Abstract
BackgroundMolecular interaction networks summarize complex biological processes as graphs, whose structure is informative of biological function at multiple scales. Simultaneously, omics technologies measure the variation or activity of genes, proteins, or metabolites across individuals or experimental conditions. Integrating the complementary viewpoints of biological networks and omics data is an important task in bioinformatics, but existing methods treat networks as discrete structures, which are intrinsically difficult to integrate with continuous node features or activity measures. Graph neural networks map graph nodes into a low-dimensional vector space representation, and can be trained to preserve both the local graph structure and the similarity between node features.ResultsWe studied the representation of transcriptional, protein–protein and genetic interaction networks in E. coli and mouse using graph neural networks. We found that such representations explain a large proportion of variation in gene expression data, and that using gene expression data as node features improves the reconstruction of the graph from the embedding. We further proposed a new end-to-end Graph Feature Auto-Encoder framework for the prediction of node features utilizing the structure of the gene networks, which is trained on the feature prediction task, and showed that it performs better at predicting unobserved node features than regular MultiLayer Perceptrons. When applied to the problem of imputing missing data in single-cell RNAseq data, the Graph Feature Auto-Encoder utilizing our new graph convolution layer called FeatGraphConv outperformed a state-of-the-art imputation method that does not use protein interaction information, showing the benefit of integrating biological networks and omics data with our proposed approach.ConclusionOur proposed Graph Feature Auto-Encoder framework is a powerful approach for integrating and exploiting the close relation between molecular interaction networks and functional genomics data.
Highlights
Biological networks of genetic, transcriptional, protein–protein, or metabolic interactions summarize complex biological processes as graphs, whose structure or topology is informative of biological function at multiple scales
We propose the framework of graph alone (Graph) Feature Auto-Encoder (GFAE) for the prediction of expression values utilizing gene network structures, and introduce a new convolution layer named FeatGraphConv using a message passing neural networks (MPNNs) framework, tailored to reconstructing the representation of the node features rather than the graph structure
Graph structural embeddings reconstruct gene networks and explain variation in gene expression We obtained low-dimensional embeddings of transcriptional regulatory (TF_net), protein–protein interaction (PPI) and genetic interaction networks in E. coli and a Protein–protein interaction (PPI) network in mouse (MPPI), with and without using expression data as node features, and trained the Graph Auto-Encoder (GAE) to optimize the reconstruction of the original graph from the node embedding
Summary
Biological networks of genetic, transcriptional, protein–protein, or metabolic interactions summarize complex biological processes as graphs, whose structure or topology is informative of biological function at multiple scales. Genomics, transcriptomics, proteomics, and metabolomics technologies measure the variation or activity of genes, proteins, or metabolites across individuals or experimental conditions [4, 5]. Existing methods treat biological networks as discrete structures, which are intrinsically difficult to integrate with continuous node features or activity measures. Molecular interaction networks summarize complex biological processes as graphs, whose structure is informative of biological function at multiple scales. Omics technologies measure the variation or activity of genes, proteins, or metabolites across individuals or experimental conditions. Integrating the complementary viewpoints of biological networks and omics data is an important task in bioinformatics, but existing methods treat networks as discrete structures, which are intrinsically difficult to integrate with continuous node features or activity measures. Graph neural networks map graph nodes into a low-dimensional vector space representation, and can be trained to preserve both the local graph structure and the similarity between node features
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