AI Article Synopsis
- FXR is crucial for balancing bile acids, cholesterol, and glucose metabolism, and is expressed in pancreatic beta-cells.
- FXR activation boosts glucose-induced insulin secretion through both genomic (via KLF11 transcription factor) and non-genomic pathways (enhancing Akt signaling and GLUT2 transporter activity).
- Studies in Non Obese Diabetic (NOD) mice show that FXR activation helps delay diabetes symptoms by improving insulin secretion and glucose uptake in the liver.
Article Abstract
Farnesoid X Receptor plays an important role in maintaining bile acid, cholesterol homeostasis and glucose metabolism. Here we investigated whether FXR is expressed by pancreatic beta-cells and regulates insulin signaling in pancreatic beta-cell line and human islets. We found that FXR activation induces positive regulatory effects on glucose-induced insulin transcription and secretion by genomic and non-genomic activities. Genomic effects of FXR activation relay on the induction of the glucose regulated transcription factor KLF11. Indeed, results from silencing experiments of KLF11 demonstrate that this transcription factor is essential for FXR activity on glucose-induced insulin gene transcription. In addition FXR regulates insulin secretion by non-genomic effects. Thus, activation of FXR in betaTC6 cells increases Akt phosphorylation and translocation of the glucose transporter GLUT2 at plasma membrane, increasing the glucose uptake by these cells. In vivo experiments on Non Obese Diabetic (NOD) mice demonstrated that FXR activation delays development of signs of diabetes, hyperglycemia and glycosuria, by enhancing insulin secretion and by stimulating glucose uptake by the liver. These data established that an FXR-KLF11 regulated pathway has an essential role in the regulation of insulin transcription and secretion induced by glucose.
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| http://dx.doi.org/10.1016/j.bbadis.2010.01.002 | DOI Listing |
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