Effect of Fe and Zn Spraying on Yield and Nutrients Bioavailability of Bread Wheat Cultivars

Document Type : Research Article

Authors

1 University of Mohaghegh Ardabili

2 Agricultural Research, Education and Extension Organization (AREEO), Ardabil

Abstract

Introduction: Wheat is one of the most important foods for the people in the world. For many Central Asia and Middle Eastern nations, wheat provides ≈50% of the daily energy consumption and the proportion can exceed 70% in rural areas. The production of high-yielding modern cultivars may provide the amount of energy needed by humans, but these cultivars, due to the low concentration of micronutrients such as iron (Fe) and zinc (Zn), are usually deficient and cause health problems. This shortage is intensified in dryland areas due to dryness, alkalinity, and so on. Two-thirds of the total area under wheat cultivation in Iran belongs to rainfed wheat. Declines in the concentration of micronutrients such as Fe and Zn in cereal grain which are often important sources of micronutrients for humans cause several diseases. Agronomic fortification (e.g., fertilizer application) is imperative and necessary for improving micronutrient concentrations in grains in a short period. Phytic acid has a high potential for binding Zn and Fe, making them less bioavailable for humans. If the amount of phytic acid in the wheat grain is high, the absorption of small elements in the intestine decreases. The use of micronutrient fertilizers, such as zinc reduces the amount of phytic acid and enhance grain zinc concentration. Therefore, the purpose of this research was to investigate the role of zinc and iron fertilizers on the performance and quality of modern and local cultivars of bread wheat.
Materials and Methods: To investigate the role of iron and zinc Nano-chelate fertilizers on the improvement of grain yield and elemental composition of bread wheat cultivars, a factorial experiment based on randomized complete block design with three replications arranged in Moghan Agricultural and Natural Resources Research Center, 2015-2016. The first factor was control and spraying with iron, zinc, and iron + zinc. The cultivars included Aftab (G1), Karim (G2) and two new genotypes (G3 and G4). Foliar application of Khazra iron and zinc Nano-chelate fertilizers was carried out at tillering, early of heading and milky stages with a ratio of 2 and 1.5 per thousand, respectively. Iron, zinc, and iron + zinc Nano fertilizers at the rate of 2 kg ha-1, 1.5 kg ha-1 and 2 + 1.5 kg ha-1 were sprayed at every stage. Ammonium phosphate and urea fertilizers at a rate of 50 kg ha-1 from each one of them were applied before planting. Measurement of Fe and Zn elements was carried out at wavelengths of 233.28 and 2333 nm, respectively with the use of the atomic absorption device Shimadzu, AA-6300. Measured traits included a number of spikelets per spike, number of grains per spike, number of seeds per spike, and 1000 grain weight per the main spike, grain yield m2, zinc concentration, iron concentration, phytic acid, and phytic acid molar ratio to zinc and iron.
Results and Discussion: The results showed that cultivar G1, G2, and G3 produced significantly higher seed yield than G1. This was mainly due to an increase in spikelet number, the number of seeds per spikelet, and/or both. The G1 and G2 cultivars had a higher concentration of zinc in comparison with the new genotypes. Cultivar G1 had the highest Phytic acid and phytic acid to zinc and iron molar ratio, and genotype G4 had the lowest values. Maximum grain yield, Zn and Fe concentrations were obtained at the foliar application of Fe + Zn, Zn, and Fe, respectively. Zinc application had the lowest amounts of phytic acid and phytic acid to Zn molar ratio in comparison with the other spraying levels.
Conclusions: As a result, the foliar application of iron and especially zinc in dryland farms, by improving the bioavailability of iron and zinc and increasing wheat yield, can play a significant role in providing daily energy intake and reducing health risks.

Keywords


1. Abu-Dahi, Y. M., Shati, R. K., and AL-Taher, F. M. 2009. Effect of foliar feeding of iron, zinc and potassium on grain yield, and protein percentage of bread wheat. Iraqi Journal of Agricultural Sciences 40 (4): 27-37.
2. Ali, E. A. 2012. Effect of iron nutrient care sprayed on foliage at different physiological growth stages on yield and quality of some durum wheat (Triticum durum L.) varieties in sandy soil. Asian Journal of Plant Sciences 4 (4): 139-149.
3. Ali, S., Khan, R., Mairaj, G., Arif, M., Fida, M., and Bibi, S. 2008. Assessment of different crop nutrient management practices for yield improvement. Australian Journals of Crop Science 2 (3): 150-157.
4. Black, R. E., Allen, L. H., Bhutta, Z. A., Caulfield, L. E., Onis, M. D., Ezzati, M., Mathers, C., and Rivera, J. 2008. Maternal and child undernutrition: global and regional exposures and health consequences. Lancet. 371: 243-260.
5. Boscher, D., Lu, Z., Janssens, G., Van Caillie- Bertrand, M., Rubberiest, H., De, H., and Rycke, H. 2001. In vitro availability of zinc from infant foods with increasing phytic acid contents. British Journal of Nutrition 86: 241-247.
6. Bouis, H. E., and Welch, R. M. 2010. Biofortification: a sustainable agricultural strategy for reducing micronutrient malnutrition in the global south. Crop Science 50: S20-S32.
7. Cakmack, I., and Braun, H. J. 2001. Genotypic variation for zinc efficiency. In: Reynolds, M.P., Ortiz-Monasterio, J.I. and McNab, A. (eds.), Application of Physiology in Wheat Breeding. Mexico, D.F.: CIMMYT.
8. Cakmak, I. 2008. Enrichment of cereal grains with zinc: agro- nomic or genetic biofortification. Plant and Soil 302: 1-17.
9. Cakmak, I., Kalayci, M., Kaya, Y., Torun, A. A., Aydin, N., Wang, Y., Arisoy, Z., Erdem, H., Yazici, A., Gokmen, O., Ozturk, L., and Horst, W. J. 2010. Biofortification and localization of zinc in wheat grain. Journal of Agricultural and Food Chemistry 58: 9092-9102.
10. Cakmak, I., Torun, A., Millet, E., Feldman, M., Fahima, T., Korol, A., Nevo, E., Braun, H. J., and Ozkan, H. 2004. Triticum dicoccoides: Animportant genetic resource for increasing zinc and iron concentration in modern cultivated wheat. Soil Science and Plant Nutrition 50: 1047-1054.
11. Chen, Y., Shi, J., Tin, G., Zheng, S., and Lin, Q. 2004. Fe deficiency induces Cu uptake and accumulation in Commelia communis. Plant Science 166: 1371-1377.
12. Daghan, H., Uygur, V., Koleli, N., Arslan, M., and Eren, A. 2013. The effect of heavy metal treatments on uptake of nitrogen, phosphorus and potassium in transgenic and non-transgenic tobacco plants. Tarım Bilimleri Dergisi-Journal of Agricultural Sciences 19: 129-139.
13. Doria, L., Galleschi, L., Calucci, L., Pinzino, C., Pilu, R., Cassani, E., and Nielsen, E. 2009. Phytic acid prevents oxidative stress in seeds: evidence from a maize (Zea mays L.) low phytic acid mutant. Journal of Experimental Botany 60 (3): 967-978.
14. Dorostkar, V., Afyuni, M., and Khoshgoftarmanesh, A. 2013. Effects of Preceding Crop Residues on Total and Bio-available Zinc Concentration and Phytic Acid Concentration in Wheat Grain. Journal of Water and Soil Science 17 (64) 81-93. (in Persian with English abstract).
15. El-Habbasha, S. F., Tawfik, M. M., and El-Kramany, M. F. 2013. Comparative efficacy of different bio-chemical foliar applications on growth, yield and yield attributes of some wheat cultivars. World Journal of Agricultural Sciences 9 (4): 345-353.
16. Fan, M. S., Zhao, F. J., Fairweather-Tait, S. J., Poulton, P. R., Dunham, S. J., and McGrath, S. P. 2008. Evidence of decreasing mineral density in wheat grain over the last 160 years. Journal of Trace Elements in Medicine and Biology 22: 315-24.
17. Fang, Y., Wang, L., Xin, Z., Zhao, L., An, X., and Hu, Q. 2008. Effect of foliar application of zinc, selenium, and iron fertilizers on nutrients concentration and yield of rice grain in China. Journal of Agricultural and Food Chemistry 56: 2079-2084.
18. Ficco, D. B. M., Riefolo, C., Nicastro, G., Simone, V. D., Gesu, A. M. D., Beleggia, R., and Platani, C. 2009. Phytate and mineral elements concentration in a collection of Italian durum wheat cultivars. Field Crop Research 111: 235-242.
19. Godsey, C. B., Schmidt, J. P., Schlegel, A. J., Taylor, R. K., Thompson, C. R., and Gehl, R. J. 2003. Correcting iron deficiency in corn with seed row-applied iron sulfate. Agronomy Journal 95 (1): 160-166.
20. Habib, M. 2009. Effect of foliar application of Zn and Fe on wheat yield and quality. African Journal of Biotechnology 8: 6795-6798.
21. Hambidge, K. M., Miller, L. V., Westcott, J. E., and Krebs, N. F. 2008. Dietary reference intakes for zinc may require adjustment for phytate intake based upon model prediction. The Journal of Nutrition-American Society for Nutrition 2363-2366.
22. Haug, W., and Lantzsch, H. J. 1983. Sensitive method for the rapid determination of phytate in cereal products. Journal of the Science of Food and Agriculture 34: 1423-1426.
23. Hossain, M. A., Jahiruddin, M., Islam, M. R., and Mian, M. H. 2008. The requirement of zinc for improvement of crop yield and mineral nutrition in the maize-mungbean-rice system. Plant and Soil 306: 13-22.
24. Hussain, N., Khan, M. A., and Javad, M. A. 2005.Effect of foliar application of plant micronutrient mixture on growth and yield of wheat (Triticum aestivum L.). Pakistan Journal of Biological Sciences 8 (8): 1096-1099.
25. Karami, M., Afyuni, M., Khoshgoftarmanesh, A. H., Hajabbasi, M. A., Khademi, H., and Abdi, A. 2013. Status and Modeling of Zn in Wheat Grain in Relation to Agroecosystem Parameters of Some Arid and Semi Arid Regions. Journal of Sciences and Technology of Agriculture and Natural Resources 17 (64): 119-136. (in Persian with English abstract).
26. Kaya, C., and Higgs, D. 2002. Response of tomato (Lycopersicon esculentum L.) cultivars to foliar application of zinc when grown in sand culture at low zinc. Scientia Horticulturae 93 (1): 53-64.
27. Kaya, M., Küçükyumuk, Z., and Erdal, I. 2009. Phytase activity, phytic acid, zinc, phosphorus and protein contents in different chickpea genotypes in relation to nitrogen and zinc fertilization. African Journal of Biotechnology 8: 4508-4513.
28. Khan, M. A., Fuller, M. P., and Baloch, F. S. 2008. Effect of soil applied zinc sulfate on wheat (Triticum aestivum L.) grown on a calcareous soil Pakistan. Cereal Research Communications 36 (4): 571-582.
29. Khoshgoftarmanesh, H., Shariatmadari, H., Karimian, N., Kalbasi, M., and Khajehpour, M. R. 2005. Zinc Efficiency of Wheat Cultivars Grown on a Saline Calcareous Soil. Journal of Plant Nutrition 27 (11): 1953-1962.
30. Mahmoudi H., Ksouri, R., Gharsalli, M., and Lachaal, M. 2005. Differences in responses to iron deficiency between two legumes: lentil (Lens culinaris) and chickpea (Cicer arietinum). Journal of Plant Physiology 162 (11): 1237-1245.
31. Malakouti, M .J. 2007. Zinc is a neglected element in the life cycle of plants. Middle Eastern and Russian Journal of Plant Science and Biotechnology 1 (1): 1-12.
32. Malakouti, M. J. 2010. Why our agricultural products facing zinc deficiency? Proceedings of the 7th International Symposium on Trace Elements in Human: New Perspectives. Trace Elements and Electrolytes 27: 176-177.
33. Malakouti, M. J. 2011. Towards improving the quality of consumed breads in Iran: A Review. Journal of Food Science and Technology 8 (31) 12-21. (in Persian with English abstract).
34. Malakouti, M. J., Keshavarz, P., and Karimian, N. 2008. A comprehensive approach towards identification of nutrients deficiencies and optimal fertilization for sustainable agriculture. Tarbiat Modares University Press. 755 pp. (in Persian).
35. Malakouti, M. J., Malakouti, A., Bybordi, I., and Khamesi, E. 2010. Zinc (Zn) is the neglected element in the life cycle of plant, animal and human health (10th ed.). Technical bulletin No. 007. Soil Science Department-Tarbiat Modares University. Sana Pubication Co. 14 pp. (in Persian).
36. Mekkei, M. E. R., and El-Haggan E. A. M. A. 2014. Effect of Cu, Fe, Mn, Zn foliar application on productivity and quality of some wheat cultivars (Triticum aestivum L.). Journal of Agri-Food and Applied Science 2 (9): 283-291.
37. Morris, C.E., and Sands, D.C. 2006. The breeder’s dilemma-yield or nutrition? Nature Biotechnology 24:1078–1080.
38. Ning, N., Liu, Z., Wang, Q., Lin, Z., Chen, S., Wang, S., and Ding, Y. 2009. Effect of nitrogen fertilizer application on grain phytic acid and protein concentrations in Japonica rice and its variations with genotypes. Journal of Cereal Science 50: 49-55.
39. Pahlavan-Rad, M., and Pessarakli, M. 2009. Response of wheat plants to zinc, iron and manganese applications and uptake and concentration of zinc, iron and manganese in wheat grains. Communications in Soil Science and Plant Analysis 40: 1322-1332.
40. Pandey, N., Pathak, G. C., and Sharma, C. P. 2006. Zinc is critically required for pollen function and fertilisation in lentil. Journal of Trace Elements in Medicine and Biology 20: 89-96.
41. Prasad, A. S. 2003. Zinc deficiency. British Medical Journal 326 (7386): 409-410.
42. Rajabi, R. 2015. Evaluation of Genetic diversity for fertilizer use efficiency in bread wheat genotypes under rainfed Conditions of Iran. Agronomy Journal (Pajouhesh & Sazandegi) 108: 24-34. (in Persian).
43. Sandberg, A. S. 2002. Bioavailability of minerals in legumes. British Journal of Nutrition 88 (3): 281-285.
44. Seadh, S. E., El-Abady, M. I., El-Ghamry, A. M., and Farouk, S. 2009. Influence of micronutrients foliar application and nitrogen fertilization on wheat yield and quality of grain and seed. Journal of Biological Sciences 9 (8): 851-858.
45. Shivay, Y. S., Kumar, D., and Prasad, R. 2008. Effect of zinc- enriched urea on productivity, zinc uptake and efficiency of an aromatic rice-wheat cropping system. Nutrient Cycling in Agroecosystems 81: 229-243.
46. Stein, A. J. 2010. Global impacts of human mineral malnutrition. Plant and Soil 335: 133-154.
47. Welch, R. M., and Graham, R. 2004. 2004. Breeding for micronutrients in staple food crops from a human nutrition perspective. Journal of Experimental Botany 55: 353-364.
48. White, P. J., and Broadley, M. R. 2009. Biofortification of crops with seven mineral elements often lacking in human diets – iron, zinc, copper, calcium, magnesium, selenium and iodine. New Phytologist 182: 49-84.
49. Zhang Y., Shi, R. M. D., Rezaul, K., Zhang, F., and Zou, C. 2010. Iron and zinc concentrations in grain and flour of winter wheat as affected by foliar application. Journal of Agricultural and Food Chemistry 58: 12268-12274.
50. Zhang, Y. Q., Sun, Y. X., Ye, Y. L., Karim, M. R., Xue, Y. F., Yan, P., Meng, Q. F., Cui, Z. L., Cakmak, I., Zhang, F. S., and Zou, C. Q. 2012. Zinc biofortification of wheat through fertilizer applications in different locations of China. Field Crop Research 125: 1-7.
51. Ziaeian, A. H., and Malakouti, M. J. 2002. Effects of Fe, Mn, Zn and Cu fertilization on the yield and grain quality of wheat in the calcareous soils of Iran. Plant Nutrition 92: 840-841.
52. Zou, C. Q., Zhang, Y. Q., Rashid, A., Ram, H., Savasli, E., Arisoy, R. Z., Ortiz-Monasterio, I., Simunji, S., Wang, Z. H., Sohu, V., Hassan, M., Kaya, Y., Onder, O., Lungu, O., Yaqub Mujahid, M., Joshi, A. K., Zelenskiy, Y., Zhang, F. S., and Cakmak, I. 2012. Biofortification of wheat with zinc through zinc fertilization in seven countries. Plant and Soil 361:119-130.
CAPTCHA Image
  • Receive Date: 13 August 2018
  • Revise Date: 06 October 2018
  • Accept Date: 10 November 2018
  • First Publish Date: 22 June 2019