The use of unsaturated methylidene ketones in catalytic conjugate allylations allows for a significant expansion in substrate scope and, with appropriate chiral ligands, occurs in a highly enantioselective fashion.Catalytic enantioselective conjugate addition of organometallic reagents to unsaturated carbonyls is an important method in asymmetric synthesis. These reactions are usually accomplished under the aegis of late transition metal catalysts and occur with a broad variety of organometallic reagents. 1 While significant successes have been recorded with aryl, alkyl, vinyl, and alkynyl nucleophiles, reactions of allylmetal reagents are much less developed. In recent studies, we have addressed this limitation and have introduced an enantio-and regioselective catalytic conjugate addition of allylB(pin) (2 , Scheme 1) to arylidene alkylidene ketones (1). 2 Mechanistic studies suggest that this reaction proceeds by way of Lewis acid-induced oxidative addition of the metal to the less hindered alkylidene enone (to give I), followed by transmetallation and 3,3′-reductive elimination 3 via transition state II. 4 Thus for substrate 1, the hexylidene group functions as an activator for allylation of an aryl-substituted enone. While this strategy is effective, it leaves a gap in technology for the selective allylation of alkyl-substituted enones. 5 In this manuscript, we address this issue and describe a general strategy that is effective for the regio-and enantioselective allylation of both aromatic and aliphatic substituted enones.Under the paradigm described above, it appeared plausible that a general catalytic allylation of both aryl-and alkyl-substituted enones might arise from reactions of methylidenesubstituted enones such as 3 (Table 1). In this scenario, oxidative addition of the transition metal to the less hindered methylidene site would be favored, and subsequent 3,3′ reductive elimination would deliver the allyl group to the adjacent internal prochiral alkene. An initial experiment probing this strategy was conducted with Taddol-derived phosphonite ligand L1 6 (Taddol = trans-4,5-Bis(diphenylhydroxymethyl)-2,2-dimethyldioxolane), the most effective ligand for conjugate allylation of arylidene alkylidene ketones (1). In the event, morken@bc.edu. Supporting Information Available. Complete experimental procedures and characterization data ( 1 H and 13 C NMR, IR, and mass spectrometry). This material is free of charge via the internet at http://pubs.acs.org. (Table 1) in the presence of 5 mol % Ni(cod) 2 , 6 mol % ligand L1 and 1.2 equiv of allylB(pin), provided addition product 4 with high regioselectivity and moderate enantiocontrol (entry 1). This encouraging result prompted further study. Examination of ligand structure L1 with Pd 2 (dba) 3 (entry 2) revealed that the regioselectivity was slightly enhanced with Pd relative to Ni; however, the enantioselectivity was diminished. To improve enantioselection a number of other Taddolderived phosphorus ligands were examined, and a selection of results ...
