Synthesis of a DNA-Encoded Macrocyclic Library Utilizing Intramolecular Benzimidazole Formation

The Furan-Thiol-Amine Reaction Facilitates DNA-Compatible Thiopyrrole-Grafted Macrocyclization and Late-Stage Amine Transformation

We here report an efficient DNA-compatible furan-thiol-amine reaction for macrocyclization and late-stage amine transformation. This reaction, conducted under mild conditions, enables the facile cyclization of DNA-conjugated linear peptides into thiopyrrole-grafted macrocycles regardless of ring size or side-chain modification with good to excellent conversion yields. Additionally, this strategy was employed for the late-stage transformation of terminal amines, serving as critical intermediates in the construction of DNA-encoded peptide libraries. Diverse amines were successfully converted into their corresponding thiopyrrole scaffolds, thereby expanding the structural diversity that can be achieved within DNA-encoded libraries.

Synthesis of DNA-Encoded Macrocyclic Peptides via Visible-Light-Mediated Desulfurative C-C Bond Formation

DNA-encoded library (DEL) technology has been developed to serve as a practical platform for the discovery of biologically active macrocyclic peptide compounds. However, the cyclization of linear peptides has been widely regarded as the challenging step in the production of macrocyclic peptide DELs. Herein, we describe a novel DNA-compatible macrocyclization strategy, which enables the construction of ring systems via visible-light-mediated desulfurative C-C bond formation. The macrocyclization proceeds smoothly under mild conditions and in a good yield. Moreover, the reaction is compatible with a variety of linear substrates and can thus be employed to generate structurally diverse DNA-encoded macrocycles with various ring sizes.

High-yield and high-purity amide bond formation using DMTMM PF6 for DNA-encoded libraries

In this study, we report on the ability of DMTMM PF6 to improve the amidation reaction. The on-DNA amidation reaction using DMTMM PF6 demonstrates higher conversion rates than those using HATU or DMTMM Cl, particularly with challenging sterically hindered amines and carboxylic acids. The developed method enables the expansion of available building blocks and the efficient synthesis of high-purity DNA-encoded libraries.

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.

Synthesis of DNA-Encoded Macrocyclic Peptides via Nitrile-Aminothiol Click Reaction

DNA-encoded library (DEL) technology holds exciting potential for discovering novel therapeutic macrocyclic peptides (MPs). Herein, we describe the development of a DEL-compatible peptide macrocyclization method that proceeds via intramolecular click-condensation between 3-(2-cyano-4-pyridyl)-l-alanine (Cpa) and an N-terminal cysteine. Cyclization takes place spontaneously in a buffered aqueous solution and affords the cyclized products in excellent yields. The reaction exhibits a broad substrate scope and can be employed to generate MPs of variable ring size and amino acid composition.