Protease-activated receptor-2 (PAR2) has been implicated in multiple pathophysiologies but drug discovery is challenging due to low small molecule tractability and a complex activation mechanism. Here we report the pharmacological profiling of a potent new agonist, suggested by molecular modelling to bind in the putative orthosteric site, and two novel PAR2 antagonists with distinctly different mechanisms of inhibition. We identify coupling between different PAR2 binding sites. One antagonist is a competitive inhibitor that binds to the orthosteric site, while a second antagonist is a negative allosteric modulator that binds at a remote site. The allosteric modulator shows probe dependence, more effectively inhibiting peptide than protease activation of PAR2 signalling. Importantly, both antagonists are active in vivo, inhibiting PAR2 agonist-induced acute paw inflammation in rats and preventing activation of mast cells and neutrophils. These results highlight two distinct mechanisms of inhibition that potentially could be targeted for future development of drugs that modulate PAR2.
Structure–activity relationships
for a series of small-molecule
thiophenes resulted in potent and selective antagonism of human Complement
C3a receptor. The compounds are about 100-fold more potent than the
most reported antagonist SB290157. A new compound JR14a was among
the most potent of the new antagonists in vitro, assessed by (a) inhibition
of intracellular calcium release (IC50 10 nM) induced in
human monocyte-derived macrophages by 100 nM C3a, (b) inhibition of
β-hexosaminidase secretion (IC50 8 nM) from human
LAD2 mast cells degranulated by 100 nM C3a, and (c) selectivity for
human C3aR over C5aR. JR14a was metabolically stable in rat plasma
and in rat liver microsomes and efficacious in rats when given orally
to suppress rat paw inflammation, macrophage and mast cell activation,
and histopathology induced by intraplantar paw administration of a
C3aR agonist. Potent C3aR antagonists are now available for interrogating
C3a receptor activation and suppressing C3aR-mediated inflammation
in mammalian physiology and disease.
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