Engineering a Cell-Based Orthogonal Ubiquitin Transfer Cascade for Profiling the Substrates of RBR E3 Parkin

Shuai Fang, Li Zhou, Geng Chen, Xiaoyu Wang, In Ho Jeong, Savannah E Jacobs, Bradley R. Kossmann, Wei Wei, Jing Zhang, Geon Jeong, Ivaylo Ivanov, Angela M Mabb, Hiroaki Kiyokawa, Bo Zhao, Jun Yin
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Abstract

The E3 ubiquitin (UB) ligase Parkin utilizes a Ring-Between-Ring (RBR) domain to mediate the transfer of UB to its substrates to regulate diverse cellular functions, including mitochondrial quality control, cell cycle progression, metabolism programming, and the establishment of synaptic functions. Mutations affecting the E3 ligase activity of Parkin are associated with cancer and Parkinson's disease (PD). An essential role of Parkin is to synthesize UB chains on the surface of damaged mitochondria to initiate mitophagy. Still, it is not clear how Parkin carries out other biological functions through the ubiquitination of its downstream targets in the cell. We hypothesized that a comprehensive substrate profile of Parkin would facilitate the discovery of ubiquitination pathways underpinning its multifaceted roles in cell regulation and reveal mechanistic linkages between Parkin malfunction and disease development. Here, we used phage display to assemble an orthogonal ubiquitin transfer (OUT) cascade of Parkin that can exclusively deliver an engineered UB mutant (xUB) to Parkin and its substrates in living cells. We then generated a substrate profile of Parkin by purifying xUB-conjugated proteins from cells and identifying them by proteomics. The OUT screen identified Parkin substrates involved in DNA replication, protein translation, intracellular protein transport, and rhythmic regulation. Based on previous literature implicating alterations in membrane vesicle trafficking in PD, we verified Parkin-catalyzed ubiquitination of Rab GTPases (Rab1a, Rab5a, Rab5c, Rab7a, Rab8a, Rab10, an Rab13) as well as CDK5, with reconstituted ubiquitination reactions in vitro and in cells. We also found chemical-induced stimulation of mitophagy enhanced Parkin-mediated ubiquitination of Rab proteins. These findings demonstrate that the OUT cascade of Parkin can serve as an empowering tool for identifying Parkin substrates to elucidate its cellular functions.
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设计一种基于细胞的正交泛素转移级联,用于分析 RBR E3 Parkin 的底物
E3 泛素(UB)连接酶 Parkin 利用环间环(RBR)结构域介导 UB 向其底物的转移,从而调节多种细胞功能,包括线粒体质量控制、细胞周期进展、新陈代谢编程和突触功能的建立。影响 Parkin E3 连接酶活性的突变与癌症和帕金森病(PD)有关。Parkin 的一个重要作用是在受损线粒体表面合成 UB 链,以启动有丝分裂。然而,目前还不清楚Parkin如何通过泛素化细胞中的下游靶标来实现其他生物功能。我们假设,全面的 Parkin 底物图谱将有助于发现支撑其在细胞调控中多方面作用的泛素化途径,并揭示 Parkin 功能失常与疾病发展之间的机理联系。在这里,我们利用噬菌体展示技术组装了Parkin的正交泛素转运(OUT)级联,该级联可以在活细胞中将工程UB突变体(xUB)专门传递给Parkin及其底物。然后,我们从细胞中纯化 xUB 连接的蛋白质,并通过蛋白质组学鉴定它们,从而生成了 Parkin 的底物图谱。OUT 筛选确定了参与 DNA 复制、蛋白质翻译、细胞内蛋白质转运和节律调节的 Parkin 底物。基于之前有文献指出帕金森病与膜囊泡运输的改变有关,我们在体外和细胞中通过重组泛素化反应验证了帕金催化的 Rab GTP 酶(Rab1a、Rab5a、Rab5c、Rab7a、Rab8a、Rab10 和 Rab13)以及 CDK5 的泛素化。我们还发现,化学物质诱导的有丝分裂刺激增强了 Parkin 介导的 Rab 蛋白泛素化。这些研究结果表明,Parkin 的 OUT 级联可作为鉴定 Parkin 底物以阐明其细胞功能的有力工具。
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