2-phenoxynicotinic acid

A series of 2-phenoxynicotinic acid hydrazides were synthesized and evaluated for their analgesic and anti-inflammatory activities. Several compounds having an unsubstituted phenyl/4-pyridyl or C-4 methoxy substituent on the terminal phenyl ring showed moderate to high analgesic or anti-inflammatory activity in comparison to mefenamic acid as the reference drug. The compounds with highest anti-inflammatory activity were subjected to in vitro COX-1/COX-2 inhibition assays and showed moderate to good COX-1 and weak COX-2 inhibition activities.

We describe the construction of a DNA-encoded chemical library comprising 148 135 members, generated through the self-assembly of two sub-libraries, containing 265 and 559 members, respectively. The library was designed to contain building blocks potentially capable of forming covalent interactions with target proteins. Selections performed with JNK1, a kinase containing a conserved cysteine residue close to the ATP binding site, revealed the preferential enrichment of a 2-phenoxynicotinic acid moiety (building block A82) and a 4-(3,4-difluorophenyl)-4-oxobut-2-enoic acid moiety (building block B272). When the two compounds were joined by a short PEG linker, the resulting bidentate binder (A82-L-B272) was able to covalently modify JNK1 in the presence of a large molar excess of glutathione (0.5 mm), used to simulate intracellular reducing conditions. By contrast, derivatives of the individual building blocks were not able to covalently modify JNK1 in the same experimental conditions. The A82-L-B272 ligand was selective over related kinases (BTK and GAK), which also contain targetable cysteine residues in the vicinity of the active site.