跨细胞类型代谢特征的表观遗传控制

Maria Pires Pacheco, Deborah Gerard, Riley J. Mangan, Alec R. Chapman, Dennis Hecker, Manolis Kellis, Marcel H. Schulz, Lasse Sinkkonen, Thomas Sauter
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引用次数: 0

摘要

基于约束的网络建模是在基因组尺度上分析细胞代谢的有力工具。在这里,我们对从RNA-seq数据重建的代谢网络与国际人类表观基因组联盟(IHEC)的EpiATLAS资源中的成对表观基因组数据进行了综合分析。我们应用最先进的情境化算法,重建了1,555个样本的代谢网络,这些样本对应58种组织和细胞类型。对这些网络的分析揭示了新陈代谢功能在人类细胞类型中的分布,并提供了人类新陈代谢活动汇编。这种综合方法使我们能够在不同组织和细胞类型中定义 i) 实现基本代谢过程的反应(核心代谢),以及 ii) 细胞类型特有的功能(独特代谢),从而形成细胞或组织的代谢特征。与 EpiATLAS 导出的细胞类型特异性基因水平染色质状态和增强子-基因相互作用相结合,确定了控制核心代谢和独特代谢的增强子、转录因子和关键节点。在通路不活跃的细胞类型中,通路的运输和第一反应富含高表达、活跃的染色质状态和多聚酶介导的抑制,这表明关键节点是抑制的目标。这一综合分析为确定控制人类细胞代谢特性的调控点奠定了基础。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Epigenetic control of metabolic identity across cell types
Constraint-based network modelling is a powerful tool for analysing cellular metabolism at genomic scale. Here, we conducted an integrative analysis of metabolic networks reconstructed from RNA-seq data with paired epigenomic data from the EpiATLAS resource of the International Human Epigenome Consortium (IHEC). Applying a state-of-the-art contextualisation algorithm, we reconstructed metabolic networks across 1,555 samples corresponding to 58 tissues and cell types. Analysis of these networks revealed the distribution of metabolic functionalities across human cell types and provides a compendium of human metabolic activity. This integrative approach allowed us to define, across tissues and cell types, i) reactions that fulfil the basic metabolic processes (core metabolism), and ii) cell type-specific functions (unique metabolism), that shape the metabolic identity of a cell or a tissue. Integration with EpiATLAS-derived cell type-specific gene-level chromatin states and enhancer-gene interactions identified enhancers, transcription factors, and key nodes controlling core and unique metabolism. Transport and first reactions of pathways were enriched for high expression, active chromatin state, and Polycomb-mediated repression in cell types where pathways are inactive, suggesting that key nodes are targets of repression. This integrative analysis forms the basis for identifying regulation points that control metabolic identity in human cells.
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