Brain-derived neurotrophic factor enhances conditioned taste aversion retention

Brain-derived neurotrophic factor (BDNF) has recently emerged as one of the most potent molecular mediators of not only central synaptic plasticity, but also behavioral interactions between an organism and its environment. Our previous studies on the insular cortex (IC), a region of the temporal cortex implicated in the acquisition and storage of conditioned taste aversion (CTA), have demonstrated that induction of long-term potentiation (LTP) in the projection from the basolateral nucleus of the amygdala (Bla) to the IC, previous to CTA training, enhances the retention of this task. Recently, we found that intracortical microinfusion of BDNF induces a lasting potentiation of synaptic efficacy in the Bla-IC projection of adult rats in vivo. In this work, we present experimental data showing that intracortical microinfusion of BDNF previous to CTA training enhances the retention of this task. These findings support the concept that BDNF may contribute to memory-related functions performed by a neocortical area, playing a critical role in long-term synaptic plasticity.     

Hand-eye coordination relies on extra-retinal signals: evidence from reactive saccade adaptation

Brain-derived neurotrophic factor (BDNF) has emerged as an important molecular mediator of synaptic plasticity. Our previous studies on the insular cortex (IC), a region of the temporal cortex implicated in the acquisition and storage of conditioned taste aversion (CTA), have demonstrated that the intracortical microinfusion of BDNF induces a lasting potentiation of synaptic efficacy in the projection from the basolateral nucleus of the amygdala (Bla) to the IC of adult rats in vivo. Recently, we have found that intracortical microinfusion of BDNF previous to CTA training modifies the retention of this task. In this work, we present experimental data showing that BDNF effects on CTA retention are dependent on both the activation of mitogen-activated protein kinases (MAPK) and phosphatidylinositol-3-kinase (PI-3K) at the insular cortex. Our results are evidence of the crucial role of both pathways in the modification of the CTA trace of memory caused by BDNF at a neocortical area.     

In vivo effects of intracortical administration of NMDA and metabotropic glutamate receptors antagonists on neocortical long-term potentiation and conditioned taste aversion.

It has been proposed that long-term potentiation (LTP), a form of activity-dependent modification of synaptic efficacy, may be a synaptic mechanism for certain types of learning. Recent studies on the insular cortex (IC), a region of the temporal cortex implicated in the acquisition and storage of conditioned taste aversion (CTA), have demonstrated that tetanic stimulation of the basolateral nucleus of the amygdala (Bla) induce an N-methyl-D-aspartate (NMDA) dependent LTP in the IC of adult rats in vivo. Here we present experimental data showing that intracortical administration of the NMDA receptor competitive antagonists CPP (-3(-2 carboxipiperazin-4-yl)-propyl-1-phosphonic acid, 0.03 microg per hemisphere) and AP-5 (D(-)-2-amino-5-phosphonopentanoic, 2.5 microg per hemisphere) disrupt the acquisition of conditioned taste aversion, as well as IC-LTP induction in vivo. In contrast, administration of the metabotropic glutamate receptor antagonist MCPG ((RS)-alpha-methyl-4-carboxyphenylglycine, 2.5 microg per hemisphere) does not disrupt the acquisition of CTA nor IC-LTP induction. These findings are of particular interest since they provide support for the view that the neural mechanisms underlying NMDA-dependent neocortical LTP constitute a possible mechanism for the learning-related functions performed by the IC.     

The NMDA receptor antagonist CPP impairs conditioned taste aversion and insular cortex long-term potentiation in vivo.

It has been proposed that long-term potentiation (LTP) a form of activity-dependent modification of synaptic efficacy, may be a synaptic mechanism for certain types of learning. Recent studies on the insular cortex (IC) a region of the temporal cortex implicated in the acquisition and storage of conditioned taste aversion (CTA), have demonstrated that tetanic stimulation of the basolateral nucleus of the amygdala (Bla) induce an N-methyl- -aspartate (NMDA) dependent LTP in the IC of adult rats in vivo. Here we present experimental data showing that intracortical administration of the NMDA receptor competitive antagonist CPP (-3(-2 carboxipiperazin-4-yl)-propyl-1-phosphonic acid) disrupts the acquisition of conditioned taste aversion, as well as, the IC-LTP induction in vivo. These findings are of particular interest since they provide support for the view that the neural mechanisms underlying NMDA dependent neocortical LTP, constitute a possible mechanism for the learning related functions performed by the IC.     

Critical role of insular cortex in taste but not odour aversion memory

Conditioned odour aversion (COA) and conditioned taste aversion (CTA) result from the association of a novel odour or a novel taste with delayed visceral illness. The insular cortex (IC) is crucial for CTA memory, and the present experiments sought to determine whether the IC is required for the formation and the retrieval of COA memory as it is for CTA. We first demonstrated that ingested odour is as effective as taste for single-trial aversion learning in rats conditioned in their home cage. COA, like CTA, tolerates long intervals between the ingested stimuli and the illness and is long-lasting. Transient inactivation of the IC during acquisition spared COA whereas it greatly impaired CTA. Similarly, blockade of protein synthesis in IC did not affect COA but prevented CTA consolidation. Moreover, IC inactivation before retrieval tests did not interfere with COA memory expression when performed either 2 days (recent memory) or 36 days after acquisition (remote memory). Similar IC inactivation impaired the retrieval of either recent or remote CTA memory. Altogether these findings indicate that the IC is not necessary for aversive odour memory whereas it is essential for acquisition, consolidation and retrieval of aversive taste memory. We propose that the chemosensory stimulations modulate IC recruitment during the formation and the retrieval of food aversive memory.     

Differential participation of temporal structures in the consolidation and reconsolidation of taste aversion extinction

The extinction process has been described as the decline in the frequency or intensity of the conditioned response following the withdrawal of reinforcement. Hence, experimental extinction does not reflect loss of the original memory, but rather reflects new learning, which in turn requires consolidation in order to be maintained in the long term. During extinction of conditioned taste aversion (CTA), a taste previously associated with aversive consequences acquires a safe status through continuous presentations of the flavor with no aversive consequence. In addition, reconsolidation has been defined as the labile state of a consolidated memory after its reactivation by the presentation of relevant information. In this study, we analyzed structures from the temporal lobe that could be involved in consolidation and reconsolidation of extinction of CTA by means of new protein synthesis. Our results showed that protein synthesis in the hippocampus (HC), the perirhinal cortex (PR) and the insular cortex (IC) of rats participate in extinction consolidation, whereas the basolateral amygdala plays no part in this phenomenon. Furthermore, we found that inhibition of protein synthesis in the IC in a third extinction trial had an effect on reconsolidation of extinction. The participation of the HC in taste memory has been described as a downmodulator for CTA consolidation, and has been related to a context–taste association. Altogether, these data suggest that extinction of aversive taste memories are subserved by the IC, HC and PR, and that extinction can undergo reconsolidation, a process depending only on the IC.     

Basolateral amygdala glutamatergic activation enhances taste aversion through NMDA receptor activation in the insular cortex

In conditioned taste aversion (CTA), a subject learns to associate a novel taste with visceral malaise. Brainstem, limbic and neocortical structures have been implicated in CTA memory formation. Nevertheless, the role of interactions between forebrain structures during these processes is still unknown. The present experiment was aimed at investigating the possible interaction between the basolateral nucleus of the amygdala (BLA) and the insular cortex (IC) during CTA memory formation. Injection of a low dose of lithium chloride (30 mg/kg, i.p.) 30 min after novel taste consumption (saccharin 0.1%) induces a weak CTA. Unilateral BLA injection of glutamate (2 microg in 0.5 microL) just before low lithium induces a stronger CTA. Unilateral injection of an N-methyl-d-aspartate (NMDA) receptor antagonist (AP5, 5 microg in 0.5 microL) in IC has no effect. However, AP5 treatment in IC at the same time or 1 h after the ipsilateral BLA injection reverses the glutamate-induced CTA enhancement. Injection of AP5 in IC 3 h after BLA injection does not interfere with the glutamate effect. Moreover, the CTA-enhancing effect of glutamate was also blocked by contralateral IC injection of AP5 at the same time. These results provide strong evidence that NMDA receptor activation in the IC is essential to enable CTA enhancement induced by glutamate infusion in the BLA during a limited time period that extends to 1 but not to 3 hours. These findings indicate that BLA-IC interactions regulate the strength of CTA. The bilateral nature of these amygdalo-cortical interactions is discussed.     

Establishing aversive, but not safe, taste memories requires lateralized pontine-cortical connections

Aversive and safe taste memory processing is dramatically disrupted by bilateral lesions of the pontine parabrachial nucleus (PBN). To determine how such lesions affect patterns of neuronal activation in forebrain, lesions were combined with assessment of cFos-like immunoreactivity (FLI) in insular cortex (IC) and amygdala after conditioned taste aversion (CTA) training. Increases in FLI in amygdala and IC, which are normally seen following novel (versus familiar) CS-US pairing, were eliminated after PBN lesions. This suggests that PBN lesions prevent transmission of critical CS and US information to forebrain regions for the processing of both aversive and safe taste memories. Unilateral asymmetrical lesions of PBN and IC blocked CTA acquisition as well as normal patterns of FLI in amygdala after novel CS-US pairing, an effect not seen when unilateral lesions were confined to a single hemisphere. The crossed-disconnection experiments provide compelling evidence that functional interactions between PBN and IC are required for CTA acquisition, but not for safe taste memory formation and retrieval. The dissociation between effects of the different types of lesions on safe and aversive taste memories supports emerging evidence that the neural underpinnings of the two types of taste learning differ.     

In vivo insular cortex LTP induced by brain-derived neurotrophic factor

Recent studies suggest that brain-derived neurotrophic factor (BDNF) plays a critical role in long-term synaptic plasticity in the adult brain. Previous studies on the insular cortex (IC), a region of the temporal cortex implicated in the acquisition and storage of different aversive learning tasks, have demonstrated that tetanic stimulation of the basolateral nucleus of the amygdala (Bla) induces an N-methyl-D-aspartate (NMDA)-dependent form of long-term potentiation (LTP) in the IC of adult rats in vivo. Here, we show that acute intracortical microinfusion of BDNF induces a lasting potentiation of synaptic efficacy in the Bla-IC projection of anesthetized adult rats. This constitutes an in vivo demonstration of neurotrophin-induced potentiation of synaptic transmission in the neocortex. These findings support the concept that BDNF could be a synaptic messenger involved in activity-dependent synaptic plasticity.     

Bilateral lesions in a specific subregion of posterior insular cortex impair conditioned taste aversion expression in rats

The gustatory cortex (GC) is widely regarded for its integral role in the acquisition and retention of conditioned taste aversions (CTAs) in rodents, but large lesions in this area do not always result in CTA impairment. Recently, using a new lesion mapping system, we found that severe CTA expression deficits were associated with damage to a critical zone that included the posterior half of GC in addition to the insular cortex (IC) that is just dorsal and caudal to this region (visceral cortex). Lesions in anterior GC were without effect. Here, neurotoxic bilateral lesions were placed in the anterior half of this critical damage zone, at the confluence of the posterior GC and the anterior visceral cortex (termed IC₂), the posterior half of this critical damage zone that contains just VC (termed IC₃), or both of these subregions (IC₂ + IC₃). Then, pre‐ and postsurgically acquired CTAs (to 0.1 M NaCl and 0.1 M sucrose, respectively) were assessed postsurgically in 15‐minute one‐bottle and 96‐hour two‐bottle tests. Li‐injected rats with histologically confirmed bilateral lesions in IC₂ exhibited the most severe CTA deficits, whereas those with bilateral lesions in IC₃ were relatively normal, exhibiting transient disruptions in the one‐bottle sessions. Groupwise lesion maps showed that CTA‐impaired rats had more extensive damage to IC₂ than did unimpaired rats. Some individual differences in CTA expression among rats with similar lesion profiles were observed, suggesting idiosyncrasies in the topographic representation of information in the IC. Nevertheless, this study implicates IC₂ as the critical zone of the IC for normal CTA expression. J. Comp. Neurol. 524:54–73, 2016. © 2015 Wiley Periodicals, Inc.     

Distinct mechanisms of bidirectional activity-dependent synaptic plasticity in superficial and deep layers of rat entorhinal cortex

The entorhinal cortex plays a key role in processing memory information in the brain; superficial layers relay information to, and deep layers receive information from, the hippocampus. The cellular mechanisms of memory are thought to include a number that produce long-term potentiation (LTP) and depression (LTD) of synaptic strength. Our work presents evidence that LTP and LTD occur simultaneously at memory-relevant synapses. We report here that low frequency stimulation generates NMDA receptor-dependent LTD in Wistar rat superficial (layers II and III), and LTP in the deep entorhinal cortex layers (layers V and VI). LTP in deep layers is masked by simultaneously occurring voltage-gated calcium channel-dependent LTD. Our data support a novel mechanism for the sliding-threshold (BCM) model of synaptic plasticity: The sliding thresholds for induction of LTP and LTD in entorhinal cortex deep layers will be driven by the relative activation state of NMDA receptors and voltage-gated calcium channels. The co-expression of LTD and LTP at presynaptic sites in the entorhinal cortex deep layers reveals an intriguing mechanism for differential processing of synaptic information, which may underlie the vast dynamic capacity for information storage by this cortical structure.     

Synaptic plasticity from amygdala to perirhinal cortex: a possible mechanism for emotional enhancement of visual recognition memory?

Emotionally salient experiences are better remembered than events that have little emotional context. Several lines of evidence indicate that the amygdala plays an important role in this emotional enhancement of memory. Visual recognition memory relies on synaptic plasticity in the perirhinal cortex, but little is known about the mechanisms involved in emotional enhancement of this form of memory. The results of the present study, performed in rat brain slices, show for the first time that the amygdala input to the perirhinal cortex undergoes synaptic plasticity. Stimulation in the amygdala resulted in long-term potentiation (LTP) in perirhinal cortex that was dependent on β-adrenoceptors and L-type voltage-dependent calcium channels (L-VDCCs) but was NMDAR-independent. In contrast, intracortical perirhinal stimulation resulted in LTP that was NMDAR-dependent but β-adrenoceptor- and L-VDCC-independent. In addition, the present results provide the first evidence that stimulation of the amygdala can reduce the threshold for LTP in the perirhinal cortex. Interestingly, this associative form of LTP requires β-adrenoceptor activation but not NMDA or L-VDCC activation. Knowing the mechanisms that control amygdala-perirhinal cortex interactions will allow better understanding of how emotionally charged visual events are remembered, and may help to understand how memories can consolidate and become intrusive in anxiety-related disorders.     

Protection of stress-induced impairment of hippocampal/prefrontal LTP through blockade of glucocorticoid receptors: implication of MEK signaling

We previously reported that exposure to acute and chronic stress impairs long-term potentiation (LTP) in the hippocampal–prefrontal cortex pathway and showed evidence for a fundamental role of the prefrontal cortex in maladaptive responses to stress. The goal of the current studies was to examine whether blockade of glucocorticosteroid receptors (GR), by mifepristone (a Type II glucocorticoid receptor antagonist), just after exposure to acute stress could prevent stress-induced impairment of prefrontal LTP. We further examine the effects of mifepristone on mitogen-activated protein/ERK kinase (MEK) signaling pathway in the prefrontal cortex. The data show that an acute injection of mifepristone after stress restored the stress-induced blockade of prefrontal LTP and reduction of phospho-Ser217/221-MEK. These findings have significance for the treatment of memory deficits in hypercortisolemic states, such as stress and depression.     

Identification of neurons producing long-term potentiation in the cat motor cortex: Intracellular recordings and labeling

Intracellular, in vivo recordings were used to identify and subsequently to label neurons in the cat motor cortex in which long-term potentiation (LTP) was induced. Thirty-nine motor cortical neurons that produced excitatory postsynaptic potentials (EPSPs) in response to microstimulation in areas 1--2 (SI) or in area 5a (SIII) were studied. Amplitudes of EPSPs produced in response to test stimulation (1 Hz) were recorded before and after tetanic stimulation (200 Hz, 20 seconds). In 25/39 cells (64%), EPSP amplitudes were significantly increased following the tetanic stimulation (65 ± 51% average increase), and remained at the potentiated level as long as stable recordings could be maintained (20 ± 18 minutes, maximum = 90 minutes). LTP was induced exclusively in cells that produced monosynpatic EPSPs in response to area 1--2 or area 5a stimulation. Of the 39 analyzed cells, 13 were labeled by intracellular injections of 5% biocytin. Neurons in which LTP was induced included both pyramidal and nonpyramidal cells and were located exclusively in layers II or III of the motor cortex; cells in deeper cortical layers were not potentiated. These findings indicate that various corticocortical inputs can increase the efficacy of synaptic transmission in a subset of motor cortical neurons. We propose that this plasticity in synaptic transmission constitutes one of the bases of motor learning and memory.     

Insular cortex and amygdala lesions differentially affect acquisition on inhibitory avoidance and conditioned taste aversion

These experiments examined the effects of NMDA-induced lesions of the amygdala and insular (gustatory) cortex (IC) on inhibitory avoidance learning and conditioned taste aversion (CTA) in rats. IC lesions, but not amygdala lesions, disrupted CTA. In contrast, lesions of either brain region disrupted inhibitory avoidance learning. These findings support the view that the IC is strongly involved in the acquisition of external as well as visceral aversively motivated behavior. Despite extensive functional interconnections, these 2 brain regions appear to have different roles in mediating different forms of aversively based learning.     

Electrophysiological properties of hippocampal–cortical neural networks,role in the processes of learning and memory in rats

The recording of hippocampal and cortical long-term potentiation (LTP) in rats in vivo is an appropriate and commonly used method to describe changes in cellular mechanisms underlying synaptic plasticity. Recently, we introduced a method for the simultaneous recording of LTP in bilateral CA1 regions and parietal association cortex (PtA), and observed differences between the Schaffer collateral–CA1 pathway (SC), Schaffer collateral/associational commissural pathway (SAC) and Schaffer collateral/associational commissural–cortex pathway (SACC). In this study, we found that (1) synaptic transmission of the SAC and SACC pathways depended on hippocampal commissural fibers [dorsal and ventral hippocampal commissural fibers, the medial septum (MS) and hippocampal CA3 commissural fibers], (2) nerve conduction velocity of the SACC pathway might be higher than that of the SAC pathway, (3) the input/output (I/O) curve of the SC pathway was shifted to the left side, compared to that of the SAC and SACC pathways, (4) all three pathways could induce stable LTP; however, LTP of the SAC and SACC pathways was much stronger than that of the SC pathway, (5) the degree of paired-pulse facilitation (PPF) was weaker in the SC pathway than that in the SAC and SACC pathways, (6) after cutting off the corpus callosum and commissural fibers, spatial learning and memory were impaired, and the ability to explore the novel environment and spontaneous locomotor activity were weakened. Taken together, our results suggested that hippocampal commissural fibers were very important for exchanging information between hemispheres, and basic differences in electrophysiological properties of hippocampal–cortical neural networks play a vital role in the processes of learning and memory.     

Prefrontal infusion of PD098059 immediately after fear extinction training blocks extinction-associated prefrontal synaptic plasticity and decreases prefrontal ERK2 phosphorylation

A previous study has demonstrated that disruption of fear extinction-induced long-term potentiation (LTP) in the medial prefrontal cortex (mPFC) is associated with the return of fear responding. Given that immediate posttraining infusion of PD098059, an inhibitor of extracellular signal-regulated kinase (ERK) mitogen-activated protein kinase (MAPK) cascade, into the mPFC also promotes recovery of fear, we investigated whether impairment of mPFC ERK/MAPK cascade also interferes with development of extinction-related LTP in the mPFC in rats. In Experiment 1, extinction training consisting of repetitive presentations of a tone previously associated with eyelid-shock application induced LTP-like changes at hippocampal inputs to the mPFC that were evident for approximately 2 h following fear extinction. Infusion of PD098059 into the mPFC immediately after extinction training abolished training-related prefrontal LTP and impaired retention of extinction memory tested on the following day. In Experiment 2, immunoblotting assays revealed that posttraining infusion of PD098059 into the mPFC produced a significant reduction of mPFC ERK2. These data, along with previous findings, suggest that low levels of ERK2 phosphorylation in the mPFC may interfere with mechanisms of retention of extinction training. The involvement of mPFC LTP in fear extinction is discussed.     

Effects of inescapable stress on LTP in the amygdala versus the dentate gyrus of freely behaving rats

Stress impairs hippocampal long-term potentiation (LTP), a model of synaptic plasticity that is assumed to underlie memory formation. In the amygdala, little is known about the effects of stress on LTP, or about its longevity. Here we assessed the ability of entorhinal cortex (EC) stimulation to induce LTP simultaneously in the basal amygdaloid nucleus (B) and in the dentate gyrus (DG) of freely behaving Wistar rats. We also tested whether LTP persists over days. Once established, we investigated the effects of acute vs. repeated inescapable stressful experiences on LTP in both structures. Results show that B, like DG, sustained LTP for 7 days. Furthermore, a single exposure to moderate stress facilitated LTP in B but did not affect DG LTP. Stress re-exposure inhibited LTP in DG but only long-lasting LTP (>3 days) in B. Behaviourally, animals exhibited a higher immobility when re-exposed to the stressor than with a single/first exposure. These data support a role for B in memory storage. Furthermore, they support a differential involvement of the amygdala and hippocampus in memory formation and storage depending on the emotional characteristics of the experience.     

Long-term potentiation in the reciprocal corticohippocampal and corticocortical pathways in the chronically implanted, freely moving rat

The hippocampus and adjacent cortical structures, including the entorhinal, perirhinal, and parahippocampal cortices, appear to serve as an integrated memory system. This extended hippocampal system is believed to influence memory and consolidation through an extensive set of reciprocal connections with widespread areas of the neocortex. Long-term potentiation (LTP) has been well-examined in the intrinsic connections of the hippocampus and neocortex. However, LTP in the pathways and structures thought to convey information between the hippocampus and neocortex has received little attention. If these pathways and structures are involved in information storage, and if LTP reflects a general synaptic encoding mechanism, then these systems are also likely to support LTP. In this paper we discuss a series of experiments aimed at investigating LTP in the efferents between the hippocampus and neocortex in chronically implanted animals. In the first experiment, the efferents of the perirhinal cortex were stimulated. LTP in the dentate gyrus (DG) reached asymptote more slowly than is typically seen following perforant path stimulation, whereas the frontal area (M1) reached asymptote more quickly than reported following corticocortical stimulation. The DG and M1 LTP was long-lasting, but entorhinal cortex LTP had decayed to baseline levels after a week. In the second experiment, the hippocampal efferents were stimulated. The perirhinal, entorhinal, and frontal cortex showed a similar slow potentiation, with only the perirhinal cortex levels returning to baseline after a week. In the third experiment, the projections from M1 were tested. The perirhinal cortex and hippocampus showed a long-lasting LTP. Although LTP was found in all pathways examined, there were differences in the induction and decay rate, and these properties may correspond to differences in learning rate and longevity of information storage.     

Long-lasting potentiation of synaptic potentials in the motor cortex produced by stimulation of the sensory cortex in the cat: a basis of motor learning

A long-lasting increase in the efficiency of synaptic transmission in the central nervous system has been thought to be one of the bases of learning and memory. To explore the possibility that the motor cortex (area 4γ) itself is involved in motor learning, the existence of long-term potentiation (LTP) was examined by recording excitatory postsynaptic potentials (EPSPs) from motor cortical neurons. Short tetanic intracortical microstimulation (ICMS) of the somatic sensory cortex produced a marked potentiation of the EPSPs in a small group of motor cortical neurons. The results raised the possibility that the input from the sensory cortex participates in motor learning and retention of the learned motor skills.