MoRFs_TransFuse：一个基于多模态特征融合和轻量级Transformer网络的morf预测器。

IF 6.1 3区生物学 Q1 MATHEMATICAL & COMPUTATIONAL BIOLOGY

Biodata Mining Pub Date : 2025-09-29 DOI:10.1186/s13040-025-00481-6

Lele Zhang, Hao He, Xuesen Shi

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引用次数: 0

摘要

分子识别特征（morf）可以通过与它们的蛋白质伴侣结合时经历无序到有序的转变来促进特定的蛋白质相互作用。因此，准确预测morf是至关重要的。在本文中，我们提出了一种基于多模态特征融合和轻量级Transformer网络的创新性morf预测方法——MoRFs_TransFuse。为了构建高质量的生物特征，MoRFs_TransFuse创新地整合了物理化学特性、进化特征和预训练模型嵌入，同时通过多窗口提取和随机森林二次筛选保留最佳特征组合。在架构方面，MoRFs_TransFuse通过使用自注意机制来准确捕获蛋白质序列中的远程残基关联，克服了远程依赖关系建模的局限性。在基准数据集上的对比实验表明，MoRFs_TransFuse显著优于现有的单成分和组合成分预测器。此外，轻量化设计在保证预测精度的同时大大提高了计算效率。

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MoRFs_TransFuse: a MoRFs predictor based on multimodal feature fusion and the lightweight Transformer network.

Molecular recognition features (MoRFs) can facilitate specific protein-protein interactions by undergoing disorder-to-order transitions when binding to their protein partners. Thus, it is essential to accurately predict MoRFs. In this paper, we propose an innovative MoRFs prediction method, named MoRFs_TransFuse, based on multimodal feature fusion and a lightweight Transformer network. To construct high-quality biological features, MoRFs_TransFuse innovatively integrates physicochemical properties, evolutionary features, and pre-trained model embeddings, while retaining optimal feature combinations through multi-window extraction and Random Forest secondary screening. In terms of architecture, MoRFs_TransFuse overcomes the limitations of modeling long-range dependencies by using a self-attention mechanism to accurately capture long-range residue associations in protein sequences. Comparative experiments on benchmark datasets show that MoRFs_TransFuse significantly outperforms existing single component and combined component predictors. Additionally, the lightweight design greatly improves computational efficiency while ensuring prediction accuracy.

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来源期刊

Biodata Mining MATHEMATICAL & COMPUTATIONAL BIOLOGY-

CiteScore

7.90

自引率

0.00%

发文量

审稿时长

23 weeks

期刊介绍： BioData Mining is an open access, open peer-reviewed journal encompassing research on all aspects of data mining applied to high-dimensional biological and biomedical data, focusing on computational aspects of knowledge discovery from large-scale genetic, transcriptomic, genomic, proteomic, and metabolomic data. Topical areas include, but are not limited to: -Development, evaluation, and application of novel data mining and machine learning algorithms. -Adaptation, evaluation, and application of traditional data mining and machine learning algorithms. -Open-source software for the application of data mining and machine learning algorithms. -Design, development and integration of databases, software and web services for the storage, management, retrieval, and analysis of data from large scale studies. -Pre-processing, post-processing, modeling, and interpretation of data mining and machine learning results for biological interpretation and knowledge discovery.