Effect of Seed Priming and Encrusting Coating on Yield and Yield Components of Two Rice Cultivars

Document Type : Research Article

Authors

Department of Seed Improvement, Rice Research Institute of Iran, Agricultural Research, Education and Extension Organization (AREEO), Rasht, Iran

Abstract

Introduction: Rice (Oryza sativa L.) is one of the most important staple food crops in the world. However, rapid increase in world population and adverse effects of climate change, such as prolonged drought, has resulted in challenges in food security. One of the important factors in reducing rice yield can be the emergence and poor establishment of seedlings in the field. Seed treatment before sowing is the foundation for activation of seed resources that in combination with external ingredients could contribute to the efficient plant growth and high yield. Various physiological and non-physiological techniques are available for enhancing seed performance as well as to combat environmental constraints. Pre-sowing seed treatment such as seed coating and seed priming could improve the seed germination and vigor particularly under unfavorable environmental conditions.
Materials and Methods: In order to investigate the effect of priming and seed coating on emergence characteristics, yield and yield components of rice, a field experiment was conducted in the 2020 growing season, Rice Research Institute of Iran (RRII). The experiment was performed as a factorial in a randomized complete block design with three replications. Experimental factors include rice cultivars (Hashemi and Gohar) and treatment of rice cultivars in seven levels including 1- Priming with calcium chloride (-1.25 MPa in 24 hours), 2- Priming with potassium chloride (1.25 MPa in 24 hours), 3- Priming with zinc sulfate (concentration of 0.5 mM in 12 hours), 4- Hydropriming (48 hours) + Coating the seeds with calcium chloride, 5- Hydropriming (48 hours) + Coating With potassium chloride, 6- Hydropriming (48 hours) + coating with zinc sulfate and 7- Hydropriming (48 hours as control).
Results and Discussion: The results showed that the highest emergence percentage with 87% and 94% and the emergence rate with 0.17 and 0.19 (1.day-1) were obtained in Hashemi and Gohar cultivars, respectively. From these results, it is inferred that Gohar cultivar has higher genetic potential and physiological quality than Hashemi cultivar. The results of mean comparison showed that the highest height of rice plant with 147 and 143 cm was observed in coating and priming with potassium chloride in Hashemi cultivar, respectively. The results of this study attributed the increase in height to the effect of pretreatment on increasing the rate of emergence and better establishment of seedlings due to better plant use of related resources. The results showed that seed pretreatment with calcium chloride, potassium chloride and zinc sulfate increased the panicle length by 27, 24 and 12% under priming and 37, 34 and 17% under seed coating, respectively. The results of the mean comparison table showed that the highest panicle weight with 1.35 and 1.32 g was observed by seed coating with potassium chloride and calcium chloride, respectively. However, priming with calcium chloride, potassium chloride and zinc sulfate also increased the cluster weight by 12, 17 and 5%, respectively, compared to the control treatment. The results showed that the highest 1000-seed weight was obtained among the two cultivars with 24.63 g in Gohar cultivar. Also, the findings of this study showed well that pretreatment of rice seeds can increase the 1000-seed weight. Pretreatment of rice seeds with calcium chloride, potassium chloride and zinc sulfate 10, 12 and 5% under priming and 18, 22 and 10% under seed coating, respectively, increased 1000-seed weight. The results of mean comparison showed that grain yield in Hashemi and Gohar cultivars were 3046 and 4929 kg.ha-1, respectively. Pretreatment of rice seeds with calcium chloride and potassium chloride 14 and 20% under priming and 19 and 23% seed coating respectively, increased rice grain yield. In general, the increase in grain yield can be due to the improvement of antioxidant properties, proper establishment and optimal use of environmental factors such as light, soil moisture and nutrients.
Conclusions: According to the results of this study, priming and seed coating treatments with calcium chloride and potassium chloride in rice cultivars can increase rice yield by improving seedling characteristics. Therefore, farmers can be advised to use a simple and inexpensive crop management method to pre-treat seeds with calcium chloride and potassium chloride.

Keywords

Main Subjects


  1. Abbas Dokht, H., and Aref beyki, M. 2015. The effects of hydropriming, planting depth and nitrogen split application on grain yield and it’scomponents of 370 double cross hybrid corn in arid zone. Journal of Plant Production Research 22 (1): 149-172. (in Persian with English abstract).
  2. Abbas Dokht, H., Afshari, H., Owji, E., and Taheri, S. 2016. The effect of seed priming and different levels of nitrogen application on quantitative and qualitative yield of sunflower progress cultivar. Crop Physiology 8 (29): 105-120. (in Persian with English abstract).
  3. Ahmad, R., Hussain, S., Farooq, M., Rehman, A. U., and Jabbar, A. 2013. Improving the performance of direct seeded system of Rrice intensification by seed priming. International Journal of Agriculture and Biology 15 (4): 791-794.
  4. Akhgary, H., Esfahani, M., Mohsenabadi, G. R., and Alami, A. 2017. Evaluating the effect of seed priming on growth and yield of two rice (Oryza sativa) cultivars in direct seeding method. Cereal Research 7 (3): 315-329.
  5. Arif, M., Tariqjan, M., Marwat K. R., and Azim khan, M. 2008. Seed priming improves emergence and yield of soybean. Pakistan Journal of Botany 40 (3): 1169-1177.
  6. Ashraf, M., and Foolad, M. R. 2005. Pre-sowing seed treatment– A shot-gun approach to improve germination, plant growth and crop yield under saline and non-saline conditions. Advances in Agronomy 88: 223-271.
  7. Dastan, S., Noormohamadi, G., and Madani, H. 2014. Comparison of agronomical traits of four rice genotypes in cropping systems at Neka region. Journal of Crops Improvement 16 (2): 231-246. (in Persian with English abstract).
  8. Du, L. V., and Tuong, T. P. 2002. Enhancing the performance of dry-seeded rice: effects of seed priming, seedling rate, and time of seedling. In: Pandey, S., Mortimer, M., Wade, L., Tuong, T. P., Lopes, K., and Hardy B. (eds), Direct seeding: Research strategies and opportunities. International Research Institute, Manila, Philippines 241-256.
  9. Du, B., Luo, H., He, L., Zheng, L., Liu, Y., Mo, Z., Pan, S., Tian, H., Duan, M., and Tang, X. 2019. Rice seed priming with sodium selenate: Effects on germination, seedling growth, and biochemical attributes. Scientific Reports 9: 1-9.
  10. Farooq, M., Basra, S. M. A., and Hafeez, K. 2006. Seed invigoration by osmohardening in coarse and fine rice Seed Science and Technology 341: 181-187.
  11. Farooq, M., Basra, S. M. A., and Ahmad, N. 2007. Improving the performance of transplanted rice by seed priming. Plant Growth Regulation 51: 129-137.
  12. Farooq, M., Wahid, A., and Siddique, K. H. M. 2012. Micronutrient application through seed treatments–a review. Journal of Soil Science and Plant Nutrition 12: 125-142.
  13. Farooq, M., Basra, S. M. A., and Wahid, A. 2015. Priming of field-sown rice seed enhances germination, seedling establishment, allometry and yield. Plant Growth Regulation 49: 285-294.
  14. Food and Agriculture Organization Corporate Statistical Database (FAOSTAT). 2020. Food and Agriculture Organization of the United Nations Database; Food and Agriculture Organization (FAO), Rome. Available online: http://www.fao.org.
  15. Gallardo, K., Job, C., Groot, S. P. C., Puype, M., Demol, H., and Job, D. 2001. Proteomic analysis of Arabidopsis seed germination and priming. Plant Physiology 126: 835-848.
  16. Harris, D., Pathan, A. K., Gothkar, P., Joshi, A., Chivasa, W., and Nyamudaza, P. 2001. On-farm seed priming: using participatory methods to revive and refine a key technology. Agricultural Systems 69: 151-164.
  17. Hasan, M. N., Salam, M. A., Chowdhury, M. M. L., Sultan, M., and Islam, N. 2016. Effect of osmopriming on germination of rice seed. Bangladesh Journal of Agricultural Research 41 (3): 451-460.
  18. Hussain, S., Khan, F., Cao, W., Wu, L., and Geng, M. 2016. Seed priming alters the production and detoxification of reactive oxygen intermediates in rice seedlings grown under sub-optimal temperature and nutrient supply. Frontiers in Plant Science 7: 1-14.
  19. Imran, M., Mahmood, A., Romheldand, V., and Neuman, G. 2013. Nutrient seed priming improves seedling development of maize exposed to low root zone temperatures during early growth. European Journal of Agronomy 49: 141-148.
  20. International Rice Research Institute (IRRI). 2020. International Rice Research Institute. Available online: http://www.irri.org.
  21. Kalita, U., Suhrawardy, J., and Das, J. R. 2002. Effect of seed priming with potassium salt and potassium levels on growth and yield of direct seeded summer rice (Oryza sativa) under rainfed upland condition. Indian Journal of Hill Farming 15: 50-53.
  22. Khaliq, A., Aslam, F., Matloob, A., Hussain, S., Geng, M., Wahid, A., and Rehman, H. 2015. Seed priming with selenium: consequences for emergence, seedling growth, and biochemical attributes of rice. Biological Trace Element Research 166 (2): 236-244.
  23. Khan, A. A., Ilyas, S., and Ptasznik, W. 1995. Integrating low water potential seed hydration with other treatments to improve cold tolerance. Annals of Botany 75: 13-19.
  24. Latifzadeh, M., Aboutalbian, M. A., Zavareh, M., and Rabiei, M. 2013. Effects of seed priming and sowing dates on seedling emergence, yield and yield components of a local genotype bean as a double crop in Iranian Journal of Field Crop Science 44 (1): 23-33. (in Persian with English abstract).
  25. Mahajan, G., Sarlach, R. S., Japinder, S., and Gill, M. S. 2011. Seed priming effects on germination, growth and yield of dry directed-seeded rice. Journal of Crop Improvement 25 (4): 409-417.
  26. Mohagheghi, A., and Aboutalbian, M. A. 2014. Study of sowing date and seed priming effect on seed yield, its components and some of agronomic and qualitative properties of two spring canola cultivars in Hamedan. Iranian Journal of Field Crops Research 12 (3): 516-525. (in Persian with English abstract).
  27. Musa, A., Harris, D., Johansen, C., and Kumar, J. 2001. Short duration chick pea to replace fallow after a man-rice: the role of on farm seed priming in the High Barind Tract of Bangladesh. Experimental Agriculture 37 (4): 509-521.
  28. Nawaz, A., Farooq, M., Ahmad, R., Basra, S. M. A., and Lal, R. 2016. Seed priming improves stand establishment and productivity of no till wheat grown after direct seeded aerobic and transplanted flooded rice. European Journal of Agronomy 76: 130-137.
  29. Nie, L., Liu, H., Zhang, L., and Wang, W. 2020. Enhancement in rice seed germination via improved respiratory metabolism under chilling stress. Food and Energy Security 9 (4): 1-13.
  30. Priya, T. S. R., Nelson, A. R. L. E., Ravichandran, K., and Antony, U. 2019. Nutritional and functional properties of coloured rice varieties of South India: A review. Journal of Ethnic Foods 6: 1-11.
  31. Rahchamani, H., Aboutalbian, M. A., Ahmadvand, G., and Jahedi, A. 2013. Effects of on-farm seed priming and sowing date on germination properties and some physiological growth indices of three soybean cultivars (Glycine max) in Hamedan. Iranian Journal of Field Crop Science 43 (4): 715-728. (in Persian with English abstract).
  32. Rashid, A., Harris, D., Hollington, P. A., and Rafiq, M. 2004. Improving the yield of mungbean (vigna radiata) in the North West frontier province of Pakistan using on-farm seed priming. Experimental Agriculture 40: 233-244.
  33. Rehman, H. U., Basra, S. M. A., and Farooq, M. 2011. Field appraisal of seed priming to improve the growth, yield, and quality of direct seeded rice. Turkish Journal of Agriculture and Forestry 35: 357-365.
  34. Rehman, A., Farooq, M., Ahmad, R., and Basra, S. M. A. 2015. Seed priming with zinc improves the germination and early seedling growth of wheat. Seed Science and Technology 43: 262-268.
  35. Rezvantalab, N., Dastan, S., Soltani, A. 2019. Identification of production constraints and yield gap monitoring of local rice (Oryza sativa) cultivars in Mazandaran province. Iranian Journal of Crop Sciences 21 (2): 155-172. (in Persian with English abstract).
  36. Roy, N. K., and Srivastava, A. K. 2009. Adverse effect of salt stress conditions on chlorophyll content in wheat (Triticum aestivum) leaves and its amelioration through pre-soaking treatments. Indian Journal of Agriculture Science 70: 777-778.
  37. Seyami, R., Mirshekari, B., Farahvash, F., Rashidi, V., and Tari Nejad. A. R. 2017. The effect of seed priming with salicylic acid and water deficit tension on enzyme activity and yield of grain corn. Crop Physiology 9 (34): 23-35. (in Persian with English abstract).
  38. Shivankar, R. S., Deore, D. B., and Zode. N. G. 2003. Effect of pre-sowing seed treatment on establishment and seed yield of sunflower. Journal of Oilseeds Research 20: 299-300.
  39. Shivay, Y. S., Kumar, D., Prasad, R., and Ahlawat, L. P. S. 2008. Relative yield and zinc uptake by rice from zinc sulphate and zinc oxide coatings onto urea. Nutrient Cycling in Agroecosystems 80: 181-188.
  40. Soltani, E., Miri, A. A., and Ghaderifar, F. 2009. The effect of seed priming on emergence and yield of cotton at different sowing date. Journal of Plant Production 16 (3): 163-174.
  41. Soltani, A., and Madah, V. 2010. Simple Applied Programs for Education and Research in Agronomy. Iranian Society of Ecological Agriculture. Tehran. Iran. 80p. (in Persian).
  42. Subedi, R., Maharjan, B. K., and Adhikari, R. 2015. Effect of different priming methods in rice. Journal of Agricultural and Environmental 16: 156-160.
  43. Taghi Zoghi, S., Soltani, E., Allahdadi, I., and Sadeghi, R. 2018. The effects of seed coating treatments on seedling emergence and growth of rapeseed and the growth of pathogenic fungi. Iranian Journal of Seed Science and Research 5 (3): 103-115. (in Persian with English abstract).
  44. Taheri, S., Gholami, A., Abbas Dokht, H., and Makarian, H. 2018. Response of yield, yield components and seed quality of safflower cultivars to water deficit tension and seed priming. Crop Physiology 10 (38): 39-58. (in Persian with English abstract).
  45. Tajbakhsh, M., Hasanzadeh, A., and Aghaii, R. 2015. The effect of different priming treatments on morphophysiological characteristics and yield of two wheat cultivars in optimal conditions and irrigation cut-off. Applied Field Crops Research 28 (4): 74-84. (in Persian with English abstract).
  46. Toklu, F. 2015. Effect of different priming treatments on seed germination properties yield components and grain yield of lentil. Notulae Botanicae Horti Agrobotanici Cluj-Napoca 43 (1): 153-158.
  47. Varier, A., Vari, A. K., and Dadlani, M. 2010. The subcellular basis of seed priming. Current Science 99: 450-456.
  48. Wang, S., Wang, E., Wang, F., and Tang, L. 2012. Phenological development and grain yield of canola as affected by sowing date and climate variation in the Yangtze River Basin of China. Crop and Pasture Science 63: 478-488.
  49. Zeb, T., and Arif, M. 2008. Effect of zinc application methods on yield and yield components of maize. Australian Journal of Crop Science 3 (2): 37-41.
CAPTCHA Image