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HPODNets: deep graph convolutional networks for predicting human protein–phenotype associations

Lizhi Liu, Hiroshi Mamitsuka, Shanfeng Zhu

2021Bioinformatics13 citationsDOIOpen Access PDF

Abstract

MOTIVATION: Deciphering the relationship between human genes/proteins and abnormal phenotypes is of great importance in the prevention, diagnosis and treatment against diseases. The Human Phenotype Ontology (HPO) is a standardized vocabulary that describes the phenotype abnormalities encountered in human disorders. However, the current HPO annotations are still incomplete. Thus, it is necessary to computationally predict human protein-phenotype associations. In terms of current, cutting-edge computational methods for annotating proteins (such as functional annotation), three important features are (i) multiple network input, (ii) semi-supervised learning and (iii) deep graph convolutional network (GCN), whereas there are no methods with all these features for predicting HPO annotations of human protein. RESULTS: We develop HPODNets with all above three features for predicting human protein-phenotype associations. HPODNets adopts a deep GCN with eight layers which allows to capture high-order topological information from multiple interaction networks. Empirical results with both cross-validation and temporal validation demonstrate that HPODNets outperforms seven competing state-of-the-art methods for protein function prediction. HPODNets with the architecture of deep GCNs is confirmed to be effective for predicting HPO annotations of human protein and, more generally, node label ranking problem with multiple biomolecular networks input in bioinformatics. AVAILABILITY AND IMPLEMENTATION: https://github.com/liulizhi1996/HPODNets. SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.

Topics & Concepts

Computer scienceGraphAnnotationPhenotypeProtein function predictionDeep learningConvolutional neural networkArtificial intelligenceRanking (information retrieval)Machine learningComputational biologyData miningProtein functionGeneBiologyTheoretical computer scienceGeneticsBioinformatics and Genomic NetworksBiomedical Text Mining and OntologiesGenomics and Rare Diseases
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