تاثیر نانو سیلیکون بر خصوصیات بیوشیمیایی گیاه گاوزبان اروپایی (.borago oficinalis l) تحت تنش کادمیوم

فلزات سنگین به عنوان یکی از مشکلات زیست محیطی مهم است که منجر به کاهش رشد، عملکرد و کیفیت محصولات گیاهان می‌شود. سیلیکون به دلیل نقش فیزیولوژیکی و ساختاری برای رشد گیاهان مفید بوده و در سازگاری گیاه به تنش های محیطی می تواند موثر باشد. در این پژوهش تاثیر کادمیوم (صفر، 81 و 243 میکرومولار) و نانوسیلیکون ( صفر و 1.5 میلی‌مولار) در سه بازه زمانی 24 ساعت، یک هفته و دو هفته پس از اعمال تیمار بر گیاه گاوزبان اروپایی مورد مطالعه قرار گرفت. نتایج نشان داد با افزایش غلظت کادمیوم از 81 به 243 میکرومولار میزان پروتئین کل کاهش و میزان پراکسید هیدروژن و مالون‌دی‌آلدئید افزایش یافت. حضور 1.5 میلی‏ مولار نانوسیلیکون باعث کاهش اثرات تخریبی کادمیوم شده به گونه‌ای که میزان تجمع کادمیوم در تیمار کادمیوم 243 میکرومولار+ نانوسیلیکون 1.5 میلی‏ مولار و میزان پراکسید هیدروژن و مالون دی آلدئید در هر دو غلظت، 81 و 243 میکرومولار بطور معنی‌داری در مقایسه با تیمار بدون نانوسیلیکون کاهش یافته است. بنابراین، نتایج این پژوهش نشان داد که کاربرد نانوسیلیکون در خاک‌های آلوده به کادمیوم می‏تواند به عنوان ایده‏ای در جهت افزایش کیفیت و تولید گیاه گاوزبان اروپایی باشد و اثرات نامطلوب تنش کادمیوم را بهبود بخشد.

The effect of nano-silicone on biochemical characteristics of European borage (Borago oficinalis L.) under the cadmium stress

IntroductionEnvironmental pollution with heavy metals has spread in the world. The impact these pollutants on the human health and food chain, as one of the factors of economic and health concerns, needs more attention. Cadmium (cd) as one of the most important heavy metals compared to other metals is rapidly absorbed and accumulated in plant tissues, and its transfer to the food chain is the result of widespread contamination of the soil with cadmium. Nanosilicon (Si) is more effective than usual fertilizers in protecting plants against biotic and abiotic stresses. Medicinal plants are one of the most important sources of drug production that humans have used for many years, and their importance is expanding day by day. Many secondary metabolites of Borago officinalis and its products are consumed in the world pharmaceutical markets, so it requires special attention to improve the quality of culture, production efficiency, and health. This attention requires increasing knowledge about the physiological mechanisms of this plant affected by environmental factors such as cadmium stress. This study aimed to investigate the effect of nanosilicon on alleviating the detrimental effects of cadmium stress on physiological properties such as antioxidant enzyme activity in Borago officinalis.Materials and methodsTreatment was performed by adding cadmium in the form of cadmium nitrate (Cd (NO3)2) and nanosilicon in hydroponic cultures of borage plants at the 78 leaf stage. This study was conducted as a factorial experiment based on a completely randomized design with three replications. Experimental factors were cadmium at three levels (0 (control), 25 mg L1, and 75 mg L1) and nano silicon at two different levels (0 and 1.5 mM). One day, one week, and two weeks after treatment, plant leaves were sampled and the amount of cadmium accumulation and biochemical and physiological properties were measured.Results and discussionThe results showed that the accumulation of cadmium in the aerial parts of the borage plant was significantly increased with increasing the cadmium concentration in the hydroponic medium. The utilization of nanosilicon significantly reduced the amount of cadmium absorption and accumulation in borage plants.Cadmium nitrate increased the amount of hydrogen peroxide compared to the control. The use of nanosilicon significantly reduced the amount of hydrogen peroxide under cadmium stress at one and two weeks after treatment. One of the important consequences of increasing the concentration of heavy metals in plants is increasing in the production and accumulation of reactive oxygen species (ROS) such as superoxide, hydroxyl and hydrogen peroxide (H2O2) radicals in the cells. This reactive oxygen species leads to the oxidation and destruction of macromolecules such as protein, DNA, cell membrane damage and ion leakage.With increasing the concentration of cadmium, the amount of malondialdehyde (MDA) and proline in the cells were significantly increased. Malondialdehyde (MDA) and proline levels were significantly reduced by nanosilicon treatment. Heavy metals such as cadmium lead to the production of hydroxyl radicals, followed by lipid peroxidation. With increasing the lipid peroxidation, the cell membrane is destroyed and malondialdehyde levels increase. In the present study, the amount of malondialdehyde was significantly reduced under the influence of nano silicon treatment. Proline accumulation in plants may also be a biomarker of cadmium stress, because proline can scavenge free radicals and protect the cells from their damaging effects.With increasing the concentration of cadmium, the activity of polyphenol oxidase, peroxidase, and catalase enzymes was increased. In addition, the activity of these enzymes was reduced with the utilization of nanosilicon. The highest activities of these enzymes were recorded under cadmium concentration at 75 mg l1 and the lowest activities of these enzymes were related to the treatment of nanosilicon and control. Increasing the level of antioxidant activity can sweep ROS produced by heavy metals, and protects the cell from the damaging effects of oxidative stress, which increases the plant’s tolerance to environmental stresses, including heavy metals. The use of nanosilicon positively reduces cadmium accumulation in the plant maybe by maintaining the photosynthetic capacity and regulating the uptake and transfer of cadmium under cadmium stress conditions. On the other hand, nanosilicon reduces the amount of malondialdehyde (MDA) and reactive oxygen species (H2O2) may be through the reduction of cadmium uptake and accumulation in the plant cells and tissues as well as increase in the efficiency of enzymatic and nonenzymatic antioxidant systems.ConclusionsThe results of the present study showed that the accumulation of cadmium in the borage tissues under cadmium stress was reduced due to the application of nanosilicon. In other words, the use of nanosilicon improved the physiological characteristics of the borage plant by reducing the uptake and transfer of cadmium nitrate. This reduction in the amount of uptake and accumulation of cadmium nitrate in plant tissues is important for the health of agricultural products and human communities.