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Synthesis 2023; 55(04): 617-636
DOI: 10.1055/a-1941-8680
DOI: 10.1055/a-1941-8680
paper
Total Synthesis and Anti-inflammatory Activity of Stemoamide-Type Alkaloids Including Totally Substituted Butenolides and Pyrroles
This research was supported by a Grant-in-Aid for Scientific Research (C) from the Ministry of Education, Culture, Sports, Science and Technology (MEXT, 18K05127), the TOBE MAKI Scholarship Foundation, the JGC-S Scholarship Foundation, the Kato Memorial Bioscience Foundation, and the Amano Institute of Technology Foundation. Japan Society for the Promotion of Science (JSPS) fellowships [to M.Y. (15J05926) and Y. Sugiyama (21J21546)], and the Yoshida Scholarship Foundation (Y. Soda) are gratefully acknowledged.
Abstract
Totally substituted butenolide including two tetrasubstituted olefins is a distinct structural motif seen in Stemona alkaloids, but efficient methods for its synthesis are not well developed. As an ongoing program aimed at the collective total synthesis of the stemoamide group, we report a stereodivergent method to give either (E)- or (Z)-totally substituted butenolide from the same intermediate. While AgOTf-mediated elimination via an E1-type mechanism results in the formation of the kinetic (Z)-tetrasubstituted olefin, subsequent TfOH-mediated isomerization gives the thermodynamic (E)-tetrasubstituted olefin. The pyrrole ring is another important structure found in Stemona alkaloids. The direct oxidation of pyrrolidine rings with MnO2 and careful purification gives the pyrrole groups without isomerization of the stereocenter in the lactone group. These two methods enabled us to synthesize a series of stemoamide-type alkaloids including tricyclic, tetracyclic, and pentacyclic frameworks. The anti-inflammatory activities by inhibition of iNOS expression in macrophage cell line RAW264.7 indicate that the most potent anti-inflammatory compounds without cytotoxicity are protostemonines, which consist of pentacyclic frameworks including the totally substituted butenolide.
Key words
amides - anti-inflammatory agents - butenolides - DFT calculations - iNOS - pyrroles - Stemona alkaloids - total synthesisSupporting Information
- Supporting information for this article is available online at https://doi.org/10.1055/a-1941-8680.
- Supporting Information
Publication History
Received: 22 August 2022
Accepted after revision: 13 September 2022
Accepted Manuscript online:
13 September 2022
Article published online:
17 October 2022
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For reviews on Stemona alkaloids, see:
For isolation and structural determination of protostemonine (1) and isoprotostemonine (17), see:
For biological activity of protostemonine (1), see:
For synthesis of the totally substituted butenolides and application to total synthesis of natural products, see:
For oxidation of the pyrrolidines to the pyrroles, see:
For isolation of tuberostemonine (8), see:
For isolation of bisdehydrotuberostemonine (9), see:
For total synthesis of tuberostemonine (8) and bisdehydrotuberostemonine (9), see:
For isolation of croomine (10) and didehydrocroomine (11), see:
For total synthesis of croomine (10), see:
For total synthesis of stemoamide (12), see:
For selected reviews on nucleophilic addition to amides, see:
For recent selected examples of nucleophilic addition to amides, see:
For selected total synthesis of other tetracyclic and pentacyclic stemoamide-type alkaloids, see:
For preparation of model lactone 31, see:
For isolation of stemonine (41), see:
For total synthesis of stemonine (41), see:
Curtis reported the synthesis of siloxane oligomer using (Me2HSi)2O and a catalytic amount of the Vaska complex [IrCl(CO)(PPh3)2]; see:
For selected reviews on iNOS, see: