Abstract
The Runt-related transcription factor, Runx2, is essential for osteogenesis and is controlled by both distal (P1) and proximal (P2) promoters. To understand Runx2 function requires determination of the spatiotemporal activity of P1 and P2 to Runx2 protein production. We generated a mouse model in which the P1-derived transcript was replaced with a lacZ reporter allele, resulting in loss of P1-derived protein while simultaneously allowing discrimination between the activities of the two promoters. Loss of P1-driven expression causes developmental defects with cleidocranial dysplasia-like syndromes that persist in the postnatal skeleton. P1 activity is robust in preosteogenic mesenchyme and at the onset of bone formation but decreases as bone matures. Homozygous Runx2-P1(lacZ/lacZ) mice have a normal life span but exhibit severe osteopenia and compromised bone repair in adult mice because of osteoblastic defects and not increased osteoclastic resorption. Gene expression profiles of bone, immunohistochemical studies, and ex vivo differentiation using calvarial osteoblasts and marrow stromal cells identified mechanisms for the skeletal phenotype. The findings indicate that P1 promoter activity is necessary for generating a threshold level of Runx2 protein to commit sufficient osteoprogenitor numbers for normal bone formation. P1 promoter function is not compensated via the P2 promoter. However, the P2 transcript with compensatory mechanisms from bone morphogenetic protein (BMP) and Wnt signaling is adequate for mineralization of the bone tissue that does form. We conclude that selective utilization of the P1 and P2 promoters enables the precise spatiotemporal expression of Runx2 necessary for normal skeletogenesis and the maintenance of bone mass in the adult.
Highlights
Runx2 is the master regulator of both osteoblast and terminal chondrocyte differentiation and is essential for in vivo bone formation and mineralization [1, 2]
Cellular and Molecular Basis for Defective Growth Plate Maturation and Reduced Cortical and Trabecular Bone Formation in Runx2-P1lacZ/lacZ Mice—To identify mechanisms contributing to the phenotype of these mice, we investigated the cellular basis for the delay in endochondral bone formation in the absence of Runx2 P1-derived protein expression (Fig. 4)
As a result of this spatiotemporal function of the P1 and P2 promoters, loss of Runx2 P1 protein results in a cleidocranial dysplasia (CCD) phenotype with severe osteopenia due to decreased osteoblast lineage cells throughout the life span of the homozygous mouse. This phenotype is caused by a combination of factors including: loss of Runx2 P1-driven protein in preosteogenic mesenchyme where the Runx2 P1 promoter exhibits robust expression; the inability of Runx2-P1lacZ/lacZ mice to generate sufficient committed osteoprogenitor cells to support normal bone formation; cell-autonomous defects in differentiation of ex vivo calvarial osteogenic cells isolated from Runx2-P1lacZ/lacZ mice; and the reduced expression of Runx2 target genes
Summary
Runx2 is the master regulator of both osteoblast and terminal chondrocyte differentiation and is essential for in vivo bone formation and mineralization [1, 2]. Elimination of Runx2 P1-driven expression results in coordinate down-regulation of Runx1 and Runx3 transcripts during membranous bone formation of the calvaria from Runx2-P1lacZ/lacZ mice compared with WT (Fig. 1F).
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