State Key Laboratory of Pharmaceutical Biotechnology, School of Life Sciences, Nanjing University, Nanjing 210023, PR China.
Jiangsu Key Laboratory of Targeted Antiviral Research, Chia Tai Tianqing Pharmaceutical Group Co., Ltd, Nanjing 210023, PR China.
Biochem Pharmacol. 2019 Aug;166:139-152. doi: 10.1016/j.bcp.2019.05.016. Epub 2019 May 11.
High fructose intake is a risk of glomerular podocyte dysfunction. Podocyte apoptosis has emerged as a major cause of podocyte loss, exacerbating proteinuria. Magnesium isoglycyrrhizinate (MgIG) is usually used as a hepatoprotective agent in clinic. Liver and kidney injury often occurs in human diseases. Recent report shows that MgIG improves kidney function. In this study, we found that MgIG significantly alleviated kidney dysfunction, proteinuria and podocyte injury in fructose-fed rats. It also restored fructose-induced podocyte apoptosis in rat glomeruli and cultured differentiated podocytes. Of note, high-expression of miR-193a, downregulation of Wilms' tumor protein (WT1) and RelA, as well as upregulation of C-Maf inducing protein (C-mip) were observed in these animal and cell models. The data from the transfection of miR-193a mimic, miR-193a inhibitor, WT1 siRNA or LV5-WT1 in cultured differentiated podocytes showed that fructose increased miR-193a to down-regulate WT1, and subsequently activated C-mip to suppress RelA, causing podocyte apoptosis. These disturbances were significantly attenuated by MgIG. Taken together, these results provide the first evidence that MgIG restrains fructose-induced podocyte apoptosis at least partly through inhibiting miR-193a to upregulate WT1, supporting the application of MgIG with a novel mechanism-of-action against podocyte apoptosis associated with fructose-induced kidney dysfunction.
高果糖摄入是肾小球足细胞功能障碍的一个风险。足细胞凋亡已成为导致足细胞丢失、加剧蛋白尿的主要原因。 镁甘氨酸(MgIG)通常在临床上用作肝保护剂。肝和肾损伤在人类疾病中经常发生。最近的报告表明,MgIG 可改善肾功能。在这项研究中,我们发现 MgIG 可显著缓解果糖喂养大鼠的肾功能障碍、蛋白尿和足细胞损伤。它还恢复了果糖诱导的大鼠肾小球和培养分化的足细胞中的足细胞凋亡。值得注意的是,在这些动物和细胞模型中观察到 miR-193a 的高表达、Wilms 肿瘤蛋白(WT1)和 RelA 的下调以及 C-Maf 诱导蛋白(C-mip)的上调。在培养分化的足细胞中转染 miR-193a 模拟物、miR-193a 抑制剂、WT1 siRNA 或 LV5-WT1 的数据表明,果糖增加 miR-193a 以下调 WT1,随后激活 C-mip 以抑制 RelA,导致足细胞凋亡。MgIG 显著减轻了这些干扰。总之,这些结果首次提供了证据,表明 MgIG 通过抑制 miR-193a 来上调 WT1,从而抑制果糖诱导的足细胞凋亡,至少部分缓解了果糖诱导的足细胞凋亡,为 MgIG 的应用提供了一种新的作用机制,以对抗与果糖诱导的肾功能障碍相关的足细胞凋亡。
