Impact of Calcium-Silicon nanoparticles on flower quality and biochemical characteristics of Lilium under salt stress

Lilium plants are one of the most important and widely distributed ornamental crops in the world. However, these plants are also susceptible to salinity, an environmental factor that is one of the main ones worldwide. Salinity negatively affects the development and productivity of plants, in addition to the fact that it can affect the quality of flowers in ornamental crops. The use of nanotechnology can be a useful tool to counteract the negative effects of salinity, since the application of nanoparticles can function as a biostimulant and induce positive responses against different types of abiotic stress. In the present study, the foliar application of two types and concentrations of calcium-silicon nanoparticles (Ca-Si NPs) (500 and 750 mg L−1) in lilium plants grown with or without stress and under saline stress (30 mM NaCl) was evaluated. The differences between both nanoparticles were the size and content of inorganic residues, where CaSi-1 had a size of 23.29 nm and a content of inorganic residues of 62.0 %, while CaSi-2 had a size of 15.29 nm and a content of inorganic residues of 87.0 %. The results showed that salinity affected the quality of the flowers, as well as the biochemical parameters of the plants. In contrast, the application of Ca-Si NPs induced positive effects on flower quality, improved flower size and fresh biomass. Under salt stress conditions, the application of Ca-Si NPs in lilium improved the biochemical parameters, increased the content of chlorophylls (up to 38.1 %), vitamin C (9.4 %), and antioxidant capacity (19.2-23.8 %) in the leaves. Regarding the stress indicators in the leaves, the hydrogen peroxide (H2O2) was not affected by salinity or by the Ca-Si NPs, while the malondialdehyde (MDA) increased by the application of the NPs, however, under saline stress there were no differences. In lilium flowers without salt stress, both H2O2 and MDA increased by the application of Ca-Si NPs, while under salt stress only MDA increased. The use of Ca-Si NPs can be an alternative to counteract the harmful effects of salinity stress in plants.