非生物胁迫
纳米材料
串扰
非生物成分
化学
纳米技术
生物物理学
生物逆境
代谢组学
光合作用
重编程
细胞生物学
渗透性休克
生物
氧化应激
材料科学
活性氧
生物化学
茉莉酸
作物生产力
植物发育
拟南芥
植物生长
氧化还原
胞浆
抗氧化剂
渗透调节
作者
Yang Xu,Zhiqiang Sun,Panxin Wang,Qi Wang,Q Li,Xingbo Bian
出处
期刊:Small
[Wiley]
日期:2025-12-30
卷期号:22 (11): e07364-e07364
标识
DOI:10.1002/smll.202507364
摘要
Soil salinity is a critical abiotic stressor that disrupts plant growth by impairing redox balance, membrane stability, and metabolic coordination. While nanomaterials have emerged as promising abiotic stress modulators, the influence of nanoscale architecture on multi-level plant responses remains insufficiently understood. Here, we report the design and application of pinwheel-like α-Fe2O3@Ag nanohybrids, engineered through controlled hydrolysis, ball milling, and high-temperature calcination, to reprogram salt stress responses across physiological and molecular scales. These hybrids exhibit hierarchical anisotropic structures that promote leaf adhesion, cellular uptake, and redox interface activity. Integrated multi-omics analyses reveal that α-Fe2O3@Ag enhances stress tolerance by modulating antioxidant defense, preserving photosynthetic efficiency, and rebalancing osmotic and hormonal pathways. At the molecular level, the nanohybrids induce transcriptomic and metabolomic rewiring across key axes, including unsaturated fatty acid metabolism, sulfur assimilation, hormone signaling (ABA and JA), and protein turnover. This study presents a structure-function-response framework linking nanomaterial morphology to biological outcomes, and highlights the potential of hybrid nanoregulators as versatile tools for enhancing crop resilience under environmental stress. The findings offer conceptual and practical advances for developing next-generation nano-enabled strategies in sustainable agriculture.
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