Abstract
With the intention of improving synthetic efficiency, organic chemists have turned to bioinspired organocascade or domino processes that generate multiple bonds and stereocentres in a single operation. However, despite the great importance of substituted cyclopentanes, given their prevalence in complex natural products and pharmaceutical agents, the rapid, enantioselective assembly of these carbocycles lags behind cyclohexanes. Here, we describe a Michael-aldol-β-lactonization organocascade process for the synthesis of complex cyclopentanes utilizing chiral α,β-unsaturated acylammonium intermediates, readily generated by activation of commodity unsaturated acid chlorides with chiral isothiourea catalysts. This efficient methodology enables the construction of two C-C bonds, one C-O bond, two rings and up to three contiguous stereogenic centres delivering complex cyclopentanes with high levels of relative and absolute stereocontrol. Our results suggest that α,β-unsaturated acylammonium intermediates have broad utility for the design of organocascade and multicomponent processes, with the latter demonstrated by a Michael-Michael-aldol-β-lactonization.
Publication types
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Research Support, Non-U.S. Gov't
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Research Support, U.S. Gov't, Non-P.H.S.
MeSH terms
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Ammonium Compounds / chemistry
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Catalysis
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Cyclopentanes / chemical synthesis*
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Cyclopentanes / chemistry*
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Malonates / chemistry
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Models, Molecular
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Stereoisomerism
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Thiourea / chemistry
Substances
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Ammonium Compounds
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Cyclopentanes
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Malonates
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mesoxalic acid
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Thiourea
Associated data
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PubChem-Substance/164178426
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PubChem-Substance/164178427
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