The Effects of Foliar Application of Chitosan-Salicylic Acid Nanocomposite on Mentha spicata L. under Salinity Stress in Hydroponic Conditions

Hassanpouraghdam, Mohammad Bagher; Mohammadi, Leila; Gohari, Gholamreza; Vojodi Mehrabani, Lamia

doi:10.22034/iuvs.2022.546245.1189

The Effects of Foliar Application of Chitosan-Salicylic Acid Nanocomposite on Mentha spicata L. under Salinity Stress in Hydroponic Conditions

Document Type : Original Article

Authors

Mohammad Bagher Hassanpouraghdam ¹

Leila Mohammadi ²

Gholamreza Gohari ³

Lamia Vojodi Mehrabani ⁴

¹ Associate Professor, Department of Horticultural Sciences, Faculty of Agriculture, University of Maragheh, Maragheh, Iran

² M.Sc. Graduate, Department of Horticultural Sciences. Faculty of Agriculture, University of Maragheh, Maragheh, Iran

³ Associate Professor, Department of Horticultural Sciences. Faculty of Agriculture, University of Maragheh, Maragheh, Iran

⁴ Associate Professor, Department of Agronomy and Plant Breeding, Azarbaijan Shahid Madani University, Tabriz, Iran

10.22034/iuvs.2022.546245.1189

Abstract

Introduction: Mentha spicata is one of the most widely consumed vegetables that is grown commercially worldwide. The essential oil and extracts of Mentha spicata are used in the cosmetics, food, and pharmaceutical industries. Salinity is one of the most important abiotic stresses that endanger plant growth and productivity. Salinity stress reduces the plant's capacity to absorb water, creates ion imbalances, and induces oxidative stress in the plant due to the accumulation of ions such as sodium and chlorine at toxic levels in cells and tissues. Salicylic acid plays an important role in improving physiological activities and increasing plant resistance to biotic and abiotic stress factors. Chitosan as a biostimulant can improve plant growth and yield. Furthermore, the combined application of salicylic acid and chitosan is believed to ameliorate the salinity defects more efficiently. This study aimed to investigate the application of chitosan-salicylic acid nanocomposite under salinity stress on the growth and some physiological traits of Mentha spicata in hydroponic culture.
Matrrials and Methods: To investigate the effects of different levels of salinity stress and application of chitosan-salicylic acid nanocomposite on the morphological and physiological traits of M. spicata, a factorial pot experiment based on a completely randomized design with four replications was performed at the University of Maragheh, Iran during 2019. Treatments used in this experiment included salicylic acid (1 mM), chitosan (10 mg L^-1), an aqueous mixture of chitosan and salicylic acid (1 mM and 10 mg L^-1), and 1% w/v chitosan-salicylic acid nanocomposite.
Results and Discussion: Salinity reduced the height of M. spicata compared to the control plants. However, foliar application of chitosan-salicylic acid nanocomposite improved plant growth and increased plant height under non-salinity conditions and different salinity levels compared to the controls. Salinity stress significantly reduced the fresh and dry weight of the M. spicata. The highest leaf chlorophyll index (56.9) was related to the treatment of 1% w/v of the chitosan-salicylic acid nanocomposite. The highest amount of proline (20.6 µmol g^-1 fresh weight) was related to the treatment of an aqueous mixture of chitosan and salicylic acid at a salinity level of 100 mM sodium chloride. The highest content of malondialdehyde (2.93 nmol g^-1 fresh weight) was obtained in the treatment without foliar application and a salinity level of 100 mM. The highest protein content (1.81 mg g^-1) was related to the treatment with 1% chitosan-salicylic acid nanocomposite and the treatment without salinity stress. Otherwise, the lowest amount (0.858 mg g^-1) for protein content belonged to the control and salinity of 100 mM. With increasing salinity levels, H₂O₂ content in the plant tissues increased. So that, the highest content for H₂O₂ was observed in the treatment without foliar application and salinity level of 100 mmol and, the lowest H₂O₂ content was recorded in the control treatment (without foliar application and salinity).
Conclusions: The overall results revealed that salinity stress had a detrimental effect on the growth and some physiological traits of the Mentha spicata L., but the foliar application of salicylic acid and chitosan alone or in combination had a promising role in reducing the effects of salinity stress on the M. spicata. Considering the progressive salinity stress incidence in many parts of the world and Iran, it seems that the results of the present study can be proposed to the agricultural extension sections to use the resulting mixture in plant breeding programs under saline areas to possibly reduce the salinity adverse effects.

Keywords

Bio-stimulant

H2O2

Malondialdehyde

Proline

20.1001.1.26764814.1400.5.2.3.5

Abdelhameed, R. E., Abdel Latef, A. A. H. & Shehata, R. S. (2021). Physiological responses of salinized fenugreek (Trigonellafoenum-graecum) plants to foliar application of aalicylic acid. Plants, 10, 657.
Arnon, A. N. (1967). Method of extraction of chlorophyll in the plants. Agronomy Journal,23, 112-121.
Bates, L. S., Waldren, R. P. & Teare, I. D. (1973). Rapid determination of free proline for water-stress studies. Plant and Soil, 39, 205-207.
Bradford, M. M. (1976). A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry, 72, 248-254.
Coban, O. & Baydar, N. G. (2016). Brassinosteroid effects on some physical and biochemical properties and secondary metabolite accumulation in Peppermint (Mentha piperita) under salt stress. Industrial Crops and Products, 86, 251-258.‏
Es-sbihi, F. Z., Hazzoumi, Z., Aasfar, A. & Amrani Joutei, K. (2021). Improving salinity tolerance in Salvia officinalis by foliar application of salicylic acid. Chemical and Biological Technologies in Agriculture, 8, 1-12.
Gacnik, S., Veberic, R., Hudina, M., Marinovic, S. & Halbwirth, H. (2021). Methyl salicylic acid affect quality and phenolic apple fruit three weeks before the harvest. Plants, 10, 1807.
Gohari, R. & Bahrami, M. K. (2020). Effects of chitosan as growth elicitor on some growth parameters and essential oils yield of Dracocephalium moldavica L. under salinity condition. Journal of Agricultural Science and Sustainable Production, 30(1), 155-169.
Gorni, P. H., Pacheco, A. C., Moro, A. L., Silva, J. F. A., Moreli, R. R., de Miranda, G. R. & da Silva, R. M. G. (2020). Salicylic acid foliar application increases biomass, nutrient assimilation, primary metabolites and essential oil content in Achillea millefolium Scientia Horticulturae, 270, 109436.‏
Gorni, P. H. & Pacheco, A. C. (2016). Growth promotion and elicitor activity of salicylic acid in Achillea millefolium African Journal of Biotechnology, 15, 657-665.
Hassan, F. A. S., Ali, E., Gaber, A., Fetouh, M. I. & Mazrou, R. (2021). Chitosan nanoparticles effectively combat salinity stress by enhancing antioxidant activity and alkaloid biosynthesis in Catharanthus roseus (L.) G. Don. Plant Physiology and Biochemistry, 162, 291-300.‏
Hasanpour, M., Jafari, H., Sharifi, S., Rezaiee, J., Mehri Lighvan, Z., Mahdavinia, G. R., Gohari, G. R. & Akbari, A. (2021). Salicylic acid-loaded chitosan nanoparticles (SA/CTS NPs) for breast cancer targeting: synthesis, characterization and controlled release kinetics. Journal of Molecular Structure, 1245, 40-50.
Heath, R. L. & Packer, L. (1968). Photoperoxidation in isolated chloroplasts: I. kinetics and stoichiometry of fatty acid peroxidation. Archives of Biochemistry and Biophysics,125, 189-198.
Kadam, P. M., Prajapati, D., Kumaraswamy, R. V., Kumari, S., Devi, K. A., Pal, A. & Saharan, V. (2021). Physio-biochemical responses of wheat plant towards salicylic acid-chitosan nanoparticles. Plant Physiology and Biochemistry, 162, 699-705.‏
Khan, A., Numan, M., Khan, A. L., Lee, I. J., Imran, M., Asaf, S. & Al-Harrasi, A. (2020). Melatonin: Awakening the defense mechanisms during plant oxidative stress. Plants, 9, 407.
Khan, N., Bano, A., Rahman, M. A., Rathinasabapathi, B. & Babar, M. A. (2019). UPLC‐HRMS‐based untargeted metabolic profiling reveals changes in Chickpea (Cicer arietinum) metabolome following long‐term drought stress. Plant, Cell & Environment, 42, 115-132.
Kibria, M. G. & Hoque, M. A. (2019). A review on plant responses to soil salinity and amelioration strategies. Open Journal of Soil Science, 9, 219.
Kumaraswamy, R. V., Kumari, S., Choudhary, R. C., Sharma, S. S., Pal, A., Raliya, R., Biswas, P. & Saharan, V. (2019). Salicylic acid functionalized chitosan nanoparticle: a sustainable biostimulant for plant. International Journal of Biological Macromolecules, 123, 59-69.
Kundu, M., Halder, S. & Bhattacharjee, A. (2018). Salicylic acid-induced modulation of growth and metabolism of a medicinal plant Mentha Spicata International Journal of Pharmaceutical Sciences and Research, 9, 5294-5300.
Mahendran, G., Verma, S. K. & Rahman, L. U. (2021). The traditional uses, phytochemistry and pharmacology of spearmint (Mentha spicata): A review. Journal of Ethnopharmacology, 278, 114266.
Safikhan, S., Khoshbakht, K., Chaichi, M. R., Amini, A. & Motesharezadeh, B. (2018). Role of chitosan on the growth, physiological parameters and enzymatic activity of milk thistle (Silybum marianum (L.) Gaertn.) in a pot experiment. Journal of Applied Research on Medicinal and Aromatic Plants, 10, 49-58.‏
Sanjary-Mijani, M., Syrosmehr, A. & Fakhery, B. (2015). Effect of drought stress and humic acid on some physiological characteristics of Hibiscus (Hibiscus sabdarifa). Crops Improvement, 2, 403-414.
Shahid, M. A., Sarkhosh, A., Khan, N., Balal, R. M., Ali, S., Rossi, L., Gomez, C., Mattson, N., Nasim, W. & Garcia-Sanchez, F. (2020). Insights into the physiological and biochemical impacts of salt stress on plant growth and development. Agronomy, 10, 938.
Sinha, S., Saxena, R. & Singh, S. (2005). Chromium induced lipid peroxidation in the plants of Pistia stratiotes: role of antioxidants and antioxidant enzymes. Chemosphere,58, 595-604.
Vojodi Mehrabani, L., Hassanpouraghdam, M. B. & Shamsi-Khotab, T. (2018). The effects of common and nano-zinc foliar application on the alleviation of salinity stress in Rosmarinus officinalis Acta Scientiarum Polonorum Hortorum Cultus, 17(6), 65-73.
Zeeshan, M., Lu, M., Sehar, S., Holford, P. & Wu, F. (2020). Comparison of biochemical, anatomical, morphological, and physiological responses to salinity stress in Wheat and Barley genotypes deferring in salinity tolerance. Agronomy, 10, 127.