Hypervalent-Iodine(III)-Mediated Tandem Oxidative Dearomatization/Aziridination of Phenolic Amines: Synthesis of Functionalized Unactivated Aziridines.

A new hypervalent-iodine(III)-mediated tandem reaction involving oxidative dearomatization and in situ aziridination of phenolic amines is described, providing a mild and effective method for the assembly of structurally interesting and synthetically useful aziridines. Importantly, the densely functionalized aziridines resulting from this unprecedented tandem reaction offer a platform for expeditious access to architecturally diverse aza-heterocycles through transformations initiated by selective ring-opening of aziridines.

Total Synthesis of (±)-Lycojaponicumin D and Lycodoline-Type Lycopodium Alkaloids.

Lycopodium alkaloids with structural diversity and biological significance have been stimulating an increasing interest in the synthetic and medicinal communities, in which inspiration and exploration of their related biogenetic relationship generally constitute one of the major concerns. Driven by the plausible biogenetic entry to lycojaponicumin D as the first member of Lycopodium alkaloids having a structurally unusual C3-C13-linked scaffold, a new connection with lycodoline has been proposed and discovered on the basis of the design of an unprecedented bioinspired tandem fragmentation/Mannich reaction. Initiated by expeditious assembly of bridgehead heterofunctionalization in the [3.3.1] bicyclic system of lycodoline, a novel tandem palladium-mediated oxidative dehydrogenation/hetero-Michael reaction has been developed for the strain-driven formation of the C-heteroatom bond, leading to a new approach to conformationally rigid bridgehead heteroquaternary carbons. The present unified strategy provides a scenario for the divergent total syntheses of nine natural Lycopodium alkaloids and four unnatural C12 epimers, wherein (±)-lycojaponicumin D and six lycodoline-type alkaloids have been synthetically achieved for the first time.

Total Synthesis of Lycopodium Alkaloids Palhinine A and Palhinine D.

The first total syntheses of Lycopodium alkaloids palhinine A, palhinine D, and their C3-epimers have been divergently achieved through the use of a connective transform to access a pivotal hexacyclic isoxazolidine precursor. A microwave-assisted regio- and stereoselective intramolecular nitrone-alkene cycloaddition was tactically orchestrated as a key step to install the crucial 10-oxa-1-azabicyclo[5.2.1]decane moiety embedded in the conformationally rigid isotwistane framework, demonstrating the feasibility of constructing the highly strained medium-sized ring by introduction of an oxygen bridging linker to relieve the transannular strain in the polycyclic scaffold. Subsequent N-O bond cleavage provided the synthetically challenging nine-membered azonane ring system bearing the requisite C3 hydroxyl group. Late-stage transformations featuring a chemo- and stereoselective reduction of the pentacyclic ß-diketone secured the availability of our target molecules.

Tandem (2 + 2) Annulation/Retro-4π Electrocyclization/Imino-Nazarov Cyclization Reaction of p-Quinone Methides with Ynamides: Expeditious Construction of Functionalized Aminoindenes.

A new tandem annulation of p-quinone methides (p-QMs) with ynamides is described. This cascade reaction features a unique combination of (2 + 2) annulation, retro-4π electrocyclization, and imino-Nazarov cyclization, wherein vinyl p-quinone methides (p-VQMs) as one of the key intermediates have been identified chemically. Significantly, an unusual structural reconstruction of p-QMs involving the cleavage of the C5-C6 bond and the late-stage formation of the C4-C6 bond is involved, leading to a methodology development for the construction of functionalized aminoindenes.