Structure Report for: 5Y6Y

Li, F.L., Kong, X.D., Chen, Q., Zheng, Y.C., Xu, Q., Chen, F.F., Fan, L.Q., Lin, G.Q., Zhou, J.H., Yu, H.L., Xu, J.H.

Title: Regioselectivity Engineering of Epoxide Hydrolase: Near-Perfect Enantioconvergence through a Single Site Mutation
Li FL, Kong XD, Chen Q, Zheng YC, Xu Q, Chen FF, Fan LQ, Lin GQ, Zhou J and Xu JH <1 more author(s)> Li FL, Kong XD, Chen Q, Zheng YC, Xu Q, Chen FF, Fan LQ, Lin GQ, Zhou J, Yu HL, Xu JH (- 1)
Ref: ACS Catal, 8:8314, 2018 : PubMed
Abstract


ESTHER: Li_2018_ACS.Catal_8_8314
PubMedSearch: Li 2018 ACS.Catal 8 8314
Gene_locus related to this paper: vigra-Vreh3

Abstract

An epoxide hydrolase from Vigna radiata (VrEH2) affords partial enantioconvergence (84% ee) in the enzymatic hydrolysis of racemic p-nitrostyrene oxide (pNSO), mainly due to insufficient regioselectivity for the (S)-enantiomer (rS = alphaS/betaS = 7.3). To improve the (S)-pNSO regioselectivity, a small but smart library of VrEH2 mutants was constructed by substituting each of four key residues lining the substrate binding site with a simplified amino acid alphabet of Val, Asn, Phe, and Trp. Among the mutants, M263N attacked almost exclusively at Calpha in the (S)-epoxide ring with satisfactory regioselectivity (rS = 99.0), without compromising the original high regioselectivity for the (R)-epoxide (rR = 99.0), resulting in near-perfect enantioconvergence (>99% analytical yield, 98% ee). Structural and conformational analysis showed that the introduced Asn263 formed additional hydrogen bonds with the nitro group in substrate, causing a shift in the substrate binding pose. This shift increased the difference in attacking distances between Calpha and Cbeta, leading to an improved regiopreference toward (S)-pNSO and affording near-perfect enantioconvergence.