The global integrative network: integration of signaling and metabolic pathways

IF 4.6 4区 农林科学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY aBIOTECH Pub Date : 2022-09-21 DOI:10.1007/s42994-022-00078-1
Yuying Lin, Shen Yan, Xiao Chang, Xiaoquan Qi, Xu Chi
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引用次数: 1

Abstract

The crosstalk between signaling and metabolic pathways has been known to play key roles in human diseases and plant biological processes. The integration of signaling and metabolic pathways can provide an essential reference framework for crosstalk analysis. However, current databases use distinct structures to present signaling and metabolic pathways, which leads to the chaos in the integrated networks. Moreover, for the metabolic pathways, the metabolic enzymes and the reactions are disconnected by the current widely accepted layout of edges and nodes, which hinders the topological analysis of the integrated networks. Here, we propose a novel “meta-pathway” structure, which uses the uniformed structure to display the signaling and metabolic pathways, and resolves the difficulty in linking the metabolic enzymes to the reactions topologically. We compiled a comprehensive collection of global integrative networks (GINs) by merging the meta-pathways of 7077 species. We demonstrated the assembly of the signaling and metabolic pathways using the GINs of four species—human, mouse, Arabidopsis, and rice. Almost all of the nodes were assembled into one major network for each of the four species, which provided opportunities for robust crosstalk and topological analysis, and knowledge graph construction.

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全球整合网络:信号和代谢途径的整合
众所周知,信号传导和代谢途径之间的相互作用在人类疾病和植物生物过程中发挥着关键作用。信号传导和代谢途径的整合可以为串扰分析提供重要的参考框架。然而,目前的数据库使用不同的结构来呈现信号和代谢途径,这导致了集成网络中的混乱。此外,对于代谢途径,代谢酶和反应因当前广泛接受的边缘和节点布局而断开,这阻碍了集成网络的拓扑分析。在这里,我们提出了一种新的“元途径”结构,它使用均匀的结构来显示信号和代谢途径,并解决了将代谢酶与反应拓扑联系起来的困难。我们通过合并7077个物种的元途径,汇编了一个全面的全球整合网络(GINs)集合。我们使用四个物种——人类、小鼠、拟南芥和水稻——的GINs展示了信号和代谢途径的组装。几乎所有的节点都被组装成四个物种中每一个的一个主要网络,这为鲁棒串扰和拓扑分析以及知识图构建提供了机会。
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CiteScore
7.70
自引率
2.80%
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0
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