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锌转运蛋白 5 和锌转运蛋白 9 协同作用于锌/镉摄取。

ZINC TRANSPORTER5 and ZINC TRANSPORTER9 Function Synergistically in Zinc/Cadmium Uptake.

机构信息

Key Laboratory of Agro-Ecological Processes in Subtropical Region, Institute of Subtropical Agriculture, Innovation Academy for Seed Design, Chinese Academy of Sciences, Changsha, 410205, China.

Center for Applied Genetic Technologies, University of Georgia, Athens, Georgia 30602.

出版信息

Plant Physiol. 2020 Jul;183(3):1235-1249. doi: 10.1104/pp.19.01569. Epub 2020 Apr 27.

DOI:10.1104/pp.19.01569
PMID:32341004
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7333683/
Abstract

The elements Zinc (Zn) and cadmium (Cd) have similar chemical and physical properties, but contrasting physiological effects in higher organisms. In plants, Zn/Cd transport is mediated by various transporter proteins belonging to different families. In this study, we functionally characterized two Zn transporter genes in rice (), () and (), which are tandem duplicates and act synergistically in Zn/Cd uptake. Both genes encode plasma membrane-localized proteins with influx transporter activity. The expression profiles of and overlap in the root epidermis and respond to the local Zn status in the root. However, is also regulated by systemic signals of Zn status from the shoot. OsZIP5 functions redundantly to OsZIP9, but has a relatively weaker effect. Plants with the knockout mutations , , or show impaired Zn/Cd uptake. The decreased Zn/Cd levels and growth retardation in the mutant are less severe than in the mutant. However, the double mutant showed an enhanced Zn deficiency phenotype compared with the single mutants, and few double-knockout plants were able to survive the entire growth cycle without excessive Zn supply. Transgenic plants overexpressing had markedly enhanced Zn/Cd levels in the aboveground tissues and brown rice. The results of our study fill a gap in current knowledge of Zn uptake and improve our understanding of Zn/Cd accumulation in rice.

摘要

锌(Zn)和镉(Cd)这两种元素具有相似的化学和物理性质,但在高等生物中却具有相反的生理效应。在植物中,Zn/Cd 的转运是由属于不同家族的各种转运蛋白介导的。在这项研究中,我们对水稻中的两个 Zn 转运基因()、()和()进行了功能表征,它们是串联重复的,在 Zn/Cd 摄取中协同作用。这两个基因都编码具有输入转运体活性的质膜定位蛋白。和的表达谱在根表皮中重叠,并响应根中局部 Zn 状态。然而,也受到来自地上部的 Zn 状态的系统信号的调节。OsZIP5 与 OsZIP9 功能冗余,但作用较弱。缺失突变体、、或的植物表现出 Zn/Cd 摄取受损。与突变体相比,缺失突变体中 Zn/Cd 水平降低和生长迟缓的程度较轻。然而,双突变体与单突变体相比表现出增强的 Zn 缺乏表型,并且很少有双敲除植物能够在没有过量 Zn 供应的情况下存活整个生长周期。过表达的转基因植物在地上组织和糙米中的 Zn/Cd 水平明显升高。我们的研究结果填补了当前 Zn 摄取知识的空白,并提高了我们对水稻中 Zn/Cd 积累的理解。

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