Total Syntheses of Cylindrocyclophanes Exemplifying the Power of Transition-Metal Catalysis in Natural-Product Synthesis

Dino Berthold; Bernhard Breit

doi:10.1055/s-0040-1707144

Synlett, Table of Contents

Synlett 2021; 32(05): 436-446
DOI: 10.1055/s-0040-1707144

account

The Power of Transition Metals: An Unending Well-Spring of New Reactivity

Total Syntheses of Cylindrocyclophanes Exemplifying the Power of Transition-Metal Catalysis in Natural-Product Synthesis

Dino Berthold

,

Bernhard Breit ∗

Abstract

All articles of this category

Dedicated to Barry Trost on the occasion of his 80^th birthday.

Published as part of the Cluster The Power of Transition Metals: An Unending Well-Spring of New Reactivity

Abstract

Cylindrocyclophanes are a class of naturally occurring 22-membered macrocycles with a unique architecture and interesting physical, chemical, and biological properties. This comprehensive account summarizes progress in various synthetic approaches to these compounds during the last twenty years, thereby emphasizing the key steps for establishing the [7,7]-paracyclophane scaffold, as well as alternative approaches to the construction of its stereocenters. Many of these syntheses highlight the power of transition-metal catalysis for natural-product synthesis. Furthermore, the unraveling of the biosynthesis to these natural products in Cylindrospermum licheniforme is discussed.

1 Introduction

2 Biosynthesis

3 Smith’s Synthesis of (–)-Cylindrocyclophanes A and F

4 Hoye’s Synthesis of (–)-Cylindrocyclophane A

5 Iwabuchi’s Syntheses of (–)-Cylindrocyclophane A and (+)-Cylindrocyclophane A

6 Nicolaou’s Synthesis of (–)-Cylindrocyclophanes A and F

7 Breit’s Synthesis of (–)-Cylindrocyclophane F

8 Conclusion

Key words

cylindrocyclophanes - total synthesis - transition-metal catalysis - dimerization - biosynthesis

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References

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