Enamine catalysis dienamines

Over the past decade, rapid growth has been achieved in organocatalytic asymmetric Diels-Alder and hetero-Diels-Alder reactions. Numerous organocatalysts such as chiral amines, guanidines, N-heterocyclic carbenes, Bronsted acids, and bifunctional catalysts have been successfully developed. The activation modes for these catalysts, such as imine-catalysis, enamine-catalysis, dienamine catalysis. 

Referring to a mechanistic classification of organocatalysts (Seayad and List 2005), currently the two most prominent classes are Brpnsted acid catalysts and Lewis base catalysts. Within the latter class chiral secondary amines (enamine, iminium, dienamine activation for a short review please refer to List 2006) play an important role and can be considered as—by now—already widely extended mimetics of type I aldolases, whereas acylation catalysts, for example, refer to hydrolases or peptidases (Spivey and McDaid 2007). Thiamine-dependent enzymes, a versatile class of C-C bond forming and destructing biocatalysts (Pohl et al. 2002) with their common catalytically active coenzyme thiamine (vitamin Bi), are understood to be the biomimetic roots ofcar-bene catalysis, a further class of nucleophilic, Lewis base catalysis with increasing importance in the last 5 years. 

Enamine (/Dienamine)-Iminium Cycle-Specific Cascade Catalysis... 

The enamine (/dienamine)-iminium cycle-specific cascade catalysis is an important constituent of amine-catalyzed cascade reactions [10]. This strategy has been explored extensively and also applied to natural product synthesis. One such example is the total synthesis of dihydrocorynantheol, which was first isolated from the bark of Aspidosperma marcgravianum in 1967 [29]. This indole alkaloid is a member of the corynantheine and was found to exhibit antiparasitic, antiviral, or analgetic activities, which have attracted considerable attention from the synthetic community. Among those reported total syntheses, Itoh et al. developed a Mannich-Michael cascade reaction catalyzed by L-proline 52 for the total synthesis of ent-dihydrocorynantheol 54 (Scheme 3.8) [30], The cascade reaction of 3-ethyl-3-buten-2-one 51 with dihydro-P-carboline 50 catalyzed by 30mol% of (S)-proline afforded the tetracyclic core structure 53 in 85% yield. Excellent stereoselectivity was achieved in this cascade reaction (99% enantiomeric excess and almost complete diastereomeric control). Therefore, this organocascade reaction could lead expeditiously to construction of the core structure, which enabled the authors to accomplish the total synthesis of enl-dihydrocorynantheol 54 in just five steps. 

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