Silicon and arbuscular mycorrhizal species complement in improving soil characteristics, sulfur metabolism and antioxidant defense responses in arsenic stressed Cajanus cajan (L.) Millsp

IF 2.3 4区 农林科学 Q1 AGRONOMY
Shyna Bhalla, A. Bisht, N. Garg
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引用次数: 3

Abstract

ABSTRACT Arsenic (As) is a major soil contaminant that restricts plant growth and metabolism. Silicon-Si and arbuscular mycorrhizae-AM have the potential to impart As stress tolerance. The study assessed relative and cumulative effects of Si and mycorrhizal species; Claroideoglomus etunicatum-M1 and Rhizoglomus intraradices-M2 in alleviating AsV and AsIII toxicities in pigeonpea [Cajanus cajan (L.) Millsp.]. Arsenic reduced mycorrhizal symbiosis, nutrient availability and plant biomass by inducing oxidative stress. Si and AM inoculations decreased metalloid uptake and reactive species generation, with higher benefits under M2, followed by Si, then M1. Higher efficiency of M2 corresponded to its colonization ability and glomalin production as well as its capability of enhancing nutrient uptake by modulating soil enzymes (alkaline phosphate-ALP and arylsulfatase-aryl-S) activities. In addition, S metabolism and antioxidant system got up-regulated, leading to increased synthesis of thiol compounds and antioxidants in the order M2>Si>M1. Accumulated thiols further reduced As translocation by chelating and immobilizing metalloid in plant roots. Moreover, significantly higher As tolerance could be recorded when plants were supplemented with a combination of +Si+M2, indicating functional complementarity between the two amendments. The study, thus, demonstrated introduction of Si and AM in the rhizosphere as a promising strategy for inducing As tolerance to pigeonpea.
硅和丛枝菌根在改善砷胁迫下Cajanus cajan(L.)Millsp的土壤特性、硫代谢和抗氧化防御反应方面发挥互补作用
摘要砷是制约植物生长和代谢的主要土壤污染物。硅和丛枝菌根AM具有赋予As应力耐受性的潜力。该研究评估了硅和菌根物种的相对和累积效应;Claroideoglomus etunicatum-M1和根内根球菌-M2在减轻豌豆中AsV和AsIII毒性方面[Cajanus cajan(L.)Millsp.]。砷通过诱导氧化应激降低菌根共生、养分有效性和植物生物量。Si和AM接种降低了类金属吸收和反应性物种的产生,在M2条件下效益更高,其次是Si,然后是M1。M2的高效性与其定殖能力和glomalin的产生以及通过调节土壤酶(碱性磷酸酶ALP和芳基硫酸酯酶-芳基-S)活性来提高养分吸收的能力相对应。此外,S代谢和抗氧化系统得到上调,导致硫醇化合物和抗氧化剂的合成增加,顺序为M2>Si>M1。积累的硫醇通过螯合和固定植物根系中的类金属进一步减少了As的转运。此外,当用+Si+M2的组合补充植物时,可以记录到显著更高的As耐受性,这表明两种改良剂之间的功能互补性。因此,该研究表明,在根际引入Si和AM是诱导木豆对as耐受的一种有前途的策略。
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来源期刊
CiteScore
5.50
自引率
4.20%
发文量
107
期刊介绍: rchives of Agronomy and Soil Science is a well-established journal that has been in publication for over fifty years. The Journal publishes papers over the entire range of agronomy and soil science. Manuscripts involved in developing and testing hypotheses to understand casual relationships in the following areas: plant nutrition fertilizers manure soil tillage soil biotechnology and ecophysiology amelioration irrigation and drainage plant production on arable and grass land agroclimatology landscape formation and environmental management in rural regions management of natural and created wetland ecosystems bio-geochemical processes soil-plant-microbe interactions and rhizosphere processes soil morphology, classification, monitoring, heterogeneity and scales reuse of waste waters and biosolids of agri-industrial origin in soil are especially encouraged. As well as original contributions, the Journal also publishes current reviews.
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