化学
双功能
组合化学
催化作用
配体(生物化学)
对映选择合成
双功能催化剂
背景(考古学)
动力学分辨率
肽
有机化学
合理设计
联吡啶
立体化学
金属
生物催化
取代基
手性配体
作者
Halle M. Marvich,Olivia C. Langner,Nicolò Tampellini,Scott J. Miller
摘要
High Resolution Image Download MS PowerPoint Slide Chiral aminoxyl catalysts have shown promise for applications in asymmetric oxidations but have been historically synthetically challenging to develop. The paucity of chiral catalysts is particularly severe in aerobic oxidations when cocatalysis involves the combined action of an aminoxyl species and a Cu-based metal complex. In these oxidations, the venerable bipyridine ligand (bpy) is most commonly employed to bind to the Cu metal center. The utility of bpy ligands, in this context and many others, has created great interest in the development of modular chiral variants. However, the design of efficient chiral versions within this ligand class remains a significant challenge. Herein, we report a bifunctional chiral peptide ligand featuring both an aminoxyl and a bipyridyl motif and demonstrate its utility in the copper(I)-catalyzed aerobic oxidation of biaryl diols to furnish axially chiral aldehydes. This catalyst was found to efficiently catalyze atroposelective oxidations using ambient air as the terminal oxidant. Additionally, catalyst bifunctionality was found to be essential for enantioselectivity in this desymmetrization, affording axially chiral products in up to >99.5:0.5 er, facilitated by combined initial enantiotopic group selection followed by varying levels of secondary kinetic resolution. Central to catalyst design is the synthesis and incorporation of bipyridylalanine into an aminoxyl-containing peptide. Mechanistic studies reveal a first-order kinetic profile on the catalyst, which, in combination with computational experiments, suggest that the aminoxyl and bipyridyl moieties of a single bifunctional peptide function in unison throughout the catalytic cycle.
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