Pascal Roullet

Recruitment of adult-generated neurons into functional hippocampal networks contributes to updating and strengthening of spatial memory

The dentate gyrus (DG), a hippocampal subregion, continuously produces new neurons in the adult mammalian brain that become functionally integrated into existing neural circuits. To what extent this form of plasticity contributes to memory functions remains to be elucidated. Using mapping of activity-dependent gene expression, we visualized in mice injected with the birthdating marker 5-bromo-2′-deoxyuridine the recruitment of new neurons in a set of controlled water maze procedures that engage specific spatial memory processes and require hippocampal–cortical networks. Here, we provide new evidence that adult-generated hippocampal neurons make a specific but differential contribution to the processing of remote spatial memories. First, we show that new neurons in the DG are recruited into neuronal networks that support retrieval of remote spatial memory and that their activation is situation-specific. We further reveal that once selected, new hippocampal neurons are durably incorporated into memory circuits, and also that their recruitment into hippocampal networks contributes predominantly to the updating and strengthening of a previously encoded memory. We find that initial spatial training during a critical period, when new neurons are more receptive to surrounding neuronal activity, favors their subsequent recruitment upon remote memory retrieval. We therefore hypothesize that new neurons activated during this critical period become tagged so that once mature, they are preferentially recruited into hippocampal networks underlying remote spatial memory representation when encountering a similar experience.

Hippocampal CA3-region is crucial for acquisition and memory consolidation in Morris water maze task in mice.

This experiment investigated the involvement of the dorsal hippocampal CA3-region in the different phases of learning and memory in spatial and non-spatial tasks. To do so, we temporarily inactivated the CA3-subfield by a focal injection of diethyldithiocarbamate (DDC) which chelates most of the heavy metals present in this region. The effects of temporary inactivation of the CA3-region were examined in an associative task, the Morris water maze (MWM). To study the different phase of memory we used a new behavioural massed-procedure founded on four massed training sessions in the spatial and the non-spatial (cue) version of this task. In the spatial version, we showed that a bilateral injection of DDC into the CA3-region impairs the acquisition but not the recall of spatial information. The main result of this study is that the same injection performed immediately after the training session also perturbed memory consolidation. In the cue version of the MWM, we found no difference between the DDC-injected mice and their controls in acquisition or memory consolidation of non-spatial information. These results suggest that the hippocampal CA3-region is essential for spatial memory processes and specifically in memory consolidation of spatial information.

Protein degradation, as with protein synthesis, is required during not only long‐term spatial memory consolidation but also reconsolidation

The formation of long‐term memory requires protein synthesis, particularly during initial memory consolidation. This process also seems to be dependant upon protein degradation, particularly degradation by the ubiquitin‐proteasome system. The aim of this study was to investigate the temporal requirement of protein synthesis and degradation during the initial consolidation of allocentric spatial learning. As memory returns to a labile state during reactivation, we also focus on the role of protein synthesis and degradation during memory reconsolidation of this spatial learning. Male CD1 mice were submitted to massed training in the spatial version of the Morris water maze. At various time intervals after initial acquisition or after a reactivation trial taking place 24 h after acquisition, mice received an injection of either the protein synthesis inhibitor anisomycin or the protein degradation inhibitor lactacystin. This injection was performed into the hippocampal CA3 region, which is specifically implicated in the processing of spatial information. Results show that, in the CA3 hippocampal region, consolidation of an allocentric spatial learning task requires two waves of protein synthesis taking place immediately and 4 h after acquisition, whereas reconsolidation requires only the first wave. However, for protein degradation, both consolidation and reconsolidation require only one wave, taking place immediately after acquisition or reactivation, respectively. These findings suggest that protein degradation is a key step for memory reconsolidation, as for consolidation. Moreover, as protein synthesis‐dependent reconsolidation occurred faster than consolidation, reconsolidation did not consist of a simple repetition of the initial consolidation.

N-methyl-D-aspartate and dopamine receptor involvement in the modulation of locomotor activity and memory processes

Abstract In this study we report on the effects of N-methyl-d-aspartate (NMDA)- and dopamine (DA)-receptor manipulation on the modulation of one-trial inhibitory avoidance response and the encoding of spatial information, as assessed with a non-associative task. Further, a comparison with the well-known effects of the manipulation of these two receptor systems on locomotor activity is outlined. It is well assessed that NMDA-receptor blockage induces a stimulatory action on locomotor activity similar to that exerted by DA agonists. There is evidence showing that the nucleus accumbens is involved in the response induced by both NMDA antagonists and DA agonists. We show results indicating a functional interaction between these two neural systems in modulating locomotor activity, with D2 DA-receptor antagonists (sulpiride and haloperidol) being more effective than the D1 antagonist (SCH 23390) in blocking MK-801-induced locomotion. A different profile is shown in the effects of NMDA antagonists and DA agonists in the modulation of memory processes. In one-trial inhibitory avoidance response, NMDA antagonists (MK-801 and CPP) impair the response on test day, while DA agonists exert a facilitatory effect; furthermore, sub-effective doses of both D1 (SKF 23390) and D2 (quinpirole) are able to attenuate the impairing effect in a way similar to that induced by NMDA antagonists. The effects of NMDA- and DA-acting drugs on the response to spatial novelty, as assessed with a task designed to study the ability of animals to react to discrete spatial changes, are in good accord with the effects observed on passive avoidance. The results show that NMDA as well as DA antagonists, at low doses, selectively impair the reactivity of mice to spatial changes. In a last series of experiments, the possible role of NMDA receptors located in the nucleus accumbens was investigated regarding reactivity to spatial novelty. The experiments gave apparently contrasting results: while showing an impairing effect of focal administrations of NMDA antagonists in the nucleus accumbens on reactivity to spatial novelty, no effect of ibotenic acid lesions of the same structure was observed.

Consolidation of memory after its reactivation: involvement of beta noradrenergic receptors in the late phase.

Evidence is growing that the cAMP pathway through the cAMP responsive element binding protein (CREB) transcription factor plays an important role in long-term memory formation (LTM). To study the role of β-noradrenergic receptors, positively linked to the cAMP secondmessenger system, in the dynamics of LTM processes, we used a memory-reactivation paradigm because recent studies in our laboratory confirmed that reactivated memory is labile and undergoes an extended reconsolidation process. In an eight-arm maze, rats were trained to choose the same three baited arms; 24 hr later, memory was reactivated and then the rats were injected intracerebroventricularly at 5 min, 30 min, 60 min, or 5 hr later with the β-antagonist timolol or with saline. The results showed that injection of timolol induced amnesia only at the 60 min post-reactivation interval, whereas all control groups and groups that were timolol-injected at other post-reactivation intervals displayed optimal retention. The delayed amnesic action of timoloi suggests that β noradrenergic receptors and the cAMP cascade are implicated in the late phase of reprocessing of a remembered event.

Involvement of the hippocampal CA3-region in acquisition and in memory consolidation of spatial but not in object information in mice.

This study investigates the implication of the hippocampal CA3-region in the different phases of learning and memory in spatial and non-spatial tasks. For that purpose, we performed focal injections of diethyldithiocarbamate (DDC) into the CA3-region of the dorsal hippocampus. The DDC chelates most of the heavy metals in the brain which blocks selectively and reversibly the synapses containing heavy metals, i.e., the mossy fibres synaptic buttons and synapses of the dendrites of pyramidal cells. The effects of temporal inactivation of the CA3-region was examined in a non-associative task, the spatial open-field, designed to estimate the ability of mice to react to spatial changes, and in the object recognition task, designed to estimate the ability of mice to identify a familiar object. The results show that DDC induced a specific impairment on learning and memory consolidation in the spatial open-field but had no effect on recall in this task. In the object recognition task, DDC did not induce any impairment in the different phases of learning and memory. These data demonstrate that the hippocampal CA3-region is specifically implicated in spatial information processing and seems to be involved not only in acquisition but also in consolidation of spatial information.

Effects of intra-accumbens focal administrations of glutamate antagonists on object recognition memory in mice.

Generally recognition memory is distinguished into spatial and object memories that have been suggested to relay at a cortical level on different neural substrates. Recent studies point to a possible involvement of the nucleus accumbens (Nac) in spatial memory, demonstrating that blockade of glutamate antagonists within this structure impairs acquisition and consolidation of spatial information, while not many data are available on the potential role of this structure in object recognition. Thus in this study we wanted to investigate the effects of intra-accumbens focal administrations of NMDA antagonist, AP-5 (0.05, 0.1, 0.15 or 0.2 microg per side), and AMPA antagonist, DNQX (0.0005 or 0.001 microg per side), in object recognition memory. The spontaneous preference displayed by mice for novel objects was taken as an index for measuring object recognition. Pre-training focal administrations of both antagonists impaired the ability of mice to selectively explore the novel object in test session. However, the AMPA antagonist induced also a decrease in exploration and locomotion. In order to assess whether glutamate receptors located within the Nac were also involved in subsequent steps of object information processing, we performed additional experiments injecting AP-5 and DNQX immediately after training and testing the animals 24-h later. In this case, AP-5 but not the AMPA antagonist impaired exploration of the novel object. These results demonstrate that the Nac is involved in object recognition, and confirm that the different glutamate receptors mediate different component of information processing within the accumbens.

N-Methyl-D-aspartate receptors in the nucleus accumbens⋅are involved in detection of spatial novelty in mice

Abstract The aim of this study was to investigate the role played by intra-accumbens N-methyl-D-aspartate (NMDA) receptors in spatial information encoding. For this purpose, the effect of local administration of both competitive (AP-5) and non-competitive (MK-801) NMDA antagonists was assessed in a task designed to estimate the ability of rodents to encode spatial relationships between discrete stimuli. The task consists of placing mice in an open field containing five objects and, after three sessions of habituation, examining their reactivity to object displacement (spatial novelty) and object substitution (object novelty). The results show that both doses of MK-801 (0.15 and 0.3 μg/side) induced a selective impairment in the capability of mice to detect spatial novelty. A similar effect was obtained by injecting the low dose of the competitive antagonist AP-5 (0.1 μg/side), whereas the high dose (0.15 μg/side) abolished detection of both spatial and object novelty. Taken together, these results show that intra-accumbens injections of low doses of competitive and non-competitive NMDA antagonists can produce selective deficits in processing spatial information resembling those observed after hippocampal damage. Moreover, the fact that pharmacological treatments spare memory processes involved in habituation suggests that NMDA antagonists may interfere with the formation of spatial representations rather than producing memory deficits per se.

Effects of lesions to the glutamatergic afferents to the nucleus accumbens in the modulation of reactivity to spatial andnon-spatial novelty in mice

The purpose of this study was to compare the effects of selective lesions of the three main sources of limbic afferents to the nucleus accumbens-fornix, prelimbic cortex and amygdala-with those induced by N-methyl-D-aspartate receptor blockage in this structure, in a non-associative task designed to estimate the ability of rodents to encode spatial and non-spatial relationships between discrete stimuli. The task consists of placing mice in an open field containing five objects and, after three sessions of habituation, examining their reactivity to object displacement (spatial novelty) and object substitution (object novelty). Focal administrations of the competitive N-methyl-D-aspartate antagonist DL-2-amino-5-phosphonopentanoic acid (0.1 microg/side) induced a selective impairment in the ability of mice to react to the spatial change. Lesions to the different structures affect the response of mice to spatial and non-spatial novelty in different ways. In particular, while fornix lesions induced a decrease in re-exploration of the displaced objects, prelimbic cortex lesions enhanced the exploration of both displaced and non-displaced objects. Finally, the basolateral amygdala lesions did not induce any impairment in the detection of the displaced objects but decreased the latencies to approach novel objects. It is concluded that N-methyl-D-aspartate receptor blockage in the nucleus accumbens subsumes the effects of the three lesions. Some hypotheses on the role of glutamatergic transmission in the accumbens on information processing are briefly discussed.

Involvement of glutamatergic and dopaminergic systems in the reactivity of mice to spatial and non-spatial change

Injections of glutamatergic NMDA as well as dopaminergic antagonists produce selective place- but not cue-learning deficits in associative spatial tasks. The present work was aimed at examining if the blockade of NMDA and dopaminergic receptors interferes with the encoding of spatial information in a non-associative task specifically designed for rodents. CD1 mice injected with MK-801 (0.1 and 0.25 mg/kg), haloperidol (0.04 and 0.08 mg/kg), a combination of the lower doses of each drug (haloperidol: 0.04 mg/kg and MK-801: 0.1 mg/kg) or saline were placed in an open field containing five objects and their reactivity to the displacement (spatial change) or the substitution (non-spatial change) of some of these objects was examined. The results show that saline-injected mice reacted to spatial as to non-spatial change by increasing the time spent exploring the displaced objects or the substituted one. Both doses of MK-801 prevented mice from detecting spatial change but did not affect their reactivity to the novel object. Both doses of haloperidol abolished the reactivity of mice to spatial change but the higher dose of the drug also altered the reaction to non-spatial change. Taken together, the present results indicate that the blockade of dopaminergic or glutamatergic NMDA receptors abolishes the detection of spatial novelty. The well-documented impairing effects of haloperidol and MK-801 on spatial learning may, therefore, be the consequence of a drug-induced inability in forming and/or updating spatial representions. The effect of haloperidol was, however, less specific than that of MK-801, since haloperidol always modified activity together with the response to spatial change and, at the higher dose, abolished the detection of both spatial and non-spatial change. Finally, haloperidol pretreatment was found to enhance the effect of MK-801 thus suggesting a possible interaction between the two systems in modulating these behavioral responses.