Drought affects Fe deficiency-induced responses in a purple durum wheat (Triticum turgidum subsp. durum) genotype.

IF 4.2 3区生物学 Q1 PLANT SCIENCES

Plant Biology Pub Date : 2025-03-17 DOI:10.1111/plb.70012

G Quagliata, M D G Molina, G Mannino, E Coppa, M N Saidi, S Palombieri, F Sestili, G Vigani, S Astolfi

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引用次数: 0

Abstract

Iron (Fe) is essential for plants and humans, with over 2 billion people suffering deficiency disorders because most plant foods, including cereals, are low in Fe. Durum wheat, a staple crop in Mediterranean regions, is facing increased droughts, which reduce plant yield and ability to acquire and use Fe. Therefore, understanding mechanisms underlying Fe acquisition and accumulation in durum wheat under drought is essential for both agronomic and nutritional purposes. Here, a durum wheat (Triticum turgidum subsp. durum) genotype with a purple grain pericarp was grown hydroponically under adequate (80 μM) or limited (10 μM) Fe, with or without water stress (induced with 10% PEG 6000) for 6 days. Fe accumulation decreased under Fe deficiency and drought, with the highest phytosiderophore (PS) release in Fe-deficient plants. Interestingly, despite adequate Fe availability, drought inhibited Fe accumulation in roots. This response was accompanied by increased release of PS from roots, although the increase was less than that observed with single or combined Fe deficiency. Both TdIRT1 and TdYS15 were upregulated by Fe deficiency but downregulated by drought and the combined stress. Drought stress and Fe deficiency led to increased ABA production, being 250-fold higher with respect to controls. TdIRT1 downregulation in plants exposed to the combined stress suggests a trade-off between water and Fe stress responses. Our findings demonstrate that the response to combined stress differs from, and is rarely additive to, the response to a single stressor, reinforcing the complexity of plant adaptation to combined environmental stresses.

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干旱对紫硬粒小麦（Triticum turgidum subsp）缺铁诱导的响应有影响。硬质)基因型。

铁（Fe）对植物和人类至关重要，超过20亿人患有缺乏性疾病，因为大多数植物性食物，包括谷物，铁含量低。硬粒小麦是地中海地区的一种主要作物，正面临日益严重的干旱，这降低了作物产量和获取和利用铁的能力。因此，了解干旱条件下硬粒小麦铁的获取和积累机制对农艺和营养都有重要意义。这里，硬粒小麦(Triticum turgidum subsp。在足够（80 μM）或有限（10 μM） Fe条件下，有或没有水分胁迫（10% PEG 6000诱导），水培培养6天。缺铁和干旱条件下，铁积累量减少，缺铁植株释出的植物铁素（PS）最高。有趣的是，尽管铁的有效性充足，干旱却抑制了铁在根系中的积累。这一反应伴随着根系PS释放的增加，尽管增幅小于单一或联合缺铁情况下的增幅。TdIRT1和TdYS15在缺铁条件下表达上调，在干旱和综合胁迫下表达下调。干旱胁迫和缺铁导致ABA产量增加，比对照高出250倍。暴露在联合胁迫下的植物TdIRT1下调表明水和铁胁迫反应之间存在权衡。我们的研究结果表明，植物对复合胁迫的反应不同于对单一胁迫的反应，而且很少是附加的，这加强了植物对复合环境胁迫的适应的复杂性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Plant Biology 生物-植物科学

CiteScore

8.20

自引率

2.60%

发文量

109

审稿时长

3 months

期刊介绍： Plant Biology is an international journal of broad scope bringing together the different subdisciplines, such as physiology, molecular biology, cell biology, development, genetics, systematics, ecology, evolution, ecophysiology, plant-microbe interactions, and mycology. Plant Biology publishes original problem-oriented full-length research papers, short research papers, and review articles. Discussion of hot topics and provocative opinion articles are published under the heading Acute Views. From a multidisciplinary perspective, Plant Biology will provide a platform for publication, information and debate, encompassing all areas which fall within the scope of plant science.