NaCl affects lipids peroxidation and oxygen free radicals scavenging machinery in callus tissues of a cultivated (Solanum macrocarpon L.) and a wild Eggplant (Solanum dasyphyllum L.)
Abstract
Background: In vitro techniques are an efficient tool to select salt tolerant lines in several plant species. The impacts of increasing salt concentration on membrane lipids oxidation and oxygen free radicals scavenging enzymes were evaluated in the callus of a cultivated eggplant (Solanum macrocarpon L.) and Wild Eggplant (Solanum dasyphyllum L.)
Methods: A salt stress ranging from 40 to 160 mM NaCl was imposed to callus of S. macrocarpon ‘Akwaseho’, a cultivated African eggplant and callus of S. dasyphyllum var dasyphyllum, a putative wild ancestor, for 40 days. Selected callus physiology and biochemistry features were investigated after 40 days of growing both species in MS medium added with NaCl at the concentration of 0 (control), 40, 80, 120 and 160 mM.
Results: A close correlation was observed between rising salinity level and the enhancement of proline accumulation. Callus of S. dasyphyllum var dasyphyllum succeeded efficiently in keeping higher K+, lower Na+ rate and Na+/K+ ratio than S. macrocarpon L. Ion content can be considered as useful tool to select salt tolerant callus tissue. Under saline condition, S. dasyphyllum L. showed lower amounts of malondialdehyde (MDA) and H2O2 but higher activity for superoxide dismutase (SOD), catalase (CAT), guaiacol peroxidase (GPX) and ascorbate peroxidase (APX) than S. macrocarpon L. in both case control and NaCl treatments.
Conclusion: The current study concluded that the two species responded differently to salinity induced oxidative damage. S. dasyphyllum L. callus showed more effective antioxidant defense system, which contributes, to better adaptive and protective capacity against salinity induced oxidative impairment by keeping more intense antioxidant enzymes activities than S. macrocarpon L. callus.
Keywords: Salinity; Tissue Culture; Oxygen Free Radicals; Eggplant
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Mohamed Elhag. Evaluation of Different Soil Salinity Mapping Using Remote Sensing Techniques in Arid Ecosystems, Saudi Arabia, Journal of Sensors, (2016); 2016: 8.
Munns R, Gilliham M. Salinity tolerance of crops—what is the cost? New Phytoligist, (2015); 208:668–673.
Forni C, Duca D, Glick BR. Mechanisms of plant response to salt and drought stress and their alteration by rhizobacteria. Plant Soil, (2017); 410: 335–356
Golkar P., Amooshahi, F., Arzani, A. The effects of salt stress on physio-biochemical traits, total phenolic and mucilage content of Plantago ovata Forsk under in vitro conditions. Journal of Applied Botany and Food Quality, (2017); 90, 224 – 231.
Al Khateeb AA, Sattar MN, Mohmand AS. Induced in vitro adaptation for salt tolerance in date palm (Phoenix dactylifera L.) cultivar Khalas. Biological Research, (2020); 53: 37.
Aghaleh M, Niknam, V, Ebrahimzadeh, H, Razavi, K. Salt stress effects on growth, pigments, proteins and lipid peroxidation in Salicornia persica and S. europaea. Biologia Plantarum, (2009); 53: 243–248.
Nikam AA, Devarumath RM, Shitole MG. Gamma radiation, in vitro selection for salt (NaCl) tolerance, and characterization of mutants in sugarcane (Saccharum officinarum L.). In Vitro Cellular & Developmental Biology – Plant, (2014); 50: 766–776.
Dita MA, Rispai N, Prats E, Rubiales D, Singh KB. Biotechnology approaches to overcome biotic and abiotic stress constraints in legumes. Euphytica, (2006); 147: 1–24.
Munns R, Tester M. Mechanisms of salinity tolerance. Annual Review of Plant Biology, (2008); 59: 651–681.
Koc NK, Bas B, Koc M, Kusek M. Investigations of in vitro selection for salt tolerant lines in sour orange (Citrus aurantium L.). Biotechnology, (2009); 8: 155–159.
Rout GR, Senapati SK, Panda JJ. Selection of salt tolerant plants of Nicotiana tabacum L. through invitro and its biochemical characterization. Acta Biologia Hung, (2008); 59: 77–92.
Vaidyanathan H, Sivakumar P, Chakrabarty R, Thomas G. Scavenging of reactive oxygen species in NaCl-stressed rice (Oryza sativa L.) differential response in salt-tolerant and sensitive varieties. Plant Science, (2003); 165: 1411–1418.
Zhang F, Yang YL, He WL, Zhao X, Zhang X. Effects of salinity on growth and compatible solutes of callus induced from Populus euphratica. In Vitro Cell Development Biology-Plant, (2004); 40: 491–494.
Chance B, Maehly AC. Assay of catalases and peroxidases. Methods of Biochemical Analysis, (1955); 2:764–775.
Locato V, De Gara L. Plant programmed cell death: an overview. Methods in Molecular Biology, (2018); 1743: 1–8.
Formentin E, Sudiro C, Ronci MB, Locato V, Barizza E, Stevanato P, Ijaz B, Zottini M, De Gara L, Lo Schiavo F. H2O2 Signature and Innate Antioxidative Profile Make the Difference Between Sensitivity and Tolerance to Salt in Rice Cells. Front Plant Science, (2018); 9:1549.
Azevedo Neto AD, Prisco JT, Eneas-Filho J, de Abreu CEB, Gomes-Filho E. Effect of salt stress on antioxidative enzymes and lipid peroxidation in leaves and roots of salttolerant and salt-sensitive maize genotypes. Environmental and Experimental Botany, (2006)5: 87–94.
Kusvuran S, Ellialtioglu S, Yasar F, Abak K. Effects of salt stress on ıon accumulations and some of the antioxidant enzymes activities in melon (Cucumis melo L.), International Journal of Food and Agriculture, (2007); 2(5): 351-354.
Sudhakar C, Lakshmi A, Giridarakumar S. Changes in the antioxidant enzyme efficacy in two high yielding genotypes of mulberry (Morus alba L.) under NaCl salinity. Plant Science, (2001); 161:613–619.
Ünlükara A, Kurunç A, Kesmez GD, Yurtseven E, Suarez DL. Effects of Salinity on Eggplant (Solanum Melongena L.) Growth and Evapotranspiration. Journal of Irrigation and Drainage Engineering, (2008); 59: 203-214
Bukenya ZR, Hall JB. Six cultivars of Solanum macrocarpon (Solanaceae) in Ghana. Bothalia, (1987); 17: 91–95.
Bukenya ZR, Carasco JF. Crossability and cytological studies in Solanum macrocarpon and Solanum linnaeanum (Solanaceae). Euphytica, (1985); 86: 5–13.
Knapp S, Vorontsova MSA. revision of the “African non-spiny” clade of Solanum L. (Solanum sections Afrosolanum Bitter, Benderianum Bitter, Lemurisolanum Bitter, Lyciosolanum Bitter, Macronesiotes Bitter, and Quadrangulare Bitter: Solanaceae). PhytoKeys, (2016); 66: 1–142.
Yasar F, Ellialtioglu S. Antioxidative Responses of Some Eggplant Genotypes to Salinity Stress YYU Journal of Agricultural Science, (2013); 23: 215-221
Brenes M, Pérez J, González-Orenga S, Solana A, Boscaiu M, Prohens J, Plazas M, Fita A, Vicente O. Comparative Studies on the Physiological and Biochemical Responses to Salt Stress of Eggplant (Solanum melongena) and Its Rootstock S. torvum. Agriculture, (2020); 10: 328.
Murshige T, Skoog F. A revised medium for rapid growth and bioassays with tobacco tissue cultures. Plant Physioly, (1962); 15:473-97.
Sairam RK, Srivastava GC. Changes in antioxidant activity in subcellular fractions of tolerant and susceptible wheat genotypes in response to long term salt stress. Plant Science, (2002); 162: 897–904.
Bates LS, Waldran RP, Teare ID. Rapid determination of free proline for water stress. Plant Soil, (1973); 39, 205-208.
Skoog DA, West DM, Holler FJ, Crouch SR. Analytical Chemistry: An Introduction, New Age International PVT, UK, (1973); 594-631.
Velikova V, Yordanov I, Edreva A. Oxidative stress and some antioxidant systems in acid rain-treated bean plants: protective role of exogenous polyamines. Plant Science, (2000); 151: 59–66
Hodges DM, Delong JM, Forney FC, Prange RK. Improving the thiobarbituric acidreactive- substances assay for estimating lipid peroxidation in plant tissues containing anthocyanin and other interfering compounds. Planta, (1999); 207:604– 611.
Bradford MM. A rapid and sensitive method for the quantitation of microgram quantities of protein utilizing the principle of protein-dye binding. Analytical Biochemistry, (1976); 72: 248–254.
Beauchamp C, Fridovich I. Superoxide dismutase improved assays and an assay applicable to acrylamide gels. Analytical Biochemistry, (1971); 44:276–287.
Nakano Y, Asada K. Hydrogen peroxide is scavenged by ascorbate-specific peroxidase in spinach chloroplasts. Plant Cell Physiology, (1981); 22:867–880
Aebi H. Catalases. In: Bergmeyer H. U. (ed) Methods of enzymatic analysis, vol. 2. Academic Press, New York, (1974); 673–684.
Abed Alrahman NM, Shibli RA, Ereifej KI, Hindiyeh MY. Influence of salinity on growth and physiology of in vitro grown cucumber (Cucumis sativus L.). Jordanian Journal of Agricultural Science, (2005); 1: 93–106.
Sotiropoulos TE, Dimassi KN, Tsirakoglou V, Therios IN. Response of two Prunus rootstocks to KCl induced salinity in vitro. Biologia Plantarum, (2006); 50: 477-480.
Ibrahim MA, Jerry AN, Khalil AI. Effect of salt stress on some chemicals characteristics of callus for three cultivars of potato plant (Solanum tuberosum L.). AAB Bioflux, (2018); 10(2):87-96
Rejeb KB, Abdelly C, Savouré A. How reactive oxygen species and proline face stress together. Plant Physiology and Biochemistry, (2014); 80: 278–284.
Santangeli M, Capo C, Beninati S, Pietrini F, Forni C. Gradual Exposure to Salinity Improves Tolerance to Salt Stress in Rapeseed (Brassica napus L.). Water, (2019); 11: 1667.
Beloualy N, Bouharmont J. NaCl-tolerant plants of Poncirus trifoliata regenerated from tolerant cell lines. Theoretical and Applied Genetics, (1992); 83: 509–514
Marcum KB, Yensen NP, Leake JE. Genotypic variation in salinity tolerance of Distichlis spicata turf ecotypes. Australian Journal of experimental Agriculture, (2007); 47(12): 1506-1511
Ganie SA, Molla KA, Henry RJ, et al. Advances in understanding salt tolerance in rice. Theoretical and Applied Genetics, (2019); 132:851–70.
Pessarakli M, Tucker TC. Dry Matter Yield and Nitrogen-15 Uptake by Tomatoes under Chloride Stress. Soil Fertility and Plant Nutrition, (1988); 52: 698-700.
Masood A, Ahmad SN, Zeeshan M, Abraham G. Differential response of antioxidant enzymes to salinity stress in two varieties of Azolla (Azolla pinnata and Azolla filiculoides). Environmental and Experimental Botany, (2006); 58: 216–222.
Sevengor S. Investigations on antioxydant enzyme activities under in vitro and in vivo conditions to obtain salt tolerance in squash (Cucurbita pepo L.). Ph.D.Thesis, Ankara Universitiy, Graduate School of Natural and Applied Sciences, Ankara, (2010); p. 17.
Shigeoka S, Ishikawa T, Tamoi M, Miyagawa Y, Takeda T, Yabuta Y, Yoshimura K. Regulation and function of ascorbate peroxidase isoenzymes. Journal of Experimental Botany, (2002) ;53:1305–1319
Lopez MV, Satti SME. Calcium and Potassium- Enhanced Growth and Yield of Tomato Under Sodium Chloride Stress. Plant Science, (1996); 114: 19-27.
Kukreja S, Nandwal AS, Kumar N, Sharma SK, Unvi V, Sharma PK. Plant water status, H2O2 scavenging enzymes, ethylene evolution and membrane integrity of Cicer arietinum roots as affected by salinity. Biologia Plantarum, (2005); 49: 305–308.
Eyidogan F, Öz MT. Effect of salinity on antioxidant responses of chickpea seedlings. Acta Physiologia Plantarum, (2007); 29: 485–493.
Kusvuran S. Relationships between physiological mechanisms of tolerances to drought and salinity in melons. PhD Thesis, Department of Horticulture, Institute of Natural and Applied Sciences, University of Cukurova, Turkey, (2007); p.356
Roychoudhury A, Basu S, Sengupta DN. Antioxidants and stress related metabolites in the seedlings of two indica rice varieties exposed to cadmium chloride toxicity. Acta Physiologia Plantarum. (2012c); 34: 835–847.
Gapiñska M, Skłodowska M, Gabara B. Effect of short-and longterm salinity on the activities of antioxidative enzymes and lipid peroxidation in tomato roots. Acta Physiologia Plantarum, (2008); 30, 11–18.
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