Mohasseli, V., Khoshgoftarmanesh, A., Shariatmadari, H. (2016). Impact of Distance from Air Pollution Source on Iron Nutritional Status of Plantago major L. in Shiraz City. , 30(3), 295-304. doi: 10.22092/ijsr.2016.107366
V. Mohasseli; A. H. Khoshgoftarmanesh; H. Shariatmadari. "Impact of Distance from Air Pollution Source on Iron Nutritional Status of Plantago major L. in Shiraz City". , 30, 3, 2016, 295-304. doi: 10.22092/ijsr.2016.107366
Mohasseli, V., Khoshgoftarmanesh, A., Shariatmadari, H. (2016). 'Impact of Distance from Air Pollution Source on Iron Nutritional Status of Plantago major L. in Shiraz City', , 30(3), pp. 295-304. doi: 10.22092/ijsr.2016.107366
Mohasseli, V., Khoshgoftarmanesh, A., Shariatmadari, H. Impact of Distance from Air Pollution Source on Iron Nutritional Status of Plantago major L. in Shiraz City. , 2016; 30(3): 295-304. doi: 10.22092/ijsr.2016.107366

Impact of Distance from Air Pollution Source on Iron Nutritional Status of Plantago major L. in Shiraz City

پژوهش های خاک
Article 6, Volume 30, Issue 3, December 2016, Pages 295-304    PDF (332.28 K)
Document Type: Research Paper
DOI: 10.22092/ijsr.2016.107366
Authors
V. Mohasseli* ; A. H. Khoshgoftarmanesh; H. Shariatmadari
Abstract
As an essential micronutrients, iron (Fe) has significant effect on activity of antioxidant enzymes and thereby influences the crop tolerance to environmental stresses. On the other hand, environmental stresses, i.e. air pollution might modify Fe nutritional status of plants by affecting the activity of antioxidant enzymes. The purpose of this study was to investigate the changes in Fe concentration and activity of Fe-dependent antioxidant enzymes in leaves of Plantago major L.with distance from two major sources of air pollution in Shiraz city. Oil Refinery of Shiraz (ORS) and urban traffic of Imam Hossein square were selected as two major air pollutant sources in Shiraz city. Plant leaf samples were collected at different distances from the air pollutant sources. The concentrations of Fe, zinc (Zn), chlorophyll a and b, carotenoids, and activity of catalase and peroxidase in the leaves were measured. The results showed that Fe concentration in the plant leaves increased with distance from the ORS. Leaf Fe concentration was 34.86% and 44.73 % higher in the plants at the Rokn Abbad (12 km far from the ORS)  town and Melli garden (20 km far from the ORS), respectively, in comparison with those plants close to the ORS. Chlorophyll concentration increased with distance from the ORS. Activity of catalase and peroxidase was increased by distance from the ORS. For the second route, traffic of Imam Hossein square, leaf Fe concentration significantly increased with distance from the source of pollution while no regular trend was found for the changes in chlorophyll concentration and catalase and peroxidase activity. Although many factors including soil properties may be effective in this regard, considering the similarities observed in the characteristics of the studied soils, it can be concluded that there was a close relationship between the Fe nutritional status of Plantago major L. and intensity of air pollution. 
Keywords
Air pollutants; catalase; Fe concentration; peroxidase; Plantago major L
References
  1. Agarwal, S., and V. Pandey. 2004. Antioxidant enzyme respones to NaCl stress in Cassia angustifolia. Biologia Plantarum. 48: 555- 560.
  2. Arnon, A. N. 1967.Method of extraction of chlorophyll in the plants. J. 23: 112- 121.
  3. Blakrishman, K. 2000. Peroxidase activity as an indicator of the iron deficiency banana. Indian J. Plant Physiol. 5: 389- 391.
  4. Britton, C., and A. C. Mehley. 1955. Assay of catalase and peroxidase. In: Colowick, S.P., Kaplan, N.O. (Eds.), Methods in Enzymology, vol. II. Academic press, New York, pp. 764–775.
  5. Coleman, J. S., H. A. Mooney, and J. N. Gorham. 1989. Effects of multiple stresses on radish growth and resource allocation I. Responses of wild radish plants to a combination of SO2 exposure and decreasing nitrate availability. Oecologia. 81, 124–131.
  6. Corpas, F. J., L. M. Sandalio, L. A. Del Rio, and R. N. Trelease. 1998. Copper-zinc superoxide dismutase is a constituent enzyme of the matrix of peroxisomes in the cotyledons of oilseed plants. New Phytologist. 138: 307- 314.
  7. Del Rio, L. A., J. M. Palma, L. M. Sandalio, F. J. Corpas, G. M. Pastori, P. Bueno, and E. Lopez-Huertas. 1996. Peroxisomes as a source of superoxide and hydrogen peroxide in stressed plants. Soc. Transac. 24: 434– 438.
  8. Iturbe-Ormaetxe, I., J. F. Moran, C. Arrese-Igor, Y. Gogorcena, R. V. Klucas, and M. Becana. 1995. Activated oxygen and antioxidant defenses in iron-deficient pea plants. Plant, Cell and Environ. 18: 421– 429.
  9. Jones, J. B. 1984. Plants. In: Williams, S. (ed.). Official methods of analysis of the association of official analytical chemists. pp: 38–64. Arlington, Virginia, USA.
  10. Khan, M. R., and M. W. Khan. 1994. Single and interactive effect of O3 and SO2 on Tomato. Exper. Bot. 34 (4): 461– 469.
  11. Kumar, M., M. Anjali, M. Narayan, S. Chaudhary, and K. Pal. 2012. Effect of sulphur dioxide on plant chlorophyll on the family of Brassicaceae. J. Pharm. Profes. Res. 3: 605- 609.
  12. Lombardi, L., L. Sebastiani, and C. Vitagliano. 2003. Physiological, biochemical, and molecular effects of in vitro induced Iron deficiency in Peach rootstock Mr.S 2/5. Plant Nutr. 26: 2149– 2163.
  13. Marschner, H. 1995. Mineral nutrition of higher plants. Academic Press London. pp. 313- 323.
  14. Radtke, K., R. W. Byrnes, P. Kerrigan, W. E. Antholine, and D. H. Petering. 1992. Requirement for endogenous iron cytotoxicity caused by hydrogen peroxide in Euglena gracilis. Marine Environ. Res. 34: 339– 343.
  15. Rahimizadeh, M., D. Habibi, H. Madani, G. N. Mohammadi, A. Mehraban, and A. M. Sabet. 2007. The effect of micronutrients on antioxidant enzymes metabolism in sunflower (Helianthus annus L.) under drought stress. Helia. 30: 167- 174.
  16. Rai, A., and K. Kulshreshtha. 2006. Effect of particulates generated from automobile emission on some common plants. Eco Education Division J. Food, Agric. Environ. 4 (1): 253– 259.
  17. Rajput, M., and M. Agrawal. 1994. Responses of soybean plants to sulphur dioxide at varying soil fertility regimes. Biotronics. 23, 81– 92.
  18. Renuga, G., and K. Paliwal. 1995. Detoxification of SO2 derivatives in chloroplasts of Hardwickia binata. Bios. 20 (1): 59– 68.
  19. Salama, Z. A. E., H. S. El-Beltagi, and D. M. El-Hariri. 2009. Effect of Fe deficiency on antioxidant system in leaves of three flax cultivars. Notulae Botanicae Horti AgrobotaniciCluj-Napoca. 37 (1): 122- 128.
  20. Shigeoka, S., T. Ishikawa, M. Tamoi, Y. Miyagawa, T. Takeda, and Y. Yabuta. 2002. Regulation and function of ascorbate peroxidase isoenzymes. Exp. Bot. 53: 1305- 1319.
  21. Singh, A., S. B. Agrawal, and D. Rathore. 2003. Growth responses of wheat (Triticum aestivum L. var. HD 2329) exposed to ambient air pollution under varying fertility regimes. Sci. Word J. 3, 799– 810.
  22. Singh, A., S. B. Agrawal, and D. Rathore. 2005. Amelioration of Indian urban air pollution phytotoxicity in Beta vulgaris by modifying NPK nutrients. Environ. Pollu. 34: 358- 395.
  23. Stocking, C. R. 1975. Iron deficiency and the structure and physiology of Maize chloroplasts1. Plant Physiol. 55: 626- 631.
  24. Sun, B., Y. Jing, K. Chen, L. Song, F. Chen, and L. Zhang. 2007. Protective effect of nitric oxide on iron deficiency-induced oxidative stress in maize (Zea mays ). J. Plant Physiol. 164: 536- 543.
  25. Swanepoel, J. W., G. H. J. Kruger, and P. D. R. Van Heerden. 2007. Effects of sulphur dioxide on photosynthesis in the succulent Augea capensis J. Ari. Environ. 70: 208– 221.
  26. Verma, M., and M. Agrawal. 2001. Response of wheat plants to sulfur dioxide and herbicide interaction at different fertility regimes. Indian Bot. Soc. 80: 67– 72.
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