Multi-domain knowledge graph embeddings for gene-disease association prediction.

IF 1.6 3区工程技术 Q3 MATHEMATICAL & COMPUTATIONAL BIOLOGY

Journal of Biomedical Semantics Pub Date : 2023-08-14 DOI:10.1186/s13326-023-00291-x

Susana Nunes, Rita T Sousa, Catia Pesquita

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引用次数: 0

Abstract

Background: Predicting gene-disease associations typically requires exploring diverse sources of information as well as sophisticated computational approaches. Knowledge graph embeddings can help tackle these challenges by creating representations of genes and diseases based on the scientific knowledge described in ontologies, which can then be explored by machine learning algorithms. However, state-of-the-art knowledge graph embeddings are produced over a single ontology or multiple but disconnected ones, ignoring the impact that considering multiple interconnected domains can have on complex tasks such as gene-disease association prediction.

Results: We propose a novel approach to predict gene-disease associations using rich semantic representations based on knowledge graph embeddings over multiple ontologies linked by logical definitions and compound ontology mappings. The experiments showed that considering richer knowledge graphs significantly improves gene-disease prediction and that different knowledge graph embeddings methods benefit more from distinct types of semantic richness.

Conclusions: This work demonstrated the potential for knowledge graph embeddings across multiple and interconnected biomedical ontologies to support gene-disease prediction. It also paved the way for considering other ontologies or tackling other tasks where multiple perspectives over the data can be beneficial. All software and data are freely available.

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基因疾病关联预测的多领域知识图谱嵌入。

背景:预测基因与疾病的关联通常需要探索不同的信息来源以及复杂的计算方法。知识图嵌入可以通过基于本体中描述的科学知识创建基因和疾病的表示来帮助解决这些挑战，然后可以通过机器学习算法进行探索。然而，最先进的知识图嵌入是在单个本体或多个但不相连的本体上产生的，忽略了考虑多个相互连接的领域可能对复杂任务(如基因-疾病关联预测)的影响。结果:我们提出了一种预测基因-疾病关联的新方法，该方法使用基于知识图嵌入的丰富语义表示，通过逻辑定义和复合本体映射连接多个本体。实验表明，考虑更丰富的知识图可以显著提高基因疾病的预测效果，不同的知识图嵌入方法受益于不同类型的语义丰富度。结论:这项工作证明了跨多个相互关联的生物医学本体的知识图谱嵌入支持基因疾病预测的潜力。它还为考虑其他本体或处理其他任务铺平了道路，在这些任务中，数据的多个透视图可能是有益的。所有软件和数据都是免费提供的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Biomedical Semantics MATHEMATICAL & COMPUTATIONAL BIOLOGY-

CiteScore

4.20

自引率

5.30%

发文量

审稿时长

30 weeks

期刊介绍： Journal of Biomedical Semantics addresses issues of semantic enrichment and semantic processing in the biomedical domain. The scope of the journal covers two main areas: Infrastructure for biomedical semantics: focusing on semantic resources and repositories, meta-data management and resource description, knowledge representation and semantic frameworks, the Biomedical Semantic Web, and semantic interoperability. Semantic mining, annotation, and analysis: focusing on approaches and applications of semantic resources; and tools for investigation, reasoning, prediction, and discoveries in biomedicine.