Effect of Various Concentrations of Potassium Silicate on Biomass, Yield and Silicon Distribution in Tomato Plants

Shokri Fomeshkenari, Mohammad; Ghasemi, Kamran; Emadi, Seyed Mostafa

doi:10.22034/iuvs.2022.543981.1187

Effect of Various Concentrations of Potassium Silicate on Biomass, Yield and Silicon Distribution in Tomato Plants

Document Type : Original Article

Authors

Mohammad Shokri Fomeshkenari ¹

Kamran Ghasemi ²

Seyed Mostafa Emadi ³

¹ Department of Horticultural Sciences and Engineering, Faculty of Crop Sciences, Sari Agricultural Sciences and Natural Resources University, Sari, Iran

² Horticultural Sciences and Engineering Department, Sari Agricultural Sciences and Natural Resources University, Sari, Sari, Iran

³ Department of Soil Sciences, Faculty of Crop Sciences, Sari Agricultural Sciences and Natural Resources University, Sari, Iran

10.22034/iuvs.2022.543981.1187

Abstract

Extended Abstract
1-Introduction: Silicon (Si) is considered as a beneficial nutrient in most plants which can contribute to various positive physiological impacts. It is well documented that Si can alleviate a broad range of biotic and abiotic stresses, so this element is an effective inorganic antistress. As tomato is usually attacked by different pathogens like fungi, in addition it is vulnerable against a vast range of abiotic stresses including water stress, chilling, freezing and so forth, Si treatment can be a good strategy for strengthening the plant defense system. It is so obvious that Si treatment should be applied before stress; because of this, comprehension of this element behavior in normal conditions can be important. However, most experiments about Si have been conducted in stressful conditions, but evaluation of the Si effect in normal conditions, its behavior in plants, and its distribution in different organs need to be explored. Recently, the active gene of S1Lsi1 which is responsible for Si influx, was detected in tomato, but efflux gene named S1Lsi2 was inactive, therefor translocation of Si from root to above parts of plant might be seriously restricted. Evaluation of tomato potential for Si root absorption and after that transporting of the element to the aerial parts can shed light on the efficiency of Si fertilization. So, this research was outlined to monitor the Si uptake by root, its distribution in different plant organs, and its effects on biomass and yield in tomatoes treated by different concentrations of Si.
2-Material and methods: In this research, Si uptake and translocation in tomato plant was evaluated in completely randomized design experiment with 11 treatments (0, 100, 200, 300, 400, 500, 600, 700, 800, 900, and 1000 mg Si/l from K₂SiO₃), and four replications in an open field soil pot experiment. Potassium silicate treatments were applied every 10 days up to 8 times during the experiment conduction. Each pot was fertigated 200 ml of Si contained solution. Fresh and dry weight of fruits, fresh and dry weight of old leaves, fresh and dry weight of young leaves, fresh and dry weight of stem, fresh and dry weight of root, and Si content of different parts of plant were determined in this experiment. Analysis of variation was carried out by SAS 9.1 software and the Duncan test was used for mean comparison.
3-Results and discussions: PCR Based on obtained results, treatments of 300 and 600 mg/l caused an increase in fresh weight of old leaves and stem. A huge amount of Si settles down on the cell wall; as a result, the stronger stem of plants in these treatments can be expected. Also, Si in 600, 700, 800, and 900 mg/l led to more fruit dry biomass. Two treatments of 500 and 600 mg/l produced the highest yield per plant, but the highest fruit number was observed just in 600 mg/l treatment. According to regression analysis the highest fruit yield per plant will be obtained in 548mg/l of Si. Positive effect of Si on the yield of different crops was frequently reported which is in harmony with our results. Si fertigation in 600mg/l concentration significantly contributed to more Si content in old leaves and total plant. Recently, it was reported that Si accumulation in old leaves is more than young once which can be related to the immobility mode of this element in plants. Distribution model of Si in tomato plants showed 73.09% of absorbed Si accumulated in fruits and after that stem, leaves and root placed in lower levels with 11.49, 13.81 and 1.61% respectively. So, the hypothesis of low Si translocation from root to aerial parts in tomato was contradicted by the present results. Accumulation of Si in fruits is a promising indication, because positive influences of Si can be observed in fruits especially in postharvest phase.
4-Conclusion: It can be definitely said that Si applied through the fertigation was absorbed by tomato root and the large percentage of the element was transported to other organs especially fruits which received a large extent of absorbed Si. Overall, treatment of tomato plants with 600 mg/l of Si improved vegetative growth, stem strength, yield, and fruit number per plant, so this concentration can be recommended for growing tomato; in contrast, low or high concentrations were not efficient enough.

Keywords

silica

nutrition

translocation

element accmulation

- Cao, B.L., Xu, K., Shi, J., Xin, G.F., Liu, C.Y. & Li, X. (2013). Effects of silicon on growth, photosynthesis and transpiration of tomato. Plant Nutrition and Fertilizer Science, 19: 354-60.

- Doshi, R., braida, W., Christodoulatos, C., Wazne, M., & Oconnor, G. (2008). Nano aluminum: Transport through sand columns and environmental effects on plant and soil communities. Environmental Research, 106: 296-3.

- Fauteux, F., Rémus-Borel, W., Menzies, J.G., & Belanger, R.R. (2006). Silicon and plant disease resistance against pathogeni fungi. FEMS Microbiology Letters, 249:1-6.

- Emadi S.M. & Ghasemi K. (2018). Silicon in Agriculture. Sari University of Agricultural Sciences and Natural Resources Press. 670.

- Gou, T., Su , Y., Han , R., Jia, J., Zhu , Y., Huo, H., Liu, H & Gong, H. (2022). Silicon delays salt stress-induced senescence by increasing cytokinin synthesis in tomato. Scientia Horticulturae, 293.

- Hallmark, C.T., Wilding, L.P., & Smeck, N.E. (1982). Silicon. In: Page AL, Miller RH, Keeney DR, editors. Methods of soil analysis. Part 2: Chemical and microbiological properties, Agronomy onograph no. 9. 2nd ed. Madison: The America Society of Agronomy and Soil Science Society of America. p. 263-73.

- Karimi, S., Torki, Z., Nazok-kar Maher M. & Yegane N. (2021) Pre-transplant silicon priming improved drought tolerance and biomass partitioning in young tomato plants, International Journal of Vegetable Science, DOI: 10.1080/19315260.2021.1974145

- Liang, Y.C., Chen, X.H., Ma, T.S., Qian, Z.J., & Liu, L.R. 1993. Effect of Si on the growth, yield and quality of tomato. Jiangsu Agricultural Science, 4: 48-50.

- Liang, Y.C., Jin, S., & Romheld. V. (2005). Silicon uptake and transport is an active process in Cucumis sativus. Phytopathology, 167: 797-804.

- Liang, Y. C., Sun, W.C., Zhu, Y.G., & Christie, P. (2007). Mechanisms of silicon- mediated alleviation of abiotic stresses in higher plants: a review. Environmental Pollution, 147: 422-8.

- Liang, Y. C., Sun, W.C., Zhu, Y.G., & Christie, P. (2007). Mechanisms of silicon- mediated alleviation of abiotic stresses in higher plants: a review. Environmental Pollution, 147:422-8.

- Liang, Y. C., Sun, W.C., Zhu, Y.G., & Christie, P. (2007). Mechanisms of silicon- mediated alleviation of abiotic stresses in higher plants: a review. Environmental Pollution, 147: 422-8.

- Liang Y., Nikolic M., Bélanger R., Gong H., & Song A. (2015). Silicon in Agriculture. Dordrecht: Springer.

- Mvondo-She, M.A., & Marais, D. 2019. The Investigation of Silicon Localization and Accumulation in Citrus. Plants. 8: 200.

- Liu, J. M., Han, C., Sheng, X.B., Liu, S.K., & Qi, X. (2011). Potassium-containing silicate fertilizer: its manufacturing technology and agronomic effects. Oral presentation at 5th International Conference on Silicon in Agriculture; 13-18.

- Liu, H.Y. (1997). Preliminary report on effect of Si fertilizer on tomato growth. Journal of Guizhou Agricultural College, 16:76-7.

- Marodin, J.C., Resende, J.T.V., Morales, R.G.F., Silva, M.L.S., Galvão, A.G. & Zanin, D.S. (2014). Yield of tomato fruits in relation to silicon sources and rates. Horticultura Brasileira, 32(2): 220-224.

- Miyake, Y. & Takahashi, E. (1983). Effect of silicon on the growth of solution-cultured cucumber plant. Soil Science Plant Nutrition, 29:71-83.

- Mohaghgh, P., Shervani, M. & Ghasemi, S. (2011). The effect of silicon application on growth and yield of two cucumber cultivars in hydroponic system. Science and Technology of Greenhouse Cultivation, 1 (1): 40-35.

- Mvondo-She, M.A., & Marais, D. (2019). The Investigation of Silicon Localization and Accumulation in Citrus. Plants. 8, 200.

- Nair, P.K., & Aiyer, R.S. (1968). Status of available silica in the rice soils of Kerala State (India). II. Silicon uptake by different varieties of rice in relation to available silica contributed by soil and irrigation water. Agricultural Research Journal of Kerala, 6:88-94.

- Nikolic, M., Nikolic, N., Liang, Y., Kirkby, E. A., & Römheld, V. (2007). Germanium-68 as an adequate tracer for silicon transport in plants. Characterization of silicon uptake in different crop species. Plant Physiology, 143:495-503.

- Samuels, A. L., Glass, A. D. M., Ehret, D. L., & Menzies, J. G. (1993). The effects of silicon supplementation on cucumber fruit: Changes in surface characteristics. Annals of Botany. 72: 433-440.

- Savant, N. K., Snyder, G.H., & Datnoff, L.E. (1996). Silicon management and sustainable rice production. Advances in Agronomy, 58 :151-199.

- Sun, H., Duan, Y., Mitani-Ueno, N., Che, J., jia, J., Liu, J., Guo, J. Ma, J.F. & Gong, H. (2020) Tomato roots have a functional silicon influx transporter but not a functional silicon efflux transporter. Plant, Cell & Environment, 43:732-744.

- Takijima, Y., Wijayaratna, H.M.S., & Seneviratne, C.J. (1970). Nutrient deficiency and physiological disease of lowland rice in Ceylon. III. Effect of silicate fertilizers and dolomite for increasing rice yields. Soil Science and Plant Nutrition, 16:11-6.

- Xue, G., Zhang, G., Sun, Y., Liao, S., & Chen, Y. (2012). Influences of spraying two different forms of silicon on plant growth and quality of tomato in solar greenhouse. Chinese Agricultural Sciences Bulletin, 28(16):272-6.