Center for Neural Science · New York University

Society for Neuroscience Meetings

 

2000 ABSTRACTS

DIFFERENT INDUCTION PROTOCOLS RECRUIT NMDA AND L-TYPE CALCIUM CHANNEL-DEPENDENT LTP IN THE LATERAL AMYGDALA (LA): CORRELATION WITH FEAR MEMORY.

E.P. Bauer,* G.E. Schafe and J.E. LeDoux. Center for Neural Science, NYU, NY, NY, 10003.

LTP at sensory input synapses to the LA is a candidate mechanism for memory storage during fear learning. NMDA receptors may be required for LTP at cortical synapses to LA (Huang and Kandel, 1998), and are necessary for acquisition of fear conditioning (Gewirtz and Davis, 1997). This latter finding is confounded, however, by their contribution to baseline synaptic transmission (Weisskopf and LeDoux, 1999) and effects on fear expression (Maren et al., 1996). We have recently shown that calcium influx through L-type voltage-gated calcium channels (VGCCs) is necessary for LTP at thalamic input synapses to LA in vitro (Weisskopf et al., 1999). In the present study, we induced LTP in vitro by pairing trains of presynaptic stimulation with depolarizations of the postsynaptic cell to open dendritic VGCCs (30Hz, 10 stimuli, paired with 1nA, 5 ms depolarizations, given 15 times) (Markram et al., 1997). The LTP induced with this protocol was blocked by bath application of the VGCC-blocker Verapamil (50mM), but was insensitive to D-APV (50mM). Verapamil had no effect on baseline synaptic transmission. We next induced LTP using a 30Hz tetanus (100 stimuli, given twice). Here, LTP was blocked by D-APV, but was unaffected by Verapamil. Since LTP induction via co-occurrence of activity in the pre- and post-synaptic cell is believed to be more consistent with the mechanisms of plasticity underlying natural learning, we next examined the role of VGCCs in the acquisition of fear conditioning. Rats were given bilateral infusions of Verapamil (4 mg/side) or vehicle 30 min prior to Pavlovian fear conditioning. Consistent with the LTP findings, results showed that fear memory was impaired 24 hr later. Further, infusions of Verapamil prior to fear expression had little effect. Collectively, findings suggest that while NMDA receptors may be involved in both plasticity and routine transmission, VGCCs play a selective role in synaptic plasticity and memory in LA. Supported by an NSF Graduate Fellowship and NIMH grants: 46516, 38774, 00956.

SINGLE-UNIT RECORDING OF AUDITORY AND NOCICEPTIVE RESPONSES FROM LATERAL AMYGDALA (LA) NEURONS DURING AUDITORY FEAR CONDITIONING IN FREELY BEHAVING RATS.

H.T. Blair* and J.E. LeDoux. Center for Neural Science, New York University, New York, NY 10003.

Convergent auditory and nociceptive inputs to LA may drive Hebbian synaptic plasticity that underlies memory storage during auditory fear conditioning (LeDoux 1995, Ann Rev Psych 46:209-35). Supporting this theory, it has been shown that LA neurons respond to both auditory and nociceptive stimuli in anesthetized rats (Muramoto et al. 1993, Neurosci 52:621-36; Romanski et al. 1993, Beh Neurosci 107:444-50), and that fear conditioning to a tone CS potentiates auditory evoked responses in LA (Quirk et al. 1995, Neuron 15:1029-39; Rogan et al. 1997, Nature 390:604-7). Here, for the first time, we recorded responses of LA neurons to auditory and nociceptive stimuli during auditory fear conditioning in freely moving rats. Auditory fear conditioning was conducted in a chamber where hungry rats searched for small food pellets dropped randomly by an overhead dispenser. The CS was a train of 20 white noise pips (80 dB), each 250 ms in duration, presented at a rate of 1 Hz (total CS duration=19.25 s). The US, which began 300 ms after the last CS pip, was a train of 8 shock pulses (2.5 mA), each 2 ms in duration, delivered to the eyelid at a rate of 5 Hz (total US duration=1.4 s). Training consisted of 6 habituation (CS alone) trials, 6 sensitization (unpaired CS/US) trials, 16 acquisition (paired CS-US) trials, and 16 extinction (CS alone) trials. Freezing behavior was measured to verify that conditioning was successful in all rats. Neurons (n=25) were recorded from LA and the amygdalostriatal transition area in 5 rats; 5 cells responded to the CS alone, 3 responded to the US alone, 7 responded to both CS and US, and 10 had no clear firing correlate. Of the 12 CS responsive cells, 3 increased their CS response during acquisition, and all 3 were shock responsive; 2 cells decreased their CS response during acquisition, and neither was shock responsive. These preliminary findings are consistent with the theory that convergent auditory and nociceptive inputs may support Hebbian learning in LA. Supported by MH12341 to H.T.B., and MH38774, MH46516, & MH00956 to J.E.L.

IMMUNOCYTOCHEMICAL LOCALIZATION OF SEROTONIN 1A, 2A, 2C, 3, AND 7 RECEPTOR SUBTYPES IN THE LATERAL AMYGDALA (LA) OF THE RAT.

N.S. Burghardt*, C. R. Farb, G.M. Sullivan and J.E. LeDoux. Center for Neural Science, NYU, NY, NY, 10003.

Serotonin (5-HT) has been shown to modulate the processing of sensory input to the LA (Stutzmann et al., 1998; Rainnie, 1999). To gain a better understanding of how 5-HT mediates its effects, we used antisera directed against the 5-HT1A, 2A, 2C, 3 and 7 receptor subtypes and evaluated their regional, cellular and subcellular localizations within the LA. Each antiserum produced unique distributions of perikaryal and neuropilar staining. Using light microscopy, 5-HT1A-immunoreactivity (-ir) was seen in the parikarya and processes of many cells throughout the LA. The morphological features of these cells are characteristic of excitatory cells. 5-HT2A-ir appeared as diffuse neuropil staining in the dorsal and lateral regions of the LA. Only a few lightly stained cell bodies with morphological characteristics of interneurons were observed. 5-HT2C-ir was seen throughout the LA as a dense plexus of labeled processes, with no observable cell body staining. 5-HT3-ir prominently stained many axons and punctate processes. Some cell bodies with morphological features of inhibitory interneurons were also labeled. This finding is consistent with our dual label experiments, which indicate that the 5-HT3 receptor is expressed in GABAergic cells in LA. The 5-HT7 immunolabel was present in many cell bodies and processes, with the most robust staining in the dorsal LA. More detailed analyses using electron microscopy revealed that the immunoreaction product of all receptor subtypes was seen in somata, dendrites and dendritic spines receiving asymmetric (excitatory) contacts, and glia. Often, the dendritic immunolabel was also seen away from the synaptic site. In addition to these sites, 5-HT3 receptor antiserum frequently labeled presynaptic axon terminals. The presence of 5-HT receptor immunolabel in a heterogeneous population of cells, on dendrites receiving asymmetric synapses, on glia, and on presynaptic axon terminals, suggests serotonergic modulation of neurotransmission in the LA is complex. Supported by NIMH grants: 58911 and 00956.

GABAERGIC INHIBITION IN THE FEAR CONDITIONING CIRCUIT OF THE LATERAL AMYGDALA IS POTENTIATED BY DOPAMINE D1 AGONISTS.

L.R.Johnson *, J. E. LeDoux. CNS, New York University, New York, NY. 10003.

Auditory fear conditioning is dependent on auditory signaling from the medial geniculate (MGm) and the auditory cortex (TE3) to principal neurons of the lateral amygdala (LA). Local circuit GABAergic interneurons are known to inhibit LA principal neurons via fast and slow IPSP's. Stimulation of MGm and TE3 produces excitatory post-synaptic potentials in both LA principal and interneurons, followed by inhibitory post-synaptic potentials. Manipulations of D1 receptors in the lateral and basal amygdala modulate the retrieval of learned association between an auditory CS and foot shock. Here we examined the effects of D1 agonists on GABAergic IPSP's evoked by stimulation of MGm and TE3 afferents in vitro. Whole cell patch recordings were made from principal neurons of the LA, at room temperature, in coronal brain slices using standard methods. Stimulating electrodes were placed on the fiber tracts medial to the LA and at the external capsule/layer VI border dorsal to the LA to activate (0.1-0.2mA) MGm and TE3 afferents respectively. Neurons were held at -55.0 mV by positive current injection to measure the amplitude of the fast IPSP. Changes in input resistance and membrane potential were measured in the absence of current injection. Stimulation of MGm or TE3 afferents produced EPSP's in the majority of principal neurons and in some an EPSP/IPSP sequence. Stimulation of MGm afferents produced IPSP's with amplitudes of -2.30 0.53 mV and stimulation of TE3 afferents produced IPSP's with amplitudes of -1.98 1.26 mV. Bath application of 20mM SKF38393 increased IPSP amplitudes to -5.94 1.62 mV (MGm, n=3) and -5.46 0.31 mV (TE3, n=3). Maximal effect occurred <10mins. A small increase in resting membrane potential and decrease in input resistance were observed. These data suggest that DA modulates both the auditory thalamic and auditory cortical inputs to the LA fear conditioning circuit via local GABAergic circuits. Supported by NIMH Grants 00956, 46516, and 58911.

FEAR CONDITIONING INDUCE TYROSINE PHOSPHORYLATION OF A 60 KDA PROTEIN IN RAT THALAMUS.

R. Lamprecht and J.E. LeDoux. Center for Neural Science, New York University, New York, NY 10003.

We are studying molecular events in amygdala, and interconnected brain regions, underlying long-term fear-conditioning memory. In the present study we have monitored the alteration in phosphorylation of proteins extracted from amygdala and auditory thalamus following different stages of fear conditioning. Adult rats were habituated to the conditioning chamber. In the next day the animals were divided into four groups: 1) Control group: exposed to conditioning chamber; 2) CS group: exposed to tone (5kHz 75dB for 30 sec); 3) US group: received mild footshock (1.5 mA for 1 sec); 4) Fear conditioned group: 30 sec tone (5kHz 75 dB for 30 sec) terminated with a footshock (1.5mA for 1 sec). The brains were removed at various time points following the behavioral manipulations, frozen rapidly, and the amygdala and the thalamus (which contains the auditory thalamus) were dissected. The brain tissue was homogenized and subjected to SDS-PAGE followed by Western blots with anti-phosphoserine, anti-phosphothreonine or anti-phosphotyrosine antibodies. Tyrosine phosphorylation of a ~60kDa protein in the thalamus was significantly increased 30 minutes following fear conditioning training when compared to the control, CS and US groups (p<0.0003; p<0.008; p<0.005 respectively; n=8 for control group, n=8 for the CS group, n=9 for the US group and n=9 for fear conditioning group). Tyrosine phosphorylation of the 60 kDa protein was also significantly increased 60 minutes (n=6 p<0.05), but not 10 minutes, 6 hrs and 24 hours, following fear conditioning when compared to the control group. Tyrosine phosphorylation of the 60 kDa in the CS and US groups was not significantly increased when compared to the control group. Fear conditioning experience can thus increase tyrosine phosphorylation of a 60 kDa protein in the auditory thalamus.

SINGLE-UNIT RECORDING OF HIPPOCAMPAL CELLS DURING AUDITORY FEAR CONDITIONING.

M.A.P. Moita, H.T. Blair, G.M. Sullivan*, and J.E. LeDoux. Center for Neural Science, New York University, New York, NY 10003.

During fear conditioning, the hippocampus may construct a representation of the environment where training takes place (Kim & Fanselow 1992, Science 256: 675-677; Phillips & LeDoux 1992, Behav Neurosci 106: 274-285). The hippocampus is also involved in trace fear conditioning to an auditory CS (McEchron et al. 1998, Hippocampus 8:638-46). Here we studied hippocampal involvement in fear learning by recording hippocampal neurons during auditory fear conditioning. Hungry rats foraged randomly for small food pellets in two familiar chambers: box A, a neutral chamber where no stimuli were presented, and box B, where auditory fear conditioning occurred using the same CS and US as in the accompanying abstract by Blair & LeDoux. Conditioning in box B occurred in three parts: habituation (HAB = 9 trials, CS alone), acquisition (ACQ = 16 CS-US pairings), and extinction (EXT = 16 trials, CS alone). Baseline activity in box B was recorded before/after each conditioning session, and in box A before HAB, after ACQ, and after EXT. In 5 rats we recorded 51 hippocampal neurons, of which 11 were theta cells and 40 were complex spike (CSP) cells. 38/40 CSP cells had place fields in box B; of these, 18 were stable throughout the experiment, and 15 "remapped" their fields during conditioning, despite remaining stable in box A. This suggests that conditioning may induce some hippocampal cells to re-represent the training environment. 27/51 cells responded to the CS (19/38 CSP cells; 8/11 theta cells), of which 10 also responded to the US (3/19 CSP cells; 7/8 theta cells). Importantly, 26/27 cells that responded to the CS were not CS responsive during HAB, but only during ACQ/EXT. This suggests that hippocampal cells acquire conditioned responses to auditory CSs, in agreement with previous reports (Berger & Thompson 1982, Behav Brain Res 4:63-76). These preliminary results suggest that fear conditioning induces changes in spatial and non-spatial firing properties of hippocampal neurons, which may be related to the role of the hippocampus in some fear learning paradigms. Supported by PRAXIS XX1 (Portugal) to MAPM, MH12341 to HTB, and MH38774, MH46516, & MH00956 to JEL.

Consolidated Fear Memories Become Labile During Retrieval And Require Protein Synthesis In The Amygdala For Reconsolidation

K Nader, GE Schafe* & JE LeDoux, Center for Neural Science, NYU, NY, NY, 10003.

"New" memories are initially labile and sensitive to disruption before being consolidated into stable long-term memories. A wealth of data indicates that this consolidation process involves the synthesis of new proteins in neurons. The lateral and basal nuclei of the amygdala (LBA) are believed to be a site of memory storage in fear learning. Intra-LBA infusion of the protein synthesis blocker anisomycin (ANISO) shortly after training prevents consolidation of this memory. We retested the idea that when consolidated memories are reactivated, they return to a labile state. Rats were trained with 1 CS-US pairing. The following day, 1 CS presentation was given followed immediately by intra-LBA infusions of ANISO. The next day, ANISO infused rats showed greatly impaired freezing compared to controls. This result was obtained regardless of whether reactivation occurred 1 or 14 days after conditioning. The behavioral deficit was not due to ANISO-induced amygdala damage or late waves of protein synthesis because if memory reactivation was omitted prior to ANISO infusions, then freezing was normal the next day. Consistent with a time limited role for protein synthesis production in consolidation, delay of the infusion until 6 hours after memory reactivation produced no amnesia. Lastly, animals demonstrated intact freezing 4 hr but impaired freezing 24 hr after reactivation and ANISO. This pattern of results is similar to the effects of protein synthesis on consolidation: intact short-term memory and impaired long-term memory. These data demonstrate that consolidated fear memories, when reactivated, return to a labile state that requires de novo protein synthesis to be reconsolidated. These findings are not predicted by traditional theories of memory consolidation. Supported by Grant MH00956, MH46516, MH38774. We'd like to acknowledge the WM Keck Foundation.

DIFFERENTIAL EXPRESSION OF THE N-METHYL-D-ASPARTATE RECEPTOR NR2B SUBUNIT IN THE LATERAL NUCLEUS DIVISIONS OF THE RAT AMYGDALA.

S.M. Rodrigues*; J.E. LeDoux*; J.H. Morrison** . *Center for Neural Science, New York University, New York, NY, USA . **Neurobiology of Aging Laboratories, Mount Sinai School of Medicine, New York, NY, USA

Emotionally relevant sensory information about the external world reaches the amygdala primarily be way of its lateral nucleus (LA). More specifically, anatomical and physiological evidence suggests that distinct divisions of the LA play separate functional roles in processing the information involved in fear conditioning to auditory stimuli. Previous studies indicate that NMDA receptors are key for synaptic transmission in the LA and possibly in fear conditioning. Moreover, the overexpression of the NR2B subunit of NMDA receptors in transgenic animals has been shown to elicit stronger fear responses as compared to those of wild-type animals. The present study utilized immunohistochemical methods to analyze the distribution of the NR2B subunit of the NMDA receptor in the LA of the rat amygdala. The resultant staining revealed a higher density of the NR2B subunit in the LA's lateral portion in comparison to that found in the medial portion. In addition, the dorsolateral division (Ld1) displayed a higher abundance of the NR2B subunit in relation to the levels detected in both the ventrolateral and medial divisions of the LA. Furthermore, co-localization analysis of the NR1 and NR2B NMDA receptor subunits by immunofluorescence revealed that virtually all functional NMDA receptors in Ld1 express the NR2B subunit. The NR1-NR2B complex contributes to prolonged excitatory postsynaptic potentials and thus increases the time window for detecting synaptic coincidence. Ld1 receives the earliest information about auditory stimuli and it is also the site of auditory and somatosensory convergence. These findings, which display a prominent expression of the NR2B subunit in the Ld1 when contrasted to other divisions of the LA, help explain how this unit is primed to play a role in the transmission of sensory information during the process of emotional learning. Supported by: MH00956, MH46516 and MH58911

BLOCKADE OF ERK/MAP KINASE ACTIVATION IN THE AMYGDALA IMPAIRS MEMORY CONSOLIDATION OF PAVLOVIAN FEAR CONDITIONING.
*G.E. Schafe,**C.M. Atkins*, 2J.D. Sweatt & *J.E. LeDoux. *Center for Neural Science, New York University, NY, NY 10003 and **Division of Neuroscience, Baylor College of Medicine, Houston, TX, 77030.

Recent experiments in our lab have shown that ERK/MAP kinase is transiently activated in the lateral and basal amygdala (LBA) following Pavlovian fear conditioning, a result which is consistent with studies that have shown impairments of fear memory consolidation following either systemic (Atkins et al, 1998) or intracerebroventricular (Schafe et al, 1999) administration of ERK/MAPK inhibitors. To determine whether ERK/MAPK activation in the LBA is obligatory for fear memory consolidation, rats in the present experiments were given localized infusions of U0126, an inhibitor of MEK, an upstream regulator of ERK/MAPK. Rats were infused with different doses of U0126 (0.1 or 1.0 mg/side; 0.5 ml) or 50% DMSO vehicle into LBA 30 min prior to single or multiple-trial auditory Pavlovian fear conditioning. Western blot experiments indicated that administration of U0126 dose-dependently impaired ERK/MAPK activation in the LBA. Accordingly, behavioral experiments showed that U0126 dose-dependently impaired long-term memory (LTM) of fear conditioning assessed 24 hrs after training. However, short-term memory (STM), assessed at 1 hr, was intact. Additional controls showed that the LTM impairment was likely due to impaired memory consolidation processes rather than to sensory or performance deficits. Finally, a time-course analysis of the effects of U0126 revealed that fear memory was intact 1 and 3 hrs following conditioning, but significantly impaired 6 and 24 hrs later. Collectively, results suggest that memory consolidation of Pavlovian fear conditioning is dependent on a MAPK-dependent mechanism in the LBA. Supported by: MH11902, MIMH 57014, MH38774, & MH46516.

UNCTIONAL INACTIVATION OF AMYGDALA NUCLEI DURING ACQUISITION OF PAVLOVIAN FEAR CONDITIONING.

A.E. Wilensky*, G.E. Schafe and J.E. LeDoux. Center for Neural Science, New York University, NY, NY, 10003.

Anatomical, behavioral and physiological evidence have all implicated the amygdala in the acquisition of Pavlovian fear conditioning. It is generally accepted that input from the conditioned (CS) and unconditioned (US) stimuli converge in the lateral nucleus (LA) where alterations in synaptic transmission are thought to encode key aspects of the learning. During retrieval, this information is thought to be transmitted to the central nucleus (CE), which controls the expression of conditioned fear responses. Studies of CE function have mostly relied on permanent lesions of the nucleus, which confound effects on learning with effects on expression. We examined the effect of functional inactivation of different nuclei of the amygdala during Pavlovian conditioning. Bilateral injections of muscimol (0.18 nmol/side) or ACSF (0.2 ml) were made into LA or CE before Pavlovian conditioning consisting of two tone-footshock pairings. Findings indicated that infusions aimed at either nucleus impaired acquisition of conditioned fear relative to vehicle controls. All groups showed high levels of postshock freezing after the second tone, suggesting that the differences in fear acquisition did not result from a lack of sensory input from functional inactivation. Examination of focal points of the injections and further behavioral data examining the spread of muscimol into adjacent nuclei will clarify the role of CE vs. LA in the acquisition of Pavlovian conditioning. Supported by NIMH grants: MH46516, MH00956, & MH38774.

TP. Amorapanth, K. Nader, & J.E. LeDoux(1998) The Fear Arousing And Motivational Properties Of Aversive Stimuli Are Mediated By Different Systems Within The Amygdala.

Aversive, fear arousing stimuli elicit automatic defensive reactions (like freezing, autonomic and endocrine responses), and can also reinforce the acquisition of a new response that leads to the termination, escape from or the avoidance of the stimulus. We tested whether the mechanisms mediating the conditioned defensive behaviors and aversive properties elicited by emotional stimuli are isomorphic or dissociable. In order to assay for the conditioned aversive properties of fear evoking stimuli, we used an acquisition of a new response paradigm called Escape From Fear (EFF). Phase 1 entailed giving rats 5 pairings of a conditioned stimulus (CS; 20 sec., 10 kHz, 75 dB) which co-terminated with a 0.5 sec. (0.5 mA) footshock for 2 days. In Phase 2, rats were placed into one of two identical compartments of an avoidance box. The guillotine door separating the two compartments was raised and 10 sec later the CS was presented. Moving to the alternate environment terminated the CS, thus removing the aversive properties elicited by the CS and reinforcing the operant of moving to the alternate environment. Ten trials a day were given for 2 days. Electrolytic lesions were made in the central or basal (sparing the lateral) nucleus of the amygdala prior to fear conditioning. Central nucleus lesions blocked freezing behavior, but had no effect on the acquisition of EFF. Lesions of the basal amygdala produced the exact opposite pattern of results. Basal amygdala lesions blocked the acquisition of EFF, but had no effect on freezing behavior. These results double dissociate the mechanisms mediating the conditioned aversive properties of fear from the mechanisms mediating the behavioral properties of fear. We are presently testing whether these two processes are the output of a single or distinct learning systems. Supported by Grant #R37-MH38774.

 

N.N. Doron & J.E. LeDoux(1998) Topographic Organization of Thalamo-Amygdala Projections: A Retrograde Tract Tracing Study in the Rat.

Projections to the amygdala from the auditory thalamus have been implicated in the associative conditioning of fear responses to acoustic stimuli. Thalamo-amygdala auditory projections enter the amygdala via the lateral nucleus (LA). It is well documented that these projections originate in the medial division (MGm) of the medial geniculate nucleus (MGN), the posterior intralaminar nucleus (PIN), and the suprageniculate nucleus (Sg). It is not known, however, whether these thalamic projections terminate in a topographical fashion within the LA. We therefore used seven different methods of retrograde tract tracing to determine whether the termination of thalamo-amygdala fibers has a topographic organization within the LA: (1) CTb-conjugated to gold, visualized using silver-intensification; (2) cholera toxin B subunit (CTb), visualized by either immunocytochemistry using fluorescein or immunohistochemical ABC technique; (3) rhodamine B; (4) fast blue; (5) diamidino yellow; (6) bisbenzimide; and (7) nuclear yellow. These tracers were injected locally to various locations within the LA and the distribution of the retrogradely labeled cells throughout the thalamus were analyzed. Two major findings were obtained. First, the thalamo-amygdala projections are topographically organized. In general, rostral-caudal distinctions in the thalamus are maintained in the LA. Furthermore, the density of cells which give rise to thalamo-amygdala projections varies within each thalamic nucleus along the rostro-caudal axis. Second, in addition to the known projections to the LA originating from PIN, MGN, and Sg, we also found substantial projections from the dorsal portion of the MGN (MGd). These findings suggest that some of the functional segregation in the thalamus may be preserved in the LA, and that the role of the MGd in thalamo-amygdala transmission should be reconsidered. Supported by R37-MH38774.

 

X.F. Li, M.G. Weisskopf, and J.E. LeDoux.(1998)  INHIBITORY LTP IN THE LATERAL AMYGDALA INDUCED BY TETANIZATION OF THE THALAMO-AMYGDALA PATHWAY.

Most work on long-term potentiation (LTP) has involved studies in brain slices. In the present study, we used in vivo intracellular recordings to examine LTP in the pathway connecting the auditory thalamus (MGm/PIN) with the lateral amygdala (LA). Rats were anesthetized with urethane (1.6 g/kg, ip) and pyramidal cells in LA penetrated by stereotaxic procedures. Stimulation of MGm/PIN elicited a characteristic EPSP/IPSP sequence from these neurons (n=7). Most (6 of 7) cells had a fast-IPSP (<50ms) and 5 of 7 also had a slow-IPSP (100-200ms). Following tetanization (100 Hz for 4 sec, or 300 Hz for 100 ms given 3 or 10 times at 1 sec intervals), a potentiated fast-IPSP was seen in all 7 cells, and the slow-IPSPs were potentiated in the 5 cells in which they were present. Potentiation of the fast-IPSPs appeared to decline over 30 min, while potentiation of the slow-IPSPs persisted throughout the experiments (up to 60 min). Changes in the EPSPs were difficult to assess, and may have been masked by the potentiation of the fast IPSPs. These results demonstrate that inhibitory circuits in LA undergo a form of activity-dependent plasticity comparable to so-called long-term potentiation (LTP) at excitatory synapses. During fear learning, the balance of excitation and inhibition within amygdala networks may be changed by excitatory and/or inhibitory LTP. Supported by NIMH grants: R01-MH 46516, R37-MH38774 and 1K02-MH00956.

 

K. Nader & J.E. LeDoux(1998)  The Mesoamygdala Dopaminergic Pathway Modulates Emotional Memories.

We have previously demonstrated that systemic manipulations of the dopaminergic system modulates the association between an auditory conditioned stimulus (CS) and footshock unconditioned stimulus (US). The results implicated an action on post-synaptic D1 receptors as the mechanism modulating the association. Given the role of the lateral and basal amygdala (LB) in the acquisition and expression of fear conditioning, the dopaminergic projection from the ventral tegmental area (VTA) to the LB and the presence therein of D1 receptors, we tested whether manipulations of this pathway was capable of modulating fear. Rats underwent cannulation of either the VTA or LB and subsequently were trained using a second order fear conditioning paradigm. Phase 1 entailed 2 pairings of an auditory CS1 which co-terminated with a 0.5 sec., 0.5 mA footshock. In Phase 2, rats received microinfusions, and 15 min. later, 3 pairings of a second distinct auditory stimulus (CS2) with CS1. In Phase 3, rats were tested drug free for freezing behavior elicited by CS2. We predicted that either activation of pre-synaptic D2 auto-receptors in the VTA or inactivation of post-synaptic D1 receptors in the LB will inhibit the CS1-US association, and in turn, decrease freezing to CS2. In addition, we predicted that an increase in D1 receptor activation in the LB will have no effect on the acquisition of second order conditioning because no inhibition of the CS1-US association exists to be reversed. Infusions of either the D2 agonist quinpirole into the VTA or the D1 antagonist SCH 23390 into the LB caused a dose dependent decrease in freezing to CS2 on test day. The identical infusions dorsal to the VTA and LB had no effect on acquisition of second order conditioning. This demonstrates that the behavioral effects of quinpirole and SCH 23390 were due to an action within the VTA and LB, respectively. Infusions of the D1 agonist SKF 38393 into the LB caused a nonsignificant increase in freezing to CS2. This pattern of results is consistent with the hypothesis that the VTA-LB dopaminergic projection can modulate the association between a CS and footshock US. Supported by Grant #R37-MH38774.

 

G.E. Schafe, G.M. Sullivan, and J.E. LeDoux.(1998) PHOSPHORYLATION OF cAMP RESPONSE ELEMENT BINDING PROTEIN IN THE RAT AMYGDALA FOLLOWING PAVLOVIAN FEAR CONDITIONING.

The cAMP response element binding protein (CREB) is a constituitively expressed nuclear protein that has been hypothesized, following phosphorylation of its Ser133 by synaptic stimulation, to induce the transcription of genes containing cAMP response element (CRE) promoter regions. CRE-mediated genes, in turn, encode proteins thought to be necessary for the long-term structural changes underlying memory formation. The present studies utilized immunohistochemical methods to examine the expression of phosphorylated CREB (pCREB) in the rat amygdala, a region that neuroanatomical, pharmacological, and physiological studies have shown to be essential for the establishment of Pavlovian fear conditioning. Rats were exposed to five tone (80dB, 30 sec)-shock (0.5mA, 0.5 sec) pairings over the course of 15 min (ITI=90-120 sec) and were sacrificed 15 min later. Results indicated that exposure to fear conditioning trials led to increases in pCREB expression in the lateral (LA) and central (CE) nuclei of amygdala relative to non-stimulated controls. However, in a separate experiment exposure to tone alone or shock alone conditions also led to increases in pCREB. Current experiments are utilizing Western blot analysis to accurately quantify levels of pCREB in the LA and other regions involved in fear conditioning

 

Grace E. Stutzmann and Joseph E. LeDoux.(1998)   GABAergic Antagonists Block the Inhibitory Effects of Serotonin in the Lateral Amygdala: A Mechanism for Modulation of Sensory Inputs Related to Fear Conditioning.

Neurons in the lateral amygdala (LA) receive glutamatergic sensory input from the auditory thalamus and auditory cortex, and these inputs can be modulated by serotonin (5-HT). It is known that the LA also receives a dense serotonergic projection from the dorsal raphe nucleus and the 5-HT3 receptor subtype is found on GABAergic interneurons in the LA. Activation of these receptors may serve as a means to modulate the glutamatergic inputs and affect amygdala related behaviors such as fear conditioning and anxiety states. In the present study, we examined if serotonergic inhibition of glutamate activated neurons occurs via activation of GABAergic interneurons. Single unit extracellular activity in the LA was recorded in response to iontophoretically applied glutamate (10 mM, 5-40 nA), and concurrent application of 5-HT (20 mM, 40-70 nA) inhibited this activation in 12 of 13 neurons. To examine if this inhibitory effect of 5-HT is mediated through GABAergic interneurons, the GABAA and GABAB antagonists (Bicuculline 5mM, 60-80 nA; Saclofen 20mM, 60-80 nA, respectfully) were iontophoresed with glutamate and 5-HT to determine if 5-HT's inhibitory effects can be reversed or blocked. Of the 12 neurons that were inhibited by 5-HT, concurrent application of the GABA antagonists reversed this effect in 75% (n=8) of these neurons. Application of the GABA antagonists alone had little or no effect on basal neuronal activity. We conclude that the 5-HT induced inhibition of glutamatergic activity may be through activation of serotonergic receptors (likely the 5-HT3 receptor subtype) on GABAergic interneurons, and blocking the GABAergic receptors is therefore able to block the 5-HT mediated inhibition.

 

M.G. Weisskopf and J.E. LeDoux(1998)  NMDA-INDEPENDENT LTP AT CORTICAL AND THALAMIC INPUT SYNAPSES TO THE LATERAL AMYGDALA

Fear conditioning depends on the transmission of auditory inputs to the lateral nucleus of the amygdala from the thalamus and cortex and may require NMDA receptor activation within the amygdala. In-vivo recordings have shown that the NMDA receptor antagonist APV preferentially inhibits thalamic activation of LAd cells compared to cortical (Li et al., 1995), suggesting possible synaptic profile and plasticity differences. We used an in-vitro amygdala slice preparation to examine the physiology of synaptic input to this region. Both cortical and thalamic EPSCs onto cells of LAd consisted of two components. A fast component showed a linear current-voltage relation and was blocked by the non-NMDA antagonist CNQX (10mM). A slower component had a region of negative slope conductance and was blocked by D-APV (25mM). In addition, we found that the ratio of NMDA to AMPA response is greater at thalamic synapses into LAd than at cortical synapses. These data confirm the previous finding that synaptic input to LAd is glutamatergic and could explain the differential APV sensitivity of action potentials elicited by thalamic and cortical stimulation in-vivo. Using a pairing protocol, LTP could be induced at both cortical and thalamic synapses, suggesting the involvement of postsynaptic mechanisms. In spite of the involvement of NMDA receptors in transmission in these two pathways, blockade of NMDA receptors did not prevent LTP induction in either. LTP induction was accompanied by a reduction in paired-pulse facilitation, suggesting that the expression of LTP depends on presynaptic mechanisms. Thus, plasticity at the input synapses in the amygdala involves both pre and postsynaptic changes, but does not depend on NMDA receptors. If NMDA receptors contribute to behavioral plasticity in the amygdala, their contributions are not likely to be at the input stage. Supported by NIH grants: R01-MH46516 and F32 NS10222.

Armony, J.L., Servan-Schreiber, D., Romanski, L.M., Cohen, J.D. & LeDoux, J.E. (1997) Stimulus generalization of fear responses: Effects of auditory cortex lesions in a computational model and in rats. Cerbral Cortex 7: 157-165 .

The conditioning of fear responses to a simple acoustic stimulus (pure tone) paired with footshock can be mediated by the transmission of auditory information to the lateral nucleus of the amygdala from either the auditory thalamus or the auditory cortex. We examined the processing capacity of the thalamo-amygdala pathway by making lesions of the auditory cortex and testing the extent to which conditioned fear responses generalized to tones other than the one paired with footshock. Two studies were performed, one in an anatomically-constrained computational model of the fear conditioning network, and the other in rats. Stimulus generalization was unaffected in both. These findings support the validity of the model as an approach to studying the neural basis of conditioned fear learning, and in addition suggest that the thalamo-amygdala pathway, possibly by the use of population coding, is capable of performing at least crude stimulus discriminations.

Armony J.L., Servan-Schreiber D., Cohen J.D. & LeDoux J.E. (1997)
Computational modeling of emotion: Explorations through the anatomy and physiology of fear conditioning.
Trends in Cognitive Sciences, 1: in press.


Recent discoveries about the neural system and cellular mechanisms in pathways mediating classical fear conditioning have provided a foundation for pursuing concurrent connectionist models of this form of emotional learning. The models described are constrained by the known anatomy underlying the behavior being simulated. Implementations to date capture salient features of fear learning at the level of behavior and at the level of single units, and additionally make use of generic biophysical constraints to mimic fundemental excitatory and inhibitory transmission properties. Due to the modular nature of the systems model, the biophysical modeling can be done in a single region, in this case the amygdala. Future directions include application of the biophysical model to questions about temporal summation in the two sensory input paths to amygdala, and modeling of an attentional interrupt signal that will extend the emotional procesing model to interactions with cognitive systems.

Li X.F., Stutzmann G.E. and LeDoux J.E. (1996)
Convergent but temporally spaced inputs to lateral amygdala neurons from the auditory thalamus and auditory cortex use different postsynaptic receptors: in vivo intracellular and extracellular recordings.
Learning and Memory, 3: 219-242

The lateral nucleus of the amygdala (LA), a key component of the fear conditioning circuitry, receives a rapid but relatively impoverished auditory input from the auditory thalamus and a slower but richer input from the auditory cortex. We examined, in urethane anesthetized rats, whether individual cells in LA receive convergent inputs from these two areas, and whether different postsynaptic receptors contribute to the temporally separated excitations over the two pathways. With both extracellular and intracellular recordings, individual cells could be activated by stimulation of each pathway. In extracellular recordings, iontophoretic application of NMDA receptor antagonist APV and the AMPA receptor antagonist CNQX demonstrated that synaptic transmission in both pathways depends on AMPA receptors, whereas transmission in the thalamic pathway also depends on the involvement of NMDA receptors. The involvement of NMDA receptors in synaptic activation of LA from the thalamus but not the cortex was confirmed in intracellular recordings using systemic injections of the NMDA antagonist, MK-801. The slow time course of NMDA currents could provide LA cells with a mechanism to integrate the inputs arriving rapidly from the thalamus and somewhat later from the cortex, thus allowing LA to integrate signals in the two pathways during the acquisition and expression of conditioned fear reactions.

Quirk G.J., Armony J.L. & LeDoux J.E. (1996)
A comparison of lateral amygdala and auditory cortex (TE3) neurons during fear conditioning.
Society for Neuroscience Abstracts, 22:1874

Previous work from our laboratory has examined the conditioned responses of lateral amygdala (LA) neurons during fear conditioning in freely moving rats (Quirk et al., 1995). In order to investigate the contribution of the auditory cortex (ACx) to fear conditioning, we have used identical procedures to record from the region of auditory cortex that projects to the lateral amygdala (TE3). A total of 42 neurons were recorded and compared to previosuly collected data in LA. A tone CS (5 KHz, 2 sec) was either unpaired (control) or paired with a footshock US (last 500 ms of tone). ACx cells were tone responsive in similar proportions to LA and showed early tone responses (10-20 ms following tone onset). Like LA, these short latency responses showed associative plasticity. Unlike LA, a late onset conditioned response leading up the time of shock onset (500-1500 ms) was observed. Further analysis of LA neurons showed that conditioned responses occurred at tone onset and offset only. This suggests that the role of LA is to signal changes in the occurrence of a threatening stimulus, while that of the cortex may involve additional processes, such as maintenance of sustained attention to the stimulus whilke present. Following 30 extinction trials, the short latency conditioned responses of LA neurons extinguished, while responses of ACx were not significantly attenuated, suggestingn that ACx may be a storage site for extinction-resistant memories.

Armony J.L., Quirk G.J . & LeDoux J.E. (1996)
Amygdala control of cortical plasticity in fear conditioning.
Society for Neuroscience Abstracts, 22:1874

In auditory fear conditioning, pairing of a neutral acoustic conditioned stimulus (CS) with with an aversive unconditioned stimulus (US) results in an enhancement of neural responses to the CS in the auditory cortex and amygdala. It is not clear, however, whether cortical plasticity governs neural changes in the amygdala or vice versa, or whether learning in these two structures is determined by independent processes. We examined this issue by recording multi- and single-cell activity in the auditory cortex (TE1 and TE3) of freelyÐbehaving amygdalectomized rats, using a movable bundle of microwires. Lesions were confirmed histologically and behaviorally, by absence of any conditioned fear responses (freezing). Responses to the CS presentation, without the US, after conditioning were compared to sensitization trials (unpaired CS and US). Lesion of the amygdala did not interfere with auditory processing in the cortex, but had significant effects on some aspects of cortical plasticity. Whereas cortical cells in unoperated animals developed conditioned increases in their response to the entire duration of the 2 sec CS, cells in amygdalectomized rats only exhibited conditioned increases shortly after tone onset (< 250 ms) and immediately preceding the time when the US would have occurred (1500 ms after tone onset). These results suggest that the amygdala activates (either directly or indirectly) the cortex during fear learning and enables a sustained response to a threatening stimulus.

Armony J.L., Servan-Schreiber D., Cohen J.C. & LeDoux J.E. (1996)
Emotion and cognition interactions in the thalamo-cortico-amygdala network: Theory and model
Cognitive Neuroscience Society Abstracts, 3:76.

Sensory information reaches the amygdala Ða structure critical for the acquisition and expression of emotionsÐ by way of two parallel pathways originating in the sensory thalamus: a direct thalamo-amygdala projection and an indirect pathway through the cortex. The role of the direct pathway has not been elucidated. On the basis of physiological evidence, we propose that the cortical pathway is subject to filtering by top-down attentional processes, whereas the direct pathway is not. Attentional filtering in the cortical pathway may block processing of a threatening stimulus (e.g., a CS+) that occurs as a component of an unattended stimulus. The role of the direct pathway would then be to convey the unfiltered stimulus to the amygdala in order to evoke appropriate survival responses. The direct pathway would thus be acting as an "interrupt" signal that redirects cortical processing towards survival-relevant stimuli. We implemented this theory in a connectionist network that combines the principles of our previous model of the thalamo-cortico-amygdala circuit involved in fear conditioning (Armony et al., 1995) with those of a model of attentional filtering (Cohen et al., 1990). 







  

   

       
        
 
      

         
        
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