PPARγ full agonists, thiazolidinediones (TZDs), have been known as a class of most effective drugs for the treatment of type 2 diabetes mellitus (T2DM). However, recently their therapeutic benefits have been compromised by several undesirable side effects. In this study, a host-based repurposing strategy and in combination with comprehensive biological evaluations were synergistically employed to seek for potent PPARγ ligands, which led to the identification of an anti-thrombotic drug, dicoumarol (Dic), as the novel and safer selectively PPARγ modulator (SPPARγM) with advantages over current TZD drugs. The results in vitro showed that Dic had a potent binding affinity and weakly agonistic activity for PPARγ and its downstream key genes. Moreover, in diabetic model, it significantly reduced blood glucose without leading to the weight gain of both body and main organ tissues. Further mechanistic investigations revealed that Dic possessed such desired pharmacological properties mainly through effectively inhibiting the phosphorylation of PPARγ-Ser273 and selectively regulating the expressions of insulin-sensitive and resistance genes. Finally, the docking studies on the analysis of the potent binding mode of Dic with PPARγ revealed a remarkable difference on interaction region compared with other developed PPARγ agonists, which not only gave a proof of concept for the abovementioned mechanism but also provided the molecular basis for the discrimination of Dic from other PPARγ ligands, especially TZD drugs. Taken together, our findings suggested that Dic could serve as a new and promising candidate with good therapeutic index for treating T2DM, especially for those T2DM patients with thrombosis.
Keywords: Anti-diabetic effects; Dicoumarol; Insulin sensitivity; SB-VHTS; SPPARγM; T2DM.
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