An Approach to Mimicking the Sesquiterpene Cyclase Phase by Nickel-Promoted Diene/Alkyne Cooligomerization

Holte, Dane; Götz, Daniel C. G.; Baran, Phil S.

doi:10.1021/jo202314a

Cited by 23 publications

(9 citation statements)

References 67 publications

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“…[1] Earlier this year, we reported our initial forays into the redox-economic synthesis of terpenes that resemble 1 by oligomerization of unfunctionalized isoprene (Scheme 1 B, path a). [2] These studies ultimately led us to a new approach that utilizes the more advanced, yet readily available, C 15 building block farnesol (2, Scheme 1 A) as a starting point. In this Communication, a short, efficient, scalable, and enantioselective synthesis of 1 is described.…”

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Scalable, Enantioselective Synthesis of Germacrenes and Related Sesquiterpenes Inspired by Terpene Cyclase Phase Logic

et al. 2012

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Our laboratory has a longstanding interest in harvesting new chemical knowledge by learning from terpene biosynthesis. The straightforward construction of carbocyclic terpene backbones such as epoxy-germacrenol (1, Scheme 1A) in a low oxidation state (cyclase phase) followed by regio-, chemo-, and stereoselective oxidative modifications (oxidase phase) allow Nature to access a wide variety of related family members in a divergent manner. [1] Earlier this year, we reported our initial forays into the redox-economic synthesis of terpenes that resemble 1 by oligomerization of unfunctionalized isoprene (Scheme 1B, path a). [2] These studies ultimately led us to a new approach that utilizes the more advanced, yet readily available, C 15 building block farnesol (2, Scheme 1A) as a starting point. In this communication, a short, efficient, scalable, and enantioselective synthesis of 1 is described. Furthermore, we demonstrate how the key intermediate 1 can be processed not only to germacrane-type natural products by chemo-and stereoselective oxidations, but also to a variety of polycyclic sesquiterpene frameworks (like selinanes, guaianes, or elemenes) by acid-mediated transannular cyclization reactions.For the goal of establishing a scalable, divergent, and broadly applicable entry to a variety of related sesquiterpene families, the germacrenes were identified as strategic key intermediates due to the following reasons: 1) germacrenes constitute a large class of cyclic terpenes, many of which have been shown to exhibit promising bioactivities and, in addition, are of growing importance in the perfumery industry; 2) germacrenes are known to be a biosynthetic linchpin en route to various related terpene congeners; and 3) most importantly, many studies have demonstrated that germacrenes can be transformed into mono-, di-, and tricyclic sesquiterpene subclasses (e.g., the elemenes, cadinanes, eudesmanes, guaianes, and bourbonanes) with the "Achilles heel" of these approaches being the accessibility of germacrene precursors in quantity. [3] Despite the industrial interest in terpene natural products, most of the naturally occurring germacrenes and their congeners are not easily available in bulk quantities due to a variety of challenges associated with their synthesis and/or isolation: germacrenes featuring a * pbaran@scripps.edu. † These authors contributed equally to the paper.Supporting information for this article is available on the WWW under http://www.angewandte.org or from the author. Although the total synthesis of sesquiterpenes has been an area of intense research efforts for decades, [4] there is still no reliable synthetic pathway to rapidly forge the ten-membered germacrene carbocycle. The most effective synthetic approaches published to date (Scheme 1B) suffer from serious drawbacks such as low overall yield, poor step economy, and/or are impractical to perform on scale In addition, these syntheses either yield racemic products or start from chiral-pool starting materials. Whereas Nature's cyclase enzymes c...

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Scalable, Enantioselective Synthesis of Germacrenes and Related Sesquiterpenes Inspired by Terpene Cyclase Phase Logic

et al. 2012

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“…179 Diene-alkyne cycloisomerization has been extensively studied with Ni(cod) 2 , and an attempt to mimic the cyclase phase of terpene biosynthesis has been reported. 180 Although the desired cyclization of two isoprene units with an internal alkyne was unsuccessful due to complex reaction mixtures and unstable products, the cooligomerization of butadiene with internal alkynes produced desired cyclodecatrienes.…”

Section: C-f Bond Activationmentioning

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Bis(1,5-cyclooctadiene)nickel(0)

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Duong

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Encyclopedia of Reagents for Organic Synthesis

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“…Inspired by the early work on Ni-catalyzed diene oligomerizations from Wilke, 4 Heimbach, 5 and others, 6 the Baran group proposed a Ni-catalyzed diene/alkyne cooligomerization that could mimic Nature’s cyclase approach to terpenes (Scheme 1 ). 7 From the nickel–butadiene complex 1 , the oxidative cyclization of dienes gives the nine-membered ring intermediate 2 . This intermediate, 2 , undergoes alkyne insertion to produce the 11-membered ring intermediate 5 .…”

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Mechanism, Reactivity, and Selectivity of Nickel-Catalyzed [4 + 4 + 2] Cycloadditions of Dienes and Alkynes

et al. 2014

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Density functional theory (DFT) calculations with B3LYP and M06 functionals elucidated the reactivities of alkynes and Z/E selectivity of cyclodecatriene products in the Ni-catalyzed [4 + 4 + 2] cycloadditions of dienes and alkynes. The Ni-mediated oxidative cyclization of butadienes determines the Z/E selectivity. Only the oxidative cyclization of one s-cis to one s-trans butadiene is facile and exergonic, leading to the observed 1Z,4Z,8E-cyclodecatriene product. The same step with two s-cis or s-trans butadienes is either kinetically or thermodynamically unfavorable, and the 1Z,4E,8E- and 1Z,4Z,8Z-cyclodecatriene isomers are not observed in experiments. In addition, the competition between the desired cooligomerization and [2 + 2 + 2] cycloadditions of alkynes depends on the coordination of alkynes. With either electron-deficient alkynes or alkynes with free hydroxyl groups, the coordination of alkynes is stronger than that of dienes, and alkyne trimerization prevails. With alkyl-substituted alkynes, the generation of alkyne-coordinated nickel complex is much less favorable, and the [4 + 4 + 2] cycloaddition occurs.

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An Approach to Mimicking the Sesquiterpene Cyclase Phase by Nickel-Promoted Diene/Alkyne Cooligomerization

Cited by 23 publications

References 67 publications

Scalable, Enantioselective Synthesis of Germacrenes and Related Sesquiterpenes Inspired by Terpene Cyclase Phase Logic

Scalable, Enantioselective Synthesis of Germacrenes and Related Sesquiterpenes Inspired by Terpene Cyclase Phase Logic

Bis(1,5-cyclooctadiene)nickel(0)

Mechanism, Reactivity, and Selectivity of Nickel-Catalyzed [4 + 4 + 2] Cycloadditions of Dienes and Alkynes

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