Litcius/Paper detail

Zirconaaziridine-Mediated Ni-Catalyzed Diastereoselective C(sp<sup>2</sup>)-Glycosylation

Yu Gan, Jun‐Feng Zhou, Xuejiao Li, Ji‐Ren Liu, Fangjie Liu, Xin Hong, Baihua Ye

2024Journal of the American Chemical Society20 citationsDOI

Abstract

In the realm of organic synthesis, the catalytic and stereoselective formation of C-glycosidic bonds is a pivotal process, bridging carbohydrates with aglycones. However, the inherent chirality of the saccharide scaffold often has a substantial impact on the stereoinduction imposed by a chiral ligand. In this study, we have established an unprecedented zirconaaziridine-mediated asymmetric nickel catalysis, enabling the diastereoselective coupling of bench-stable glycosyl phosphates with a range of (hetero)aromatic and glycal iodides as feasible coupling electrophiles. Our developed method showcases a broad scope and a high tolerance for various functional groups. More importantly, precise stereocontrol toward both anomeric configurations of forming C(sp 2 )-glycosides can be realized by simply utilizing the popular chiral bioxazoline (biOx) ligands in this reductive Ni catalysis. Regarding the operating mechanism, both experimental and computational studies support the occurrence of a redox transmetalation process, leading to the formation of a transient, bimetallic Ni–Zr species that acts as a potent and efficient single-electron reductant in the catalytic process.

Topics & Concepts

ChemistryTransmetalationCatalysisCombinatorial chemistryGlycosidic bondElectrophileChirality (physics)Reductive eliminationStereoselectivityCatalytic cycleGlycalGlycosylAxial chiralityEnantioselective synthesisGlycosylationLigand (biochemistry)StereochemistryOrganic chemistryEnzymeBiochemistryPhysicsQuarkChiral symmetry breakingNambu–Jona-Lasinio modelReceptorQuantum mechanicsCarbohydrate Chemistry and SynthesisMicrobial Natural Products and BiosynthesisSynthesis and Catalytic Reactions