Tomato (Lycopersicon esculentum L.) belongs to the Solanaceae family. It is a crop of immense economic importance worldwide and salinity is one of the major abiotic factors limiting it's production and productivity globally. The amount of irrigation water and their evapotranspiration is the main reason that causes salinization. Salinity is an abiotic stress that affects agriculture by severely impacting crop growth and, consequently, final yield. Considering that sea levels rise at an alarming rate over year, it is clear that salt stress constitutes a top-ranking threat to agriculture. Among the economically important crops that are sensitive to high salinity is tomato one that is more affected by salt stress. Si plays the beneficial role of the quasi-essential metalloid silicon (Si), which increases the vigor and protects plants against a biotic stresses. The use of silicon fertilization can be used as sustainable practices in agricultural production to increase yield and quality of plants. Silicon fertilization also plays role in plant protection against various range of exogenous stresses especially, under changing environment. The use of appropriate irrigation method, amount and water quality to minimize the risk of salt accumulation around root zone of plants. Different plant growth regulators and amino acids could also play a great role in increasing yield and growth of tomato under salt stress.

Ashraf, M.A.; Iqbal, M.; Rasheed, R.; Hussain, I.; Riaz, M.; Arif, M.S. (2018). Chapter 8—Environmental stress and secondary metabolites in plants: An overview. In Plant Metabolites and Regulation under Environmental Stress;

Berni, R.; Luyckx, M.; Xu, X.; Legay, S.; Sergeant, K.; Hausman, J.-F.; Lutts, S.; Cai, G.; Guerriero, G. (2019). Reactive oxygen species and heavy metal stress in plants: Impact on the cell wall and secondary metabolism. Environ. Exp. Bot. 161, 98–106.

Selmar, D.; Kleinwächter, M. (2013). Stress enhances the synthesis of secondary plant products: The impact of stress-related over-reduction on the accumulation of natural products. Plant Cell Physiol., 54, 817–826.

Merchante, C.; Stepanova, A.N.; Alonso, J.M. (2017). Translation regulation in plants: An interesting past, an exciting present and a promising future. Plant J., 90, 628–653.

Sablok, G.; Powell, J.J.; Kazan, K. (2017). Emerging roles and landscape of translating mRNAs in plants. Front. Plant Sci., 8, 1443.

Taiz, L.; Zeiger, E.; Moller, I.M.; Murphy, A. (2015). Plant Physiology and Development, 6th ed.; Sinauer Associates, Inc.:Sunderland, MA, USA, ISBN 978-1-60535-255-8.

Pandolfi, C.; Bazihizina, N.; Giordano, C.; Mancuso, S.; Azzarello, E. (2017). Salt acclimation process: A comparison between a sensitive and a tolerant Olea europaea cultivar. Tree Physiol. 37, 380–388.

Polle, A.; Chen, S. (2015). On the salty side of life: Molecular, physiological and anatomical adaptation and acclimation of trees to extreme habitats. Plant Cell Environ. 38, 1794–1816.

Baillie, C.-K.; Kaufholdt, D.; Meinen, R.; Hu, B.; Rennenberg, H.; Hänsch, R.; Bloem, E. (2018). Surviving volcanic environments—interaction of soil mineral content and plant element composition. Front. Environ. Sci. 6, 52.

Smale, M.C.;Wiser, S.K.; Bergin, M.J.; Fitzgerald, N.B. (2018). A classification of the geothermal vegetation of the Taup¯o Volcanic Zone, New Zealand. J. R. Soc. N. Z.48, 21–38.

Furtado, B.U.; Nagy, I.; Asp, T.; Tyburski, J.; Skorupa, M.; Goł˛ebiewski, M.; Hulisz, P.; Hrynkiewicz, K. (2019). Transcriptome profiling and environmental linkage to salinity across Salicornia europaea vegetation. BMC Plant Biol. 19, 427.

Reeves, R.D., Baker, A.J.M., Ja_ré, T., Erskine, P.D., Echevarria, G.; van der Ent, A. (2018). A global database for plants that hyper accumulate metal and metalloid trace elements. New Phytol.407–411.

Ramegowda, V., Senthil-Kumar, M. (2015). The interactive effects of simultaneous biotic and abiotic stresses on plants: Mechanistic understanding from drought and pathogen combination. J. Plant Physiol. 176, 47–54.

Machado, R.M.A., Serralheiro, R.P. (2017). Soil Salinity: Effect on vegetable crop growth. Management practices to prevent and mitigate soil salinization. Horticulturae, 3, 30.

Corwin, D.L.; Yemoto, K. (2019). Measurement of soil salinity: Electrical conductivity and total dissolved solids. Soil Sci. Soc. Am. J.83, 1–2.

Rengasamy, P. (2006). World salinization with emphasis on Australia. Proc. J. Exp. Bot. 57, 1017–1023.

Rozema, J.; Flowers, T. (2008). Ecology: Crops for a salinized world. Science, 322, 1478–1480.

Akladious SA, Mohamed HI. (2018). Ameliorative effects of calcium nitrate and humic acid on the growth, yield component and biochemical attribute of pepper (Capsicum annuum) plants grown under salt stress. Scientia Horti 236:244–250. https://doi.org/10.1016/j.scien ta.2018.03.047.

Latif HH, Mohamed HI. (2016). Exogenous applications of moringa leaf extract effect on retrotransposon, ultrastructural and biochemical contents of common bean plants under environmental stresses. S Afr J Bot 106:221–231. https ://doi.org/10.1016/j.sajb.2016.07.010.

Sofy MR, Elhawat N, Tarek A. (2020b). Glycine betaine counters salinity stress by maintaining high K+/Na+ ratio and antioxidant defense via limiting Na+ uptake in common bean (Phaseolus vulgaris L.). Ecotoxicol Environ Saf 200:110732. https://doi.org/10.1016/j.ecoen v.2020.11073 2.

Niu GD, Rodriguez D, Dever J, Zhan J. (2013). Growth and physiological responses of five cotton genotypes to sodium chloride and sodium sulfate saline water irrigation. Cotton Sci 17(2):233–244.

Khan H, Basit A, Alam M, Ahmad I, Ullah I, Ullah I, Alam N, Khalid M, Shair M, Ain N. (2020). Efficacy of Chitosan on performance of tomato (Lycopersicon esculentum L.) plant under water stress condition. Pak J Agric. Res.33:27–41.https://doi.org/10.17582/journ al.pjar/2020/33.1.27.41.

Byrt, C.S., Munns, R., Burton, R.A., Gilliham, M.,Wege, S. (2018). Root cell wall solutions for crop plants in saline soils. Plant Sci. 269, 47–55.

Guerriero, G.; Behr, M.; Hausman, J.-F.; Legay, S. (2017). Textile hemp vs. salinity: Insights from a targeted gene expression analysis. Genes, 8, 242.

Guo, Q.; Liu, L.; Barkla, B.J. (2019). Membrane lipid remodeling in response to salinity. Int. J. Mol. Sci.20, 4264.

Di Meo, F.; Lemaur, V.; Cornil, J.; Lazzaroni, R.; Duroux, J.-L.; Olivier, Y.; Trouillas, P. (2013). Free radical scavenging by natural polyphenols: Atom versus electron transfer. J. Phys. Chem. A.117, 2082–2092.

Lim, J.-H.; Park, K.-J.; Kim, B.-K.; Jeong, J.-W.; Kim, H.-J. (2013). Effect of salinity stress on phenolic compounds and carotenoids in buckwheat (Fagopyrum esculentum M.) sprout. Food Chem. 135, 1065–1070.

Chalker-Scott, L. (2002). Do anthocyanins function as osmo regulators in leaf tissues? In Advances in Botanical Research; Academic Press: Cambridge, MA, USA, Volume 37, pp. 103–127.

Hughes, N.M.; Carpenter, K.L.; Cannon, J.G. (2013). Estimating contribution of anthocyanin pigments to osmotic adjustment during winter leaf reddening. J. Plant Physiol. 170, 230–233.

Ali Salehi, Sardoei1 and Gholam Abbas Mohammadi. (2014). Study of salinity effect on germination of tomato (Lycopersicon esculentum L.) genotypes. European Journal of Experimental Biology, 4(1): 283-287.

Shamil Alo, Derbew Belew and Edossa Etissa. (2020). Germination Response of Released Tomato (Solanum lycopersicum L.) Varieties to Salt Stress. World Journal of Agricultural Sciences 16 (4): 295-302. DOI: 10.5829/idosi.wjas.2020.295.302.

Rivero, R.M, TC Mestre, R.O Mittler, F. Rubio, F.R Garcia-Sanchez and V Martinez. (2014). The combined effect of salinity and heat reveals a specific physiological, biochemical and molecular response in tomato plants. Plant, Cell and Environment.37: 1059-1073.

Manan, A., Ayyub, C.M., Ahmad, R., Bukhari, M.A. and Mustafa, Z. (2016). Salinity Induced Deleterious Effects on Biochemical and Physiological Processes of Tomato. Pakistan Journal of Life & Social Sciences, 14(2).

Zhang H, YK. Ye, SH. Wang, JP. Luo, J. Tang and DF. M. (2009). Hydrogen sulfide counteracts chlorophyll loss in sweet potato seedling leaves and alleviates oxidative damage against osmotic stress. Plant Growth Regulation.58: 243-250.

Zribi, L. G Fatma, R. Fatma, R. Salwa, N. Hassan and R.M Nejib. (2009). Application of chlorophyll fluorescence for the diagnosis of salt stress in tomato “Solanum lycopersicum L. (variety Rio Grande)”. Scientia Horticulturae. 120:367- 372.

Flexas, J., A. Diaz-Espejo, J. Galmés, R. Kaldenhoff, H. Medrano and M. Ribas-Carbo. (2007). Rapid variations of mesophyll conductance in response to changes in CO2 concentration around leaves. Plant Cell Environment. 30(5): 1284–1298.

Ashraf, M. and Harris, P.J.C. (2013). Photosynthesis under stressful environments: An overview. Photosynthetica.51: 163–190.

Ciobanu, I.P. and R. Sumalan. (2009). The effects of the salinity stress on the growing rates and physiological characteristics to the Lycopersicum esculentum specie. Bulletin of University of Agricultural Sciences and Veterinary Medicine Cluj-Napoca. Horticulture. 66(2): 616-620.

Danait. H. (2018). Impact of surface and ground water salinity on soil and plant productivity in the central rift valley region around Lake Ziway. Academia Journal of Environmental Science. 6(3): 067-084.

Shao X, M. Hou and J. Chen. (2013). Effects of EM-calcium spray on Ca uptake, blossom-end rot incidence and yield of greenhouse tomatoes (Lycopersicon esculentum L.). Research on Crops. 14: 1159–1166.

Hou M, X. Shao, Y.Zhai. (2014). Effects of Different Regulatory Methods on Improvement of Greenhouse Saline Soils, Tomato Quality, and Yield. Scientific World Journal. 953675.

Basit A, Khan H, Alam M, Ullah I, Shah S, Zuhair S, Ullah I. (2020). Quality indices of tomato plant as affected by water stress conditions and chitosan application. Pure Appl Biol 9:1364–1375. https ://doi.org/10.19045 /bspab .2020.90143.

Sofy, A.R, Dawoud, R.A, Sofy, M.R, Mohamed, H.I, Hmed, A.A, El-Dougdoug, N.K. (2020a). Improving regulation of enzymatic and non-enzymatic antioxidants and stress-related gene stimulation in Cucumber mosaic cucumovirus-infected cucumber plants treated with glycine betaine, chitosan and combination. Molecules 25:2341. https ://doi.org/10.3390/ molec ules2 51023 41.

de Alvarenga, E.S. (2011). Characterization and Properties of Chitosan. Bio Tech Biopolym. https ://doi.org/10.5772/17020.

Haytova, D. (2013). A review of foliar fertilization of some vegetables crops. Ann Rev Res Bio 3:455–465.

Malerba M, Cerana, R. (2016). Chitosan effects on plant systems. Int J Mol Sci. https://doi.org/10.3390/ijms1 70709 96.

Ortiz O.H, Benavides, A.M, Villarreal, R.M, Rodriguez, H.R, Romenus, K.A. (2007). Enzymatic activity in tomato fruits as a response to chemical elicitors. J Mexi Chemi Socie 51:141–144.

Naeem Ullah, Abdul Basit, Imran Ahmad, Izhar Ullah, Syed Tanveer Shah, Heba I. Mohamed and Shahryar Javed1. (2020). Mitigation the adverse effect of salinity stress on the performance of the tomato crop by exogenous application of chitosan. Bull Natl Res Cent (2020) 44:181 https://doi.org/10.1186/s42269-020-00435-4.

Li, X.; Chang, S.X.; Salifu, K.F. (2013). Soil texture and layering effects on water and salt dynamics in the presence of a water table: A review. Environ. Rev. 22, 41–50.

Zhai, Y.; Yang, Q.;Wu, Y. (2016). Soil Salt distribution and tomato response to saline water irrigation under straw mulching. PLoS ONE, 11, e0165985.

Rady, M.M. (2012). A novel organo-mineral fertilizer can mitigate salinity stress effects for tomato production on reclaimed saline soil. S. Afr. J. Bot. 81, 8–14.

Al-Yahyai, R.; Al-Ismaily, S.; Al-Rawahy, S.A. (2010). Growing tomatoes under saline field conditions and the role of fertilizers. Monogr. Manag. Salt Affect. Soils Water Sustain. Agric. 83–88.

Neeraja, G.; I. P. Reddy; B. Gautham. (2005). Effect of growth promoters on growth and yield of tomato cv. Marutham. Journal-of-Research-ANGRAU.; 33(3): 68-70.

Hafez, M.R. (2001). Impact of some chemical treatments on salinity tolerance of some tomato

Jonas, H.o_mann , Roberto Berni, , Jean-Francois, Hausman and Gea Guerriero. (2020). A Review on the Beneficial Role of Silicon against Salinity in Non-Accumulator Crops: Tomato as a Model, Biomolecules, 10, 1284; doi: 10. 3390/biom10091284.

Khan, A.; Kamran, M.; Imran, M.; Al-Harrasi, A.; Al-Rawahi, A.; Al-Amri, I.; Lee, I.-J.; Khan, A.L. (2019). Silicon and salicylic acid confer high-pH stress tolerance in tomato seedlings. Sci. Rep. 9, 19788.

Shi, Y.; Zhang, Y.; Yao, H.; Wu, J.; Sun, H.; Gong, H. (2014). Silicon improves seed germination and alleviates oxidative stress of bud seedlings in tomato under water deficit stress. Plant Physiol. Biochem. 78, 27–36.

Zhang, Y.; Shi, Y.; Gong, H.; Zhao, H.; Li, H.; Hu, Y.; Wang, Y. (2018). Beneficial efects of silicon on photosynthesis of tomato seedlings under water stress. J. Integr. Agric. 17, 2151–2159.

Jiang, N.; Fan, X.; Lin,W.;Wang, G.; Cai, K. (2019). Transcriptome analysis reveals new insights into the bacterial wilt resistance mechanism mediated by silicon in tomato. Int. J. Mol. Sci. 20, 761.

Li, H.; Zhu, Y.; Hu, Y.; Han,W.; Gong, H. (2015). Beneficial effects of silicon in alleviating salinity stress of tomato seedlings grown under sand culture. Acta Physiol. Plant, 37, 71.

Romero-Aranda, M.R.; Jurado, O.; Cuartero, J. (2006). Silicon alleviates the deleterious salt effect on tomato plant growth by improving plant water status. J. Plant Physiol. 163, 847–855.

H. Rasulu and J. Juharnib, “The Physicochemical Characteristics of Smart Food Bars Enriched with Moringa Leaf Extract And Chitosan as An Emergency Food in Disaster Times,” International Journal on Food, Agriculture and Natural Resources, vol. 2, no. 3, pp. 24–28, Dec. 2021, doi: https://doi.org/10.46676/ij-fanres.v2i3.51.