Author
Listed:
- Antonia Wiegering
(Dev2A
Institut de Biologie Paris Seine)
- Isabelle Anselme
(Dev2A
Institut de Biologie Paris Seine)
- Ludovica Brunetti
(Dev2A
Institut de Biologie Paris Seine)
- Laura Metayer-Derout
(Dev2A
Institut de Biologie Paris Seine)
- Damelys Calderon
(Université Paris Cité)
- Sophie Thomas
(Université Paris Cité)
- Stéphane Nedelec
(UMR-S 1270
Institut Jacques Monod)
- Alexis Eschstruth
(Dev2A
Institut de Biologie Paris Seine)
- Valentina Serpieri
(University of Pavia)
- Martin Catala
(Dev2A
Institut de Biologie Paris Seine)
- Christophe Antoniewski
(Institut de Biologie Paris Seine)
- Sylvie Schneider-Maunoury
(Dev2A
Institut de Biologie Paris Seine)
- Aline Stedman
(Dev2A
Institut de Biologie Paris Seine)
Abstract
Studying ciliary genes in the context of the human central nervous system is crucial for understanding the underlying causes of neurodevelopmental ciliopathies. Here, we use pluripotent stem cell-derived spinal organoids to reveal distinct functions of the ciliopathy gene RPGRIP1L in humans and mice, and uncover an unexplored role for cilia in human axial patterning. Previous research has emphasized Rpgrip1l critical functions in mouse brain and spinal cord development through the regulation of SHH/GLI pathway. Here, we show that RPGRIP1L is not required for SHH activation or motoneuron lineage commitment in human spinal progenitors and that this feature is shared by another ciliopathy gene, TMEM67. Furthermore, human RPGRIP1L-mutant motoneurons adopt hindbrain and cervical identities instead of caudal brachial identity. Temporal transcriptome analysis reveals that this antero-posterior patterning defect originates in early axial progenitors and correlates with cilia loss. These findings provide important insights into the role of cilia in human neural development.
Suggested Citation
Antonia Wiegering & Isabelle Anselme & Ludovica Brunetti & Laura Metayer-Derout & Damelys Calderon & Sophie Thomas & Stéphane Nedelec & Alexis Eschstruth & Valentina Serpieri & Martin Catala & Christo, 2025.
"A differential requirement for ciliary transition zone proteins in human and mouse neural progenitor fate specification,"
Nature Communications, Nature, vol. 16(1), pages 1-19, December.
Handle:
RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-58554-3
DOI: 10.1038/s41467-025-58554-3
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