DisDock：一种金属离子-蛋白质再对接的深度学习方法。

IF 3.2 4区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Proteins-Structure Function and Bioinformatics Pub Date : 2025-01-22 DOI:10.1002/prot.26791

Menghan Lin, Keqiao Li, Yuan Zhang, Feng Pan, Wei Wu, Jinfeng Zhang

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引用次数: 0

摘要

金属蛋白的结构是理解其功能和相互作用的基础。AlphaFold的突破使得以实验精度预测蛋白质结构成为可能。然而，即使有预测的蛋白质结构，金属蛋白所结合的金属离子类型和结合结构仍然不容易得到。在这项研究中，我们提出了DisDock，一种用于预测蛋白质-金属对接的深度学习方法。DisDock以随机初始化的蛋白质配体构型图作为输入，输出预测结合复合物的图。它将U-net体系结构与自关注模块相结合，提高了模型的性能。这个预测器的灵感来自物理原理，即靠近的原子表现出更强的相互吸引力，它利用几何信息来揭示指示原子相互作用的潜在特征。为了训练我们的模型，我们使用了来自所有数据库之母（MOAD）的高质量金属蛋白数据集。实验结果表明，我们的方法在各种类型金属离子的预测精度上优于其他现有方法。

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DisDock: A Deep Learning Method for Metal Ion-Protein Redocking.

The structures of metalloproteins are essential for comprehending their functions and interactions. The breakthrough of AlphaFold has made it possible to predict protein structures with experimental accuracy. However, the type of metal ion that a metalloprotein binds and the binding structure are still not readily available, even with the predicted protein structure. In this study, we present DisDock, a deep learning method for predicting protein-metal docking. DisDock takes distogram of randomly initialized protein-ligand configuration as input and outputs the distogram of the predicted binding complex. It combines the U-net architecture with self-attention modules to enhance model performance. Taking inspiration from the physical principle that atoms in closer proximity display a stronger mutual attraction, this predictor capitalizes on geometric information to uncover latent characteristics indicative of atom interactions. To train our model, we employ a high-quality metalloprotein dataset sourced from the Mother of All Databases (MOAD). Experimental results demonstrate that our approach outperforms other existing methods in prediction accuracy for various types of metal ions.

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来源期刊

Proteins-Structure Function and Bioinformatics 生物-生化与分子生物学

CiteScore

5.90

自引率

3.40%

发文量

172

审稿时长

3 months

期刊介绍： PROTEINS : Structure, Function, and Bioinformatics publishes original reports of significant experimental and analytic research in all areas of protein research: structure, function, computation, genetics, and design. The journal encourages reports that present new experimental or computational approaches for interpreting and understanding data from biophysical chemistry, structural studies of proteins and macromolecular assemblies, alterations of protein structure and function engineered through techniques of molecular biology and genetics, functional analyses under physiologic conditions, as well as the interactions of proteins with receptors, nucleic acids, or other specific ligands or substrates. Research in protein and peptide biochemistry directed toward synthesizing or characterizing molecules that simulate aspects of the activity of proteins, or that act as inhibitors of protein function, is also within the scope of PROTEINS. In addition to full-length reports, short communications (usually not more than 4 printed pages) and prediction reports are welcome. Reviews are typically by invitation; authors are encouraged to submit proposed topics for consideration.