Stereoselective synthesis of spirocyclic compounds containing heterocyclic motifs represents a formidable challenge in enantioselective synthesis. Here, we present a cascade reaction between α,β-unsaturated aldehydes and isoxazolones under synergistic catalysis of a chiral secondary amine and a palladium(0) catalyst. This strategy allows access to chiral spiroisoxazolone derivatives with a large substrate scope tolerance and high levels of diastereoselectivity (dr up to 20:1) and enantioselectivity (up to 99% ee). Furthermore, the utility of this methodology is showcased by the transformation of chiral spiroisoxazolones into structurally attractive and enantiomerically enriched cyclopentene carboxylic acids with two stereogenic centers.

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Azlactone is an important starting material for synthesizing amino acids containing a quaternary α-carbon. In this study, we have developed a sequential "one-pot" procedure involving an enantioselective spirocyclization reaction followed by acidic azlactone opening, which led to amino acid derivatives. The key step of this procedure is a spirocyclization between propargylated azlactones and enals by using a cooperative catalytic approach that combines chiral secondary amine and achiral Pd(0) complexes. The final acid opening of the azlactone motif allows isolation of the corresponding amino acid derivatives as major diastereoisomers in yields ranging from 37% to 70% with enantioselectivities of 85-97% ee. These synthesized amino acid derivatives hold great potential in the pharmaceutical and bioactive compound industries. Moreover, the final amino acid products with a cyclopentene moiety can be further derivatized, opening up even more possibilities for their application.

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In this study, we report a highly stereoselective and versatile synthesis of spiro pyrazolones, promising motifs that are being employed as pharmacophores. The new synthetic strategy merges organocatalysis and metal catalysis to create a synergistic catalysis using proline derivatives and Pd catalysts. This protocol is suitable for late-stage functionalization, which is very important in drug discovery. Additionally, a thorough computational study proved to be very useful to elucidate the function of the different catalysts along the reaction, showing a peculiar feature: the -CPh2OSiMe3 group of the proline catalyst switches its role during the reaction. In the initial Michael reaction, this group plays its commonly-assumed role of bulky blocking group, but the same group generates π-Pd interactions and acts as a directing group in the subsequent Pd-catalyzed Conia-ene reaction. This finding might be very relevant especially for processes with many steps, such as cascade reactions, in which functional groups are assumed to play the same role during all reaction steps.

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