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一种拟南芥土壤盐分耐受性突变赋予乙烯介导的钠/钾稳态增强作用。

An Arabidopsis soil-salinity-tolerance mutation confers ethylene-mediated enhancement of sodium/potassium homeostasis.

作者信息

Jiang Caifu, Belfield Eric J, Cao Yi, Smith J Andrew C, Harberd Nicholas P

机构信息

Department of Plant Sciences, University of Oxford, Oxford OX1 3RB, United Kingdom.

出版信息

Plant Cell. 2013 Sep;25(9):3535-52. doi: 10.1105/tpc.113.115659. Epub 2013 Sep 24.

DOI:10.1105/tpc.113.115659
PMID:24064768
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3809548/
Abstract

High soil Na concentrations damage plants by increasing cellular Na accumulation and K loss. Excess soil Na stimulates ethylene-induced soil-salinity tolerance, the mechanism of which we here define via characterization of an Arabidopsis thaliana mutant displaying transpiration-dependent soil-salinity tolerance. This phenotype is conferred by a loss-of-function allele of ethylene overproducer1 (ETO1; mutant alleles of which cause increased production of ethylene). We show that lack of ETO1 function confers soil-salinity tolerance through improved shoot Na/K homeostasis, effected via the ethylene resistant1-constitutive triple response1 ethylene signaling pathway. Under transpiring conditions, lack of ETO1 function reduces root Na influx and both stelar and xylem sap Na concentrations, thereby restricting root-to-shoot delivery of Na. These effects are associated with increased accumulation of respiratory burst oxidase homolog F (RBOHF)-dependent reactive oxygen species in the root stele. Additionally, lack of ETO1 function leads to significant enhancement of tissue K status by an RBOHF-independent mechanism associated with elevated high-affinity K(+) TRANSPORTER5 transcript levels. We conclude that ethylene promotes soil-salinity tolerance via improved Na/K homeostasis mediated by RBOHF-dependent regulation of Na accumulation and RBOHF-independent regulation of K accumulation.

摘要

高土壤钠浓度通过增加细胞内钠积累和钾流失来损害植物。过量的土壤钠刺激乙烯诱导的土壤盐分耐受性,我们通过对一个表现出蒸腾作用依赖的土壤盐分耐受性的拟南芥突变体进行表征来定义其机制。这种表型由乙烯过量产生基因1(ETO1)的功能缺失等位基因赋予(其突变等位基因导致乙烯产量增加)。我们表明,缺乏ETO1功能通过改善地上部钠/钾稳态赋予土壤盐分耐受性,这是通过乙烯抗性1-组成型三重反应1乙烯信号通路实现的。在蒸腾条件下,缺乏ETO1功能会减少根部钠流入以及中柱和木质部汁液中的钠浓度,从而限制钠从根部向地上部的运输。这些效应与根中柱中呼吸爆发氧化酶同源物F(RBOHF)依赖性活性氧的积累增加有关。此外,缺乏ETO1功能通过与高亲和力钾转运体5转录水平升高相关的RBOHF非依赖性机制导致组织钾状态显著增强。我们得出结论,乙烯通过RBOHF依赖性的钠积累调节和RBOHF非依赖性的钾积累调节介导的改善的钠/钾稳态来促进土壤盐分耐受性。

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