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鞭毛内运输蛋白IFT57是纤毛维持所必需的,并在脊椎动物光感受器中调节IFT颗粒与驱动蛋白-II的解离。

The intraflagellar transport protein IFT57 is required for cilia maintenance and regulates IFT-particle-kinesin-II dissociation in vertebrate photoreceptors.

作者信息

Krock Bryan L, Perkins Brian D

机构信息

Department of Biology, Texas A&M University, College Station, TX 77843, USA.

出版信息

J Cell Sci. 2008 Jun 1;121(11):1907-15. doi: 10.1242/jcs.029397.

DOI:10.1242/jcs.029397
PMID:18492793
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2637114/
Abstract

Defects in protein transport within vertebrate photoreceptors can result in photoreceptor degeneration. In developing and mature photoreceptors, proteins targeted to the outer segment are transported through the connecting cilium via the process of intraflagellar transport (IFT). In studies of vertebrate IFT, mutations in any component of the IFT particle typically abolish ciliogenesis, suggesting that IFT proteins are equally required for IFT. To determine whether photoreceptor outer segment formation depends equally on individual IFT proteins, we compared the retinal phenotypes of IFT57 and IFT88 mutant zebrafish. IFT88 mutants failed to form outer segments, whereas IFT57 mutants formed short outer segments with reduced amounts of opsin. Our phenotypic analysis revealed that IFT57 is not essential for IFT, but is required for efficient IFT. In co-immunoprecipitation experiments from whole-animal extracts, we determined that kinesin II remained associated with the IFT particle in the absence of IFT57, but IFT20 did not. Additionally, kinesin II did not exhibit ATP-dependent dissociation from the IFT particle in IFT57 mutants. We conclude that IFT20 requires IFT57 to associate with the IFT particle and that IFT57 and/or IFT20 mediate kinesin II dissociation.

摘要

脊椎动物光感受器内蛋白质运输缺陷可导致光感受器退化。在发育中和成熟的光感受器中,靶向至外段的蛋白质通过鞭毛内运输(IFT)过程经连接纤毛进行运输。在脊椎动物IFT的研究中,IFT颗粒任何组分的突变通常都会消除纤毛发生,这表明IFT蛋白对于IFT同样是必需的。为了确定光感受器外段形成是否同样依赖于单个IFT蛋白,我们比较了IFT57和IFT88突变斑马鱼的视网膜表型。IFT88突变体无法形成外段,而IFT57突变体形成了短的外段,视蛋白含量减少。我们的表型分析表明,IFT57对于IFT不是必需的,但对于高效IFT是必需的。在来自全动物提取物的共免疫沉淀实验中,我们确定在没有IFT57的情况下驱动蛋白II仍与IFT颗粒相关联,但IFT20并非如此。此外,在IFT57突变体中,驱动蛋白II并未表现出从IFT颗粒的ATP依赖性解离。我们得出结论,IFT20需要IFT57才能与IFT颗粒相关联,并且IFT57和/或IFT20介导驱动蛋白II的解离。

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