Abstract
Monoacylglycerol lipase (MAGL) is a key regulator of lipid signaling networks implicated in tumor progression and represents an attractive anticancer target. To combine MAGL inhibition with potentially enhanced uptake by highly glycolytic cancer cells, we designed glycoconjugated analogs of a N-benzoylpiperidine MAGL inhibitor scaffold bearing a glucopyranose unit. An alkyne-functionalized benzoylpiperidine intermediate was prepared and coupled to azido sugars through a CuAAC "click" reaction to afford two triazole-linked glycoconjugates. In a colorimetric assay on human MAGL, the new compounds 17 and 18 inhibited the enzyme with IC(50) values of 43.3 and 68.8 μM, respectively, confirming compatibility with MAGL inhibition albeit with reduced potency versus reference triazole-substituted benzoylpiperidine 13 (IC(50) = 4.1 μM). In PANC-1 pancreatic cancer cells, both glycoconjugates were inactive in high-glucose medium, but displayed antiproliferative activity under low-glucose conditions (GI(50)17 = 129 μM; GI(50)18 = 12 μM), consistent with glucose-dependent uptake/competition. Overall, these first-in-class MAGL-targeting glycoconjugates provide a starting point for optimizing dual MAGL inhibition and metabolically driven cellular selectivity.