J. Schroer et al., DESIGN AND SYNTHESIS OF TRANSITION-STATE ANALOGS FOR INDUCTION OF HYDRIDE TRANSFER CATALYTIC ANTIBODIES, Journal of organic chemistry, 62(10), 1997, pp. 3220-3229
Alcohol dehydrogenases and related aldehyde reductase enzymes catalyze
the oxidation of alcohols to aldehydes and the simultaneous reduction
of a nicotinamide derivative (NAD(+) or NADP(-)) to the corresponding
1,4-dihydronicotinamide. Herein we report the design and synthesis of
a stable transition state analog for this hydride transfer process. C
ompound 1 is a rigid [3.2.2] bicyclic structure containing 3-piperidon
e oxime as a mimic for 1,4-dihydronicotinamide. The piperidone is held
in the boat conformation corresponding to the transition state by a t
hree-atom lactam bridge between N(1) and C(4). The oxime function mimi
cs the carboxamide group in nicotinamide. The lactam nitrogen sers es
as an attachment point for the alkyl group of the alcohol substrate, a
nd the amide oxygen atom mimics its hydroxyl group. Compound 1 was pre
pared in 10 steps from N-benzylpiperidone, functionalized with substra
te and cofactor recognition elements into transition state analogs 2 a
nd 3 and conjugated to carrier proteins for immunization. These novel
analogs open the way for the exploration of the dehydrogenase reaction
using catalytic antibodies.