Brief exposure to a novel environment enhances binding of hippocampal transcription factors to their DNA recognition elements

Behavioral and Cellular Tagging in Young and in Early Cognitive Aging

The ability to maintain relevant information on a daily basis is negatively impacted by aging. However, the neuronal mechanism manifesting memory persistence in young animals and memory decline in early aging is not fully understood. A novel event, when introduced around encoding of an everyday memory task, can facilitate memory persistence in young age but not in early aging. Here, we investigated in male rats how sub-regions of the hippocampus are involved in memory representation in behavioral tagging and how early aging affects such representation by combining behavioral training in appetitive delayed-matching-to-place tasks with the “cellular compartment analysis of temporal activity by fluorescence in situ hybridization” technique. We show that neuronal assemblies activated by memory encoding were also partially activated by novelty, particularly in the distal CA1 and proximal CA3 subregions in young male rats. In early aging, both encoding- and novelty-triggered neuronal populations were significantly reduced with a more profound effect in encoding neurons. Thus, memory persistence through novelty facilitation engages overlapping hippocampal assemblies as a key cellular signature, and cognitive aging is associated with underlying reduction in neuronal activation.

Evolutionarily-conserved role of the NF-kappaB transcription factor in neural plasticity and memory

NF-kappaB is an evolutionarily conserved family of transcription factors (TFs) critically involved in basic cellular mechanisms of the immune response, inflammation, development and apoptosis. In spite of the fact that it is expressed in the central nervous system, particularly in areas involved in memory processing, and is activated by signals such as glutamate and Ca2+, its role in neural plasticity and memory has only recently become apparent. A surprising feature of this molecule is its presence within the synapse. An increasing number of reports have called attention to the role of this TF in processes that require long-term regulation of the synaptic function underlying memory and neural plasticity. Here we review the evidence regarding a dual role for NF-kappaB, as both a signalling molecule after its activation at the synapse and a transcriptional regulator upon reaching the nucleus. The specific role of this signal, as well as the general transcriptional mechanism, in the process of memory formation is discussed. Converging lines of evidence summarized here point to a pivotal role for the NF-kappaB transcription factor as a direct signalling mechanism in the regulation of gene expression involved in long-term memory.

Phosphorylation state of CREB in the rat hippocampus: a molecular switch between spatial novelty and spatial familiarity?

The activation of cAMP response element-binding protein (CREB) after a learning experience is a common feature in the formation of several associative memories. We recently demonstrated that the increase in the hippocampal phosphorylated CREB (pCREB) levels 1 h after a short exploration of an open field (OF) was associated to detection of spatial novelty and was not related to the memory formation of habituation in this non-associative learning paradigm. Moreover, after a long training of three OF sessions, hippocampal pCREB levels were below to that observed in control rats. The present results show that such decrease does not correlate with memory retrieval or improvement in long-term memory of habituation. Instead, it is associated with the familiarity to the arena. Our experiments revealed that the relevant variable to induce CREB deactivation was the prolonged exploration of the arena (30 min). A 15 min OF exploration was ineffective. Furthermore, the last 5 min period of a prolonged exploration was crucial to change CREB phosphorylation state: when exploration took place in a novel arena the level of pCREB increased; in contrast, when it was performed in the familiar OF, pCREB levels decreased. Taken as a whole, our results suggest that CREB phosphorylation state in the hippocampus switches in response to exposure to a novel or to a familiar spatial environment.

Detection of novelty, but not memory of spatial habituation, is associated with an increase in phosphorylated cAMP response element-binding protein levels in the hippocampus

There is a growing body of evidence showing that the formation of associative memories is associated with an increase in phosphorylated cAMP response element-binding protein (pCREB) levels. We recently reported increased pCREB levels in the rat hippocampus after an exploration to a novel environment. In the present work, we studied whether this increment in CREB activation is associated with the formation of memory of habituation to a novel environment or with the detection of novelty. Rats were submitted to consecutive open field sessions at 3-h intervals. Measurement of the hippocampal pCREB level, carried out 1 h after each training session, showed that (1) it did not increase when rats explored a familiar environment; (2) it did not increase after a reexposure that improves the memory of habituation; (3) it increased after a brief novel exploration unable to form memory of habituation; and (4) it increased in amnesic rats for spatial habituation. Taken as a whole, our results suggest that the elevated pCREB level after a single open field exploration is not associated with the memory formation of habituation. It is indeed associated with the detection of a novel environment.

Spatial pre-training attenuates hippocampal impairments in rats exposed to intermittent hypoxia

Intermittent hypoxia (IH), such as occurs in sleep apnea, is associated with increased apoptosis and neurobehavioral impairments in rats. To determine whether pre-training (P) modifies the effect of IH on spatial learning, adult male rats were trained in a spatial version of the water maze, exposed to IH or room air (RA) for 14 days, and then trained in a novel spatial task. P-RA had lower initial pathlengths than naive RA (N-RA), which were similar in P-IH and N-IH, indicating an adverse effect of IH on retention of behavioral strategies to solve the maze. However, P-IH acquired the later spatial task faster than N-IH. Pre-training was associated with increased phosphorylation of the cAMP-response element binding protein (CREB) in the hippocampus. Further, IH-induced decreases in CREB phosphorylation were attenuated by pre-training. We conclude that prior exposure to the water maze behavioral requirements attenuates the behavioral deficits occurring after IH exposure.

Insights into immediate-early gene function in hippocampal memory consolidation using antisense oligonucleotide and fluorescent imaging approaches

In the 14 years since it was discovered that specific genes could be dynamically regulated in the brain by neural activity, there has been a substantial research focus attempting to understand the role immediate-early genes (IEGs) play in various brain functions. This article examines the involvement of IEGs in hippocampal synaptic plasticity and in memory consolidation processes performed by the hippocampus. Studies employing conventional IEG detection methodologies and a novel gene-imaging approach that provides temporal and cellular resolution (cellular compartment analysis of emporal activity by fluorescence in situ hybridization or catFISH) provide evidence supporting the assertion that IEG expression reflects the integration of information processed by hippocampal neurons. However, IEG expression is not merely correlated with neural activity, but also plays a pivotal role in stabilizing recent changes in synaptic efficacy. As such, localized disruption of IEGs Arc or c-fos by intrahippocampal administration of antisense oligonucleotides or germline disruption of the IEGs c-fos, tissue plasminogen activator, or zif268 impairs consolidation of long-term memory formation, without affecting learning or short-term memory. Further investigation into the expression and function of IEGs using catFISH and antisense approaches will likely increase understanding of the molecular and cellular bases of information processing involving the hippocampus.

Two time periods of hippocampal mRNA synthesis are required for memory consolidation of fear-motivated learning

Information storage in the brain is a temporally graded process involving different memory types or phases. It has been assumed for over a century that one or more short-term memory (STM) processes are involved in processing new information while long-term memory (LTM) is being formed. It has been repeatedly reported that LTM requires de novo RNA synthesis around the time of training. Here we show that LTM formation of a one-trial inhibitory avoidance training in rats, a hippocampal-dependent form of contextual fear conditioning, depends on two consolidation periods requiring synthesis of new mRNAs. By injecting the RNA polymerase II inhibitors 5,6-dichloro-1-beta-d-ribofuranosylbenzimidazole or alpha-amanitin into the CA1 region of the dorsal hippocampus at various times before and after training, we found that hippocampal gene expression is critical in two time windows: around the time of training and 3-6 hr after training. Interestingly, these two periods of sensitivity to transcriptional inhibitors are similar to those observed using the protein synthesis inhibitor anisomycin. These findings underscore the parallel dependence of LTM formation of contextual fear on mRNA and protein synthesis in the hippocampus and suggest that the two time periods of anisomycin-induced amnesia depend at least in part on new mRNA synthesis.

The genomic action potential

Neurons compute in part by integrating, on a time scale of milliseconds, many synaptic inputs and generating a digital output-the "action potential" of classic electrophysiology. Recent discoveries indicate that neurons also perform a second, much slower, integration operating on a time scale of minutes or even hours. The output of this slower integration involves a pulse of gene expression which may be likened to the electrophysiological action potential. Its function, however, is not directed toward immediate transmission of a synaptic signal but rather toward the experience-dependent modification of the underlying synaptic circuitry. Commonly termed the "immediate early gene" (IEG) response, this phenomenon is often assumed to be a necessary component of a linear, deterministic cascade of memory consolidation. Critical review of the large literature describing the phenomenon, however, leads to an alternative model of IEG function in the brain. In this alternative, IEG activation is not directed at the consolidation of memories of a specific inducing event; instead, it sets the overall gain or efficiency of memory formation and directs it to circuits engaged by behaviorally significant contexts. The net result is a sharpening of the selectivity of memory formation, a recruitment of temporally correlated associations, and an ultimate enhancement of long-term memory retrieval.

Defensive conditioning-related increase in AP-1 transcription factor in the rat cortex

In the studies reported herein, electrophoretic mobility shift assay (EMSA) and immunocytochemistry have been applied to document increased levels of AP-1 transcription factor, and its major component, c-Fos in the rat brain following behavioral training of two-way active avoidance. A single training session (50 trials) provoked elevation of AP-1 in the visual, sensory and limbic cortex but not in the hippocampus. A session following long term training (10 sessions, up to asymptotic level of performance) had much smaller effect on AP-1 levels in the visual cortex than single training session. The long term training was used to ensure that observed effects were related to acquisition of the reaction rather than simply to behavioral performance. Supershift EMSA analysis with antibodies directed at individual AP-1 components revealed that AP-1 extracted from the brains of trained as well as naive animals is composed of the same proteins, i.e., in order of relative level within the protein family: c-Fos, Fos B, Fra-2, and Jun D, Jun B, c-Jun. These studies reinforce the notion that transcription factors as regulators of gene expression-and AP-1 in particular-may respond to behavioral stimulation and furthermore may play a role in acquisition of behavioral reactions.

Antisense oligodeoxynucleotide-mediated disruption of hippocampal cAMP response element binding protein levels impairs consolidation of memory for water maze training

Extensive evidence suggests that long term memory (LTM) formation is dependent on the activation of neuronal second messenger systems and requires protein synthesis. The cAMP response element binding protein (CREB) is a constitutively expressed regulatory transcription factor that couples changes in second messenger levels to changes in cellular transcription. Several recent studies suggest that CREB and related transcription factors regulate gene expression necessary for neuronal plasticity and LTM. However, the role of CREB, within defined mammalian brain structures, in mediating the cellular events underlying LTM formation has not been investigated. We examined whether CREB-mediated transcription within the dorsal hippocampus is critical to LTM consolidation of water maze spatial training, which is known to depend on dorsal hippocampal function. Pretraining infusions of antisense oligodeoxynucleotides (ODN) directed against CREB mRNA were used to disrupt hippocampal CREB protein levels in adult rats. Control groups received pretraining infusions of ODN of the same base composition but in a randomized order (scrambled ODN) or buffer. Task acquisition and memory up to 4 h (i.e., short term memory) were similar in CREB antisense ODN and control groups. In contrast, CREB antisense ODN-infused rats exhibited significantly impaired memory 48 h later (i.e., LTM). Moreover, administration of antisense ODN 1 day after training did not affect subsequent retention performance. These findings provide the first evidence that CREB-mediated transcription is integral to hippocampal-dependent memory consolidation processes.

Androgens selectively modulate C-fos messenger RNA induction in the rat hippocampus following novelty

We have previously shown that androgen receptors are found in high concentrations in hippocampal CA1 pyramidal cells. To begin to explore the possible roles for androgen receptors in this area of the brain, we studied the effects of endogenous and exogenous androgen on the behaviourally induced expression of cellular immediate early gene messenger RNAs. Adult male Fischer 344 rats were either gonadectomized, gonadectomized and given two Silastic capsules of dihydrotestosterone propionate at the time of surgery, or left intact. Three weeks later, animals were placed into a novel open field for 20 min. This behavioural paradigm caused region- and gene-specific increases of c-fos, jun-B, c-jun and zif268 messenger RNA in the hippocampus as determined by semi-quantitative in situ hybridization histochemistry. The removal of circulating androgen by gonadectomy potentiated, whereas dihydrotestosterone treatment of castrates attenuated, the behaviourally induced expression of c-fos messenger RNA in the CA1 region of the hippocampus. No changes in c-fos messenger RNA expression were detected in the CA3 or dentate gyrus regions where androgen receptor levels are low. Androgen status did not affect either the basal or stimulated expression of Jun-B, c-Jun or zif268 messenger RNA in any of the three cellular regions of the hippocampus examined. These results implicate androgen receptors in modulating the active response of hippocampal neurons to a behaviourally relevant stimulus. Since the products of cellular immediate genes can function to alter an array of downstream genes, the modulation of these genes in the hippocampus by gonadal hormones may have important ramifications for hippocampal function.

The anxiolytics CI-988 and chlordiazepoxide fail to reduce immediate early gene mRNA stimulation following exposure to the rat elevated X-maze

This study uses immediate early transcription factor gene expression to map neuronal activation after a single exposure to the elevated X-maze. Exposure to this novel environment leads to widespread upregulation in the gene expression of c-fos, NGFI-A and NGFI-B (the nerve growth factor induced genes), but not c-jun nor jun B as shown by in situ hybridization and northern blot analysis. Changes in c-fos were evident after just 5 min exposure to the maze. The cholecystokininB receptor antagonist, CI-988, given intraperitoneally at 1 mg/kg 40 min prior to exposure to the X-maze demonstrated an anxiolytic profile without affecting overall movement around the maze, however it did not reduce the increased levels of gene expression with the methodology used. Likewise the anxiolytic benzodiazepine, chlordiazepoxide at 3 mg/kg did not reduce gene expression. It is concluded that a reduction in an index of behavioural stress/anxiety produced by anxiolytic agents is not concomitantly followed by a detectable reduction in immediate early gene induction.

Gene expression of the transcription factor NF-kappa B in hippocampus: regulation by synaptic activity

NF-kappa B is a potent transcriptional activator that resides in latent form in the cytoplasm complexed to its inhibitor I kappa B. Phosphorylation of I kappa B by protein kinase C (PKC) releases NF-kappa B, enabling its translocation to the nucleus. Since PKC can activate NF-kappa B and PKC is activated by long-term potentiation (LTP), we investigated NF-kappa B expression after hippocampal LTP induced in vivo. We first described the expression of the NF-kappa B subunits, p50 and p65, and I kappa B alpha mRNAs, in each cell field of the hippocampus. In other brain locations I kappa B alpha mRNA exhibited a more selective expression than p50 and p65. We then demonstrated specific NF-kappa B-like DNA-binding activity in hippocampal whole-cell extracts and in synaptosomes using electrophoretic mobility shift assays by the following criteria: (1) latent binding was revealed after deoxycholate treatment; (2) binding was competed off by unlabeled kappa B oligonucleotides; and (3) antibodies to either p50 or p65 blocked binding. Since p50 gene expression is auto-regulated by NF-kappa B, we used its expression as a reporter for NF-kappa B activity using quantitative in situ hybridization. Both p50 and p65 increased their expression in response to either LTP-inducing or low-frequency control stimulation, although the increase in p65 mRNA levels was greater after LTP than control stimulation. In contrast to p50 and p65, I kappa B alpha hybridization levels were not increased, but were inversely correlated with the magnitude of LTP. Since NF-kappa B subunit gene expression in the hippocampus is increased by augmented synaptic activity, NF-kappa B activation may contribute to alterations in target gene expression that accompany activity-dependent synaptic plasticity, but only in a combinatorial fashion with other transcription factors.

Prolonged alteration in E-box binding after a single systemic kainate injection: potential relation to F1/GAP-43 gene expression

The presence in hippocampus of a basic helix-loop-helix (bHLH) family of transcription factors (TFs) specifically binding in an electrophoretic mobility shift assay (EMSA) to the E-box recognition element was established by selective blockade of binding both by cold competition and by an antibody to MyoD1, an E-box TF. Protein source was from a micro-dissected preparation enriched in hippocampal granule cells. Specific E-box binding of hippocampal transcription factors was significantly reduced in kainate acid (KA) treated animals. This was observed at 24 and 72 h, but not before (3, 6 h) or after (96 h). This is the first report to our knowledge to study functional regulation of E-box binding protein in adult hippocampus. To determine the generality of this E-box regulatory event, we studied four other situations, in addition to kainate treatment, where axonal growth is known or has been suggested to increase: NGF treatment of PC12 cells, unilateral hilar lesions, long-term potentiation after 1 h, and postnatal rat hippocampal development. In all four cases, decreased E-box binding was observed. The recent link of F1/GAP-43 mRNA induction in hippocampal granule cells by KA to growth of their axons, the mossy fibers in the adult rat, suggests a potential role for the F1/GAP-43 5' flanking promoter region in regulating neurite outgrowth. Since in all cases decreased E-box binding preceded increased F1/GAP-43 mRNA expression, it is suggested that E-box binding to the F1/GAP-43 promoter in hippocampal granule cells could negatively regulate F1/GAP-43 gene expression. Indeed, analysis of recognition elements on the F1/GAP-43 gene revealed an arrangement, previously described in other genes, of multiple adjacent E-box elements. E-box binding of bHLH transcription factors is likely to occur on several different genes in addition to F1/GAP-43. It is, therefore, attractive to think that E-box binding is regulated by in vivo activation of the adult brain and that this gene regulatory event participates in the orchestration of molecular and cellular responses underlying axonal growth.

Immediate-early gene responses in the avian song control system: cloning and expression analysis of the canary c-jun cDNA

Previous studies have shown that song presentation results in a rapid rise in mRNA levels for the ZENK gene (the avian homologue of zif-268, Egr-1, NGFI-A, and Krox-24) in specific parts of the songbird forbrain. Metrazole-induced seizures also cause an increase in ZENK mRNA, even more widely throughout the telencephalon. Surprisingly, however, little or no ZENK induction by either stimulus was observed in several forebrain areas involved in auditory processing and song production. To learn whether this pattern of regulation is specific to ZENK, we examined the response of another 'immediate-early' gene, c-jun. Here we first describe the identification, cloning and sequence analysis of a canary cDNA encoding c-jun. Then, by in situ hybridization we show that c-jun is also induced by song or seizure, and in a pattern mostly similar to ZENK. As with ZENK, no induction of c-jun is observed in the androgen receptor-containing song nuclei or within the primary thalamo-recipient auditory area of the forebrain. Thus common immediate early gene responses appear to be selectively uncoupled from physiological activation in these specific forebrain regions, which are also characterized by tight developmental, hormonal and seasonal regulation.

AP-1 and CRE DNA binding activities in rat brain following pentylenetetrazole induced seizures

Pentylenetetrazole (PTZ) evoked seizures, known to be dependent on stimulation of excitatory amino acids (EAA) receptors, serve as a useful model to study genomic responses to increased brain activity. It is believed that these responses form the basis for long term modifications in neuronal functions. Formation of the AP-1 transcription factor genes and proteins in hippocampal cells is the best known example of a genomic response to PTZ seizures and to an activation of the EAA receptors. In the studies reported herein electrophoretic mobility shift assay (EMSA) was employed to investigate levels of AP-1 DNA binding activity in various regions of the rat brain following PTZ seizures and these levels were compared to the cyclic AMP responsive element (CRE) DNA binding activity. A dramatic increase of the AP-1 DNA binding activity was observed in the hippocampus and in sensory and limbic cortices, and to much lesser extent in the cerebellum. The EMSA supershift method provided an evidence that Jun B and c-Fos and probably Fos B are major components of AP-1 at 2 h after the seizures. In none of the structure investigated, clear modulation of CRE DNA binding activity was noted. These data are discussed in the context of CRE and AP-1 DNA binding crossreactivity.