Abstract
AbstractSelenium (Se) and silicon (Si) are the beneficial elements that may significantly modify plants’ tolerance to various types of biotic and abiotic stress. They may be particularly important due to the current climate changes. The aim of model experiments was to assess how selenium and silicon could alleviate short-term drought stress in French marigold (Tagetes patula L. “Pascal”). Tagetes plant species are economically important annual plants and are also very popular decorative flowering species in city parks due to its beautiful colored flowers and resistance on drought stress. Silicon was applied in the form of silica sol and choline-stabilized orthosilicic acid (ch-OSA). Selenium was applied in the form of sodium selenate (Na2SeO4). They were tested at the following concentrations (mg dm−3 of NS): silica sol – level I (23.25), level II (31.0); ch-OSA – level I (0.21), level II (0.63); and Se – level I (0.4), level II (0.8). The experiment showed that silicon had stimulating effect on the biometric parameters of control plants cultivated under an optimal water regime. When the plants treated with selenium were exposed to stress, the values of their biometric parameters were generally higher than in the plants treated with silicon. Both silicon and selenium significantly modified the gas exchange parameters. During the growing season, the net photosynthesis activity (PN), stomatal conductance (gs), and transpiration rate (E) tended to decrease, but they increased significantly when selenium and silicon were applied. In general, the factors significantly modified the plants’ content of macro- and micronutrients as well as the proportions between them. Both selenium and silicon alleviated the short-term drought stress in French marigolds as a model plant, but when silicon was applied, the positive effect was modified by the source and its concentration.
Highlights
The mass of inflorescences increased in both the plants grown under the optimal water regime and those exposed to drought stress
Selenium mitigated the effects of drought stress, whereas silicon caused the mass of shoots to increase, but the difference was not statistically significant
When silicon was applied to the plants grown under the optimal water regime as well as those exposed to the water stress, the relative iron content increased
Summary
The availability of water in soil is a major environmental factor that may limit the growth and the yield of crops [1]. Water stress may be caused by a real water deficit in soil (drought) or excessive salinity of the root zone. Drought causes abiotic stress, which results in lower growth and development rates, flower abortion, and lower yield during plants’ maturation and reproduction [2]. Drought stress reduces water potential, dry weight, root development, and photosynthetic parameters. Drought stress causes physiological and biochemical changes in plants, the accumulation of some compounds, e.g. sugars (oligosaccharides, sucrose, trehalose, sorbitol), sugar alcohols (mannitol), amino acids (proline), and amines (glycine, betaine, polyamides) [1].
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