Diverse opportunities: A Rhodium(III)-catalyzed ortho-selective olefination of arenes using a novel triazene as a directing group is reported. This method exhibits substantial post-functionalization synthetic versatility, overcoming a vital limitation in C sp 2-H activation/functionalization products: restricted structural diversity.
We report a formal [4+2] cycloaddition reaction of styrenes under visible-light catalysis. Two styrene molecules with different electronic or steric properties were found to react with each other in good yield and excellent chemo- and regioselectivity. This reaction provides direct access to polysubstituted tetralin scaffolds from readily available styrenes. Sophisticated tricyclic and tetracyclic tetralin analogues were prepared in high yield and up to 20/1 diasteroselectivity from cyclic substrates.
N-heterocyclic carbenes are a class of persistent carbenes stabilized by adjacent heteroatoms that are part of a heterocycle. They play a central role in multiple enzymatic biosynthetic reactions that involve thiamine diphosphate. Inspired by this biocatalysis machinery, N-heterocyclic carbenes have emerged as one of the most versatile classes of organocatalysts for organic reactions. However, the asymmetric synthesis of carbon-carbon bonds through a non-covalent interaction mechanism has not been previously established for chiral carbenes. Here, we report an N-heterocylic carbene-catalysed, highly enantioselective process that uses weak hydrogen bonds to relay asymmetric bias. We find that catalytic amounts of hexafluoroisopropanol are the critical proton shuttle that facilitates hydrogen transfer to provide high-reaction rates and high enantioselectivity. We demonstrate that a successful asymmetric reaction of this type can be accomplished through a rational design that balances the pKa values of the substrate, the carbene precursor and the product.
Targeted inhibition of anaplastic
lymphoma kinase (ALK) dramatically
improved therapeutic outcomes in the treatment of ALK-positive cancers,
but unfortunately patients invariably progressed due to acquired resistance
mutations in ALK. Currently available drugs are all type-I inhibitors
bound to the ATP-binding pocket and are most likely to be resistant
in patients harboring genetic mutations surrounding the ATP pocket.
To overcome drug resistance, we rationally designed a novel kind of
“bridge” inhibitor, which specially bind into an extended
hydrophobic back pocket adjacent to the ATP-binding site of ALK. The
novel type-I1/2 inhibitors display excellent antiproliferation
activity against ALK-positive cancer cells and appear superior to
two clinically used drugs, crizotinib and ceritinib. Structural and
molecular modeling analyses indicate that the inhibitor induces dramatic
conformational transition and stabilizes unique DFG-shifted loop conformation,
enabling persistent sensitivity to different genetic mutations in
ALK. These data highlight a rationale for further development of next-generation
ALK inhibitors to combat drug resistance.
Remote asymmetric protonation is a longstanding challenge due to the small size of protons. Reactions involving electron-deficient olefins pose a further difficulty due to the electrophilic nature of these substrates. We report a shuttling system that delivers a proton in a highly enantioselective manner to the β-carbon of enals using a chiral N-heterocyclic carbene (NHC) catalyst. Choices of a Brønsted base shuttle and a Brønsted acid cocatalyst are critical for highly stereoselective β-protonation of the homoenolate intermediate and regeneration of the NHC catalyst results in functionalization of the carbonyl group. Thioesters with a β-chiral center were prepared in a redox-neutral transformation with an excellent yield and ee.
CH activation/functionalization is one of the most effective ways to assemble complex organic scaffolds. A vital limitation is the need for a directing group that remains in the product architecture and restricts structural diversity. In their Communication on , Y. Huang et al. describe a triazine directing group for C sp 2H activation/functionalization. This group exhibits substantial post‐functionalization synthetic versatility, thus allowing for a range of further transformations.
The aza-Michael addition reaction is a vital transformation for the synthesis of functionalized chiral amines. Despite intensive research, enantioselective aza-Michael reactions with alkyl amines as the nitrogen donor have not been successful. We report the use of chiral N-heterocyclic carbenes (NHCs) as noncovalent organocatalysts to promote a highly selective aza-Michael reaction between primary alkyl amines and β-trifluoromethyl β-aryl nitroolefins. In contrast to classical conjugate-addition reactions, a strategy of HOMO-raising activation was used. Chiral trifluoromethylated amines were synthesized in high yield (up to 99 %) with excellent enantioselectivity (up to 98 % ee).
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