Straightforward synthesis of quinolines from enones and 2-aminobenzyl alcohols using an iridium-catalyzed transfer hydrogenative strategy.

A new protocol for the direct synthesis of quinolines from enones and 2-aminobenzyl alcohols via iridium-catalyzed transfer hydrogenative reactions has been demonstrated. This method employs easily available [IrCp*Cl2]2/t-BuOK as the efficient catalyst system, proceeding with the merits of high step- and atom efficiency, mild reaction conditions and operational simplicity. The experimental studies suggest that the reactions start with transfer hydrogenation, followed by the Friedländer reaction to give the final products.

Macrocyclizing DNA-Linked Peptides via Three-Component Cyclization and Photoinduced Chemistry.

While DNA-encoded macrocyclic libraries have gained substantial attention and several hit compounds have been identified from DNA-encoded library technology, efficient on-DNA macrocyclic methods are also required to construct DNA-linked libraries with a high degree of cyclization and DNA integrity. In this paper, we reported a set of on-DNA methodologies, including the use of an OPA-mediated three-component cyclization with native handles of amino acids and photoredox chemistries. These chemistries proceed smoothly under mild conditions in good to excellent conversions, successfully generating novel isoindole, isoindoline, indazolone, and bicyclic scaffolds.

The Development of DNA-Compatible S-Glycosyl Transformations.

In this study, we revealed two distinct S-glycosyl transformations in a DNA-encoded library (DEL)-compatible environment. The first approach involves 2-chloro-1,3-dimethylimidazolidinium chloride (DMC)-mediated S-glycosylation, which is facilitated by the coupling of unprotected sugar units with the thiol residue of the DNA-linked compounds. However, this methodology falls short of the requirement for DEL construction due to its limited substrate scope. We further investigated a photoinduced DNA-compatible S-glycosyl transformation through a radical process. In this alternative approach, allyl sugar sulfones serve as sugar donors and are conjugated to DNA-linked compounds upon irradiation with green light. Encouragingly, this on-DNA glycosyl chemistry demonstrated excellent compatibility with functional groups presented in both sugar units and peptides, affording the desired DNA-linked glycosyl derivatives with good to excellent conversions. This pioneering DNA-compatible S-glycosyl transformation represents a valuable tool, facilitating the preparation of glycosyl DELs and offering avenues for the exploration of sugar-incorporated delivery systems.