posted on 2024-07-21, 20:05authored byGuoqiang Cheng, Bo Yang, Yang Han, Wei Lin, Siyuan Tao, Yong Nian, Yingzi Li, Maciej A. Walczak, Feng Zhu
Nonclassical C-glycosides, distinguished
by their
unique glycosidic bond connection mode, represent a promising avenue
for the development of carbohydrate-based drugs. However, the accessibility
of nonclassical C-glycosides hinders broader investigations
into their structural features and modes of action. Herein, we present
the first example of Pd-catalyzed stereospecific glycosylation of
nonclassical anomeric stannanes with aryl or vinyl halides. This method
furnishes desired nonclassical aryl and vinyl C-glycosides
in good to excellent yields, while allowing for exclusive control
of nonclassical anomeric configuration. Of significant note is the
demonstration of the generality and practicality of this nonclassical C-glycosylation approach across more than 50 examples, encompassing
various protected and unprotected saccharides, deoxy sugars, oligopeptides,
and complex molecules. Furthermore, biological evaluation indicates
that nonclassical C-glycosylation modifications of
drug molecules can positively impact their biological activity. Additionally,
extensive computational studies are conducted to elucidate the rationale
behind differences in reaction reactivity, unveiling a transmetalation
transition state containing silver (Ag) within a six-membered ring.
Given its remarkable controllability, predictability, and consistently
high chemical selectivity and stereospecificity regarding nonclassical
anomeric carbon and Z/E configuration, the method
outlined in this study offers a unique solution to the longstanding
challenge of accessing nonclassical C-glycosides
with exclusive stereocontrol.