Natural Product Synthesis Enabled by Domino Processes Incorporating a 1,2-Rearrangement Step

Bastien Delayre, Qian Wang, Jieping Zhu
2021
Journal paper

Abstract

The art of natural product total synthesis is closely associated with two major determinants: the development/application of novel chemical reactions and the innovation in strategic use of classic organic reactions. While purposely seeking/applying a new synthetic methodology allowing nonconventional bond disconnections could shorten the synthetic route, the development of domino processes composed of a series of well-established reactions could also lead to a concise, practical, and aesthetically appealing synthesis. As an important class of textbook reactions, the 1,2-anionotropic rearrangements discovered at the dawn of modern organic chemistry have important bearings not only on chemical synthesis but also on the conceptual breakthroughs in the field. In its basic form, the 1,2-shift affords nothing but a constitutional isomer of the starting material and is therefore not a complexity-generating transformation. However, such a simple 1,2-shift could in fact change the molecular topology if the precursor is cleverly designed. More dramatically, it can metamorphosize the structure of the substrate when it is combined with other transformations in a domino sequence. In this Outlook, we highlight recent examples of natural product synthesis featuring a key domino process incorporating a 1,2-anionotropic rearrangement. Specifically, domino reactions integrating Wagner−Meerwein, pinacol, α-ketol, α-aminoketone, α-iminol, or benzilic acid rearrangements will be discussed.

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Bastien Delayre, Qian Wang, Jieping Zhu
2021
Journal paper

Abstract

Official source

https://infoscience.epfl.ch/record/285328?ln=en

About this result

Related concepts (14)

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Related publications

Total Synthesis of Dolabriferol and Polypropionate Fragments Applying New Organic Chemistry of Sulfur Dioxide

Sylvain Claude Laclef

Polypropionates are common products of metabolism in bacteria, insects, fungi and marine organisms. They constitute an important class of products with a wide range of interesting biological activities. Our group has shown previously that 1-alkoxy-3-acyloxy-2-methyl-1,3-pentadienes can undergo hetero-Diels-Alder reactions with SO2, to give the corresponding sultines, which at low temperature in the presence of Lewis acids, can be opened to zwitterionic intermediates. The latter can be trapped by nucleophiles like enoxysilanes (oxyallylation) to generate the corresponding substituted silyl alkenylsulfinate. Desilylation of the latter under acidic conditions leads to intermediate allylsulfinic acids, which, after retro-ene desulfitation, provide a dipropionate stereotriad which is a useful fragment for polypropionate synthesis. Indeed this fragment obtained using this new SO2 reaction cascade, hetero-Diels-Alder addition/oxyallylation/retro-ene desulfitation (Vogel's cascade) is containing keto and enol ester fonctionality which allows the design of the asymmetric total synthesis of complicated polyketides fragments. Firstly a study was made in order to improve the way of synthesis of dienes and their use in Vogel's cascade to improve the diastereoselectivity of the oxyallylation step. The use of this methodology, using (E)-enoxysilanes as nucleophile for the oxyallylation step allowed us to obtain anti,anti-dipropionate stereotriad in high diastereoselectivity. This common subunit found in polyketide-derived natural products has generally been recognized to be difficult to synthesize. This fragment and its properties was used successfully in the first asymmetric total synthesis of the marine natural product dolabriferol. The use of Vogel's cascade with (Z)-enoxysilanes as nucleophile for the oxyallylation step is providing anti-syn-dipropionate stereotriad as major compound. Combination of this method and aldol chemistry allowed us the synthesis of polypropionate fragments in a short sequence. Efforts toward the synthesis of 6-deoxyrythronolide B, and analogues was presented. This strategy allowed us also, to synthesize, in a very efficient way, a lot of compound like lactones which are natural precursor of polypropionate with interesting biological activity or sulfonamide which are well known class of drugs.

EPFL2010

Total Synthesis of Alstilobanine C, Undulifoline and Alstilobanine B

Nicolas David Gaeng

The total synthesis of pentacyclic monoterpene indole alkaloids is the focus of this thesis. Total syntheses of (±)-alstilobanine C, (±)-undulifoline and (±)-alstilobanine B, three natural products from the Ulean family of alkaloids, were accomplished. The characteristic features of our synthesis included: a) a domino sequence involving a highly diastereoselective Michael addition followed by chemoselective C-acylation of the resulting enolate by Mander¿s ester; b) an unprecedented Lewis acid mediated intramolecular addition of enolate to oxonium, generated in situ from MOM protective group; c) a sequence of chemoselective reduction/indolization/intramolecular aza-Michael addition. This domino process afforded directly the (±)-alstilobanine C, a pentacyclic monoterpene indole alkaloid in 87% yield. Reductive N-methylation of (±)-alstilobanine C provided (±)-undulifoline which, upon N-oxidation, was further converted to (±)-alstilobanine B. Enantioselective total synthesis of the same natural products through a different synthetic route is presented. After exploring different unsuccessful strategies, an enzymatic desymmetrization of a meso compound was adopted for the synthesis of enantioenriched cyclopentenone intermediate. Applying the two domino sequence developed previously, namely, Michael addition/C-acylation and oxepane formation, an efficient synthesis of the oxobicyclo[4.2.1]nonane was realized. A palladium-catalyzed decarboxylative cross-coupling, a methodology developed in our group, afforded an advanced bicyclic intermediate with all the carbon and functional groups needed to accomplish the total synthesis. However, conversion of the vinyl group to alkylazide or its synthetic equivalent proved to be difficult in spite of the efforts dedicated to this seemingly trivial transformation.

EPFL2018

The development of an unusual oxidative alkene difunctionalization using methyl formate and syn-thetic studies towards alkaloid natural products provide the basis of the thesis. The first chapter details the development of a method that forges methoxycarbonyl radical direct-ly from its most accessible precursor: methyl formate. Although the aforementioned transfor-mation was documented in the literature, no synthetically useful method was developed at the time. We were able to identify conditions that transform methyl formate and simple styrene de-rivatives to value added ï¢-methoxy alkanoates and cinnamic acid derivatives under copper cataly-sis. We also demonstrated that by tethering nucleophilic moieties to the styrene substrates, we could access medicinally important heterocycles such as pyrrolidines, tetrahydrofurans and ï§-lactones. Our method proved to be scalable on each classes of substrates. Mechanistic studies re-vealed that methyl formate has an unprecedented double role in the transformation. It acts as a precursor for methoxycarbonyl radical; furthermore, it is the direct source of the ï¢-methoxy func-tion in the synthesis of ï¢-methoxy alkanoates. A ternary ï¢-diketiminato-Cu(I)-styrene complex, fully characterized by NMR spectroscopy and X-ray crystallographic analysis is capable of catalyz-ing the same transformation. We hypothesize that pre-coordination of electron-rich double bond to copper might play an important role in the polarity-mismatched addition between nucleophilic methoxycarbonyl radical and electron rich olefins. Synthetic studies toward the total synthesis of koumine is discussed in the second chapter. Our synthetic strategy features an oxidative ring closing, Fukuyama indole synthesis and an enantiose-lective Diels-Alder cycloaddition for the construction of the core of koumine skeleton. We designed a rapid route to access 1,2-dihydropyridine derivatives and these compounds were examined as dienes in the Diels-Alder cycloaddition reaction. Despite our efforts, we were unable to effect the [4+2] cycloaddition, which eventually lead us to decide to discontinue our campaign. In chapter three, our synthetic efforts toward voacafricine A and voacafricine B is presented. In our pursuit towards the natural products, we devised and followed a divergent and potentially en-antioselective strategy. We successfully developed a synthetic route to reach the key intermediate in five steps. Despite our efforts, we were not able to construct the remaining F ring of the natural product. Our conformational analysis of advanced intermediates suggest that epimerization of the C14 stereocenter potentially unlocks the desired reactivity and enables us to reach the target mol-ecules. Work towards the total synthesis of voacafricine A and voacafricine B is underway and may focus on the conformational manipulation of advanced intermediates to allow the elaboration of the F ring and complete the synthesis.

EPFL2020

Total Synthesis of Dolabriferol and Polypropionate Fragments Applying New Organic Chemistry of Sulfur Dioxide

Sylvain Claude Laclef

EPFL2010