posted on 2022-03-24, 18:51authored byHonghao Guan, Chen-Ho Tung, Lei Liu
Mimicking naturally occurring metalloenzymes
to enrich the diversity
of catalytic asymmetric oxidation reactions is a long-standing goal
for modern chemistry. Toward this end, a range of methane monooxygenase
(MMO) mimic chiral carboxylate-bridged (μ-hydroxo) diiron(III)
dimer complexes using salan as basal ligand and sodium aryl carboxylate
as additive have been designed and synthesized. The chiral diiron
complexes exhibit efficient catalytic reactivity in dehydrogenative
kinetic resolution of indolines using environmentally benign hydrogen
peroxide as oxidant. In particular, complex C9 bearing
sterically encumbered salan ligands and a 2-naphthoate bridge is identified
as the optimal catalyst in terms of chiral recognition. Further investigation
reveals that this MMO mimic chiral catalyst can be readily generated
by self-assembly under the dehydrogenation conditions. The self-assembling
catalytic system is applicable to a series of indolines with multiple
stereocenters and diverse substituent patterns in high efficiency
with a high level of chiral recognition (selectivity factor up to
153). Late-stage dehydrogenative kinetic resolution of bioactive molecules
is further examined.