Study of the Sonic Hedgehog signaling pathway in the control of oligodendrocyte progenitors during demyelination

La voie de signalisation activée par la protéine Sonic Hedgehog (Shh) est connue pour son rôle majeur au cours de l’embryogenèse et en particulier dans la prolifération et la spécification cellulaire ou encore le guidage axonal au cours de l’établissement des structures du système nerveux. Depuis quelques années, ce morphogène a aussi été identifié comme un régulateur important de plusieurs processus physiologiques du cerveau adulte comme le maintien de la neurogenèse ou la régulation de l’activité électrique de certains neurones (Traiffort et al., 2010). La suractivation de la voie Shh dans un cerveau sain entraine une augmentation significative de la prolifération des cellules progénitrices des oligodendrocytes (OPCs), la source des oligodendrocytes matures, les cellules responsables de la formation des gaines de myéline (Loulier et al., 2006). Au cours de ma thèse, j’ai étudié le potentiel que représente l’activation de la voie Shh dans la régulation de ces progéniteurs dans un contexte de démyélinisation. Pour cela, j’ai utilisé une souris transgénique plp-GFP, chez laquelle la protéine fluorescente verte est exprimée par les cellules du lignage oligodendrocytaire. Après avoir caractérisé le profil d’expression de la GFP dans le cerveau mature de ces souris, j’ai mis au point un modèle de démyélinisation focale par injection stéréotaxique d’un détergent spécifique de la myéline, la lysolécithine (LPC). J’ai identifié les cellules du lignage oligodendrocytaire comme source directe de protéines Shh au sein de la lésion à un temps très précoce après l’injection de LPC. Les gènes cibles de la voie Shh sont aussi fortement induits dans cette population cellulaire à une période plus tardive, correspondant à la différenciation des OPCs en cellules matures. L’utilisation d’adénovirus codant soit pour Shh lui-même soit pour son antagoniste physiologique Hip, m’a permis de réaliser des expériences de gain et de perte de fonction et ainsi d’analyser comment la modulation de la voie Shh peut influencer sur le processus de régénération des oligodendrocytes suite à une lésion. La surexpression de Shh permet d’augmenter la prolifération des OPCs mais aussi d’accélérer leur différenciation, aboutissant à un nombre plus élevé d’oligodendrocytes matures plus précocement au cours du processus de remyélinisation. De plus, il est intéressant de constater que la densité des cellules astrocytaires et microgliales, notamment associées au processus inflammatoire, diminue dans la lésion chez les animaux ayant reçu l’adénovirus Shh comparés au animaux contrôles. A l’inverse, le blocage de la voie induit l’arrêt complet de la production de nouveaux oligodendrocytes. Au-delà de l’amélioration de notre compréhension de la physiologie et de la régulation du lignage oligodendrocytaire dans le cerveau adulte, l’ensemble de ce travail montre de quelle manière la voie Shh peut représenter une nouvelle piste dans la recherche de cibles thérapeutiques dans les affections de la myéline telles que la sclérose en plaques.The Sonic Hedgehog (Shh) signaling pathway is known for its role during embryogenesis and in particular for controlling cell proliferation and specification, as well as axon guidance. In recent years, this morphogen has also been identified as an important regulator of several physiological processes in the adult brain such as the maintenance of neurogenesis or the regulation of the electrophysiological propreties of mature neurons (Traiffort et al., 2010). Overactivation of the Shh pathway in a healthy brain causes a significant increase in the proliferation of oligodendrocyte progenitor cells (OPCs), the source of mature oligodendrocytes, the cells responsible for the formation of myelin sheaths (Loulier et al., 2006).In my thesis, I studied the effects of the Shh pathway activation on OPC regulation in the context of demyelination. To that purpose, I used a plp-GFP transgenic mouse, in which the green fluorescent protein (GFP) is expressed by cells belonging to the oligodendrocyte lineage. After characterization of the expression pattern of GFP in the mature brain of these mice, I developed a model of focal demyelination by stereotaxic injection of lysolecithin (LPC). I identified the oligodendrocyte lineage cells as a source of Shh protein within the lesion, soon after the LPC injection. Target genes of the Shh pathway are also strongly induced in this cell population, at a time corresponding to the differentiation of OPCs into mature cells. The use of adenoviral vectors encoding either Shh itself or its physiological antagonist Hip allowed me to conduct gain- and loss-of-function experiments. This way I could analyze how the modulation of Shh pathway may influence the regeneration ofoligodendrocytes after injury. Shh overexpression increases the survival and proliferation of OPCs but also accelerates their differentiation, resulting in a higher number of mature oligodendrocytes earlier during the remyelination process. In addition, the density of astrocytes and microglia, associated with the inflammatory process, is decreased in animalsreceiving the Shh adenoviral vector compared to control animals. Altogether these effects are associated with a reduction of the lesion. Conversely, blocking the pathway induced a complete arrest of new oligodendrocyte production. Besides the fundamental knowledge gained about the molecular mechanism involved in the oligodendroglial precursor cells survival, proliferation, differentiation and myelin repair in vivo, this project should also give valuable insights concerning the potential use of pharmacological modulators of Shh signaling as a novel therapeutic approach for the treatment of multiple sclerosis and other myelin diseases

Cellules souches neurales et signalisation Notch

Les cellules souches neurales (CSN) sont essentielles au développement du système nerveux central et à sa réparation. Parmi les mécanismes contrôlant ces cellules, la signalisation Notch joue un rôle majeur. Chez l’embryon, elle permet le maintien des CSN pendant les différentes phases de développement du système nerveux central qui débute par la production des neurones, ou neurogenèse, et se poursuit par la gliogenèse conduisant aux astrocytes et oligodendrocytes. Au cours de la période post-natale et adulte, la signalisation Notch reste présente dans les principales aires de neurogenèse adulte, la zone sous-ventriculaire des ventricules latéraux et la zone sous-granulaire de l’hippocampe, où elle maintient la quiescence des CSN adultes, contribue au caractère hétérogène de ces cellules et exerce des effets pléiotropes au cours de la régénération du tissu neural lésé

Etude de la voie de signalisation Sonic Hedgehog dans le contrôle des progéniteurs oligodendrocytaires au cours de la démyélinisation

La voie de signalisation activée par la protéine Sonic Hedgehog (Shh) est connue pour son rôle majeur au cours de l embryogenèse et en particulier dans la prolifération et la spécification cellulaire ou encore le guidage axonal au cours de l établissement des structures du système nerveux. Depuis quelques années, ce morphogène a aussi été identifié comme un régulateur important de plusieurs processus physiologiques du cerveau adulte comme le maintien de la neurogenèse ou la régulation de l activité électrique de certains neurones (Traiffort et al., 2010). La suractivation de la voie Shh dans un cerveau sain entraine une augmentation significative de la prolifération des cellules progénitrices des oligodendrocytes (OPCs), la source des oligodendrocytes matures, les cellules responsables de la formation des gaines de myéline (Loulier et al., 2006). Au cours de ma thèse, j ai étudié le potentiel que représente l activation de la voie Shh dans la régulation de ces progéniteurs dans un contexte de démyélinisation. Pour cela, j ai utilisé une souris transgénique plp-GFP, chez laquelle la protéine fluorescente verte est exprimée par les cellules du lignage oligodendrocytaire. Après avoir caractérisé le profil d expression de la GFP dans le cerveau mature de ces souris, j ai mis au point un modèle de démyélinisation focale par injection stéréotaxique d un détergent spécifique de la myéline, la lysolécithine (LPC). J ai identifié les cellules du lignage oligodendrocytaire comme source directe de protéines Shh au sein de la lésion à un temps très précoce après l injection de LPC. Les gènes cibles de la voie Shh sont aussi fortement induits dans cette population cellulaire à une période plus tardive, correspondant à la différenciation des OPCs en cellules matures. L utilisation d adénovirus codant soit pour Shh lui-même soit pour son antagoniste physiologique Hip, m a permis de réaliser des expériences de gain et de perte de fonction et ainsi d analyser comment la modulation de la voie Shh peut influencer sur le processus de régénération des oligodendrocytes suite à une lésion. La surexpression de Shh permet d augmenter la prolifération des OPCs mais aussi d accélérer leur différenciation, aboutissant à un nombre plus élevé d oligodendrocytes matures plus précocement au cours du processus de remyélinisation. De plus, il est intéressant de constater que la densité des cellules astrocytaires et microgliales, notamment associées au processus inflammatoire, diminue dans la lésion chez les animaux ayant reçu l adénovirus Shh comparés au animaux contrôles. A l inverse, le blocage de la voie induit l arrêt complet de la production de nouveaux oligodendrocytes. Au-delà de l amélioration de notre compréhension de la physiologie et de la régulation du lignage oligodendrocytaire dans le cerveau adulte, l ensemble de ce travail montre de quelle manière la voie Shh peut représenter une nouvelle piste dans la recherche de cibles thérapeutiques dans les affections de la myéline telles que la sclérose en plaques.The Sonic Hedgehog (Shh) signaling pathway is known for its role during embryogenesis and in particular for controlling cell proliferation and specification, as well as axon guidance. In recent years, this morphogen has also been identified as an important regulator of several physiological processes in the adult brain such as the maintenance of neurogenesis or the regulation of the electrophysiological propreties of mature neurons (Traiffort et al., 2010). Overactivation of the Shh pathway in a healthy brain causes a significant increase in the proliferation of oligodendrocyte progenitor cells (OPCs), the source of mature oligodendrocytes, the cells responsible for the formation of myelin sheaths (Loulier et al., 2006).In my thesis, I studied the effects of the Shh pathway activation on OPC regulation in the context of demyelination. To that purpose, I used a plp-GFP transgenic mouse, in which the green fluorescent protein (GFP) is expressed by cells belonging to the oligodendrocyte lineage. After characterization of the expression pattern of GFP in the mature brain of these mice, I developed a model of focal demyelination by stereotaxic injection of lysolecithin (LPC). I identified the oligodendrocyte lineage cells as a source of Shh protein within the lesion, soon after the LPC injection. Target genes of the Shh pathway are also strongly induced in this cell population, at a time corresponding to the differentiation of OPCs into mature cells. The use of adenoviral vectors encoding either Shh itself or its physiological antagonist Hip allowed me to conduct gain- and loss-of-function experiments. This way I could analyze how the modulation of Shh pathway may influence the regeneration ofoligodendrocytes after injury. Shh overexpression increases the survival and proliferation of OPCs but also accelerates their differentiation, resulting in a higher number of mature oligodendrocytes earlier during the remyelination process. In addition, the density of astrocytes and microglia, associated with the inflammatory process, is decreased in animalsreceiving the Shh adenoviral vector compared to control animals. Altogether these effects are associated with a reduction of the lesion. Conversely, blocking the pathway induced a complete arrest of new oligodendrocyte production. Besides the fundamental knowledge gained about the molecular mechanism involved in the oligodendroglial precursor cells survival, proliferation, differentiation and myelin repair in vivo, this project should also give valuable insights concerning the potential use of pharmacological modulators of Shh signaling as a novel therapeutic approach for the treatment of multiple sclerosis and other myelin diseases.PARIS11-SCD-Bib. électronique (914719901) / SudocSudocFranceF

Extracellular Control of Radial Glia Proliferation and Scaffolding During Cortical Development and Pathology

International audienceDuring the development of the cortex, newly generated neurons migrate long-distances in the expanding tissue to reach their final positions. Pyramidal neurons are produced from dorsal progenitors, e.g., radial glia (RGs) in the ventricular zone, and then migrate along RG processes basally toward the cortex. These neurons are hence dependent upon RG extensions to support their migration from apical to basal regions. Several studies have investigated how intracellular determinants are required for RG polarity and subsequent formation and maintenance of their processes. Fewer studies have identified the influence of the extracellular environment on this architecture. This review will focus on extracellular factors which influence RG morphology and pyramidal neuronal migration during normal development and their perturbations in pathology. During cortical development, RGs are present in different strategic positions: apical RGs (aRGs) have their cell bodies located in the ventricular zone with an apical process contacting the ventricle, while they also have a basal process extending radially to reach the pial surface of the cortex. This particular conformation allows aRGs to be exposed to long range and short range signaling cues, whereas basal RGs (bRGs, also known as outer RGs, oRGs) have their cell bodies located throughout the cortical wall, limiting their access to ventricular factors. Long range signals impacting aRGs include secreted molecules present in the embryonic cerebrospinal fluid (e.g., Neuregulin, EGF, FGF, Wnt, BMP). Secreted molecules also contribute to the extracellular matrix (fibronectin, laminin, reelin). Classical short range factors include cell to cell signaling, adhesion molecules and mechano-transduction mechanisms (e.g., TAG1, Notch, cadherins, mechanical tension). Changes in one or several of these components influencing the RG extracellular environment can disrupt the development or maintenance of RG architecture on which neuronal migration relies, leading to a range of cortical malformations. First, we will detail the known long range signaling cues impacting RG. Then, we will review how short range cell contacts are also important to instruct the RG framework. Understanding how RG processes are structured by their environment to maintain and support radial migration is a critical part of the investigation of neurodevelopmental disorders

Establishing Hedgehog Gradients during Neural Development

A morphogen is a signaling molecule that induces specific cellular responses depending on its local concentration. The concept of morphogenic gradients has been a central paradigm of developmental biology for decades. Sonic Hedgehog (Shh) is one of the most important morphogens that displays pleiotropic functions during embryonic development, ranging from neuronal patterning to axon guidance. It is commonly accepted that Shh is distributed in a gradient in several tissues from different origins during development; however, how these gradients are formed and maintained at the cellular and molecular levels is still the center of a great deal of research. In this review, we first explored all of the different sources of Shh during the development of the nervous system. Then, we detailed how these sources can distribute Shh in the surrounding tissues via a variety of mechanisms. Finally, we addressed how disrupting Shh distribution and gradients can induce severe neurodevelopmental disorders and cancers. Although the concept of gradient has been central in the field of neurodevelopment since the fifties, we also describe how contemporary leading-edge techniques, such as organoids, can revisit this classical model

Sonic Hedgehog signaling is a positive oligodendrocyte regulator during demyelination.

International audienceThe morphogen Sonic Hedgehog (Shh) controls the generation of oligodendrocyte (OLs) during embryonic development and regulates OL production in adulthood in the cortex and corpus callosum. The roles of Shh in CNS repair following lesions associated with demyelinating diseases are still unresolved. Here, we address this issue by using a model of focal demyelination induced by lysolecithin in the corpus callosum of adult mice. Shh transcripts and protein were not detected in control animals but were upregulated in a time-dependent manner in the oligodendroglial lineage within the lesion. We report an increased transcription of Shh target genes suggesting a broad reactivation of the Shh pathway. We show that the adenovirus-mediated transfer of Shh into the lesioned brain results in the attenuation of the lesion extent with the increase of OL progenitor cells (OPCs) and mature myelinating OL numbers due to survival, proliferation, and differentiation activities as well as the decrease of astrogliosis and macrophage infiltration. Furthermore, the blocking of Shh signaling during the lesion, using its physiological antagonist, Hedgehog interacting protein, results in a decrease of OPC proliferation and differentiation, preventing repair. Together, our findings identify Shh as a necessary factor playing a positive role during demyelination and indicate that its signaling activation stands as a potential therapeutic approach for myelin diseases

Genetic activation of Hedgehog signaling unbalances the rate of neural stem cell renewal by increasing symmetric divisions.

International audienceIn the adult brain, self-renewal is essential for the persistence of neural stem cells (NSCs) throughout life, but its regulation is still poorly understood. One NSC can give birth to two NSCs or one NSC and one transient progenitor. A correct balance is necessary for the maintenance of germinal areas, and understanding the molecular mechanisms underlying NSC division mode is clearly important. Here, we report a function of the Sonic Hedgehog (SHH) receptor Patched in the direct control of long-term NSC self-renewal in the subependymal zone. We show that genetic conditional activation of SHH signaling in adult NSCs leads to their expansion and the depletion of their direct progeny. These phenotypes are associated in vitro with an increase in NSC symmetric division in a process involving NOTCH signaling. Together, our results demonstrate a tight control of adult neurogenesis and NSC renewal driven by Patched

Self-organizing models of human trunk organogenesis recapitulate spinal cord and spine co-morphogenesis

Integrated in vitro models of human organogenesis are needed to elucidate the multi-systemic events underlying development and disease. Here we report the generation of human trunk-like structures that model the co-morphogenesis, patterning and differentiation of the human spine and spinal cord. We identified differentiation conditions for human pluripotent stem cells favoring the formation of an embryo-like extending antero-posterior (AP) axis. Single-cell and spatial transcriptomics show that somitic and spinal cord differentiation trajectories organize along this axis and can self-assemble into a neural tube surrounded by somites upon extracellular matrix addition. Morphogenesis is coupled with AP patterning mechanisms, which results, at later stages of organogenesis, in in vivo-like arrays of neural subtypes along a neural tube surrounded by spine and muscle progenitors contacted by neuronal projections. This integrated system of trunk development indicates that in vivo-like multi-tissue co-morphogenesis and topographic organization of terminal cell types can be achieved in human organoids, opening windows for the development of more complex models of organogenesis

Heterozygous Mutant Mice Have a Subtle Locomotor Phenotype

Axon guidance receptors such as deleted in colorectal cancer (DCC) contribute to the normal formation of neural circuits, and their mutations can be associated with neural defects. In humans, heterozygous mutations in have been linked to congenital mirror movements, which are involuntary movements on one side of the body that mirror voluntary movements of the opposite side. In mice, obvious hopping phenotypes have been reported for bi-allelic mutations, while heterozygous mutants have not been closely examined. We hypothesized that a detailed characterization of heterozygous mice may reveal impaired corticospinal and spinal functions. Anterograde tracing of the motor cortex revealed a normally projecting corticospinal tract, intracortical microstimulation (ICMS) evoked normal contralateral motor responses, and behavioral tests showed normal skilled forelimb coordination. Gait analyses also showed a normal locomotor pattern and rhythm in adult mice during treadmill locomotion, except for a decreased occurrence of out-of-phase walk and an increased duty cycle of the stance phase at slow walking speed. Neonatal isolated spinal cords had normal left-right and flexor-extensor coupling, along with normal locomotor pattern and rhythm, except for an increase in the flexor-related motoneuronal output. Although mice do not exhibit any obvious bilateral impairments like those in humans, they exhibit subtle motor deficits during neonatal and adult locomotion