Periderm cells covering palatal shelves have tight junctions and their desquamation reduces the polarity of palatal shelf epithelial cells in palatogenesis.

In palatogenesis, bilateral palatal shelves grow and fuse with each other to establish mesenchyme continuity across the horizontal palate. The palatal shelves are covered with the medial edge epithelium (MEE) in which most apical cells are periderm cells. We investigated localization and roles of tight junction (TJ) and adherens junction (AJ) components and an apical membrane marker in the MEE in palatogenesis. Immunofluorescence and immunoelectron microscopy analyses revealed that TJs were located at the boundary between neighboring periderm cells, whereas AJ components were localized at the boundary between all epithelial cells in the MEE. Specifically, typical AJs were observed at the boundaries between neighboring periderm cells and between periderm cells and underlying epithelial cells where the signal for nectin-1 was observed. The TGF-ß-induced desquamation of periderm cells reduced the polarity of remaining epithelial cells as estimated by changes of epithelial cell morphology and the staining of the polarity marker and the AJ components. These less polarized epithelial cells then intermingled and finally disappeared at least partly by apoptosis. These results indicate that periderm cells covering growing palatal shelves have bona fide TJs and their desquamation reduces the polarity of palatal shelf epithelial cells in palatogenesis.

Sox9 expression during fracture repair.

The molecular and cellular mechanisms involved in bone development provide an insight into the nature of bone regeneration. Sox9 is a key transcription factor for chondrogenesis and is also expressed in osteochondroprogenitors during embryonic bone development. However, it has not been determined whether Sox9-expressing cells appear during fracture repair other than in the cartilaginous callus. On the other hand, the difference between bone development and repair is that the motion of the fractured segments is associated with the subsequent fate decision of osteochondrogenic precursors between osteogenesis or chondrogenesis, but the underlying mechanism of this still has to be elucidated. We herein evaluate whether Sox9-expressing cells appear during osseous regeneration in the initial stages of fracture healing in vivo. We also investigated the association between Sox9 induction and mechanical stress and the role of Runx1 expression. As a result, Sox9- and Runx1-expressing cells were detected in the periosteal callus together with Runx2 expression. Their expression levels were significantly downregulated during its ossification, as observed in embryonic bone development. The application of cyclic tension to isolated and cultured stromal cells resulted in the upregulation and maintenance of Sox9 mRNA expression in vitro. These results showed that as in early skeletal development, Sox9- and Runx1-expressing precursor cells first appear in the periosteal callus as an early fracture repair response. Our findings also suggested that the mechanical environment modulates Sox9 expression levels in osteochondrogenic precursors and consequently influences their fate decision between osteogenic and chondrogenic lineage commitment.

Runx1 is involved in the fusion of the primary and the secondary palatal shelves.

Runx1 is expressed in medial edge epithelial (MEE) cells of the palatal shelf. Conditionally rescued Runx1(-/-) mice showed limited clefting in the anterior junction between the primary and the secondary palatal shelves, but not in the junction between the secondary palates. In wild type mice, the fusing epithelial surface exhibited a rounded cobblestone-like appearance, while such cellular prominence was less evident in the Runx1 mutants. We also found that Fgf18 was expressed in the mesenchyme underlying the MEE and that locally applied FGF18 induced ectopic Runx1 expression in the epithelium of the palatal explants, indicating that Runx1 was induced by mesenchymal Fgf18 signaling. On the other hand, unpaired palatal explant cultures revealed the presence of anterior-posterior (A-P) differences in the MEE fates and fusion mechanism. Interestingly, the location of anterior clefting in Runx1 mutants corresponded to the region with different MEE behavior. These data showed a novel function of Runx1 in morphological changes in the MEE cells in palatal fusion, which is, at least in part, regulated by the mesenchymal Fgf signaling via an epithelial-mesenchymal interaction.

Diclofenac inhibits proliferation and differentiation of neural stem cells.

Nonsteroidal anti-inflammatory drugs (NSAIDs) are widely used in clinical situations as anti-inflammatory, analgesic and antipyretic drugs. However, it is still unknown whether NSAIDs have effects on the development of the central nervous system. In the present study, we investigated the effects of NSAIDs on neural stem cell (NSC) proliferation and differentiation into neurons. In contrast to aspirin, naproxen, indomethacin and ibuprofen, treatment with diclofenac (10 microM) for 2 days induced the death of NSCs in a concentration-dependent manner. Diclofenac also inhibited the proliferation of NSCs and their differentiation into neurons. Treatment with diclofenac resulted in nuclear condensation (a morphological change due to apoptosis of NSCs) 24hr after the treatment and activated caspase-3 after 6 hr, indicating that diclofenac may cause apoptosis of neuronal cells via activation of the caspase cascade. These results suggest that diclofenac may affect the development of the central nervous system.