Disruption of distal appendage protein CEP164 causes skeletal malformation in mice

Biochem Biophys Res Commun. 2024 Dec 31:741:151063. doi: 10.1016/j.bbrc.2024.151063. Epub 2024 Nov 26.

Abstract

The primary cilium is a cellular antenna to orchestrate cell growth and differentiation. Deficient or dysfunctional cilia are frequently linked to skeletal abnormalities. Previous research demonstrated that ciliary proteins regulating axoneme elongation are essential for skeletogenesis. However, the role of the ciliary proteins responsible for initiating cilium assembly in skeletal development remains unknown. Here, we investigate the function of centrosomal protein of 164 kDa (CEP164), a key ciliogenesis regulator that localizes at the distal appendages of the mother centriole, during skeletal development in mice. Interestingly, the mesodermal cell-specific Cep164 deletion resulted in severe bone defects and osteoblast-specific deletion of Cep164 affected bone development. In contrast, chondrocyte-specific Cep164 deletion did not cause overt skeletal abnormalities, indicating that CEP164 functions in a cell type-specific manner within skeletal tissues. Importantly, Cep164-mutant osteoblasts not only displayed a lack of cilia but also showed an increased number of γH2AX-positive cells, indicating the involvement of defective DNA damage response in the etiology of skeletal lesions of Cep164-mutant mice. These results demonstrate that CEP164 has both ciliary and non-ciliary functions to control osteoblast growth and survival. Our study therefore reveals a novel understanding of the pathogenesis of skeletal ciliopathies associated with CEP164 dysfunction.

Keywords: Bone; CEP164; Cilia; DNA damage response; Mice.

MeSH terms

  • Animals
  • Bone and Bones / abnormalities
  • Bone and Bones / metabolism
  • Bone and Bones / pathology
  • Chondrocytes / metabolism
  • Chondrocytes / pathology
  • Cilia* / genetics
  • Cilia* / metabolism
  • Cilia* / pathology
  • DNA Damage
  • Mice
  • Mice, Knockout
  • Osteoblasts* / metabolism
  • Osteoblasts* / pathology