Stem cell–associated osteogenic deficiency causes craniofacial deformities with progeroid accumulation of prelamin A
Kai Li, Trunee Hsu, Hitoshi Uchida, Tingxi Wu, Susan Michaelis, Howard Worman, Wei Hsu
Kai Li, Trunee Hsu, Hitoshi Uchida, Tingxi Wu, Susan Michaelis, Howard Worman, Wei Hsu
View: Text | PDF
Research Article Aging Cell biology Development

Stem cell–associated osteogenic deficiency causes craniofacial deformities with progeroid accumulation of prelamin A

Abstract

Mutations in LMNA, encoding nuclear lamina protein Lamin A/C, cause premature aging disorders, most notably Hutchinson-Gilford progeria syndrome. Despite obvious skull abnormalities in patients with progeria, the etiology remains elusive. The L648R single–amino acid substitution blocks prelamin A maturation in mice, modeling a unique patient. Here, we identify prelamin A accumulation as a causative link to craniosynostosis in low bone density, contrasting conventional suture fusion in excessive ossification. The mutation causes skeletal stem cell deficiencies and subsequent osteogenesis. Intrasutural bones present in patients with progeria resemble synostosis caused by stem cell exhaustion. Comparative gene expression profiling further reveals cytoskeletal dynamics associated with skeletogenic cell aging and suture patency in mice and humans. Functional studies demonstrate that abnormal structures of progeric nuclei affect cytoskeleton organization and nucleoskeleton assembly essential for craniofacial skeletogenesis. Our findings provide compelling evidence for nuclear and cytoskeletal defects, causing stem cell–associated osteogenic defects in progeroid disorders.

Authors

Kai Li, Trunee Hsu, Hitoshi Uchida, Tingxi Wu, Susan Michaelis, Howard Worman, Wei Hsu

×

Figure 5

Transcriptomic profiling linking cytoskeletal regulation to skeletal cell aging.

Options: View larger image (or click on image) Download as PowerPoint
Transcriptomic profiling linking cytoskeletal regulation to skeletal cel...
(A) UMAP plots visualize 3 batches of single-cell sequencing datasets. (B) Clustering a total of 20,811 cells into 10 subsets: granulocyte (GRAN), monocyte (MONO), erythrocyte (ERY), myeloid cell (MC), T lymphocyte (T Cell), skeletogenic cell (SC), endothelial cell (ENDO), B lymphocyte (B Cell), megakaryocyte (MK), and pericyte (PERI). (C) Dot plot showing marker gene expression for the classification of 10 clusters. (D) Pathway enrichment analysis of 2135 DEGs in SC cluster exhibited with a bar graph showing selected pathways, including cytoskeleton and cell adhesion, related to stem cell regulation from the top 10 enriched KEGG pathways (P < 0.05, logFC < –0.1, 2M versus 18M).