Catalyst-free late-stage functionalization to assemble α-acyloxyenamide electrophiles for selectively profiling conserved lysine residues.
Yuanyuan ZhaoKang DuanYoulong FanShengrong LiLiyan HuangZhengchao TuHongyan SunGregory M CookJing YangPinghua SunYi TanKe DingZhengqiu LiPublished in: Communications chemistry (2024)
Covalent probes coupled with chemical proteomics represent a powerful method for investigating small molecule and protein interactions. However, the creation of a reactive warhead within various ligands to form covalent probes has been a major obstacle. Herein, we report a convenient and robust process to assemble a unique electrophile, an α-acyloxyenamide, through a one-step late-stage coupling reaction. This procedure demonstrates remarkable tolerance towards other functional groups and facilitates ligand-directed labeling in proteins of interest. The reactive group has been successfully incorporated into a clinical drug targeting the EGFR L858R mutant, erlotinib, and a pan-kinase inhibitor. The resulting probes have been shown to be able to covalently engage a lysine residue proximal to the ATP-binding pocket of the EGFR L858R mutant. A series of active sites, and Mg 2+ , ATP-binding sites of kinases, such as K33 of CDK1, CDK2, CDK5 were detected. This is the first report of engaging these conserved catalytic lysine residues in kinases with covalent inhibition. Further application of this methodology to natural products has demonstrated its success in profiling ligandable conserved lysine residues in whole proteome. These findings offer insights for the development of new targeted covalent inhibitors (TCIs).
Keyphrases
- small molecule
- protein protein
- epidermal growth factor receptor
- amino acid
- cell cycle
- small cell lung cancer
- transcription factor
- tyrosine kinase
- fluorescence imaging
- living cells
- room temperature
- cancer therapy
- single cell
- mass spectrometry
- advanced non small cell lung cancer
- emergency department
- binding protein
- ionic liquid
- minimally invasive
- cell proliferation
- dna binding
- reduced graphene oxide
- transition metal