Stimulation of skeletal stem cells in the growth plate promotes linear bone growth
Dana Trompet, Anastasiia D. Kurenkova, Baoyi Zhou, Lei Li, Ostap Dregval, Anna P. Usanova, Tsz Long Chu, Alexandra Are, Andrei A. Nedorubov, Maria Kasper, Andrei S. Chagin
Dana Trompet, Anastasiia D. Kurenkova, Baoyi Zhou, Lei Li, Ostap Dregval, Anna P. Usanova, Tsz Long Chu, Alexandra Are, Andrei A. Nedorubov, Maria Kasper, Andrei S. Chagin
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Research Article Bone biology Stem cells

Stimulation of skeletal stem cells in the growth plate promotes linear bone growth

Abstract

Recently, skeletal stem cells were shown to be present in the epiphyseal growth plate (epiphyseal skeletal stem cells, epSSCs), but their function in connection with linear bone growth remains unknown. Here, we explore the possibility that modulating the number of epSSCs can correct differences in leg length. First, we examined regulation of the number and activity of epSSCs by Hedgehog (Hh) signaling. Both systemic activation of Hh pathway with Smoothened agonist (SAG) and genetic activation of Hh pathway by Patched1 (Ptch1) ablation in Pthrp-creER Ptch1fl/fl tdTomato mice promoted proliferation of epSSCs and clonal enlargement. Transient intra-articular administration of SAG also elevated the number of epSSCs. When SAG-containing beads were implanted into the femoral secondary ossification center of 1 leg of rats, this leg was significantly longer 1 month later than the contralateral leg implanted with vehicle-containing beads, an effect that was even more pronounced 2 and 6 months after implantation. We conclude that Hh signaling activates growth plate epSSCs, which effectively leads to increased longitudinal growth of bones. This opens therapeutic possibilities for the treatment of differences in leg length.

Authors

Dana Trompet, Anastasiia D. Kurenkova, Baoyi Zhou, Lei Li, Ostap Dregval, Anna P. Usanova, Tsz Long Chu, Alexandra Are, Andrei A. Nedorubov, Maria Kasper, Andrei S. Chagin

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Figure 3

SAG administration expands the growth plate skeletal stem cell pool and creates a Wnt-inhibitory environment.

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SAG administration expands the growth plate skeletal stem cell pool and ...
(A) Representative images of Pthrp-mCherry mice treated with vehicle (DMSO) or SAG P30–P36 and sacrificed at P38. (B) Histological analysis of mCherry+ cells in the top 50 μm layer of the growth plate (n = 7/4 mice control/experiment). (C) Schematic representation of experimental setup. (D) Representative flow cytometry gating example for the quantification of Pthrp-mCherry+ cells in the growth plates of vehicle and SAG-treated Pthrp-mCherry mice, harvested at P38. (E and F) Quantification of CD73+ cells and CD73+mCherry+ cells obtained after digestion for FACS (n = 7/4 mice control/experiment). The percentage is calculated based on the total amount of live single cells obtained after the digestion of the bone marrow region cut as illustrated in C. (G) Volcano plot of Pthrp-mCherry+ bulk-sequenced cells (n = 4/4 control/experiment). (H) KEGG enrichment plots with most upregulated and downregulated pathways (n = 4/4 control/experiment). (I) Heatmap of 16 most up- and downregulated genes (n = 4/4 control/experiment). (J) Heatmap of of top differentially expressed Wnt pathway–associated genes (n = 4/4 control/experiment). Scale bar 50 μm. rz, resting zone; dashed lines depict the uppermost 50 μm of the growth plate.