Author
Listed:
- Seoyeon Bok
(Weill Cornell Medicine)
- Alisha R. Yallowitz
(Weill Cornell Medicine)
- Jun Sun
(Weill Cornell Medicine)
- Jason McCormick
(Weill Cornell Medicine)
- Michelle Cung
(Weill Cornell Medicine)
- Lingling Hu
(Hospital for Special Surgery)
- Sarfaraz Lalani
(Weill Cornell Medicine)
- Zan Li
(Weill Cornell Medicine)
- Branden R. Sosa
(Weill Cornell Medicine)
- Tomas Baumgartner
(Weill Cornell Medicine)
- Paul Byrne
(Weill Cornell Medicine)
- Tuo Zhang
(Weill Cornell Medicine)
- Kyle W. Morse
(Hospital for Special Surgery)
- Fatma F. Mohamed
(University of Michigan)
- Chunxi Ge
(University of Michigan)
- Renny T. Franceschi
(University of Michigan)
- Randy T. Cowling
(University of California)
- Barry H. Greenberg
(University of California)
- David J. Pisapia
(Weill Cornell Medicine)
- Thomas A. Imahiyerobo
(New York-Presbyterian Hospital and Columbia University Medical Center)
- Shenela Lakhani
(Weill Cornell Medicine)
- M. Elizabeth Ross
(Weill Cornell Medicine)
- Caitlin E. Hoffman
(Weill Cornell Medicine and New York-Presbyterian Hospital)
- Shawon Debnath
(Weill Cornell Medicine)
- Matthew B. Greenblatt
(Weill Cornell Medicine
Hospital for Special Surgery)
Abstract
Craniosynostosis is a group of disorders of premature calvarial suture fusion. The identity of the calvarial stem cells (CSCs) that produce fusion-driving osteoblasts in craniosynostosis remains poorly understood. Here we show that both physiologic calvarial mineralization and pathologic calvarial fusion in craniosynostosis reflect the interaction of two separate stem cell lineages; a previously identified cathepsin K (CTSK) lineage CSC1 (CTSK+ CSC) and a separate discoidin domain-containing receptor 2 (DDR2) lineage stem cell (DDR2+ CSC) that we identified in this study. Deletion of Twist1, a gene associated with craniosynostosis in humans2,3, solely in CTSK+ CSCs is sufficient to drive craniosynostosis in mice, but the sites that are destined to fuse exhibit an unexpected depletion of CTSK+ CSCs and a corresponding expansion of DDR2+ CSCs, with DDR2+ CSC expansion being a direct maladaptive response to CTSK+ CSC depletion. DDR2+ CSCs display full stemness features, and our results establish the presence of two distinct stem cell lineages in the sutures, with both populations contributing to physiologic calvarial mineralization. DDR2+ CSCs mediate a distinct form of endochondral ossification without the typical haematopoietic marrow formation. Implantation of DDR2+ CSCs into suture sites is sufficient to induce fusion, and this phenotype was prevented by co-transplantation of CTSK+ CSCs. Finally, the human counterparts of DDR2+ CSCs and CTSK+ CSCs display conserved functional properties in xenograft assays. The interaction between these two stem cell populations provides a new biologic interface for the modulation of calvarial mineralization and suture patency.
Suggested Citation
Seoyeon Bok & Alisha R. Yallowitz & Jun Sun & Jason McCormick & Michelle Cung & Lingling Hu & Sarfaraz Lalani & Zan Li & Branden R. Sosa & Tomas Baumgartner & Paul Byrne & Tuo Zhang & Kyle W. Morse & , 2023.
"A multi-stem cell basis for craniosynostosis and calvarial mineralization,"
Nature, Nature, vol. 621(7980), pages 804-812, September.
Handle:
RePEc:nat:nature:v:621:y:2023:i:7980:d:10.1038_s41586-023-06526-2
DOI: 10.1038/s41586-023-06526-2
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