Abstract
Silicon (Si) is an important plant-derived metabolite that is significantly involved in maintaining the stability of a plant’s metabiological, structural and physiological characteristics under the abiotic stressed environment. We conducted the present study using maize (Zea mays L.) cultivars (Sadaf and EV-20) grown in sand artificially contaminated with cadmium (500 µM) in Hoagland’s nutrient solution to investigate its efficiency. Results from the present study evidenced that the toxic concentration of Cd in sand significantly reduced shoot length, root length, shoot fresh weight, root fresh weight, shoot dry weight and root dry weight by 88, 94, 89, 86 99 and 99%, respectively, in Sadaf while decreasing by 98, 97, 93, 99, 84 and 91%, respectively, in EV-20. Similarly, Cd toxicity decreased total chlorophyll and carotenoid content in both varieties of Z. mays. Moreover, the activities of various antioxidants (superoxidase dismutase, peroxidase and catalase) increased under the toxic concentration of Cd in sand which was manifested by the presence of membrane permeability, malondialdehyde (MDA), and hydrogen peroxide (H2O2). Results additionally showed that the toxic effect of Cd was more severe in EV-20 compared with Sadaf under the same conditions of environmental stresses. In addition, the increased concentration of Cd in sand induced a significantly increased Cd accumulation in the roots (141 and 169 mg kg−1 in Sadaf and EV-20, respectively), and shoots (101 and 141 mg kg−1 in Sadaf and EV-20, respectively), while; EV-20 accumulated higher amounts of Cd than Sadaf, with the values for both bioaccumulation factor (BAF) and translocation factor (TF) among all treatments being less than 1. The subsequent negative results of Cd injury can be overcome by the foliar application of Si which not only increased plant growth and biomass, but also decreased oxidative damage induced by the higher concentrations of MDA and H2O2 under a Cd-stressed environment. Moreover, external application of Si decreased the concentration of Cd in the roots and shoots of plants, therefore suggesting that the application of Si can ameliorate Cd toxicity in Z. mays cultivars and results in improved plant growth and composition under Cd stress by minimizing oxidative damage to membrane-bound organelles.
Highlights
Metal contamination issues are becoming increasingly common across the world, with many documented cases of metal toxicity in mining industries, foundries, smelters, coal-burning power plants and agriculture [1,2]
In root length, shoot length, root fresh weight, shoot fresh weight, root dry weight and shoot dry weight, respectively, were observed in Sadaf, while decreases of 98, 97, 93, 99, 84 and 91%, respectively, in EV-20, were observed in the plants grown under the toxic concentration of Cd (500 μM) in the sand
Results showed that the toxic effect of Cd was more severe in EV-20 compared with Sadaf under the same environmental stressed condition in terms of plant growth and biomass attributes
Summary
Metal contamination issues are becoming increasingly common across the world, with many documented cases of metal toxicity in mining industries, foundries, smelters, coal-burning power plants and agriculture [1,2]. Cadmium (Cd) is a more prominent toxic pollutant due to its severe toxicity and ability to induce damage to normal growth and development [3,4]. Cd is classified as a non-essential element for plant growth and development and its high accumulation in the plant organs is concerning [7]. Fe transporters and by passive transport through ionic transcription rates by transferring through xylem and phloem transportation processes [8,9]. Accumulation of Cd leads to the deficiency of iron, calcium, and magnesium by disturbing morphological and biochemical processes in plants [10]. Cd-toxicity damages plant cells including chloroplasts, cell nuclei, and mitochondria leading to a reduction in chlorophyll [11]
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