The exploration of a new environment leads to the modulation of gene expression for prolonged times in the rat.

In the present study we performed a transcriptional analysis in order to evaluate changes in gene expression induced by exploration in prolonged times. The analysis was carried out 3, 10 and 20 days after exploration. We analyzed the modulation of the expression levels of Pfn2, Casp3, Pdrg1, Pea15, Ywhaz genes which previously were found not modulated 2 days after exploration. Our data show that the expression of Pfn2, Casp3, Pdrg1, Pea15, Ywhaz genes was modulated at 10 or 20 days. The transcript, whose expression had been evaluated with the qRT-PCR, code for proteins which belong to the following functional categories: synaptic modulation, apoptosis, signal transduction. It is interesting to note that the modulation of the expression of these genes was evident some days after environmental exploration, and not previously at 2 days after conditioning as occurred after contextual fear conditioning (CFC). Hence it is possible to hypothesize that the spatial memory processes require a longer period of elaboration than the emotional ones, fundamental for the survival of the species.

Vitamin D receptor expression and acid sphingomyelinase activity in prefrontal region of a learning animal model.

Contextual fear conditioning (CFC) paradigm is routinely used to study fear-based learning in animals and it provides a useful model for understanding fear and anxiety in human. In the present study, such model was used following the previously established CFC protocol, and immunohistochemistry, enzymatic activity and western blotting analysis approaches were used to identify the expression of acid sphingomyelinase (aSMase) and vitamin D receptor (VDR) in prefrontal region brain of rat. Results revealed an increase of aSMase activity in conditioned rats, suggesting an apoptotic condition in such animals. In addition, an increase of density and organization of axonal neurofilaments and of VDR expression has been observed in brain of conditioned rats, supporting an induction of growth and organization of new neurons in prefrontal regions, whose contribution to various aspects of contextual fear learning is still largely unknown.

Contextual fear conditioning modulates the gene expression over time.

Contextual fear conditioning (CFC) is a quick cognitive test based on the association context-aversive stimulus in which a single training leads to a long-term memory. Previously, we showed that 2 days after conditioning the expression of the genes Napa, Pnf2, Casp3, Pdrg1, Ywhaz, Stmn1, Bpgm, were positively modulated in CFC rats respect to naïve rats, explor rats which had freely explored the experimental apparatus and SO rats to which the same number of aversive shocks used in CFC paradigm had been administered in the same CFC apparatus in less time to prevent the association between painful stimuli and apparatus, whereas the genes Actr3, Pea15 and Tiprl were more expressed in SO rats and Cplx1, Trim32 and Ran genes were more expressed in explor rats. At 2 days, Tomm20 gene expression resulted positively modulated in both CFC and explor rats. Herein, we have tested the expression of these genes for a period longer than 2 days, by monitoring the modulation of transcripts within 20 days after conditioning. The expression of the transcripts was assessed by qRT-PCR.We found that three days after CFC only the genes Tiprl and Trim32 were positively modulated in CFC rats whereas the gene Tomm20 was negatively modulated in CFC rats as well as in SO and explor rats. Ten days after CFC, the expression of Trim32 was still positively modulated whereas the genes Tiprl and Tomm20 returned to the constitutive level, and the gene Ran was significantly more expressed in CFC rats than in naïve, SO and explor rats. Interestingly, 20 days after CFC, the genes Stmn1 and Tiprl again became significantly more expressed in CFC rats compared with naïve, SO and explor rats.

DM235 (sunifiram): a novel nootropic with potential as a cognitive enhancer.

DM235 (sunifiram), a new compound structurally related to piracetam, prevented the amnesia induced by scopolamine (1.5 mg kg(-1) i.p.), after intraperitoneal (0.001-0.1 mg kg(-1)) or oral (0.01-0.1 mg kg(-1)) administration, as shown by a passive avoidance test in mice. The antiamnesic effect of DM235 was comparable to that of well-known nootropic drugs such as piracetam (30-100 mg kg(-1) i.p.), aniracetam (100 mg kg(-1) p.o.) or rolipram (30 mg kg(-1) p.o.). DM235 also prevented mecamylamine (20 mg kg(-1) i.p.)-, baclofen (2 mg kg(-1) i.p.)- and clonidine (0.125 mg kg(-1) i.p.)-induced amnesia in the same test. In the Morris water maze test with rats, scopolamine (0.8 mg kg(-1) i.p.) inhibited the reduction of escape latency in both acquisition and retention/retraining tests. DM235 (0.1 mg kg(-1) i.p.), 20 min before each daily acquisition training, prevented the scopolamine-induced memory impairment. DM235 (1 mg kg(-1) i.p.) also reduced the duration of pentobarbitone-induced hypnosis in mice without modifying the induction time of hypnosis. At the highest effective doses, the investigated compound neither impaired motor coordination (rota-rod test), nor modified spontaneous motility and inspection activity (Animex and hole board tests). These results indicate that DM235, a compound structurally related to piracetam, is a novel nootropic endowed with the capability to prevent cognitive deficits at very low doses. Indeed, its potency is about 1,000 times higher than that of the most active piracetam-like compounds.

Histamine H3 receptor-mediated impairment of contextual fear conditioning and in-vivo inhibition of cholinergic transmission in the rat basolateral amygdala.

We investigated the effects of agents acting at histamine receptors on both, spontaneous release of ACh from the basolateral amygdala (BLA) of freely moving rats, and fear conditioning. Extensive evidence suggests that the effects of histamine on cognition might be explained by the modulation of cholinergic systems. Using the microdialysis technique in freely moving rats, we demonstrated that perfusion of the BLA with histaminergic compounds modulates the spontaneous release of ACh. The addition of 100 mm KCl to the perfusion medium strongly stimulated ACh release, whereas, 0.5 microm tetrodotoxin (TTX) inhibited spontaneous ACh release by more than 50%. Histaminergic H3 antagonists (ciproxifan, clobenpropit and thioperamide), directly administered to the BLA, decreased ACh spontaneous release, an effect fully antagonized by the simultaneous perfusion of the BLA with cimetidine, an H2 antagonist. Local administration of cimetidine alone increased ACh spontaneous release slightly, but significantly. Conversely, the administration of H1 antagonists failed to alter ACh spontaneous release. Rats receiving intra-BLA, bilateral injections of the H3 antagonists at doses similar to those inhibiting ACh spontaneous release, immediately after contextual fear conditioning, showed memory consolidation impairment of contextual fear conditioning. Post-training, bilateral injections of 50 microg scopolamine also had an adverse effect on memory retention. These observations provide the first evidence that histamine receptors are involved in the modulation of cholinergic tone in the amygdala and in the consolidation of fear conditioning.

Pituitary adenylate cyclase-activating polypeptide hormone (PACAP) at very low dosages improves memory in the rat.

To ascertain whether very low dosages of pituitary adenylate cyclase-activating polypeptide (PACAP) influence learning in mammals, immediately after the acquisition trial of a passive avoidance response (PAR) paradigm, PACAP-38 was administered intracerebroventricularly at increasing dosages (0, 0.02, 0.2, 2, 20, and 200 ng in 10 microl saline) to different groups of rats. The mnemonic effects were measured by means of retention testing 48 and 96 h later. At intermediate PACAP-38 concentrations there was a significant mnemonic improvement of the PAR. The maximal effect was observed after the 0.2-ng PACAP-38 administration (longer step-through latencies). There was a lesser effect at the subsequent higher concentration, 2 ng. Higher dosages had no effects. It is concluded that PACAP-38 acts as an enhancer of mammalian mnemonic processes even at very low dosages. The positive effect follows an inverted U-shaped dose-response curve. The results may be of interest for the therapy of some neuropathological conditions.

Long-lasting hippocampal potentiation and contextual memory consolidation.

In order to ascertain whether there are hippocampal electrophysiological modifications specifically related to memory, exploratory activity and emotional stress, extracellular electrical activity was recorded in hippocampal slices prepared from the brains of male adult rats. Several groups of animals were employed: (i) rats which had freely explored the experimental apparatus (8 min exposure); (ii) rats which had been subjected, in the same apparatus, to a fear conditioning paradigm training entailing the administration of aversive electrical footshocks (8 min exposure); (iii) rats to which the same number of aversive shocks had been administered in the same apparatus, but temporally compressed so as to make difficult the association between painful stimuli and the apparatus (30 s exposure); (iv) naïve rats never placed in the apparatus. Half of the rats from each treatment group were used for retrieval testing and the other half for hippocampal excitability testing. The conditioned freezing response was exhibited for no less than 4 weeks. Hippocampal excitability was measured by means of input-output curves (IOC) and paired-pulse facilitation curves (PPF). Retrieval testing or brain slices preparation were performed at increasing delays after the training sessions: immediately afterwards or after 1, 7 or 28 days. Only the rats subjected to the fear conditioning training exhibited freezing when placed again in the apparatus (retrieval testing). It was found that IOCs, with respect to naïve rats, increased in the conditioned animals up to the 7-day delay. In free exploration animals the IOCs increased only immediately after the training session. In all other rats no modification of the curves was observed. IOC increases do not appear to imply presynaptic transmitter release modifications, because they were not accompanied by PPF modifications. In conclusion, a clear-cut correlation was found between the increase in excitability of the Schaffer collateral-CA1 dendrite synapses and freezing response consolidation.

Role of the perirhinal cortex in rats' conditioned taste aversion response memorization.

The role of the perirhinal cortex (PC) in conditioned taste aversion (CTA) learning was investigated in Long Evans rats. CTA was induced by the intraperitoneal administration of LiCl 60 min after saccharin-sweetened water drinking. The PC was reversibly inactivated by the stereotaxic administration of tetrodotoxin (TTX) 60 min before saccharin drinking, immediately after saccharin drinking (Experiment 1), 6 or 24 hr after LiCl administration (Experiment 2), and 60 min before CTA retrieval testing (Experiment 3). Only pre-saccharin drinking PC inactivation disrupted CTA. Thus, PC integrity is necessary only during the earliest phases of CTA mnemonic processing, that is, taste information acquisition and early gustatory memory elaboration. The results are discussed in relation to PC connectivity and PC temporal involvement in the memorization process of other aversive responses.

Effects of coupled perirhinal cortex and medial septal area, fimbria-fornix, entorhinal cortex tetrodotoxin inactivations on passive avoidance consolidation in the rat.

In order to ascertain the rat perirhinal cortex (PC) function during early consolidation of a passive avoidance response (PAR), and to ascertain whether there are some functional interactions with the medial septal area (MSA), the fimbria-fornix complex (FF) and the entorhinal cortex (EC), PC-MSA, PC-FF, and PC-EC coupled inactivations were performed immediately after the PAR acquisition session. Anesthetized male adult Wistar rats aged 60 days were treated with stereotaxical bilateral injections of TTX (5 ng in 0.5 microl saline) in the appropriate sites. Retrieval testing was performed 48 h later. It was shown that all three coupled inactivations were followed by significant PAR disruption. It may be concluded that PC is somehow active even during the first mnemonic phase following the acquisition session, thus better defining PC mnemonic involvement chronology. These results may be taken as indicating that during initial consolidation the engram is concurrently processed in more than one septal and parahippocampal site, each of which by itself is not absolutely necessary for the final engram formation.

Auditory thalamus, dorsal hippocampus, basolateral amygdala, and perirhinal cortex role in the consolidation of conditioned freezing to context and to acoustic conditioned stimulus in the rat.

On the basis of previous experimental evidence, it is known that the auditory thalamus (AT), the dorsal hippocampus (DH), the basolateral amygdala (BLA), and the perirhinal cortex (PC) are involved in the mnemonic processing of conditioned freezing. In particular, BLA and PC appear to be involved both in conditioned stimulus (CS) and context conditioned freezing. Through AT, the auditory CS is sent to other sites, whereas DH is involved in context conditioning. Nevertheless, the existing evidence does not make it possible to assess AT, DH, BLA, and PC involvement during the consolidation phase of conditioned freezing. To address this question, fully reversible tetrodotoxin (TTX) inactivation was performed on adult male Wistar rats having undergone CS and context fear training. Anesthetized animals were injected stereotaxically with TTX (either 5 or 10 ng in 0.5 or 1.0 microliter of saline, according to site dimensions) at increasing post-acquisition delays. Context and CS freezing durations were measured during retention testing, always performed 48 and 72 hr after TTX administration. The results showed that AT inactivation does not disrupt consolidation of either contextual or auditory fear memories. In contrast, inactivation of the other three structures disrupted consolidation. For the DH, this disruption was specific to contextual cues and only occurred when inactivation was performed early (up to 1.5 hr) after training. The BLA and PC were shown to be involved in the consolidation of both contextual and auditory fear. Their involvement persisted for longer periods of time (2d for BLA and 8 d for PC). These findings provide information to build a temporal profile for the post-training processing of fear memories in structures known to be important for this form of learning. The results are discussed in relation to previous studies on conditioned freezing and other aversive conditioned response neural correlates.

Memorization of contextual and CS conditioned fear response (freezing) in a one-trial acquisition paradigm.

In fear-conditioned Wistar rats freezing was induced by the delivery of a series of footshocks paired to tones (CS) in a specific conditioning chamber (context). CS and contextual fear were acquired in the same single conditioning session without preexposition to the conditioning chamber (day 1). Different groups of animals were conditioned employing three increasing US (footshock) intensities (0.25, 0.5, 0.75 mA). During the retention sessions context and CS conditioned freezing (fear response) were measured using a paradigm that fulfilled the following conditions: i) CS freezing retention was measured in a context different from the conditioning one; ii) CS and context freezing were measured at increased delays after the training session (days 3 and 4, 14 and 15, 28 and 29). The results show that there are significant differences between CS and context freezing retention, which are clearly related to delay after the initial session and to US intensity. In particular: 1) conditioned freezing to a discrete tone is better retained than conditioned freezing to context (irrespective of US intensity); 2) context freezing is directly related to US intensity much more than to tone freezing; 3) context freezing is easier to extinguish than tone freezing. The results are discussed in relation to previous ones and to their relevance to freezing genesis neural correlates.

Effects of combined medial septal area, fimbria-fornix and entorhinal cortex tetrodotoxin inactivations on passive avoidance response consolidation in the rat.

On the basis of previous experimental evidence, it has been concluded that the entorhinal cortex (EC), the fimbria-fornix (FF) complex and medial septal area (MSA) do not take part in the consolidation phase of passive avoidance response (PAR) memorization. On the other hand, a mnemonic role during consolidation of at least two of these structures has been argued, based on several considerations. In order to ascertain whether the EC and FF are still involved in PAR memorization during consolidation, the coupled fully reversible functional tetrodotoxin (TTX) inactivation of MSA, FF and EC was performed in rats having undergone a PAR training. In Experiment 1 MSA, FF and EC were inactivated pair-wise (FF and EC always bilaterally). Permanently cannulated animals were injected stereotaxically with TTX (5 ng in 0.5 microliter saline) or saline (0.5 microliter) immediately following PAR acquisition. It was shown that combined FF-EC inactivation induced PAR retention impairment, whereas FF-MSA and EC-MSA inactivation was not followed by amnesic effects. Having obtained a positive result, in Experiment 2 the combined FF-EC inactivation was performed at different post-acquisition delays (0.25 h, 1.5 h, 6 h), so as to assess the duration of their involvement in PAR consolidation. It was shown that only the coupled inactivation performed at the shortest post-acquisition delay was followed by amnesic effects. Thus EC and FF play a definite role during early consolidation. The results are discussed in relation to EC, FF, MSA, and hippocampal involvement in PAR memorization, as reported in previous studies, and to their connectivity.

Neural topography and chronology of memory consolidation: a review of functional inactivation findings.

Findings on the role of subcortical and cortical structures in mnemonic processes, obtained by means of the reversible functional inactivation technique, are reviewed. The main advantage of this method (subcortical or cortical administration of local anesthetics or tetrodotoxin) is that it provides information not only on "where" but also "when" and for "how long" these processes take place, thus adding to the topographical dimension the chronological one. The review covers several types of memory (e.g., passive avoidance and spatial memory) studies examining the neural substrates of memory consolidation on the basis of the functional inactivation of the nucleus of the solitary tract, parabrachial nuclei, substantia nigra, hippocampus (dorsal and ventral), nucleus basalis magnocellularis, amygdala, medial septal area, striatum, olfactory bulb, and neocortex. The data are discussed in relation to earlier research and with respect to the anatomical and functional connectivity of the examined centers.

A peculiar pattern of temporal involvement of rat perirhinal cortex in memory processing.

By means of the fully reversible tetrodotoxin inactivation technique, perirhinal cortex (PC) mnemonic function was investigated in rats trained to a passive avoidance response (PAR). It was shown that PC functional integrity is necessary during PAR acquisition, during late and very late consolidation (from 24 hr up to 192 hr after the training session), and during retrieval. An unexpected finding was that the PC was not involved in the early consolidation period. Thus the PC may play a relatively simple relay or connective role during acquisition, but its very late and very long consolidative involvement may indicate a peculiar function in consolidation and possibly in the storage of the PAR engram. The results are discussed in terms of the mnemonic characteristics of other neural sites (amygdala, hippocampus, and entorhinal cortex) involved in the same learning process.

Temporal characterization of subcortical nuclei in mnemonic processes: results of tetrodotoxin reversible inactivation studies in the rat.

By means of permanent lesion techniques it has been possible to ascertain whether a given subcortical neural structure is involved in memory processing. These results, however, are useful only to build a topography of memory, i.e. to provide information only on the "where" such processes take place. Memory being, per se, a temporal process, organized in at least three putative phases (acquisition, consolidation, retrieval) it is of paramount importance to know not only the "where", but also the "when", and, possibly, the "how long" of a given site involvement. The fully reversible inactivation technique has been employed to assess the chronological involvement of subcortical sites. By means of the stereotaxic administration of tetrodotoxin (TTX) it has been possible to inactivate known volumes of nervous tissue for given periods of time. In this way, it has been possible to measure the amnesic effects (disruption of the performance of a passive avoidance response, PAR) after inactivation of discrete neural sites. The data so far obtained by these means are presented and discussed. The comparison of results is justified by the constancy of the experimental subjects (young adult male rats of the same age), the surgical interventions, and the conditioning paradigm (passive avoidance responding in the light-dark box). The parabrachial nuclei, substantia nigra, ventral hippocampus, dorsal hippocampus, nucleus basalis magnocellularis, amygdala, globus pallidus, nucleus caudate-putamen (anterior, median, posterior), medial septal area and nucleus accumbens have been investigated. From these studies, data have been acquired on all three phases of memorization. The most detailed findings concern consolidation. In particular, it was shown that the functional integrity duration necessary to avoid amnesic damages varies greatly from site to site, from at least 15 min to no less than 48 hours. The results confirm and amplify previous experimental work, by defining the chronology of mnemonic involvement of many neural sites. The results are discussed in terms of comparison between sites and connectivity between the investigated sites and other sites or neuronal systems.

Entorhinal cortex and fimbria-fornix role in rat's passive avoidance response memorization.

The stereotaxic administration of tetrodotoxin (TTX) was employed to induce the fully reversible inactivation of the fimbria-fornix complex (FF) and of the entorhinal cortex (EC), in order to ascertain the role of these structures in the memorization of a passive avoidance response (PAR). On permanently cannulated rats TTX (5 ng in 0.5 microliter saline) or saline (0.5 microliter) was injected uni- or bilaterally, respectively, in the FF and in the EC, 60 min before PAR acquisition, immediately after PAR acquisition and 60 min before PAR retrieval, always performed 48 h after the acquisition trial. It was shown that EC unilateral or bilateral pre-acquisition inactivation was followed by amnesia, while TTX inactivation in post-acquisition and pre-retrieval had no effects. Identical results were obtained by TTX administration in FF. The experimental evidence indicates that both EC and FF play a role during acquisition of PAR engram. The results are discussed in comparison with previous ones concerning dorsal and ventral hippocampus TTX inactivation effects on rat's PAR, and in relation to hippocampal and medial septal area connectivity.

2-Deoxy-D-galactose effects on passive avoidance memorization in the rat.

2-Deoxy-D-galactose (do-gal) hinders glycoprotein fucosylation. This compound was intracerebroventricularly administered to male adult Wistar rats in order to assess whether it could exert amnesic effects on a passive avoidance response (PAR) to be learned in the light-dark box apparatus. Three experiments were performed. In the first, do-gal was administered immediately after the acquisition trials at three dosages (2, 4, and 8 mumol). It was found that only the 4-mumol dosage was followed by PAR disruption. In the second, do-gal was administered at the adequate dosage (4 mumol) either 30 min before the acquisition trial or 30 min before retrieval testing. It was found that only the preretrieval administration was followed by PAR impairment. In the third, do-gal (4 mumol) was administered in postacquisition, at increasing postacquisition delays (0.25, 1.5, 4, and 6 h). It was found that there was PAR disruption only after do-gal administration at the shortest (0.25 h) delay. The results confirm that in the rat, glycoprotein fucosylation is involved in some of the phases of memory trace processing, and they are discussed in relation to other findings in the rat and the chick.

Analysis of mnemonic processing by means of totally reversible neural inactivations.

The irreversible lesions technique precludes the analysis of the possibly critical role played by discrete brain sites in the several distinct stages of mnemonic processing (acquisition, consolidation, retrieval) during which these may be specifically but transiently active. On the contrary, the reversible functional inactivation techniques, by means of stereotaxic local microinjection of active compounds, make it possible to suppress the neuronal function of a discrete volume of nervous tissue, for a pre-determined time, with the assurance of complete functional recovery within a known duration. This technique makes it possible to block the neural activity of a chosen neural site at a given stage of memory processing without any interference with the function of the same structure either during earlier or later stages of the same process. Thus, the reversible ablation results may provide information not only on the qualitative topographical but also on the quantitative temporal dimension of learning and memory. The technique employed to cause totally reversible neural inactivation is detailed. The employment of several agents to obtain functional inactivation is discussed. Of these, perhaps the safest and most manageable is tetrodotoxin when a fairly long functional inactivation (e.g., 1 h) is desired. The effects of a reversible inactivation can be quite easily and accurately assessed by observing the severity of the amnesic disruption, if any, of a conditioned response. In order to do this as well as possible, it is advantageous to employ a very simple behavioral paradigm. The passive avoidance response in the light-dark box apparatus fulfills this requirement. Moreover, this paradigm, being one-trial, provides the necessary condition of a single well-defined temporal beginning. The present protocol has been successfully employed in learning and memory research, to assess when the functional integrity of a given neural structure is necessary in order that a conditioned response may be acquired, consolidated or retrieved. The employment of this protocol in relation to the intrinsic functional characteristics of a given subcortical neural site is discussed.

Role of ventral hippocampus in acquisition, consolidation and retrieval of rat's passive avoidance response memory trace.

By means of local administration of tetrodotoxin (TTX) a fully reversible functional inactivation of rat's ventral hippocampus (VH) was obtained in order to characterize the role of this structure in the memorization of a conditioned passive avoidance response (PAR). In Experiment 1, on permanently cannulated animals, TTX (10 ng in 1.0 microl saline) or saline (1.0 microl) was injected uni- or bilaterally in the VH, respectively, 1 h before PAR acquisition, immediately after PAR acquisition, and 1 h before PAR retrieval, always performed 48 h after the acquisition trial. It was shown that both pre-acquisition and pre-retrieval VH uni- or bilateral blockades were followed by significant PAR retention impairment, while in post-acquisition only the bilateral blockade determined PAR retention impairment. In Experiment 2, on three different groups of rats, TTX (10 ng in 1 microl saline) was bilaterally administered, under general ketamine anesthesia (100 mg/kg b.w.), into the VH at different post-acquisition delays (0.25, 1.5, 6 h). Retrieval testing, 48 h after treatment, showed that post-acquisition bilateral VH blockade caused PAR impairment only when performed 0.25 h after acquisition. The results clearly indicate a role of VH during acquisition, consolidation and retrieval of PAR engram. The experimental evidence is discussed in comparison to previous results concerning TTX dorsal hippocampus blockade effects on rat's PAR and in relation to hippocampal connectivity with the medial septal area and the amygdala.