Inhibitor Report for: ML225

Oxidative stress has been implicated as an underlying inflammatory factor in several disease pathologies, including cancer, atherosclerosis, aging, and various neurodegenerative disorders. Phospholipids in particular are susceptible to oxidative damage, and it is thought that the cytosolic enzyme type II platelet-activating factor acetylhydrolase (PAFAH2) may facilitate turnover of oxidized phospholipids via hydrolysis of their oxidatively truncated acyl chains. In support of this theory, over-expression of PAFAH2 has been shown to reduce oxidative stress-induced cell death. However, no selective inhibitors of PAFAH2 are known for investigation of PAFAH2 biology. We initiated a fluorescence polarization activity-based protein profiling (FluoPol-ABPP) HTS campaign to identify potential inhibitors of PAFAH2 (AIDs 492956 and 493030). The assay also served as a counterscreen for inhibitor discovery for the related enzyme, plasma PAFAH (pPAFAH; AIDs 463082, 463230). Interestingly, the triazole urea SID 7974398a top lead in the lysophospholipase (LYPLA1) inhibitor screen from which we derived a dual inhibitor of LYPLA1/LYPLA2 (ML211) and inhibitor of ABHD11 (ML226) was also a top hit in the PAFAH2 HTS assay. Given that triazole ureas were previously found to have tunable potency and selectivity, low cytotoxicity, and good activity in situ, we endeavored to derive a PAFAH2-selective probe from the triazole urea scaffold. The medchem optimized probe (ML225, SID 103913572) is highly potent against its target enzyme (IC50 = 3 nM), and is active in situ at sub-nanomolar concentrations. ML225 is at least 333-fold selective for all other serine hydrolases (~20) assessed by gel-based competitive activity-based protein profiling, and is selective for other PAFAH enzymes. ML225 inhibits PAFAH2 by carbamoylating the active site serine. The complete properties, characterization, and synthesis of ML225 are detailed in this Probe Report.

Serine hydrolases are a diverse enzyme class representing approximately 1% of all human proteins. The biological functions of most serine hydrolases remain poorly characterized owing to a lack of selective inhibitors to probe their activity in living systems. Here we show that a substantial number of serine hydrolases can be irreversibly inactivated by 1,2,3-triazole ureas, which show negligible cross-reactivity with other protein classes. Rapid lead optimization by click chemistry-enabled synthesis and competitive activity-based profiling identified 1,2,3-triazole ureas that selectively inhibit enzymes from diverse branches of the serine hydrolase class, including peptidases (acyl-peptide hydrolase, or APEH), lipases (platelet-activating factor acetylhydrolase-2, or PAFAH2) and uncharacterized hydrolases (alpha,beta-hydrolase-11, or ABHD11), with exceptional potency in cells (sub-nanomolar) and mice (<1 mg kg(-1)). We show that APEH inhibition leads to accumulation of N-acetylated proteins and promotes proliferation in T cells. These data indicate 1,2,3-triazole ureas are a pharmacologically privileged chemotype for serine hydrolase inhibition, combining broad activity across the serine hydrolase class with tunable selectivity for individual enzymes.