Physiological, metabolic and ionomic responses of Solanum lycopersicum plants to Fe3O4 and FePO4 nanoparticles

IF 7.7

Plant Nano Biology Pub Date : 2025-08-01 DOI:10.1016/j.plana.2025.100182

Valerio Petruccelli , Emanuele Vaccarella , Emma Cocco , Francesco Mura , Domenico Rosa , Alessio Talone , Martina Iazzetta , Chiara Dal Bosco , Alessandra Gentili , Luca Di Palma , Silvia Canepari , Gabriella Pasqua , Elisa Brasili , Lorenzo Massimi

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引用次数: 0

Abstract

Fe₃O₄ (NPS-M) and FePO₄ (NPS-P) nanoparticles, as representative magnetic materials, have been widely used in the industrial and biomedical fields, although their use in agriculture still needs to be evaluated. The effect of NPS-M and NPS-P in tomato plants was investigated by a combination of phenotypic and metabolic approaches. Tomato plants were grown in soil treated with NPS-M and NPS-P at 0, 5, 50, 100, 500 and 1000 ppm for 8 months. Plant biomass, phenolics and carotenoids in leaves and fruits, soil pH, chlorophyll, and ionome of soil, fruits, roots and leaves, were analysed. NPS-M and NPS-P at higher concentrations increased biomass, total chlorophyll and carotenoid levels in leaves compared to controls. NPS-P caused the major soil acidification, making some nutrients more available to the roots. Although no significant differences were observed in fruit carotenoids, a significant increase in chlorogenic and luteone hexoside levels was observed after NPs treatment at low concentrations compared to controls. Inductively coupled plasma mass spectrometry (ICP-MS) revealed that both NPs compared to EDTA-based chelators resulted in differential element accumulation in roots, leaves/fruits. EDTA-based treatments increased leaf accumulation of Cr, As, K, P, while both NPs increased leaf accumulation of Ca, Co, Sr, Ti, V. Fruit accumulation of Ca, K, and Rb was higher with NPs, while Na, Mg, and P were higher with EDTA-based chelators. The obtained results offer new insights into the response of tomato plants to NPS-M and NPS-P exposure and could be useful for designing alternative strategies to the use of commercial fertilizers.

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番茄茄对Fe3O4和FePO4纳米颗粒的生理、代谢和生物学响应

Fe3O4 （NPS-M）和FePO4 （NPS-P）纳米颗粒作为磁性材料的代表，在工业和生物医学领域得到了广泛的应用，但其在农业领域的应用仍有待评价。采用表型和代谢相结合的方法研究了NPS-M和NPS-P对番茄植株的影响。在0、5、50、100、500和1000 ppm浓度的NPS-M和NPS-P处理的土壤中种植番茄植株8个月。分析了植物生物量、叶片和果实中的酚类物质和类胡萝卜素、土壤pH、叶绿素和土壤、果实、根和叶的离子素。与对照相比，较高浓度的NPS-M和NPS-P增加了叶片生物量、总叶绿素和类胡萝卜素水平。NPS-P导致土壤酸化，使一些养分更容易被根系吸收。虽然在水果类胡萝卜素中没有观察到显著差异，但在低浓度NPs处理后，与对照组相比，绿原和叶黄素己糖水平显著增加。电感耦合等离子体质谱（ICP-MS）显示，与edta螯合剂相比，这两种NPs在根、叶/果中的元素积累不同。以edta为基础的螯合剂增加了Cr、As、K、P的叶片积累，而两种NPs均增加了Ca、Co、Sr、Ti、v的叶片积累，果实Ca、K、Rb的积累以NPs为基础的较高，而Na、Mg和P的积累以edta为基础的螯合剂较高。所获得的结果为番茄植株对NPS-M和NPS-P暴露的反应提供了新的见解，并可用于设计商业肥料使用的替代策略。

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来源期刊

Plant Nano Biology

CiteScore

2.80

自引率

0.00%

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