Abstract
How osteoblast cells are induced is a central question for understanding skeletal formation. Abnormal osteoblast differentiation leads to a broad range of devastating craniofacial diseases. Here we have investigated intramembranous ossification during cranial bone development in mouse models of skeletal genetic diseases that exhibit craniofacial bone defects. The GNAS gene encodes Gαs that transduces GPCR signaling. GNAS activation or loss-of-function mutations in humans cause fibrous dysplasia (FD) or progressive osseous heteroplasia (POH) that shows craniofacial hyperostosis or craniosynostosis, respectively. We find here that, while Hh ligand-dependent Hh signaling is essential for endochondral ossification, it is dispensable for intramembranous ossification, where Gαs regulates Hh signaling in a ligand-independent manner. We further show that Gαs controls intramembranous ossification by regulating both Hh and Wnt/β-catenin signaling. In addition, Gαs activation in the developing cranial bone leads to reduced ossification but increased cartilage presence due to reduced cartilage dissolution, not cell fate switch. Small molecule inhibitors of Hh and Wnt signaling can effectively ameliorate cranial bone phenotypes in mice caused by loss or gain of Gnas function mutations, respectively. Our work shows that studies of genetic diseases provide invaluable insights in both pathological bone defects and normal bone development, understanding both leads to better diagnosis and therapeutic treatment of bone diseases.
Highlights
Identifying the cellular and molecular mechanisms whereby osteoblast cells are induced is centrally important in understanding the organizational principles underpinning a functional skeletal system
The knowledge gained in these studies will facilitate development of therapeutic approaches for craniosynostosis, cleidocranial dysplasia, Progressive osseous heteroplasia (POH), and acquired heterotopic ossification (HO)
We have shown previously that Hh signaling is required before Wnt/βcatenin signaling during osteoblast differentiation.[19]
Summary
Identifying the cellular and molecular mechanisms whereby osteoblast cells are induced is centrally important in understanding the organizational principles underpinning a functional skeletal system. Osteoblast differentiation was examined by alkaline phosphatase (Alp) and Osx expression, which were both increased in the Prrx1-Cre; Gnasf(R201H)/+ mutants to loss of Gli[2] function resulted in reduced intramembranous bone formation.[36] We asked whether Gαs critically regulates intramembranous ossification during cranial vault bone formation by inhibiting Hh signaling. Gαs signaling activation in osteoblast lineage increases cartilage formation without changing cell fate specification In both Prrx1-Cre; Gnasf(R201H)/+ and Osx1-GFP::Cre; Gnasf(R201H)/+ mice, we found that reduced ossification in the cranial bone was accompanied by increased cartilage formation as evidence by increased Safranin O staining compared to the controls (Fig. 8a, S5a). These results provide further insights in strategic development to treat FD, POH, and other related craniofacial bone malformation such as craniosynostosis
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