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鞭毛靶向精氨酸激酶需要保守的脂化蛋白鞭毛内运输 (LIFT) 途径。

Flagellar targeting of an arginine kinase requires a conserved lipidated protein intraflagellar transport (LIFT) pathway in .

机构信息

Department of Biological Sciences, National University of Singapore, Singapore.

Department of Biological Sciences, National University of Singapore, Singapore

出版信息

J Biol Chem. 2020 Aug 7;295(32):11326-11336. doi: 10.1074/jbc.RA120.014287. Epub 2020 Jun 25.

DOI:10.1074/jbc.RA120.014287
PMID:32587088
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7415996/
Abstract

Both intraflagellar transport (IFT) and lipidated protein intraflagellar transport (LIFT) pathways are essential for cilia/flagella biogenesis, motility, and sensory functions. In the LIFT pathway, lipidated cargoes are transported into the cilia through the coordinated actions of cargo carrier proteins such as Unc119 or PDE6δ, as well as small GTPases Arl13b and Arl3 in the cilium. Our previous studies have revealed a single Arl13b ortholog in the evolutionarily divergent , the causative agent of African sleeping sickness. TbArl13 catalyzes two TbArl3 homologs, TbArl3A and TbArl3C, suggesting the presence of a conserved LIFT pathway in these protozoan parasites. Only a single homolog to the cargo carrier protein Unc119 has been identified in genome, but its function in lipidated protein transport has not been characterized. In this study, we exploited the proximity-based biotinylation approach to identify binding partners of TbUnc119. We showed that TbUnc119 binds to a flagellar arginine kinase TbAK3 in a myristoylation-dependent manner and is responsible for its targeting to and enrichment in the flagellum. Interestingly, only TbArl3A, but not TbArl3C interacted with TbUnc119 in a GTP-dependent manner, suggesting functional specialization of Arl3-GTPases in These results establish the function of TbUnc119 as a myristoylated cargo carrier and support the presence of a conserved LIFT pathway in

摘要

动纤毛运输(IFT)和脂化蛋白动纤毛运输(LIFT)途径对于纤毛/鞭毛的发生、运动和感觉功能都是必不可少的。在 LIFT 途径中,脂化货物通过货物载体蛋白(如 Unc119 或 PDE6δ)以及小 GTP 酶 Arl13b 和 Arl3 在纤毛中的协调作用被运输到纤毛中。我们之前的研究揭示了一个在进化上有分歧的,即引起非洲昏睡病的病原体中的单个 Arl13b 同源物。TbArl13 催化两个 TbArl3 同源物,TbArl3A 和 TbArl3C,表明在这些原生动物寄生虫中存在保守的 LIFT 途径。在 基因组中只鉴定出一个货物载体蛋白 Unc119 的同源物,但它在脂化蛋白运输中的功能尚未被表征。在这项研究中,我们利用基于邻近的生物素化方法来鉴定 TbUnc119 的结合伙伴。我们表明,TbUnc119 以依赖于豆蔻酰化的方式与鞭毛精氨酸激酶 TbAK3 结合,并负责其靶向和在鞭毛中的富集。有趣的是,只有 TbArl3A,而不是 TbArl3C 以 GTP 依赖的方式与 TbUnc119 相互作用,这表明 Arl3-GTP 酶在 中的功能专业化。这些结果确立了 TbUnc119 作为豆蔻酰化货物载体的功能,并支持在 中存在保守的 LIFT 途径。

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