Anticancer and Drug-Likeness Evaluation of Allylphenol-Based 15-LOX Inhibitors in Prostate Cancer: An In Vitro and Computational Study.

[BACKGROUND] Prostate cancer remains the second most common cancer among men around the world, with 1.4 million new cases annually. Treatment resistance and off-target toxicity require innovative therapeutic approaches. Natural compounds such as eugenol exhibit anticancer potential, but poor pharmacokinetic properties constrain clinical application.

[OBJECTIVE] This study evaluated the cytotoxic, apoptotic, and pharmacokinetic properties of three eugenolderived allyl phenol compounds (38, 42, 47), previously recognized as potent 15-lipoxygenase-1 (15-LOX-1) inhibitors, in prostate cancer models.

[METHODS] The cytotoxic activity was evaluated in PC-3 prostate cancer cells and Human Dermal Fibroblasts (HDF) using AlamarBlue assays, flow cytometry, and morphological analysis. Computational validation involved Density Functional Theory (DFT) calculations, molecular docking into 15-lipoxygenase-1 (15-LOX-1; PDB: 2P0M), and structural analysis. Pharmacokinetic and toxicity profiles were predicted in silico using SwissADME, pkCSM, and ProTox-III platforms.

[RESULTS] All three compounds were cytotoxic to PC-3 cells in a concentration-dependent way with some selectivity for normal cells. Apoptosis was confirmed by increased sub-G1 peak and morphological changes, while BAX or BCL-2 mRNA levels did not change. In silico studies (DFT and docking) showed that the compounds bound well to 15-LOX-1 (docking scores: -6.6 to -7.3 kcal/mol), with compound 42 having the strongest binding affinity. Structural analysis showed that the proteins were moderately flexible (B-factor: 47.45 ± 13.07 Ų), which supports stable ligand accommodation. Computational ADME/toxicity predictions suggested generally favorable pharmacokinetic profiles; however, compound 42 was poorly soluble, and compound 47 was identified as a P-gp substrate, indicating a potential efflux liability.

[DISCUSSION] The pro-apoptotic effects observed despite unaltered BAX and BCL-2 mRNA levels indicate that the apoptotic response is likely mediated through mechanisms other than transcriptional regulation of these genes, potentially by blocking 15-LOX-1. Computational modeling indicated that all three compounds can effectively bind to the 15-LOX-1 active site, and their binding affinities are in line with their experimental inhibitory potencies (IC: 0.80-0.88 μM). The integration of in vitro and in silico results confirms the therapeutic potential of these compounds and underscores the necessity for additional mechanistic studies and in vivo evaluation.

[CONCLUSION] These results highlight the anticancer properties of eugenol-derived allylphenol compounds. The compounds induce apoptosis by mechanisms independent of BAX/BCL-2 transcriptional modulation. Computational modeling suggests potential involvement of 15-LOX-1; nevertheless, direct mechanistic validation via caspase activity, ROS generation, or protein-level quantification of BAX/BCL-2 is necessary to verify the apoptotic pathway. The compounds suggest favorable pharmacokinetic profiles along with strong enzyme binding characteristics. Compound 38 exhibited the most balanced profile, characterized by high cytotoxicity, selectivity, and predicted ADME properties. Additional mechanistic investigations and in vivo validation are necessary to advance these candidates through preclinical development.