In recent years, asymmetric catalysis of ynamides has attracted much attention, but these reactions mostly constructed central chirality, except for a few examples on the synthesis of axially chiral compounds which exclusively relied on noble-metal catalysis. Herein, a facile access to axially chiral Nheterocycles enabled by chiral Brønsted acid-catalyzed 5-endo-dig cyclization of ynamides is disclosed, which represents the first metal-free protocol for the construction of axially chiral compounds from ynamides. This method allows the practical and atom-economical synthesis of valuable N-arylindoles in excellent yields with generally excellent enantioselectivities. Moreover, organocatalysts and ligands based on such axially chiral Narylindole skeletons are demonstrated to be applicable to asymmetric catalysis.
In the past decades,
significant advances have been made on radical
Smiles rearrangement. However, the eventually formed radical intermediates
in these reactions are limited to the amidyl radical, except for the
few examples initiated by a N-centered radical. Here, a novel and
practical radical Smiles rearrangement triggered by photoredox-catalyzed
regioselective ketyl–ynamide coupling is reported, which represents
the first radical Smiles rearrangement of ynamides. This method enables
facile access to a variety of valuable 2-benzhydrylindoles with broad
substrate scope in generally good yields under mild reaction conditions.
In addition, this chemistry can also be extended to the divergent
synthesis of versatile 3-benzhydrylisoquinolines through a similar
ketyl–ynamide coupling and radical Smiles rearrangement, followed
by dehydrogenative oxidation. Moreover, such an ynamide Smiles rearrangement
initiated by intermolecular photoredox catalysis via addition of external
radical sources is also achieved. By control experiments, the reaction
was shown to proceed via key ketyl radical and α-imino carbon
radical intermediates.
The generation of metal carbenes from readily available alkynes represents a significant advance in metal carbene chemistry. However, most of these transformations are based on the use of noble-metal catalysts and successful examples of such an asymmetric version are still very scarce. Here a copper-catalyzed enantioselective cascade cyclization of N-propargyl ynamides is reported, enabling the practical and atom-economical construction of diverse chiral polycyclic pyrroles in generally good to excellent yields with wide substrate scope and excellent enantioselectivities (up to 97:3 e.r.). Importantly, this protocol represents the first coppercatalyzed asymmetric diyne cyclization. Moreover, mechanistic studies revealed that the generation of donor/donor copper carbenes is presumably involved in this 1,5-diyne cyclization, which is distinctively different from the related gold catalysis, and thus it constitutes a novel way for the generation of donor/donor metal carbenes.
Ynamides are important building blocks in organic synthesis, and a variety of versatile synthetic methods have been developed in the past decade. Among these, catalytic cyclizations of π-tethered ynamides are particularly attractive, since this approach enables facile access to a diverse array of synthetically useful nitrogen heterocycles. However, due to the fact that the nitrogen atom is able to impose an electronic bias, these cyclizations exclusively occur on the α position of ynamides. Herein, we report the reversal of regioselectivity in arene-ynamide cyclization by copper catalysis, which represents the first catalytic π-tethered ynamide cyclization involving the reversal of regioselectivity. This strategy allows the expedient and practical synthesis of valuable azepino [4,5-b]indoles and β-carbolines in generally high yields under mild conditions. Moreover, the relevant mechanistic rationale for this cyclization, especially for the observed high regioselectivity, is strongly supported by density functional theory (DFT) calculations. The synthetic utility of this chemistry is also indicated by the synthesis of several biologically active compounds and natural product bauerine A.
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