Chlorogenic acid modulates glucose and lipid metabolisms via AMPK activation in HepG2 cells and shows its anti-hyperglycemic effect on streptozocin-induced diabetic mice.

Hong-Ji Yao; Zhao-Yi Xue; Rui-Qi Wang; Cheng-Zuo Jiang; Jing-Yan Xiong; Zhi-Xuan Xia; Qiang Liu; Qi-Bing Li; Yong Zhang

Objective: In this study, we focus on the hypoglycemic effects of chlorogenic acid (CGA) in vitro and in vivo and its mechanism base on regulate glucose and lipid metabolism via AMPK activation. Methods: The cytotoxicity, glucose consumption and intracellular triglyceride assay were been detected by commercial kits. The western blots were used to detection the associated protein levels after CGA treatment, and the inhibiter blocking experiments were also be done. In vivo experiment, the fasting blood-glucose, lipid metabolism, liver function, insulin resistance, glucose tolerance, and pathological change were assessed on streptozocin induced diabetic mice. Results: We found that CGA exhibited no cytotoxicity at concentrations of 100µM, it caused a significant increasing of glucose consumption and reducing of the PA-BSA induced intracellular TG level on HepG2 cells at 50µM and 100µM treatment, CGA exhibited up-regulating the level of p-AMPK (Thr172) and p-ACC (Ser79) in dose-dependent manners in vitro and in vivo. The stimulating activities of CGA on AMPK were completely blocked by compound c (CC) on HepG2 cells. And the efficacies of CGA on glucose consumption and intracellular TG accumulation were also completely blocked by CC pretreatment. The CGA also exhibited potent anti-diabetic effects with hypoglycemic activity, improve insulin resistance and glucose tolerance, regulate glucose and lipid metabolism and protect the liver function in vivo. Conclusion: Our results suggested that CGA can regulate glucose and lipid metabolism by AMPK activation, and exhibit potent anti-hyperglycemic effect in streptozocin induced diabetes mice, and may be used as a potential effective anti-diabetes drug.

LIPID metabolism; CHLOROGENIC acid; GLUCOSE metabolism; AMP-activated protein kinases; ANIMAL models of diabetes

Journal of Hainan Medical University, 2022, Vol 28, Issue 9, p14

1007-1237

Academic Journal