mosGraphGen:一种生成多组学信号图的新型工具,有助于开发具有综合性和可解释性的图形人工智能模型。

IF 2.4 Q2 MATHEMATICAL & COMPUTATIONAL BIOLOGY Bioinformatics advances Pub Date : 2024-10-08 eCollection Date: 2024-01-01 DOI:10.1093/bioadv/vbae151
Heming Zhang, Dekang Cao, Zirui Chen, Xiuyuan Zhang, Yixin Chen, Cole Sessions, Carlos Cruchaga, Philip Payne, Guangfu Li, Michael Province, Fuhai Li
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引用次数: 0

摘要

动因:多组学数据,即基因组学、表观基因组学、转录组学、蛋白质组学,从多层次、多视角描述了细胞复杂信号系统的特征,提供了复杂细胞信号通路的整体视图。然而,如何整合和解释多组学数据以挖掘关键的生物标志物仍是一项挑战。图人工智能模型已被广泛用于分析图结构数据集,是整合多组学数据分析的理想选择,因为它能自然地将多组学数据整合并表示为具有生物学意义的多层次信号图,并通过图节点和边的排序分析来解释多组学数据。然而,对于图人工智能模型开发者来说,预先分析多组学数据并将数据转换为具有生物学意义的图,从而直接输入图人工智能模型,并非易事:为了解决这一难题,我们开发了mosGraphGen(多组学信号图生成器),通过将多组学数据映射到具有生物学意义的多层次背景信号网络上,并通过聚合测量数据和与参考基因组对齐进行数据归一化,生成单个样本的多组学信号图(mos-graph)。有了mosGraphGen,人工智能模型开发人员就可以直接使用这些mos图来应用和评估他们的模型。在研究结果中,mosGraphGen被用于癌症基因组图谱(TCGA)和阿尔茨海默病(AD)样本这两个广泛使用的多组学数据集,并进行了说明:mosGraphGen的代码是开源的,可通过GitHub公开获取:https://github.com/FuhaiLiAiLab/mosGraphGen。
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mosGraphGen: a novel tool to generate multi-omics signaling graphs to facilitate integrative and interpretable graph AI model development.

Motivation: Multi-omics data, i.e. genomics, epigenomics, transcriptomics, proteomics, characterize cellular complex signaling systems from multi-level and multi-view and provide a holistic view of complex cellular signaling pathways. However, it remains challenging to integrate and interpret multi-omics data for mining critical biomarkers. Graph AI models have been widely used to analyze graph-structure datasets, and are ideal for integrative multi-omics data analysis because they can naturally integrate and represent multi-omics data as a biologically meaningful multi-level signaling graph and interpret multi-omics data via graph node and edge ranking analysis. Nevertheless, it is nontrivial for graph-AI model developers to pre-analyze multi-omics data and convert the data into biologically meaningful graphs, which can be directly fed into graph-AI models.

Results: To resolve this challenge, we developed mosGraphGen (multi-omics signaling graph generator), generating Multi-omics Signaling graphs (mos-graph) of individual samples by mapping multi-omics data onto a biologically meaningful multi-level background signaling network with data normalization by aggregating measurements and aligning to the reference genome. With mosGraphGen, AI model developers can directly apply and evaluate their models using these mos-graphs. In the results, mosGraphGen was used and illustrated using two widely used multi-omics datasets of The Cancer Genome Atlas (TCGA) and Alzheimer's disease (AD) samples.

Availability and implementation: The code of mosGraphGen is open-source and publicly available via GitHub: https://github.com/FuhaiLiAiLab/mosGraphGen.

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