Department of Chemistry, Yale University, New Haven, Connecticut 06520, United States.
Department of Pharmacology, Yale School of Medicine, New Haven, Connecticut 06520, United States.
J Am Chem Soc. 2021 Feb 24;143(7):2777-2783. doi: 10.1021/jacs.0c11262. Epub 2021 Feb 8.
The introduction of glycosides bearing basic nitrogen is challenging using conventional Lewis acid-promoted pathways owing to competitive coordination of the amine to the Lewis acid promoter. Additionally, because many aminoglycosides lack a C2 substituent, diastereomeric mixtures of -glycosides are often produced. Herein, we present a method for the synthesis of α- or β- 2,3,6-trideoxy-3-amino- and 2,4,6-trideoxy-4-amino -glycosides from a common precursor. Our strategy proceeds by the reductive lithiation of thiophenyl glycoside donors and trapping of the resulting anomeric anions with 2-methyltetrahydropyranyl peroxides. We apply this strategy to the synthesis of α- and β-forosamine, pyrrolosamine, acosamine, and ristosamine derivatives using primary and secondary peroxides as electrophiles. α-Linked products are obtained in 60-96% yield and with >50:1 selectivity. β-Linked products are obtained in 45-94% yield and with 1.7->50:1 stereoselectivity. Contrary to donors bearing an equatorial amine substituent, donors bearing an axial amine substituent favored β-products at low temperatures. This work establishes a general strategy to synthesize -glycosides bearing a basic nitrogen.
由于伯胺与路易斯酸促进剂的竞争性配位,使用传统的路易斯酸促进途径来引入带有碱性氮的糖苷具有挑战性。此外,由于许多氨基糖苷缺乏 C2 取代基,因此经常产生β-糖苷的非对映异构体混合物。在此,我们提出了一种从共同前体制备α-或β-2,3,6-三脱氧-3-氨基和 2,4,6-三脱氧-4-氨基糖苷的方法。我们的策略是通过噻吩糖苷供体的还原锂化和用 2-甲基四氢吡喃过氧化物捕获所得的非对映阴离子来进行。我们将此策略应用于使用伯和仲过氧化物作为亲电试剂合成α-和β-岩藻糖胺、吡咯烷糖胺、阿糖胺和瑞妥糖胺衍生物。α-连接的产物以 60-96%的产率和 >50:1 的选择性获得。β-连接的产物以 45-94%的产率和 1.7->50:1 的立体选择性获得。与带有赤道胺取代基的供体相反,带有轴向胺取代基的供体在低温下有利于β-产物的形成。这项工作建立了一种合成带有碱性氮的β-糖苷的通用策略。
