baseline (p > 0.05), but was significantly different from vehicle controls (t(9) = 2.31; p < 0.05).
To determine whether verapamil affects baseline synaptic transmission
in the LA, we next examined the effects of 50 µM
verapamil on the initial slope and maximum amplitude of EPSPs induced
by thalamic stimulation (Fig. 1C). Verapamil was added to
the superfusing ACSF after a baseline period of at least 10 min. An
analysis of the size of the initial slope and maximum amplitude of the
EPSPs 15-20 min after verapamil application showed no significant
effects of the drug (slope, 95 ± 1.8%; amplitude, 96 ± 2.0%; p > 0.05 for both). Additionally, there was no
change in resting membrane potential (71.4 ± 0.55 mV predrug vs
69 ± 1.15 mV postdrug; p > 0.05). Finally, as
a more general measure of the effects of verapamil on EPSP kinetics, we
calculated the integral under the evoked EPSP [area under the curve
(AUC)] (Fig. 1C, inset) and found no significant
effect (110 ± 20.1% of predrug baseline; p > 0.05).
NMDARs and pairing-induced LTP
Next, we examined the ability of the NMDAR antagonist APV to block
the induction of LTP by the pairing protocol (Fig.
1D). In contrast to cells treated with verapamil,
cells treated with 50 µM APV did not show
significantly different levels of LTP. The APV-treated cells showed 147 ± 21% potentiation, which was significantly different from baseline
(t(7) = 2.49; p < 0.05) but not from vehicle controls (148 ± 21%;
p > 0.05).
Thus, blockade of L-type VGCCs, but not NMDARs, impairs pairing-induced
LTP at thalamic input synapses in the LA without affecting routine
synaptic transmission. These data are consistent with previous findings
from our laboratory showing that LTP induced by pairing at thalamic
input synapses to the LA is VGCC dependent and NMDAR independent
(Weisskopf et al., 1999).
A 30 Hz tetanus induces an NMDAR-dependent, L-type VGCC-independent
form of LTP at thalamic input synapses in the LA
Although the pairing protocol induces an NMDAR-independent form of
LTP, previous studies using tetanus protocols have demonstrated an
NMDAR-dependent LTP in the LA, particularly in the cortical input
pathway (Huang and Kandel, 1998). Moreover, NMDARs are necessary for
auditory fear conditioning (Lee and Kim, 1998; Rodrigues et al., 2001).
Because the pairing protocol described above triggers BPAPs that may
open dendritic VGCCs, we next used a second induction protocol that did
not trigger action potentials but rather produced a long depolarization
of the postsynaptic cell. This protocol, inspired by those used to
induce NMDAR-dependent LTP in the hippocampus (Cavus and Teyler, 1996),
consisted of 100 stimuli at 30 Hz delivered to the thalamic afferents
(Fig. 2A). This tetanus
was given twice, with a 20 sec interval between presentations.
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Figure 2.
Both tetanus-induced LTP and synaptic transmission
at thalamic input synapses to LA are impaired by APV. A,
Example of the response of one cell to 30 stimuli at 30 Hz. A tetanus
of 100 stimuli at 30 Hz given twice was used to induce LTP.
B, Mean ± SE percentage of EPSP slope (relative to
baseline) in cells treated with ACSF vehicle (n = 7; squares) or 50 µM APV
(n = 6; triangles) before and after
LTP induction by a 30 Hz tetanus at time 0. Traces
(averages of 10 responses) from individual experiments before and 30 min after LTP induction are shown below. C, Mean ± SE percentage of EPSP slope (n = 6;
squares) and amplitude (n = 6;
triangles) relative to baseline before and after
treatment with 50 µM APV at time 0. Traces
(averages of 10 responses) are taken from an individual experiment
before and 30 min after APV application. Inset,
Mean ± SE AUC (relative to baseline) before and 30 min after APV
application (n = 6). *p < 0.05 relative to predrug AUC.
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NMDARs and tetanus-induced LTP
Treatment of cells with 50 µM APV blocked LTP
induced by the tetanus relative to control cells (Fig.
2B). The control group showed 149 ± 5.3%
potentiation, which was significantly different from baseline
(t(6) = 9.81; p < 0.05). The APV-treated group showed 94 ± 5.0% potentiation,
which was not significantly different from baseline
(p > 0.05) but was significantly different from vehicle controls (t(11) = 8.24, p < 0.05).
To determine whether APV affects baseline synaptic transmission in the
LA, we next examined the effects of 50 µM APV on the initial slope and maximum amplitude of EPSPs (Fig. 2C). An
analysis of the size of the initial slope of the EPSPs 25-30 min after APV application showed no significant effects of the drug (slope, 90 ± 5.3%; p > 0.05). There was also no change
in resting membrane potential (67.4 ± 1.2 mV predrug vs
67.3 ± 1.8 mV postdrug; p > 0.05). However,
there was a significant decrease in the maximum amplitude of the EPSPs
(79 ± 3.4%; t(6) = 6.38;
p < 0.05). There was also a significant decrease in
the AUC of the EPSP (Fig. 2C, inset) (64 ± 8.2% of predrug baseline; t(5) = 5.02; p < 0.05). Thus, consistent with the results of
previous experiments, APV appeared to impair routine synaptic
transmission at thalamic input synapses (Li et al., 1995, 1996;
Weisskopf and LeDoux, 1999). As a result, it is not possible to
unambiguously conclude that the effect of APV on tetanus-induced LTP in
this pathway is a result of an impairment of synaptic plasticity.
The NR2B subunit and tetanus-induced LTP
APV is an NMDAR antagonist that disrupts the entire NMDA receptor
complex, including the NR1 subunits, which are critical for channel
function, and the NR2 subunits, which appear to regulate channel
function (Monyer et al., 1992). Thus, it may be possible to circumvent
the effects of APV on synaptic transmission in the thalamic input
pathway by selectively blocking individual subunits of the NMDA
receptor complex. In vitro studies have shown that the
NR1-NR2B complex exhibits longer EPSPs than the NR1-NR2A complex (Monyer et al., 1994), suggesting that NR2B might be particularly well
suited for coincidence detection and plasticity. Indeed, tyrosine
phosphorylation of NR2B has been correlated with synaptic plasticity in
the hippocampus (Rostas et al., 1996) and with taste learning in the
insular cortex (Rosenblum et al., 1996, 1997). Overexpression of this
subunit enhances LTP in the hippocampus, as well as learning in several
tasks, including fear conditioning (Tang et al., 1999). Furthermore, we
showed recently that intra-LA blockade of the NR2B subunit by the
selective antagonist ifenprodil disrupts the acquisition but not the
expression of fear conditioning (Rodrigues et al., 2001). This suggests
that NMDARs incorporating the NR2B subunit may be involved specifically
in synaptic plasticity, but not synaptic transmission, in the LA. In
the present study, we tested this hypothesis by examining whether
application of ifenprodil to amygdala brain slices impairs
tetanus-induced LTP at thalamic input synapses independently of an
effect on baseline synaptic transmission. Although, in cortical
preparations, ifenprodil has been shown to paradoxically increase NMDA
currents at concentrations ranging from 3 to 10 µM (Zhang et al., 2000), its effects have not
been examined on the electrophysiological properties of amygdala neurons.
Bath application of 10 µM ifenprodil blocked LTP relative
to control cells (Fig.
3A). The control group showed
143 ± 13.1% potentiation, which was significantly different from
baseline (t(6) = 3.31;
p < 0.05). The ifenprodil group showed 103 ± 9.5% potentiation, which was not significantly different from baseline (p > 0.05) but was significantly different from
vehicle controls (t(11) = 2.56;
p < 0.05). Unlike APV, however, ifenprodil had no
significant effects on EPSP kinetics (Fig. 3B). There was no significant effect of ifenprodil on the size of the initial slope of
the EPSP (99 ± 11% at 20-25 min relative to baseline;
p > 0.05) or the maximum amplitude (95 ± 5%;
p > 0.05). Additionally, there was no change in the
resting membrane potential (69.3 ± 0.8 mV predrug vs
69.4 ± 0.9 postdrug; p > 0.05) or in the AUC
(111 ± 16.6% of predrug baseline; p > 0.05)
(Fig. 3B, inset). Thus, bath application of
ifenprodil in our preparation impaired LTP induced by tetanus but had
no effect on different aspects of routine synaptic transmission.
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Figure 3.
Tetanus-induced LTP at thalamic input synapses is
impaired by selective NR2B blockade but not by an L-type VGCC
antagonist. A, Mean ± SE percentage of EPSP slope
(relative to baseline) in cells treated with ACSF vehicle
(n = 7; squares) or 10 µM of the selective NR2B antagonist ifenprodil (n = 6;
triangles) before and after LTP induction by a tetanus
at time 0. Traces (averages of 10 responses) from
individual experiments before and 30 min after LTP induction are shown
below. B, Mean ± SE percentage of EPSP slope
(n = 6; squares) or amplitude
(n = 6; triangles) relative to
baseline before and after treatment with 10 µM ifenprodil
at time 0. Traces (averages of 10 responses) are taken
from an individual experiment before and 25 min after ifenprodil
application. Inset, Mean ± SE AUC relative to
baseline before and 25 min after ifenprodil application
(n = 6). C, Mean ± SE
percentage of EPSP slope (relative to baseline) in cells treated with
ACSF vehicle (n = 7; squares) or 50 µM verapamil (n = 7;
triangles) before and after LTP induction by a tetanus
at time 0. Traces (averages of 10 responses) from
individual experiments before and 30 min after LTP induction are shown
below.
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VGCCs and tetanus-induced LTP
Finally, we examined the effect of VGCC blockade in the LA on
tetanus-induced LTP (Fig. 3C). Cells treated with 50 µM verapamil showed significant potentiation
from baseline (t(6) = 2.58;
p < 0.05) but did not show significantly different
levels of LTP relative to vehicle controls (p > 0.05). The control group showed 150 ± 5% potentiation, whereas
the verapamil group showed 164 ± 25% potentiation. The apparent
enhancement observed in the first 10 min after the tetanus is
consistent with the findings of previous reports that have examined
L-type VGCC-independent LTP in the hippocampus (Cavus and Teyler, 1996)
and may be similar to the previously documented
depolarization-dependent excitatory effects of dihydropyridine
compounds (O'Regan et al., 1990).
In summary, LTP induced by tetanus at thalamic input synapses in the LA
is impaired by NMDAR antagonists, including a selective NR2B
antagonist, but not by blockade of VGCCs. Together with the results of
the pairing protocol experiments, these findings suggest that, as in
the hippocampus, two pharmacologically distinct forms of LTP can be
induced at thalamic input synapses to the LA depending on the induction
protocol used. Furthermore, in each of our LTP experiments, the drugs
(verapamil, APV, and infenprodil) were washed off of the slice 10-15
min after LTP induction, whereas the impairment in LTP was observed to
last out to at least 30 min (Figs. 1-3). Additionally, in many
experiments, we held cells out to 1 hr after LTP induction, and the
impairment, where evident, was long lasting in each case (data not
shown). Thus, we believe that the most likely explanation for our
results is that we impaired LTP induction rather than expression with
these compounds.
Intra-LA blockade of L-type VGCCs and NMDARs impairs memory
formation of auditory fear conditioning but in different ways
Whereas the role of NMDA receptors in fear conditioning has been
studied extensively (Miserendino et al., 1990; Kim et al., 1991; Maren
et al., 1996; Walker and Davis, 2000; Rodrigues et al., 2001), no study
has to date examined the role of VGCCs in fear conditioning. In the
present experiments, we therefore gave rats intra-LA infusions of
different doses of the selective L-type VGCC blocker verapamil before
fear conditioning.
Blockade of VGCCs dose-dependently impairs fear
memory formation
In the first experiment, rats were infused with vehicle
(dH2O) or different doses of verapamil (0.04, 0.4, or 4.0 µg/side) before conditioning and tested for retention of
auditory fear conditioning ~24 hr later (Fig.
4A). Infusion of
dH2O as a vehicle did not appear to affect the
amount of freezing in controls. Vehicle-treated rats froze 75-80%
during retention tests, which is comparable with the level of freezing
that we observed in previous studies in which controls have been
infused with NaCl or ACSF (Wilensky et al., 1999; Schafe and LeDoux,
2000). Cannula tips were observed to lie throughout the rostrocaudal
extent of the amygdala (Fig. 4B). Only rats with
cannula tips at or within the borders of the LA or the basal amygdala
were included in the data analysis.
View larger version (29K):
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Figure 4.
Intra-LA infusion of an L-type VGCC antagonist
dose-dependently impairs auditory fear conditioning. A,
Schematic of behavioral protocol. B, Cannula tip
placements from rats infused with dH2O (black
squares), 0.04 µg of verapamil (white
squares), 0.4 µg of verapamil (white circles),
or 4 µg of verapamil (white triangles). Adapted from
Paxinos and Watson (1997). B, Basal nucleus of amygdala;
CE, central nucleus of amygdala. C,
Mean ± SE postshock freezing after the two conditioning trials in
rats given intra-LA infusions of dH2O (vehicle;
n = 10): 0.04 µg (n = 6), 0.4 µg (n = 8), or 4 µg (n = 9). D, Mean ± SE auditory fear memory 24 after
conditioning in the same rats. *p < 0.05 relative
to vehicle controls.
|
|
Infusion of verapamil had no effect on postshock freezing at any dose
(Fig. 4C), suggesting that foot shock sensitivity and US
processing in the LA were not disrupted by the drug. The ANOVA (drug
dose by trial) for postshock freezing scores showed an effect only for
trials (F(1,29) = 78.27;
p < 0.01). The effect for dose and the interaction
were not significant (p > 0.05). Twenty-four hours later, however, rats treated with verapamil showed a
dose-dependent impairment of long-term memory (LTM) to the tone (Fig.
4D). The ANOVA for LTM scores revealed a significant
effect for group (drug dose) (F(3,29) = 16.08; p < 0.01). Tukey's post hoc
t tests revealed that significant differences existed
between vehicle controls and the two highest doses of verapamil (0.4 and 4 µg; p < 0.05). No difference was detected
between the vehicle group and the lowest dose group (0.04 µg;
p > 0.05). Thus, long-term retention of Pavlovian fear
memory is dose-dependently disrupted by intra-LA infusion of verapamil.
Blockade of VGCCs selectively impairs LTM of fear conditioning
In the second experiment, we evaluated the role of L-type VGCCs in
fear memory consolidation. That is, rats were infused with the highest
dose of verapamil (4 µg/side), conditioned, and tested for auditory
fear conditioning at 1, 3, 6, and 24 hr after conditioning (Fig.
5A). For comparison with
previous studies, in this latter experiment, we also included a group
that was infused with 5 µg/side APV, a dose that has been shown
recently to block both short-term memory (STM) and LTM of fear
conditioning (Walker and Davis, 2000). Cannula tips were observed to
lie throughout the rostrocaudal extent of the amygdala (Fig.
5B).
View larger version (38K):
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Figure 5.
Blockade of L-type VGCCs or NMDARs in the LA
impairs memory formation of auditory fear conditioning in different
ways. A, Schematic of behavioral protocol.
B, Cannula tip placements from rats infused with
dH2O (black squares), 4 µg of verapamil
(white triangles), or 5 µg of APV (white
circles). Adapted from Paxinos and Watson (1997).
C, Mean ± SE postshock freezing between
conditioning trials in rats given intra-LA infusions of
dH2O (vehicle; n = 11), 4 µg of
verapamil (n = 11), or 5 µg of APV
(n = 8). D, Mean ± SE auditory
fear memory assessed at 1 hr after conditioning in the rats from
C. E, Mean ± SE auditory fear
memory assessed at 3 hr after conditioning in the rats from
C. F, Mean ± SE auditory fear
memory assessed at 6 hr after conditioning in the rats from
C. G, Mean ± SE auditory fear
memory assessed at 24 hr after conditioning in the rats from
C. Freezing during the 24 hr test is also expressed as a
percentage of that during the 1 hr test (% of
STM) for each rat (inset).
*p < 0.05 relative to vehicle controls.
|
|
As in the first experiment, intra-LA infusion of 4 µg of verapamil
had no effect on postshock freezing (Fig. 5C). However, consistent with previous studies (Lee and Kim, 1998), APV (5 µg) was
observed to have a significant effect. The ANOVA (drug by trials) for
postshock freezing scores showed a significant effect of drug
(F(2,27) = 137.01; p < 0.01), a significant effect of trials
(F(2,54) = 48.09; p < 0.01), and a significant drug by trials interaction
(F(4,54) = 8.71; p < 0.01). Tukey's post hoc t tests showed that
significant differences existed between the vehicle-verapamil groups
and the APV group on each trial (p < 0.05). No
significant differences were observed between the vehicle group and the
verapamil group after any of the training trials (p > 0.05).
Figure 5D-F depicts retention of auditory fear at 1, 3, and
6 hr after conditioning. Although APV-infused rats were observed to
have impaired fear memory at every time point, no significant differences were observed between the vehicle and 4 µg of
verapamil-treated groups. The ANOVAs for the 1, 3, and 6 hr tests
revealed a significant effect for drug (1 hr,
F(2,27) = 57.45, p < 0.01; 3 hr, F(2,27) = 13.92, p < 0.01; 6 hr,
F(2,27) = 10.35, p < 0.01). Tukey's post hoc t tests revealed that,
for each test, the APV-treated group was significantly different from
the vehicle-verapamil-treated groups (p < 0.05). No significant difference was detected between the vehicle and
verapamil-treated groups at any time point (p > 0.05). Thus, postshock freezing, as well as STM, was not affected by
intra-LA infusions of verapamil, which indicates that verapamil had no
significant effect on either shock or tone sensitivity in the LA.
Twenty-four hours after conditioning, however, verapamil-treated rats
showed substantial impairments in fear retention (Fig. 5G).
The ANOVA for the 24 hr test revealed a significant effect for drug
(F(2,27) = 8.86; p < 0.01). Tukey's post hoc t tests showed that the
both the APV- and verapamil-treated groups were significantly different
from the vehicle group (p < 0.05). No difference existed between verapamil-treated rats and those receiving APV (p > 0.05). To further analyze the memory
impairment in verapamil-treated rats at 24 hr, we examined 24 hr
freezing scores as a percentage of freezing scores for the 1 hr test in
rats from the vehicle- and verapamil-treated groups (Fig.
5G, inset). Once again, a significant difference
was observed (t(20) = 3.32;
p < 0.01).
Thus, intra-LA blockade of L-type VGCCs with verapamil impaired
long-term memory formation of auditory fear conditioning (>24 hr) but
had no effect on memory shortly after training. On the other hand,
consistent with the results of previous studies (Walker and Davis,
2000; Rodrigues et al., 2001), blockade of NMDARs impaired both STM and
LTM. Together, these findings suggest that NMDARs and L-type VGCCs
contribute to fear memory formation in qualitatively different ways.
The effect of verapamil on fear memory formation is not altered
when dissolved in saline vehicle
In our behavioral experiments, we dissolved the different doses of
verapamil in dH20 because the highest dose (4 µg/side) was not readily soluble in ionic solution. Thus, it could be
argued that our lack of an effect on acquisition and STM is
attributable to either (1) less than optimal performance of our
vehicle controls as a result of osmotic changes in the amygdala,
bringing them down to the level of verapamil-treated rats and thus
masking a difference in acquisition and STM, or (2) the drug
temporarily coming out of solution during infusion into brain, which
would make it unavailable at sufficient concentrations to affect
acquisition or STM. To address these two possibilities, we performed an
additional behavioral experiment using saline as a vehicle and a dose
of verapamil (1 µg/side) that is soluble in saline. Rats were infused with either 0.9% NaCl (0.5 µl/side; n = 8) or
verapamil (1 µg/side in 0.9% NaCl; n = 7) 10-15 min
before receiving three conditioning trials. One hour after
conditioning, rats were given an STM test consisting of presentation of
five tones, followed ~24 hr later by an LTM test consisting of 10 tones. For analysis, freezing scores across trials for both the STM and
LTM tests were averaged into a single score.
Results (data not shown) showed that both groups of rats had equivalent
STM at 1 hr (t(13) = 0.48;
p = 0.63). The NaCl-infused rats exhibited 77 ± 4.7% freezing, whereas the verapamil-treated rats exhibited 80 ± 3.8% freezing. Twenty-four hours later, however, a significant
difference was observed between groups
(t(13) = 2.65; p = 0.01). The NaCl-infused rats exhibited 54.25 ± 6.8% freezing,
whereas the verapamil-treated rats exhibited 29.07 ± 6.3%
freezing. This difference was even more pronounced when LTM was
expressed as a percentage of STM for each rat
(t(13) = 3.04; p = 0.009; NaCl, 69.9 ± 6.6%; verapamil, 23.1 ± 8.7%). Thus,
as in our previous experiments in which dH20 was
used as a vehicle, verapamil impaired LTM of auditory fear
conditioning, whereas STM was left intact.
| |
DISCUSSION |
The present series of experiments evaluated the roles of VGCCs and
NMDARs in both the induction of LTP at thalamic input synapses in LA
in vitro and the acquisition and memory formation of
auditory fear conditioning. The findings indicate that two
pharmacologically distinct forms of LTP in this pathway can be
distinguished depending on the induction protocol used. Using a pairing
protocol, in which presynaptic stimulation of thalamic input fibers is
paired with brief postsynaptic depolarizations, we were able to induce
a VGCC-dependent, NMDAR-independent form of LTP. Using a tetanus that
produced prolonged depolarization of the postsynaptic cell but not
spiking, we induced a VGCC-independent LTP that was blocked by the
NMDAR antagonist APV, as well as the more selective NR2B subunit
antagonist ifenprodil. In behavioral experiments, blockade of NMDARs in
the LA before training produced deficits in both STM, as assessed at 1 hr, and in LTM, as assessed 24 hr later. Blockade of VGCCs, on the
other hand, produced an impairment only at 24 hr, suggesting that VGCCs are selectively involved in LTM formation.
Two pharmacologically distinct forms of LTP at thalamic input
synapses in the LA
Recent experiments in our laboratory have shown that LTP at
thalamic input synapses to the LA is L-type VGCC dependent and NMDAR
independent (Weisskopf et al., 1999). Those experiments used a pairing
protocol in which subthreshold presynaptic stimulation of auditory
afferents was paired with brief postsynaptic depolarizations (Magee and
Johnston, 1997; Markram et al., 1997; Johnston et al., 1999; Nishiyama
et al., 2000). In this protocol, BPAPs originating in the soma are
thought to invade the dendrites and interact with EPSPs, leading to
calcium influx through VGCCs (Magee and Johnston, 1997; Stuart et al.,
1997; Johnston et al., 1999). Accordingly, LTP induced by pairing in
the thalamic pathway is blocked by application of nifedipine, an L-type
VGCC blocker (Weisskopf et al., 1999). In the present study, a second
L-type VGCC blocker, verapamil, similarly blocked LTP induced by
pairing, whereas the NMDAR antagonist APV had no significant effect.
Thus, when EPSPs and brief depolarizations are induced repeatedly in a
synchronous train, they appear to cause enough calcium influx through
VGCCs to induce LTP independently of NMDARs (Weisskopf et al., 1999;
Blair et al., 2001).
It is clear, however, that NMDARs are essential for fear conditioning
(Miserendino et al., 1990; Kim et al., 1991; Maren et al., 1996; Walker
and Davis, 2000; Rodrigues et al., 2001) and that an NMDAR-independent
form of LTP in the LA is not adequate to account for fear
conditioning at the cellular level. In the LA, NMDAR-dependent LTP has
been induced by tetanic stimulation in the cortical input pathway
(Huang and Kandel, 1998). However, no study has to date demonstrated
the involvement of NMDARs in LTP induced in thalamic input synapses to
the LA. In fact, previous studies have shown that NMDARs contribute to
transmission in the LA (Rainnie et al., 1991; Danober and Pape, 1998;
Mahanty and Sah, 1999; Weisskopf and LeDoux, 1999) and that
application of APV can reduce synaptic transmission in the LA (Li et
al., 1995, 1996; Weisskopf and LeDoux, 1999). In the present study, we
used a tetanus protocol to induce LTP in the thalamic pathway, a
protocol that, unlike the pairing protocol, does not trigger action
potentials but instead produces a sustained depolarization of the
postsynaptic cell. This type of LTP was effectively blocked by the
NMDAR antagonist APV, as well as the more selective NR2B subunit
antagonist ifenprodil, but spared by application of VGCC blockers.
Moreover, whereas APV was observed, as in previous studies, to have
effects on routine transmission in this pathway, ifenprodil had no
effect on synaptic transmission. Thus, consistent with behavioral
studies that have demonstrated a role for NMDARs (Miserendino et al.,
1990; Kim et al., 1991; Maren et al., 1996; Walker and Davis, 2000) and the NR2B subunit (Rodrigues et al., 2001) in fear memory,
NMDAR-dependent LTP exists at thalamic input synapses to the LA. As in
the hippocampus, however, the involvement of NMDARs appears to be
sensitive to the LTP induction protocol.
Although the present experiments show that it is possible to
artificially induce LTP in the LA that selectively requires either NMDARs or VGCCs, this should not be taken to indicate that amygdala LTP
must always depend on one of these mechanisms and not the other. In
fact, as discussed previously, some forms of hippocampal LTP appear to
require both types of receptor (Huber et al., 1995; Cavus and Teyler,
1996; Magee and Johnston, 1997; Morgan and Teyler, 1999). Furthermore,
a recent study found that LTP in the LA at cortical input synapses is
attenuated, but not completely blocked, by NMDAR antagonists (Huang and
Kandel, 1998). That study used a protocol that involved pairing of
low-frequency (0.2 Hz) presynaptic stimulation with prolonged
depolarization of the postsynaptic cell by current injection. In
contrast to our pairing protocol in which brief depolarizations of the
postsynaptic cell were used, this prolonged depolarization protocol
appeared to be sufficient to open the channel of NMDARs. Furthermore,
although not explicitly tested, the present data would suggest that the
NMDAR-independent component of this type of LTP might depend on VGCCs
(Huang and Kandel, 1998).
Implications for fear memory formation
The LTP findings in the present study indicate that both L-type
VGCCs and NMDARs are essential to synaptic plasticity in the LA but
that their involvement depends on the LTP induction protocol used. In
the behavioral studies, we showed that both NMDARs and L-type VGCCs are
necessary for fear memory formation in the LA but in qualitatively
different ways. Consistent with previous studies (Walker and Davis,
2000; Rodrigues et al., 2001), intra-LA blockade of NMDARs resulted in
impaired STM and LTM. Blockade of L-type VGCCs, however, selectively
impaired the formation of LTM. This latter finding is consistent with
that of a recent report that demonstrated the involvement of L-type
VGCCs in the maintenance of spatial memory over long, but not shorter,
time periods (Borroni et al., 2000).
Because fear conditioning in the LA requires both NMDARs and L-type
VGCCs, this suggests that a combination of the two in vitro
LTP models is necessary to explain fear memory formation at the
cellular level (Blair et al., 2001). Specifically, we propose that pairing of CS and US inputs during fear conditioning leads to
calcium entry through both NMDARs and L-type VGCCs in LA principal cells. The increase in intracellular calcium through both types of
channels ultimately, however, results in the formation of different kinds of memory. NMDARs, in particular the NR2B subunit, play an
essential role in STM formation (Walker and Davis, 2000; Rodrigues et
al., 2001), possibly by activation of local protein kinases that can
phosphorylate existing membrane proteins (Soderling and Derkach, 2000).
L-type VGCCs, on the other hand, play a selective role in LTM, possibly
by activation of different protein kinases that can translocate to the
nucleus and initiate gene expression and the synthesis of new proteins
that are required for LTM formation (Blair et al., 2001; Schafe et al.,
2001). In support of this hypothesis, a number of studies have
implicated the involvement of L-type VGCCs in cAMP response
element-binding protein (CREB) phosphorylation and CRE-driven
gene expression in hippocampal neurons (Bading et al., 1993; Deisseroth
et al., 1998; Mermelstein et al., 2000; Deisseroth and Tsien, 2002).
More recently, it has been shown that stimulation of L-type VGCCs, but
not NMDARs, leads to sustained nuclear CREB phosphorylation and
CREB binding protein-driven gene expression via the
Ca2+/calmodulin-dependent kinase IV (CaMKIV)
signaling pathway (Hardingham et al., 2001). Furthermore,
Greenberg and colleagues have demonstrated recently a selective role
for L-type VGCCs in signaling to the nucleus to initiate CRE-mediated
transcription via the extracellular signal-regulated
kinase/mitogen-activated protein (ERK/MAP) kinase signaling
pathway (Dolmetsch et al., 2001). Importantly, ERK/MAP kinase, CaMKIV,
and CREB have all been shown to be necessary for the formation of
long-term, but not short-term, fear memories (Bourtchuladze et al.,
1994; Schafe et al., 2000; Josselyn et al., 2001; Kang et al.,
2001). Additional experiments will be necessary to determine the
contribution of L-type VGCCs to activation of protein kinases and
CRE-driven gene expression in the LA after fear conditioning.
As in previous studies that have directly examined the relationship
between LTP and memory in the amygdala, LTP in our verapamil-treated slices appears to decay with a much faster time course than fear memory
after the same manipulation (Figs. 1, 5). This is not a novel finding
but is in fact quite common in the LTP-behavior literature and one
that we wrote about recently (Schafe et al., 2001). Many compounds that
impair long-term but not short-term memory have been shown to block LTP
within minutes after induction. In the in vitro amygdala
preparation, for example, bath application of inhibitors of protein
synthesis, PKA or ERK/MAPK activity begins to impair LTP immediately
after induction (Huang et al., 2000), whereas intra-amygdala infusion
of the same compounds in behavioral experiments results in memory
impairment only at 24 hr after conditioning (Schafe and LeDoux, 2000;
Schafe et al., 2000). It is not immediately clear what this pattern of
findings could mean. However, it does not appear to be unique to
pharmacological manipulations. The same pattern of findings is observed
in the molecular genetic literature, in which genetic manipulation of
the Ras/ERK/Rsk pathway results in complete decay of LTP in the
amygdala with 30 min after induction, whereas fear memory in the same
mice is intact for at least 1 hr after training (Brambilla et al.,
1997). One likely possibility is that it is simply a quantitative
difference created by the in vitro slice preparation (Schafe
et al., 2001). Future experiments using in vivo
electrophysiological methods will be necessary to examine this question further.
The findings of the present study clearly suggest that NMDARs and
L-type VGCCs make unique contributions to fear memory formation in the
LA. However, many important questions remain to be addressed. For
example, how do CS and US inputs engage these different channels during
fear learning? How are these channels differentially involved in the
activation of signal transduction pathways that promote short-term and
long-term memory formation? Additional experiments will be required to
address these questions. However, our ability to isolate two
pharmacologically distinct types of LTP at thalamic input synapses in
the LA and explicitly test hypotheses generated from those findings in
behavioral studies of fear conditioning has distinct advantages. Not
only does it allow us to address biophysical questions of cellular and
synaptic activity as they relate to memory storage, but it may also
allow us to determine the relative contribution of VGCCs and NMDARs in
initiating second-messenger systems and/or gene expression that
underlie different types of memory formation in the LA.
| |
FOOTNOTES |
Received Jan. 24, 2002; revised April 5, 2002; accepted April 9, 2002.
*
E.P.B. and G.E.S. contributed equally to this work.
This research was supported in part by National Institute of Mental
Health Grants MH 46516, MH00956, MH 39774, and MH 11902 and a National
Science Foundation Graduate Fellowship to E.P.B. The work was also
supported by a grant from the W. M. Keck Foundation to New York
University. We thank Kathryn Johnson and Annemieke Schoute for
technical assistance. We also thank Hugh T. Blair for helpful comments
on this manuscript.
Correspondence should be addressed to Elizabeth P. Bauer, Center for
Neural Science, 4 Washington Place, Room 809, New York, NY 10003. E-mail: bauer{at}cns.nyu.edu.
| |
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A. W. Hendricson, M. P. Thomas, M. J. Lippmann, and R. A. Morrisett
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S. Lei, K. A. Pelkey, L. Topolnik, P. Congar, J.-C. Lacaille, and C. J. McBain
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C.-H. Lin, S.-H. Yeh, H.-Y. Lu, and P.-W. Gean
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C. Szinyei, O. Stork, and H.-C. Pape
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C.-H. Lin, C.-C. Lee, and P.-W. Gean
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C. K. Cain, A. M. Blouin, and M. Barad
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TOP
ABSTRACT
INTRODUCTION
Compound via MeSH
