拟南芥中高灵敏度的特异性 SUMOylation 蛋白质组学。

Highly sensitive site-specific SUMOylation proteomics in Arabidopsis.

机构信息

Institute of Advanced Biotechnology and School of Medicine, Southern University of Science and Technology, Shenzhen, China.

Shanghai Center for Plant Stress Biology, CAS Center for Excellence in Molecular Plant Sciences, Chinese Academy of Sciences, Shanghai, China.

出版信息

Nat Plants. 2024 Sep;10(9):1330-1342. doi: 10.1038/s41477-024-01783-z. Epub 2024 Sep 18.

DOI:10.1038/s41477-024-01783-z

PMID:39294263

Abstract

SUMOylation-the attachment of a small ubiquitin-like modifier (SUMO) to target proteins-plays roles in controlling plant growth, nutrient signalling and stress responses. SUMOylation studies in plants are scarce because identifying SUMOylated proteins and their sites is challenging. To date, only around 80 SUMOylation sites have been identified. Here we introduce lysine-null SUMO1 into the Arabidopsis sumo1 sumo2 mutant and establish a two-step lysine-null SUMO enrichment method. We identified a site-specific SUMOylome comprising over 2,200 SUMOylation sites from 1,300 putative acceptors that function in numerous nuclear processes. SUMOylation marks occur on several motifs, differing from the canonical ψKxE motif in distant eukaryotes. Quantitative comparisons demonstrate that SUMOylation predominantly enhances the stability of SUMO1 acceptors. Our study delivers a highly sensitive and efficient method for site-specific SUMOylome studies and provides a comprehensive catalogue of Arabidopsis SUMOylation, serving as a valuable resource with which to further explore how SUMOylation regulates protein function.

摘要

SUMOylation——将一个小的泛素样修饰物（SUMO）连接到靶蛋白上——在控制植物生长、营养信号和应激反应中发挥作用。由于鉴定 SUMO 化蛋白及其位点具有挑战性，因此植物中的 SUMOylation 研究很少。迄今为止，仅鉴定了约 80 个 SUMO 化位点。在这里，我们将赖氨酸缺失的 SUMO1 引入拟南芥 sumo1sumo2 突变体中，并建立了两步赖氨酸缺失 SUMO 富集方法。我们从 1300 个假定的接受体中鉴定出一个具有 2200 多个位点的特异性 SUMO 组蛋白，这些接受体在许多核过程中发挥作用。SUMO 化标记出现在几个基序上，与远距离真核生物中的典型 ψKxE 基序不同。定量比较表明，SUMOylation 主要增强了 SUMO1 接受体的稳定性。我们的研究提供了一种用于特异性 SUMO 组蛋白研究的高度敏感和有效的方法，并提供了一个全面的拟南芥 SUMOylation 目录，作为进一步探索 SUMOylation 如何调节蛋白质功能的宝贵资源。

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拟南芥中高灵敏度的特异性 SUMOylation 蛋白质组学。

Highly sensitive site-specific SUMOylation proteomics in Arabidopsis.

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