Etude de la neurogenèse hippocampique adulte et des fonctions cognitives chez trois souris modèles de déficience intellectuelle

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.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

Adult Hippocampal Neurogenesis and Cognitive Functions in Three Mouse Models of Intellectual Disability

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

Selective alteration of adult hippocampal neurogenesis and impaired spatial pattern separation performance in the RSK2-deficient mouse model of Coffin-Lowry syndrome

International audienceAdult neurogenesis is involved in certain hippocampus-dependent cognitive functions and is linked to psychiatric diseases including intellectual disabilities. The Coffin-Lowry syndrome (CLS) is a developmental disorder caused by mutations in the Rsk2 gene and characterized by intellectual disabilities associated with growth retardation. How RSK2-deficiency leads to cognitive dysfunctions in CLS is however poorly understood. Here, using Rsk2 Knock-Out mice, we characterized the impact of RSK2 deficiency on adult hippocampal neurogenesis in vivo. We report that the absence of RSK2 does not affect basal proliferation, differentiation and survival of dentate gyrus adult-born neurons but alters the maturation progression of young immature newborn neurons. Moreover, when RSK2-deficient mice were submitted to spatial learning, in contrast to wild-type mice, proliferation of adult generated neurons was decreased and no pro-survival effect of learning was observed. Thus, learning failed to recruit a selective population of young newborn neurons in association with deficient long-term memory recall. Given the proposed role of the dentate gyrus and of adult-generated newborn neurons in hippocampal-dependent pattern separation function, we explored this function in a delayed non-matching to place task and in an object-place pattern separation task and report severe deficits in spatial pattern separation in Rsk2-KO mice. Together, this study reveals a previously unknown role for RSK2 in the early stages of maturation and learning-dependent involvement of adult-born dentate gyrus neurons. These alterations associated with a deficit in the ability of RSK2-deficient mice to finely discriminate relatively similar spatial configurations, may contribute to cognitive dysfunction in CLS

Notch receptor-ligand binding facilitates extracellular vesicle-mediated neuron-to-neuron communication

Summary: Extracellular vesicles (EVs) facilitate intercellular communication by transferring cargo between cells in a variety of tissues. However, how EVs achieve cell-type-specific intercellular communication is still largely unknown. We found that Notch1 and Notch2 proteins are expressed on the surface of neuronal EVs that have been generated in response to neuronal excitatory synaptic activity. Notch ligands bind these EVs on the neuronal plasma membrane, trigger their internalization, activate the Notch signaling pathway, and drive the expression of Notch target genes. The generation of these neuronal EVs requires the endosomal sorting complex required for transport-associated protein Alix. Adult Alix conditional knockout mice have reduced hippocampal Notch signaling activation and glutamatergic synaptic protein expression. Thus, EVs facilitate neuron-to-neuron communication via the Notch receptor-ligand system in the brain

The intellectual disability PAK3 R67C mutation impacts cognitive functions and adult hippocampal neurogenesis

International audienceThe link between mutations associated with intellectual disability (ID) and the mechanisms underlying cognitive dysfunctions remains largely unknown. Here, we focused on PAK3, a serine/threonine kinase whose gene mutations cause X-linked ID. We generated a new mutant mouse model bearing the missense R67C mutation of the Pak3 gene (Pak3-R67C), known to cause moderate to severe ID in humans without other clinical signs and investigated hippocampal-dependent memory and adult hippocampal neurogenesis. Adult male Pak3-R67C mice exhibited selective impairments in long-term spatial memory and pattern separation function, suggestive of altered hippocampal neurogenesis. A delayed-non-matching-to-place paradigm testing memory flexibility and proactive interference, reported here as being adult neurogenesis-dependent, revealed a hypersensitivity to high interference in Pak3-R67C mice. Analyzing adult hippocampal neurogenesis in Pak3-R67C mice reveals no alteration in the first steps of adult neurogenesis, but an accelerated death of a population of adult-born neurons during the critical period of 18-28 days after their birth. We then investigated the recruitment of hippocampal adult-born neurons after spatial memory recall. Post-recall activation of mature dentate granule cells in Pak3-R67C mice was unaffected, but a complete failure of activation of young DCX+ newborn neurons was found, suggesting they were not recruited during the memory task. Decreased expression of the KCC2b chloride co-transporter and altered dendritic development indicate that young adult-born neurons are not fully functional in Pak3-R67C mice. We suggest that these defects in the dynamics and learning-associated recruitment of newborn hippocampal neurons may contribute to the selective cognitive deficits observed in this mouse model of ID