硅对单独和复合氮水亏缺番茄幼苗抗氧化系统的影响

IF 2.2 3区 农林科学 Q2 AGRICULTURE, MULTIDISCIPLINARY
Joana Machado, Ana Patricia G. Fernandes, Boris Bokor, Marek Vaculík, Ep Heuvelink, Susana M. P. Carvalho, Marta W. Vasconcelos
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引用次数: 0

摘要

探索提高作物水和氮利用效率的可持续战略至关重要。据报道,硅(Si)是一种对植物有益的类金属元素,因为它能通过触发植物的抗氧化系统来缓解多种非生物胁迫(包括干旱)。然而,对于硅在减轻氮(N)赤字单独或与水(W)赤字结合造成的负面影响方面的作用,目前还没有很好的研究。本研究将 0 或 2 mM 的 Na₂SiO3 施加到 3 周大的番茄品种 Micro-Tom 幼苗上。Micro-Tom幼苗在以下条件下生长:对照(CTR;100%氮+100%田间持水量)、缺氮(N;50%氮+100%田间持水量)、缺水(W;100%氮+50%田间持水量)或联合胁迫(N+W;50%氮+50%田间持水量)。硅对番茄植株生长的影响取决于胁迫类型。硅只能缓解氮+钾不足造成的胁迫,从而提高根干重(28%)、总干重(23%)和根长(37%)。与此同时,抗氧化(AOX)系统的活性也有所提高,根部抗坏血酸过氧化物酶和过氧化氢酶的活性分别提高了 48% 和 263%。当番茄植株受到个体缺素影响时,施硅也能增强 AOX 酶的活性,但程度较低。总之,经硅处理的番茄植株能在氮和水共同受限的情况下有效调节其 AOX 网络,从而减轻这种综合胁迫的一些不利影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The effect of silicon on the antioxidant system of tomato seedlings exposed to individual and combined nitrogen and water deficit

The effect of silicon on the antioxidant system of tomato seedlings exposed to individual and combined nitrogen and water deficit

Exploring sustainable strategies for improving crop water and nitrogen use efficiency is essential. Silicon (Si) has been reported as a beneficial metalloid for plants since it alleviates several abiotic stresses (including drought) by triggering the plants' antioxidant system. However, its role in mitigating the negative impact of nitrogen (N) deficit alone or when combined with water (W) deficit is not well studied. This study applied 0 or 2 mM of Na₂SiO3 to 3-week-old tomato cv. Micro-Tom seedlings that were grown under the following conditions: control (CTR; 100%N + 100% Field Capacity), N deficit (N; 50% N + 100% Field Capacity), water deficit (W; 100% N + 50% Field Capacity) or combined stress (N + W; 50% N + 50% Field Capacity). The Si effect on tomato plant growth depended on the type of stress. Si could only alleviate stress caused by N + W deficit resulting in a higher root dry weight (by 28%), total dry weight (by 23%) and root length (by 37%). Alongside this, there was an increase in the antioxidant (AOX) system activity with the root activity of ascorbate peroxidase and catalase enzymes being enhanced by 48% and by 263%, respectively. Si application also enhanced AOX enzyme activity when tomato plants were subjected to individual deficits but to a lesser extent. In conclusion, Si-treated tomato plants could efficiently modulate their AOX networks in a situation of combined N and water limitation, thus mitigating some of the adverse effects of this combined stress.

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来源期刊
Annals of Applied Biology
Annals of Applied Biology 生物-农业综合
CiteScore
5.50
自引率
0.00%
发文量
71
审稿时长
18-36 weeks
期刊介绍: Annals of Applied Biology is an international journal sponsored by the Association of Applied Biologists. The journal publishes original research papers on all aspects of applied research on crop production, crop protection and the cropping ecosystem. The journal is published both online and in six printed issues per year. Annals papers must contribute substantially to the advancement of knowledge and may, among others, encompass the scientific disciplines of: Agronomy Agrometeorology Agrienvironmental sciences Applied genomics Applied metabolomics Applied proteomics Biodiversity Biological control Climate change Crop ecology Entomology Genetic manipulation Molecular biology Mycology Nematology Pests Plant pathology Plant breeding & genetics Plant physiology Post harvest biology Soil science Statistics Virology Weed biology Annals also welcomes reviews of interest in these subject areas. Reviews should be critical surveys of the field and offer new insights. All papers are subject to peer review. Papers must usually contribute substantially to the advancement of knowledge in applied biology but short papers discussing techniques or substantiated results, and reviews of current knowledge of interest to applied biologists will be considered for publication. Papers or reviews must not be offered to any other journal for prior or simultaneous publication and normally average seven printed pages.
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