Stereoselective synthesis of polyenic alarm pheromones of cephalaspidean molluscs

Dehydrogenative desaturation-relay via formation of multicenter-stabilized radical intermediates

In organic molecules, the reactivity at the carbon atom next to the functional group is dramatically different from that at other carbon atoms. Herein, we report that a versatile copper-catalyzed method enables successive dehydrogenation or dehydrogenation of ketones, aldehydes, alcohols, α,β-unsaturated diesters, and N-heterocycles to furnish stereodefined conjugated dienecarbonyls, polyenecarbonyls, and nitrogen-containing heteroarenes. On the basis of mechanistic studies, the copper-catalyzed successive dehydrogenation process proceeds via the initial α,β-desaturation followed by further dehydrogenative desaturation of the resultant enone intermediate, demonstrating that the reactivity at α-carbon is transferred through carbon–carbon double bond or longer π-system to the carbon atoms at the positions γ, ε, and η to carbonyl groups. The dehydrogenative desaturation–relay is ascribed to the formation of an unusual radical intermediate stabilized by 5- or 7,- or 9-center π-systems. The discovery of successive dehydrogenation may open the door to functionalizations of the positions distant from functional groups in organic molecules.

Synthesis of valuable polyene molecules under mild conditions and with good functional groups tolerance is of paramount importance. Here, the authors show the versatile copper-catalyzed successive dehydrogenation of a variety of organic substrates affording highly conjugated unsaturated products.

An enantioselective synthesis of the C24-C40 fragment of (-)-pulvomycin

The C24-C40 fragment of (-)-pulvomycin was prepared in enantiomerically pure form using a concise synthesis method (15 linear steps from D-fucose, 6.8% overall yield) featuring a diastereoselective addition to an aldehyde, a β-selective glycosylation and a Stille cross-coupling as the key steps.

The Suzuki coupling reaction in the stereocontrolled synthesis of 9-cis-retinoic acid and its ring-demethylated analogues

The thallium-accelerated Suzuki coupling reaction of tetraenyl iodide 19 and cyclohexenyl boronate 18 afforded ethyl 9-cis-retinoate (12) in high yield. Both coupling partners of the Suzuki reaction are better reacted immediately after generation from their precursors, tetraenylstannane 10 and cyclohexenyl iodide 13. The geometrically homogeneous tetraenylstannane 10, comprising the polyenic side chain of ethyl 9-cis-retinoate and its ring-demethylated analogues, was synthesized by a stereoselective Horner-Wadsworth-Emmons reaction. On the other hand, easily available cyclohexanones are ideal starting materials for preparation of the cyclohexenyl boronates required for the synthesis of the ring-modified 9-cis-retinoic acid analogues. For hindered cyclohexanones, hydrazones were converted to cyclohexenyl iodides. Iodine-lithium exchange and trapping with B(OMe)(3) then afforded the cyclohexenyl boronates. If the precursor cyclohexanone has secondary carbons, the alkenyllithium species was conveniently formed by elimination of the C,N-dilithiated intermediate obtained upon treating the trisylhydrazone with n-BuLi (Shapiro reaction). None of the above procedures allowed the generation of the more substituted organolithium from 2-methylcyclohexanone. However, the alternative Stille cross-coupling of 34 and 10 afforded 9-cis-1,1-bisdemethylretinoic acid 7. Both Suzuki and Stille coupling reactions took place under mild conditions, and the preservation of the retinoid side-chain geometry was therefore secured.