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体内锌毒性表型为大多数果蝇 Zip 和 ZnT 基因提供了一个敏感的背景,提示锌转运活性。

In vivo zinc toxicity phenotypes provide a sensitized background that suggests zinc transport activities for most of the Drosophila Zip and ZnT genes.

机构信息

School of Biological Sciences, Monash University, Wellington Rd, Clayton, VIC, 3800, Australia.

出版信息

J Biol Inorg Chem. 2013 Mar;18(3):323-32. doi: 10.1007/s00775-013-0976-6. Epub 2013 Jan 17.

DOI:10.1007/s00775-013-0976-6
PMID:23322169
Abstract

Members of the ZIP (SLC39A) and ZnT (SLC30A) families of transmembrane domain proteins are predicted to transport the essential transition metal zinc across membranes, regulating cellular zinc content and distribution via uptake and efflux at the outer plasma and organellar membranes. Twenty-four ZIP and ZnT proteins are encoded in mammalian genomes, raising questions of whether all actually transport zinc, whether several function together in the same tissues/cell types, and how the activity of these transporters is coordinated. To address these questions, we have taken advantage of the ability to manipulate several genes simultaneously in targeted cell types in Drosophila. Previously we reported zinc toxicity phenotypes caused by combining overexpression of a zinc uptake gene, dZip42C.1, with suppression of a zinc efflux gene, dZnT63C. Here we show that these phenotypes can be used as a sensitized in vivo system to detect subtle alterations in zinc transport activity that would be buffered in healthy cells. Using two adult tissues, the fly eye and midline (thorax/abdomen), we find that when overexpressed, most of the 17 Drosophila Zip and ZnT genes modify the zinc toxicity phenotypes in a manner consistent with their predicted zinc transport activity. In most cases, we can reconcile that activity with the cellular localization of an enhanced green fluorescent protein tagged version of the protein. Additionally, targeted suppression of each gene by RNA interference reveals several of the fly Zip and ZnT genes are required in the eye, indicating that numerous independent zinc transport genes are acting together in a single tissue.

摘要

ZIP(SLC39A)和 ZnT(SLC30A)家族的跨膜域蛋白成员被预测能够将必需的过渡金属锌跨膜运输,通过在外质膜和细胞器膜上的摄取和外排来调节细胞内锌的含量和分布。哺乳动物基因组中编码了 24 种 ZIP 和 ZnT 蛋白,这引发了以下问题:是否所有的蛋白实际上都运输锌,是否几种蛋白在同一组织/细胞类型中共同发挥作用,以及这些转运蛋白的活性如何协调。为了解决这些问题,我们利用了在果蝇中靶向细胞类型同时操纵多个基因的能力。之前我们报道了锌摄取基因 dZip42C.1 过表达与锌外排基因 dZnT63C 抑制组合引起的锌毒性表型。在这里,我们显示这些表型可以作为一种敏感的体内系统来检测锌转运活性的细微变化,而这些变化在健康细胞中会被缓冲。使用两个成年组织,即果蝇的眼睛和中线(胸部/腹部),我们发现当过表达时,17 种果蝇 Zip 和 ZnT 基因中的大多数以与它们预测的锌转运活性一致的方式修饰锌毒性表型。在大多数情况下,我们可以将该活性与蛋白质的增强型绿色荧光蛋白标记版本的细胞定位相协调。此外,通过 RNA 干扰靶向抑制每个基因揭示了果蝇的一些 Zip 和 ZnT 基因在眼睛中是必需的,这表明许多独立的锌转运基因在单个组织中共同发挥作用。

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