Development of a novel ring contraction strategy and application to the total synthesis of presilphiperfolanol natural products

Biologically active and structurally complex natural products provide a powerful driving force for the development of novel reaction methodology. Major advances can reshape the way chemists approach the construction of challenging chemical bonds. In this work, we begin by describing the development of a catalytic asymmetric synthesis of five and seven-membered rings containing all-carbon quaternary stereocenters. Enantioselective Pd-catalyzed decarboxylative allylic alkylation reactions of β-ketoester substrates afforded a variety of chiral seven-membered α-quaternary vinylogous esters. Initial attempts to convert these compounds to γ-quaternary cycloheptenones led to the discovery of a two-carbon ring contraction reaction, which provided isomeric γ-quaternary acylcyclopentenes. Subsequent adjustment of reaction parameters provided divergent access to the originally targeted cycloheptenones. Numerous synthetic applications of the two versatile product types are demonstrated. The methodology expands on our previous investigations of six-membered ring scaffolds and provides additional chiral building blocks for asymmetric total synthesis. The ring contraction approach to acylcyclopentenes was further developed in the total synthesis of the presilphiperfolanols, which are important intermediates in sesquiterpene biosynthesis. Key to our synthetic route to the tricyclic core was the application of intramolecular Diels-Alder and Ni-catalyzed 1,4-hydroboration reactions. From these efforts, the enantioselective total synthesis of presilphiperfolan-1β-ol was achieved. Future research efforts seek to extend the synthetic route to presilphiperfolan-9α-ol and study the synthetic compounds in biomimetic carbocation rearrangement processes.