mTORC1 induces plasma membrane depolarization and promotes preosteoblast senescence by regulating the sodium channel Scn1a.
Ajuan ChenJian JinShasha ChengZezheng LiuCheng YangQingjing ChenWenquan LiangKai LiDawei KangZhicong OuyangChenfeng YaoXiao-Chun BaiQingchu LiDadi JinBin HuangPublished in: Bone research (2022)
Senescence impairs preosteoblast expansion and differentiation into functional osteoblasts, blunts their responses to bone formation-stimulating factors and stimulates their secretion of osteoclast-activating factors. Due to these adverse effects, preosteoblast senescence is a crucial target for the treatment of age-related bone loss; however, the underlying mechanism remains unclear. We found that mTORC1 accelerated preosteoblast senescence in vitro and in a mouse model. Mechanistically, mTORC1 induced a change in the membrane potential from polarization to depolarization, thus promoting cell senescence by increasing Ca 2+ influx and activating downstream NFAT/ATF3/p53 signaling. We further identified the sodium channel Scn1a as a mediator of membrane depolarization in senescent preosteoblasts. Scn1a expression was found to be positively regulated by mTORC1 upstream of C/EBPα, whereas its permeability to Na + was found to be gated by protein kinase A (PKA)-induced phosphorylation. Prosenescent stresses increased the permeability of Scn1a to Na + by suppressing PKA activity and induced depolarization in preosteoblasts. Together, our findings identify a novel pathway involving mTORC1, Scn1a expression and gating, plasma membrane depolarization, increased Ca 2+ influx and NFAT/ATF3/p53 signaling in the regulation of preosteoblast senescence. Pharmaceutical studies of the related pathways and agents might lead to novel potential treatments for age-related bone loss.
Keyphrases
- endothelial cells
- bone loss
- high glucose
- dna damage
- protein kinase
- stress induced
- diabetic rats
- mouse model
- poor prognosis
- drug induced
- signaling pathway
- transcription factor
- single cell
- endoplasmic reticulum stress
- risk assessment
- human health
- binding protein
- mesenchymal stem cells
- climate change
- toll like receptor
- smoking cessation