Enhanced TRPC3 transcription through AT1R/PKA/CREB signaling contributes to mitochondrial dysfunction in renal tubular epithelial cells in D-galactose-induced accelerated aging mice.
Bin WangWenpei YuWeiguang ZhangMin ZhangYue NiuXinye JinJie ZhangDing SunHao LiZehao ZhangQing LuoXiaowei ChengJingxue NiuGuangyan CaiXiangmei ChenYizhi ChenPublished in: Aging cell (2024)
Aging-associated renal dysfunction promotes the pathogenesis of chronic kidney disease. Mitochondrial dysfunction in renal tubular epithelial cells is a hallmark of senescence and leads to accelerated progression of renal disorders. Dysregulated calcium profiles in mitochondria contribute to aging-associated disorders, but the detailed mechanism of this process is not clear. In this study, modulation of the sirtuin 1/angiotensin II type 1 receptor (Sirt1/AT1R) pathway partially attenuated renal glomerular sclerosis, tubular atrophy, and interstitial fibrosis in D-galactose (D-gal)-induced accelerated aging mice. Moreover, modulation of the Sirt1/AT1R pathway improved mitochondrial dysfunction induced by D-gal treatment. Transient receptor potential channel, subtype C, member 3 (TRPC3) upregulation mediated dysregulated cellular and mitochondrial calcium homeostasis during aging. Furthermore, knockdown or knockout (KO) of Trpc3 in mice ameliorated D-gal-induced mitochondrial reactive oxygen species production, membrane potential deterioration, and energy metabolism disorder. Mechanistically, activation of the AT1R/PKA pathway promoted CREB phosphorylation and nucleation of CRE2 binding to the Trpc3 promoter (-1659 to -1648 bp) to enhance transcription. Trpc3 KO significantly improved the renal disorder and cell senescence in D-gal-induced mice. Taken together, these results indicate that TRPC3 upregulation mediates age-related renal disorder and is associated with mitochondrial calcium overload and dysfunction. TRPC3 is a promising therapeutic target for aging-associated renal disorders.
Keyphrases
- high glucose
- oxidative stress
- vascular smooth muscle cells
- angiotensin ii
- endothelial cells
- diabetic rats
- chronic kidney disease
- reactive oxygen species
- transcription factor
- high fat diet induced
- dna damage
- type diabetes
- drug induced
- stem cells
- insulin resistance
- adipose tissue
- signaling pathway
- ischemia reperfusion injury
- cell therapy
- stress induced
- peritoneal dialysis