北島 満里子

Abstract Alstrostine A and isoalstrostine A are monoterpenoid indole alkaloid glycosides with unique structures found in the plant families Apocynaceae and Rubiaceae. With molecular weights exceeding 900, nine chiral centers (excluding sugar rings), and complex fused‐ring structures, the structural elucidation of these molecules using spectral analysis is highly challenging. Therefore, their structural identification through total synthesis is important in both natural product chemistry and synthetic organic chemistry. In this study, we successfully accomplished the first asymmetric total syntheses of these alkaloids in 18 or 19 steps. A key synthetic feature was a two‐ or three‐component coupling reaction between secologanin and a pyrrolidinoindoline moiety based on our proposed biosynthetic pathway. This approach enabled the synthesis of all isomers of the pyrrolidinoindoline ring, which constitutes the upper fragment of the alstrostines, and allowed us to revise the stereochemistry of alstrostine A. Additionally, a compound previously isolated as alstrostine A from Palicourea luxurians (Rubiaceae) was successfully reidentified and renamed as epialstrostine A.

The first enantioselective total synthesis of kopsiyunnanine B, which has a unique folded and complex pentacyclic structure containing six contiguous chiral centers, has been achieved along our originally proposed biosynthetic pathway. The key reaction of this synthesis includes a bioinspired cascade that builds three ring structures and three chiral centers in one step and features the stereoselective reduction of a β-acrylate and oxidation to an oxindole.

The enantioselective total syntheses of (-)-silicine and (-)-20-episilicine, which contain a chiral piperidine with three contiguous chiral centers (D-ring) and a strained seven-membered ring (C-ring) attached to an indole, were achieved. The key steps of these syntheses included a chiral secondary amine-catalyzed formal aza-[3 + 3] cycloaddition reaction and Lewis acid-mediated irreversible ring-closing reaction. In addition, the stereochemistry at C20 was controlled at a later stage in the syntheses.