Hong Sungwoo, Yang Jinhai, Weinreb Steven M
Department of Chemistry, The Pennsylvania State University, University Park, Pennsylvania 16802, USA.
J Org Chem. 2006 Mar 3;71(5):2078-89. doi: 10.1021/jo052504r.
In work directed toward a total synthesis of the marine alkaloid sarain A (1), the advanced intermediate 54, containing all the key elements and the seven stereogenic centers of sarain A, has been successfully synthesized from bicyclic lactam 4, previously prepared via an intramolecular stereospecific [3 + 2]-azomethine ylide dipolar cycloaddition. Intermediate lactam 4 could be efficiently converted to N-Boc derivative 12. Introduction of a two-carbon fragment into lactam 12 which eventually becomes the C-7',8' syn diol of the "eastern" ring was then achieved by C-acylation of the corresponding enolate with methoxyacetyl chloride followed by a highly stereoselective ketone reduction with Zn(BH4)2 to afford alcohol 16. Intermediate 16 has the incorrect C-7' relative stereochemistry for sarain A, but this problem was conveniently remedied by inverting the C-7' center via an intramolecular Ohfune-type cyclization of the silyl carbamate derived from Boc mesylate 27 to produce the key cyclic carbamate 28. It was then possible to convert acetal 28 to allylsilane 32 followed by cyclization to the alkaloid tricyclic core 33 via an allylsilane/N-sulfonyliminium ion cyclization. Formation of the "western" macrocyclic ring has been successfully addressed using functional group handles at C-3' and N-1' on the tricyclic core via a ring-closing olefin metathesis (RCM) strategy with the second-generation Grubbs ruthenium catalyst to produce intermediate macrolactam 47. A chelation-controlled addition of ethynylmagnesium bromide to advanced aldehyde 51 afforded a single diastereomeric adduct 53 which is tentatively assigned to have the correct C-7',8' syn-diol stereochemistry. This adduct could be rearranged to the conveniently protected amino carbonate 54 which is set up for construction of the remainder of the eastern ring of sarain A.
在旨在全合成海洋生物碱沙林 A(1)的工作中,已从双环内酰胺 4 成功合成了高级中间体 54,其包含沙林 A 的所有关键元素和七个立体中心,双环内酰胺 4 先前是通过分子内立体专一性的[3 + 2]-甲亚胺叶立德偶极环加成反应制备的。中间体内酰胺 4 可有效地转化为 N - Boc 衍生物 12。然后通过用甲氧基乙酰氯对相应的烯醇盐进行 C - 酰化,接着用 Zn(BH₄)₂进行高度立体选择性的酮还原,将一个二碳片段引入内酰胺 12 中,该片段最终成为“东部”环的 C - 7',8' 顺式二醇,得到醇 16。中间体 16 具有与沙林 A 不正确的 C - 7' 相对立体化学,但通过将源自 Boc 甲磺酸酯 27 的甲硅烷基氨基甲酸酯进行分子内 Ohfune 型环化来翻转 C - 7' 中心,从而方便地解决了这个问题,以产生关键的环状氨基甲酸酯 28。然后可以将缩醛 28 转化为烯丙基硅烷 32,接着通过烯丙基硅烷/N - 磺酰基亚胺离子环化反应环化生成生物碱三环核心 33。通过使用第二代格拉布催化剂,利用三环核心上 C - 3' 和 N - 1' 处的官能团手柄,通过闭环烯烃复分解(RCM)策略成功解决了“西部”大环的形成问题,以产生中间体大环内酰胺 47。用乙炔基溴化镁对高级醛 51 进行螯合控制的加成反应,得到单一的非对映体加合物 53,初步确定其具有正确的 C - 7',8' 顺式二醇立体化学。该加合物可以重排为方便保护的氨基碳酸酯 54,为构建沙林 A 东部环的其余部分做好了准备。