Increased mandibular condylar growth in mice with estrogen receptor beta deficiency.

Temporomandibular joint (TMJ) disorders predominantly afflict women of childbearing age, suggesting a role for female hormones in the disease process. In long bones, estrogen acting via estrogen receptor beta (ERß) inhibits axial skeletal growth in female mice. However, the role of ERß in the mandibular condyle is largely unknown. We hypothesize that female ERß-deficient mice will have increased mandibular condylar growth compared to wild-type (WT) female mice. This study examined female 7-day-old, 49-day-old, and 120-day-old WT and ERß knockout (KO) mice. There was a significant increase in mandibular condylar cartilage thickness as a result of an increased number of cells, in the 49-day-old and 120-day-old female ERß KO compared with WT controls. Analysis in 49-day-old female ERß KO mice revealed a significant increase in collagen type X, parathyroid hormone-related protein (Pthrp), and osteoprotegerin gene expression and a significant decrease in receptor activator for nuclear factor κ B ligand (Rankl) and Indian hedgehog (Ihh) gene expression, compared with WT controls. Subchondral bone analysis revealed a significant increase in total condylar volume and a decrease in the number of osteoclasts in the 49-day-old ERß KO compared with WT female mice. There was no difference in cell proliferation in condylar cartilage between the genotypes. However, there were differences in the expression of proteins that regulate the cell cycle; we found a decrease in the expression of Tieg1 and p57 in the mandibular condylar cartilage from ERß KO mice compared with WT mice. Taken together, our results suggest that ERß deficiency increases condylar growth in female mice by inhibiting the turnover of fibrocartilage.

Roles of SATB2 in osteogenic differentiation and bone regeneration.

Expressed in branchial arches and osteoblast-lineage cells, special AT-rich sequence-binding protein (SATB2) is responsible for preventing craniofacial abnormalities and defects in osteoblast function. In this study, we transduced SATB2 into murine adult stem cells, and found that SATB2 significantly increased expression levels of bone matrix proteins, osteogenic transcription factors, and a potent angiogenic factor, vascular endothelial growth factor. Using an osterix (Osx) promoter-luciferase construct and calvarial cells isolated from runt-related transcription factor 2 (Runx2)-deficient mice, we found that SATB2 upregulates Osx expression independent of Runx2, but synergistically enhances the regulatory effect of Runx2 on Osx promoter. We then transplanted SATB2-overexpressing adult stem cells genetically double-labeled with bone sialoprotein (BSP) promoter-driven luciferase and ß-actin promoter-driven enhanced green fluorescent protein into mandibular bone defects. We identified increased luciferase-positive cells in SATB2-overexpressing groups, indicating more transplanted cells undergoing osteogenic differentiation. New bone formation was consequently accelerated in SATB2 groups. In conclusion, SATB2 acts as a potent transcription factor to enhance osteoblastogenesis and promote bone regeneration. The application of SATB2 in bone tissue engineering gives rise to a higher bone forming capacity as a result of multiple-level amplification of regulatory activity.