Sulfonyl(Thio)Urea Derivative Induction Of Insulin Secretion Is Mediated By Potassium, Calcium, And Sodium Channel Signal Transduction

AimTo investigate the mechanism of action of sulfonyl(thio)urea derivative (SD) on glycemia and on insulin secretion in pancreatic islets.MethodsWistar rats were divided into hyperglycemic control group, rats received 4g/kg body weight glucose plus sitagliptin 10mg/kg (p.o.); hyperglycemic plus SD 10mg/kg (p.o.); hyperglycemic plus SD plus sitagliptin. Blood was collected before glucose overloading (zero time), and at 15, 30, 60, and 180min after glucose, from the afore mentioned groups for glycemia and glucagon-like peptide 1 (GLP-1) measurements and intestinal disaccharidases activity. Pancreatic islets were isolated for the calcium influx and insulin secretion in in vitro studies.ResultsSD reduced glycemia and increased GLP-1 secretion, while inhibited sucrase and lactase activity. This SD (1.0 and 10.0 mu M) stimulated calcium influx in a similar percentile to that of glibenclamide, and in a nonsynergic manner. In addition, the trigger effect of SD on calcium influx was through the K+-ATP-dependent channels, and partially by activating voltage-dependent K (+) channels and voltage-dependent calcium channels. Furthermore, SD-stimulated Na (+) and Ca (2+) entry, induced by the transient receptor potential ankyrin 1 and by modulation of Na (+)/Ca (2+) exchange. The activation of these pathways by SD culminated in in vitro insulin secretion, reinforcing the critical role of K (+)-ATP channels in the secretagogue effect of SD.ConclusionsSD diminish glycemia by inducing GLP-1 secretion and inhibiting disaccharidases. To our knowledge, this is the first report of an insulin secretagogue effect of SD that is mediated by potassium and calcium, as well as sodium, signal transduction.