复分解
组合化学
肽
生物正交化学
化学
计算生物学
纳米技术
化学生物学
烯烃复分解
肽合成
拟肽
仿生材料
生物化学
生物相容性材料
药物输送
碳氢化合物
药物发现
作者
Linji Li,Rong Li,Yanan Jiang,Jingru Chao,Si Chen,Hongli Liao,Xiang Li
出处
期刊:ChemBioChem
[Wiley]
日期:2025-10-01
卷期号:26 (23): e202500527-e202500527
被引量:3
标识
DOI:10.1002/cbic.202500527
摘要
Peptide stapling has emerged as a powerful strategy to stabilize α-helical structures in peptides, thereby enhancing their proteolytic resistance, membrane permeability, and biological activity. Among the various stapling methodologies, hydrocarbon stapling via ruthenium-catalyzed ring-closing metathesis remains the most widely adopted due to its robust chemical efficiency and synthetic compatibility with solid-phase peptide synthesis. This review summarizes key advancements in hydrocarbon stapling technologies, including mono- and multiple-stapling, solution- and solid-phase approaches, and newer developments such as stitched and aza-stapled peptides. The integration of rigidified anchoring residues (e.g., cyclobutane or carbocyclic α, α-disubstituted amino acids) and orthogonal metathesis strategies has significantly expanded the structural diversity and functional potential of stapled peptides. Furthermore, novel bioorthogonal modifications and imaging capabilities, such as Raman-active diyne bridges, have opened new directions in therapeutic and diagnostic applications. Together, these innovations underscore the growing utility of stapled peptides in modulating protein-protein interactions and advancing peptide drug discovery.
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