Curvature-enhanced Graph Convolutional Network for Biomolecular
Interaction Prediction
- URL: http://arxiv.org/abs/2306.13699v1
- Date: Fri, 23 Jun 2023 14:45:34 GMT
- Title: Curvature-enhanced Graph Convolutional Network for Biomolecular
Interaction Prediction
- Authors: Cong Shen, Pingjian Ding, Junjie Wee, Jialin Bi, Jiawei Luo and Kelin
Xia
- Abstract summary: We propose a curvature-enhanced graph convolutional network (CGCN) for biomolecular interaction prediction.
Our CGCN model is extensively validated on fourteen real-world bimolecular interaction networks and a series of simulated data.
- Score: 17.646218316008014
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Geometric deep learning has demonstrated a great potential in non-Euclidean
data analysis. The incorporation of geometric insights into learning
architecture is vital to its success. Here we propose a curvature-enhanced
graph convolutional network (CGCN) for biomolecular interaction prediction, for
the first time. Our CGCN employs Ollivier-Ricci curvature (ORC) to characterize
network local structures and to enhance the learning capability of GCNs. More
specifically, ORCs are evaluated based on the local topology from node
neighborhoods, and further used as weights for the feature aggregation in
message-passing procedure. Our CGCN model is extensively validated on fourteen
real-world bimolecular interaction networks and a series of simulated data. It
has been found that our CGCN can achieve the state-of-the-art results. It
outperforms all existing models, as far as we know, in thirteen out of the
fourteen real-world datasets and ranks as the second in the rest one. The
results from the simulated data show that our CGCN model is superior to the
traditional GCN models regardless of the positive-to-negativecurvature ratios,
network densities, and network sizes (when larger than 500).
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