Abstract
Tomato plants often grow in saline environments in Mediterranean countries where salt accumulation in the soil is a major abiotic stress that limits its productivity. However, silicon (Si) supplementation has been reported to improve tolerance against several forms of abiotic stress. The primary aim of our study was to investigate, using comparative physiological and proteomic approaches, salinity stress in chloroplasts of tomato under silicon supplementation. Tomato seedlings (Solanum lycopersicum L.) were grown in nutrient media in the presence or absence of NaCl and supplemented with silicon for 5 days. Salinity stress caused oxidative damage, followed by a decrease in silicon concentrations in the leaves of the tomato plants. However, supplementation with silicon had an overall protective effect against this stress. The major physiological parameters measured in our studies including total chlorophyll and carotenoid content were largely decreased under salinity stress, but were recovered in the presence of silicon. Insufficient levels of net-photosynthesis, transpiration and stomatal conductance were also largely improved by silicon supplementation. Proteomics analysis of chloroplasts analyzed by 2D-BN-PAGE (second-dimensional blue native polyacrylamide-gel electrophoresis) revealed a high sensitivity of multiprotein complex proteins (MCPs) such as photosystems I (PSI) and II (PSII) to the presence of saline. A significant reduction in cytochrome b6/f and the ATP-synthase complex was also alleviated by silicon during salinity stress, while the complex forms of light harvesting complex trimers and monomers (LHCs) were rapidly up-regulated. Our results suggest that silicon plays an important role in moderating damage to chloroplasts and their metabolism in saline environments. We therefore hypothesize that tomato plants have a greater capacity for tolerating saline stress through the improvement of photosynthetic metabolism and chloroplast proteome expression after silicon supplementation.
Highlights
Silicon (Si) is the most abundant element present in most soils, after oxygen
It has been observed that the transportation of Si from an external medium is mediated from cortical cells to the xylem by silicon transporter genes such as Lsi-1 and Lsi-2 [1]
Several studies have been reported on silicon with several abiotic stresses including salt stress [38,39,40], little information exists on physiological aspects for chloroplasts
Summary
Silicon (Si) is the most abundant element present in most soils, after oxygen It plays an important role in plants at the bio-macromolecular level [1,2,3], and is taken up by a wide range of organisms due to its high solubility [4,5,6]. Silicon is a non-essential element, but its biological significance has been demonstrated in many species [2,7,8] It is taken up by plants via their roots in the form of silicic acid (Si(OH)4) through silicon transporters and accumulates in the epidermis of various tissues, mainly as a polymer of hydrated amorphous silica. At the chloroplast proteome level, no information has been published regarding how chloroplast multiprotein complex proteins interact with
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