Methyltransferase G9A Regulates Osteogenesis via Twist Gene Repression

Here we investigate the role of epigenetic factors in controlling the timing of cranial neural crest cell differentiation. the gene coding for histone h3 lysine 9 methyltransferase g9a was conditionally deleted in neural crest cells with wnt1-cre. the majority of homozygous-null animals survived to birth but thereafter failed to thrive. phenotypic analysis of postnatal animals revealed that the mutants displayed incomplete ossification and 20% shorter jaws as compared to their wild-type littermates. at e13.5,patterns of expression of the osteogenic transcription factor runx2 and the mesenchymal transcription factor twist are similar in controls and mutants; both overlap in areas of future intramembranous bone formation. at e14.5,the nonosteogenic mesenchyme expressed twist,whereas the ossification center had strong runx2 and osteopontin expression. in the mutants,twist protein was present in the osteogenic mesenchyme,while osteopontin was not expressed until e15.5. in addition,in mutants,small regions of twist-positive osteogenic mesenchyme were visible until e15.5. the delay in ossification and reduction in size of the ossification centers were correlated with an earlier decrease in proliferation. we used micromass cultures of the face to investigate the direct effects of g9a inhibition on skeletal differentiation. addition of a small molecule inhibitor for g9a,bix-01294,to wild-type cells upregulated twist genes similar to what was observed in vivo. the inhibitor also caused decreases in several osteogenic markers. chromatin immunoprecipitation analysis of primary osteogenic mesenchyme from calvaria revealed that twist1 and twist2 regulatory regions contain the repressive h3k9me2 marks catalyzed by g9a,which are removed when bix-01294 is added. our results establish a role for g9a and h3k9me2 in the regulation of twist genes and provide novel insights into the significance of epigenetic mechanisms in controlling temporal and tissue-specific gene expression during development. © international & american associations for dental research.