Nandipha L Botha, Karen J Cloete, Žiga Šmit, Kristina Isaković, Mahmood Akbari, Razieh Morad, Itani Madiba, Oladipupo Moyinoluwa David, Luis P M Santos, Admire Dube, Primoz Pelicon, Malik Maaza
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Molecular dynamics simulations to investigate the interaction of some active phytocompounds in avocado seeds that act as reducing agents with the nano-digenite further showed that 4-hydroxybenzoic acid had a higher affinity for interacting with the nanoparticle's surface than other active compounds. Seeds treated with the digenite nanoparticles exhibited a unique ionome distribution pattern as determined with external beam proton-induced X-ray emission, with hotspots of Cu and S appearing in the hilum and micropyle area that indicated a possible uptake mechanism via the seed coat. The nano-digenite also triggered a plant stress response by slightly altering seed amino acid metabolism. 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引用次数: 0
摘要
本研究利用台式和离子束分析技术,报告了计算信息和鳄梨种子介导的植物工程纳米 CuS 粒子作为肥料对平托豆种子离子组和氨基酸代谢组的影响。利用扫描电子显微镜、透射电子显微镜、X 射线衍射和傅立叶变换红外光谱对植物工程纳米粒子进行的物理化学分析证实了 CuS 纳米粒子的存在。分子动力学模拟研究了牛油果种子中作为还原剂的一些活性植物化合物与纳米滇铁矿的相互作用,结果进一步表明,与其他活性化合物相比,4-羟基苯甲酸与纳米粒子表面的相互作用亲和力更高。根据外束质子诱导 X 射线发射的测定结果,用纳米迭戈硝石处理过的种子呈现出独特的离子组分布模式,在种脐部和微孔区出现了 Cu 和 S 的热点,这表明可能存在通过种皮吸收的机制。纳米滇铁矿还通过轻微改变种子氨基酸代谢引发了植物胁迫反应。最终,纳米菱锰矿独特的分布模式和对氨基酸代谢的影响表明,它作为种子保护剂或营养剂可能具有重要意义。
Ionome mapping and amino acid metabolome profiling of Phaseolus vulgaris L. seeds imbibed with computationally informed phytoengineered copper sulphide nanoparticles.
This study reports the effects of a computationally informed and avocado-seed mediated Phyto engineered CuS nanoparticles as fertilizing agent on the ionome and amino acid metabolome of Pinto bean seeds using both bench top and ion beam analytical techniques. Physico-chemical analysis of the Phyto engineered nanoparticles with scanning-electron microscopy, transmission electron microscopy, X-ray diffraction, and Fourier Transform Infrared Spectroscopy confirmed the presence of CuS nanoparticles. Molecular dynamics simulations to investigate the interaction of some active phytocompounds in avocado seeds that act as reducing agents with the nano-digenite further showed that 4-hydroxybenzoic acid had a higher affinity for interacting with the nanoparticle's surface than other active compounds. Seeds treated with the digenite nanoparticles exhibited a unique ionome distribution pattern as determined with external beam proton-induced X-ray emission, with hotspots of Cu and S appearing in the hilum and micropyle area that indicated a possible uptake mechanism via the seed coat. The nano-digenite also triggered a plant stress response by slightly altering seed amino acid metabolism. Ultimately, the nano-digenite may have important implications as a seed protective or nutritive agent as advised by its unique distribution pattern and effect on amino acid metabolism.