Passive avoidance impairment in rats following cycloheximide injection into the amygdala

Memory retrieval requires ongoing protein synthesis and NMDA receptor activity-mediated AMPA receptor trafficking

Whereas consolidation and reconsolidation are considered dynamic processes requiring protein synthesis, memory retrieval has long been considered a passive readout of previously established plasticity. However, previous findings suggest that memory retrieval may be more dynamic than previously thought. This study therefore aimed at investigating the molecular mechanisms underlying memory retrieval in the rat. Infusion of protein synthesis inhibitors (rapamycin or anisomycin) in the amygdala 10 min before memory retrieval transiently impaired auditory fear memory expression, suggesting ongoing protein synthesis is required to enable memory retrieval. We then investigated the role of protein synthesis in NMDA receptor activity-mediated AMPA receptor trafficking. Coinfusion of an NMDA receptor antagonist (ifenprodil) or infusion of an AMPA receptor endocytosis inhibitor (GluA23Y) before rapamycin prevented this memory impairment. Furthermore, rapamycin transiently decreased GluA1 levels at the postsynaptic density (PSD), but did not affect extrasynaptic sites. This effect at the PSD was prevented by an infusion of GluA23Y before rapamycin. Together, these data show that ongoing protein synthesis is required before memory retrieval is engaged, and suggest that this protein synthesis may be involved in the NMDAR activity-mediated trafficking of AMPA receptors that takes place during memory retrieval.

The amygdala is critical for trace, delay, and contextual fear conditioning

Numerous investigations have definitively shown amygdalar involvement in delay and contextual fear conditioning. However, much less is known about amygdala contributions to trace fear conditioning, and what little evidence exists is conflicting as noted in previous studies. This discrepancy may result from selective targeting of individual nuclei within the amygdala. The present experiments further examine the contributions of amygdalar subnuclei to trace, delay, and contextual fear conditioning. Rats were trained using a 10-trial trace, delay, or unpaired fear conditioning procedure. Pretraining lesions targeting the entire basolateral amygdala (BLA) resulted in a deficit in trace, delay, and contextual fear conditioning. Immediate post-training infusions of the protein synthesis inhibitor, cycloheximide, targeting the basal nucleus of the amygdala (BA) attenuated trace and contextual fear memory expression, but had no effect on delay fear conditioning. However, infusions targeting the lateral nucleus of the amygdala (LA) immediately following conditioning attenuated contextual fear memory expression, but had no effect on delay or trace fear conditioning. In follow-up experiments, rats were trained using a three-trial delay conditioning procedure. Immediate post-training infusions targeting the LA produced deficits in both delay tone and context fear, while infusions targeting the BA produced deficits in context but not delay tone fear. These data fully support a role for the BLA in trace, delay, and contextual fear memories. Specifically, these data suggest that the BA may be more critical for trace fear conditioning, whereas the LA may be more critical for delay fear memories.

The effect of insulin and insulin-like growth factors on hippocampus- and amygdala-dependent long-term memory formation

Recent work has reported that the insulin-like growth factor 2 (IGF2) promotes memory enhancement. Furthermore, impaired insulin or IGF1 functions have been suggested to play a role in the pathogenesis of neurodegeneration and cognitive impairments, hence implicating the insulin/IGF system as an important target for cognitive enhancement and/or the development of novel treatments against cognitive disorders. Here, we tested the effect of intracerebral injections of IGF1, IGF2, or insulin on memory consolidation and persistence in rats. We found that a bilateral injection of insulin into the dorsal hippocampus transiently enhances hippocampal-dependent memory and an injection of IGF1 has no effect. None of the three peptides injected into the amygdala affected memories critically engaging this region. Together with previous data on IGF2, these results indicate that IGF2 produces the most potent and persistent effect as a memory enhancer on hippocampal-dependent memories. We suggest that the memory-enhancing effects of insulin and IGF2 are likely mediated by distinct mechanisms.

Induction and requirement of gene expression in the anterior cingulate cortex and medial prefrontal cortex for the consolidation of inhibitory avoidance memory

BACKGROUND

Memory consolidation is a process to stabilize short-term memory, generating long-term memory. A critical biochemical feature of memory consolidation is a requirement for gene expression. Previous studies have shown that fear memories are consolidated through the activation of gene expression in the amygdala and hippocampus, indicating essential roles of these brain regions in memory formation. However, it is still poorly understood whether gene expression in brain regions other than the amygdala/hippocampus is required for the consolidation of fear memory; however, several brain regions are known to play modulatory roles in fear memory formation.

RESULTS

To further understand the mechanisms underlying the formation of fear memory, we first identified brain regions where gene expression is activated after learning inhibitory avoidance (IA) by analyzing the expression of the immediately early genes c-fos and Arc as markers. Similarly with previous findings, the induction of c-fos and Arc expression was observed in the amygdala and hippocampus. Interestingly, we also observed the induction of c-fos and Arc expression in the medial prefrontal cortex (mPFC: prelimbic (PL) and infralimbic (IL) regions) and Arc expression in the anterior cingulate cortex (ACC). We next examined the roles of these brain regions in the consolidation of IA memory. Consistent with previous findings, inhibiting protein synthesis in the hippocampus blocked the consolidation of IA memory. More importantly, inhibition in the mPFC or ACC also blocked the formation of IA memory.

CONCLUSION

Our observations indicated that the formation of IA memory requires gene expression in the ACC and mPFC as well as in the amygdala and hippocampus, suggesting essential roles of the ACC and mPFC in IA memory formation.

Macromolecular synthesis, distributed synaptic plasticity, and fear conditioning

Recent work from a number of laboratories has provided new and important insights about how gene expression is altered by experience and how these molecular changes may provide a substrate for the long-term storage of new memories. Here, we review a series of recent studies using aversive Pavlovian conditioning in rats as a well characterized model system in which experience-dependent alterations in gene expression can be manipulated and quantified within a specific neural circuit. We highlight some of the issues involved in using broad-spectrum inhibitors of mRNA and protein synthesis to study cellular changes underlying the formation and long-term stability of memory and discuss the idea that these changes occur over widespread, behaviorally-defined, networks of cells. We also discuss the idea that the maintenance of memory and its susceptibly to disruption after retrieval may relate to local protein synthesis in dendrites. Finally, a series of recent experiments from our laboratory studying the role of a specific signaling pathway (mTOR) which regulates translational processes and memory formation in the amygdala and hippocampus during fear conditioning are reviewed.

Temporal requirement of C/EBPbeta in the amygdala following reactivation but not acquisition of inhibitory avoidance

Following learning, a memory is fragile and undergoes a protein synthesis-dependent consolidation process in order to become stable. Established memories can again become transiently sensitive to disruption if reactivated and require another protein synthesis-dependent process, known as reconsolidation, in order to persist. Here, we show that, in the basolateral amygdala (BLA), protein synthesis is necessary for both consolidation and reconsolidation of inhibitory avoidance (IA) memory, while the expression of the transcription factor CCAAT enhancer binding protein beta (C/EBPbeta) is essential only for the reconsolidation process. Moreover, the critical roles of both protein synthesis and C/EBPbeta following IA reactivation are temporally restricted, as they are necessary only for recent but not old IA memories. These results, together with previous findings showing that in the hippocampus both protein synthesis and C/EBPbeta expression are required for consolidation but not reconsolidation of IA indicate that the stabilization process that takes place either after training or memory retrieval engages distinct neural circuits. Within these circuits, the C/EBPbeta-dependent molecular pathway appears to be differentially recruited.

Linking new information to a reactivated memory requires consolidation and not reconsolidation mechanisms

A new memory is initially labile and becomes stabilized through a process of consolidation, which depends on gene expression. Stable memories, however, can again become labile if reactivated by recall and require another phase of protein synthesis in order to be maintained. This process is known as reconsolidation. The functional significance of the labile phase of reconsolidation is unknown; one hypothesis proposes that it is required to link new information with reactivated memories. Reconsolidation is distinct from the initial consolidation, and one distinction is that the requirement for specific proteins or general protein synthesis during the two processes occurs in different brain areas. Here, we identified an anatomically distinctive molecular requirement that doubly dissociates consolidation from reconsolidation of an inhibitory avoidance memory. We then used this requirement to investigate whether reconsolidation and consolidation are involved in linking new information with reactivated memories. In contrast to what the hypothesis predicted, we found that reconsolidation does not contribute to the formation of an association between new and reactivated information. Instead, it recruits mechanisms similar to those underlying consolidation of a new memory. Thus, linking new information to a reactivated memory is mediated by consolidation and not reconsolidation mechanisms.

The association of new information with an established memory is mediated through a consolidation mechanism, leaving the original memory intact.

Differential involvement of nucleus accumbens shell and core subregions in maternal memory in postpartum female rats

Maternal memory refers to the long-term retention of maternal responsiveness as a consequence of animals' prior experiences with their young. This study examined the relative roles of 2 subregions of the nucleus accumbens (NA; shell and core) in maternal memory in rats. NA shell lesions either before or immediately after a short experience significantly disrupted maternal memory, but lesions after a 24-hr maternal experience had no effect. NA core lesions had no significant impact on maternal memory. Cycloheximide (a protein synthesis inhibitor) at a high dose (25 micrograms/microliter) infused in the NA shell immediately after 1 hr of maternal experience also significantly disrupted maternal memory, whereas infusions in the medial preoptic area had no effect. It was concluded that the NA shell, but not the NA core, is involved in the consolidation of maternal memory.

Time-dependent effects of cycloheximide on long-term memory in the cuttlefish

When shown prawns in a glass tube, cuttlefish promptly learn to inhibit their predatory behavior and retain this ability for a long time. The cellular and molecular mechanisms of this long-term memory (LTM) are not yet known. In this study, we analyzed the dependency of LTM on de novo brain protein synthesis. Cycloheximide (CXM), a protein synthesis inhibitor, is injected intravenously immediately, 1 h, 3 h, 4 h or 6 h after the training. Retention is tested 24 h posttraining. The injections of CXM revealed one period of memory sensitivity to pharmacological intervention. CXM administered immediately or 6 h after training has no effect on LTM. Conversely, injections given between 1 and 4 h posttraining resulted in amnesia. Taken together, findings of this study establish for the first time in Sepia officinalis that de novo protein synthesis is an essential and time-dependent event for LTM formation of this form of associative learning.

Amnesia induced by stimulation of the amygdala is attenuated by hexamethonium

Bilateral subseizure stimulation of the amygdala given immediately following training in an inhibitory avoidance task produced retrograde amnesia. Hexamethonium (3.0 and 10.0 mg/kg), a peripherally acting nicotinic cholinergic antagonist, attenuated the retention deficits induced by amygdala stimulation if the drug was given 30 min prior to, but not immediately following training. Hexamethonium had no effect in normal unoperated animals, but did produce a retention deficit in operated control (nonstimulated) animals if it was given immediately following training (3.0 and 10.0 mg/kg). The results suggest that memory deficits induced by electrical stimulation of the amygdala are associated with, or perhaps mediated in some way by peripheral autonomic function.

Cycloheximide inhibits context memory and long-term habituation in the crab Chasmagnathus

A shadow moving over head elicits an escape response in the crab Chasmagnathus that habituates promptly and for a long period. The effect of the protein synthesis inhibitor cycloheximide (CY) on this long-term memory was analyzed. Two hours after injection, 10 micrograms CY inhibited [14C]-amino amino acid incorporation into cerebral plus thoracic ganglia by 88% and 20 micrograms by 92%, but no inhibition was found at 24 h. A single injection of 10-20 micrograms CY given 30 min before training, failed to affect the short-term habituation. Similar doses impaired both context memory (CM) and long-term habituation (LTH) when tested at 72 and 120 h but only CM at 24 h. Such a disparity was explained by an unspecific depressing effect upon the response, attributed to an interaction between CY and training. The hypothesis was confirmed, because CY injected immediately after training disclosed amnestic effect at 24 h on both CM and LTH. A similar effect was proven when animals were injected at 2 h but not at 6 h after training. Results from experiments with pretraining and pretesting injections put aside a state-dependence or retrieval deficit effects of the drug. Taken together, findings of this article argue strongly for de novo protein synthesis as a mechanism of LTH and for the close relation between CM and LTH.

Genetic dissection of consolidated memory in Drosophila

Behavioral and pharmacological experiments in many animal species have suggested that memory is consolidated from an initial, disruptable form into a long-lasting, stable form within a few hours after training. We combined these traditional approaches with genetic analyses in Drosophila to show that consolidated memory of conditioned (learned) odor avoidance 1 day after extended training consisted of two genetically distinct, functionally independent memory components: anesthesia-resistant memory (ARM) and long-term memory (LTM). ARM decayed away within 4 days, was resistant to hypothermic disruption, was insensitive to the protein synthesis inhibitor cycloheximide (CXM), and was disrupted by the radish single-gene mutation. LTM showed no appreciable decay over 7 days, was sensitive to CXM, and was not disrupted by the radish mutation.

Noradrenergic involvement in the consolidation of maternal experience in postpartum rats

If postpartum rats are separated from pups following cesarean delivery, their maternal responsiveness declines such that in tests on day 10 they show maternal onset latencies that do not differ from those shown by virgin rats. If, however, dams are permitted a 1-h experience with pups within 36 h of cesarean delivery, rats exhibit a high level of responsiveness to foster pups on day 10 after c-section. The present research investigates the effect of the noradrenergic system in the long-term consolidation of a brief maternal experience in new mother rats. Groups of dams were cesarean delivered and were either given pups for a brief period 36 h after section (experienced) or received no experience (inexperienced). Immediately following the experience phase, dams were injected with different concentrations of the beta-adrenergic antagonist, propranolol (0, 0.5, 1.0, 5.0 mg/kg), or the adrenergic agonist, isoproterenol (0, 0.25 or 0.5 mg/kg). Ten days after cesarean delivery rats were given maternal induction tests. Rats receiving 60 min of experience and injected with propranolol exhibited significantly longer maternal onset latencies than did saline-injected rats, although their latencies were not as long as shown by the maternally inexperienced groups. In contrast, rats receiving 15 min of experience and injected with isoproterenol exhibited significantly shorter onset latencies than did saline-injected rats, whether or not they exhibited maternal behavior during the initial 15 min exposure period. These results suggest that the noradrenergic system is involved in the consolidation of a maternal experience.

Time-dependent disruption of passive avoidance acquisition by post-training intra-amygdala injection of tetrodotoxin in rats

The role of the amygdala (AM) in the consolidation of the passive avoidance reaction (PAR) has been examined with the tetrodotoxin (TTX)-induced functional block of this structure. Rats were trained in the step-through PAR and anesthetized with ketamine. TTX injected immediately after acquisition into both AM (2 x 10 ng) significantly reduced avoidance of the dark compartment in the retrieval test performed two days later. The amnesic effect was significant when the acquisition--TTX delay was prolonged to 90 min but not to 6 h or 24 h. Earlier research indicated that TTX blockade of the parabrachial nuclei caused similar PAR disruption when elicited 24 h but not 48 h after acquisition. Comparison of the TTX-induced retrograde amnesias indicates that the two structures play different roles in the formation of the PAR engram.

MK801, an NMDA antagonist, blocks acquisition of a spatial task but does not block maternal experience effects

Two studies were conducted to determine the effect on learning and memory of MK801, an N-methyl-D-aspartate (NMDA) antagonist that acts through noncompetitive blockade of the ion channel associated with the NMDA receptor. In the first study we found a dose-dependent impairment in the acquisition of a modified radial-arm maze task, resulting from injections (IP) of MK801 10 minutes prior to training. The retention of that learning, as measured by the amount of training required for reacquisition on the following day, was unaffected by the drug. In contrast, in the second study, MK801 did not block the experience-based facilitation of maternal responding seen 8 days after one hour of exposure to pups: experienced dams showed facilitated onset of maternal behavior, relative to inexperienced dams, regardless of the drug they received. However, injections of MK-801, either just before or just after the maternal experience, did lead to some deficits in maternal responding on the first day of testing. We have previously shown that these maternal experience effects are blocked by injections (ICV, SC) of cycloheximide, a protein synthesis inhibitor. These results suggest that the NMDA system does not mediate all, if any, of cycloheximide's effects on maternal experience and, furthermore, that the NMDA system may mediate some but not all forms of learning.

Cardiovascular changes induced by chemical stimulation of the amygdala in rats

The role of the amygdaloid complex in the central regulation of the cardiovascular system was studied in unanesthetized, unrestrained rat. The injection of carbachol into the amygdaloid complex elicited a pressor response, whereas the injection of noradrenaline and 5-hydroxytryptamine into the same area caused no significant cardiovascular changes. The greatest pressor response was obtained when carbachol was injected into the central nucleus. Bradycardia and tachycardia occurred when injection of carbachol was made into dorso-central and medio-ventral parts of the amygdaloid complex, respectively. Concomitant with cardiovascular responses, the injection of carbachol into the amygdaloid complex produced behavioral changes including immobilization, body shaking, searching and rearing. The pressor response and bradycardia were suppressed by prior local injection into the amygdaloid complex of atropine but not hexamethonium. These results suggest that the cholinergic system mediated by activation of muscarinic receptors in the amygdaloid complex may play a role in the control of cardiovascular and autonomic function.

Effects of nucleus basolateralis amygdalae neurotoxic lesions on aversive conditioning in the rat

After bilateral stereotaxic administration of ibotenic acid on the n. basolateralis amygdalae, male adult rats were tested in the light-dark box apparatus to measure the time-course of the acquisition and retention of passive and active avoidance responses. The results show that after the lesions both passive avoidance and active avoidance acquisition were impaired. Passive avoidance responses were retained quite well, while active avoidance responses disappeared quickly. Conditioned freezing was almost completely absent. Thus it appears that the n. basolateralis plays a facilitatory role in all the conditioned responses which were investigated.

Passive avoidance conditioning and unitary activity in the basolateral amygdaloid nucleus of the rat

Single unit activity was recorded in the basolateral nucleus of amygdala in rats in a passive avoidance test. Simultaneously, visual control of exploratory behaviour was carried out. Prior to establishing the conditioning, the mean frequency of the unit discharge was 14 Hz (SD = 9) and 1 minute after conditioning this unit activity decreased to values close to zero; later on (24 and 48 hours), a progressive recovery of the discharge was observed. Behavioural changes were also detected. The long term recovery of unit activity follows the time course of the extinction process. The possible significance of these findings is discussed in relation to some of the functional roles of this nucleus.

Learning-induced change in neural activity during acquisition and consolidation of a passive avoidance response in the rat

Time-dependent alterations in neural activity have been established during the acquisition and consolidation of a stepdown passive avoidance paradigm. Change in neural activity was established by administering a glucose analogue, [3H]2-deoxyglucose, 50min prior to sacrifice and estimating perchloric acid soluble counts in nine hand dissected brain regions. Change in [3H]2-deoxyglucose uptake was closely paralleled in both trained and yoked animals for up to 40min following task acquisition however the striatum was the only area to exhibit a task-specific increase in [3H]2-deoxyglucose uptake at 20-30min after training. Longterm changes in neural activity were also apparent as the amygdala and brainstem showed increased [3H]2-deoxyglucose uptake at the 24 h time point. No further paradigm-specific changes were apparent at 48 h. These findings are concluded to suggest that the striatum is involved in the early events of acquiring a passive avoidance response and the amygdala and brainstem during the later events.

Cycloheximide blocks the retention of maternal experience in postpartum rats

Two studies were done to determine the effects of cycloheximide (CYX), a protein synthesis inhibitor, on maternal experience effects in rats. In the first study eight groups received a 2-h maternal experience 36 h after cesarean (c)-section and two groups received no post c-section experience. Among the experienced groups, two received icv injections of CYX or saline (SAL) 30 min before the maternal experience, two received CYX or SAL 10 min after the experience, and two received the injections 24 h after the experience. One inexperienced group received CYX and the other received SAL 36 h after c-section. Tests for maternal behavior occurred 10 days after c-section. CYX was not able to block or disrupt the "acquisition" or expression of ongoing maternal behavior during the 2-h experience phase. However, CYX was able to block the long-term "retention" of a 2-h maternal experience if the drug was present during or immediately after the experience, prior to "consolidation." The second study investigated the effects of CYX administered immediately after the maternal experience on the expression and retention of maternal behavior 4 and 6 days after c-section, to determine whether the hormonally mediated short-onset latencies of the 4-day group would be blocked by CYX. Eight groups of animals were tested for maternal behavior. Four were tested 4 days after c-section and four were tested 6 days after c-section. Within each of these groups two were experienced and two inexperienced; within each experience condition one group received CYX and one received SAL. Day 4 groups exhibited shorter onset latencies than Day 6 groups. There was also a CYX-SAL difference in maternal onset latencies among experienced Day 6 groups but not among Day 4 groups. These data indicate that the blocking effects of CYX can be seen only when hormonal priming of maternal behavior is no longer in evidence.

Mechanism of the rapid effect of 17 beta-estradiol on medial amygdala neurons

The mechanism by which sex steroids rapidly modulate the excitability of neurons was investigated by intracellular recording of neurons in rat medial amygdala brain slices. Brief hyperpolarization and increased potassium conductance were produced by 17 beta-estradiol. This effect persisted after elimination of synaptic input and after suppression of protein synthesis. Thus, 17 beta-estradiol directly changes the ionic conductance of the postsynaptic membrane of medial amygdala neurons. In addition, a greater proportion of the neurons from females than from males responded to 17 beta-estradiol.

Cerebral protein synthesis during long-term recovery from severe hypoglycemia

Regional protein synthesis was investigated in the rat brain during long-term recovery from insulin-induced hypoglycemia with 30 min of cerebral electrical silence. At various time intervals up to 14 days after glucose replenishment, animals received a single dose of L-[3,5-3H]tyrosine and were killed 30 min later. Brains were processed for autoradiography using the stripping film technique. Although hypoglycemia sufficiently severe to cause cessation of EEG activity leads to almost complete inhibition of amino acid incorporation in all "vulnerable" forebrain structures (cerebral cortex, hippocampus, caudoputamen), autoradiographs revealed a very specialized sequence with differential posthypoglycemic restoration of biosynthetic activity in certain neuronal cell types. Three major subpopulations could be distinguished: Neurons that fully regained their protein synthetic capacity within 6 h following hypoglycemia (cortical neurons of layer III-VI, large neurons in the caudoputamen, CA3 and CA4 pyramidal neurons, the majority of granule cells of the dentate gyrus) seemed to escape neuronal necrosis. Prolonged impairment of protein synthesis with only partial restoration during the early posthypoglycemic recovery period (CA1 neurons, most small- to medium-sized neurons of the caudoputamen) carried an increased risk of permanent cell damage. The large majority of these neurons, however, showed full recovery of protein synthesis as late as 7 days after hypoglycemia. Neurons with complete lack of amino acid incorporation after 6 h of recovery (granule cells at the crest of the dentate gyrus, small neurons of the dorsolateral caudoputamen) never resumed protein synthesis, regressed, and died. These studies in conjunction with morphological analysis indicate that the sequential recovery of protein synthesis reflects the extent to which neuronal populations are at risk during severe hypoglycemia.

Amnesia attenuation specificity: propranolol reverses norepinephrine but not cycloheximide-induced amnesia

Post-trial injections of norepinephrine (NE) or cycloheximide (CHX) into the amygdala produces a long-term retention deficity (amnesia) for a 1-trial footshock experience in rats. concomitant post-trial injections of the adrenergic antagonist, propranolol, prevents NE-, but not CHX-induced amnesia. These results indicate separate mechanisms of action for amnesia produced by intracranial CHX and NE injections.

Lesions of the stria terminalis attenuate the amnestic effect of amygdaloid stimulation on avoidance responses

The present study investigated the involvement of two amygdala pathways, the stria terminalis (ST) and the ventral amygdalofugal pathway (VAF), in the effect of post-training electrical stimulation of the amygdala on retention. Rats with implanted amygdaloid electrodes and ST lesions, VAF transections or sham pathway operations, were trained on an inhibitory avoidance task and an active avoidance task. Electrical stimulation of the amygdala was given immediately after training and retention was tested 24 h later. In rats with sham ST lesions, post-training amygdaloid stimulation impaired retention in both tasks. Lesions of the ST did not significantly affect retention in the unstimulated rats. However, the ST lesions attenuated the amnestic effect of amygdaloid stimulation. In rats with sham VAF transections, stimulation of the amygdala impaired retention in the inhibitory avoidance task but enhanced retention in the active avoidance task. Transecting the VAF impaired retention performance of the unstimulated rats in the inhibitory avoidance task. However, the VAF transections did not alter the effect of amygdaloid stimulation: in both tasks, the retention performance of stimulated rats with VAF transections did not differ from that of stimulated rats with sham transections. These findings suggest that the ST may be involved in mediating the influences of the stimulated amygdala in modulating memory storage processing in the brain.

Transient aversion and long-lasting amnesia following cycloheximide injection in the rat

Rats were first trained to press a bar for water reinforcement. The day after reaching criterion, the animals received a subcutaneous injection of cycloheximide (CXM-2.5 mg/kg) or saline, 15 minutes before a single punishment (P) session where bar pressing was followed by a strong inescapable footshock (CXM-P and saline-P groups). No punishment was given to control groups (CXM-NP and saline-NP groups). Retention for this learning experience was tested 24 hr, one week or two weeks later. Performances of the control groups were similar at the three retention intervals although some CXM-induced aversion appeared at 24 hr. The saline-P groups always demonstrated good retention of prior aversive experience. By contrast, a long-lasting CXM-induced amnesia was apparent among the CXM-P groups. This deficit is not easily explained by nonspecific effects of the drug such as altered motor activity or motivational changes. Moreover, CXM-induced amnesia seems to be the result of impaired memory formation rather than impaired memory retrieval.

Post-training amygdaloid lesions impair retention of an inhibitory avoidance response

The study examined the effect of pre- and post-training bilateral amygdaloid lesions on retention of a one-trial inhibitory avoidance response. Groups of rats, including unimplanted controls and implanted controls, were trained and tested for retention at 4, 7 or 12 days following training. The lesions were made at one of several intervals before or after training: 2 days before, immediately after, or 2, 5 or 10 days after. At all retention intervals the retention of implanted controls was poorer than that of unimplanted controls and, in comparison with both control groups, the retention of animals lesioned before training was impaired. Retention was also impaired by the post-training lesions. The degree of impairment varied with the interval between the training and the lesion: lesions made within 2 days following training impaired retention, while lesions made 10 days following training had no impairing effect. These findings suggest that post-training lesions of the amygdala affect retention by impairing time-dependent processes involved in memory storage. With a sufficiently long training-lesion interval (10 days) an intact amygdala is not essential for retention.

Retrograde amnesia produced by electrical stimulation of the amygdala: attenuation with adrenergic antagonists

Subseizure electrical stimulation of the amygdala produced retrograde amnesia for a visual discrimination shock-motivated task. Animals pretreated with the alpha-adrenergic antagonist phenoxybenzamine, or the beta-adrenergic antagonist propranolol, did not develop amnesia. The findings indicate that adrenergic antagonists attenuate amnesia produced by amygdala stimulation for visual discrimination training. These results are consistent with previous evidence indicating that adrenergic antagonists attenuate the amnesias produced by a variety of agents, and thus, suggest that adrenergic mechanisms may be involved in the production of retrograde amnesia.

A quantitative regional analysis of protein synthesis inhibition in the rat brain following localized injection of cycloheximide

Previous work has shown that bilateral injection of as little as 10 microgram of cycloheximide (CHX) into the amygdala, but not into the internal capsule, caused a time-dependent disruption of long-term retention of passive avoidance training. Under these conditions, protein synthesis in the entire brain was inhibited by less than 10%. The present study was undertaken to quantify the resulting inhibition of protein synthesis in various brain regions (amygdala, internal capsule, caudate, cortex, hippocampus, thalamus, hypothalamus and the entire half brain). Rats were subcutaneously injected with L-[14C-methyl]methionine following unilateral administration of CHX via a cannula implanted in either the amygdala or the internal capsule. Regional inhibition of protein synthesis was determined by analysis of autoradiograms from different brain levels using an image analyzing computer to measure the optical densities of microscopic areas corresponding to discrete neuroanatomical structures. Regional patterns of inhibition were assessed: (a) after injection of different doses of CHX (10 or 20 microgram) into the amygdala; (b) after injection of 20 microgram of CHX into the amygdala or internal capsule; and (c) at different times (0.5, 3, 6 and 24 h) after injection of 20 microgram of CHX into the amygdala. Quantitative results are presented for the temporal and spatial patterns of protein synthesis inhibition caused by CHX injection. Since injection of CHX into the amygdala resulted in a profound inhibition of protein synthesis in both the amygdala and internal capsule while injection into the thermal capsule only caused a marked inhibition in the capsule itself, these results provide a possible explanation for our earlier observation that injection of CHX into the amygdala produced a retention deficit while injection into the adjacent internal capsule had no effect on memory function. These observations on protein synthesis inhibition support our earlier hypothesis that CHX injected into the amygdala might impair memory by virtue of its action on amygdaloid function rather than as a result of its effect on the brain as a whole.

A comparison of the effects of localized brain administration of catecholamine and protein synthesis inhibitors on memory processing

Protein synthesis inhibitors disrupt biosynthetic processes thought to control the formation of long-term memory. While the agents used (i.e. puromycin, acetoxycycloheximide, cycloheximide and anisomycin) do not selectively inhibit the synthesis of any particular class of protein, it has generally been hypothesized or assumed that the critical proteins(s) is structural and necessary for modification and/or growth of synapses. Recent reports indicated that all of the protein synthesis inhibitors causing amnesia inhibited tyrosine hydroxylase activity. Tyrosine hydroxylase is needed for the conversion of tyrosine to dopamine (DA) and norpinephrine (NE); altering the level of this enzyme could affect catecholamine (CA) turnover. Since drugs known to inhibit CA synthesis cause amnesia, it is of considerable interest whether amnesia induced by protein synthesis inhibitors depends basically on inhibition of CA synthesis.

Two sensitive periods for the amnesic effect of anisomycin

Impairment of retention of a brightness discrimination in rats was obtained when anisomycin (80 microgram bilaterally into both hippocampi) was injected 10 min before and 80 min after training or 240 and 360 min after training. No amnesia was observed when anisomycin was injected 45 and 165 min post training. The two separate sensitive periods for the amnesic effect of the inhibitor obviously correspond to the two phases of increased protein synthesis during the consolidation of the same learning procedure. The results support the previous findings of the two independent and qualitatively different macromolecular processes. They also argue for the inhibition of protein synthesis as an important mechanism in the amnesic effect of anisomycin.