SphK1/mitophagy axis in cementocytes drives orthodontic root resorption via mitochondrial transfer to osteoclasts
Wang Han, Chen Sihang, Chen Shuo, Duan Chengchen, Zhu Li, Lin Hengyi, Zou Shujuan, Li Yu, Duan Peipei
Journal:Bone Research
IF:20.1
DOI:10.1038/s41413-026-00538-0
PMID:42135275
Published:2026-05-14
research field:骨重建线粒体动力学细胞生物学牙科分子信号传导
Abstract
Orthodontically induced inflammatory root resorption (OIIRR) is a prevalent complication driven by excessive mechanical force, yet the underlying mechanisms linking mechanotransduction to osteoclast activation remain elusive. Here, we identify a novel signaling axis wherein sphingosine kinase 1 (SphK1) in cementocytes translates heavy orthodontic force into a pro-osteoclastogenic signal via mitophagy-mediated mitochondrial transfer. In vivo, heavy force induced OIIRR and upregulated mitophagy markers in cementocytes. In vitro, heavy compression force triggered SphK1-dependent mitophagy in IDG-CM6 cementocytes, as evidenced by increased mitophagosome formation, co-localization of mitochondria with lysosomes, and elevated PINK1/PARKIN signaling. Inhibition of SphK1, either pharmacologically or genetically, suppressed this mitophagic response. Conditioned media from force-loaded cementocytes enhanced osteoclast differentiation and glycolytic metabolism, effects that were abolished by SphK1 inhibition and rescued by a mitophagy agonist. Crucially, we demonstrated that heavy force promotes the transfer of mitochondria from cementocytes to osteoclast precursors, a process dependent on mitophagy. This transferred mitochondrial cargo functioned as a metabolic subsidy, boosting osteoclast bioenergetics and resorptive activity. Our findings unveil the SphK1-mitophagy-mitochondrial transfer axis as a fundamental mechanism of cementocyte-osteoclast communication, positioning SphK1 as a promising therapeutic target to prevent OIIRR.
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