MEK mutations are more common in various human malignancies, such as pancreatic cancer (70-90%), mock melanoma (50%), liver cancer (20-40%), colorectal cancer (25-35%), melanoma (15-20%), non-small cell lung cancer (10-20%) and basal breast cancer (1-5%). Considering the significance of MEK mutations in diverse cancer types, the rational design of the proposed compounds relies on the structural resemblance to FDA-approved MEK inhibitors like selumetinib and binimetinib. The compound under design features distinct substitutions at the benzimidazole moiety, specifically at positions 2 and 3, akin to the FDA-approved drugs, albeit differing in positions 5 and 6. Subsequent structural refinement was guided by key elements including the DFG motif, hydrophobic pocket and catalytic loop of the MEK protein. A set of 15 diverse diaryl benzimidazole derivatives (S1-S15) were synthesized via a one-pot approach and characterized through spectroscopic techniques, including MASS, IR, 1H NMR and 13C NMR. In vitro anticancer activities of all the synthesized compounds were evaluated against four cancer cell lines, A375, HT -29, A431 and HFF, along with the standard drug trametinib. Molecular docking was performed for all synthesized compounds (S1-15), followed by 950 ns molecular dynamics simulation studies for the promising compounds S1, S5 and S15. The stability of these complexes was assessed by calculating the root-mean-square deviation, solvent accessible surface area and gyration radius relative to their parent structures. Additionally, free energy of binding calculations were performed. Based on the biological and computational results, S15 was the most potent compound and S1 and S5 are comparable to the standard drug trametinib.Communicated by Ramaswamy H. Sarma.
Keywords: DFG; MEK; anticancer; catalytic loop; hydrophobic; molecular dynamics.