Downey A Michael, Pohl Radek, Roithová Jana, Hocek Michal
Institute of Organic Chemistry and Biochemistry, Czech Academy of Sciences, Flemingovo nám. 2, 16610, Prague 6, Czech Republic.
Department of Organic Chemistry, Faculty of Science, Charles University in Prague, Hlavova 8, 12843, Prague 2, Czech Republic.
Chemistry. 2017 Mar 17;23(16):3910-3917. doi: 10.1002/chem.201604955. Epub 2017 Feb 15.
Simplifying access to synthetic nucleosides is of interest due to their widespread use as biochemical or anticancer and antiviral agents. Herein, a direct stereoselective method to access an expansive range of both natural and synthetic nucleosides up to a gram scale, through direct glycosylation of nucleobases with 5-O-tritylribose and other C5-modified ribose derivatives, is discussed in detail. The reaction proceeds through nucleophilic epoxide ring opening of an in situ formed 1,2-anhydrosugar (termed "anhydrose") under modified Mitsunobu reaction conditions. The scope of the reaction in the synthesis of diverse nucleosides and other 1-substituted riboside derivatives is described. In addition, a mechanistic insight into the formation of this key glycosyl donor intermediate is provided.
由于合成核苷作为生化试剂、抗癌和抗病毒药物被广泛使用,简化其获取方法备受关注。本文详细讨论了一种直接立体选择性方法,该方法通过用5-O-三苯甲基核糖和其他C5修饰的核糖衍生物对核苷碱基进行直接糖基化反应,可在克级规模上获得多种天然和合成核苷。该反应在改良的 Mitsunobu 反应条件下,通过原位形成的1,2-脱水糖(称为“脱水糖”)的亲核环氧开环反应进行。描述了该反应在合成各种核苷和其他1-取代核糖苷衍生物中的应用范围。此外,还对这种关键糖基供体中间体的形成提供了机理见解。
