Nanoselenium inhibits chromium toxicity in wheat plants by modifying the antioxidant defense system, ascorbate glutathione cycle, and glyoxalase system

Abstract

Chromium (Cr) stress negatively impacts plant growth and physiological processes, making it a significant environmental concern. This study investigates the effectiveness of selenium nanoparticles (Se-NPs) in mitigating Cr stress on plants, comparing its efficacy with traditional selenium (Se). Nevertheless, research on using soil-applied Se-NP to lessen Cr buildup in plants has not been widely documented as of now. Here, we investigate the effectiveness of Se-NPs in mitigating Cr stress on plants, comparing their efficacy with traditional Se and control. Under the pervasive influence of Cr stress, Se-NPs exhibit remarkable superiority over conventional Se, significantly enhancing growth parameters (fresh weight, dry weight, shoot length, and root length), respectively, compared to the Cr-stressed plants. Physiologically, Se-NPs outperform Se by substantially improving the net photosynthesis rate (+32%), transpiration (+147%), and stomatal conductance (+64%), indicating its exceptional contribution to fortifying plant resilience under Cr stress. In mitigating oxidative stress, Se-NPs surpass Se, demonstrating a more pronounced reduction in LOX activity (−35%), MDA levels (−34%), H2O2 (−37%), and MG (−47%), showcasing heightened protection against Cr induced oxidative damage. Antioxidant defense systems also witness greater activation under Se-NPs, with higher increases in SOD (+27%), CAT (+54%), GPX (+7%), and GST (+37%) activities. Moreover, under Cr stress Se-NPs induce a more profound upregulation of antioxidant genes and the production of secondary metabolites, emphasizing its superior impact on the plant's defense mechanisms. The modulation of the ASA-GSH cycle by Se-NPs is more robust, with increased levels of ASA (+69%) and GSH (+33%), and decreased DHA (−28%) and GSSG (−29%), suggesting a more effective antioxidant network. Moreover, Se-NPs demonstrate heightened interference in Cr uptake in both root (−30%) and shoot tissues (−23%), indicating its potential to disrupt the Cr-induced ASA-GSH cycle. The study highlights the potential of Se-NPs as a more effective and sustainable approach to mitigate Cr-induced stress in plants, emphasizing the importance of understanding the underlying mechanisms and optimizing application strategies for improved agricultural sustainability and productivity in Cr-contaminated environments. Furthermore, it is necessary to conduct economic feasibility studies and assessments of the effects of Se-NP on soil microbiota in order to promote the widespread application in agricultural activities.