Yamamoto Yoshihiko, Yamashita Ken, Hotta Tomitaka, Hashimoto Toru, Kikuchi Makoto, Nishiyama Hisao
Department of Applied Chemistry, Graduate School of Science and Engineering, Tokyo Institute of Technology, O-okayama, Meguro-ku, Tokyo 152-8552, Japan.
Chem Asian J. 2007 Nov 5;2(11):1388-99. doi: 10.1002/asia.200700077.
Spirocyclic C-arylglycosides were synthesized from the appropriately protected delta-gluconolactones. Addition of lithium acetylide followed by glycosylation with 3-(trimethylsilyl)propargyl alcohol converted the delta-gluconolactones into silylated diynes. After desilylation, subsequent ruthenium-catalyzed cycloaddition of the resultant diynes with alkynes or chloroacetonitrile gave spirocyclic C-arylglycosides in good yields and selectivity. This strategy was also extended to the synthesis of spirocyclic C-arylribosides from the known gamma-ribonolactone derivative. Moreover, silver-catalyzed iodination of the sugar diynes followed by ruthenium-catalyzed cycloaddition with acetylene delivered spirocyclic C-iodophenylglycosides and -ribosides, which were subjected to palladium-catalyzed C-C bond-forming reactions and copper-catalyzed coupling with nitrogen heterocycles to lead to various derivatives.
螺环C-芳基糖苷由适当保护的δ-葡萄糖内酯合成。加入乙炔锂,随后与3-(三甲基甲硅烷基)丙炔醇进行糖基化反应,可将δ-葡萄糖内酯转化为硅烷化二炔。脱硅后,所得二炔与炔烃或氯乙腈进行钌催化的环加成反应,以良好的产率和选择性得到螺环C-芳基糖苷。该策略还扩展至由已知的γ-核糖内酯衍生物合成螺环C-芳基核糖苷。此外,糖二炔的银催化碘化反应,随后与乙炔进行钌催化的环加成反应,得到螺环C-碘苯基糖苷和-核糖苷,它们经过钯催化的C-C键形成反应以及铜催化的与氮杂环的偶联反应,生成各种衍生物。
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