Ciliogenesis Control Mechanisms in Cerebellar Neuron Progenitors / Contrôle de la ciliogenèse des progéniteurs des neurones du cervelet

Zanini, Marco

05 December 2019

Pendant le développement du cervelet, les progéniteurs des neurones granulaires (PNG) nécessitent la présence du cil primaire pour proliférer en réponse à Sonic Hedgehog (SHH). En effet, la prolifération dérégulée des PNGs peut conduire à la formation d'une tumeur pédiatrique maligne appelée SHH-médulloblastome (MB), de ce fait comprendre comment le cil primaire est régulé dans les PNGs est crucial.Nous montrons que le facteur de transcription Atoh1 contrôle la présence du cil primaire dans les PNGs in vitro et in vivo. En particulier, la suppression du cil primaire par l’inactivation génétique de gènes impliqués dans la ciliogenèse (par exemple, Kif3a ou Ift88) empêche Atoh1 de maintenir les PNGs en prolifération, ce qui indique qu’Atoh1 favorise l’expansion des PNGs en maintenant la présence du cil primaire. D’un point de vue moléculaire, Atoh1 contrôle la formation du cil primaire en régulant le bon positionnement peri-centrosomal des satellites centriolaires (SC), complexes protéiques essentiels pour la ciliogenèse. L'inactivation de Atoh1 dans les PNGs perturbe en effet la distribution subcellulaire des SCs, altérant ainsi inévitablement la ciliogenèse. Cette nouvelle fonction de Atoh1 est gouvernée par la régulation transcriptionnelle directe d'un composant clé des SCs, Cep131. L’expression ectopique de Cep131 dans les PNGs restore les effets liés à l'inactivation d'Atoh1, rétablissant la localisation correcte du SC et comme conséquence la présence d’un cil primaire.De plus, nous avons montré que cette voie Atoh1-SC-cil primaire-SHH contrôlant la prolifération des PNGs est également conservée dans le contexte du SHH-MB, où Atoh1 est surexprimée et essentielle pour sa formation et sa maintenance.Ces données révèlent un mécanisme par lequel la ciliogenèse est régulée dans des progéniteurs de neurones, offrant de nouvelles informations sur la neurogenèse dans le cervelet et sur la pathogenèse du SHH-MB. / Cerebellar granule neuron progenitors (GNPs) require the primary cilium to proliferate in response to Sonic Hedgehog (SHH) during cerebellar development. As aberrant proliferation of GNPs may lead to SHH-type medulloblastoma (SHH-MB), a pediatric brain tumor, understanding which mechanisms control ciliogenesis in GNPs represents a major interest in the field. Here, we show that the proneural bHLH transcription factor Atoh1 controls the presence of primary cilia in GNPs both in vitro and in vivo, thus maintaining GNPs responsive to the mitogenic effects of SHH. Indeed, loss of primary cilia induced via knockdown of specific ciliary components (e.g. Kif3a and Ift88) abolishes the ability of Atoh1 to keep GNPs in proliferation in vivo. Mechanistically, Atoh1 controls ciliogenesis by regulating the proper peri-centrosomal clustering of centriolar satellites (CS), large multiprotein complexes working as essential machineries for ciliogenesis. Knockdown of Atoh1 in GNPs perturbs CS subcellular distribution, leading to impairment of ciliogenesis. Luciferase reporter assays and chromatin immunoprecipitation experiments indicate that Atoh1 can directly regulate the expression of Cep131, a key CS core component. Importantly, ectopic expression of Cep131 in GNPs depleted of Atoh1, is sufficient to restore proper CS localization and consequent primary cilia formation, indicating that the Atoh1-Cep131-CS axis is responsible for ciliogenesis in GNPs.In addition, we further demonstrated that these functions of Atoh1 are conserved in the context of SHH-MB, where Atoh1 is typically overexpressed and acts as a lineage-dependent transcription factor.These data reveal a mechanism whereby ciliogenesis is regulated in neuron progenitors providing novel insights into cerebellar neurogenesis and pathogenesis of SHH-MB.

Cervelet

Médulloblastome

Atoh1

Cil Primaire

Cep131

Sonic Hedgehog

Cerebellum

Medulloblastoma

Atoh1

Primary Cilium

Cep131

Sonic Hedgehog

Identification and characterization of CEP131 as a novel BBSome interacting protein

Chamling, Xitiz

01 May 2014

Bardet-Biedl syndrome (BBS) is a pleiotropic and genetically heterogeneous disorder, and a well-known ciliopathy. Nineteen different genes have been reported for BBS, mutations in which cause characteristic phenotypes including retinal degeneration, obesity, polydactyly, renal abnormalities, hypogenitalism and cognitive impairment. Protein products of eleven BBS genes are part of two major complexes: the BBSome complex and a CCT/CTRiC/BBS complex. The CCT/CTRiC/BBS complex assists in the formation of the BBSome complex, which in turn traffics numerous receptor proteins to the cilia. However, the precise mechanism by which BBSome ciliary trafficking activity is regulated is not fully understood. In fact, a complete picture of the cellular functions of BBS proteins is still missing, and gaps remain in our understanding of the pleiotropy and heterogeneity of the disease. With the aim of bridging those gaps, this thesis project was designed to identify tissue specific cargoes of the BBSome and to characterize their BBS-related functions. To this end, we generated a transgenic LAP-BBS4 mouse, which expresses the transgene in various tissues including brain, eye, testis, heart, kidney, and adipose tissue. We found that despite tissue specific variable expression, LAP-BBS4 was able to complement the deficiency of Bbs4 and rescue all the BBS phenotypes in the Bbs4 null mice. The finding provides an encouraging prospective for gene therapy for BBS related phenotypes and potentially for other ciliopathies. We also utilized the transgenic mice to search for tissue specific BBSome cargo proteins and identified CEP131 as a novel BBSome interacting protein. Using in vitro cell culture models we show that CEP131 interacts with the BBSome through BBS4. CEP131 is not involved in BBSome assembly, but accumulation of the BBSome in cilia is enhanced upon CEP131 depletion. Our in vitro data implicate CEP131 as a negative regulator of ciliary BBSome trafficking. Finally, we show that cep131 knockdown in zebrafish embryos results in typical BBS phenotypes including Kupffer's vesicle abnormalities and melanosome transport delay. This finding confirms the association of CEP131 with the BBS pathway. Overall, the work performed for this thesis provides further insight into the regulation of BBSome ciliary trafficking and suggests CEP131 as a BBS candidate gene.

Bardet-Biedl Syndrome

BBS4

BBSome

CEP131

Ciliopathy

primary cilia

Genetics