Node-adaptive graph Transformer with structural encoding for accurate and robust lncRNA-disease association prediction

Li, Guanghui; Bai, Peihao; Liang, Cheng; Luo, Jiawei

doi:10.1186/s12864-024-09998-2

Cited by 11 publications

(1 citation statement)

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“…GCLMTP 52 explores lncRNA and disease node features using graph Contrastive Learning and uses machine learning classifiers for association classification. NAGTLDA 53 utilized GCN to explore potential global and local features, and utilized Transformer's attention mechanism for feature fusion.…”

Section: Performance Comparisonsmentioning

confidence: 99%

Predicting lncRNA–Disease Associations Based on a Dual-Path Feature Extraction Network with Multiple Sources of Information Integration

Yao,

Zhang,

Zhan

et al. 2024

ACS Omega

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Identifying the associations between long noncoding RNAs (lncRNAs) and disease is critical for disease prevention, diagnosis and treatment. However, conducting wet experiments to discover these associations is time-consuming and costly. Therefore, computational modeling for predicting lncRNA-disease associations (LDAs) has become an important alternative. To enhance the accuracy of LDAs prediction and alleviate the issue of node feature oversmoothing when exploring the potential features of nodes using graph neural networks, we introduce DPFELDA, a dual-path feature extraction network that leverages the integration of information from multiple sources to predict LDA. Initially, we establish a dual-view structure of lncRNAs and disease and a heterogeneous network of lncRNA-disease-microRNA (miRNA) interactions. Subsequently, features are extracted using a dual-path feature extraction network. In particular, we employ a combination of a graph convolutional network, a convolutional block attention module, and a node aggregation layer to perform multilayer topology feature extraction for the dual-view structure of lncRNAs and diseases. Additionally, we utilize a Transformer model to construct the node topology feature residual network for obtaining node-specific features in heterogeneous networks. Finally, XGBoost is employed for LDA prediction. The experimental results demonstrate that DPFELDA outperforms the benchmark model on various benchmark data sets. In the course of model exploration, it becomes evident that DPFELDA successfully alleviates the issue of node feature oversmoothing induced by graph-based learning. Ablation experiments confirm the effectiveness of the innovative module, and a case study substantiates the accuracy of DPFELDA model in predicting novel LDAs for characteristic diseases.

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Section: Performance Comparisonsmentioning

confidence: 99%