AUTHOR=Veistinen Lotta K. , Mustonen Tuija , Hasan Md. Rakibul , Takatalo Maarit , Kobayashi Yukiho , Kesper Dörthe A. , Vortkamp Andrea , Rice David P. 

TITLE=Regulation of Calvarial Osteogenesis by Concomitant De-repression of GLI3 and Activation of IHH Targets

JOURNAL=Frontiers in Physiology

VOLUME=8

YEAR=2017

URL=https://www.frontiersin.org/journals/physiology/articles/10.3389/fphys.2017.01036

DOI=10.3389/fphys.2017.01036

ISSN=1664-042X

ABSTRACT=<p>Loss-of-function mutations in <italic>GLI3</italic> and <italic>IHH</italic> cause craniosynostosis and reduced osteogenesis, respectively. In this study, we show that <italic>Ihh</italic> ligand, the receptor <italic>Ptch1</italic> and <italic>Gli</italic> transcription factors are differentially expressed in embryonic mouse calvaria osteogenic condensations. We show that in both <italic>Ihh</italic><sup>−/−</sup> and <italic>Gli3</italic><sup><italic>Xt</italic>−<italic>J</italic>/<italic>Xt</italic>−<italic>J</italic></sup> embryonic mice, the normal gene expression architecture is lost and this results in disorganized calvarial bone development. RUNX2 is a master regulatory transcription factor controlling osteogenesis. In the absence of <italic>Gli3</italic>, RUNX2 isoform II and IHH are upregulated, and RUNX2 isoform I downregulated. This is consistent with the expanded and aberrant osteogenesis observed in <italic>Gli3</italic><sup><italic>Xt</italic>−<italic>J</italic>/<italic>Xt</italic>−<italic>J</italic></sup> mice, and consistent with <italic>Runx2-I</italic> expression by relatively immature osteoprogenitors. <italic>Ihh</italic><sup>−/−</sup> mice exhibited small calvarial bones and HH target genes, <italic>Ptch1</italic> and <italic>Gli1</italic>, were absent. This indicates that IHH is the functional HH ligand, and that it is not compensated by another HH ligand. To decipher the roles and potential interaction of Gli3 and Ihh, we generated <italic>Ihh</italic><sup>−/−</sup>;<italic>Gli3</italic><sup><italic>Xt</italic>−<italic>J</italic>/<italic>Xt</italic>−<italic>J</italic></sup> compound mutant mice. Even in the absence of <italic>Ihh, Gli3</italic> deletion was sufficient to induce aberrant precocious ossification across the developing suture, indicating that the craniosynostosis phenotype of <italic>Gli3</italic><sup><italic>Xt</italic>−<italic>J</italic>/<italic>Xt</italic>−<italic>J</italic></sup> mice is not dependent on IHH ligand. Also, we found that Ihh was not required for <italic>Runx2</italic> expression as the expression of RUNX2 target genes was unaffected by deletion of <italic>Ihh</italic>. To test whether RUNX2 has a role upstream of IHH, we performed RUNX2 siRNA knock down experiments in WT calvarial osteoblasts and explants and found that <italic>Ihh</italic> expression is suppressed. Our results show that IHH is the functional HH ligand in the embryonic mouse calvaria osteogenic condensations, where it regulates the progression of osteoblastic differentiation. As GLI3 represses the expression of <italic>Runx2-II</italic> and <italic>Ihh</italic>, and also elevates the <italic>Runx2-I</italic> expression, and as IHH may be regulated by RUNX2 these results raise the possibility of a regulatory feedback circuit to control calvarial osteogenesis and suture patency. Taken together, RUNX2-controlled osteoblastic cell fate is regulated by IHH through concomitant inhibition of GLI3-repressor formation and activation of downstream targets.</p>