标杆管理
概化理论
水准点(测量)
灵活性(工程)
折叠(DSP实现)
蛋白质结构预测
集合(抽象数据类型)
计算机科学
计算生物学
数据挖掘
相似性(几何)
肽
机器学习
人工智能
蛋白质结构
化学
业务
生物化学
生物
工程类
数学
营销
统计
大地测量学
电气工程
图像(数学)
程序设计语言
地理
作者
Silong Zhai,Huifeng Zhao,Jike Wang,Shaolong Lin,T. Liu,Shukai Gu,Dejun Jiang,Huanxiang Liu,Yu Kang,Xiaojun Yao,Tingjun Hou
标识
DOI:10.1021/acs.jcim.5c01084
摘要
Accurate modeling of protein-peptide interactions is essential for understanding fundamental biological processes and designing peptide-based drugs. However, predicting the complex structures of these interactions remains challenging, primarily due to the high conformational flexibility of peptides. To support a fair and systematic evaluation of recent deep learning (DL) approaches, we introduce PepPCBench, a benchmarking framework tailored to assess protein folding neural networks (PFNNs) in protein-peptide complex prediction. As part of this framework, we curated PepPCSet, a data set of 261 experimentally resolved complexes with peptides ranging from 5 to 30 residues. We benchmark five full-atom PFNNs, including AlphaFold3 (AF3), AlphaFold-Multimer (AFM), Chai-1, HelixFold3 (HF3), and RoseTTAFold-All-Atom (RFAA), using comprehensive evaluation metrics. Our benchmarking reveals meaningful performance differences among these methods and highlights the influence of peptide length, conformational flexibility, and training set similarity on prediction accuracy. While AF3 shows strong performance in structure prediction, further analysis indicates that confidence metrics correlate poorly with experimental binding affinities, underscoring the need for improved scoring strategies and generalizability. By providing a reproducible and extensible framework, PepPCBench enables a robust evaluation of PFNN-based methods and supports their continued development for peptide-protein structure prediction.
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