Molecular Modeling Studies to Mimic the Binding Hypothesis of NEU3 Sialidase and EGFR in Nonsmall Cell Lung Carcinoma.

The activation of the Neuraminidase 3 (NEU3) enzyme has been associated with the hyperphosphoryla-tion of Epidermal Growth Factor Receptor (EGFR) in Nonsmall Cell Lung Carcinoma (NSCLC). Existing EGFR inhibitors (such as gefitinib, erlotinib, lapatinib, icotinib, afatinib and osimertinib) reduce the hyperactivation of downstream signaling pathways (Akt, Mapk, Jak-Stat, Plc) but fail to completely abolish EGFR hyperphosphorylation. Therefore, co-targeting NEU3 and EGFR presents a greater potential to be used as a combinatorial therapy for NSCLC. This study employs structure guided approaches to elucidate the binding hypothesis of NEU3 and EGFR inhibitors. Toward this, important 3D features associated with high inhibitory potency of NEU3, and EGFR modulators were identified through SAR. The triazole substitution in acetamide dihydropyran carboxylic acid derivatives is mainly responsible for improved inhibitory potency against NEU3. Therefore, the hydrophobic (ϕ -H) interaction with the benzene ring and hydrogen bonding with the hydroxyl group of triazole are critical for designing new NEU3 modulators. Molecular Dynamics (MD) simulation studies demonstrate the stability of hydrogen bonding interactions of highly active NEU3 inhibitors with Pro66, Gly199 and Glu410 residues. Similarly, pyrimidine ring of EGFR inhibitors forms stable hydrogen bonds with Lys721 and Asp831 residues, contributing to their inhibitory potency. Our findings suggest that incorporating these identified 3D features associated with triazole and pyrimidine substitutions into a suitable scaffold could be a valuable strategy for developing a new generation of NEU3 and EGFR modulators. This approach offers a potential multi-targeted therapy for NSCLC patients. This study explores co-targeting NEU3 and EGFR for treating NSCLC by identifying key 3D features that enhance inhibitor potency. The research highlights that triazole substitutions improve NEU3 inhibition, while pyrimidine rings contribute to EGFR inhibition through stable hydrogen bonding and hydrophobic interactions. By integrating the identified interactions associated with the potent triazole and pyrimidine substitutions into a new scaffold may provide a promising approach for developing multi-targeted therapies for NSCLC. [ABSTRACT FROM AUTHOR]