Subset of the periodontal ligament expressed leptin receptor contributes to part of hard tissue-forming cells.

The lineage of periodontal ligament (PDL) stem cells contributes to alveolar bone (AB) and cementum formation, which are essential for tooth-jawbone attachment. Leptin receptor (LepR), a skeletal stem cell marker, is expressed in PDL; however, the stem cell capacity of LepR+ PDL cells remains unclear. We used a Cre/LoxP-based approach and detected LepR-cre-labeled cells in the perivascular around the root apex; their number increased with age. In the juvenile stage, LepR+ PDL cells differentiated into AB-embedded osteocytes rather than cementocytes, but their contribution to both increased with age. The frequency of LepR+ PDL cell-derived lineages in hard tissue was < 20% per total cells at 1-year-old. Similarly, LepR+ PDL cells differentiated into osteocytes following tooth extraction, but their frequency was < 9%. Additionally, both LepR+ and LepR- PDL cells demonstrated spheroid-forming capacity, which is an indicator of self-renewal. These results indicate that both LepR+ and LepR- PDL populations contributed to hard tissue formation. LepR- PDL cells increased the expression of LepR during spheroid formation, suggesting that the LepR- PDL cells may hierarchically sit upstream of LepR+ PDL cells. Collectively, the origin of hard tissue-forming cells in the PDL is heterogeneous, some of which express LepR.

Development of a method for the identification of receptor activator of nuclear factor-κB+ populations in vivo.

OBJECTIVES: Osteoclasts are induced by macrophage colony-stimulating factor-1 (CSF-1) and receptor activator of nuclear factor-κB (RANK) ligand (RANKL). Monocyte/macrophage lineages are thought to be osteoclast precursors; however, such cells have not been fully characterized owing to a lack of tools for their identification. Osteoclast precursors express colony-stimulating factor-1 receptor (CSF-1R) and RANK. However, the capacity of conventional methods using anti-RANK antibodies to detect RANK+ cells by flow cytometry is insufficient. Here, we developed a high-sensitivity method for detecting RANK+ cells using biotinylated recombinant glutathione S-transferase-RANKL (GST-RANKL-biotin). METHODS: We sorted sub-populations of mouse bone marrow (BM) or peripheral blood (PB) cells using GST-RANKL-biotin, anti-CSF1R, and anti-B220 antibodies and induced osteoclastogenesis in vitro. RESULTS: The frequency of the RANK+ population in BM detected by GST-RANKL-biotin was significantly higher than that detected by anti-RANK antibodies. Although RANK+ cells were detected in both the B220+ and B220- populations, the macrophage lineage was present only in B220-. Unexpectedly, a significantly higher number of osteoclasts was induced in RANK-CSF-1R+ cells than in RANK+CSF-1R+ cells contained in the B220- population. In contrast, the PB-derived B220-RANK+CSF-1R+ population contained a significantly higher frequency of osteoclast precursors than the B220-RANK-CSF-1R+ population. CONCLUSIONS: These results suggest that GST-RANKL-biotin is useful for the detection of RANK+ cells and that RANK and CSF-1R may be helpful indicators of osteoclast precursors in PB.