Engineering Neuroglobin for Synthesis of Chiral Organoborons via Carbene B–H Insertion

Organoborons have recently received much attention, while a biocatalytic platform for the synthesis of chiral organoborons is limited only to Rma cytochrome c. In this study, we exploited the other heme protein, neuroglobin (Ngb), and engineered a quadruple mutant, A15C/H64G/V68F/F28M Ngb, by redesigning the heme active site using the structural information on A15C Ngb and molecular docking studies. The enzyme was shown to be efficient in catalyzing carbene transfer B–H insertion reactions between pyridine/quinoline boranes and benzyl 2-diazopropanoates and their derivatives (29 examples). The designed cavity in the heme distal site favors the binding of large volume substrates such as those containing a quinoline, naphthyl, or biphenyl group. As further determined by the X-ray crystallography of 6c, the chiral products are in the R-configuration, with up to 98:2 e.r. Furthermore, both the whole cell and cell lysate containing the enzyme are reactive toward the B–H insertion reactions. This study presents a convenient biocatalytic platform that may be generally applicable for the synthesis of functional chiral organoborons.