Document Type : Original Article

Authors

1 MSc of plant production, Gonbad Kavous University, Gonbad Kavous, Iran

2 Associated of professor of Plant Production Department, Faculty of Agriculture and Natural Resource, Gonbad Kavous University, Gonbad Kavous, Iran

3 Assistant professor of Plant Production Department, Faculty of Agriculture and Natural Resource, Gonbad Kavous University, Gonbad Kavous, Iran

Abstract

Introduction
The basil (Ocimum basilicum), is a medicinal plant of the Lamiaceae family. Since these plants are quite rich in essential oils, they are commonly produced for economic purposes. Also these plants contain phenylpropanoid compounds. Basils are commonly used in gastronomy and oral health care. Unfortunately, the production of theses crops is reduced under different stress. Salinity is the greatest concern in plant production and may result in serious losses in yields. There are 24 million ha of saline soil in Iran, which is equal to 15% of Iran's agricultural lands. Therefore, the use of elicitors can be very effective in improving the plant's resistance potential. Chitosan and Trichoderma fungus with elicitor’s action induce defense mechanisms of plants.
 
Materials and methods
In the present study in order to evaluated the effect of Trichoderma fungus and chitosan on tolerance to salinity stress of basil, two separate experiments were carried out in a greenhouse of a Gonbad-Kavous university in a factorial arrangement based on randomized compelete design with 3 repeats at 2016. At first experiment, at first seeds of basil inoculated with Trichoderma fungus, then these seeds were planted in pots. One month plants were treated salinity stress in 4 levels (0, 75,150 and 200 mM) of NaCl for 2 weeks. At second experiment, at first, one month plantsˈ leaves spray with chitosan. Then after 24 hours theses plants were exposed salinity stress like first experiments. Control treat without chitosan spray and inoculation with the fungus were conducted.
 
Results
The results of analysis of variance showed indicated that effect of chitosan, salinity and fungus on stem length, root length, root volume, fresh weight of stem, fresh weight of root, fresh weight of leaves, dry weight of stem, dry weight of root and harvest index were significant. While, the effect of chitosan × salt and fungus × salt was not significant for any of the studied treats. The findings showed a decrease of all of studied triats with increasing salinity levels, while chitosan and fungus pretreatment improved the effect of salinity stress. So that, the treated plant showed the significant increasing in all of the treats compared to control plants. Also the results showed chitosan and Trichoderma fungus pretreatment caused resistance to salinity stress up to 150 mM in basil. But increasing salinity stress up to 200 mM caused decrease tolerance in basil to salinity stress and yield loss in all studied treats.
 
Conclusion
The results of this study confirmed that chitosan and Trichoderma can act as biological elicitors. It seems that these elicitors by increasing the uptake of water and nutrients and better transfer of these substances in plant organs and ultimately lead to improvement of stem length and root length and increasing dry weight and fresh weight of stem and root on treated basil caused the negative effect of salinity stress in these plants were significantly reduced compared to control plants. Thus, it is suggested comprehensive molecular and enzymes studied is needed to better understand how chitosan and trichoderma fungi function in reducing stress effects.

Keywords

Akhzari, D., Sepehry, A., Pessarakli, M., Barani, H., 2012. Studying the effects of salinity stress on the growth of various halophytic plant species (Agropyron elongatum, Kochia prostrata and Puccinellia distans). World Applied Science Journal. 16, 998–1003.
Amirul Alam, M., Shukor Juraimi, A., Raffi, M.Y., Abdul Hamid, A., 2015. Effect of salinity on biomass yield and physiological and stem-root anatomical characteristics of Purslane (Portulaca oleracea L.) accessions. BioMed Research International. 10, 1-15
Anith, K.N., Faseela, K.M., Archana, P.A., Prathapan, K.D., 2011. Compatibility of Piriformospora indica and Trichoderma harzianum as dual inoculants in black pepper (Piper nigrum L.). Symbiosis. 55, 11–17.
Blum, A. 1988. Plant Breeding for Stress Environments. (CRC Press: Boca Raton, FL).
Cho, M.H., No, H.K., Prinyawiwatkul, W., 2008. Chitosan treatments affect growth and selected quality of sunflower sprouts. Journal of Food Science. 73. 570-577.
Contreras-Cornejo, H.A., Macías-Rodríguez, L., Alfaro-Cuevas, R., López-Bucio, J., 2014. Trichoderma spp. improve growth of Arabidopsis seedlings under salt stress through enhanced root development, osmolite production and Na+ elimination through root exudates. American Physical Society Journal. 27, 6-17
Dzung, N.A., Thang, N.T., 2004. Effect of oligoglucosamine on the growth and development of peanut (Arachis hypogea L.). In: Khor, E., Hutmacher, D., Yong, L. (Eds.), Proceedings of the 6th Asia-Pacific on chitin, chitosan symposium Singapore, ISBN: 981, 422-438.
Dzung, N., Phuong Khanh, V., Dzung, T., 2011. Research on impact of chitosan oligomers on biophysical characteristics, growth, development and drought resistance of coffee. Carbohydrate Polymers. 84, 751-755
El-Tantawy, E.M., 2009. Behaviour of tomato plants as affected by spraying with chitosan and aminofort as natural stimulator substances under application of soil organic amendments. Pakistan Journal Biological Science. 12, 1164-1173.
Farhadi, H., Azizi, M., Nemati, S.H., 2014. Investigation the effects of salinity stress on related yield traits in eight landraces of Fenugreek (Trigonella foenum- graceum L.). Iranian Journal of Field Crop Research. 12, 862-870. [In Persian with English Summary]
Gengmao, Z., Quanmei, Sh., Yu, H., Shihui, L., Changhai, W., 2014. The Physiological and biochemical responses of a medicinal plant (Salvia miltiorrhiza L.) to stress caused by various concentrations of NaCl. Plos One. https://doi.org/10.1371/journal.pone.0089624
Gorgi, M., Zahedi, M., Eshghizadeh, H.R., 2015. Relationship between responses of safflower genotypes to salinity at germination and vegetative growth stages. Journal of Crop Production and Processing. 14, 147-158. [In Persian with English Summary]
Harman, G., Howell, Ch.R., Viterbo, A., Chet, I., Lorito, M., 2004. Trichoderma species opportunistic, avirulent plant symbionts. Nature Reviews Microbiology. 2, 43-56
Jabeen, N., Ahmad, R., 2013. The activity of antioxidant enzymes in response to salt stress in safflower (Carthamus tinctorius L.) and sunflower (Helianthus annuus L.) seedlings raised from seed treated with chitosan. Journal of the Science Food and Agriculture. 93, 1699–1705
Javanmardi, J., Khalighi, A., Kashi, A., Bais, H.P., Vivanco, J.M., 2002. Chemical characterization of basil (Ocimum basilicum L.) found in local accessions and used in traditional medicines in Iran. Journal of Agricultural and Food Chemistry. 50, 5878–5883.
Krupa-Malkiewicz, M., Fornal, N., 2018. Application of chitosan In Vitro to minimize the adverse effects of salinity in Petunia × atkinsiana D. don. Journal of Ecological Engineering. 19, 143-149.
Labra, M., Miele, M., Ledda, B., Grassi, F., Mazzei, M., Sala, F., 2004. Morphological characterization, essential oil composition and DNA genotyping of Ocimum basilicum L. cultivars, Plant Science. 167, 725-731.
Lianju, M., Yueying, L., Cuimei, Y., Yan, W., Xuemei, L., Na, L., Qiang, C., Ning, B., 2011. Alleviation of exogenous oligochitosan on wheat seedlings growth under salt stress. Protoplasma. 249, 393-399.
Mahdavi, B., 2013. Seed germination and growth responses of Isabgol (Plantago ovata Forsk) to chitosan and salinity. International Journal of Agriculture and Crop Sciences. 5, 1084-1088.
Mahdavi, B., Safari, H., 2015. Effect of chitosan on growth and some physiological characteristics in chickpea under salinity stress condition. Journal of Plant Process and Function. 12, 117-127. [In Persian with English Summary]
Mastouri, F., Björkman, T. H., Harman. G. E. 2010. Seed treatment with Trichoderma harzianum alleviates biotic, abiotic, and physiological stresses in germinating seeds and seedlings. Biological control. 11, 1213-1221.
Mazhabi, M., Nemati, H., Rouhani, H., Tehranifar, A., Moghadam, E.M., Kaveh, H., Rezaee. A., 2011. The effect of Trichoderma on polianthes qualitative and quantitative properties. The Journal of Animal and Plant Sciences. 21, 617-621.
Mosapour Yahyaabadi, H., Asgharipour, M.R., Basiri, M., 2016. Role of chitosan in improving salinity resistance through some morphological and physiological characteristics in fenugreek (Trigonella foenum-graecum L.). Journal of Science and Technology. Greenhouse Culture. 7, 175-184
Oliveira, H.C., Gomes, B.C., Pelegrino, M.T., Seabra, A.B. 2016. Nitric oxide-releasing chitosan nanoparticles alleviate the effects of salt stress in maize plants. Nitric Oxide. 61, 10–19
Ozcan, M., Derya, A.M., Unver, A., 2005. Effect of drying methods on ral the minecontent of basil (Ocimum basilicum). Journal of Food Engineering. 69, 375-379.
Paul, E.A., Clark, F.E., 1989. Soil Microbiology and Biochemistry, Academic Press, London
Polma, P., Jakson, K. Merivee, A., Albert, A., 2000. Trichoderma viride promotes growth of cucumber plants. Proceeding of the International Conference on Development of Environment Friendly protection in the Baltic Region, Transition of Estonian Agriculture University. 209, 162-164, Tartu, Estonia.
Rasponti, E., Cacciola, S.O., Gotor, C., Romero, L.C., Garci, I., 2009. Implications of steine metabolism heavy metal response in Trichoderma harizanum and in three fusarium species, chemosphere.76, 5460-5470.
Reggiani, R., Bozo, S., Bertani, A., 1995. The effects of salinity on early seeding growth of seeds of three wheat cultivar. Canadian Journal of Plant Science. 75, 175-177.
Rodriguez, P., Torrecillas, A., Morales, M.A., Ortuno M.F., Sanchez-Blanco, M.J., 2005. Effects of NaCl salinity and water stress on growth and leaf water relations of Asteriscus Maritimus plants. Environmental and Experimental BotanyJournal. 53, 113-123.
Sadrzade Aghajani, F., Pirdashti, H., Bakhshi Khaniki, Gh. 2013. Effect of Bacteria growth stimulus PGPR and Trichoderma harzianum on nitrogen absorb and some growth characterstics on Basil (Ocimum basilicum) under cadmium toxicity. First Abiotic Plant Stress Conference. [In Persian with English Summary]
Salimi Tamalla, N., Seraj, F., Pirdashti, H., Yaghoubian, Y., 2014. The effect of seed biopriming by Piriformospora indica and Trichoderma virens on the growth, morphological and physiological parameters of mung bean (Vigna radiate L.) seedlings. Seed Science Research. 1, 75-90. [In Persian, With English abstract]
Selvaraj, T., Sumithra, P., 2011. Effect of Glomus aggregatum and plant growth promoting rhizomicroorganisms on growth, nutrition and content of secondary metabolites in Glycyrrhiza glabra L. Indian Journal of Applied and Pure Biology. 26, 283–290.
Seraj, F., Salimi Tamali, N., Pirdashti, H., Yaghoubian. Y., 2018. The response of wheat (Triticum aestivum L.) vegetative and physiological attributes to salt stress and effect of seed biopriming by Piriformospora indica and Trichoderma virens in improving salinity compatibility. Iranian Journal of Seed Science and Technology. 6, 77-90. [In Persian with English Summary]
Sheikha, S.A.A.K., AL-Malki, F.M., 2011. Growth and chlorophyll responses of bean plants to the chitosan applications. European Journal of Scientific Research. 50, 124-134.
Tuncturk, M., Tuncturk, R., Yildirim, B., Ciftci, V. 2011. Effect of salinity stress on plant fresh weight and nutrient composition of some Canola (Brassica napus L.) cultivars. African Journal of Biotechnology. 10, 1827–1832.
Van-Hulten, M., Pelser, M., Van-Loon, L.C., Pieterse, C.M.J., Ton, J., 2006. Costs and benefits of priming for defense in Arabidopsis. Proceeding of National Academy of Science. U.S.A. 103, 5602–5607.
Vessey, J.K., 2003. Plant growth promoting rhizobacteria as biofertilizers. Plant and Soil. 255, 571-586.
Watt, M., Magee L.J., McCully, M.E., 2008. Types, structure and potential for axial water flow in thedeepest roots of field-grown cereals. New Phytology. 178, 135-146
Xue-Lin, L., Zhong-Xu, L., Yi-Chun, N., Xiao-Ping, G., Xian-Long, Z., 2009. Methylationsensitive amplification polymorphism of epigenetic changes in cotton under salt stress. Acta Agronomica Sinence. 35, 588-596.
Yarnia, M., Heydari Sharif Abad, H., Hashemi Dezfuli, A., Rahim Zadeh Khui F., ghalavand, A., 2011. Evaluation of tolerance to salinity in alfalfa lines (Medicago sativa L.). Journal of Agriculture Science. 3, 12-26. [In Persian with English Summary]
Yazdani, M., Pirdashti, H., Tajik, M.A., Bahmanyar, M.A., 2008. Effect of Trichoderma spp. and different organic manures on growth and development in soybean (Glycine max L. Merril). Electeronic Journal of Crop Production. 1, 65-82. [In Persian with English Summary]