Coordinated genomic control of ciliogenesis and cell movement by RFX2

Chung, Mei I.; Kwon, Taejoon; Tu, Fan; Brooks, Eric; Gupta, Ritu; Meyer, Matthew D; Baker, Julie C.; Marcotte, Edward M.; Wallingford, John B.

doi:10.7554/elife.01439

Cited by 125 publications

(187 citation statements)

References 78 publications

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“…Multicilin induces not only centriole assembly via the deuterosome-mediated pathway but also motile extension via its ability to up-regulate additional transcriptional regulators; namely, Foxj1 and the RFX transcription factors (Yu et al 2008;Stubbs et al 2012;Chung et al 2014). Since the former pathway is much more sensitive to inhibition by E2f4DCT and Gmnn than the latter, Multicilin could activate motile cilium formation by forming additional complexes other than the one with E2f proteins.…”

Section: Discussionmentioning

confidence: 99%

Multicilin drives centriole biogenesis via E2f proteins

et al. 2014

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Multiciliate cells employ hundreds of motile cilia to produce fluid flow, which they nucleate and extend by first assembling hundreds of centrioles. In most cells, entry into the cell cycle allows centrioles to undergo a single round of duplication, but in differentiating multiciliate cells, massive centriole assembly occurs in G0 by a process initiated by a small coiled-coil protein, Multicilin. Here we show that Multicilin acts by forming a ternary complex with E2f4 or E2f5 and Dp1 that binds and activates most of the genes required for centriole biogenesis, while other cell cycle genes remain off. This complex also promotes the deuterosome pathway of centriole biogenesis by activating the expression of deup1 but not its paralog, cep63. Finally, we show that this complex is disabled by mutations in human Multicilin that cause a severe congenital mucociliary clearance disorder due to reduced generation of multiple cilia. By coopting the E2f regulation of cell cycle genes, Multicilin drives massive centriole assembly in epithelial progenitors in a manner required for multiciliate cell differentiation.

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Section: Discussionmentioning

confidence: 99%

Multicilin drives centriole biogenesis via E2f proteins

et al. 2014

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“…Chez le xénope, Rfx2 est également nécessaire à la mise en place de l'épithélium mucociliaire [16]. Il a été récemment démontré qu'il contrôle l'expression d'un grand nombre de gènes ciliaires [17]. La présence du domaine de dimérisation n'est pas systématiquement corrélée avec le contrôle des gènes ciliaires, puisqu'il a aussi été montré que le facteur Rfx7, qui ne possède pas ce domaine, est requis pour réguler la ciliogenèse dans le tube neural chez le xénope (Tableau I) [18].…”

Section: Les Protéines Rfxunclassified

“…La présence du domaine de dimérisation n'est pas systématiquement corrélée avec le contrôle des gènes ciliaires, puisqu'il a aussi été montré que le facteur Rfx7, qui ne possède pas ce domaine, est requis pour réguler la ciliogenèse dans le tube neural chez le xénope (Tableau I) [18]. De façon générale, les facteurs RFX régulent la ciliogenèse en contrôlant directement la transcription des gènes ciliaires et, notamment, de nombreux gènes codant pour des protéines essentielles à l'assemblage et à la fonction des cils [17,19]. Ainsi, ils contrôlent l'expression de la majorité des protéines de la zone de transition nécessaires à l'ancrage du corps basal à la membrane plasmique, étape clé pour l'initiation de la ciliogenèse [51] ( §).…”

Section: Les Protéines Rfxunclassified

“…De la même manière, une étude visant à trouver les cibles de RFX2 dans les cellules multiciliées de la peau de xénope a conduit à l'identification de deux nouveaux gènes ciliaires. Le premier, ttc29 (tetratricopeptide repeat domain 29), est nécessaire à la régulation de l'IFT et le second, ribc2 (RIB43A domain with coiled-coils 2), est essentiel à la motilité des cils, et son absence perturbe l'organisation microtubulaire de l'axonème [17]. Ces études ont aussi permis d'identifier des gènes dont l'importance chez l'homme a été démontrée par leur implication dans plusieurs ciliopathies.…”

Section: Contrôle De La Diversité Ciliaireunclassified

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Contrôle transcriptionnel des gènes ciliaires

2014

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“…Finally, Notch activation was shown to induce supernumerary P63-positive cells, whereas Notch inhibition had the opposite effect, suggesting that P63-positive cells are counterparts to MCCs and ionocytes selected through lateral inhibition (Sirour et al, 2011). Following their commitment, MCCs, ionocytes and SSCs sequentially migrate to the outer layer, where they intercalate among goblet cells and resume differentiation (Chung et al, 2014;Cibois et al, 2014;Quigley et al, 2011;Stubbs et al, 2006), whereas the P63-positive cells remain in the inner layer. The role of P63-positive cells remains uncharacterised, although the mature inner layer of the amphibian embryonic epidermis has been proposed to constitute the source of the late larval and postmetamorphic skin (Yoshizato, 2007).…”

Section: Introductionmentioning

confidence: 99%

BMP signalling controls the construction of vertebrate mucociliary epithelia

et al. 2015

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Despite the importance of mucociliary epithelia in animal physiology, the mechanisms controlling their establishment are poorly understood. Using the developing Xenopus epidermis and regenerating human upper airways, we reveal the importance of BMP signalling for the construction of vertebrate mucociliary epithelia. In Xenopus, attenuation of BMP activity is necessary for the specification of multiciliated cells (MCCs), ionocytes and small secretory cells (SSCs). Conversely, BMP activity is required for the proper differentiation of goblet cells. Our data suggest that the BMP and Notch pathways interact to control fate choices in the developing epidermis. Unexpectedly, BMP activity is also necessary for the insertion of MCCs, ionocytes and SSCs into the surface epithelium. In human, BMP inhibition also strongly stimulates the formation of MCCs in normal and pathological (cystic fibrosis) airway samples, whereas BMP overactivation has the opposite effect. This work identifies the BMP pathway as a key regulator of vertebrate mucociliary epithelium differentiation and morphogenesis.

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Coordinated genomic control of ciliogenesis and cell movement by RFX2

Cited by 125 publications

References 78 publications

Multicilin drives centriole biogenesis via E2f proteins

Multicilin drives centriole biogenesis via E2f proteins

Contrôle transcriptionnel des gènes ciliaires

BMP signalling controls the construction of vertebrate mucociliary epithelia

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