Senescence of bone marrow-derived mesenchymal stem cells (BMSCs) has been widely reported to be closely correlated with aging-related diseases, including osteoporosis (OP). Moreover, the beneficial functions of BMSCs decline with age, limiting their therapeutic efficacy in OP. In the present study, using RNA sequencing (RNA-Seq), we found that leucine-rich repeat containing 17 (LRRc17) expression in BMSCs was highly positively correlated with age. Therefore, we investigated whether LRRc17 knockdown could rejuvenate aged MSCs and increase their therapeutic efficacy in OP. Consistent with the RNA-Seq results, the protein expression of LRRc17 in senescent BMSCs was significantly increased, whereas LRRc17 knockdown inhibited cell apoptosis and reduced the expression of age-related proteins and G2 and S phase quiescence. Furthermore, LRRc17 knockdown shifted BMSCs from adipogenic to osteogenic differentiation, indicating the critical role of LRRc17 in BMSC senescence and differentiation. Additionally, similar to rapamycin (RAPA) treatment, LRRc17 knockdown activated mitophagy via inhibition of the mTOR/PI3K pathway, which consequently reduced mitochondrial dysfunction and inhibited BMSC senescence. However, the effects of LRRc17 knockdown were significantly blocked by the autophagy inhibitor hydroxychloroquine (HCQ), demonstrating that LRRc17 knockdown prevented BMSC senescence by activating mitophagy. In vivo , compared with untransfected aged mouse-derived BMSCs (O-BMSCs), O-BMSCs transfected with sh-LRRc17 showed effective amelioration of ovariectomy (OVX)-induced bone loss. Collectively, these results indicated that LRRc17 knockdown rejuvenated senescent BMSCs and thus enhanced their therapeutic efficacy in OP by activating autophagy.
Objective Cisplatin, an anticancer drug, always lead to nephrotoxicity via causing mitochondrial dysfunction. As a major catabolic pathway, autophagy has been proved that could protect against cisplatin‐induced acute kidney injury (AKI). Base on the activation of autophagy induced by trehalose, we aimed to investigated whether trehalose could alleviate mitochondrial dysfunction and kidney injury in mice though autophagy‐lysosome mediated clearance of damaged mitochondria. Methods Mice were administered a single intraperitoneal (i.p.) injection of cisplatin 16mg/kg to induce AKI, then mice were treated with PBS or trehalose (i.p.). In vitro, HK2 cells were treated with cisplatin 16mg/kg in the presence or absence of trehalose. To evaluate mitochondrial bioenergetic, mitochondrial morphology, membrane potential and ATP content were detected. Results In vivo, comparing with the normal mice, BUN and Crea were significantly increased in AKI mice, while decreased after the treatment with trehalose, indicating that trehalose could alleviate kidney injury in AKI mice. In vitro, along with the activation of autophagy (elevated expression of LC3 II and ATG5), mitochondrial fragmentation, depolarization, and reduced ATP generation induced by cisplatin were markedly inhibited in trehalose‐treated HK2 cells. Moreover, the double immunofluorescence staining results showed that the co‐localization between mitochondria and LC3 was increased, indicating that the mitophagy was induced. In addition, we found that the protective effect of trehalose was largely abolished when the autophagy process was inhibited by HCQ. Conclusion These results indicated that trehalose can ameliorate cisplatin‐induced mitochondrial dysfunction by activating autophagy, and thus it might be a promising therapy to acute kidney injury. This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
Mesenchymal stem cells (MSCs) have fueled ample translation for treatment of immune-mediated diseases. Our previous study had demonstrated that MSCs could elicit macrophages (Mφ) into anti-inflammatory phenotypes, and alleviate kidney injury in diabetic nephropathy (DN) mice via improving mitochondrial function of Mφ, yet the specific mechanism was unclear. Recent evidence indicated that MSCs communicated with their microenvironment through exchanges of mitochondria. By a coculture system consisting of MSCs and Mφ, we showed that MSCs-derived mitochondria (MSCs-Mito) were transferred into Mφ, and the mitochondrial functions were improved, which contributed to M2 polarization. Furthermore, we found that MSCs-Mito transfer activated peroxisome proliferator-activated receptor gamma coactivator-1 alpha (PGC-1α)-mediated mitochondrial biogenesis. In addition, PGC-1α interacted with TFEB in high glucose-induced Mφ, leading to the elevated lysosome-autophagy, which was essential to removal of damaged mitochondria. As a result, in Mφ, the mitochondrial bioenergy and capacity to combat inflammatory response were enhanced. Whereas, the immune-regulatory activity of MSCs-Mito was significantly blocked in PGC-1α knockdown Mφ. More importantly, MSCs-Mito transfer could be observed in DN mice, and the adoptive transfer of MSCs-Mito educated Mφ (MφMito) inhibited the inflammatory response and alleviated kidney injury. However, the kidney-protective effects of MφMito were abolished when the MSCs-Mito was impaired with rotenone, and the similar results were also observed when MφMito were transfected with sipgc-1α before administration. Collectively, these findings suggested that MSCs elicited Mφ into anti-inflammatory phenotype and ameliorated kidney injury through mitochondrial transfer in DN mice, and the effects were relied on PGC-1α-mediated mitochondrial biogenesis and PGC-1α/TFEB-mediated lysosome-autophagy.
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