In-vitro and in-silico exploration of glycogen phosphorylase inhibition by Aloe sinkatana anthraquinones.

Glycogen phosphorylase (GP), a glycosyltransferase protein, was the initial allosteric enzyme identified and has since undergone thorough characterization. GP regulates the intracellular metabolization of glycogen thereby regulating blood glucose levels. Any dysfunction in this process results in altered blood glucose levels, such as Diabetes Mellitus (DM). Anthraquinones isolated from Aloe sinkatana have been found to possess several medicinal benefits. In this study, in-vitro techniques and computational tools were utilized to study in-depth the potential of inhibiting effects of A. sinkatana anthraquinones on GP. Two anthraquinones were isolated for this purpose. Their structures were elucidated and the possible effect on phosphorylase activity was assessed via an enzyme inhibition assay, where both the compounds showed substantial inhibitory activity against GP. The minimal difference between HOMO and LUMO energy levels further supported their potential binding, in line with DFT results. The binding modes and interactions were further explored in detail using in-silico studies via molecular docking and MD simulation. Results revealed strong protein-ligand interactions with Asn284 and Glu382, indicating stability. The deviations (RMSD) and fluctuations (RMSF) remained consistent, with RMSD averaging 2.2Å and RMSF around 1.5 Å. Compounds A and B are effectively bound to the receptor's active site, with -58.63 and -59.65 kcal/mol binding free energies recorded, suggesting potent GP inhibition potential. QSAR analysis revealed positive Log P values, indicating their lipophilic nature, and adhered to Lipinski's rule of 5. In conclusion these anthraquinones showed strong potential in controlling chronically elevated blood sugar levels which could help in the management of DM.