Identification of Postn+ periosteal progenitor cells with bone regenerative potential
Bei Yin, Fangyuan Shen, Qingge Ma, Yongcheng Liu, Xianglong Han, Xuyu Cai, Yu Shi, Ling Ye
Bei Yin, Fangyuan Shen, Qingge Ma, Yongcheng Liu, Xianglong Han, Xuyu Cai, Yu Shi, Ling Ye
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Research Article Bone biology

Identification of Postn+ periosteal progenitor cells with bone regenerative potential

Abstract

Bone contains multiple pools of skeletal stem/progenitor cells (SSPCs), and SSPCs in periosteal compartments are known to exhibit higher regenerative potential than those in BM and endosteal compartments. However, the in vivo identity and hierarchical relationships of periosteal SSPCs (P-SSPCs) remain unclear due to a lack of reliable markers to distinguish BM SSPCs and P-SSPCs. Here, we found that periosteal mesenchymal progenitor cells (P-MPs) in periosteum can be identified based on Postn-CreERT2 expression. Postn-expressing periosteal subpopulation produces osteolineage descendants that fuel bones to maintain homeostasis and support regeneration. Notably, Postn+ P-MPs are likely derived from Gli1+ skeletal stem cells (SSCs). Ablation of Postn+ cells results in impairments in homeostatic cortical bone architecture and defects in fracture repair. Genetic deletion of Igf1r in Postn+ cells dampens bone fracture healing. In summary, our study provides a mechanistic understanding of bone regeneration through the regulation of region-specific Postn+ P-MPs.

Authors

Bei Yin, Fangyuan Shen, Qingge Ma, Yongcheng Liu, Xianglong Han, Xuyu Cai, Yu Shi, Ling Ye

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Figure 4

The Postn+ cells may be derived from Gli1+ cells.

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The Postn+ cells may be derived from Gli1+ cells. (A) The distribution o...
(A) The distribution of Gli1 reporter activity and immunofluorescence staining of POSTN in the femoral metaphyseal periosteum of Gli1-CreERT2; tdTomato mice with tamoxifen injection for 3 days and samples acquired at day 4. (B) The distribution of tdTomato reporter activity and immunofluorescence staining of POSTN and CTSK in Gli1-CreERT2; tdTomato mice 1 month after tamoxifen injection for 3 days. To the right of the dashed box showed Z stack images of the cell in dashed box. (C) The distribution of tdTomato reporter activity and immunofluorescence staining of KI67, POSTN, and CTSK in day 10 callus of Gli1-CreERT2; tdTomato mice with tamoxifen injection at post fracture days 8 and 9. (D) The immunofluorescence staining of POSTN and CTSK in day 5 callus of Gli1-CreERT2; tdTomato mice. Data were obtained from 3 independent experiments. Data are presented as mean ± SD. n = 3 per genotype. Red scale bar: 200 μm. White scale bar: 20 μm. Orange scale bar: 5 μm. F, fibrous layer; C, cambium layer; B, cortical bone; Ca, callus. See also Supplemental Figure 4.