Impact of Silicon Application on Physiochemical Traits of Vigna radiata Exposed to Salinity Stress

Q3 Agricultural and Biological Sciences

Indian Journal Of Agricultural Research Pub Date : 2023-11-24 DOI:10.18805/ijare.a-6150

Sinky, Sapna, Sarita, Meenakshi, Vijay Kumar, Aarti Soni, K. D. Sharma

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引用次数: 0

Abstract

Background: Salinity stress affects crop yields worldwide. Mungbean, a popular grain legume with protein-rich seeds, is glycophytic and vulnerable to saline stress. Silicon has become a key ingredient that boosts plant enzymatic antioxidant activity and osmoprotectant synthesis, promoting stress tolerance. Methods: In chloride-dominated salinity conditions of 4 and 6 dSm-1, sodium meta-silicate administration strategies were examined in salt-affected mungbean (MH421). Two application strategies were used: foliar spraying at 50 mg/l and 100 mg/l at 30 and 45 DAS and soil addition at 50 mg/kg soil as a solution during planting. The effects of these treatments were examined at 33 and 48 DAS, three days following foliar sodium meta-silicate application. Result: Salinity stress reduced dry weight, nodule counts, gas exchange characteristics and plant water relation features, although Si treatment buffered the detrimental effect to a varied amount. Best effects were obtained with 100 ppm foliar application. Lipid peroxidation and electrolyte loss increased with salinity stress, while Si reduces these losses by scavenging free radicals. Silicon supplementation lowered Na+ and increased K+ absorption. Also, Si altered photosynthetic machinery, Na+/K+ homeostasis, osmolyte synthesis and oxidative stress in mungbean to reduce salinity stress and increase seed yield.

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施硅对遭受盐度胁迫的黑木耳理化性状的影响

背景：盐分胁迫影响着全世界的作物产量。绿豆是一种广受欢迎的谷物豆类，种子富含蛋白质，具有糖叶性，易受盐胁迫影响。硅已成为促进植物酶抗氧化活性和渗透保护剂合成、提高抗逆性的关键成分。方法：在以氯化物为主的 4 和 6 dSm-1 盐度条件下，研究了在受盐分影响的绿豆（MH421）中施用偏硅酸钠的策略。采用了两种施用策略：在 30 和 45 DAS 叶面喷施 50 毫克/升和 100 毫克/升，以及在种植期间以 50 毫克/千克土壤的溶液添加到土壤中。在叶面喷施偏硅酸钠后三天，即 33 DAS 和 48 DAS，对这些处理的效果进行了检测。结果盐分胁迫降低了干重、结核数量、气体交换特性和植物水分关系特征，但 Si 处理在不同程度上缓冲了不利影响。叶面喷施 100ppm 的效果最好。脂质过氧化和电解质流失会随着盐胁迫而增加，而硅能清除自由基，从而减少这些损失。补硅能降低 Na+，增加 K+的吸收。此外，硅还能改变绿豆的光合作用机制、Na+/K+平衡、渗透溶质合成和氧化应激，从而减轻盐胁迫并提高种子产量。

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来源期刊

Indian Journal Of Agricultural Research Agricultural and Biological Sciences-Soil Science

CiteScore

1.00

自引率

0.00%

发文量

143