Biomimetic Approach to Diverse Coral Diterpenes from a Biosynthetic Scaffold

Thousands of coral terpenes originate from simple scaffolds that undergo oxidative tailoring. While corals are excellent sources of drug leads, the challenge of supplying structurally complex drug leads from marine organisms has sometimes slowed their development. Making this even more challenging,...

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Veröffentlicht in:Angewandte Chemie International Edition 2023-09, Vol.62 (39), p.e202311406-n/a
Hauptverfasser: Scesa, Paul D., Schmidt, Eric W.
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Sprache:eng
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Zusammenfassung:Thousands of coral terpenes originate from simple scaffolds that undergo oxidative tailoring. While corals are excellent sources of drug leads, the challenge of supplying structurally complex drug leads from marine organisms has sometimes slowed their development. Making this even more challenging, in comparison to other organisms, such as plants and microbes, for which the terpene literature is substantial, very little is known about how the unique coral terpenes are biosynthesized and elaborated in nature. In this study, we used a semisynthetic strategy to produce at gram scale in yeast the eunicellane scaffold that underlies >200 coral compounds. Synthetic oxidation reactions were explored, generating key scaffolds that reflect three of the four structural classes derived from eunicellane and enabling the first asymmetric syntheses of the natural products solenopodin C and klysimplexin Q. Biomimetic methods and detailed mechanistic studies of synthetic reactions shed light on potential enzymological reactivity, including the role of epoxide rearrangement in eunicellane biosynthesis. Synthetic biology enables the semisynthesis of numerous complex chemotypes starting from the soft coral metabolite klysimplexin R produced at gram scale. This approach has the potential to provide diverse molecules for drug discovery and development using a green approach inspired by nature.
ISSN:1433-7851
1521-3773
1521-3773
DOI:10.1002/anie.202311406