Loss of Mst1/2 activity promotes non-mitotic hair cell generation in the neonatal organ of Corti

Loss of Mst1/2 activity promotes non-mitotic hair cell generation in the neonatal organ of Corti

Mammalian sensory hair cells (HCs) have limited capacity for regeneration, which leads to permanent hearing loss after HC death. Here, we used in vitro RNA-sequencing to show that the Hippo signaling pathway is involved in HC damage and self-repair processes. Turning off Hippo signaling through Mst1...

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Veröffentlicht in:npj Regenerative medicine 2022-10, Vol.7 (1), p.64-64, Article 64
Hauptverfasser: Lu, Xiaoling, Yu, Huiqian, Ma, Jiaoyao, Wang, Kunkun, Guo, Luo, Zhang, Yanping, Li, Boan, Zhao, Zehang, Li, Huawei, Sun, Shan
Format: Artikel
Sprache:eng
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Biomaterials
Biomedical and Life Sciences
Biomedicine
Cell Biology
Cell cycle
Cell growth
Gene expression
Hearing loss
Immunology
Kinases
Laboratories
Mammals
Neurosciences
Otolaryngology
Regenerative medicine
Regenerative Medicine/Tissue Engineering
Science
Stem Cells
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Zusammenfassung:Mammalian sensory hair cells (HCs) have limited capacity for regeneration, which leads to permanent hearing loss after HC death. Here, we used in vitro RNA-sequencing to show that the Hippo signaling pathway is involved in HC damage and self-repair processes. Turning off Hippo signaling through Mst1/2 inhibition or Yap overexpression induces YAP nuclear accumulation, especially in supporting cells, which induces supernumerary HC production and HC regeneration after injury. Mechanistically, these effects of Hippo signaling work synergistically with the Notch pathway. Importantly, the supernumerary HCs not only express HC markers, but also have cilia structures that are able to form neural connections to auditory regions in vivo. Taken together, regulating Hippo suggests new strategies for promoting cochlear supporting cell proliferation, HC regeneration, and reconnection with neurons in mammals.
ISSN:2057-3995
2057-3995
DOI:10.1038/s41536-022-00261-4