Scaffold transforming and in-silico design of potential androgen receptor antagonists in prostate cancer therapy.

Androgens like testosterone and dihydrotestosterone are essential for the growth and development of the prostate gland. Androgenic receptors are overexpressed, which promotes the progression of prostate cancer; therefore, androgenic receptors are a key target in the therapy of prostate cancer. Enzalutamide is used to treat prostate cancer; however, it also causes toxicities such as cardiovascular toxicity, acute myocarditis, hypertension, and seizures. The objective of this research was to create novel and safer analogues of enzalutamide, followed by the prediction of the pharmacokinetic and toxicity characteristics of these enzalutamide analogues. Molecular docking studies of analogues were also done to guess how ligands will work biologically in treating prostate cancer. A total of 195 analogues were generated, and among them, 23 bioisosteres were selected for further pharmacokinetic, toxicological screening and docking studies. The predicted physical-chemical, medicinal, and ADMET characteristics of the designed bioisosteres were optimal to good compared to enzalutamide. Additionally, the drug likeness and drug score of analogues were superior to enzalutamide. According to docking studies of analogues, EZ12, EZ8, and EZ10 formed hydrogen bonds of SER778 with replaceable amide groups in enzalutamide molecules. SER778 residue may be responsible for antagonistic activity towards androgen receptors. Based on the results of the ADMET, drug likeness, drug score, and docking study of designed enzalutamide analogues, the ligands EZ12, EZ8, and EZ10 could be used to find more possible antiandrogen drugs that could be used to treat prostate cancer.