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豌豆的铁效率自然变异与策略 I 机制的上调以及柠檬酸和乙烯合成的增强有关。

Natural variation for Fe-efficiency is associated with upregulation of Strategy I mechanisms and enhanced citrate and ethylene synthesis in Pisum sativum L.

机构信息

School of Biological Sciences, Flinders University, Bedford Park, SA 5042, Australia.

出版信息

Planta. 2012 Jun;235(6):1409-19. doi: 10.1007/s00425-011-1583-9. Epub 2012 Jan 3.

DOI:10.1007/s00425-011-1583-9
PMID:22212907
Abstract

Iron (Fe)-deficiency is a common abiotic stress in Pisum sativum L. grown in many parts of the world. The aim of the study was to investigate variation in tolerance to Fe deficiency in two pea genotypes, Santi (Fe-efficient) and Parafield (Fe-inefficient). Fe deficiency caused greater declines in chlorophyll score, leaf Fe concentration and root-shoot development in Parafield compared to Santi, suggesting greater Fe-efficiency in Santi. Fe chelate reductase activity and ethylene production were increased in the roots of Santi and to a lesser extent in Parafield under Fe deficiency, while proton extrusion was only occurred in Santi. Moreover, expression of the Fe chelate reductase gene, FRO1, and Fe transporter, RIT1 were upregulated in Fe-deficient roots of Santi. Expression of HA1 (proton extrusion) was also significantly higher in Santi when compared to Parafield grown in Fe-deficient conditions. Furthermore, the application of the ethylene biosynthesis inhibitor, 1-aminoisobutyric acid reduced the Fe chelate reductase activity, supporting a direct role for ethylene in its induction. A significant increase in root citrate was only observed in Santi under Fe deficiency indicating a role for citrate in the Fe-efficiency mechanism. Taken together, our physiological and molecular data indicate that genotypic variation in tolerance to Fe deficiency in Santi and Parafield plants is a result of variation in a number of Strategy I mechanisms and also suggest a direct role for ethylene in Fe reductase activity. The pea cultivar, Santi provides a new source of Fe-efficiency that can be exploited to breed more Fe-efficient peas.

摘要

缺铁(Fe)是世界许多地区豌豆(Pisum sativum L.)生长中常见的非生物胁迫。本研究的目的是研究两种豌豆基因型(Santi(Fe 高效)和 Parafield(Fe 低效))对 Fe 缺乏的耐受能力的差异。与 Santi 相比,Fe 缺乏导致 Parafield 的叶绿素评分、叶片 Fe 浓度和根-茎发育下降更大,表明 Santi 具有更高的 Fe 效率。Fe 螯合还原酶活性和乙烯产生在 Santi 和 Parafield 的根中增加,而质子外排仅在 Santi 中发生。此外,Fe 螯合还原酶基因 FRO1 和 Fe 转运蛋白 RIT1 的表达在 Santi 的 Fe 缺乏根中上调。与在 Fe 缺乏条件下生长的 Parafield 相比,HA1(质子外排)的表达在 Santi 中也显著更高。此外,乙烯生物合成抑制剂 1-氨基异丁酸的应用降低了 Fe 螯合还原酶活性,支持乙烯在其诱导中的直接作用。仅在 Santi 下观察到根柠檬酸的显著增加,表明柠檬酸在 Fe 效率机制中起作用。总之,我们的生理和分子数据表明,Santi 和 Parafield 植物对 Fe 缺乏耐受性的基因型差异是多种策略 I 机制差异的结果,并且表明乙烯在 Fe 还原酶活性中具有直接作用。豌豆品种 Santi 提供了一种新的 Fe 高效性来源,可以用来培育更高效的 Fe 豌豆。

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