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整合蛋白质组学揭示了人类红细胞生成中动态磷酸化信号网络的原理。

Integrative proteomics reveals principles of dynamic phosphosignaling networks in human erythropoiesis.

机构信息

Department of Proteomics and Signal Transduction, Max Planck Institute of Biochemistry, Martinsried, Germany.

Department of Hematology, St. Jude Children's Research Hospital, Memphis, TN, USA.

出版信息

Mol Syst Biol. 2020 Dec;16(12):e9813. doi: 10.15252/msb.20209813.

DOI:10.15252/msb.20209813
PMID:33259127
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7706838/
Abstract

Human erythropoiesis is an exquisitely controlled multistep developmental process, and its dysregulation leads to numerous human diseases. Transcriptome and epigenome studies provided insights into system-wide regulation, but we currently lack a global mechanistic view on the dynamics of proteome and post-translational regulation coordinating erythroid maturation. We established a mass spectrometry (MS)-based proteomics workflow to quantify and dynamically track 7,400 proteins and 27,000 phosphorylation sites of five distinct maturation stages of in vitro reconstituted erythropoiesis of CD34 HSPCs. Our data reveal developmental regulation through drastic proteome remodeling across stages of erythroid maturation encompassing most protein classes. This includes various orchestrated changes in solute carriers indicating adjustments to altered metabolic requirements. To define the distinct proteome of each maturation stage, we developed a computational deconvolution approach which revealed stage-specific marker proteins. The dynamic phosphoproteomes combined with a kinome-targeted CRISPR/Cas9 screen uncovered coordinated networks of erythropoietic kinases and pinpointed downregulation of c-Kit/MAPK signaling axis as key driver of maturation. Our system-wide view establishes the functional dynamic of complex phosphosignaling networks and regulation through proteome remodeling in erythropoiesis.

摘要

人类红细胞生成是一个高度调控的多步骤发育过程,其失调会导致许多人类疾病。转录组和表观基因组研究提供了对系统范围调控的深入了解,但我们目前缺乏对协调红细胞成熟的蛋白质组和翻译后调控动态的全局机制观点。我们建立了一个基于质谱(MS)的蛋白质组学工作流程,用于定量和动态跟踪体外重构成熟 CD34 HSPCs 红细胞生成的五个不同成熟阶段的 7400 种蛋白质和 27000 个磷酸化位点。我们的数据通过在红细胞成熟阶段的剧烈蛋白质组重塑揭示了发育调控,包括大多数蛋白质类别。这包括各种溶质载体的各种协调变化,表明对代谢需求变化的调整。为了定义每个成熟阶段的独特蛋白质组,我们开发了一种计算去卷积方法,该方法揭示了阶段特异性标记蛋白。动态磷酸蛋白质组学结合针对激酶组的 CRISPR/Cas9 筛选揭示了红细胞生成激酶的协调网络,并确定下调 c-Kit/MAPK 信号轴是成熟的关键驱动因素。我们的系统范围观点确立了复杂磷酸信号网络的功能动态和红细胞生成中通过蛋白质组重塑的调控。

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