Salt stress changes biochemical, physiological and photosynthetic attributes of Satureja spicigera
Subject Areas : Stress PhysiologyHoshangh Rahmati 1 , Borzou Yousefi 2
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Keywords: Antioxidant activity, Medicinal plants, Photosynthesis, Salt stress ,
Abstract :
We investigated the effect of salt stress on photosynthetic, physiological, and biochemical traits of Satureja spicigera (C. Koch) Boiss., a medicinal plant used in edible products and healthcare industries. The experiment was designed in a randomized complete block design (RCB) with three replications in a greenhouse. The salt treatments included four levels of NaCl (0, 50, 100, and 150 mM). Results showed that salinity levels caused a significant reduction in some photosynthetic, morpho-physiological, physiological, and biochemical characteristics; however, it boosted antioxidant activity. Salinity levels significantly reduced leaf fresh weight (12.56%), leaf dry weight (18.53%), relative water content (11.94%), chlorophyll a (33.33%), chlorophyll b (15.62%), chlorophyll a+b (29.24%), and carotenoid content (42.46%). However, salinity significantly boosted the antioxidant activity of superoxide dismutase (236.50%), peroxidase (85.67%), and catalase (82.78%) on average. Salt stress also significantly increased proline content (373.33%), protein content (84.49%), and leaf electrical conductivity (333.26%) on average. Results confirm that S. spicigera tolerates NaCl concentrations below 100 mM; however, it is highly sensitive to NaCl concentrations above 100 mM, so that a salinity of 150 mM causes a dramatic decrease in photosynthesis and growth. Therefore, we do not recommend the cultivation of this plant in highly saline and semi-saline soils.
Afridi, M. S., T. Mahmood, A. Salam, T. Mukhtar, S. Mehmood, J. Ali, Z. Khatoon, M. Bibi, M. T. Javed and T. Sultan. 2019. Induction of tolerance to salinity in wheat genotypes by plant growth promoting endophytes: Involvement of ACC deaminase and antioxidant enzymes. Plant Physiology and Biochemistry, 139, 569-577.
Ahad, B., W. Shahri, H. Rasool, Z. Reshi, S. Rasool and T. Hussain. 2021. Medicinal plants and herbal drugs: An overview. Medicinal and aromatic plants: healthcare and industrial applications, 1-40.
Athar, H.-U.-R., F. Zulfiqar, A. Moosa, M. Ashraf, Z. U. Zafar, L. Zhang, N. Ahmed, H. M. Kalaji, M. Nafees and M. A. Hossain. 2022. Salt stress proteins in plants: An overview. Frontiers in Plant Science, 13, 999058.
Balasubramaniam, T., G. Shen, N. Esmaeili and H. Zhang. 2023. Plants’ response mechanisms to salinity stress. Plants, 12, (12) 2253.
Bates, L. S., R. Waldren and I. Teare. 1973. Rapid determination of free proline for water-stress studies. Plant and soil, 39, 205-207.
Beauchamp, C. and I. Fridovich. 1971. Superoxide dismutase: improved assays and an assay applicable to acrylamide gels. Analytical biochemistry, 44, (1) 276-287.
Bian, S. and Y. Jiang. 2009. Reactive oxygen species, antioxidant enzyme activities and gene expression patterns in leaves and roots of Kentucky bluegrass in response to drought stress and recovery. Scientia Horticulturae, 120, (2) 264-270.
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, (1-2) 248-254.
Chance, B. and A. Maehly. 1955. [136] Assay of catalases and peroxidases.
Fabriki, O. S. and P. S. Mehrabad. 2016. The effects of drought and salt stresses on some morphological and biochemical parameters of savory (Satureja hortensis L.), 23-35.
Garcia-Caparros, P., L. De Filippis, A. Gul, M. Hasanuzzaman, M. Ozturk, V. Altay and M. T. Lao. 2021. Oxidative stress and antioxidant metabolism under adverse environmental conditions: a review. The Botanical Review, 87, 421-466.
Ghanbari, F., M. Bag-Nazari and A. Azizi. 2023. Exogenous application of selenium and nano-selenium alleviates salt stress and improves secondary metabolites in lemon verbena under salinity stress. Scientific Reports, 13, (1) 5352.
Hao, S., Y. Wang, Y. Yan, Y. Liu, J. Wang and S. Chen. 2021. A review on plant responses to salt stress and their mechanisms of salt resistance. Horticulturae, 7, (6) 132.
Harati, E., B. Kashefi and M. Matinzadeh. 2015. Investigation reducing detrimental effects of salt stress on morphological and physiological traits of (Thymus vulgaris) by application of salicylic acid. Iranian Journal of Plant Physiology, 5, (3) 1383-1391.
Hernández-Adasme, C., R. Palma-Dias and V. H. Escalona. 2023. The effect of light intensity and photoperiod on the yield and antioxidant activity of beet microgreens produced in an indoor system. Horticulturae, 9, (4) 493.
Jan, R., S. Asaf, M. Numan, Lubna and K.-M. Kim. 2021. Plant secondary metabolite biosynthesis and transcriptional regulation in response to biotic and abiotic stress conditions. Agronomy, 11, (5) 968.
Jini, D. and B. Joseph. 2017. Physiological mechanism of salicylic acid for alleviation of salt stress in rice. Rice Science, 24, (2) 97-108.
Kulak, M. 2020. Recurrent drought stress effects on essential oil profile of Lamiaceae plants: An approach regarding stress memory. Industrial Crops and Products, 154, 112695.
Kumar, R., A. Bohra, A. K. Pandey, M. K. Pandey and A. Kumar. 2017. Metabolomics for plant improvement: status and prospects. Frontiers in Plant Science, 8, 1302.
Kumar, S., M. A. Ahanger, H. Alshaya, B. L. Jan and V. Yerramilli. 2022. Salicylic acid mitigates salt induced toxicity through the modifications of biochemical attributes and some key antioxidants in Capsicum annuum. Saudi Journal of Biological Sciences, 29, (3) 1337-1347.
Lichtenthaler, H. K. and A. R. Wellburn. 1983. Determinations of total carotenoids and chlorophylls a and b of leaf extracts in different solvents. Portland Press Ltd.
Mohammadi, H., S. Hazrati and L. Parviz,2019. Morphophysiological and biochemical response of savory medicinal plant using silicon under salt stress. Proc. Annales Universitatis Mariae Curie-Sklodowska, sectio C–Biologia, 72:29-40:
Reddy, A. R., K. Chaitanya, P. Jutur and K. Sumithra. 2004. Differential antioxidative responses to water stress among five mulberry (Morus alba L.) cultivars. Environmental and experimental botany, 52, (1) 33-42.
Saadatfar, A. and S. H. Jafari. 2024. Application of 24-epibrassinolide as an Environmentally Friendly Strategy Alleviates Negative Effects of Salinity Stress in Satureja khuzistanica Jamzad. Journal of Rangeland Science, 14, (3).
Shanker, A. K., D. Gunnapaneni, D. Bhanu, M. Vanaja, N. J. Lakshmi, S. K. Yadav, M. Prabhakar and V. K. Singh. 2022. Elevated CO2 and water stress in combination in plants: brothers in arms or partners in crime? Biology, 11, (9) 1330.
Sheldon, A. R., R. C. Dalal, G. Kirchhof, P. M. Kopittke and N. W. Menzies. 2017. The effect of salinity on plant-available water. Plant and Soil, 418, 477-491.
Sinha, A. K. 1972. Colorimetric assay of catalase. Analytical biochemistry, 47, (2) 389-394.
Srivastava, S. and P. Sharma. 2021. Effect of NaCl on chlorophyll fluorescence and thylakoid membrane proteins in leaves of salt sensitive and tolerant rice (Oryza sativa L) varieties. Journal of Stress Physiology & Biochemistry, 17, (2) 35-44.
Wang, Y., W. Ma, H. Fu, L. Li, X. Ruan and X. Zhang. 2023. Effects of salinity stress on growth and physiological parameters and related gene expression in different ecotypes of Sesuvium portulacastrum on Hainan Island. Genes, 14, (7) 1336.
Zarei, B., A. Fazeli and Z. Tahmasebi. 2019. Salicylic acid in reducing effect of salinity on some growth parameters of Black cumin (Nigella sativa). Journal of Plant Process and Function, 8, (29) 287-298.
Zhang, M., Y. Fang, Y. Ji, Z. Jiang and L. Wang. 2013. Effects of salt stress on ion content, antioxidant enzymes and protein profile in different tissues of Broussonetia papyrifera. South African journal of botany, 85, 1-9.