手性酸催化的 6-去氧赤藓糖内酯 B 和土霉素衍生大环内酯的区域发散性糖基化反应。
Regiodivergent Glycosylations of 6-Deoxy-erythronolide B and Oleandomycin-Derived Macrolactones Enabled by Chiral Acid Catalysis.
机构信息
Department of Chemistry, †Life Sciences Institute, §Department of Medicinal Chemistry, ‡Department of Microbiology & Immunology, University of Michigan , Ann Arbor, Michigan 48109, United States.
出版信息
J Am Chem Soc. 2017 Jun 28;139(25):8570-8578. doi: 10.1021/jacs.7b03198. Epub 2017 Jun 19.
Abstract
This work describes the first example of using chiral catalysts to control site-selectivity for the glycosylations of complex polyols such as 6-deoxyerythronolide B and oleandomycin-derived macrolactones. The regiodivergent introduction of sugars at the C3, C5, and C11 positions of macrolactones was achieved by selecting appropriate chiral acids as catalysts or through introduction of stoichiometric boronic acid-based additives. BINOL-based chiral phosphoric acids (CPAs) were used to catalyze highly selective glycosylations at the C5 positions of macrolactones (up to 99:1 rr), whereas the use of SPINOL-based CPAs resulted in selectivity switch and glycosylation of the C3 alcohol (up to 91:9 rr). Additionally, the C11 position of macrolactones was selectively functionalized through traceless protection of the C3/C5 diol with boronic acids prior to glycosylation. Investigation of the reaction mechanism for the CPA-controlled glycosylations revealed the involvement of covalently linked anomeric phosphates rather than oxocarbenium ion pairs as the reactive intermediates.
摘要
这项工作描述了首例使用手性催化剂控制糖苷化反应位点选择性的例子,用于复杂多元醇如 6-去氧赤藓醇 B 和来源于土霉素的大环内酯的糖苷化反应。通过选择合适的手性酸作为催化剂或通过引入等摩尔硼酸基添加剂,可以实现大环内酯 C3、C5 和 C11 位的区域选择性糖基化。BINOL 衍生的手性磷酸(CPA)被用于催化大环内酯 C5 位的高度选择性糖苷化(高达 99:1 rr),而 SPINOL 衍生的 CPA 则导致选择性开关和 C3 醇的糖苷化(高达 91:9 rr)。此外,通过硼酸对大环内酯的 C3/C5 二醇进行无痕迹保护,可以选择性地对大环内酯的 C11 位进行功能化,然后进行糖苷化。对手性磷酸催化的糖苷化反应机制的研究表明,涉及共价键连接的端基磷酸酯,而不是氧杂碳翁离子对作为反应中间体。
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