The application of abundant and inexpensive fluorine feedstock sources to synthesize fluorinated compounds is an appealing yet underexplored strategy. Here, we report a photocatalytic radical hydrodifluoromethylation of unactivated alkenes with an inexpensive industrial chemical, chlorodifluoromethane (ClCF2H, Freon-22). This protocol is realized by merging tertiary amine-ligated boryl radical-induced halogen atom transfer (XAT) with organophotoredox catalysis under blue light irradiation. A broad scope of readily accessible alkenes featuring a variety of functional groups and drug and natural product moieties could be selectively difluoromethylated with good efficiency in a metal-free manner. Combined experimental and computational studies suggest that the key XAT process of ClCF2H is both thermodynamically and kinetically favored over the hydrogen atom transfer pathway owing to the formation of a strong boron–chlorine (B–Cl) bond and the low-lying antibonding orbital of the carbon–chlorine (C–Cl) bond.
The work of Kita et al. on asymmetric oxidative dearomatization of naphthol carboxylic acids to spirolactones mediated/catalyzed by a novel, conformationally rigid μ-oxo-bridged hypervalent iodine(III) species is a landmark discovery in enantioselective iodine(III) catalysis [Kita, Y.; et al. Angew. Chem., Int. Ed. 2008, 47, 3787. DOI: 10.1002/anie.200800464; J. Am. Chem. Soc. 2013, 135, 4558. DOI: 10.1021/ja401074u]. We have investigated the detailed mechanism of this important transformation using density functional theory. Calculations revealed that proton transfer from the pendant carboxylic acid of naphthols to the bridging oxygen atom or the ligand of iodine(III) species, which enhances the nucleophilicity of the carboxylic oxygen and the nucleofugality of the iodoarene, is crucial for the dearomatizing spirolactonization. Halogen bonding between the resulting carboxylate and the electron-deficient iodine(III) center further stabilizes the dearomatizing spirolactonization transition states. Calculations also revealed a long-neglected cleaved μ-oxo iodine(III) species that is more reactive but less selective than the μ-oxo-bridged hypervalent iodine(III) species itself for the oxidative dearomatization of naphthols. The coexistence of two sequential dearomatizing spirolactonization processes in the reaction system results in a lower enantioselectivity. A new stereochemical model that is able to reproduce and rationalize the observed apparent enantioselectivities is proposed.
The importance of selenium (Se) in biology and health has become increasingly clear. Hydrogen selenide (H2Se), the biologically available and active form of Se, is suggested to be an emerging nitric oxide (NO)-like signaling molecule. Nevertheless, the research on H2Se chemical biology has technique difficulties due to the lack of well-characterized and controllable H2Se donors under physiological conditions, as well as a robust assay for direct H2Se quantification. Motivated by these needs, here, we demonstrate that selenocyclopropenones and selenoamides are tunable donor motifs that release H2Se upon reaction with cysteine (Cys) at pH 7.4 and that structural modifications enable the rate of Cys-mediated H2Se release to be tuned. We monitored the reaction pathways for the H2Se release and confirmed H2Se generation qualitatively using different methods. We further developed a quantitative assay for direct H2Se trapping and quantitation in an aqueous solution, which should also be operative for investigating future H2Se donor motifs. In addition, we demonstrate that arylselenoamide has the capability of Cys-mediated H2Se release in cellular environments. Importantly, mechanistic investigations and density functional theory (DFT) calculations illustrate the plausible pathways of Cys-activated H2Se release from arylselenoamides in detail, which may help understand the mechanistic issues of the H2S release from pharmacologically important arylthioamides. We anticipate that the well-defined chemistries of Cys-activated H2Se donor motifs will be useful for studying Se biology and for development of new H2Se donors and bioconjugate techniques.
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