ABSTRACT
We describe the design, using shape comparison and fast docking computer algorithms, and rapid parallel synthesis of a 1300 member array based on GSK7721, a 4-aminobenzonitrile androgen receptor (AR) antagonist identified by focused screening of the GSK compound collection. The array yielded 352 submicromolar and 17 subnanomolar AR agonists as measured by a cell-based reporter gene functional assay. The rapid synthesis of a large number of active compounds provided valuable information in the optimization of AR modulators, which may be useful in treating androgen deficiency in aging males.
Subject(s)
Androgen Receptor Antagonists , Combinatorial Chemistry Techniques/methods , Nitriles/chemical synthesis , Nitriles/pharmacology , Algorithms , Androgens , Animals , Cell Line , Drug Design , Haplorhini , Magnetic Resonance Spectroscopy , Nitriles/chemistry , Spectrometry, Mass, Fast Atom Bombardment , Structure-Activity RelationshipABSTRACT
Traditional approaches to discovery of selective estrogen receptor modulators (SERMs) have relied on ER binding and cell-based estrogen response element-driven assays to identify compounds that are osteoprotective but nonproliferative in breast and uterine tissues. To discover new classes of potential SERMs, we have employed a cell-free microsphere-based binding assay to rapidly characterize ERalpha interactions with conformation-sensing cofactor or phage display peptides. Peptide profiles of constrained triarenes were compared to known proliferative and nonproliferative ER ligands to discover potent quinoline-based ligands with minimal Ishikawa cell stimulation.