Catalytic Glycosylation for Minimally Protected Donors and Acceptors.

Oligosaccharides have myriad functions throughout biology. 1,2 To investigate these functions requires multi-step chemical synthesis of these structurally complex molecules. With a dense concentration of stereocentres and hydroxyl groups, oligosaccharide assembly through O-glycosylation requires simultaneous control of site-, stereo-, and chemoselectivities 3,4 . Chemists have traditionally relied on protecting group manipulations for this purpose, 5-8 adding a lot of synthetic work. Here, we report a glycosylation platform that enables selective coupling between unprotected or minimally protected donor and acceptor sugars, producing 1,2-cis-O-glycosides in a catalyst-controlled, site-selective manner. Radical-based activation 9 of allyl glycosyl sulfones forms glycosyl bromides. A designed aminoboronic acid catalysts bring this reactive intermediate close to an acceptor through a network of noncovalent hydrogen bonding and reversible covalent B-O bonding interactions, allowing precise glycosyl transfer. The site of glycosylation can be switched with different aminoboronic acid catalysts by affecting their interaction modes with substrates. The method accommodates a wide range of sugar types, amenable to preparing naturally occurring sugar chains and pentasaccharides containing 11 free hydroxyls. Experimental and computational studies provide insights into the origin of selectivity outcomes.