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Forging Odd-Membered Rings: Palladium-Catalyzed Asymmetric Cycloadditions of Trimethylenemethane.

Barry M TrostGuillaume Mata
Published in: Accounts of chemical research (2020)
The catalytic asymmetric synthesis of complex molecules has been the focus of our research program for several decades because such strategies have significant utility for the construction of chiral building blocks for drug development as well as the total synthesis of natural products. Cycloaddition reactions are very powerful transformations in organic synthesis providing access to highly functionalized motifs from simple starting materials. In concert with this central interest, four decades ago, we reported the palladium-catalyzed trimethylenemethane (TMM) cycloaddition for forging odd-membered ring systems. In recent years, we focused our attention on the development of powerful ligand scaffolds which enable the preparation of valuable products with complete control of chemo-, regio-, diastereo-, and enantioselectivity, thereby addressing several limitations in the field of palladium-catalyzed asymmetric cycloadditions. The first section of this Account will outline the discovery of a new class of highly modular pyrrolidine-based phosphoramidite and diamidophosphite chiral ligands which facilitate [3 + 2] cycloadditions of TMM donors, opening a new area in asymmetric construction of five-membered rings.The formation of the Pd-TMM zwitterionic intermediates is driven by the unique charge distribution of the cationic π-allyl motif, in which the most electropositive central carbon stabilizes the neighboring carbanion generated by either desilylation or deprotonation. The second section of this Account summarizes the scope of cycloadditions between Pd-TMM zwitterionic intermediates generated via desilylation and a variety of electron-deficient acceptors to access cyclopentanes, pyrrolidines and tetrahydrofurans. This section also includes the use of nitrile-, vinyl-, alkynyl- and allene-substituted TMM donors to rapidly generate cycloadducts with high molecular complexity. The extension of this strategy to include [6 + 3] cycloadditions and dearomative processes will also be presented. The third section will discuss a new generation of TMM donors substituted with electron-withdrawing groups such as nitrile, benzophenone imine, trifluoromethyl, and phosphonate, where the Pd-TMM zwitterionic intermediates are generated via deprotonation of the acidic C-H bond adjacent to the π-allyl motif. This new strategy has enabled the synthesis of heterocycles with increased numbers of functional groups in highly asymmetric and atom-economic fashion.Throughout this Account, we will describe the implementation of these transformations toward the rapid assembly of drug candidates and the total synthesis of natural products such as (-)-marcfortine C. We will also give details of mechanistic studies regarding relevant intermediates within the catalytic cycles of the different strategies, which allowed us to better understand the origin of selectivity with various donors.
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