Abstract Background Gout is a prevalent, chronic inflammatory joint diseases, and its global prevalence and incidence are continue to rise. Currently, the adverse side effects of anti-gout drugs underscore the urgent need for safer and more effective anti-gout agents. Objective Cichoriin is a kind of coumarin, which exhibits diversity of biological activities. The current investigation aimed to explore the mechanism of the inhibition of MSU-induced gouty inflammation by cichoriin. Methods The enzyme inhibitory assay of P2Y 14 R, cell viability detection, ELISA, immunofluorescence staining, and flow cytometry were used to explore the molecular mechanism of cichoriin in the inhibition of MSU-induced gouty inflammation. The molecular level details of inhibitory effects of chchoriin against P2Y 14 R were obtained by molecular dynamics simulation. Results The in vitro experiments revealed that cichoriin could inhibit the activity of P2Y 14 R, up-regulate the expressions of NLRP3, Caspase−1, GSDMD and ASC, increase IL−1β and IL−18 levels, and decrease the percentage of Caspase−1/PI double-positive cells. The computational calculations revealed that cichoriin and P2Y 14 R could form a stable and rigid complex. Free energy landscape exhibited that cichoriin stabilized the global conformations of P2Y 14 R to the minimum global energy. MM-PBSA provided evidence for cichoriin’s stability inside the binding pocket of P2Y 14 R with a binding free energy of -35.13 kcal/mol. The decomposition of binding energy showed the pivotal amino acids residues responsible for the stability of cichoriin’s interaction with P2Y 14 R by forming hydrogen bonds and hydrophobic interactions. Conclusions This work highlighted the potential roles of cichoriin in attenuating MSU-induced gouty inflammation.
Wu et al. (Wed,) studied this question.