Identification of LRP1+CD13+ human periosteal stem cells that require LRP1 for bone repair
Youngjae Jeong, … , John R. Dawson, Dongsu Park
Youngjae Jeong, … , John R. Dawson, Dongsu Park
Published October 15, 2024
Citation Information: JCI Insight. 2024;9(22):e173831. https://doi.org/10.1172/jci.insight.173831.
View: Text | PDF
Research Article Bone biology Stem cells

Identification of LRP1+CD13+ human periosteal stem cells that require LRP1 for bone repair

Abstract

Human periosteal skeletal stem cells (P-SSCs) are critical for cortical bone maintenance and repair. However, their in vivo identity, molecular characteristics, and specific markers remain unknown. Here, single-cell sequencing revealed human periosteum contains SSC clusters expressing known SSC markers, podoplanin (PDPN) and PDGFRA. Notably, human P-SSCs, but not bone marrow SSCs, selectively expressed identified markers low density lipoprotein receptor-related protein 1 (LRP1) and CD13. These LRP1+CD13+ human P-SSCs were perivascular cells with high osteochondrogenic but minimal adipogenic potential. Upon transplantation into bone injuries in mice, they preserved self-renewal capability in vivo. Single-cell analysis of mouse periosteum further supported the preferential expression of LRP1 and CD13 in Prx1+ P-SSCs. When Lrp1 was conditionally deleted in Prx1 lineage cells, it led to severe bone deformity, short stature, and periosteal defects. By contrast, local treatment with an LRP1 agonist at the injury sites induced early P-SSC proliferation and bone healing. Thus, human and mouse periosteum contains unique osteochondrogenic stem cell subsets, and these P-SSCs express specific markers, LRP1 and CD13, with a regulatory mechanism through LRP1 that enhances P-SSC function and bone repair.

Authors

Youngjae Jeong, Lorenzo Deveza, Laura Ortinau, Kevin Lei, John R. Dawson, Dongsu Park

×

Figure 9

Conditional deletion of Lrp1 in Prx1+ cells leads to skeletal dysplasia.

Options: View larger image (or click on image) Download as PowerPoint
Conditional deletion of Lrp1 in Prx1+ cells leads to skeletal dysplasia....
(AC) Representative images of 4-week-old Prx1Cre Lrp1wt/wt and Prx1Cre Lrp1fl/fl mice and tibial 3D reconstructed μCT images. (D and E) μCT images of trabecular bone regions. (FI) Histological section of Prx1Cre Rosa26tdTomato Lrp1wt/wt and Prx1Cre Rosa26tdTomato Lrp1fl/fl mice and (G and I) zoomed-in regions of periosteum (microfracture: white arrowhead). (J) Average thickness of tdTomato+ periosteum from Prx1Cre Rosa26tdTomato Lrp1wt/wt and Prx1Cre Rosa26tdTomato Lrp1fl/fl mice. (K and L) Images showing Prx1Cre Lrp1wt/wt and Prx1Cre Lrp1fl/fl periosteal cells on day 3 and day 7. Quantitative measurement of number of cells in fold-change relative to day 0 shows Prx1Cre Lrp1fl/fl periosteal cells have significantly lower cell numbers compared with Prx1Cre Lrp1wt/wt mice (P < 0.01) (n = 5). Data presented as mean ± SD. ***P < 0.001 by 2-tailed Student’s t test.