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SICGNN: structurally informed convolutional graph neural networks for protein classificationopen access

Authors
Lee, YongHyunKim, EunchanChoi, JiwoongLee, Changhyun
Issue Date
Dec-2024
Publisher
IOP Publishing
Keywords
graph classification; graph neural network; matrix decomposition; protein classification
Citation
Machine Learning: Science and Technology, v.5, no.4, pp 1 - 21
Pages
21
Indexed
SCIE
SCOPUS
Journal Title
Machine Learning: Science and Technology
Volume
5
Number
4
Start Page
1
End Page
21
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/206134
DOI
10.1088/2632-2153/ad979b
ISSN
2632-2153
2632-2153
Abstract
Recently, graph neural networks (GNNs) have been widely used in various domains, including social networks, recommender systems, protein classification, molecular property prediction, and genetic networks. In bioinformatics and chemical engineering, considerable research is being actively conducted to represent molecules or proteins on graphs by conceptualizing atoms or amino acids as nodes and the relationships between nodes as edges. The overall structures of proteins and their interconnections are crucial for predicting and classifying their properties. However, as GNNs stack more layers to create deeper networks, the embeddings between nodes may become excessively similar, causing an oversmoothing problem that reduces the performance for downstream tasks. To avoid this, GNNs typically use a limited number of layers, which leads to the problem of reflecting only the local structure and neighborhood information rather than the global structure of the graph. Therefore, we propose a structurally informed convolutional GNN (SICGNN) that utilizes information that can express the overall topological structure of a protein graph during GNN training and prediction. By explicitly including information of the entire graph topology, the proposed model can utilize both local neighborhood and global structural information. We applied the SICGNN to representative GNNs such as GraphSAGE, graph isomorphism network, and graph attention network, and confirmed performance improvements across various datasets. We also demonstrate the robustness of SICGNN using multiple stratified 10-fold cross-validations and various hyperparameter settings, and demonstrate that its accuracy is comparable or better than those of existing GNN models.
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