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The Journal of Neuroscience, March 15, 2002, 22(6):2343-2351
Facilitation of Conditioned Fear Extinction by Systemic
Administration or Intra-Amygdala Infusions of D-Cycloserine
as Assessed with Fear-Potentiated Startle in Rats
David L.
Walker,
Kerry J.
Ressler,
Kwok-Tung
Lu, and
Michael
Davis
Department of Psychiatry and Behavioral Sciences, Emory University,
Atlanta, Georgia 30322
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ABSTRACT |
NMDA receptor antagonists block conditioned fear extinction when
injected systemically and also when infused directly into the amygdala.
Here we evaluate the ability of D-cycloserine (DCS), a
partial agonist at the strychnine-insensitive glycine-recognition site
on the NMDA receptor complex, to facilitate conditioned fear extinction
after systemic administration or intra-amygdala infusions.
Rats received 10 pairings of a 3.7 sec light and a 0.4 mA footshock
(fear conditioning). Fear-potentiated startle (increased startle in the
presence vs the absence of the light) was subsequently measured before
and after 30, 60, or 90 presentations of the light without shock
(extinction training). Thirty non-reinforced light presentations
produced modest extinction, and 60 or 90 presentations produced nearly
complete extinction (experiment 1). DCS injections (3.25, 15, or 30 mg/kg) before 30 non-reinforced light exposures dose-dependently
enhanced extinction (experiment 2) but did not influence
fear-potentiated startle in rats that did not receive extinction
training (experiment 3). These effects were blocked by HA-966, an
antagonist at the glycine-recognition site (experiment 4). Neither DCS
nor HA-966 altered fear-potentiated startle when injected before
testing (experiment 5). The effect of systemic administration was
mimicked by intra-amygdala DCS (10 µg/side) infusions (experiment 6).
These results indicate that treatments that promote NMDA receptor
activity after either systemic or intra-amygdala administration promote
the extinction of conditioned fear.
Key words:
D-cycloserine; HA-966; NMDA; fear
conditioning; fear-potentiated startle; extinction; amygdala
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INTRODUCTION |
Classical fear conditioning occurs
when an affectively neutral stimulus is paired with a noxious aversive
stimulus [unconditioned stimulus (US)] such as footshock. Afterward,
the previously neutral stimulus [i.e., now the conditioned stimulus
(CS)] is able to elicit a variety of autonomic, hormonal, and skeletal
responses that accompany the conscious experience of fear in humans and that are used to operationally define fear in laboratory animals. The
fear-eliciting properties of the CS can be extinguished by repeatedly
presenting the CS in the absence of the US. It is generally believed
that extinction does not reflect unlearning of the original association
but involves instead the formation of new associations that compete
with the previously conditioned response (cf. Bouton and Bolles, 1985 ;
Falls and Davis, 1995; Davis et al., 2000; Rescorla, 2001). As with
fear conditioning itself, fear extinction can be blocked by NMDA
receptor antagonists administered either systemically (Cox and
Westbrook, 1994; Baker and Azorlosa, 1996) or infused directly
into the amygdala (Falls et al., 1992; Lee and Kim, 1998). The
involvement of the amygdala is of particular interest given the well
known involvement of this structure in excitatory fear conditioning
(Kapp et al., 1990; Fanselow and LeDoux, 1999; Davis, 2000).
Because NMDA receptor antagonists block extinction, it is possible that
NMDA receptor agonists would facilitate extinction. However, the well
documented neurotoxic effects of NMDA receptor agonists argue against
their use in humans and, as such, increasing attention has focused on
partial agonists that might facilitate NMDA receptor activity in a more
limited manner (Lawlor and Davis, 1992; Olney, 1994). In fact, partial
agonists such as D-cycloserine (DCS), a compound that acts
at the strychnine-insensitive glycine-recognition site of the NMDA
receptor complex, have been shown to enhance learning and memory in
several animal paradigms, including visual recognition tasks in
primates (Matsuoka and Aigner, 1996), eyeblink conditioning in rabbits
(Thompson et al., 1992), avoidance learning in rats and mice (Monahan
et al., 1989; Flood et al., 1992; Land and Riccio, 1999), and maze
learning in rats and mice (Monahan et al., 1989; Quartermain et al.,
1994; Pitkanen et al., 1995; Pussinen et al., 1997), without producing
obvious neurotoxicity. DCS has also been found, in some studies, to
modestly improve cognition in clinical populations (Javitt et al.,
1994; Schwartz et al., 1996; Goff et al., 1999; Tsai et al., 1999) and
has been used for many years to treat tuberculosis, again without
obvious neurotoxicity.
Because a reduced ability to extinguish intense fear memories is a
significant clinical problem (e.g., in specific phobias, panic
disorder, and post-traumatic stress disorder) (Morgan et al., 1995;
Fyer, 1998; Gorman et al., 2000) and because treatment for these
disorders often relies on the progressive extinction of fear memories
(Zarate and Agras, 1994; Dadds et al., 1997; Foa, 2000),
pharmacological enhancement of extinction could be of considerable
clinical benefit. With this in mind, we sought to determine whether
conditioned fear extinction could be enhanced by DCS.
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MATERIALS AND METHODS |
Animals
Adult male Sprague Dawley rats (Charles River, Raleigh, NC)
weighing between 300 and 400 gm were used. Animals were housed in group
cages of four rats each in a temperature-controlled (24°C) animal
colony, with access to food and water ad libitum. They were
maintained on a 12 hr light/dark cycle with lights on at 7:00
A.M. All behavioral procedures took place during the rats' light cycle. A total of 178 rats were used.
Apparatus
Animals were trained and tested in 8 × 15 × 15 cm
Plexiglas and wire-mesh cages. The cage floor consisted of four
6.0-mm-diameter stainless-steel bars spaced 18 mm apart. Each cage was
suspended between compression springs within a steel frame and located
within a custom-designed 90 × 70 × 70 cm ventilated
sound-attenuating chamber. Background noise (60 dB wide-band) was
provided by a General Radio Type 1390-B noise generator (Concord, MA)
and delivered through high-frequency speakers (Radio Shack
Supertweeter; Tandy, Fort Worth, TX) located 5 cm from the front of
each cage. Sound level measurements (sound pressure level) were
made with a Bruel & Kjaer (Marlborough, MA) model 2235 sound-level
meter (A scale; random input) with the microphone (Type 4176) located 7 cm from the center of the speaker (approximating the distance of the
rat's ear from the speaker).
Startle responses were evoked by 50 msec, 95 dB white-noise bursts (5 msec rise-decay) generated by a Macintosh G3 computer soundfile (0-22
kHz), amplified by a Radio Shack amplifier (100 W; model MPA-200;
Tandy), and delivered through the same speakers used to provide
background noise. An accelerometer (model U321AO2; PCB Piezotronics,
Depew, NY) affixed to the bottom of each cage produced a voltage output
proportional to the velocity of cage movement. This output was
amplified (model 483B21; PCB Piezotronics) and digitized on a scale of
0-2500 U by an InstruNET device (model 100B; GW Instruments,
Somerville, MA) interfaced to a Macintosh G3 computer. Startle
amplitude was defined as the maximal peak-to-peak voltage that occurred
during the first 200 msec after onset of the startle-eliciting stimulus.
The CS was a 3.7 sec light (82 lux) produced by an 8 W fluorescent bulb
(100 µsec rise time) located 10 cm behind each cage. Luminosity was
measured using a VWR light meter (Atlanta, GA). The US was a 0.5 sec
shock, delivered to the floorbars and produced by a shock
generator (SGS-004; LeHigh Valley, Beltsville, MD). Shock intensities
(measured as in Cassella et al., 1986) were 0.4 mA. The presentation
and sequencing of all stimuli were under the control of the Macintosh
G3 computer using custom-designed software (The Experimenter;
Glassbeads Inc., Newton, CT).
Surgery and histology
Rats that were to receive intra-amygdala infusions (experiment
6) were anesthetized with Nembutal (50 mg/kg sodium pentobarbital, i.p)
and placed in a stereotaxic frame (ASI Instruments, Inc., Warren, MI).
The skull was exposed and 22 gauge guide cannulas (model C313G;
Plastics One, Inc., Roanoke, VA) were implanted bilaterally into the
basolateral nucleus of the amygdala (anteroposterior,  2.8;
dorsoventral, 9.0; mediolateral, ±5.0 from bregma). Dummy cannulas (model C313DC; Plastics One, Inc.) were inserted into each
cannula to prevent clogging. These extended ~1 mm past the end of the
guide cannula. Screws were anchored to the skull and the assembly was
cemented in place using dental cement (The Hygenic Corp., Akron, OH).
Behavioral procedures began either 10 or 11 d after surgery.
Cannulated rats subsequently received a chloral hydrate overdose and
were perfused intracardially with 0.9% saline followed by 10%
formalin. The brains were removed and immersed in a 30%
sucrose-formalin solution for at least 3 d, after which 40 µm
coronal sections were cut through the area of interest. Every fourth
section was mounted and stained with cresyl violet.
Drug administration
Systemic administration.
D-cycloserine (Sigma-Aldrich, St. Louis, MO)
(3.25, 15, and 30 mg/kg) and (±)-HA-966 (Research Biochemicals, Inc.,
Natick, MA) (6 mg/kg) were freshly dissolved in saline and injected
intraperitoneally 30 min before extinction training. Drug doses were
chosen based on preliminary findings (K. T. Lu and M. Davis,
unpublished results), on the results of other behavioral studies
(Monahan et al., 1989; Flood et al., 1992; Moraes Ferreira and Morato,
1997; Pussinen et al., 1997; Land and Riccio, 1999), on estimates of
brain concentration after systemic administration (extrapolated from
Loscher et al., 1994) together with findings relating drug
concentrations in vitro to DCS effects on NMDA receptor function measured electrophysiologically (Watson et al., 1990; Priestley and Kemp, 1994) or vis-à-vis ligand binding to the use-dependent channel-associated binding site (Hood et al., 1989; Hamelin and Lehmann, 1995), and on the ability of systemically administered DCS to influence NMDA receptor-mediated cGMP
concentrations in mouse cerebellum (Emmett et al., 1991).
Intra-amygdala infusion. DCS (10 µg/side) or saline was
infused (0.25 µl/min) through 28 gauge injection cannulas (model
C313I; Plastic Products) 20 min before extinction training. The total volume infused was 0.5 µl/side. The infusion cannulas were left in
place for 2 min before being withdrawn.
General behavioral procedures
Behavioral procedures for all experiments consisted of an
acclimation phase, a baseline startle test, a fear-conditioning phase,
a pre-extinction test, extinction training, and a postextinction test
(Fig. 1A).
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Figure 1.
Parametric evaluation of different amounts
of extinction training. A, Timeline of the behavioral
procedures for experiment 1. B. Percent fear-potentiated
startle measured 24 hr before (pretest) and 24 hr after (post-test)
extinction training or context exposure. The control group was tested
2 d after the pretest, with no intervening exposures. One session
of non-reinforced cue exposure produced only modest levels of
extinction. Two or three sessions more completely extinguished the fear
response. *p < 0.05 versus context exposure group;
+p < 0.05 versus control group.
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Acclimation. On each of 3 consecutive days, rats were placed
into the test chambers for 10 min and then returned to their home cages.
Baseline startle test. On each of the next 2 consecutive
days, animals were placed in the test chambers and presented with 30 95 dB noise bursts at a 30 sec interstimulus interval (ISI). Animals whose
baseline startle was <1% of the possible accelerometer output were
excluded insofar as fear-potentiated startle cannot be properly
measured with such a low baseline (2 of 144 rats were excluded on this basis).
Fear conditioning. After 24 hr, rats were returned to the
test chambers and 5 min later given the first of 10 light-footshock pairings. The 0.4 mA, 0.5 sec shock was delivered during the last 0.5 sec of the 3.7 sec light. The average intertrial interval was 4 min
(range, 3-5 min).
Pre-extinction test. At 24 hr after fear conditioning, rats
were returned to the test chambers and presented 5 min later with 30 95 dB noise bursts (30 sec ISI). These initial startle stimuli were used
to habituate the startle response to a stable baseline before the
noise-alone and light-noise test trials that followed. A stable
baseline, in turn, reduces variability in the fear-potentiated startle
measure described below. After 30 sec, 20 additional noise bursts were
presented (ISI of 30 sec). One-half of these were presented in darkness
(noise-alone test trial) and one-half were presented 3.2 sec after
onset of the 3.7 sec light (light-noise test trial). The order of
these two trial types was randomized with the constraint that no two
trial types occurred more than twice in a row. Percent fear-potentiated
startle was computed as [(startle amplitude on light-noise minus
noise-alone trials)/noise-alone trials] × 100. Based on these data,
rats were sorted into equal-sized groups such that each group had
comparable mean levels of percent fear-potentiated startle. Because the
fear-potentiated startle test is itself an extinction procedure (i.e.,
CS presentations without shock), and because we wanted to minimize any
incidental extinction before explicit extinction training with drug, a
minimal number of CS presentations were used in this test compared with the more lengthy postextinction test described below. However, we have
found that this abbreviated test is adequate for matching rats into
different groups with comparable levels of fear-potentiated startle.
Extinction training. At 24 hr after the pre-extinction test,
rats were returned to the test chamber and 5 min later received 30 3.7 sec light exposures without shock (ISI of 30 sec). Control rats were
placed in the test cages and remained there for the same amount of time
as rats in the extinction groups, but did not receive non-reinforced CS
presentations. Rats in experiment 1 received one, two, or three
sessions of extinction training with a 24 hr interval between each.
Rats in all other experiments received a single session of extinction training.
Postextinction test. At 24 hr after the last extinction
session, rats were returned to the test chamber and presented 5 min later with 30 95 dB noise bursts, as in the pre-extinction short test,
to habituate the startle response to a stable baseline before the
noise-alone and light-noise test trials that followed. After 30 sec,
60 intermixed noise-alone and light-noise test trials (95 dB, ISI of
30 sec) were presented. Percent potentiation was calculated from the
noise-alone and light-noise test trials as described previously.
Statistics
ANOVA on percent potentiation scores was the primary statistical
measure. Between-group comparisons were also made using two-tailed t tests for independent samples. The criterion for
significance for all comparisons was p < 0.05.
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RESULTS |
Experiment 1: parametric evaluation of different amounts of
extinction training
This experiment assessed the effect on fear-potentiated startle of
1, 2, or 3 d of extinction training. A total of 42 rats were
matched into seven groups of six animals, each based on their level of
fear-potentiated startle in the pre-extinction test. Beginning 24 hr
after the pre-extinction test, rats received 1, 2, or 3 consecutive
days of extinction training (30 non-reinforced light presentations per
day) or 1, 2, or 3 d of exposure to the context without extinction
training. An additional control group was tested 2 d after the
pre-extinction test without intervening exposures to either context or
the visual CS.
Figure 1B shows that after 1 d of extinction
training, fear-potentiated startle was reduced by ~35% compared with
the pre-extinction test. After 2 or 3 d, fear-potentiated startle
was reduced by ~90%. A two-way ANOVA with treatment (non-reinforced
CS presentations vs context exposure alone) and days (one, two, or
three extinction sessions) as between-subjects factors indicated a
significant treatment effect (F(1,30) = 13.01) and also a significant treatment × days interaction
(F(2,30) = 8.90). Thus, the reduction
of fear-potentiated startle across days was greater in the groups that
received non-reinforced CS exposures than in the groups that received
context exposure alone. Individual comparisons between non-reinforced
CS presentation and context-exposure groups indicated significant
differences after 2 (t(10) = 3.41) and
3 (t(10) = 6.37) d. Significant
differences were found between the nonexposed control group and rats
that received 1 (t(10) = 2.30), 2 (t(10) = 4.33), or 3 (t(10) = 4.26) d of extinction training.
Experiment 2: dose-response function for the effect of DCS
on extinction
A total of 27 rats were acclimated, tested for baseline startle,
fear-conditioned, and tested for fear-potentiated startle as described
previously. Rats were then divided into four groups of seven animals
each (except for the group receiving 30 mg/kg DCS, for which
n = 6) based on their pre-extinction level of
fear-potentiated startle. After 24 hr, each rat was injected with
either saline or DCS (3.25, 15, or 30 mg/kg, i.p.). After 30 min, rats
received a single session of extinction training. A single extinction
session was used because the results of experiment 1 indicated that
this produced a minimal amount of extinction against which a
facilitatory effect of DCS could be detected. After 24 hr, rats were
tested for fear-potentiated startle without drug injections to evaluate the effect on extinction of the previous drug treatments.
DCS facilitated extinction in a dose-dependent manner (Fig.
2B). ANOVA indicated a
significant dose effect (F(3,23) = 3.02) with a significant linear trend
(F(1,23) = 7.26). Fear-potentiated startle was significantly lower in rats injected with 15 and 30 mg/kg DCS before extinction training
(t(12) = 2.61 and
t(11) = 2.53 for 15 and 30 mg/kg vs
saline, respectively). Because 15 mg/kg DCS produced the maximal
enhancing effect, we used this dose in our subsequent experiments.
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Figure 2.
Dose-response function for the effect of DCS on
extinction. A, Timeline of the behavioral procedures for
experiment 2. B, Percent fear-potentiated startle
measured 24 hr before and 24 hr after a single session of extinction
training in rats injected with saline or DCS (3.25, 15, or 30 mg/kg,
i.p.) 30 min before non-reinforced cue exposure. DCS dose-dependently
facilitated extinction learning. *p < 0.05 versus
saline after extinction.
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Experiment 3: effect of DCS in nonextinguished rats
To test whether the effects of DCS reflected an augmentation of
extinction per se or instead reflected a disruption of fear-potentiated startle independent of extinction (e.g., a delayed effect on the expression of fear-potentiated startle 24 hr after drug
administration), additional rats were tested with and without
extinction training. For this experiment, 28 rats were matched into
four groups of seven animals each based on the pretest. After 24 hr,
each rat was injected with either saline or DCS (15 mg/kg) and returned to its home cage until being placed in the startle chamber 30 min
later. Two groups (one group of saline-injected rats and one group of
DCS-injected rats) underwent extinction training. Two other groups (one
group of saline-injected rats and one group of DCS-injected rats) were
placed into the test chamber but did not receive extinction training.
After 24 hr, all groups were tested for fear-potentiated startle
without drug injections.
Figure 3B shows that
fear-potentiated startle in rats receiving DCS plus extinction training
was significantly lower than in rats that received saline plus
extinction training (t(12) = 3.02).
This replicates the principal finding of experiment 2. The novel
finding here is that fear-potentiated startle in rats that received DCS
without extinction training was comparable with fear-potentiated
startle in rats that received saline without extinction training. Thus,
the effect of DCS noted in experiment 2 and replicated here appears to
reflect a specific influence on extinction and not a more
general effect on fear-potentiated startle measured 24 hr later in the
absence of the drug.
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Figure 3.
Effect of DCS in nonextinguished rats.
A, Timeline of the behavioral procedures for experiment
3. B, Percent fear-potentiated startle measured 24 hr
before and 24 hr after extinction training. Saline or DCS (15 mg/kg,
i.p.) was administered 30 min before a single session of either
extinction training (cue exposure) or context-alone exposure.
Fear-potentiated startle was significantly lower in rats that received
DCS plus extinction training compared with rats that received saline
plus extinction training. Fear-potentiated startle was not appreciably
affected by DCS in rats that did not receive extinction training.
*p < 0.05 versus saline plus extinction
training.
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Experiment 4: effect of the strychnine-insensitive
glycine-recognition site antagonist HA-966 on extinction and on the
facilitation of extinction by DCS
If DCS facilitates extinction by acting as an agonist at
the strychnine-insensitive glycine-recognition site, then the effect of
DCS should be blocked by a strychnine-insensitive glycine site antagonist. To test this, 28 rats were matched into four groups of
seven animals each based on the pre-extinction test. After 24 hr, each
rat was injected with either saline or HA-966 (6 mg/kg) followed 10 min
later by a second injection of either saline or DCS (15 mg/kg). This
dose was chosen based on pilot experiments suggesting that higher doses
of HA-966 alone blocked extinction, thereby complicating
interpretations of interactive DCS/HA-966 effects. Rats received a
single session of extinction training after 30 min and were tested 24 hr later for fear-potentiated startle with no drug injections.
HA-966 completely blocked the enhancement of extinction produced by DCS
but did not in and of itself influence extinction when administered
alone (Fig. 4B).
Replicating findings from experiments 2 and 3, fear-potentiated startle
was significantly lower in rats injected with saline plus DCS compared
with rats injected with saline plus saline
(t(12) = 2.73). This effect was
blocked by HA-966. Fear-potentiated startle in rats injected with
HA-966 plus DCS was not significantly different from fear-potentiated startle in rats injected with saline plus saline but was significantly different from fear-potentiated startle in rats injected with saline
plus DCS (t(12) = 3.35). Overall,
these results suggest that the facilitatory effect of DCS on
extinction is most likely mediated by the NMDA receptor.
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Figure 4.
Effect of the strychnine-insensitive
glycine-recognition site antagonist HA-966 on extinction and on the
facilitation of extinction by DCS. A, Timeline of the
behavioral procedures for experiment 4. B, Percent
fear-potentiated startle measured 24 hr before (pre-extinction test)
and 24 hr after (postextinction test) extinction training. Saline or
HA-966 (6 mg/kg, i.p.) was administered 10 min before a second
injection of saline or DCS, followed 30 min later by a single session
of extinction training. HA-966 completely blocked the effects of DCS
but did not, on its own, noticeably influence extinction at this dose.
*p < 0.05 versus all other groups.
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Experiment 5: effect of pretest DCS and HA-966 administration on
fear-potentiated startle
This experiment evaluated whether the effect of DCS or
HA-966 might be secondary to effects on fear itself or on CS
processing. For example, if DCS increases CS-elicited fear, this might
facilitate extinction by increasing the discrepancy between what the CS
predicts and what actually occurs (Wagner and Rescorla, 1972). If
HA-966 interferes with visual processing, this might block the
extinction produced by non-reinforced exposures to the visual CS. To
evaluate these possibilities, 17 rats (saline, n = 5;
DCS, n = 6; HA-966, n = 6) were
acclimated, tested for baseline startle, and fear-conditioned as
described previously. After 24 hr, rats were injected with saline, DCS
(15 mg/kg), or HA-966 (6 mg/kg). At 30 (for DCS) or 40 (for HA-966) min
after the injections, rats were tested for fear-potentiated startle.
As shown in Figure 5B,
neither DCS nor HA-966 significantly influenced fear-potentiated
startle when injected before testing. Thus, it is unlikely that these
compounds influence extinction by increasing fear or by disrupting CS
processing. In fact, a previous study reported a modest anxiolytic
effect of both compounds on fear-potentiated startle (Anthony and
Nevins, 1993), although at doses higher than those used in the present
study. Anxiolytic effects of DCS have also been reported with the
elevated plus-maze (Karcz-Kubicha et al., 1997) and, at very high
doses, with the Vogel-conflict procedure (Klodzinska and
Chojnacka-Wojcik, 2000).
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Figure 5.
Effect of pretest DCS and HA-966 administration on
fear-potentiated startle. A, Timeline of the behavioral
procedures for experiment 5. B, Percent fear-potentiated
startle measured 24 hr after fear conditioning in rats receiving
pretest injections of saline, DCS (15 mg/kg), or HA-966 (6 mg/kg).
Neither drug had any discernible effect on fear-potentiated
startle.
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Experiment 6: effect of intra-amygdala DCS infusions
on extinction
Previous studies indicate that NMDA receptors in the amygdala play
a critical role in the extinction of conditioned fear (Falls et al.,
1992; Lee and Kim, 1998). It is possible that the effect of
systemically administered DCS reported in the above experiments was
mediated by actions at amygdala NMDA receptors. To determine whether
the effect of systemically administered DCS would be mimicked by
intra-amygdala DCS infusions, 36 rats with intra-amygdala cannulations received fear conditioning, extinction training, and testing for fear-potentiated startle as described previously. Fifteen minutes before being placed into the test chamber for extinction training, rats
were infused with either PBS or DCS (10 µg/side). (Preliminary findings suggested a weak effect of 1 µg/side and a more potent effect of 10 µg/side.) One group of PBS-infused rats and one group of
DCS-infused rats received extinction training. An additional group of
PBS-infused rats and an additional group of DCS-infused rats were not
placed in the test chamber and did not receive extinction training.
Note that this procedure differed from that of experiment 3, in which
control rats received context exposure. Because context exposure
constitutes context extinction and because we were particularly concerned in this experiment that intra-amygdala DCS infusions might be
associated with neurotoxicity, we wanted to ensure that any loss of
fear-potentiated startle after intra-amygdala infusions could
unambiguously be attributed to amygdala damage. If, for example,
control rats that had received context extinction showed a reduction of
CS-elicited fear, it would be unclear whether this was attributable to
a DCS-induced lesion or instead to an unintended effect of context
extinction on fear to the visual CS. Rats in all groups were tested 24 hr later without drug infusions.
Behavioral data for 10 rats were excluded because the placements for
these rats were located outside of the amygdala; as a result
n = 9 for the PBS plus extinction group,
n = 9 for the DCS plus extinction group,
n = 4 for the PBS plus no extinction group, and
n = 4 for the DCS plus no extinction group. Placements for the remaining rats are shown in Figure
6, and the behavioral results are shown
in Figure 7. ANOVA indicated a
significant treatment (DCS vs PBS) × training (extinction vs no
extinction) interaction (F(1,22) = 5.05). Fear-potentiated was significantly lower in rats that received
intra-amygdala DCS infusions before extinction training compared with
rats that received intra-amygdala PBS infusions before extinction
training (t(16) = 2.49) and was also
significantly lower than in rats that received DCS without extinction
training (t(11) = 2.36).
Fear-potentiated startle was not significantly different in rats that
received PBS versus DCS infusions and no extinction training. The
latter result suggests that the effect of DCS in rats that received
extinction training is not attributable to neurotoxic DCS effects
insofar as this would have disrupted fear-potentiated startle in both
groups. In fact, fear-potentiated startle was unusually high in
nonextinguished rats that received DCS infusions. This was primarily
attributable to a single rat with a percent increase score of 465%.
Even with this outlier excluded, fear-potentiated startle was not
significantly different in rats that received PBS versus DCS infusions
and no extinction training. As before, however, fear-potentiated
startle was significantly lower in rats that received intra-amygdala
DCS infusions before extinction training compared with rats that
received intra-amygdala DCS infusions without extinction training
(t(10) = 2.34).
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Figure 6.
Cannula tip placements transcribed onto atlas
plates adapted from Paxinos and Watson (1997). The distance from bregma
is indicated to the left; nuclei within the plane of
section are identified to the right. BL,
Basolateral amygdaloid nucleus; BLV, basolateral
amygdaloid nucleus, ventral part; BM, basomedial
amygdaloid nucleus; CeL, central amygdaloid nucleus,
lateral division; CeM, central amygdaloid nucleus,
medial division; ic, internal capsule;
LA, lateral amygdaloid nucleus.
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Figure 7.
Effect of intra-amygdala DCS infusions.
A, Timeline of the behavioral procedures for experiment
3. B, PBS or D-cycloserine (10 µg/side)
was infused into the amygdala 15 min before extinction training. Other
rats received DCS without extinction training. When tested 24 hr later,
fear-potentiated startle was significantly lower in rats that received
DCS plus extinction training compared with rats that received PBS plus
extinction training. Fear-potentiated startle was not appreciably
affected by DCS in rats that did not receive extinction training. For
the group that received DCS without extinction training, the mean
percent potentiation was calculated with and without data from a single
outlier who had an atypically high percent potentiation score.
*p < 0.05 versus all other groups.
|
|
Effects of DCS and HA-966 on extinction are not attributable
to changes in baseline startle
Figure 8 shows absolute startle
values from experiments 2, 3, 4, and 6 (all experiments showing drug
effects on extinction). In no experiment did we find significant drug
effects on baseline startle when measured in the extinction test 24 hr
later. Moreover, the statistical results from analyses of percent
potentiation scores were mostly comparable with results obtained using
absolute difference scores. Thus, DCS dose-dependently facilitated
extinction (F(1,24) = 6.03; experiment
2). Fear-potentiated startle in the DCS plus extinction group was
significantly different from fear-potentiated startle in the saline
plus extinction group in experiment 3 (t(12) = 3.21), and fear-potentiated
startle was comparable in saline and DCS groups that did not receive
extinction training. The difference between fear-potentiated startle in
rats injected with DCS plus saline injected versus rats injected with
DCS plus HA-966 approached but did not reach significance
(t(12) = 1.86; p = 0.087; experiment 4). Also, fear-potentiated startle was significantly
lower in rats that received intra-amygdala DCS infusions before
extinction training compared with rats that received PBS infusions
(t(16) = 2.24; experiment 6).
View larger version (42K):
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|
Figure 8.
Composite figure showing absolute startle values
for all rats receiving drugs before extinction training. Black
bars indicate baseline startle amplitude on noise-alone trials;
white bars indicate startle amplitude on light-noise
trials. The difference between these two (i.e., fear-potentiated
startle) is indicated by the striped bars. In no case
were significant differences found in baseline startle during the
fear-potentiated startle test 24 hr after drug administration. Moreover
the statistical results were similar when absolute difference scores
(i.e., startle amplitude on light-noise trials minus startle amplitude
on noise-alone trials) rather than percent potentiation scores were
analyzed. *p < 0.05 (except Experiment 4, p = 0.087) versus leftmost bars.
|
|
| |
DISCUSSION |
The primary finding of this study is that DCS, a partial agonist
at the strychnine-insensitive glycine-recognition site on the NMDA
receptor complex, facilitates extinction of conditioned fear after
either systemic injections (experiments 2, 3, and 4) or intra-amygdala
infusions (experiment 6). Because DCS reduced fear-potentiated startle
only in rats that concurrently received extinction training
(experiments 3 and 6), the effects of DCS cannot readily be attributed
either to DCS-related neurotoxicity or to anxiolytic drug actions still
present 24 hr after drug administration (i.e., during testing). The
blockade of the facilitatory influence of DCS on extinction by the
glycine-recognition site antagonist HA-966 strongly suggests that the
effect of DCS was mediated by interactions with the NMDA receptor
(experiment 4). This seems particularly likely insofar as the dose of
HA-966 used did not, on its own, increase fear-potentiated startle.
Thus, the ability of HA-966 to reverse the effects of DCS on extinction
cannot be attributed to a summation of independent facilitatory and
disruptive effects, mediated by actions on different systems. The
failure of either compound to influence fear-potentiated startle when given before testing suggests that their effects on extinction reflect
direct effects on learning processes rather than on CS processing or on
fear itself.
As indicated previously, extinction is generally thought to reflect the
formation of new inhibitory associations, as opposed to the forgetting
of previously formed associations (Pavlov, 1927; Konorski, 1948; Bouton
and Bolles, 1985; Falls and Davis, 1995; Davis et al., 2000; Rescorla,
2001). Consistent with this view, the evidence to date suggests that
the neural mechanisms, neural circuitry, and pharmacology of excitatory
fear conditioning and of conditioned fear extinction are similar. For
example, systemic administration of the mitogen-activated protein
kinase inhibitor PD98059, as well as intra-amygdala PD98059
infusions, disrupt fear conditioning as assessed with both
freezing (Schafe et al., 2000) and shock-motivated avoidance learning
(Walz et al., 1999, 2000), respectively, and intra-amygdala PD98059
infusions also disrupt extinction as assessed with fear-potentiated
startle (Lu et al., 2001). As noted previously, intra-amygdala
infusions of NMDA receptor antagonists block fear conditioning, as
assessed with either fear-potentiated startle or freezing, and also
block extinction in these same paradigms (Miserendino et al., 1990; Falls et al., 1992; Fanselow and Kim, 1994; Maren et al., 1996; Lee and
Kim, 1998; Walker and Davis, 2000).
Although DCS has been shown previously to enhance learning in a variety
of learning paradigms (Monahan et al., 1989; Flood et al., 1992;
Thompson et al., 1992; Quartermain et al., 1994; Pitkanen et al., 1995;
Matsuoka and Aigner, 1996; Pussinen et al., 1997; Land and Riccio,
1999), we are unaware of previous studies showing an enhancement by DCS
of extinction learning. In fact, Port and Seybold (1998) reported that
DCS retarded extinction of an appetitive instrumental response, and
that the NMDA receptor antagonist MK801 enhanced extinction. The latter
finding is in contrast to several other studies showing that NMDA
receptor antagonists disrupt extinction (Falls et al., 1992; Cox and
Westbrook, 1994; Baker and Azorlosa, 1996; Kehoe et al., 1996; Lee and
Kim, 1998). The data used to evaluate extinction in Port and Seybold
(1998) were collected while animals were still under the influence of DCS (i.e., within-session extinction), and it is possible that effects
on performance obscured effects on extinction. It is also possible,
although less likely in our view, that the extinction of instrumental
responses responds differently to NMDA receptor manipulations than does
the extinction of classically conditioned responses.
Recent findings by Tang et al. (1999) are consistent with our results.
In that study, conditioned fear extinction was significantly accelerated in transgenic mice overexpressing the NMDA receptor 2B
subunit (NR2B) compared with wild-type controls. Overexpression was
noted in several forebrain areas, including the amygdala and hippocampus. A facilitatory effect of NR2B overexpression on NMDA receptor-mediated transmission was confirmed in a hippocampal slice
preparation. Specifically, Tang et al. (1999) noted significant increases in the peak amplitude and decay time of NMDA
receptor-mediated currents and an overall increase in charge transfer
through NMDA receptor-associated channels.
Findings implicating amygdala NMDA receptors in both excitatory fear
conditioning and conditioned fear extinction are of considerable theoretical interest. Evidence that the extinction of conditioned fear
memories might be accelerated by NMDA receptor agonists is also of
considerable clinical interest. Many believe that the neural circuitry
mediating adaptive fear is closely related if not identical to the
neural circuitry mediating clinical fear (e.g., in post-traumatic
stress disorder) (Rosen and Schulkin, 1998; Gorman et al., 2000; Bouton
et al., 2001). In clinical populations, a reduced ability to extinguish
conditioned fear associations might contribute to the persistence of
maladaptive fear and may reduce the effectiveness of therapeutic
interventions that rely on extinction processes (e.g., systematic
desensitization, exposure, and imagery therapies). The results reported
here suggest that the effectiveness of these traditional clinical
approaches might be facilitated by pharmacological interventions that
promote extinction. Clinical trials to test this idea are currently
being planned.
| |
FOOTNOTES |
Received Oct. 11, 2001; revised Dec. 18, 2001; accepted Dec. 19, 2001.
This work was supported by National Institute of Mental Health Grants
MH 47840, MH 57250, MH 58922, MH 52384, and MH 59906; by the Woodruff
Foundation; by the Science and Technology Center Program (The
Center for Behavioral Neuroscience) of the National Science Foundation
under Agreement No. IBN-9876754; and by a Pfizer Postdoctoral
Fellowship Award (K.J.R.).
Correspondence should be addressed to David L. Walker, Emory University
School of Medicine, Department of Psychiatry and Behavioral Sciences,
1639 Pierce Drive, Suite 4000, Atlanta, GA 30322. E-mail: dlwalke{at}emory.edu.
| |
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27(1):
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[Abstract]
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S. D. Norrholm, T. Jovanovic, B. Vervliet, K. M. Myers, M. Davis, B. O. Rothbaum, and E. J. Duncan
Conditioned fear extinction and reinstatement in a human fear-potentiated startle paradigm
Learn. Mem.,
November 1, 2006;
13(6):
681 - 685.
[Abstract]
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J. L. C. Lee, A. L. Milton, and B. J. Everitt
Reconsolidation and Extinction of Conditioned Fear: Inhibition and Potentiation
J. Neurosci.,
September 27, 2006;
26(39):
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[Abstract]
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R. Kalisch, E. Korenfeld, K. E. Stephan, N. Weiskopf, B. Seymour, and R. J. Dolan
Context-dependent human extinction memory is mediated by a ventromedial prefrontal and hippocampal network.
J. Neurosci.,
September 13, 2006;
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[Abstract]
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S.-C. Mao, Y.-H. Hsiao, and P.-W. Gean
Extinction Training in Conjunction with a Partial Agonist of the Glycine Site on the NMDA Receptor Erases Memory Trace.
J. Neurosci.,
August 30, 2006;
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[Abstract]
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K. Kamprath, G. Marsicano, J. Tang, K. Monory, T. Bisogno, V. D. Marzo, B. Lutz, and C. T. Wotjak
Cannabinoid CB1 receptor mediates fear extinction via habituation-like processes.
J. Neurosci.,
June 21, 2006;
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[Abstract]
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Z. Callaerts-Vegh, T. Beckers, S. M. Ball, F. Baeyens, P. F. Callaerts, J. F. Cryan, E. Molnar, and R. D'Hooge
Concomitant deficits in working memory and fear extinction are functionally dissociated from reduced anxiety in metabotropic glutamate receptor 7-deficient mice.
J. Neurosci.,
June 14, 2006;
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[Abstract]
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M. W. Otto, J. A. J. Smits, and H. E. Reese
Combined Psychotherapy and Pharmacotherapy for Mood and Anxiety Disorders in Adults: Review and Analysis
Focus,
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204.
[Abstract]
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S. G. Hofmann, A. E. Meuret, J. A. J. Smits, N. M. Simon, M. H. Pollack, K. Eisenmenger, M. Shiekh, and M. W. Otto
Augmentation of exposure therapy with d-cycloserine for social anxiety disorder.
Arch Gen Psychiatry,
March 1, 2006;
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[Abstract]
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K. M. Myers, K. J. Ressler, and M. Davis
Different mechanisms of fear extinction dependent on length of time since fear acquisition.
Learn. Mem.,
March 1, 2006;
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E. Likhtik, J. G. Pelletier, R. Paz, and D. Pare
Prefrontal Control of the Amygdala
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August 10, 2005;
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R. Ponnusamy, H. A. Nissim, and M. Barad
Systemic blockade of D2-like dopamine receptors facilitates extinction of conditioned fear in mice
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M. Ouyang and S. A. Thomas
From The Cover: A requirement for memory retrieval during and after long-term extinction learning
PNAS,
June 28, 2005;
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[Abstract]
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C. K. Cain, B. P. Godsil, S. Jami, and M. Barad
The L-type calcium channel blocker nifedipine impairs extinction, but not reduced contingency effects, in mice
Learn. Mem.,
May 1, 2005;
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[Abstract]
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G. C. Bird, L. L. Lash, J. S. Han, X. Zou, W. D. Willis, and V. Neugebauer
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May 1, 2005;
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C.-H. Lin, C.-C. Lee, Y.-C. Huang, S.-J. Wang, and P.-W. Gean
Activation of group II metabotropic glutamate receptors induces depotentiation in amygdala slices and reduces fear-potentiated startle in rats
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March 1, 2005;
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[Abstract]
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S. Maren
Building and Burying Fear Memories in the Brain
Neuroscientist,
February 1, 2005;
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[Abstract]
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K. J. Ressler, B. O. Rothbaum, L. Tannenbaum, P. Anderson, K. Graap, E. Zimand, L. Hodges, and M. Davis
Cognitive Enhancers as Adjuncts to Psychotherapy: Use of D-Cycloserine in Phobic Individuals to Facilitate Extinction of Fear
Arch Gen Psychiatry,
November 1, 2004;
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[Abstract]
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R. Richardson, L. Ledgerwood, and J. Cranney
Facilitation of Fear Extinction by D-Cycloserine: Theoretical and Clinical Implications
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September 1, 2004;
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F. Sotres-Bayon, D. E.A. Bush, and J. E. LeDoux
Emotional Perseveration: An Update on Prefrontal-Amygdala Interactions in Fear Extinction
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September 1, 2004;
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J. P. Schroeder and M. G. Packard
Facilitation of Memory for Extinction of Drug-Induced Conditioned Reward: Role of Amygdala and Acetylcholine
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September 1, 2004;
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[Abstract]
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G. P. McNally, M. Pigg, and G. Weidemann
Opioid Receptors in the Midbrain Periaqueductal Gray Regulate Extinction of Pavlovian Fear Conditioning
J. Neurosci.,
August 4, 2004;
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D. Pare, G. J. Quirk, and J. E. Ledoux
New Vistas on Amygdala Networks in Conditioned Fear
J Neurophysiol,
July 1, 2004;
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[Abstract]
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K. M. Myers and M. Davis
AX+, BX- Discrimination Learning in the Fear-Potentiated Startle Paradigm: Possible Relevance to Inhibitory Fear Learning in Extinction
Learn. Mem.,
July 1, 2004;
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464 - 475.
[Abstract]
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M. A. Rubin, D. B. Berlese, J. A. Stiegemeier, M. A. Volkweis, D. M. Oliveira, T. L. B. dos Santos, A. C. Fenili, and C. F. Mello
Intra-Amygdala Administration of Polyamines Modulates Fear Conditioning in Rats
J. Neurosci.,
March 3, 2004;
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G. J. Quirk
Learning Not to Fear, Faster
Learn. Mem.,
March 1, 2004;
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J. A. Hobin, K. A. Goosens, and S. Maren
Context-Dependent Neuronal Activity in the Lateral Amygdala Represents Fear Memories after Extinction
J. Neurosci.,
September 10, 2003;
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[Abstract]
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C.-H. Lin, S.-H. Yeh, T.-H. Leu, W.-C. Chang, S.-T. Wang, and P.-W. Gean
Identification of Calcineurin as a Key Signal in the Extinction of Fear Memory
J. Neurosci.,
March 1, 2003;
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[Abstract]
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M. Cammarota, L. R. M. Bevilaqua, D. Kerr, J. H. Medina, and I. Izquierdo
Inhibition of mRNA and Protein Synthesis in the CA1 Region of the Dorsal Hippocampus Blocks Reinstallment of an Extinguished Conditioned Fear Response
J. Neurosci.,
February 1, 2003;
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737 - 741.
[Abstract]
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R. Garcia
Postextinction of Conditioned Fear: Between Two CS-Related Memories
Learn. Mem.,
November 1, 2002;
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361 - 363.
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G. J. Quirk
Memory for Extinction of Conditioned Fear Is Long-lasting and Persists Following Spontaneous Recovery
Learn. Mem.,
November 1, 2002;
9(6):
402 - 407.
[Abstract]
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[PDF]
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TOP
ABSTRACT
INTRODUCTION
