Title

A Runx2 threshold for the cleidocranial dysplasia phenotype

UMMS Affiliation

Department of Cell Biology; Department of Cancer Biology

Date

11-26-2008

Document Type

Article

Subjects

Animals; Bone Development; Cells, Cultured; Clavicle; Cleidocranial Dysplasia; Core Binding Factor Alpha 1 Subunit; Female; Growth Plate; Humans; Male; Mice; Mice, Inbred C57BL; Mice, Transgenic; Osteoblasts; Phenotype; Skull

Disciplines

Life Sciences | Medicine and Health Sciences

Abstract

Cleidocranial dysplasia (CCD) in humans is an autosomal-dominant skeletal disease that results from mutations in the bone-specific transcription factor RUNX2 (CBFA1/AML3). However, distinct RUNX2 mutations in CCD do not correlate with the severity of the disease. Here we generated a new mouse model with a hypomorphic Runx2 mutant allele (Runx2(neo7)), in which only part of the transcript is processed to full-length (wild-type) Runx2 mRNA. Homozygous Runx2(neo7/neo7) mice express a reduced level of wild-type Runx2 mRNA (55-70%) and protein. This mouse model allowed us to establish the minimal requirement of functional Runx2 for normal bone development. Runx2(neo7/neo7) mice have grossly normal skeletons with no abnormalities observed in the growth plate, but do exhibit developmental defects in calvaria and clavicles that persist through post-natal growth. Clavicle defects are caused by disrupted endochondral bone formation during embryogenesis. These hypomorphic mice have altered calvarial bone volume, as observed by histology and microCT imaging, and decreased expression of osteoblast marker genes. The bone phenotype of the heterozygous mice, which have 79-84% of wild-type Runx2 mRNA, is normal. These results show there is a critical gene dosage requirement of functional Runx2 for the formation of intramembranous bone tissues during embryogenesis. A decrease to 70% of wild-type Runx2 levels results in the CCD syndrome, whereas levels >79% produce a normal skeleton. Our findings suggest that the range of bone phenotypes in CCD patients is attributable to quantitative reduction in the functional activity of RUNX2.

Rights and Permissions

Citation: Hum Mol Genet. 2009 Feb 1;18(3):556-68. Epub 2008 Nov 20. Link to article on publisher's site

Related Resources

Link to Article in PubMed

PubMed ID

19028669