Chiral Primary Amine Catalyzed α-Arylation of Simple Ketones via Asymmetric Retro-Claisen Cleavage.

Highly enantioselective α-arylation of simple ketones has been achieved by chiral primary amine catalyzed asymmetric retro-Claisen cleavage of ß-diketones. This mild organocatalytic strategy enables the construction of α-aryl tertiary carbon stereocenters in good yields and excellent enantioselectivities (up to 98 % ee) with the para-quinone monoimines as aryl sources. Furthermore, oxidative catalytic asymmetric α-arylation has also been realized with free p-aminophenols.

Catalytic Asymmetric α-Alkylsulfenylation with a Disulfide Reagent.

The use of alkylthio electrophiles in synthesis has remained elusive because of the lack of a suitable reagent that is practical and of excellent enantioselectivity and appropriate reactivity. In this work we introduce a novel alkylthio reagent based on the 2-mercapto-5-methyl-1,3,4-thiadiazole (MMTD) fragment for direct alkylsulfenylation of ketones and aldehydes. It can be readily prepared by the oxidative coupling between thiadiazole and other alkylthio reagents and be combined with chiral primary aminocatalysis. This protocol provides facile access to diverse α-alkylthio quaternary carbon centers with good stereoselectivities.

In-depth organic mass cytometry reveals differential contents of 3-hydroxybutanoic acid at the single-cell level.

Comprehensive single-cell metabolic profiling is critical for revealing phenotypic heterogeneity and elucidating the molecular mechanisms underlying biological processes. However, single-cell metabolomics remains challenging because of the limited metabolite coverage and inability to discriminate isomers. Herein, we establish a single-cell metabolomics platform for in-depth organic mass cytometry. Extended single-cell analysis time guarantees sufficient MS/MS acquisition for metabolite identification and the isomers discrimination while online sampling ensures the high-throughput of the method. The largest number of identified metabolites (approximately 600) are achieved in single cells and fine subtyping of MCF-7 cells is first demonstrated by an investigation on the differential levels of 3-hydroxybutanoic acid among clusters. Single-cell transcriptome analysis reveals differences in the expression of 3-hydroxybutanoic acid downstream antioxidative stress genes, such as metallothionein 2 (MT2A), while a fluorescence-activated cell sorting assay confirms the positive relationship between 3-hydroxybutanoic acid and target proteins; these results suggest that the heterogeneity of 3-hydroxybutanoic acid provides cancer cells with different ability to resist surrounding oxidative stress. Our method paves the way for deep single-cell metabolome profiling and investigations on the physiological and pathological processes that occur during cancer.

Asymmetric α-allylic allenylation of ß-ketocarbonyls and aldehydes by synergistic Pd/chiral primary amine catalysis.

We herein describe an asymmetric α-allylic allenylation of ß-ketocarbonyls and aldehydes with 1,3-enynes. A synergistic chiral primary amine/Pd catalyst was identified to facilitate the utilization of 1,3-enynes as atom-economic and achiral allene precursors. The synergistic catalysis enables the construction of all-carbon quaternary centers-tethered allenes bearing non-adjacent 1,3-axial central stereogenic centers in high level of diastereo- and enantio-selectivity. By switching the configurations of ligands and aminocatalysts, diastereodivergence can be achieved and any of the four diastereoisomers can be accessed in high diastereo- and enantio- selectivity.

Asymmetric Coupling of ß-Ketocarbonyls and Alkynes by Chiral Primary Amine/Rh Synergistic Catalysis.

We herein report a synergetic chiral primary amine and rhodium catalysis for asymmetric coupling of ß-ketocarbonyls and alkynes. A series of ß-ketocarbonyls could be applied to afford linear allylation products, bearing all-carbon quaternary centers in high regio- and enantioselectivities.