Enantioselective Organocatalytic Michael/Aldol Sequence: Anticancer Natural Product (+)‐<i>trans</i>‐Dihydrolycoricidine

McNulty, James; Zepeda-Velázquez, Carlos

doi:10.1002/anie.201403065

Cited by 59 publications

(36 citation statements)

References 57 publications

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“…We were inspired by recent enantioselective organocatalytic approaches toward six member carbacycles to develop a stepwise [3+3]‐type Michael‐aldol sequence,– involving an α‐nitrogen‐substituted acetone moiety reacting with an unsaturated aldehyde, as a rapid entry to the amaryllidaceae core. Such an approach proved successful in our recent synthesis of alkaloid 2 , which provided access to the natural product and structural analogs that permitted investigation of the antiviral activity against herpes viruses …”

Section: Figurementioning

confidence: 99%

“…Commercially available 5‐methoxypiperonal was subject to a two‐carbon aldehyde to alkenal homologation using a diethylacetal‐functionalized Wittig reagent yielding the cinnamaldehyde derivative 7 in 82 % yield (Scheme ). The crucial iminium ion‐mediated [3+3]‐Michael‐aldol sequence of 7 with azidoacetone 8 proved highly effective using the Jørgensen ( R )‐diphenylsilaprolinol secondary amine catalyst in combination with the tertiary amine quinidine, providing the cycloadduct 9 in 58 % isolated yield and >99 % enantiomeric excess (e.e.). The mirror‐image reaction employing ( S )‐diphenylsilaprolinol in the presence of quinidine gave ent ‐ 9 also in 99 % e.e.…”

Section: Figurementioning

confidence: 99%

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Total Synthesis of the Natural Product (+)‐trans‐Dihydronarciclasine via an Asymmetric Organocatalytic [3+3]‐Cycloaddition and discovery of its potent anti‐Zika Virus (ZIKV) Activity

et al. 2016

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An asymmetric total synthesis of the natural product (+)-transdihydronarciclasine has been achieved from a-azidoacetone and cinnamaldehyde precursors via a stepwise asymmetric [3 + 3]-organocatalytic cascade. The anti-Zika virus activity of this compound is also reported for the first time.Amaryllidaceae plants [1][2] continue to be a valuable source of compounds that exhibit potent anticancer, antiviral and other biological properties. As a class, the compounds feature complex, densely functionalized and synthetically challenging [3] aminocyclitol cores. [4] The narciclasine sub-class [1d] of the Amaryllidaceae alkaloids (Figure 1), exemplified by trans-dihydronarciclasine 1, trans-dihydrolycoricidine 2, narciclasine 3, the 7-deoxy analog (lycoricidine) 4, pancratistatin 5 and 7-deoxy analog 6 have attracted particular interest due to their anticancer and antiviral activity. [2] [a] Dr. Figure 1. Structure of the anti-flaviviral natural product trans-dihydronarciclasine 1 and related natural derivatives 2-6.

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Section: Figurementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

Total Synthesis of the Natural Product (+)‐trans‐Dihydronarciclasine via an Asymmetric Organocatalytic [3+3]‐Cycloaddition and discovery of its potent anti‐Zika Virus (ZIKV) Activity

et al. 2016

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“…The intermediate latent alkenals may be cleaved immediately, revealing synthetically useful α,β-unsaturated aldehydes, or may be carried through a wide range of synthetic transformations intact. The robust nature of these latent alkenals contrasts sharply with dialkyl- and cyclic acetals obtained using standard reagents such as 4 and 5 [57,58], and permits a multitude of chemoselective transformations demonstrated in a new synthesis of the natural product macrolactone phomolide G. Further developments on the use of DualPhos and applications of the readily available alkenals in organocatalytic cascade sequences [59,60] are under active investigation in our laboratories.…”

Section: Resultsmentioning

confidence: 99%

DualPhos: a versatile, chemoselective reagent for two-carbon aldehyde to latent ( E )-alkenal homologation and application in the total synthesis of phomolide G

McLeod

McNulty

2016

R. Soc. open sci.

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Advances on the use of the 2-pinacolacetal-tripropylphosphonium salt DualPhos as a general reagent for the two-carbon aldehyde to alkenal homologation and a chemoselective iron (III) chloride mediated deprotection are described. The strategy allows isolation of the latent alkenal intermediates or direct hydrolysis to (E)-alkenals. The robust chemical stability of the latent alkenals is demonstrated in a total synthesis of the macrolactone phomolide G.

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“…Moreover these methodsh ave been successfully employed for the synthesis of biologically active compounds. [6] Due to their multifunctional structure,a mino acids and peptides are espe-cially efficient at multi-activating easily accessible or natural molecules. The combination of either amino-, H-bonding, or Lewis-base catalysis with hydrophobic effects andi n-solvent organization has been knownt om imic enzyme behavior and selectively interactw ith substrates.…”

Section: Introductionmentioning

confidence: 99%

Bifunctional Tripeptide with a Phosphonic Acid as a Brønsted Acid for Michael Addition: Mechanistic Insights

Cortes‐Clerget

Dussart

Kolodziej

et al. 2017

Chemistry A European J

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Enamine catalysis is a widespread activation mode in the field of organocatalysis and is often encountered in bifunctional organocatalysts. We previously described H-Pro-Pro-pAla-OMe as a bifunctional catalyst for Michael addition between aldehydes and aromatic nitroalkenes. Considering that opposite selectivities were observed when compared to H-Pro-Pro-Glu-NH , an analogue described by Wennemers, the activation mode of H-Pro-Pro-pAla-OMe was investigated through kinetic, linear effect studies, NMR analyses, and structural modifications. It appeared that only one bifunctional catalyst was involved in the catalytic cycle, by activating aldehyde through an (E)-enamine and nitroalkene through an acidic interaction. A restrained tripeptide structure was optimal in terms of distance and rigidity for better selectivities and fast reaction rates. Transition-state modeling unveiled the particular selectivity of this phosphonopeptide.

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Enantioselective Organocatalytic Michael/Aldol Sequence: Anticancer Natural Product (+)‐trans‐Dihydrolycoricidine

Cited by 59 publications

References 57 publications

Total Synthesis of the Natural Product (+)‐trans‐Dihydronarciclasine via an Asymmetric Organocatalytic [3+3]‐Cycloaddition and discovery of its potent anti‐Zika Virus (ZIKV) Activity

Total Synthesis of the Natural Product (+)‐trans‐Dihydronarciclasine via an Asymmetric Organocatalytic [3+3]‐Cycloaddition and discovery of its potent anti‐Zika Virus (ZIKV) Activity

DualPhos: a versatile, chemoselective reagent for two-carbon aldehyde to latent ( E )-alkenal homologation and application in the total synthesis of phomolide G

Bifunctional Tripeptide with a Phosphonic Acid as a Brønsted Acid for Michael Addition: Mechanistic Insights

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