Rôle de la neurogenèse hippocampique adulte dans la stabilisation à long terme de la mémoire spatiale / Role of adult hippocampal neurogenesis in spatial memory stabilization

Lods, Marie

06 December 2018

La neurogenèse hippocampique adulte fait référence à la création de neurones durant la vie adulte dans le gyrus denté de l’hippocampe. Une décennie de recherche a démontré l’importance de cette neurogenèse chez l’adulte dans les processus de mémoire. En particulier, la neurogenèse adulte est nécessaire à l’apprentissage spatial et l’apprentissage spatial lui-même augmente la survie et accélère le développement d’une population de nouveaux neurones immatures. Cependant, l’implication de ces nouveaux neurones « sélectionnés » par l’apprentissage dans le devenir de la mémoire reste incertaine. En conséquence, le travail de cette thèse porte sur l’étude du rôle de ces nouveaux neurones dans les processus de mémoire spatiale à long terme résultants de l’apprentissage d’origine, comme la restitution et la reconsolidation de la mémoire. En effet depuis plus d’un siècle, on sait qu’un apprentissage n’induit pas immédiatement une mémoire stable. Les souvenirs sont tout d’abord fragiles, puis vont au fil du temps devenir stables et insensibles aux perturbations via un processus appelé «consolidation de la mémoire». Cependant ce processus n’est pas immuable ; les souvenirs établis peuvent à nouveau devenir labiles lorsqu'ils sont rappelés ou réactivés lors d’une restitution de la mémoire. Cette déstabilisation d’une mémoire consolidée nécessite alors un nouveau processus de stabilisation appelé « reconsolidation de la mémoire ». Depuis sa découverte, la reconsolidation a vivement intéressé le milieu de la recherche sur la mémoire et un nombre croissant d’études a cherché à comprendre les mécanismes sous-tendant cette reconsolidation, en particulier dans l'hippocampe. Étonnamment, le processus de reconsolidation n’a été que très peu envisagé dans le contexte de la neurogenèse hippocampique adulte.Nous avons tout d’abord mis au point un protocole de reconsolidation de la mémoire spatiale du rat dans le labyrinthe aquatique de Morris. Cela nous a permis de montrer que les néo-neurones nés avant l’apprentissage étaient activés lors de la reconsolidation de la mémoire spatiale, ce qui n’est pas le cas des neurones issus du développement précoce. Afin de pouvoir établir une relation de causalité entre néo-neurones et processus de reconsolidation, nous avons ensuite développé un outil basé sur la technique pharmacogénétique des DREADDs (Designer Receptors Exclusively Activated by Designer Drugs) couplés à un rétrovirus. Cet outil permet de marquer les néo-neurones à leur naissance et de les manipuler (inhiber ou stimuler l’activation) plus tard, lors des processus de mémoire à long terme. Nous avons observé que les néo-neurones immatures modifiés par l’apprentissage étaient non seulement activés par la reconsolidation mais également nécessaire à celle-ci, à l’inverse des néo-neurones matures au moment de l’apprentissage. Nous avons enfin montré que stimuler l’activité des néo-neurones au moment de la restitution de la mémoire améliorait les performances des rats dans le labyrinthe aquatique.Ensemble, ces résultats de thèse soulignent le rôle critique de la neurogenèse hippocampique adulte dans la stabilisation de la mémoire spatiale à long terme. / Adult hippocampal neurogenesis refers to the creation of neurons during adult life in the dentate gyrus of the hippocampus. A decade of research has demonstrated the importance of this adult neurogenesis in memory processes. In particular, adult neurogenesis is necessary for spatial learning and spatial learning itself increases survival and accelerates the development of a population of new immature neurons. However, the involvement of these new modified / promoted / amplified / selected neurons by learning in the fate of memory remains unclear. The work of this thesis focuses on the study of the role of these new neurons in the long-term spatial memory processes resulting from the original learning, such as retrieval and reconsolidation.For more than a century, we know that learning does not immediately induce a stable memory. Memories are fragile at first and then become stable and insensitive to interferences over time, through a process called “memory consolidation". However this process is not immutable; the established memories can become labile again when they are reactivated during memory recall. This destabilization of a consolidated memory requires then a new stabilization process called "memory reconsolidation". Since its discovery, the reconsolidation process has strongly interested the memory research community and a growing number of studies have sought to understand the mechanisms underlying this reconsolidation, particularly in the hippocampus. Surprisingly, the process of reconsolidation has rarely been considered in the context of adult hippocampal neurogenesis.We first developed a protocol for memory reconsolidation of spatial memory in the Morris water maze in rats. This allowed us to show that new neurons born before learning were activated during reconsolidation of spatial memory, which is not the case of the neurons generated during the early development. In order to establish a causal relationship between new neurons and reconsolidation, we developed a tool based on the pharmacogenetic technique of DREADDs (Designer Receptors Exclusively Activated by Designer Drugs) coupled with a retrovirus. This tool is used to tag new neurons at their birth and manipulate them (inhibit or stimulate their activation) later during long-term memory processes. We observed that the population of neurons that were immature at the time of learning are not only activated by but also necessary for reconsolidation, unlike new neurons that were mature at the time of learning. We have finally shown that stimulating the activity of new neurons during retrieval improves the performance of rats in the water maze.All together, these thesis results highlight the critical role of adult hippocampal neurogenesis in long-term spatial memory stabilization.

Neurogenèse adulte

Reconsolidation de la mémoire spatiale

Piscine de Morris

Dreadds

Adult neurogenesis

Spatial memory reconsolidation

Morris watermaze

Dreadds

Therapeutic Potential of FAK Inhibitor After Stroke in Neuroprotection and Neurogenesis

Malone, Hannah M, Jia, Cuihong, Phd, Hagg, Theo, MD, Phd

12 April 2019

Stroke increases neurogenesis (birth of new neurons) through upregulation of ciliary neurotrophic factor (CNTF), a potent neurogenic cytokine made almost exclusively in the central nervous system. Previous study found that CNTF is induced and needed to stimulate neurogenesis in the subventricular zone (SVZ) of mouse brain in a stroke model. CNTF also has a neuroprotective function. Focal adhesion kinase (FAK), protein tyrosine kinase 2, is ubiquitously expressed in various cell types and mediates cell adhesion and migration. We previously discovered that systemic inhibition of FAK upregulates CNTF expression in the SVZ, making FAK a pharmacological target to increase CNTF to promote neurogenesis and neuroprotection after stroke. This study examined whether systemic FAK inhibitor treatment after stroke regulates SVZ neurogenesis and neuroprotection using a middle cerebral artery occlusion (MCAO) to induce a stroke in adult male C57BL/6 mice. A filament was inserted in the external carotid artery and then fed through the carotid bifurcation into the internal carotid artery to the base of the middle cerebral artery. After 30 minutes of occlusion, the filament was removed to restore blood flow. Mice were randomly assigned to receive 3 daily doses of saline or FAK inhibitor (FAK14, i.p., 3 mg/kg) and treatment started at 6 hours, 12 days, or 58 days after MCAO. Because CNTF has a neuroprotective function, the amount of tissue damage was analyzed to compare treatment groups. The neuroprotective role of FAK14 was examined by measuring MCAO-induced infarction. The infarct size was measured using the absence of NeuN (neuronal cell marker) and GFAP (activated astrocytes) and presence of CD68 (activated microglia). FAK14 given at 6 hours post-stroke reduced the infarct size to 38% of the uninjured side of the brain compared to 46% with saline. Proliferating cells were labeled by injecting bromodeoxyuridine (BrdU, 50 mg/kg), the mice were processed 2 h after the last BrdU injection, and proliferated cells in the SVZ were counted with unbiased stereology. There were no significant differences in the total numbers of BrdU+ cells between saline and FAK14 at 3, 14 and 60 days. Future studies are needed to confirm the levels of CNTF at the various times of treatment. If there is no difference in CNTF expression or increased expression of counteracting cytokines, no difference in neurogenesis between groups would be expected. The neuroprotective effect of FAK14 during the acute phase following injury could provide novel pharmacological options to stroke patients extending the current therapeutic treatment window.

CNTF

FAK

neurogenesis

neuroprotection

stroke

Healthcare and Medicine

Traumatic Brain Injury

Stroke

Environmental Stimuli Activates Early Growth Response 3 (EGR3), an Immediate Early Gene Residing at the Center of a Biological Pathway Associated with Risk for Schizophrenia

January 2020

abstract: Schizophrenia, a debilitating neuropsychiatric disorder, affects 1% of the population. This multifaceted disorder is comprised of positive (hallucinations/psychosis), negative (social withdrawal/anhedonia) and cognitive symptoms. While treatments for schizophrenia have advanced over the past few years, high economic burdens are still conferred to society, totaling more than $34 billion in direct annual costs to the United States of America. Thus, a critical need exists to identify the factors that contribute towards the etiology of schizophrenia. This research aimed to determine the interactions between environmental factors and genetics in the etiology of schizophrenia. Specifically, this research shows that the immediate early gene, early growth response 3 (EGR3), which is upregulated in response to neuronal activity, resides at the center of a biological pathway to confer risk for schizophrenia. While schizophrenia-risk proteins including neuregulin 1 (NRG1) and N-methyl-D-aspartate receptors (NMDAR’s) have been identified upstream of EGR3, the downstream targets of EGR3 remain relatively unknown. This research demonstrates that early growth response 3 regulates the expression of the serotonin 2A-receptor (5HT2AR) in the frontal cortex following the physiologic stimulus, sleep deprivation. This effect is translated to the level of protein as 8 hours of sleep-deprivation results in the upregulation of 5HT2ARs, a target of antipsychotic medications. Additional downstream targets were identified following maximal upregulation of EGR3 through electroconvulsive stimulation (ECS). Both brain-derived neurotrophic factor (BDNF) and its epigenetic regulator, growth arrest DNA-damage-inducible 45 beta (GADD45B) are upregulated one-hour following ECS in the hippocampus and require the presence of EGR3. These proteins play important roles in both cellular proliferation and dendritic structural changes. Next, the effects of ECS on downstream neurobiological processes, hippocampal cellular proliferation and dendritic structural changes were examined. Following ECS, hippocampal cellular proliferationwas increased, and dendritic structural changes were observed in both wild-type and early growth response 3 knock-out (Egr3-/-) mice. Effects in the number of dendritic spines and dendritic complexity following ECS were not found to require EGR3. Collectively, these results demonstrate that neuronal activity leads to the regulation of schizophrenia risk proteins by EGR3 and point to a possible molecular mechanism contributing risk for schizophrenia. / Dissertation/Thesis / Doctoral Dissertation Neuroscience 2020

Psychobiology

Genetics

Health sciences

Electroconvulsive Stimulation

Immediate Early Genes

Neurogenesis

Neurotrophic Factors

Schizophrenia

Serotonin 2A-receptor

An Adult Zebrafish Brain Atlas To Investigate Shh Mediated Cell-Cell Signaling In Neurogenic Zones

Lutservitz, Alyssa P

24 March 2017

Adult neurogenesis occurs in proliferative zones of the brain that contain neural progenitor cell populations capable of differentiating into specific cell types. However, we remain limited in our understanding of the signals that regulate neural progenitor cell proliferation and differentiation in adults. Recently zebrafish (Danio rerio) have emerged as an excellent model for studying the molecular mechanisms behind adult neurogenesis, because sixteen proliferative zones remain active in the adult brains. Thousands of fluorescent transgenic reporter lines have been generated in zebrafish that reveal gene expression patterns of cell-cell signaling systems, some of which may regulate neurogenesis in these brain regions. Using a new tissue clearing technique and whole brain imaging with fluorescent light sheet microscopy (FLSM) we have generated the first 3-Dimensional atlas of gene expression in an intact adult zebrafish brain. So far we have created a reference brain image and have aligned the expression patterns from three transgenic lines. This work is a preliminary step in the generation of a new, open access brain atlas called the Zebrafish Adult Brain Browser (ZABB). While generating this atlas we focused on documenting the adult brain regions responsive to Sonic Hedgehog (Shh), a cell-cell signaling system known to regulate neurogenesis during embryonic development. We used two Shh-reporter lines to create another atlas comparing reporter transgene expression in whole brain and sectioned tissue to the expression of the Hedgehog (Hh) target gene ptch2 using in situ hybridization. We show that the reporter lines reveal different Hh responsive domains, but together identify fourteen Hh responsive regions in the brain, nine of which are known proliferative zones. Thus, it appears that subsets of both proliferating neural progenitors and non-proliferative cells remain Hh responsive in adult brains. Our data suggests that Hh signaling contributes to the regulation of neural progenitor cells in nine of the sixteen proliferative zones. Uncovering the molecular mechanisms behind adult neurogenesis and forming a greater understanding of adult neural stem cell regulation has the potential to influence the treatment of many neurodegenerative diseases and cancers.

neurogenesis

proliferative zones

Sonic Hedgehog

zebrafish

Biology

Cell and Developmental Biology

Life Sciences

Colocalization of neuronal ceroid lipofuscinosis proteins suggests a common pathway involved in embryonic and adult neurogenesis

Migliozzi, Madyson

24 November 2021

The neuronal ceroid lipofuscinoses (NCLs) are a family of neurodegenerative diseases predominantly affecting infants and children, which in some cases can present into adulthood. There are fourteen genes comprising the 13 known subtypes of NCLs (CLN1-CLN8, CLN10-CLN14; CLN9 has been reclassified as CLN4). The NCL diseases share common molecular and clinical features, including cellular accumulation of autofluorescent storage material, characteristic histological findings (curvilinear inclusions, fingerprint profiles, and granular osmophilic deposits), markedly low brain weight, seizures, blindness, motor dysfunction and behavioral disabilities. Though the functions of the CLN proteins are not fully understood, they are mainly localized to the lysosomal compartment and autophagic pathway. Previous works have focused on understanding the individual functions of the CLN proteins. However, there is little research examining the interactions between CLN proteins and their involvement in neurogenesis. The CLN proteins also show involvement in various other signaling pathways, notably the mTOR and p53 pathways, and may therefore have implication as important signaling molecules during development and aging. In this thesis, I outline a variety of interactions between CLN proteins, as well as their role in lysosome formation and autophagy. I further examine the involvement of these proteins in lysosomes of microglia, and potential functions of microglia during neurogenesis in childhood and adulthood. I hypothesize that the CLN proteins are likely involved in a common pathway which is highly regulated during neurogenesis through microglial release of pro-inflammatory molecules. Though these diseases are incurable, enzyme replacement shows promise as a treatment for NCL; cerliponase alpha (BioMarin Pharmaceuticals) is the first and only FDA-approved enzyme replacement treatment for CLN2 disease. Future in-depth investigation of protein-protein interactions as well as their involvement in signaling pathways during development is necessary in order to find a cure for these devastating diseases.

Neurosciences

Lysosomal storage disorders

Lysosome

Microglia

Neurodegenerative disorders

Neurogenesis

Neuronal ceroid lipofuscinosis

Sonic hedgehog expands neural stem cells in the neocortical region leading to an expanded and wrinkled neocortical surface / Sonic hedgehogは大脳新皮質領域の神経幹細胞数を増大させ、大脳新皮質表面積の拡大と皺形成をもたらす

MOHAMMED, J.M. SHQIRAT

24 September 2021

京都大学 / 新制・課程博士 / 博士(医学) / 甲第23464号 / 医博第4771号 / 新制||医||1053(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 林 康紀, 教授 伊佐 正, 教授 高橋 淳 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Brain Morphogenesis

Mouse

Sonic Hedgehog

neocortical development

Neurogenesis

Neural Stem Cells

490

Effects of Fluoxetine/Simvastatin/Ascorbic Acid Combination Treatment on Neurogenesis and Functional Recovery in a Model of Multiple Sclerosis

Webb, Cameron Olivia

13 August 2021

No description available.

Neurosciences

Neurobiology

Physiology

Pharmacology

multiple sclerosis

neurogenesis

subventricular zone

doublecortin

Montoya Staircase

fluoxetine

simvastatin

ascorbic acid

Expanding neurons in the developing murine brain: effects on perinatal cortical histology and implications on cognition in adulthood

Darmis, Fragkiskos

23 September 2021

Cognition is a trait of great evolutionary importance in complex organisms, but the driving factors of its evolution are still poorly understood. It is proposed that different formula variants of the encephalization index (brain to body weight ratio) might be able to serve as predictive indicators of intelligence between species, but this remains highly controversial, predominantly because of their inability to reliably validate empirical knowledge. Another proposed predictive index for intelligence has been the total neuron count in animals’ brains. There is, though, a lack of comparative and quantitative behavioral data in support of any of the proposed models, especially across non-human mammals. Total neuron count is controlled by the process of neurogenesis during development, which is directly involved in shaping brain’s dimensions. It is known that neural stem cells increasingly shift from proliferative divisions towards differentiating (or neurogenic) divisions during development. One possible approach to alter cortical topology is by manipulating the stem cell division in order to generate more neurons. It has previously been shown that one of the main factors known to influence the type of cell division mode is the length of the cell cycle and specifically the length of G1 phase. The main constituents driving progression through G1 phase are Cdk4 and Cyclin D1 (4D for simplicity) and overexpression of these proteins in neural stem cells results in a shortening of their cell cycle, leading to expansion of the progenitor cell pool at the expense of newborn neurons. Upon silencing 4D, development is allowed to continue normally and thus, the excess of progenitor cells ultimately contributes to an increased generation of neurons. Intriguingly, transient 4D overexpression during corticogenesis in transgenic mice leads to the development of brains with increased encephalization index as a result of an increase in the total neuron count, without altering cortical lamination or preventing cortical layering. In this study, I further characterize the effects of developmentally-induced 4D neurogenesis in the developing and adult mouse brain. Moreover, with the use of different cognitive tests designed to assess differences in processes such as learning, spatial navigation, motor coordination, and context iscrimination, I attempt to identify quantifiable changes in these processes between mice with increased neuron count and controls. I hypothesize that a general intelligence ranking between groups can be obtained by analyzing collective data from several tests. Altogether, my work provides a better understanding of the contribution of increased neurogenesis both in developmental processes of the cortex as well as in animal cognition and behavior.

Säugetierneurogenese, Neuron, Kognition

info:eu-repo/classification/ddc/610

ddc:610

Etude de la neurogenèse hippocampique adulte et des fonctions cognitives chez trois souris modèles de déficience intellectuelle / Adult Hippocampal Neurogenesis and Cognitive Functions in Three Mouse Models of Intellectual Disability

Castillon, Charlotte

12 March 2018

Les dernières années témoignent d'une remarquable accélération dans la compréhension des facteurs génétiques impliqués dans la déficience intellectuelle (DI) et de nombreux gènes responsables ont été identifiés. Néanmoins, les mécanismes cellulaires et moléculaires sous-jacents à la DI sont encore mal connus. Une hypothèse attractive est que les mutations à l’origine de DI affectent la neurogenèse hippocampique adulte (NGA), une forme de plasticité qui joue un rôle crucial dans la mémoire. L'objectif de ce projet est d’entreprendre une analyse comparative de la NGA chez trois modèles murins de pathologies d’origine génétique, menant à une DI sévère, impliquant des gènes localisés sur le chromosome X et participant à différentes voies de signalisation susceptibles de moduler la NGA : le syndrome de Coffin-Lowry (gène rsk2), la dystrophie musculaire de Duchenne (gène dmd) et une DI liée au gène pak3. Mes recherches actuelles montrent que ces trois modèles présentent des déficits cognitifs dépendants de l’hippocampe, dont des altérations de la fonction de séparation de patterns. Nous avons également mis en évidence des altérations de la NG adulte, avec, entre autres, des altérations du recrutement des jeunes neurones par l’apprentissage qui pourraient contribuer aux déficits cognitifs observés en particulier dans la fonction de séparation de patterns. Toutefois, selon les gènes en cause, les déficits ne sont pas observés dans les mêmes étapes de la NGA ni dans les mêmes situations comportementales. L’ensemble de ces résultats laisse donc suggérer que chacun des gènes étudiés pourrait jouer un rôle différent dans la NGA, mais qu'in fine des altérations de cette forme de plasticité contribuent, au moins en partie, aux déficits cognitifs associés à la DI dans les trois modèles. Ensemble, ces résultats apportent des informations supplémentaires qui seront directement pertinentes pour d’autres pathologies neuro-développementales conduisant à des déficits cognitifs liés à des altérations de la NG, et pourraient ouvrir de nouvelles pistes thérapeutiques. / Recent years have shown a remarkable acceleration in the understanding of genetic factors involved in intellectual disability (ID) and many genes responsible have been identified. However, the cellular and molecular underlying mechanisms are still poorly understood. An attractive hypothesis is that mutations causing ID may affect adult hippocampal neurogenesis (ANG), a form of plasticity that plays a crucial role in learning and memory. The objective of this project was to undertake a comparative analysis of adult hippocampal neurogenesis in three mouse models of genetic diseases involving genes located on the X chromosome and participating in different signalling pathways that may modulate ANG: the Coffin-Lowry syndrome (rsk2 gene), Duchenne muscular dystrophy (dmd gene) and ID due to mutation of the pak3 gene. My current research shows that these three models present hippocampal dependent cognitive deficits. Among these deficits, major deficits in spatial pattern separation function have been highlighted. We also showed specific alterations of basal ANG, together with alterations in the recruitment of young newborn neurons by learning that could contribute to the observed cognitive deficits, in particular in pattern separation function. However, depending on the genes involved, the deficits are not observed in the same steps of adult NG and in the same behavioural situations. In all, the results suggest that each of the genes plays a different role in ANG, but finally that alterations of this form of plasticity may contribute to the cognitive deficits associated with ID in the three models. Together, these results provide additional information that will be directly relevant to other neurodevelopmental disorders leading to cognitive deficits related to NG alterations, and could open new therapeutic tracks.

Neurogenèse hippocampique adulte

Déficience intellectuelle

Fonctions cognitives

Adult hippocampal neurogenesis

Intellectual disability

Cognitive functions

Rôle de microARN-9 dans la régulation de l'état cellule souche neural chez l'adulte / Role of MicroRNA-9 in Regulating Adult Neural Stem Cell State

Katz, Shauna

13 November 2015

Depuis la découverte fondatrice de la présence de cellules souches neurales (NSCs) multipotentes dans le cerveau des mammifères adultes, plusieurs études ont révélé l'importance de ces cellules pour le maintien de l'homéostasie du cerveau. Notamment, des perturbations dans l'équilibre des NSCs ont été associées au vieillissement et à diverses pathologies neurologiques, ce qui suscite un intérêt croissant pour ces cellules. Les NSCs résident dans des zones germinatives restreintes; dans le rongeur adulte les NSCs sont localisées principalement dans deux niches neurogéniques bien établies dans le télencéphale, ce qui contraste avec la situation chez le poisson zèbre adulte où des niches de NSCs actives ont été identifiées dans tout le cerveau, y compris dans le télencéphale dorsal (pallium). Aussi bien chez les rongeurs que le poisson zèbre, les NSCs adultes présentent les deux propriétés fondamentales des cellules souches: elles sont multipotentes, c’est-à-dire capables de générer de nouveaux neurones et cellules gliales, et ont la capacité d'auto-renouvellement à long terme, permettant leur maintien au long de la vie adulte. A la différence des progéniteurs neuronaux embryonnaires (NPCs), une caractéristique de ces NSCs adultes est qu’elles résident la plupart du temps dans un état d’arrêt réversible du cycle cellulaire appelé quiescence. Cet état, activement maintenu, est censé protéger la réserve de NSCs d’un épuisement prématuré, d’où l'importance de déchiffrer les mécanismes moléculaires de régulation de l’équilibre entre la quiescence et l’activation de ces cellules vers la neurogenèse.Les microARNs constituent une classe de petits ARN régulateurs, qui jouent un rôle crucial dans le contrôle d’états cellulaires et des transitions entre ces états. Ils sont capables de réagir rapidement à des signaux à la fois intra- et extracellulaires, qui peuvent moduler aussi bien leur niveau d’expression que leur impact fonctionnel, leur donnant ainsi la capacité de coordonner diverses signaux pour induire des transitions d'état cellulaire. Un microARN en particulier, miR-9, a été montré comme jouant un rôle clé et conservé au cours de la neurogenèse embryonnaire. L'objectif principal de cette étude était d'étudier, pour la première fois, un rôle potentiel de miR-9 dans le contrôle des NSCs, dans un contexte physiologique dans lequel la majorité des NSCs sont quiescentes - le pallium adulte du poisson zèbre. Nous avons constaté que miR-9 est exclusivement exprimé dans une sous-partie des NSCs, met vraisemblablement en évidence un « sous-état » de quiescence. De plus, nous avons pu montrer que miR-9 ancre les NSCs dans un état de quiescence, en partie via le maintien d’un niveau élevé d’activation de la voie de signalisation Notch. De façon surprenante, nous avons également identifié une modification de la localisation subcellulaire de miR-9 au cours du temps: alors que miR-9 est localisé dans le cytoplasme de tous les NPCs chez l’embryon ou le juvenile, chez le poisson adulte miR-9 est localisé dans le noyau des NSCs en quiescence. En outre, la localisation nucléaire de miR-9 dans ces NSCs quiescentes est fortement corrélée avec la localisation nucléaire des protéines effectrices des microARNs, les protéines Argonaute (Agos), ce qui suggère un rôle fonctionnel de miR-9 dans le noyau. De fait, l'élucidation du mécanisme de transport nucléo-cytoplasmique de miR-9/Agos nous a permis de manipuler leur localisation, et d’observer un impact de cette localisation sur l’état de quiescence vs activation des NSCs. L’ensemble des résultats de cette étude identifient ainsi miR-9 comme un régulateur essentiel de la quiescence des NSCs, fournissent pour la première fois un marqueur moléculaire d’un sous-état de quiescence spécifique du cerveau adulte et suggèrent l'implication d'un mécanisme inédit de régulation par les microARNs dans le maintien de l'homéostasie des réserves de NSCs. / Since the seminal discovery of multipotent neural stem cells (NSCs) in the adult mammalian brain, multiple studies have unravelled the importance of these cells for maintaining brain homeostasis. Notably, disturbances in NSC equilibrium have been linked to physiological aging and various neurological pathologies thus sparkling interest in harnessing them for use in regenerative medicine. NSCs reside in distinct germinal zones; in the adult rodent brain NSCs are found mainly in two well-established neurogenic niches in the telencephalon which contrasts with the situation in the adult zebrafish where NSC niches are widespread throughout the brain, including in the dorsal telencephalon or pallium. In both the rodent and zebrafish brains, adult NSCs display fundamental stem cell properties: they are multipotent, e.g. capable of generating new neurons and glia throughout adult life, and have the capacity for long-term self-renewal. Similar to stem cells in other adult tissues, and in contrast to embryonic neural progenitors, a hallmark of these adult NSCs is their relative proliferative quiescence. Quiescence is an actively maintained, reversible state of cell-cycle arrest and generally thought to protect against exhaustion of the stem cell pool. In line with this, disrupting the balance between quiescent and activated NSCs leads to a premature depletion or permanent cell-cycle exit of these cells highlighting the importance of fully deciphering the mechanisms regulating this equilibrium. microRNAs, a major class of small pleiotropic regulatory RNAs, play crucial roles in reinforcing developmental and transitional states. They are capable of reacting to environmental cues, both cell-intrinsic and -extrinsic, with varying outputs such as changing their regulatory functions and expression levels, thus enabling them to coordinating diverse cues to induce cell-state transitions. One microRNA in particular, miR-9, is a highly conserved master regulator of embryonic neurogenesis and in the embryonic zebrafish brain, it establishes a primed neural progenitor state enabling them to quickly respond to cues to differentiate or proliferate. The primary goal of this study was to investigate, for the first time, a potential role for miR-9 in influencing NSC state in a physiological context in which the majority of NSCs are quiescent – the adult zebrafish pallium. We found that miR-9 is exclusively expressed in quiescent NSCs and highlights a “sub-state” within quiescence. In part by maintaining high levels of Notch signalling, a known quiescence promoting pathway, miR-9 anchors NSCs in the quiescent state. Strikingly, we identified a conserved age-associated change in the subcellular localization of the mature miR-9 from the cytoplasm of all embryonic/juvenile neural progenitors to the nucleus of a subset of quiescent NSCs in the adult brain. Moreover, the nuclear expression of miR-9 in these quiescent NSCs is highly correlated with nuclear localization of the microRNAs effector proteins Argonaute (Agos), suggestive of a functional role for nuclear miR-9. Indeed, the elucidation of the nuclear-cytoplasmic transport mechanism of miR-9/Agos enabled us to manipulate their nuclear to cytoplasmic ratios which directly impacted NSC state. Altogether, these results identify miR-9 as a crucial regulator of NSC quiescence, provide for the first time a molecular marker for an age-associated sub-state of quiescence and suggest the involvement of a novel and unconventional microRNA-mediated mechanism to maintain homeostasis of NSC pools.

Cellules souche

Neurogenèse adulte

MicroARN

Neural stem cell

Adult neurogenesis

MicroRNA