Evaluation of Foliar Spraying of Zinc and Calcium Fertilizers on Yield and Physiological Traits of Safflower under Lead Stress

Document Type : Research Article

Authors

1 Shahrood University of Technology

2 Graduate University of Advanced Technology, Kerman

3 Agricultural and Natural Resources Research and Education center of Kerman

Abstract

Introduction In order to evaluate the effect of foliar spraying of zinc and calcium on yield and physiological traits of safflower under lead stress, a factorial experiment based on randomized complete block design was performed in Kerman agricultural and natural resource research and education center in 2014-2015 with three replications. The first factorial included three levels (control, and 0.5 and 1 μM lead spraying), whereas the second and third factorials were spraying zinc sulfate at three concentrations (zero, and 10 and 20 μM) and spraying calcium chloride at two levels (zero and 20 μM), respectively. According to the results, grain yield, the 1000-grain weight, leaf dry weight, number of seeds per head, head weight and chlorophyll content decreased. On the other hand, a significant increase was observed in the activities of catalase and ascorbate peroxidase enzymes and amount of malondialdehyde in plants. Moreover, spraying zinc fertilizer in lead treatment resulted in a significant increase in activity of catalase enzyme, reduction of membrane lipid peroxidation, prevention of chlorophyll destruction and maintenance of grain yield. However, the effect of spraying calcium fertilize in lead treatment was only significant on chlorophyll content. According to the results of the research, it seems that spraying zinc fertilizer had more effects on improved growth of safflower under lead stress, compared to spraying calcium fertilizer. Therefore, in air pollution with heavy metals (lead), application of zinc sulfate fertilizer can be an effective approach to maintain the growth and production of plants.
Among the various heavy metals, lead (Pb) is a major anthropogenic pollutant that has been released to the environment since the industrial revolution and accumulated in different terrestrial and aquatic ecosystems These elements will transfer to leaves in polluted areas and will rapidly uptake and cause irreparable damages to the most important part of the plant, i.e. photosynthetic system and changes immune system activity (Enzyme activity) and finally reduces the plant yield. Ca2+ improves plant resistance is related to maintaining a higher photosynthetic rate under stresses. Zn has a role in modulation of free radicals and their related processes through antioxidant properties and Zn applied by foliar spraying can increase the yield of crops. Therefore, this study aims to investigate how zinc and calcium fertilizers as foliar application increase safflower plant resistance to lead stress and their role on the damages caused by the stress on the activity of antioxidant defense system and photosynthetic pigments and its role in improving the plant yield in lead leaf absorption.

Materials and Methods The field experiment was carried out in a factorial based on randomized complete block design with three replications in the farm of Agricultural and Natural Resources Research and Education center of Kerman. The first factor consisted of three levels of lead (Control, 0.5 and l mM lead foliar) and the second factor, the foliar application of zinc sulfate in three concentrations (zero, 10 and 20 mM) and the third factor was the foliar application of calcium chloride in two concentrations (zero and 10 mM). Cultivars used in this experiment were Goldasht cultivars (safflower). In this study, the activity of ascorbate peroxidase, catalases enzymes and malondialdehyde contents were measured. At harvest time, stem and leaf dry weight, seed number per head, Head weight, 1000 seed weight and seed yield was calculated. All data were analyzed with SAS software. Analysis of variance and statistical analysis was performed using SAS and Excel softwares, Mean comparison was done by least significant difference (LSD) test at 5 percent.

Results and Discussion The results indicated that lead stress had a significant effect on most of the studied traits. Due to lead stress seed yield, 1000 seeds weight, leaf dry weight, seed number per head, head weight and chlorophyll contents decreased and the activity of catalases, ascorbate peroxidase and malondialdehyde contents showed significant increase in the plant. Based on the results we concluded that, decrease in seed yield and plant growth by lead exposure can be in relation to this toxicity and oxidative stress. Also the present results revealed that the increase in the activity of catalases, ascorbate peroxidase and malondialdehyde content prevent the occurrence of oxidative damage under Pb stress. The results showed that lead and zinc interaction effects were significant on grain yield, chlorophyll b and malondialdehyde. The foliar application of zinc improved catalases enzymatic activity, decreased membrane lipid peroxidation and prevented destruction of chlorophyll and maintained yield in stress lead. The optimization of zinc under Pb stress could alleviate Pb-induced toxic effects by enhancing biochemical reactions and physiological processes in safflower plant. The variance analysis showed that only lead and calcium interaction effects on chlorophyll a were significant. Content of chlorophyll a increased at non-stress conditions along with the foliar treatment of calcium (10 mM) compared to the control.

Conclusions The lead toxicity led to decline in growth and dry matter accumulation and the reduction of chlorophyll synthesis in plants and finally the reduction of the safflower yield. In the lead stress condition, the foliar application of zinc sulfate can be affected in the activation of plant defense systems and prevented the destruction of chlorophyll. Calcium successfully prevented occurrence of chlorosis and increased chlorophyll content. Based on the results, it seems that the application of zinc can have a greater impact on improving safflower growth than calcium fertilizer in lead stress. So in areas contaminated by heavy metals lead, zinc sulfate fertilizer can be as a solution to keep growing and production plants.

Keywords


1. Abbaspour, A., Kalbasi, M., Haj Rasouliha, Sh., and Golchin, A. 2006. Investigation of contamination in some agricultural soils of Iran with cadmium and lead. 9th Iranian Soil Science Congress. Soil Conservation and Watershed Management, Research Center, Tehran. (in Persian).
2. Ahmadi, J., Seyfi, M. M., and Amini, M. 2012. Effect of spraying micronutrients Fe, Zn and Ca on grain and oil yield of sesame (Sesamus indicum L.) varieties. Electronic Journal of Crop Production 5 (3): 115-130. (in Persian with English abstract).
3. Aravind, P., and Prasad, M. N. V. 2005. Cadmium–Zinc interactions in a hydroponic system using Ceratophyllum demersum L.: adaptive ecophysiology, biochemistry and molecular toxicology. Brazilian Journal of Plant Physiology 17(1): 3-20.
4. Beers, RF. J. R., and Sizer, I. 1952. A spectrophotometric method for measuring the breakdown of hydrogen peroxide by catalase. Journal of Biology and Chemistry 195: 133-140.
5. Bian, M., Zhou, M., Sun, D., and Li, Ch. 2013. Molecular approaches unravel the mechanism of acid soil tolerance in plants. The Crop Journal 1(2): 91-104.
6. Bor, M., Özdemir, F., and Turkan, I. 2003. The effect of salt stress on lipid peroxidation and antioxidants in leaves of sugar beet Beta vulgaris L. and wild beet (Beta maritima L.). Plant Science 164(1): 77-84.
7. Cakmak, I. 2000. Possible role of zinc in protecting plant cells from damage by reactive oxygen species. New Phytologist 146(2): 185-205.
8. Carapetian, J., and Zarei, G. 2005. Variation in Protein, Oil and Fatty Acid Contents in Three Wild Species of Safflower (Carthamus) from West Azerbaijan, Iran. International Journal of Botany 1(2):133-137.
9. Chvapil, M. 1973. New aspects in the biological role of zinc: a stabilizer of macromolecules and biological membranes. Life Sciences 13(8): 1041-1049.
10. Garland, C. J., and Wilkins, D. A. 1981. Effect of calcium on the uptake and toxicity of lead in hordeum vulgare l. and festuca ovina l. New Phytologist 87(3): 581-593.
11. Guo, T.R., Chen, Y., Zhang, Y. H., and Jin, Y. F. 2006. Alleviation of Al toxicity in barley by addition of calcium. Agricultural Sciences in China 5(11): 828-833.
12. Hall, J. L. 2002. Cellular mechanisms for heavy metal detoxification and tolerance. Journal of Experimental Botany 53(366): 1-11.
13. Heath, R. L., and Packer, L. 1968. Photoperoxidation in isolated chloroplast. I. Kinetics and stoichiometry of fatty acid peroxidation. Archives of Biochemistry and Biophysics 125(1): 850-857.
14. Islam, E., Liu, D., Li, T., Yang, X., Jin, X., Mahmood, Q., Tian, Sh., and Li J. 2008. Effect of Pb toxicity on leaf growth, physiology and ultrastructure in the two ecotypes of Elsholtzia argyi. Journal of Hazardous Materials 154(1-3): 914-920.
15. Islam, E., Liu, D., Li, T., Yang, X., Jin, X., Khan, M. A., Mahmood, Q., Hayat, Y., and Imtiaz, M. 2011. Effect of Pb toxicity on the growth and physiology of two ecotypes of Elsholtzia argyi and its alleviation by Zn. Environmental Toxicology 26(4): 403-416.
16. Jahed khaniki G. R., and Zazoli M. A. 2005. Cadmium and lead contents in rice (Oryza sativa) in the North of Iran. International Journal of Agriculture and Biology 7(6):1026–1029.
17. John, R., Ahmad, P., Gadgil, K., Sharma, S. 2009. Heavy metal toxicity: Effect on plant growth, biochemical parameters and metal accumulation by Brassica juncea L. International Journal of Plant Production 3(3): 65-75.
18. Kaya, C., Tuna, A. L., Sonmaz, O., Ince, F., Higgs, D. 2009. Mitigation effects of silicon on maize plants grown at high zinc. Journal of Plant Nutrition 32(10): 1788-1798.
19. Li, H., Sun, Y. L., Yu, X. H., Guo, H. P., Lian, H. F., Sun, X. D., Shi, Q. H., and Liu, S. Q. 2015. Effects of exogenous calcium on the growth and physiological traits of garlic seedlings under cadmium stress. Journal of Animal and Plant Sciences 25(3): 107-113.
20. Lichtenthaler, H. K., and Welburn, W. R. 1994. Determination of total carotenoids and chlorophyils a, b of leaf extracts in different solvents. Biochemical Society Transactions 11(5): 591-592.
21. Miszalski, Z., Slesak, I., Niewiadomska, E., Baczek-Kwinta, R., Luttge, U., and Ratajczak, R. 1998. Subcellular localization and stress responses of superoxide dismutase isoforms from leaves in the C3-CAM intermediate halophyte Mesembryanthum crystallinum L. Plant, Cell & Environment 21(2): 169-179.
22. Moradi Telavat, M. R., Roshan, F., and Siadat, S. A. 2015. Effect of foliar application of zinc sulfate on minerals contenet, seed and oil yields of two safflower cultivars (Carthamus tinctorius L.). Iranian Journal of Crop Sciences 17(2): 153-164. (in Persian with English abstract).
23. Nakano, Y., and Asada, K. 1981. Hydrogen peroxide is scavenged by ascorbate–specific peroxidases in spinach chloroplasts. Plant and Cell physiology 22(5): 867-880.
24. Potarzycki, J., and Grzebisz, W. 2009. Effect of Zinc Foliar Application on Grain Yield of Maize and Its Yielding Components. Plant, Soil and Environment 55(12): 519-527.
25. Pourkhabbaz, H. R., and Javanmardi, S. 2014. Determination of Toxicity Metals Concentration and their Emission Source in Urban Areas (Case study: Mashhad city). Geography and Environmental Planning Journal 55(3): 207-216. (in Persian).
26. Prassad, D. D. K., and Prassad, A. R. K. 1987. Altered aminolaevulinic acid metabolism by lead and mercury in germinating seedling of Bajra. Journal of Plant Physiology 127(3-4): 241-249.
27. Sarrafpour, R., Mohamedi Mahmoud Abadi, Sh., valipour, Sh., and Roozbehani, f. 2010. Study of lead concentration in air of Tehran region in 2008. Environmental Science & Technology 11(3): 93-105. (in Persian).
28. Sharma, P., and Dubey, R. S. H. 2005. Lead toxicity in Plants. Brazilian Journal of Plant Physiology 17(1): 35-52.
29. Siddiqui, M. H., Al-Whaibi, M. H., and Basalah, M. O. 2011. Interactive effect of calcium and gibberellin on nickel tolerance in relation to antioxidant systems in Triticum aestivum L. Protoplasma 248(3):503-511.
30. Tavakoli, M., Chehregani rad, A., Lariyazdi, H., and Pakdel, A. 2011. Study on the effects of different concentrations of Pb and salicylic acid on some growth factors in eggplant (Solanum melongena L.). Journal of Plant Biology 3(7): 29-40. (in Persian with English abstract).
31. Wang, C. Q., and Song. H. 2009. Calcium protects Trifolium repens L. seedlings against cadmium stress. Plant Cell reports 28(9): 1341-1349.
32. White, P. J. 2000. Calcium channels in higher plants. BBA- Biomembranes 1465: 171-189.
CAPTCHA Image