Dynamics in Catalytic Asymmetric Diastereoconvergent (3 + 2) Cycloadditions with Isomerizable Nitrones and α-Keto Ester Enolates

Factors Controlling Diastereoselectivity and Reactivity in the Catalytic Aerobic Carbooxygenation of (E)-2-Fluoro-3-aryl-allyl Nitroacetates

Radical cyclizations are powerful tools for complexity building, providing facile access to functionalized cyclic adducts. However, forging two contiguous tetrasubstituted carbons via radical cyclization through the addition of tertiary radicals to geminally disubstituted sp2 carbons has rarely been investigated. Furthermore, the effect of double-bond geometry at the geminally disubstituted sp2 carbon on reactivity and stereochemical outcomes remains underexplored. In this study, we present experimental and computational studies on the carbooxygenation of 2-fluoro-3-aryl-allyl nitroacetates to investigate reactivity and selectivity differences between (E)- and (Z)-isomers. First, we identify that (E)-isomers are less reactive than (Z)-isomers. Second, both (E)- and (Z)-isomers undergo conversion to α,α,β,β-tetrasubstituted γ-lactones with high syn-selectivity, despite the absence of putative E/Z isomerization of the alkene unit. Third, incorporating an electron-donating group at the radical acceptor enhances the reactivity of (E)-isomers in catalytic aerobic carbooxygenation. Fourth, computational studies show that syn-selectivity is mainly governed by the fluorine-induced gauche effect, whereas SOMO-HOMO level inversion induced by the electron-donating group at the radical acceptor enhances (E)-isomer reactivity. Based on these mechanistic insights, we develop a diastereoconvergent protocol using the E/Z mixture as a starting material to synthesize a potent antifungal agent.

Asymmetric [3 + 3] cycloaddition of cinnamaldehyde-derived N-aryl nitrones with 2-indolemethanols enabled by chiral phosphoric acid

We described a chiral phosphoric acid (CPA) catalyzed asymmetric [3 + 3] cycloaddition of cinnamaldehyde-derived N-aryl nitrones with 2-indolylmethanols to prepare various indole-fused 1,2-oxazines in high yields (up to 96%) with excellent enantioselectivity (>99% ee). Control experiments indicate that hydrogen bonding plays important roles in controlling the enantioselectivity of products. This strategy provides an efficient pathway to construct enantioenriched indole-fused 1,2-oxazines from N-aryl nitrones with 2-indolylmethanols.

Catalytic Enantioselective Aldol Reactions of Pyruvates as Nucleophiles with Chlorinated and Fluorinated Aldehydes and Ketones

Reactions of pyruvates as nucleophiles under catalytic conditions are difficult to control without the use of enzymes as catalysts. Here, enantioselective aldol reactions of pyruvates with chlorinated and fluorinated aldehydes and ketones under organocatalytic conditions, in which pyruvates act as nucleophiles, are reported. Based on analyses of self-aldol reactions of pyruvates in the presence of model catalysts, catalysts of the desired cross aldol reactions were developed. Using the primary amine-derived catalyst, the desired aldol products, i.e., γ-chlorinated alkyl or γ-fluorinated alkyl group-substituted γ-hydroxy α-ketoesters, were obtained in good to high yields with high enantioselectivities.

Synthesis of Quinolinoneylnitrones and Coumarinylnitrones via a Cascade Hydroamination and Aza-MBH-Type Reaction

Nitrones are quite useful intermediates and have been broadly applied in organic synthesis, drug discovery, and photochemistry research. Many functional nitrones have been successfully prepared using various strategies. In this work, an efficient method for synthesizing novel quinolinoneylnitrone and coumarinylnitrone derivatives was developed. Preliminary mechanistic research suggests that this protocol included a cascade hydroamination and aza-MBH-type reaction.

Rhodium-catalyzed enantioselective and diastereodivergent access to diaxially chiral heterocycles

N-N axially chiral biaryls represent a rarely explored class of atropisomers. Reported herein is construction of diverse classes of diaxially chiral biaryls containing N-N and C-N/C-C diaxes in distal positions in excellent enantioselectivity and diastereoselectivity. The N-N chiral axis in the products provides a handle toward solvent-driven diastereodivergence, as has been realized in the coupling of a large scope of benzamides and sterically hindered alkynes, affording diaxes in complementary diastereoselectivity. The diastereodivergence has been elucidated by computational studies which revealed that the hexafluoroisopropanol (HFIP) solvent molecule participated in an unusual manner as a solvent as well as a ligand and switched the sequence of two competing elementary steps, resulting in switch of the stereoselectivity of the alkyne insertion and inversion of the configuration of the C-C axis. Further cleavage of the N-directing group in the diaxial chiral products transforms the diastereodivergence to enantiodivergence.

Experimental and Computational Investigation of Facial Selectivity Switching in Nickel-Diamine-Acetate-Catalyzed Michael Reactions

Chiral Ni complexes have revolutionized both asymmetric acid-base and redox catalysis. However, the coordination isomerism of Ni complexes and their open-shell property still often hinder the elucidation of the origin of their observed stereoselectivity. Here, we report our experimental and computational investigations to clarify the mechanism of β-nitrostyrene facial selectivity switching in Ni(II)-diamine-(OAc)₂-catalyzed asymmetric Michael reactions. In the reaction with a dimethyl malonate, the Evans transition state (TS), in which the enolate binds in the same plane with the diamine ligand, is identified as the lowest-energy TS to promote C-C bond formation from the Si face in β-nitrostyrene. In contrast, a detailed survey of the multiple potential pathways in the reaction with α-keto esters points to a clear preference for our proposed C-C bond-forming TS, in which the enolate coordinates to the Ni(II) center in apical-equatorial positions relative to the diamine ligand, thereby promoting Re face addition in β-nitrostyrene. The N-H group plays a key orientational role in minimizing steric repulsion.

Photo-induced redox cascade reaction of nitroarenes and amines

A photo-induced redox cascade reaction has been developed for the chemoselective construction of isoxazolidine derivatives from stable and easily available nitroarenes and amines.

Fluoride Additive as a Simple Tool to Qualitatively Improve Performance of Nickel-Catalyzed Asymmetric Michael Addition of Malonates to Nitroolefins

Nowadays, design of the new chiral ligands for organometallic catalysts is often based on the step-by-step increase in their complexity to improve efficiency. Herein we describe that simple in situ addition of the fluoride source to the asymmetric organometallic catalyst can improve not only activity but also enantioselectivity. Bromide-nickel diimine complexes were found to catalyze asymmetric Michael addition in low yields and ee, but activation with fluoride leads to a significant improvement in catalyst performance. The developed approach was applied to prepare several enantioenriched GABA analogues.

Multicomponent formation route to a new class of oxygen-based 1,3-dipoles and the modular synthesis of furans

A new class of phosphorus-containing 1,3-dipoles can be generated by the multicomponent reaction of aldehydes, acid chlorides and the phosphonite PhP(catechyl). These 1,3-dipoles are formally cyclic tautomers of simple Wittig-type ylides, where the angle strain and moderate nucleophilicity in the catechyl-phosphonite favor their cyclization and also direct 1,3-dipolar cycloaddition to afford single regioisomers of substituted products. Coupling the generation of the dipoles with 1,3-dipolar cycloaddition offers a unique, modular route to furans from combinations of available aldehydes, acid chlorides and alkynes with independent control of all four substituents.

Theoretical insight into the origins of chemo- and diastereo-selectivity in the palladium-catalysed (3 + 2) cyclisation of 5-alkenyl thiazolones

The mechanism of the palladium-catalysed (3 + 2) cyclisation of 5-alkenyl thiazolones and VECs has been investigated from a computational perspective, and the origins of unique chemoselectivity and excellent diastereoselectivity have been disclosed.