Ruiz-Gómez Gloria, Uvizl Alena, Bakos Gabor, Leung Jacky K, Pisabarro M Teresa, Mansfeld Jörg
Structural Bioinformatics, Biotechnology Center (BIOTEC), TU Dresden, 01307 Dresden, Germany.
Cell Cycle, Biotechnology Center (BIOTEC), TU Dresden, 01307 Dresden, Germany.
J Med Chem. 2025 Jun 12;68(11):11468-11483. doi: 10.1021/acs.jmedchem.5c00416. Epub 2025 May 21.
The ubiquitin system represents an attractive pharmacological target for numerous pathological processes, including cancer and neurodegeneration. RING domain-containing E3 ubiquitin ligases constitute the largest class of ubiquitin enzymes, providing a scaffold for substrate recognition and catalysis. Their shallow groove recognition interfaces involving discontinuous epitopes and a lack of defined binding pockets have largely rendered them undruggable. Inspired by natural RING inhibitors, we have developed a pharmacophore-based strategy for the rational design of peptidomimetics targeting RING domains, and we demonstrate its feasibility by using the macromolecular APC/C complex (anaphase-promoting complex/cyclosome). We designed scaffolds binding to the APC/C RING domain and efficiently inhibiting its activity . Iterative structure-based design and experimental studies to optimize their chemical stability, permeability, and specificity lead to new hydrocarbon-stapled-based molecules inhibiting APC/C and in cancer cells. Our results provide a robust rationale for targeting RING-containing enzymes of therapeutic value and promising leads for clinical APC/C inhibition.
泛素系统是包括癌症和神经退行性疾病在内的众多病理过程中一个有吸引力的药理学靶点。含RING结构域的E3泛素连接酶构成了最大类别的泛素酶,为底物识别和催化提供了一个支架。它们涉及不连续表位的浅沟识别界面以及缺乏明确的结合口袋,这在很大程度上使得它们难以成药。受天然RING抑制剂的启发,我们开发了一种基于药效团的策略,用于合理设计靶向RING结构域的拟肽,并通过使用大分子后期促进复合物/环体(APC/C)证明了其可行性。我们设计了与APC/C RING结构域结合并有效抑制其活性的支架。通过基于结构的迭代设计和实验研究来优化它们的化学稳定性、渗透性和特异性,从而产生了抑制APC/C的新型基于烃钉的分子,并在癌细胞中得到验证。我们的结果为靶向具有治疗价值的含RING酶提供了有力的理论依据,并为临床APC/C抑制提供了有前景的线索。
