Effects of Foliar Application of Zinc Fertilizer on Grain Yield and Zinc Content of Rice Grain cv. Sazandegi

Document Type : Research Article

Authors

Isfahan Agricultural and Natural resources Research and Education Center

Abstract

Introduction
Rice (Oryza sativa L.) is one of the major staples feeding more than half of the world population. It is grown in more than 100 countries, predominantly in Asia and provides 21% of energy and 15% of protein requirements of human populations globally. Zinc deficiency is one of the important abiotic factors limiting rice productivity worldwide and also a widespread nutritional disorder affecting human health. Chakeralhossein et al., (2009) evaluated the effects of rate, sources and application methods of zinc fertilizer on quantity and quality of rice and reported that, application of zinc fertilizer significantly increased yield and grain Zn content. The greatest yield enhancement (56.9%) was obtained in 3 g L-1 ZnSO4 along with application of 40 kg ha-1 ZnSO4 as soil application methods. In slightly alkaline sandy clay soil with sufficient Zn under flooded conditions, soil and plant Zn concentration were increased 1.8 times with foliar spray of 0.5 %w/v ZnSO4 which was applied at panicle initiation compared to soil application of ZnSO4 at the same stage. In a field experiment during two years in Egypt, the effects of Zn, Fe and Mn as single or combined application in soil and foliar spray to the rice growth and yield were evaluated. The results showed that the single or combine application of Zn, Fe and Mn significantly improved rice growth and yield. According to Zn deficiency is a widespread nutritional disorder affecting human health in many countries, especially where people rely on cereal-based food, the aim of this study was to investigate the effect of foliar application of nano-ZnO and zinc sulfate on yield and grain zinc content of rice.
Materials and Methods
A field experiment was conducted as randomized complete block design with three replications at the Isfahan Agricultural Research Center during 2013-2014. Treatments were consisted of six zinc foliar application levels: 150 and 300 mg L-1 nano-ZnO, 3 and 6 g L-1 ZnSO4, distilled water as the first control (Control 1) and no spray as the second control (Control 2). Rice plants were foliar sprayed until runoff using a hand-sprayer, at the tillering and grain milk stages. Nano-zinc oxide had a purity of greater than 99%, average particle diameter of 10-30 nm and specific surface area of > 30 m2 g-1. Also zinc sulfate was used with purity of 99%.
Results and Discussion
The results showed that Fe, Mn and Zn concentrations of plant shoot at tillering and grain milk stages, and also grain yield and grain zinc content were significantly affected by zinc foliar application. Foliar application of nano-zinc oxide and zinc sulfate increased zinc concentration of plant shoot at tillering and grain milk stages. The highest shoot zinc concentration of 28.8 and 37.8 mg kg-1 were obtained in 6 mg L-1 zinc sulfate at tillering and grain milk stages, respectively. While the lowest shoot zinc concentration (24.2 and 30.5 mg kg-1) were observed in the first control treatment at tillering stage and in the second control treatment at grain milk stage, respectively. At tillering stage, foliar application of 3 and 6 mg L-1 zinc sulfate and 300 mg L-1 nano-zinc oxide increased shoot zinc concentration, whereas there was no significant difference between 150 mg L-1 nano-zinc oxide and two controls treatments. At grain milk stage, all zinc foliar application treatments increased shoot zinc concentration compared to the control treatments. The maximum grain zinc content (37.8 mg kg-1) was obtained with 6 g L-1 zinc sulfate which was 16.6 and 19.5% higher than first and second control treatments, respectively. Zinc foliar application significantly increased grain yield. Foliar application of nano-zinc oxide and zinc sulfate significantly improved grain yield compared to the control treatments. The highest grain yield was obtained in 6 g L-1 zinc sulfate fallowed by 150 mg L-1 nano zinc oxide, 3 g L-1 zinc sulfate and 300 mg L-1 nano-zinc oxide, respectively. Also, there were no significant difference between first and second controls. Zinc is a structural part of carbonic anhydrase, alcohol dehydrogenase, Cu/Zn-superoxide dismutase and RNA polymerase and serves as a cofactor for all 6 classes of enzymes (oxidoreductases, transferases, hydrolases, lyases, isomerase and ligases) and auxin synthesis in plants is also controlled by Zn. Adequate zinc in plants increases the synthesis of enzymes and hormones, metabolism of essential elements and stimulates plant growth and yield.
Conclusions
According to rice consumption per capita in Iran is 40 kg (110 g day-1) and the average daily human zinc requirement is 10-15 mg, zinc biofortification of rice and improving zinc of rice grain to 35 mg kg-1 will provide about one third of people’s daily zinc requirement (3.5 mg).

Keywords

References

1. Amirjani, M. R., Askari, M., and Askari, F. 2014. Effect of nano zinc oxide on alkaloids, enzymatic and antienzymatic antioxidant contents and some physiological parameters of Catharantus roseus. Cell and Tissue Journal 5 (2): 173 -183. (in Persian with English abstract).
2. Anonymous. 2016. Iranian Ministry of Jihade-Agriculture. first volume. Crops. Available at http://www.maj.ir/Portal/Home/Default.aspx?CategoryID=95a8e7d0-e5f0-4f2d-a241-92106c74dcc.
3. Auld, D. S. 2001. Zinc coordination sphere in biochemical zinc sites. In Zinc Biochemistry, Physiology, and Homeostasis. Springer. Netherlands.
4. Cakmak, I., Kalayci, M., Ekiz, H., Braun, H. J., and Yilmaz, A. 1999. Zinc deficiency as an actual problem in plant and human nutrition in Turkey: a NATO Science for Stability Project. Field Crops Research 60: 175-188.
5. Cakmak, I., Kalayci, M., Kaya, Y., Torun, A. A., Aydin, N., Wang, Y., Arisoy, Z., Erdem, H., Yazici, A., Gokmen, O., and Ozturk, L. 2010. Biofortification and localization of zinc in wheat grain. Journal of Agricultural and Food Chemistry 58 (16): 9092-9102.
6. Chakeralhosseini, M. R., Mohtashami, R., and Owliaie, H. R. 2009. Effects of rate, source, and method of zinc fertilizer application on quantitative and qualitative characteristics of rice (Choram 1). Journal of Research in Agricultural Science 5 (1): 33-43. (in Persian with English abstract).
7. Davatgar, N. 2005. Estimation of different form of Zinc in wetland soils and their availability to plant rice. Rice Research Institute. Agricultural research, education & extension organization. Registration number: 1045569. (in Persian with English abstract).
8. Dobermann, A., and Fairhurst, T. 2000. Rice: nutrient disorders & nutrient management (Vol. 1). International Rice Research Institute.
9. Depar, N., Rajpar, I., Memon, M. Y., and Imtiaz, M. 2011. Mineral nutrient densities in some domestic and exotic rice genotypes. Pakistan Journal of Agriculture: Agricultural Engineering Veterinary Sciences.
10. Emami, A. 1996. Methods of plant analysis. First volume. Technical Bulletin No. 982. Soil and Water Research Institute. Tehran, Iran. (in Persian).
11. Forno, D. A., Yoshida, S., and Asher, C. J. 1975. Zinc deficiency in rice. Plant and Soil. 42 (3): 537-550.
12. Gao, X., Hoffland, E., Stomph, T., Grant, C. A., Zou, C., and Zhang, F. 2012. Improving zinc bioavailability in transition from flooded to aerobic rice. A review. Agronomy for sustainable development 32 (2): 465-478.
13. Habib, M. 2009. Effect of foliar application of Zn and Fe on wheat yield and quality. African Journal of Biotechnology 8 (24).
14. Jiang, W., Struik, P. C., Van Keulen, H., Zhao, M., Jin, L. N., and Stomph, T. J. 2008. Does increased zinc uptake enhance grain zinc mass concentration in rice? Annals of Applied Biology 153 (1): 135-147.
15. John, L. W., Jamer, D. B., Samuel, L. T., and Warner, L. W. 2014. Soil fertility and fertilizers: An introduction to nutrient management. Person Education. Delhi. pp. 106-153.
16. Kamari, H., Seyed Sharifi, R., and Sedeghi, M. 2014. The effect of foliar application of nano-zinc oxide and free-living nitrogen-fixing bacteria on yield and morpho-physiological characteristics of triticale. Crop Physiology Journal 22 (4): 52-37. (in Persian with English abstract).
17. Karak, T., and Das, D. 2006. Effect of foliar application of different sources of Zn application on the changes in Zn content, uptake and yield of rice (Oryza sativa L.). In 18th World Congress of Soil Science. Philadelphia., Pennsylvania. USA.
18. Khot, L. R., Sankaran, S., Maja, J. M., Ehsani, R., and Schuster, E. W. 2012. Applications of nanomaterials in agricultural production and crop protection: a review. Crop Protection 35: 64-70.
19. Malakouti, M. J., and Kavousi, M. 2004. Balanced nutrition of rice. First Edition. Ministry of Jihad-e-Agriculture, Deputy Agronomy Affairs. Press the Senate. Tehran. (in Persian).
20. Morete, M. J., Impa, S. M., Rubianes, F., and Beebout, S. E. J. 2011. Characterization of zinc uptake and transport in rice under reduced conditions in agar nutrient solution. 14th Philippines Society of Soil Science and Technology. In Scientific Conference (pp. 25-27).
21. Phattarakul, N., Mongon, J., and Rerkasem, B. 2011. Variation in rice grain zinc and their response to zinc fertilizer. In 3rd International Zinc Symposium (pp. 10-14). Hyderabad. India.
22. Prasad, T. N. V. K. V., Sudhakar, P., Sreenivasulu, Y., Latha, P., Munaswamy, V., Reddy, K. R., Sreeprasad, T. S., Sajanlal, P. R., and Pradeep, T. 2012. Effect of nanoscale zinc oxide particles on the germination, growth and yield of peanut. Journal of Plant Nutrition 35 (6): 905-927.
23. Quijano-Guerta, C., Kirk, G. J. D., Portugal, A. M., Bartolome, V. I., and McLaren, G. C. 2002. Tolerance of rice germplasm to zinc deficiency. Field Crops Research. 76: 123-130.
24. Rehman, H. U. 2014. N-Zn dynamics under different rice production systems (Doctoral dissertation. University of Agriculture. Faisalabad).
25. Rehman, H. U., Aziz, T., Farooq, M., Wakeel, A., and Rengel, Z. 2012. Zinc nutrition in rice production systems: a review. Plant and soil 361 (1-2): 203-226.
26. Reinhold, J. G. 1971. High phytate content of rural Iranian bread: a possible cause of human zinc deficiency. The American journal of clinical nutrition 24 (10): 1204-1206.
27. Rengel, Z., Römheld, V., and Marschner, H. 1998. Uptake of zinc and iron by wheat genotypes differing in tolerance to zinc deficiency. Journal Plant Physiology 152: 433-438.
28. Saadati, N. 1998. The effect of different sources of zinc (Zn) on yield of rice, (var. Tarom) in peat lands. Rice Research Institute. Agricultural research, education & extension organization. Final report of research project 12 pages. (in Persian).
29. Safarpour, R., and Naqhavi, S. 1997. Determination of zinc requirement of rice in paddies of Guilan province. Rice Research Institute. Agricultural research, education & extension organization. Extension issue, 42 pages. (in Persian with English abstract).
30. Soleimani, A. 1999. Effects of zinc on rice farming. Gorgan and Gonbad Agricultural Organization. Rice Research Institute. Extension issue, 8 pages. (in Persian).
31. Shivay, Y. S., Kumar, D., Prasad, R., and Ahlawat, I. P. S. 2008. Relative yield and zinc uptake by rice from zinc sulphate and zinc oxide coatings onto urea. Nutrient Cycling in Agroecosystems 80 (2):181-188.
32. Skoog, F. 1940. Relationships between zinc and auxin in the growth of higher plants. American Journal of Botany 939-951.
33. Stomph, T. J., Hoebe, N., Spaans, E., and Van der Putten, P. E. L. 2011. The relative contribution of post-flowering uptake of zinc to rice grain zinc density. In 3rd International Zinc Symposium. (pp. 10-14). Hyderabad. India.
34. Valinejad, M. 2001. Determination of critical level of potassium and zinc in several paddy fields of Mazandaran province. Soil Science master's thesis. Islamic Azad University, Science and Research Branch of Tehran. Tehran, Iran. (in Persian with English abstract).
35. Wijebandara, D. M. D. I., Dasog, G. S., Patil, P. L., and Hebbar, M. 2009. Effect of nutrient levels and biofertilizer on growth and yield of paddy under System of Rice Intensification (SRI) and conventional methods of cultivation. Tropical Agricultural Research 20: 343-353.
36. Wu, C.Y., Lu, L. L., Yang, X. E., Feng, Y., Wei, Y. Y., Hao, H. L., Stoffella, P. J., and He, Z. L. 2010. Uptake, translocation, and remobilization of zinc absorbed at different growth stages by rice genotypes of different Zn densities. Journal of agricultural and food chemistry 58 (11): 6767-6773.
37. Zayed, B. A., Salem, A. K. M., and El Sharkawy, H. M. 2011. Effect of different micronutrient treatments on rice (Oryza sativa L.) growth and yield under saline soil conditions. World Journal of Agricultural Sciences 7 (2): 179-184.
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History

  • Receive Date: 10 October 2016
  • Revise Date: 23 January 2017
  • Accept Date: 05 April 2017
  • First Publish Date: 21 March 2018

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