Identification of a new cell cycle variant during multiciliated cell differentiation

Serizay, Jacques; Damaa, Michella Khoury; Boudjema, Amélie-Rose; Balagué, Rémi; Faucourt, Marion; Delgehyr, Nathalie; Noûs, Camille; Zaragosi, Laure-Emmanuelle; Barbry, Pascal; Spassky, Nathalie; Koszul, Romain; Meunier, Alice

doi:10.1101/2024.05.22.595357

2024

DOI: 10.1101/2024.05.22.595357

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Identification of a new cell cycle variant during multiciliated cell differentiation

Jacques Serizay,

Michella Khoury Damaa,

Amélie-Rose Boudjema

et al.

Abstract: A complex and conserved regulatory network drives the cell cycle. Individual components of this network are sometimes used in differentiated cells, i.e. to control organelle destruction in mammalian lens cells or light response in land plants. Some differentiated cells co-opt cell-cycle regulators more largely, to increase their ploidy using a cell cycle variant named endoreplication. Using single-cell RNA-seq profiling and functional assays in differentiating multiciliated cells, we identified a novel type of… Show more

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Cyclin O controls entry into the cell-cycle variant required for multiciliated cell differentiation

Damaa,

Serizay,

Balagué

et al. 2024

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Multiciliated cells (MCC) ensure proper fluid circulation in various organs in metazoans. Their differentiation is marked by the massive amplification of cilia-nucleating centrioles and is known to be controlled by various cell cycle components. In a companion study, we show that the differentiation of MCC is driven by a genuine cell-cycle variant characterized by sequential and wave-like expression of canonical and non-canonical cyclins such as Cyclin O (CCNO). Patients with CCNO mutations exhibit a subtype of Primary Ciliary Dyskinesia (PCD) designated as Reduced Generation of Multiple Motile Cilia (RGMC), yet the role of CCNO during MCC differentiation remains unclear. Here, using mice and human cellular models, single cell transcriptomics and functional studies, we show that Ccno is activated during a strategic temporal window at the crossroads between the onset of MCC differentiation, the entry into the MCC cell cycle variant, and the activation of the centriole biogenesis program. We find that the absence of Ccno leads to a block of MCC progenitor differen- tiation at the G1/S-like transition, just before the beginning of centriole formation. This leads to a complete lack of centrioles and cilia in mouse brain and human airway MCC. Altogether, our study identifies CCNO as a core regulator of entry into the MCC cell cycle variant and shows that the coupling of centriole biogenesis to an S-like phase, maintained in MCC, is dependent on CCNO.

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Cyclin O controls entry into the cell-cycle variant required for multiciliated cell differentiation

Damaa,

Serizay,

Balagué

et al. 2024

Preprint

Self Cite

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show abstract

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Identification of a new cell cycle variant during multiciliated cell differentiation

Cited by 1 publication

References 45 publications

Cyclin O controls entry into the cell-cycle variant required for multiciliated cell differentiation

Cyclin O controls entry into the cell-cycle variant required for multiciliated cell differentiation

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