灵活性(工程)
药物发现
计算生物学
计算机科学
对接(动物)
蛋白质结构
蛋白质-蛋白质相互作用
化学
生物系统
氨基酸残基
分子动力学
结构生物学
血浆蛋白结合
氨基酸
人工智能
蛋白质结构预测
构象集合
钥匙(锁)
蛋白质动力学
蛋白质折叠
动力学(音乐)
生物物理学
纳米技术
蛋白质设计
模型系统
结合亲和力
蛋白质工程
作者
Runze Zhang,Xinyu Jiang,Duanhua Cao,Zhaokun Wang,Jie Yu,Mingan Chen,Zhehuan Fan,Xiangtai Kong,JW Xiong,Zimei Zhang,Wei Zhang,Shengkun Ni,Yitian Wang,Minda Liao,Shenghua Gao,Sulin Zhang,Mingyue Zheng
标识
DOI:10.1073/pnas.2511925122
摘要
Understanding protein structure and dynamics is crucial for basic biology and drug design. Conventional methods often provide static conformations that inadequately capture protein flexibility. We present PackDock, a framework that integrates deep learning and physics-based modeling to represent protein-ligand interactions. PackDock's core, PackPocket, uses diffusion models to sample diverse binding pocket conformations and predict ligand-induced changes. We validate PackDock through side-chain packing, redocking, and cross-docking experiments, demonstrating its ability to address protein flexibility challenges. In a real-world application, PackDock identified nanomolar affinity compounds with unreported scaffolds for the protein of interest. Additionally, it revealed key amino acid conformational changes, offering insights into protein-ligand interactions. By accurately predicting complex conformations in various scenarios, PackDock enhances our understanding of protein dynamics and provides perspectives for both basic biological research and drug discovery efforts.
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