Involvement of cerebral cortical structures in the classical conditioning of eyelid responses in rabbits

The classical conditioning of the eyelid motor system in alert behaving rabbits has been used to study the expression of Fos in the hippocampus, and in the occipital, parietal, piriform and temporal cortices. Animals were classically conditioned with both delay and trace conditioning paradigms. As conditioned stimulus, both short and long (20 and 100 ms) tones (600 Hz, 90 dB) or short, weak (20 ms, 1 kg/cm²) air puffs were used. The unconditioned stimulus was always a long, strong (100 ms, 3 kg/cm²) air puff that started 250–270 ms after the onset of the conditioned stimulus. The expression of Fos was significantly increased after both delayed and trace conditioning in the hippocampus, and in the parietal and piriform cortices contralateral to the unconditioned stimulus presentation side, compared with equivalent ipsilateral structures in conditioned animals, or with Fos production in the same contralateral structures in pseudo-conditioned and control animals. Fos expression in some cortical sites was specific to tone versus air puff stimuli when used as conditioned stimulus. Thus, Fos expression was significantly increased in the contralateral temporal lobe when tones were used as conditioned stimulus, for both delayed and trace conditioning paradigms, but not when animals were conditioned to short, weak air puffs.

The present results indicate a specific Fos activation in several cerebral cortical structures during associative eyelid conditioning.     

Unilateral up-regulation of glutamate receptors in limbic regions of amygdaloid-kindled rats

Summary Quantitative autoradiography was used to examine central binding sites for L-[³H]glutamate in amygdaloid-kindled rats since receptors for excitatory amino acids have been implicated in epileptiform activity and seizure behaviors. In tissue from rats killed five days after two kindled seizures, the ipsilateral hippocampus, entorhinal, perirhinal and parietal cortices had significantly (35–100%) greater densities of binding sites for L-[³H]glutamate than the opposite, contralateral side or operated, unstimulated controls. These regions receive excitatory inputs from the amygdala via the entorhinal cortex. Dissociation constants were not altered and significant differences were not observed in the binding parameters for L-[³H]glutamate between control and kindled rats or ipsilateral and contralateral sides of the amygdala, corpus striatum, nucleus accumbens or substantia nigra. The proportion and affinity of N-methylD-aspartate (NMDA)-sensitive binding sites for L-[³H]glutamate was unchanged after kindling, as were the relative proportions of kainate- and AMPA- (DL-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid) sensitive sites. However, the density of NMDA and non-NMDA receptor subtypes was increased in the ipsilateral hippocampus, entorhinal, perirhinal and parietal cortices of kindled rats. These findings of specific, unilateral glutamate receptor up-regulation may indicate adaptive responses to the enhanced excitation found in kindling, and are consistent with other neuronal changes reported in early kindling.     

Cortical afferents of the nucleus accumbens in the cat,studied with anterograde and retrograde transport techniques

The cortical afferentation of the nucleus accumbens in the cat was studied with the aid of retrograde tracing techniques. Retrograde experiments were carried out with horseradish peroxidase or one of the fluorescent tracers Bisbenzimid, Nuclear Yellow and Fast Blue. In the anterograde experiments [³H]leucine and [³⁵S]methionine were used as tracers.Following injections in the nucleus accumbens, retrogradely-labelled cells were found in the medial frontal cortex, the anterior olfactory nucleus, the posterior part of the insular cortex, the endopiriform nucleus, the amygdalo-hippocampal area, the entorhinal and perirhinal cortices and the subiculum of the hippocampal formation. In the medial frontal cortex most of the labelled cells were found in layers III and V of the prelimbic area (area 32 of Brodmann), but retrogradely-filled neurons were also present in the infralimbic area and in the caudoventral part of the lateral bank of the proreal gyrus. Retrogradely-labelled cells in the entorhinal and perirhinal cortices were located in the deep cellular layers. Following large injections in the nucleus accumbens, retrograde labelling in the subiculum extended from the most dorsal, septal pole to the most ventral, temporal pole.Injections of anterograde tracers were placed in the frontal cortex, the entorhinal and perirhinal cortices and the hippocampal formation. The prelimbic area was found to project via the internal capsule to mainly the rostral half of the nucleus accumbens, whereas in the caudal half of the nucleus only a lateral region receives frontal cortical fibres. Following injections in the infralimbic area only fibres passing through the nucleus accumbens were labelled. Afferents from the entorhinal and perirhinal cortices reach the nucleus accumbens by way of the external capsule and terminate mainly in a ventral zone of the nucleus accumbens.Afferents from the entorhinal area are distributed to the entire accumbens, whereas the termination field of the perirhinal afferents is largely restricted to the lateral part of the nucleus accumbens. Both the frontal cortex and the entorhinal and perirhinal cortices appear to project also to the nucleus caudatus and the tuberculum olfactorium. These cortical areas also project to the contralateral striatum.Both anterograde and retrograde tracing experiments demonstrated a topographical relationship between the subiculum and the nucleus accumbens. The ventral pole of the subiculum projects via the fornix to the medial part of the caudal half of the nucleus accumbens and to a small dorsomedial area in its rostral half. Successively more dorsal portions in the subiculum project to successively more ventrolateral parts in the rostral nucleus accumbens. The projection from the hippocampus was found to extend also to the tuberculum olfactorium. The results of the present study do not provide unambiguous criteria for the delimitation of the nucleus accumbens in the cat.     

Carbachol induces fast oscillations in the medial but not in the lateral entorhinal cortex of the isolated guinea pig brain

Fast oscillations at 25-80 Hz (gamma activity) have been proposed to play a role in attention-related mechanisms and synaptic plasticity in cortical structures. Recently, it has been demonstrated that the preservation of the entorhinal cortex is necessary to maintain gamma oscillations in the hippocampus. Because gamma activity can be reproduced in vitro by cholinergic activation, this study examined the characteristics of gamma oscillations induced by arterial perfusion or local intracortical injections of carbachol in the entorhinal cortex of the in vitro isolated guinea pig brain preparation. Shortly after carbachol administration, fast oscillatory activity at 25.2-28.2 Hz was observed in the medial but not in the lateral entorhinal cortex. Such activity was transiently associated with oscillations in the theta range that showed a variable pattern of distribution in the entorhinal cortex. No oscillatory activity was observed when carbachol was injected in the lateral entorhinal cortex. Gamma activity in the medial entorhinal cortex showed a phase reversal at 200-400 microm, had maximal amplitude at 400-500 microm depth, and was abolished by arterial perfusion of atropine (5 microM). Local carbachol application in the medial entorhinal cortex induced gamma oscillations in the hippocampus, whereas no oscillations were observed in the amygdala and in the piriform, periamygdaloid, and perirhinal cortices ipsilateral and contralateral to the carbachol injection. Hippocampal oscillations had higher frequency than the gamma activity recorded in the entorhinal cortex, suggesting the presence of independent generators in the two structures. The selective ability of the medial but not the lateral entorhinal cortex to generate gamma activity in response to cholinergic activation suggests a differential mode of signal processing in entorhinal cortex subregions.     

Interaction between amygdala and neocortical inputs in the perirhinal cortex

The rhinal cortices play a critical role in high-order perceptual/mnemonic functions and constitute the main route for impulse traffic to and from the hippocampus. However, previous work has revealed that neocortical stimuli that activate a large proportion of perirhinal neurons are unable to discharge entorhinal cells. In search of mechanisms that might facilitate impulse transfer from the neocortex to the entorhinal cortex, we have examined changes in excitability produced by activation of the lateral amygdala (LA) in isoflurane-anesthetized animals. LA stimulation activated a large proportion of peri- and entorhinal neurons. However, conditioning LA stimuli did not increase the ability of neocortical inputs to activate entorhinal cells even though such pairing produced marked increases in neocortically evoked field potentials and orthodromic firing in the perirhinal cortex. Moreover, increased neocortically evoked perirhinal field potentials and unit responses persisted when the conditioning LA shock was replaced by another neocortical stimulus at the same or at a different site as the testing shock. This perirhinal paired-pulse facilitation (PPF) was maximal with interstimulus intervals of approximately 100 ms. Intracellular recordings of perirhinal neurons revealed that the PPF was generally associated with a rapid shift in the balance between inhibition and excitation, leading to an overall increase in perirhinal responsiveness. The significance of these findings for the role of the perirhinal cortex is discussed.     

Synaptic replacement in the dentate gyrus after unilateral entorhinal lesion: electron microscopic analysis of the extent of replacement of synapses by the remaining entorhinal cortex

Summary In response to a unilateral entorhinal lesion the input from the contralateral entorhinal cortex to the dentate gyrus appears to increase. We have studied this crossed projection by electron microscopy in normal animals and in animals one year or more after a unilateral entorhinal lesion. In normal animals few degenerating boutons are found after a contralateral entorhinal lesion. However, when the contralateral lesion was made one year after an ipsilateral entorhinal lesion, degenerating boutons were readily identified. The boutons were relatively few in number, but formed an abnormally large number of synaptic contacts. These results support the previous conclusion that fibres from the contralateral entorhinal cortex form additional synapses when their ipsilateral homologues are removed. However, these new cortical synapses probably account for only a small portion of those formed in response to the lesion. Thus an anatomically homologous input does not, in this case, selectively capture most of the newly available synaptic sites.     

Electrophysiological analysis of the hippocampal projections to the entorhinal area

Responses evoked in the entorhinal area by impulse volleys originating in the ipsilateral hippocampus were analysed in the guinea-pig by means of field potential analysis. Perforant path volleys, synaptically elicited by stimulation of the dorsal psalterium of one side, were used to activate the hippocampal lamellar circuit of the same side and, through interhippocampal impulses, the hippocampal pyramidal neurons of the contralateral side. Discharge of the hippocampal pyramidal neurons was followed by a response, a fast negative deflection preceded and followed by slow waves, in the dorsal third of the ipsilateral entorhinal area. Laminar distribution of the fast negative deflection and of the time-locked unit activity suggested that excitatory synaptic effects followed by neuron discharge were generated in neurons of layers VI-II of the entorhinal area. The increasing latency of the fast negative deflection and of unit firing over the cortical depth suggested that these synaptic effects were generated in temporal sequence, going from layer VI to layer II. The entorhinal response disappeared after a lesion at the caudal border of the hippocampus interrupting the caudally-directed hippocampal efferents. The anatomy of the hippocampal and subicular projections to the entorhinal area in the guinea-pig, together with electrophysiological data obtained in recordings from the ipsilateral subiculum, suggested that the hippocampal impulses were relayed to layers VI-V of the entorhinal area by the subiculum. The delayed activation of layers IV-II was possibly mediated by intracortical connections. Double-shock experiments showed that impulses of hippocampal origin inhibited the response to dorsal psalterium volleys of entorhinal neurons giving origin to perforant path fibers. The data show that the hippocampal output activates the deep layers of the entorhinal area from which it is possibly relayed to numerous cortical and subcortical regions. Moreover, the inhibitory effects exerted on neurons originating perforant path fibers give evidence of a negative feedback control system operating in the hippocampal region.     

Colchicine-induced lesion of rat hippocampal granular cells prevents conditioned active avoidance with perforant path stimulation as conditioned stimulus, but not conditioned emotion

Successful acquisition of active avoidance by rats with low frequency (15 cps) stimulation of the perforant path as a conditioning stimulus is correlated with a slowly developing long-term enhancement of perforant path-granular cell synapses. After selective destruction of granular cells of the stimulated side by unilateral microinjection of 1.6 micrograms/0.2 microliter colchicine into the dentate area, field potentials could no longer be evoked by test stimuli and animals subsequently failed to acquire the conditioned active avoidance with perforant path stimulation as a CS. However, colchicine-treated animals showed the same development of conditioned emotional responses as saline controls and they could also successfully be conditioned with light and tone as the CS. These results suggest that the granular cells are necessarily involved in the conditioning pathway for the active avoidance with perforant path stimulation as the CS. Other targets of the perforant path, e.g., ipsi- and contralateral CA1 pyramidal cells and contralateral granular cells, or antidromic activation of the entorhinal cortex seem an insufficient substitute for granular cells in the pathway for this conditioned active avoidance, but would probably participate in the conditioned emotional responses. The results additionally support our hypothesis, that post-conditioning LTP in granular cell synapses contribute to the acquisition and/or the storage of a memory trace.     

Emotional enhancement of memory via amygdala-driven facilitation of rhinal interactions

Emotions generally facilitate memory, an effect mediated by the basolateral amygdala (BLA). To study the underlying mechanisms, we recorded BLA, perirhinal and entorhinal neurons during an appetitive trace-conditioning task. We focused on the rhinal cortices because they constitute the interface between the hippocampus, a mediator of memory consolidation, and the neocortex, the storage site of declarative memories. We found that, after unexpected rewards, BLA activity increased impulse transmission from perirhinal to entorhinal neurons and that this effect decayed as the association between conditioned stimuli and rewards was learned. At this late phase of learning, the BLA effect occurred when the animals were anticipating the reward. By enhancing the processing of sensory cues, the BLA-mediated facilitation of rhinal interactions may explain how the amygdala promotes memory formation in emotional conditions.     

The topographic order of inputs to nucleus accumbens in the rat

Afferents to the nucleus accumbens have been studied with the retrograde transport of unconjugated wheatgerm agglutinin as detected by immunohistochemistry using the peroxidase-antiperoxidase method, in order to define precisely afferent topography from the cortex, thalamus, midbrain and amygdala. Cortical afferent topography was extremely precise. The largest number of cells was found following injections to the anterior accumbens. Anteromedial injections labelled a very large extent of the subiculum and part of the entorhinal cortex. Anterolateral injections produced less subicular and entorhinal label but also labelled the posterior perirhinal cortex. Posteromedial injections labelled only the ventral subiculum and a few cells in the adjacent medial entorhinal cortex. Posterolateral injections labelled few lateral entorhinal neurones but did label a long anteroposterior strip of perirhinal cortex. Prefrontal cortex label was found only after anterior accumbens injections. In the amygdala labelled neurones were found in cortical, central, lateral posterior, anteromedial and basolateral nuclei. Basolateral amygdala projected chiefly to the anteromedial accumbens and central nucleus to anterolateral accumbens. Only a weak amygdala label was found after posterior accumbens injections. In the ventral tegmental area, the midline interfascicular nucleus projected only to medial accumbens. The paranigral ventral tegmentum projected chiefly to the medial accumbens and the parabrachial area chiefly to the lateral accumbens. In the thalamus, heaviest label was found after anterior accumbens injections. Most cells were found in the paraventricular, reuniens and rhomboid nuclei and at posterior thalamic levels lying medial to the fasciculus retroflexus. There was only restricted topography found from thalamic sites. Retrograde label was also found in the ventral pallidum and lateral hypothalamus. Single small injection sites within accumbens received input from the whole anteroposterior extent of the thalamus and ventral tegmentum. The medial accumbens was found to have a close relationship to habenula, globus pallidus and interfascicular nucleus. It appeared that the heaviest volume of inputs projected to anteromedial accumbens, where output from hippocampus (CAI), subiculum, entorhinal and prefrontal cortices converged with output from amygdala, midline thalamus and ventral tegmentum.     

Acquisition of a novel behavior induces higher levels of Arc mRNA than does overtrained performance

Arc (also termed activity-regulated cytoskeleton-associated protein or Arg3.1), is an effector immediate early gene whose upregulation has been demonstrated during events of synaptic plasticity. In the present study, the possibility that Arc would be specifically upregulated in rats during the acquisition of a quickly learned behavioral task but not in overtrained animals was investigated. Three groups of rats, pseudotrained, newly trained and overtrained, were examined with respect to Arc expression following training on a simple operant lever-pressing task. Newly trained animals were killed 30 min following the session in which they demonstrated acquisition of the task, and overtrained animals were trained on the same task for 13–14 days and then killed. Relative to base level measures taken 6 h following the session, all three groups demonstrated significant levels of induction of Arc mRNA; however, newly trained animals exhibited heightened induction of Arc mRNA relative to both pseudotrained and overtrained animals. The increased levels of Arc mRNA in newly trained animals were located in the CA1 and CA3 fields of hippocampus, the subiculum, and the anterior cingulate, piriform, infra/prelimbic, perirhinal and entorhinal cortical areas. Additionally, Arc mRNA was expressed differentially across the above anatomic structures in a relative pattern that was the same in all three groups. Finally, levels of Arc mRNA in specific brain regions of newly trained animals correlated negatively with the rate of task acquisition, such that slow learners exhibited higher levels of Arc mRNA than fast learners.

From these results we suggest that Arc is upregulated in an experience-dependent manner, with higher levels of induction occurring during the initial stage of learning. Furthermore, the finding of increased Arc levels in slow versus fast learners indicates that Arc expression may be associated with the length of time required to: (1) form new associations or (2) remodel existing connections. These results confirm other reports that Arc is a critical substrate for the synaptic plasticity underlying the acquisition of new behaviors.     

Differential contribution of some cortical sites to the formation of memory traces supporting fear conditioning

The aim of the present work was to assess the role of some cortical sites of the rat (the prefrontal, PFC, frontal, FC, parietal, PAC, and perirhinal, PC, cortices) in the acquisition of classical fear conditioning (CS and context conditioned freezing). Using the reversible ablation technique the sites were inactivated with lidocaine (LIDO), administered before the one-trial training session. The freezing response, taken as memorization index, was measured in conditions of full functional recovery after the short reversible LIDO inactivation either 3 h ("short-term" memory) and/or 72 h ("long-term" memory) later, so as to follow the temporal dimension of mnemonic elaboration. The results of the inactivations performed during the training session show that PFC, FC, PAC and PC play contemporaneous but distinct roles in the memorization of aversive responses to CS and context. PC inactivation weakened the retention of both mnemonic traces at the 3-h delay. At the same delay FC and PAC inactivation weakened only freezing to acoustic CS while PFC inactivation improved the retention of both traces. Inactivation of all four sites was followed by significant amnesia for both traces at the 72-h after-acquisition delay. The present findings show that PFC, FC, PAC and PC reversible inactivation during the acquisition training session diversely interferes with the memorization of conditioned freezing to acoustic CS and context. Moreover, the different results obtained at the two different retention intervals support the hypothesis that "short-term" and "long-term" memories are not necessarily linked, the earlier one not always influencing the subsequent one.     

Neither perirhinal/entorhinal nor hippocampal lesions impair short-term auditory recognition memory in dogs.

Visual, tactile, and olfactory recognition memory in animals is mediated in part by the perirhinal/entorhinal (or rhinal) cortices and, possibly, the hippocampus. To examine the role of these structures in auditory memory, we performed rhinal, hippocampal, and combined lesions in groups of dogs trained in auditory delayed matching-to-sample with trial-unique sounds. The sample sound was presented through a central speaker and, after a delay, the sample sound and a different sound were played alternately through speakers placed on either side of the animal; the animal was rewarded for responding to the side emitting the sample sound. None of the lesion groups showed significant impairment in comparison either to their own preoperative performance or to the performance of intact control dogs. This was the case both for relearning the delayed matching rule at a delay of 1.5 s and for task performance at variable delays ranging from 10 to 90 s.From these findings we suggest that the tissue critical for auditory recognition memory is located outside both the perirhinal/entorhinal cortices and the hippocampus.     

Low-probability transmission of neocortical and entorhinal impulses through the perirhinal cortex

One model of episodic memory posits that during slow-wave sleep (SWS), the synchronized discharges of hippocampal neurons in relation to sharp waves "replay" activity patterns that occurred during the waking state, facilitating synaptic plasticity in the neocortex. Although evidence of replay was found in the hippocampus in relation to sharp waves, it was never shown that this activity reached the neocortex. Instead, it was assumed that the rhinal cortices faithfully transmit information from the hippocampus to the neocortex and reciprocally. Here, we tested this idea using 3 different approaches. 1) Stimulating electrodes were inserted in the entorhinal cortex and temporal neocortex and evoked unit responses were recorded in between them, in the intervening rhinal cortices. In these conditions, impulse transfer occurred with an extremely low probability, in both directions. 2) To rule out the possibility that this unreliable transmission resulted from the artificial nature of electrical stimuli, crosscorrelation analyses of spontaneous neocortical, perirhinal, and entorhinal firing were performed in unanesthetized animals during the states of waking and SWS. Again, little evidence of propagation could be obtained in either state. 3) To test the idea that propagation occurs only when large groups of neurons are activated within a narrow time window, we computed perievent histograms of neocortical, perirhinal, and entorhinal neuronal discharges around large-amplitude sharp waves. However, these synchronized entorhinal discharges also failed to propagate across the perirhinal cortex. These findings suggest that the rhinal cortices are more than a relay between the neocortex and hippocampus, but rather a gate whose properties remain to be identified.     

Changes in immediate early gene expression in the rat brain after unilateral lesions of the hippocampus

Activity of the immediate early genes c-fos and zif268 was compared across hemispheres in rats with unilateral, excitotoxic lesions of the hippocampus (dentate gyrus and CA fields 1-4). Counts of the protein products of these genes were made shortly after rats performed a test of spatial working memory in the radial-arm maze, a task that is sensitive to bilateral lesions of the hippocampus. Unilateral hippocampal lesions produced evidence of widespread hypoactivity. Significant reductions in immediate early gene counts were observed within all three anterior thalamic nuclei, as well as the entorhinal, perirhinal, and postrhinal cortices, and much of the subicular complex. In contrast, no observable changes were detected in the anterior cingulate, infralimbic or prelimbic cortices, as well as several amygdala nuclei, even though many of these regions receive projections from the subiculum. Instead, the immediate early gene changes were closely linked to sites that are thought to be required for successful task performance, with both immediate early genes giving similar patterns of results. The findings support the notion that the anterior thalamic nuclei, hippocampus, and parahippocampal cortices form the key components of an interdependent neuronal network involved in spatial mnemonic processing.     

Differential induction of c-Fos, c-Jun and Jun B in the rat central nervous system following unilateral entorhinal cortex lesion

In order to identify some of the molecular mechanisms that occur after a central nervous system trauma, the immediate early gene encoded proteins c-Fos, c-Jun and Jun B were analysed by immunocytochemistry following unilateral entorhinal cortex lesion (controls, 30 min, 2, 5, 12 and 24 h, two, six, 10 and 14 days, four weeks and six months postlesion). In the dentate gyrus, c-Fos was induced in some supragranular neurons (30 min), massively expressed in granule cells ipsilaterally to the lesion (2 h), expressed in hilar neurons (5 h and two days) and was absent at all later stages. A basal expression of c-Jun was found in dentate granule cells of controls, which was strongly increased on the lesion side (2 h) and on the side contralateral to the lesion (12 h). c-Jun expression returned to control levels by 24 h. Jun B was induced in granule cells ipsilateral to the lesion within 2 h and was back to control levels by 5 h. In the lateral septal area, c-Fos and c-Jun were induced 30 min postlesion and decreased rapidly thereafter. In the cerebral cortex, a widespread induction of c-Fos and c-Jun occurred within 30 min after entorhinal cortex lesion and this up-regulation lasted until two days postlesion. These data indicate that electrolytic lesion of the entorhinal cortex leads to a rapid and widespread induction of c-Fos, c-Jun and Jun B. Within the denervated fascia dentata, some of these changes may be linked to the reorganization processes following the lesion. Alternatively, the alterations in immediate early gene expression reported here may be due to changes in synaptic activity or postlesional seizures which occur in this lesioning paradigm.     

Unconditioned stimulus pathways to the amygdala: effects of lesions of the posterior intralaminar thalamus on foot-shock-induced c-Fos expression in the subdivisions of the lateral amygdala

The lateral nucleus of the amygdala (LA) is a site of convergence for auditory (conditioned stimulus) and foot-shock (unconditioned stimulus) inputs during fear conditioning. The auditory pathways to LA are well characterized, but less is known about the pathways through which foot shock is transmitted. Anatomical tracing and physiological recording studies suggest that the posterior intralaminar thalamic nucleus, which projects to LA, receives both auditory and somatosensory inputs. In the present study we examined the expression of the immediate-early gene c-fos in the LA in rats in response to foot-shock stimulation. We then determined the effects of posterior intralaminar thalamic lesions on foot-shock-induced c-Fos expression in the LA. Foot-shock stimulation led to an increase in the density of c-Fos-positive cells in all LA subnuclei in comparison to controls exposed to the conditioning box but not shocked. However, some differences among the dorsolateral, ventrolateral and ventromedial subnuclei were observed. The ventrolateral subnucleus showed a homogeneous activation throughout its antero-posterior extension. In contrast, only the rostral aspect of the ventromedial subnucleus and the central aspect of the dorsolateral subnucleus showed a significant increment in c-Fos expression. The density of c-Fos-labeled cells in all LA subnuclei was also increased in animals placed in the box in comparison to untreated animals. Unilateral electrolytic lesions of the posterior intralaminar thalamic nucleus and the medial division of the medial geniculate body reduced foot-shock-induced c-Fos activation in the LA ipsilateral to the lesion. The number of c-Fos labeled cells on the lesioned side was reduced to the levels observed in the animals exposed only to the box. These results indicate that the LA is involved in processing information about the foot-shock unconditioned stimulus and receives this kind of somatosensory information from the posterior intralaminar thalamic nucleus and the medial division of the medial geniculate body.     

Induction of cyclooxygenase-2 mRNA and protein following transient focal ischemia in the rat brain

Expression of cyclooxygenase-2 (cox-2) mRNA and inducible heat-shock protein-70 (hsp-70) mRNA was studied with in situ hybridization techniques at 30 min and 4 h following 1 h transient middle cerebral artery (MCA) occlusion in the rat brain. In addition, immunoreactivity for cox-2 was studied after 8 h of reperfusion. Induction of hsp-70 and cox-2 mRNA was found in the brain side ipsilateral to MCA occlusion. Hsp-70 mRNA was induced in the parietal cortex and striatum within the territory of the occluded MCA. Induction of cox-2 mRNA was particularly seen in cortical layer II in the brain side ipsilateral to MCA occlusion. At 30 min of reperfusion, areas showing cox-2 mRNA induction included the cingulate and frontal cortices located perifocally to the areas showing hsp-70 mRNA induction, and the piriform cortex. At 4 h of reperfusion, induction of cox-2 mRNA was seen within the parietal cortex. At 8 h of reperfusion, immunoreactivity for cox-2 was mainly seen in the ipsilateral cortex. These results demonstrate that transient focal ischemia induces the expression of cox-2 mRNA and protein in discrete areas of the rat brain during reperfusion, which might lead to local increases of arachidonic acid metabolism     

Initiation of electrographic seizures by neuronal networks in entorhinal and perirhinal cortices in vitro

The hippocampus is often considered to play a major role in the pathophysiology of mesial temporal lobe epilepsy. However, emerging clinical and experimental evidence suggests that parahippocampal areas may contribute to a greater extent to limbic seizure initiation, and perhaps epileptogenesis. To date, little is known about the participation of entorhinal and perirhinal networks to epileptiform synchronization. Here, we addressed this issue by using simultaneous field potential recordings in horizontal rat brain slices containing interconnected limbic structures that included the hippocampus proper. Epileptiform discharges were disclosed by bath applying the convulsant drug 4-aminopyridine (50 microM) or by superfusing Mg(2+)-free medium. In the presence of 4-aminopyridine, slow interictal- (duration=2.34+/-0.29 s; interval of occurrence=25.75+/-2.11 s, n=16) and ictal-like (duration=31.25+/-3.34 s; interval of occurrence=196.96+/-21.56 s, n=17) discharges were recorded in entorhinal and perirhinal cortices after abating the propagation of CA3-driven interictal activity to these areas following extended hippocampal knife cuts. Simultaneous recordings obtained from the medial and lateral entorhinal cortex, and from the perirhinal cortex revealed that interictal and ictal discharges could initiate from any of these areas and propagate to the neighboring structure with delays of 8-66 ms. However, slow interictal- and ictal-like events more often originated in the medial entorhinal cortex and perirhinal cortex, respectively. Cutting the connections between entorhinal and perirhinal cortices (n=10), or functional inactivation of cortical areas by local application of a glutamatergic receptor antagonist (n=11) made independent epileptiform activity occur in all areas. These procedures also shortened ictal discharge duration in the entorhinal cortices, but not in the perirhinal area. Similar results could be obtained by applying Mg(2+)-free medium (n=7). These findings indicate that parahippocampal networks provide independent epileptiform synchronization sufficient to sustain limbic seizures as well as that the perirhinal cortex plays a preferential role in in vitro ictogenesis.