破骨细胞
重编程
糖酵解
细胞生物学
β氧化
表观遗传学
脂肪酸代谢
代谢途径
化学
生物
脂肪酸
生物化学
新陈代谢
细胞
受体
基因
作者
Wenxiang Chu,Weilin Peng,Yingying Lü,Yishan Liu,Qisheng Li,Haibin Wang,Liang Wang,Bangke Zhang,Zhixiao Liu,Yuxia Ma,Hongdao Ma,Haisong Yang,Chaofeng Han,Xuhua Lu
标识
DOI:10.1002/advs.202403177
摘要
Abstract Epigenetic regulation of metabolism profoundly influences cell fate commitment. During osteoclast differentiation, the activation of RANK signaling is accompanied by metabolic reprogramming, but the epigenetic mechanisms by which RANK signaling induces this reprogramming remain elusive. By transcriptional sequence and ATAC analysis, this study identifies that activation of RANK signaling upregulates PRMT6 by epigenetic modification, triggering a metabolic switching from fatty acids oxidation toward glycolysis. Conversely, Prmt6 deficiency reverses this shift, markedly reducing HIF‐1α‐mediated glycolysis and enhancing fatty acid oxidation. Consequently, PRMT6 deficiency or inhibitor impedes osteoclast differentiation and alleviates bone loss in ovariectomized (OVX) mice. At the molecular level, Prmt6 deficiency reduces asymmetric dimethylation of H3R2 at the promoters of genes including Ppard , Acox3 , and Cpt1a , enhancing genomic accessibility for fatty acid oxidation. PRMT6 thus emerges as a metabolic checkpoint, mediating metabolic switch from fatty acid oxidation to glycolysis, thereby supporting osteoclastogenesis. Unveiling PRMT6's critical role in epigenetically orchestrating metabolic shifts in osteoclastogenesis offers a promising target for anti‐resorptive therapy.
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