UDM-002555

The detailed pharmacology and therapeutic potential of the central PAR4 receptors are poorly understood due to a lack of potent, selective, and brain-penetrant tool compounds. Despite this, robust data with biochemical and genetic tools show the therapeutic potential of PAR4 antagonists in traumatic brain injury, Alzheimer's disease, Parkinson's disease, and other neurodegenerative disorders with a neuroinflammatory component. Thus, we performed a functional HTS campaign, identified a fundamentally new PAR4 competitive inhibitor chemotype, optimized this new series (increased potency >45-fold), discovered enantiospecific activity (though opposing preference for human versus mouse PAR4), and engendered high central nervous system penetration (rat K_p's of 0.52 to 4.2 and K_p,uu's of 0.52 to 1.2).

Protease-activated receptor 4 (PAR4) is a promising target for antiplatelet therapy. In this study, homology modeling and molecular docking methods were used to investigate the binding modes of PAR4 agonists and antagonists. The outcomes show that agonists have good docking scores, and they also form more hydrogen bonds with PAR4 than antagonists. To reveal the different conformational changes caused by agonist and antagonist, molecular dynamic simulations were carried out on three selected PAR4 systems. Simulation results show that PAR4 activation involves breaking interactions of 3–7 lock switch (Try157 and Tyr322) and ionic lock switch (Arg188 and Asp173), and formation of transmission switch among Tyr161, Asn300 and Phe296. In addition, principal component analysis (PCA) indicates that the major change for agonist bound system takes place in the intracellular region while that for antagonist bound system is in the extracellular region. The binding free energy of BMS-986120 is much lower than AYPGKF, suggesting high affinity of antagonist. Moreover, the electronegative aspartic residues Asp230 and Asp235 at ECL2 are important for PAR4 binding to agonist. Clarifying the PAR4 structural characteristics may be helpful to understand the activation mechanism, giving insights into the molecular design and discovery of novel potential PAR4 antagonists in the future.