Fan Zhang1, Wenzhen Yuan2, Yuhui Wei1, Dongmei Zhang1, Yingting Duan3, Boxia Li1, Xiaohui Wang3, Lili Xi1, Yan Zhou1, Xinan Wu4. 1. Department of Pharmacy, The First Hospital of Lanzhou University, Lanzhou, China. 2. Clinical nutrition section, The First Hospital of Lanzhou University, Lanzhou, China. 3. Department of Pharmacy, The First Hospital of Lanzhou University, Lanzhou, China; School of pharmacy, Lanzhou University, Lanzhou, China. 4. Department of Pharmacy, The First Hospital of Lanzhou University, Lanzhou, China. Electronic address: wuxa@lzu.edu.cn.
Abstract
PURPOSE: Bile acids (BAs) as a kind of endogenous and signaling molecules altered under the circumstance of T2DM, which could impact on the relevant pathways to further affect the glucose metabolism and insulin secretion and might be associated with the T2DM development and restoration. However, the potential mechanisms still need more various and multifaceted studies. Here, we explored the alterations of BAs features and their mechanisms, and discussed the potential effects of the altered BAs on the glucose metabolic disorder via the relevant signaling pathways. MAIN METHODS: The high-fat diet (HFD) feeding combining with injection of low-dose streptozotocin (STZ) was employed for inducing the T2DM rat model. Based on that, we investigated the alterations of the concentrations and compositions of BAs and their mechanisms, and explored the effects of the altered BAs on the glucose metabolic disorder via farnesoid X receptor (Fxr) and G protein-coupled bile acid receptor (Tgr5)-mediated pathways. KEY FINDINGS: In rats with T2DM, the BAs in rats with T2DM exhibited characteristic alterations, especially the increased ratio of 12α-OH to non-12α-OH BAs in serum, which could be ascribed to the up-regulated Cyp8b1 mRNA expression ratio in the liver. Moreover, Additionally, the altered BAs had negative effects on glucose metabolic disorder via inhibiting the Trg5/Fxr-mediated pathways in colon, liver and pancreas in rats with T2DM. SIGNIFICANCE: BAs in rats with T2DM exhibited the characteristic alterations, which could provide a cue for searching biomarkers of the T2DM diagnosis, and the altered BAs might aggravate the glucose metabolic disorder.
PURPOSE:Bile acids (BAs) as a kind of endogenous and signaling molecules altered under the circumstance of T2DM, which could impact on the relevant pathways to further affect the glucose metabolism and insulin secretion and might be associated with the T2DM development and restoration. However, the potential mechanisms still need more various and multifaceted studies. Here, we explored the alterations of BAs features and their mechanisms, and discussed the potential effects of the altered BAs on the glucose metabolic disorder via the relevant signaling pathways. MAIN METHODS: The high-fat diet (HFD) feeding combining with injection of low-dose streptozotocin (STZ) was employed for inducing the T2DM rat model. Based on that, we investigated the alterations of the concentrations and compositions of BAs and their mechanisms, and explored the effects of the altered BAs on the glucose metabolic disorder via farnesoid X receptor (Fxr) and G protein-coupled bile acid receptor (Tgr5)-mediated pathways. KEY FINDINGS: In rats with T2DM, the BAs in rats with T2DM exhibited characteristic alterations, especially the increased ratio of 12α-OH to non-12α-OH BAs in serum, which could be ascribed to the up-regulated Cyp8b1 mRNA expression ratio in the liver. Moreover, Additionally, the altered BAs had negative effects on glucose metabolic disorder via inhibiting the Trg5/Fxr-mediated pathways in colon, liver and pancreas in rats with T2DM. SIGNIFICANCE: BAs in rats with T2DM exhibited the characteristic alterations, which could provide a cue for searching biomarkers of the T2DM diagnosis, and the altered BAs might aggravate the glucose metabolic disorder.
Keywords:
Bile acids; Farnesoid X receptor; G protein-coupled bile acid receptor; Glucose homeostasis; High-fat diet; Streptozotocin; Type 2 diabetes mellitus
Authors: Zhihao Shu; Shuhua Chen; Hong Xiang; Ruoru Wu; Xuewen Wang; Jie Ouyang; Jing Zhang; Huiqin Liu; Alex F Chen; Hongwei Lu Journal: Front Pharmacol Date: 2022-07-05 Impact factor: 5.988