posted on 2013-04-24, 00:00authored byKaterina Otrubova, Monica Brown, Michael
S. McCormick, Gye W. Han, Scott
T. O’Neal, Benjamin F. Cravatt, Raymond C. Stevens, Aron H. Lichtman, Dale L. Boger
The
design and characterization of α-ketoheterocycle fatty
acid amide hydrolase (FAAH) inhibitors are disclosed that additionally
and irreversibly target a cysteine (Cys269) found in the enzyme cytosolic
port while maintaining the reversible covalent Ser241 attachment responsible
for their rapid and initially reversible enzyme inhibition. Two α-ketooxazoles
(3 and 4) containing strategically placed
electrophiles at the C5 position of the pyridyl substituent of 2 (OL-135) were prepared and examined as inhibitors of FAAH.
Consistent with the observed time-dependent noncompetitive inhibition,
the cocrystal X-ray structure of 3 bound to a humanized
variant of rat FAAH revealed that 3 was not only covalently
bound to the active site catalytic nucleophile Ser241 as a deprotonated
hemiketal, but also to Cys269 through the pyridyl C5-substituent,
thus providing an inhibitor with dual covalent attachment in the enzyme
active site. In vivo characterization of the prototypical inhibitors
in mice demonstrates that they raise endogenous brain levels of FAAH
substrates to a greater extent and for a much longer duration (>6
h) than the reversible inhibitor 2, indicating that the
inhibitors accumulate and persist in the brain to completely inhibit
FAAH for a prolonged period. Consistent with this behavior and the
targeted irreversible enzyme inhibition, 3 reversed cold
allodynia in the chronic constriction injury model of neuropathic
pain in mice for a sustained period (>6 h) beyond that observed
with
the reversible inhibitor 2, providing effects that were
unchanged over the 1–6 h time course monitored.