En Route to the Transformation of Glycoscience: A Chemist's Perspective on Internal and External Crossroads in Glycochemistry

Overview

Journal J Am Chem Soc

Publisher American Chemical Society

Specialty Chemistry

Date 2020 Dec 22

PMID 33350830

Citations 37

Authors

David Crich

Affiliations

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Abstract

Carbohydrate chemistry is an essential component of the glycosciences and is fundamental to their progress. This Perspective takes the position that carbohydrate chemistry, or glycochemistry, has reached three crossroads on the path to the transformation of the glycosciences, and illustrates them with examples from the author's and other laboratories. The first of these potential inflexion points concerns the mechanism of the glycosylation reaction and the role of protecting groups. It is argued that the experimental evidence supports bimolecular S2-like mechanisms for typical glycosylation reactions over unimolecular ones involving stereoselective attack on naked glycosyl oxocarbenium ions. Similarly, it is argued that the experimental evidence does not support long-range stereodirecting participation of remote esters through bridged bicyclic dioxacarbenium ions in organic solution in the presence of typical counterions. Rational design and improvement of glycosylation reactions must take into account the roles of the counterion and of concentration. A second crossroads is that between mainstream organic chemistry and glycan synthesis. The case is made that the only real difference between glycan and organic synthesis is the formation of C-O rather than C-C bonds, with diastereocontrol, strategy, tactics, and elegance being of critical importance in both areas: mainstream organic chemists should feel comfortable taking this fork in the road, just as carbohydrate chemists should traveling in the opposite direction. A third crossroads is that between carbohydrate chemistry and medicinal chemistry, where there are equally many opportunities for traffic in either direction. The glycosciences have advanced enormously in the past decade or so, but creativity, input, and ingenuity of scientists from all fields is needed to address the many sophisticated challenges that remain, not the least of which is the development of a broader and more general array of stereospecific glycosylation reactions.

Citing Articles

Why Are 5-Thioglycopyranosyl Donors More Axially Selective than their Glycopyranosyl Counterparts? A Low and Variable Temperature NMR Spectroscopy and Computational Study.

Ahiadorme D, Givhan R, Schaefer 3rd H, Crich D JACS Au. 2025; 5(2):871-889.

PMID: 40017772 PMC: 11863163. DOI: 10.1021/jacsau.4c01113.

The effect of neighbouring group participation and possible long range remote group participation in glycosylation.

Das R, Mukhopadhyay B Beilstein J Org Chem. 2025; 21:369-406.

PMID: 39996165 PMC: 11849559. DOI: 10.3762/bjoc.21.27.

The Stereoselectivity of Neighboring Group-Directed Glycosylation Is Concentration-Dependent.

Basu P, Crich D J Am Chem Soc. 2025; 147(7):5808-5818.

PMID: 39907188 PMC: 11848824. DOI: 10.1021/jacs.4c14402.

Mechanism of C-3 Acyl Neighboring Group Participation in Mannuronic Acid Glycosyl Donors.

de Kleijne F, Moons P, Ter Braak F, Almizori H, Jakobs L, Houthuijs K J Am Chem Soc. 2024; 147(1):932-944.

PMID: 39692559 PMC: 11726434. DOI: 10.1021/jacs.4c13910.

Mechanistic insight into benzylidene-directed glycosylation reactions using cryogenic infrared spectroscopy.

Chang C, Greis K, Prabhu G, Wehner D, Kirschbaum C, Ober K Nat Synth. 2024; 3(11):1377-1384.

PMID: 39524531 PMC: 11549046. DOI: 10.1038/s44160-024-00619-0.

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