Molecular modeling, synthesis and biological evaluation of potential antineoplastics with hnRNP K and tumoral cell lines

hnRNP K protein is known for its role in the multiple processes that compose gene expression, including functions during splicing, transcription and translation, developed, mainly, by the binding of nucleotides to KH domains. Inadequate activation of hnRNP K induces the development of some types of cancer, including head and neck, breast and colorectal. In this way, hnRNP K is an attractive molecular target for antineoplastic drug design. Using in silico strategies, we have identified two organic compounds, a benzimidazole and a phenylbenzamide derivatives, able to prevent the natural binding of nucleotides to hnRNP K in vitro. Applying docking, molecular interaction fields and molecular dynamics simulations it was possible to propose that such compounds present structural characteristics capable to support intermolecular interactions inside KH3 domain binding cleft, mainly with R40 and R59 residues, which are extremely important during molecular recognition of nucleotides by hnRNP K. The benzimidazole and phenylbenzamide derivatives identified are novel lead compounds that can guide the design of new antineoplastic drugs targeting hnRNP K. Considering metabolic and toxicity predictions, the phenylbenzamide seems to be more promising than the benzimidazole derivative as a drug, once the benzimidazole presents genotoxic potential. Although both derivatives prevent the binding of nucleotides to hnRNP K, biological assays with tongue cancer cell lines revealed only a mild antitumoral activity for such compounds. Higher level of cell viability reduction, 18% at 8.4 M, was observed for the phenylbenzamide derivative. Following the similarity principle, virtual screening simulations were made intending to find novel benzimidazole and phenylbenzamide derivatives inside EXPRESS-Pick database. The search revealed 21 compounds, 5 of which were tested in vitro with hnRNP K, where 3 of them were active. Intending to optimize benzimidazole and phenylbenzamide derivatives in order to design more potent chemical entities, we have suggested in silico substituents as potential bioisosteric groups of the dioxopyrrolidine rings of hnRNP K ligands, guiding the future synthesis of novel compounds with enhanced antitumoral activity. Moreover, complementary work proposition was performed through the synthesis of benzoxazepin-purines, which also present antitumoral activity but not through hnRNP K pathway. The major limitation of such derivatives is the presence of a nitro aromatic group, which can be very toxic. 20 potential bioisosteric groups were proposed as fragment candidates to replace the nitro one in order to design novel antitumoral derivatives with reduced toxic potential. (AU)