Accelerated long-term forgetting (ALF) and the role of sleep in memory consolidation

Atherton, Kathryn Eleanor

January 2014

Accelerated long-term forgetting (ALF) is a recently described memory impairment associated with epilepsy. Patients with ALF appear to learn and initially retain new information normally, but forget it at an accelerated rate over subsequent days. ALF can have a profound impact on the lives of the people who suffer from it, but it is also of theoretical interest. In particular, the study of this disorder may provide insight into the mechanisms of memory consolidation. ALF is especially prevalent in transient epileptic amnesia (TEA), an epileptic syndrome in which the seizure focus is thought to be the medial temporal lobes (MTL). The MTL house the hippocampus and a number of other structures critical for declarative memory function. The aims of this doctoral thesis were to investigate which aspects of memory function are disrupted in patients with TEA-associated ALF, and to shed light on the neural basis of the memory impairment. Slow wave sleep (i.e. deep sleep) is known to exacerbate epileptic activity. It is also thought to play a key role in the consolidation of declarative memory. The most commonly posited explanation of ALF is the disruption of sleep- dependent memory consolidation. However, it remains possible that ALF is caused by a subtle problem with encoding that usually goes undetected until delayed memory tests. The results of this thesis demonstrate that sleep can actually benefit memory retention in TEA ALF patients just as much as it does in healthy people, and that it is not necessary for the retention interval to contain sleep in order for ALF to be seen. However, the relationship between slow wave sleep and memory was found to be abnormal in these patients. The amount of slow wave sleep, and the power in the slow oscillation frequency range, during the post-learning night correlated negatively with the benefit of that night of sleep for memory retention. Furthermore, resting-state brain activity patterns thought to reflect post-encoding memory reprocessing were found to correlate negatively with subsequent memory performance in these patients. Another chapter of this thesis provides evidence that TEA ALF patients encode memories abnormally; these patients showed reduced activity in the left hippocampus while viewing stimuli that they went on to forget. Furthermore, this encoding-related brain activity correlated with their long-term forgetting. The final experimental chapter reports a correlation in these patients between grey matter in the left hippocampus and long-term forgetting, which cannot entirely account for the encoding-related brain activity results. The hippocampus and its surrounding structures are thought to be critical to our ability to discriminate between similar stimuli and events. An intriguing hypothesis consistent with the pattern of results in this thesis is that ALF is caused by a functional impairment of the MTL that results in a diminished capacity to distinguish between similar experiences, ultimately causing memory problems; abnormally formed memories may interact with new material and memory consolidation processes in an aberrant manner, leading to retrieval deficits.

616.8

Phylogénie du sommeil chez les tétrapodes : analyse de patterns évolutifs, études électrophysiologiques et comportementales chez deux espèces de squamates et nouvelles perspectives méthodologiques / Phylogeny of sleep in tetrapods : analysis of evolutionary patterns, electrophysiological and behavioral studies in two squamates species and new methodological perspectives

Libourel, Paul-Antoine

15 February 2019

Le sommeil constitue un comportement vital complexe, identifié chez la quasi-totalité des animaux étudiés. Sur la base d’études princeps dans les années 50 chez le chat et l’homme, le sommeil a pu être séparé clairement en deux états distincts : le sommeil lent et le sommeil paradoxal. Ces deux états ont ainsi été caractérisés sur la base de critères électroencéphalographiques, physiologiques et comportementaux. Basé sur une définition mammalienne, il a ainsi été montré que les mammifères terrestres et les oiseaux, tous deux homéothermes, possédaient ces deux états de sommeil. Cependant, l'origine évolutive de ces deux états reste inconnue et nous ne savons toujours pas s’ils ont évolué de façon indépendante ou s’ils ont été hérités d'un ancêtre commun. Les amphibiens et les reptiles, positionnés à la base des tétrapodes et des amniotes constituent par conséquent, des taxons clés dans la compréhension de l'évolution de ces deux états de sommeil. Afin de mieux comprendre la phylogénie de ces deux états, nous avons réalisé dans un premier temps une revue et méta-analyse de la littérature du sommeil chez ces espèces. Dans un second temps, et dans le but de pouvoir conduire des approches comparatives et ainsi mieux décrire la plasticité du sommeil, nous avons développé un dispositif miniature sans fil permettant d’enregistrer simultanément l’électrophysiologie, la physiologie, la température et le comportement en laboratoire et en milieu naturel. Enfin, nous avons conduit une étude électrophysiologique, physiologique, pharmacologique et comportementale chez deux espèces de squamates (Salvator merianae et Pogona vitticeps). Cette étude nous a permis de montrer que deux états électroencéphalographiques de sommeil existaient chez ces espèces. Cependant, elles ont aussi révélé des divergences phénotypiques importantes au sein même des lézards, ainsi qu’avec le sommeil des mammifères et des oiseaux, démontrant ainsi une origine commune mais complexe des deux états de sommeil / Sleep is a vital and complex behavior, identified in nearly all animals. Based on studies on cats and humans conducted in the 50’s, sleep was separated into two distinct sleep states: slow wave sleep and paradoxical sleep (or REM sleep). Those two states were identified based on electroencephalographic, physiological and behavioral parameters. Based on this mammalian definition, it has been demonstrated that those two states exist in terrestrial mammals and birds, both homeotherms. However, the evolutive origin of these sleeps states remains unknown and we do not know whether they evolved independently or if they were inherited from a common ancestor. Amphibians and reptiles are respectively positioned at the base of the tetrapod and the amniote tree. Therefore, they constitute key taxa in the understanding of the origin of these states. In order to understand the phylogeny of these states, we first performed an exhaustive review and meta-analysis of the sleep literature in these groups. Next, in order to be able to conduct comparative approaches and better understand the sleep plasticity, we developed a standalone miniature device to record electrophysiology, physiology, temperature, and behavior simultaneously and this under both lab and field conditions. Finally, we conducted an electrophysiological, physiological, pharmacological and behavioral study of two squamates species (Salvator merianae and Pogona vitticeps). This study revealed that two electro-encephalographical sleep states exist in these species. However, they also showed that the phenotype of these states diverged between the two lizards and between the lizards on the one hand and mammals and birds on the other hand. This would suggest a common, but complex, origin of these two sleep states

Sommeil

Évolution

Tétrapodes

Squamates

Sommeil lent

Sommeil paradoxal

Pogona Vitticeps

Salvator merianae

Sleep

Evolution

Tetrapoda

Squamates

Slow wave sleep

Paradoxical sleep

Pogona vitticeps

Salvator merianae

610

THE ROLE OF RAPID EYE MOVEMENT AND SLOW WAVE SLEEP FOR THE CONSOLIDATION OF MEMORY IN RATS

Fogel, STUART

26 October 2009

The functions of sleep remain enigmatic. One of the dominant, yet more contentious hypotheses is that sleep is involved in memory consolidation. A large body of evidence supports the role of rapid eye movement (REM) sleep in memory consolidation, especially in rodents. In humans, the role of REM sleep in memory consolidation has also been investigated, however it is unclear if it supports only one type of memory, or consolidation for several memory systems. Recent evidence suggests that non-REM is also involved in memory consolidation. The role of theta activity during REM and sleep spindles during non-REM may provide electrophysiological signatures reflecting memory consolidation processes. The studies presented here attempt to further investigate the electrophysiological characteristics of the learning-dependent changes in REM and slow wave sleep (SWS) in rats. A 2-stage model of memory consolidation is outlined here, and both steps of the model were investigated. Consistent with previous studies, REM increases were observed following avoidance training. During this period, theta power during REM sleep was increased compared to non-learning rats. Increased sleep spindle density during SWS was observed following REM increases. When REM sleep was suppressed by infusing the GABAB agonist baclofen into the pedunculopontine nucleus, avoidance performance acquisition was impaired. Baseline sleep spindles predicted whether rats were able to learn to make avoidance responses. Results suggest that both REM and SWS may be sequentially involved in memory consolidation processes. Discrete periods (windows) exist for REM and SWS when memory consolidation processes appear to take place. Theta activity during REM sleep from 17- 20 h on the first post-training day and sleep spindles during SWS from 21-24 h on the first post- training day are increased in learning rats and are related to memory performance. / Thesis (Ph.D, Neuroscience Studies) -- Queen's University, 2009-10-26 12:07:47.515

sleep

memory

electroencephalogram (EEG)

rat

spindle

rapid eye movement (REM)

slow wave sleep (SWS)

theta

pedunculopontine nucleus

deep mesencephalic reticular nucleus

baclofen

GABA

learning

The role of sleep and dreaming in the processing of episodic memory

Stenstrom, Philippe

06 1900

La présente thèse examine les liens entre le sommeil, la mémoire épisodique et les rêves. Dans une première étude, nous utilisons les technologies de la réalité virtuelle (RV) en liaison avec un paradigme de privation de sommeil paradoxal et de collecte de rêve en vue d'examiner l'hypothèse que le sommeil paradoxal et le rêve sont impliqués dans la consolidation de la mémoire épisodique. Le sommeil paradoxal a été associé au rappel des aspects spatiaux des éléments émotionnels de la tâche RV. De la même façon, l'incorporation de la tâche RV dans les rêves a été associée au rappel des aspects spatiaux de la tâche. De plus, le rappel des aspects factuels et perceptuels de la mémoire épisodique, formé lors de la tâche VR, a été associé au sommeil aux ondes lentes. Une deuxième étude examine l'hypothèse selon laquelle une fonction possible du rêve pourrait être de créer de nouvelles associations entre les éléments de divers souvenirs épisodiques. Un participant a été réveillé 43 fois lors de l'endormissement pour fournir des rapports détaillés de rêves. Les résultats suggèrent qu'un seul rêve peut comporter, dans un même contexte spatiotemporel, divers éléments appartenant aux multiples souvenirs épisodiques. Une troisième étude aborde la question de la cognition lors du sommeil paradoxal, notamment comment les aspects bizarres des rêves, qui sont formés grâce aux nouvelles combinaisons d'éléments de la mémoire épisodique, sont perçus par le rêveur. Les résultats démontrent une dissociation dans les capacités cognitives en sommeil paradoxal caractérisée par un déficit sélectif dans l'appréciation des éléments bizarres des rêves. Les résultats des quatre études suggèrent que le sommeil aux ondes lentes et le sommeil paradoxal sont différemment impliqués dans le traitement de la mémoire épisodique. Le sommeil aux ondes lentes pourrait être implique dans la consolidation de la mémoire épisodique, et le sommeil paradoxal, par l'entremise du rêve, pourrais avoir le rôle d'introduire de la flexibilité dans ce système mnémonique. / The present dissertation examines relationships between sleep, episodic memory and dreaming. In Articles I and II we use a novel virtual reality (VR) task in conjunction with a rapid eye movement (REM) sleep deprivation (REMD) paradigm and dream sampling to examine the hypothesis that REM sleep and dreaming are involved in the consolidation of episodic memory. REM sleep was associated with the successful recall of the spatial aspects of emotionally charged elements of the VR task. Similarly, dreaming was associated with improved performance on the spatial aspects of the recall task. Recall of the factual and perceptual aspects of episodic memories formed with the VR task was associated with increased slow wave sleep (SWS) during the post-exposure night. Overall, the results suggest that SWS is associated with the perceptual and factual aspects of episodic memories while REM sleep is not, a finding which may relate to observations that REM sleep dreaming is composed of deconstructed fragments of loosely associated episodic memories. Study II examines the hypothesis that a function of dreaming may be to create new associations between previously unrelated memory items. A participant, highly trained in introspection and mentation reporting, was awakened 43 times during theta bursts at sleep onset and provided detailed reports of resulting imagery and associated memory sources. This technique provided evidence that elements of distally related memory sources are brought together in temporal and spatial proximity within a novel context provided by the dream, suggesting a role for dreaming in memory processing. To allow for this possibility, we speculate that dreaming experiences may be functionally equivalent to waking experiences in their ability to induce neural plasticity. Study III addresses an aspect of this functional equivalence by examining if dream bizarreness is incompatible with behavioral and cognitive features associated with waking state experience-driven plasticity, i.e., whether the dreamer can act upon, emote and be motivated towards an element of the dream that is bizarre and that violates basic assumptions of physical reality. The results demonstrate a dissociation in cognitive ability during dreaming characterized by a selective deficiency in appreciating bizarreness in face of a maintained ability for logical thought. This finding thus addresses the problem of the wake-like mind reflecting upon dream bizarreness and suggests that dreaming is a state in which the cognitive aspects associated with synaptic plasticity (attention, emotion and motivation associated with believing a situation to be reality) are present while allowing for the presentation of memory item combinations which may transcend the limits of physical reality. The results of the four studies are discussed in light of how REM and SWS sleep stages are differentially involved in specific aspects of episodic memory (episodic replay vs. episodic novelty) and the possible role that dreaming, as a driver of synaptic plasticity, may have in these relationships.

mémoire épisodique

episodic memory

sommeil paradoxal

REM sleep

sommeil aux ondes lentes

slow wave sleep

rêves

dreaming

réalité virtuel

virtual reality

Physiopathologie du somnambulisme : étude de l’activité cérébrale en sommeil lent profond via la Tomographie d’Émission Monophotonique (TEMP) et l'analyse de connectivité fonctionnelle cérébrale

Desjardins, Marie-Ève

08 1900

No description available.

somnambulisme

parasomnie

imagerie cérébrale

EEG

connectivité fonctionnelle cérébrale

sommeil lent profond

physiopathologie

somnambulism

parasomnias

brain imaging

Slow-wave sleep

pathophysiology

functional connectivity

The Role of Slow-Wave-Sleep in Hippocampus-Dependent Memory in Aging and Alzheimer's Disease

Ogbeide-Latario, Oghomwen

28 April 2021

Aging and Alzheimer’s disease (AD), are associated with disabling sleep and cognitive deficits. Specifically, aging and Alzheimer’s disease is associated with reduced quantity and quality of the deepest stage of sleep, called slow-wave-sleep (SWS). Interestingly, SWS has been implicated in hippocampus-dependent memory in mice. More importantly, sleep deprivation, aging, and AD are all associated with deficits in memory. Therefore, I hypothesize that, in aging and AD, the sleep deficits are, at least in part, responsible for memory impairments and increasing the quantity and quality of SWS will reverse these memory deficits. I first developed mouse models of SWS enhancement in aging and AD. Chemogenetic activation of the parafacial zone GABAergic neurons enhances SWS in aged mice as previously described in adult mice. Similarly, in AD mice, SWS enhancement is as effective as in littermate wild-type controls. Then, I used these mouse models to characterize the role of SWS in memory using novel gain-of-sleep experiments. I found that acute SWS enhancement: 1) reduce spatial memory in adult mice and 2) failed to improve spatial memory in aged mice. In a preliminary study, acute SWS enhancement seems to improve contextual memory in AD mice. Collectively, my work provides a novel mouse model of SWS enhancement in aging and AD, offering a pivotal tool to study the role of SWS in physiological functions and neurodegenerative diseases. Furthermore, my results suggest that acute SWS enhancement does not benefit the behavioral manifestation of memory consolidation in adult mice and aged mice.

Slow-wave-Sleep enhancement

Hippocampus-dependent memory

Aging

Alzheimer's Disease

APP/PS1 mice

Mouse Models

Slow Wave Activity

Chemogenetics

Behaviour

Behavioral Neurobiology

Cognitive Neuroscience

Neuroscience and Neurobiology

The role of sleep and dreaming in the processing of episodic memory

Stenstrom, Philippe

06 1900

La présente thèse examine les liens entre le sommeil, la mémoire épisodique et les rêves. Dans une première étude, nous utilisons les technologies de la réalité virtuelle (RV) en liaison avec un paradigme de privation de sommeil paradoxal et de collecte de rêve en vue d'examiner l'hypothèse que le sommeil paradoxal et le rêve sont impliqués dans la consolidation de la mémoire épisodique. Le sommeil paradoxal a été associé au rappel des aspects spatiaux des éléments émotionnels de la tâche RV. De la même façon, l'incorporation de la tâche RV dans les rêves a été associée au rappel des aspects spatiaux de la tâche. De plus, le rappel des aspects factuels et perceptuels de la mémoire épisodique, formé lors de la tâche VR, a été associé au sommeil aux ondes lentes. Une deuxième étude examine l'hypothèse selon laquelle une fonction possible du rêve pourrait être de créer de nouvelles associations entre les éléments de divers souvenirs épisodiques. Un participant a été réveillé 43 fois lors de l'endormissement pour fournir des rapports détaillés de rêves. Les résultats suggèrent qu'un seul rêve peut comporter, dans un même contexte spatiotemporel, divers éléments appartenant aux multiples souvenirs épisodiques. Une troisième étude aborde la question de la cognition lors du sommeil paradoxal, notamment comment les aspects bizarres des rêves, qui sont formés grâce aux nouvelles combinaisons d'éléments de la mémoire épisodique, sont perçus par le rêveur. Les résultats démontrent une dissociation dans les capacités cognitives en sommeil paradoxal caractérisée par un déficit sélectif dans l'appréciation des éléments bizarres des rêves. Les résultats des quatre études suggèrent que le sommeil aux ondes lentes et le sommeil paradoxal sont différemment impliqués dans le traitement de la mémoire épisodique. Le sommeil aux ondes lentes pourrait être implique dans la consolidation de la mémoire épisodique, et le sommeil paradoxal, par l'entremise du rêve, pourrais avoir le rôle d'introduire de la flexibilité dans ce système mnémonique. / The present dissertation examines relationships between sleep, episodic memory and dreaming. In Articles I and II we use a novel virtual reality (VR) task in conjunction with a rapid eye movement (REM) sleep deprivation (REMD) paradigm and dream sampling to examine the hypothesis that REM sleep and dreaming are involved in the consolidation of episodic memory. REM sleep was associated with the successful recall of the spatial aspects of emotionally charged elements of the VR task. Similarly, dreaming was associated with improved performance on the spatial aspects of the recall task. Recall of the factual and perceptual aspects of episodic memories formed with the VR task was associated with increased slow wave sleep (SWS) during the post-exposure night. Overall, the results suggest that SWS is associated with the perceptual and factual aspects of episodic memories while REM sleep is not, a finding which may relate to observations that REM sleep dreaming is composed of deconstructed fragments of loosely associated episodic memories. Study II examines the hypothesis that a function of dreaming may be to create new associations between previously unrelated memory items. A participant, highly trained in introspection and mentation reporting, was awakened 43 times during theta bursts at sleep onset and provided detailed reports of resulting imagery and associated memory sources. This technique provided evidence that elements of distally related memory sources are brought together in temporal and spatial proximity within a novel context provided by the dream, suggesting a role for dreaming in memory processing. To allow for this possibility, we speculate that dreaming experiences may be functionally equivalent to waking experiences in their ability to induce neural plasticity. Study III addresses an aspect of this functional equivalence by examining if dream bizarreness is incompatible with behavioral and cognitive features associated with waking state experience-driven plasticity, i.e., whether the dreamer can act upon, emote and be motivated towards an element of the dream that is bizarre and that violates basic assumptions of physical reality. The results demonstrate a dissociation in cognitive ability during dreaming characterized by a selective deficiency in appreciating bizarreness in face of a maintained ability for logical thought. This finding thus addresses the problem of the wake-like mind reflecting upon dream bizarreness and suggests that dreaming is a state in which the cognitive aspects associated with synaptic plasticity (attention, emotion and motivation associated with believing a situation to be reality) are present while allowing for the presentation of memory item combinations which may transcend the limits of physical reality. The results of the four studies are discussed in light of how REM and SWS sleep stages are differentially involved in specific aspects of episodic memory (episodic replay vs. episodic novelty) and the possible role that dreaming, as a driver of synaptic plasticity, may have in these relationships.

mémoire épisodique

episodic memory

sommeil paradoxal

REM sleep

sommeil aux ondes lentes

slow wave sleep

rêves

dreaming

réalité virtuel

virtual reality

Estudo da topologia de redes de conex?o funcional no c?rtex sensorial prim?rio e hipocampo durante o sono de ondas lentas

Batista, Edson Anibal de Macedo Reis

30 July 2013

Made available in DSpace on 2014-12-17T14:56:17Z (GMT). No. of bitstreams: 1 EdsonAMRB_DISSERT.pdf: 7502344 bytes, checksum: 78d70443ae2fd9033fe78b23c5cbd811 (MD5) Previous issue date: 2013-07-30 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior / Complex network analysis is a powerful tool into research of complex systems like brain networks. This work aims to describe the topological changes in neural functional connectivity networks of neocortex and hippocampus during slow-wave sleep (SWS) in animals submited to a novel experience exposure. Slow-wave sleep is an important sleep stage where occurs reverberations of electrical activities patterns of wakeness, playing a fundamental role in memory consolidation. Although its importance there s a lack of studies that characterize the topological dynamical of functional connectivity networks during that sleep stage. There s no studies that describe the topological modifications that novel exposure leads to this networks. We have observed that several topological properties have been modified after novel exposure and this modification remains for a long time. Major part of this changes in topological properties by novel exposure are related to fault tolerance / A an?lise da topologia de redes ? uma poderosa ferramenta no estudo de sistemas complexos tal como as redes cerebrais. Este trabalho procura descrever as mudan?as na topologia de redes de conex?o funcional em neur?nios do c?rtex sensorial e do hipocampo durante o sono de ondas lentas (SWS) em animais expostos ? novidade. O sono de ondas lentas ? um importante estado do sono onde h? reverbera??o de padr?es de atividade el?trica ocorridos na vig?lia, tendo com isso papel fundamental na consolida??o de mem?ria. Apesar de sua import?ncia ainda n?o h? estudos que caracterizam a din?mica da topologia de redes de conex?o funcional durante este estado. Tampouco h? estudos que descrevem as modifica??es topol?gicas que a exposi??o ? novidade traz a essas redes. Observamos que v?rias propriedades topol?gicas s?o modificadas ap?s a exposi??o ? novidade e que tais modifica??es se mant?m por um longo per?odo de tempo. A maior parte das propriedades modificadas pela exposi??o ? novidade est? relacionada ? toler?ncia ? falha

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA

Akustická stimulácia pomalovlnného spánku a jej vplyv na konsolidáciu pamäti u ľudí trpiacich nespavosťou / Acoustic stimulation of Slow wave sleep and its influence on consolidation of declarative memory in insomnia

Orendáčová, Mária

January 2019

Slow-wave sleep plays an important role in consolidation of declarative memory. From electrophysiological point of view, this process is dependent on a common occurrence and mutual integration of neocortical slow oscillations (< 1 Hz), hippocampal sharp-wave ripples (150-250 Hz) and thalamo-cortical sleep spindles (10-15 Hz). Previous studies demonstrated that periodic acoustic stimulation by pink noise pulses applied at frequency of sleep slow oscillation during slow wave sleep leads to prolongation of slow wave sleep and to enhancement in declarative memory performance in normal sleepers. Our study investigated this kind of periodic acoustic stimulation in its relation to sleep architecture and declarative memory of people suffering from insomnia due to which there often comes to a reduction in slow wave sleep which positively correlates with worsening of declarative memory performance. Our aim was to investigate if this kind of comparatively non-invasive brain stimulation has a potential to increase a total length of slow wave sleep and enhance declarative memory performance in insomnia. Our study revealed acoustic stimulation neither improved declarative memory performance nor it increased total length of slow-wave sleep. No positive association was found between level of declarative memory...

Implication of EphA4 in circadian and sleep physiology studied using transcriptional and pharmacological approaches

Ballester Roig, Maria Neus

08 1900

Le sommeil est un comportement qui occupe un tiers de notre vie. L'horaire, la durée, et la qualité du sommeil sont contrôlés par deux processus principaux : la régulation homéostatique du sommeil et l’horloge qui synchronise les rythmes circadiens internes. EPHA4 est une molécule d'adhésion cellulaire qui régule la neurotransmission et qui est exprimée dans des régions cérébrales impliquées dans la régulation circadienne et du sommeil. De manière intéressante, le gène EphA4 contient des éléments régulateurs des facteurs de transcription circadiens et les souris Clock mutantes voient leur expression d’EphA4 modifiée. De plus, les souris EphA4 knockout (KO) ont des rythmes circadiens d’activité locomotrice anormaux, moins de sommeil paradoxal dans la période de lumière, et une distribution des oscillations cérébrales du sommeil modifiée sur un cycle de 24 heures. Par conséquent, et étant donné que EPHA4 est crucial pour le neurodéveloppement, il convient d’explorer si les phénotypes du sommeil/circadiens observés chez les souris EphA4 KO proviennent d'effets sur le développement ou des rôles d'EPHA4 dans la fonction neuronale adulte. Par ailleurs, les mécanismes de régulation transcriptionnelle d'EphA4 sont encore méconnus. Dans cette thèse, nous avons émis les hypothèses que i) l'expression du gène EphA4 ou de leurs ligands Éphrines (Efns) est régulée de manière circadienne ; et ii) que le modulateur de l’activité d’EPHA4 rhynchophylline (RHY) modifie le sommeil chez les souris adultes d'une manière qui ressemble au phénotype EphA4 KO. L'étude I montre que les facteurs de transcription de l’horloge (CLOCK/NPAS2 et BMAL1) activent la transcription via les éléments de réponse à l'ADN «boîtes E» trouvées dans les promoteurs putatifs d'EphA4, EfnB2 et EfnA3 in vitro. Cependant, les protéines EPHA4 et EFNB2 n’ont pas montré une oscillation circadienne dans le cortex préfrontal et les noyaux suprachiasmatiques (horloge principale) de souris. Dans le projet II, l'effet de RHY sur le sommeil a été étudié chez des souris mâles et femelles avec des enregistrements electroencéphalographiques. Nos données ont démontré que RHY prolonge le sommeil à onde lente, mais les effets sur le sommeil paradoxal dépendent de l’heure d’injection. RHY modifie aussi les oscillations cérébrales pendant l’éveil et le sommeil. Tous ces effets sont notablement plus marqués chez les femelles, ce qui souligne l’importance d’étudier les deux sexes lors des essais pharmacologiques. La transcriptomique spatiale cérébrale révèle que RHY modifie des transcrits liés à des réponses d’inflammation dans tout le cerveau, mais qu'elle affecte l'expression génique des neuropeptides associés à la régulation du sommeil et hypophysaires particulièrement dans l’hypothalamus. En outre, RHY affecte l'expression des gènes de la transcription/traduction de manière diffèrent selon l’heure d’injection. La première publication met en évidence que la régulation transcriptionnelle d’EphA4 et des Efns pourraient expliquer quelques-uns des phénotypes observés chez les souris KO. La deuxième publication démontre que RHY induit le sommeil chez la souris et souligne l’importance de caractériser des mécanismes inexplorés sous-jacents aux composés naturels. Décrire la régulation moléculaire du sommeil peut apporter des éclairages utiles pour la chronopharmacologie. / Sleep is a behavior which occupies a third of our lifetime. The schedule, the duration and the quality of sleep are controlled by two main processes: the homeostatic sleep regulation and the clock that synchronizes the internal circadian rhythm. EPHA4 is a cell adhesion molecule regulating neurotransmission and is expressed in brain centers regulating sleep and circadian rhythms. Interestingly, the EphA4 gene contains regulatory elements for circadian transcription factors, and Clock mutant mice have altered EphA4 expression. Moreover, EphA4 knockout mice (KO) have abnormal circadian rhythms of locomotor activity, less paradoxical sleep in the light period and altered sleep brain oscillations across the 24 hours. Given that EPHA4 is crucial for development, it should be investigated whether the sleep/circadian phenotypes observed in EphA4 KO originate from developmental effects or from roles of EPHA4 in adult neuronal function. Moreover, very little is known about the transcriptional regulation of EPHA4. Thus, the hypotheses of this thesis were that i) the gene expression of EphA4 or that of its ligands Ephrins (Efns) is regulated in a circadian manner; and ii) that the modulator of EPHA4 activity rhynchophylline (RHY) modifies sleep in adult mice in manners that resemble the EphA4 KO phenotype. Project I demonstrates that the clock transcription factors (CLOCK/NPAS2 et BMAL1) activate transcription via the DNA regulatory elements “E-boxes” found in the putative promoters of EphA4, EfnB2 and EfnA3 in vitro. Nevertheless, EPHA4 and EFNB2 proteins did not show a circadian oscillation in the mouse prefrontal cortex and suprachiasmatic nuclei (master clock). In project II, the effect of RHY on sleep was studied in male and female mice with electroencephalographic recordings. RHY extends slow wave sleep and effects on paradoxical sleep depended on the time-of-injection. RHY also modified the brain oscillations during wakefulness and sleep. Importantly, all these effects were larger in females, which highlights the need to consider both sexes in pharmacological studies. Brain spatial transcriptomics reveals that RHY modifies transcripts linked to inflammatory responses throughout the brain, while it affects transcripts linked to sleep regulation and pituitary responses particularly in the hypothalamus. Moreover, RHY affected the expression of genes for transcription/translation differently depending on the time of injection. The first publication underscores that the transcriptional regulation of EphA4 and Efns may underly some of the phenotypes observed in the KO mice. The second publication demonstrates that RHY induces sleep in mice, that it modifies brain activity associated to cognitive processes and highlights the importance of characterizing unexplored mechanisms of natural compounds. Describing the molecular regulation of sleep may provide useful insights for chronopharmacology.

Circadian rhythm

Slow wave sleep

Paradoxical sleep

Ephrins

Traditional medicine

Rhynchophylline

Spatial transcriptomics

Clock transcription factors

Transcription

Rythme circadien

Sommeil à onde lente

Sommeil paradoxal

Éphrines

Médecine traditionnelle

Rhynchophylline

Transcriptomique spatiale

Facteurs de transcription de l’horloge

Transcription