Effect of Seed Priming with Zinc on Seed Germination Characteristics, and Morphological Characters, and Mineral Content of Rice Tissues of Hashemi Rice Cultivar

Document Type : Research Paper

Authors

1 Assistant Professor of rice research institute of Iran

2 Associate Professor of Rice Research Institute of Iran, Agricultural Research, Education and Extension Organization, Rasht, Iran

3 1Assistant Professor of Rice Research Institute of Iran, Agricultural Research, Education and Extension Organization, Rasht, Iran

4 Research Assistant of Rice Research Institute of Iran, Agricultural Research, Education and Extension Organization, Rasht, Iran.

Abstract

Nutripriming of rice seeds with micronutrient (Zn) is considered to have the potential of optimizing Zn application, faster germination, uniform seedlings’ growth, better establishment of transplanted rice seedlings. The current experiments were designed and conducted to explore the effects of rice seeds nutripriming of with micronutrient (Zn) on macro and micronutrient content of primed seeds, morphological characteristics of rice seedlings and uptake of macro and micronutrients (N, P, K, Zn) for Hashemi rice cultivar through two laboratory and open-air pot experiments during 2021 at rice research institute of Iran. The highest increase in seed germination vigor index (2.9 times) ad reduction in germination dynamics or three germination fractions (t 10, t 50, and t 90) compared to control were recorded at nutripriming with zinc sulfate (5g. L-1) for 12 hours by about 2.28, 2.49, and 2.47 times, respectively. The maximum increase in Zn content of rice seeds (17.5 times) were observed at nutripriming with zinc sulfate (5g.L-1) for 24 hours compared to the control. Also, the highest positive, significant increase in the length of coleoptile and radicle by seed nutripriming with zinc sulfate (5g.L-1) for 6 hours compared to the control by about 25.87 and 18.67%, respectively. The maximum significant and positive increase in root wet and dry weight of rice seedlings were found at about 24.36, 20.00, 38.23, and 38% compared to the control through nutripriming of seeds with zinc sulfate (5g.L-1) for 6 hours in soils with Zn deficiency and sufficiency, respectively. The highest significant and effect on Zn content of shoot and root of rice seedlings were observed about 2.71, 2.91, 2.27, and 2.51 compared to the control through nutripriming of seeds with zinc sulfate (5g.L-1) for 6 hours in soils with Zn deficiency and sufficiency, respectively. Nutripriming of rice seeds with zinc sulfate (5g.L-1) solution for 6 hours could be an alternative solution for traditional methods of macro and micronutrients application (soil and foliar) by farmers in seed nursery.

Keywords

Main Subjects

Effect of Seed Priming with Zinc on Seed Germination Characteristics and Morphological Characters and Mineral Content of rice tissues of Hashemi Rice Cultivar

EXTENDED ABSTRACT

Introduction:

Nutripriming of rice seeds with micronutrient (Zn) is considered to have the potential of optimizing Zn application, faster germination, and uniform seedlings’ growth, better establishment of transplanted seedlings, higher grain yield, and nutritional quality.

 

Objectives:

The current experiments were designed and conducted to explore the effects of rice seeds nutripriming of with micronutrient (Zn) on macro and micronutrient content of primed seeds, morphological characteristics of rice seedlings and uptake of macro and micronutrients (N, P, K, Zn) for rice cv. ‘Hashemi’.

 

Materials and Methods:

The current researches were carried out in three different experiments during 2021 rice growing season at the Rice Research Institute of Iran, Rasht, Iran. The first and the second experiment were done in laboratory conditions and the third experiment was done as a pot experiment based completely random design (CRD), CRD and randomized complete block (RCBD) design with three replications, respectively. The experimental factors of the two first experiments were: nutripriming with zinc sulfate (5g.L-1) on 6, 12, and 24 hours, and control. For the third experiment the soil types at two levels (less and more than Zn critical level (2 mgkg-1) were added to previous factors. The measured characters were Zn, N, P, K content of seeds and diffrenet parts of rice seedlings, length of root and shoot, root and shoot wet and dry weights.

 

Results:

The highest increase in seed germination vigor index (2.9 times) ad reduction in germination dynamics or three germination fractions (t 10, t 50, and t 90) were recorded at nutripriming with zinc sulfate (5g. L-1) for 12 hours compared to the control by about 2.28, 2.49, and 2.47 times, respectively. The maximum increase in Zn content of rice seeds (17.5 times) were observed at nutripriming with zinc sulfate (5g.L-1) for 24 hours compared to the control. Also, the highest positive and significant increase in the root and shoot length recorded in seed nutripriming with zinc sulfate (5g.L-1) for 6 hours compared to the control by about 25.87 and 18.67%, respectively. The maximum significant and positive increase in root wet and dry weights of rice seedlings were found at about 24.36, 20.00, 38.23, and 38% compared to the control through nutripriming of seeds with zinc sulfate (5g.L-1) for 6 hours in both soils with and without Zn deficiency, respectively. The highest significant effect on Zn content of shoot and root of rice seedlings were observed about 2.71, 2.91, 2.27, and 2.51 compared to the control through nutripriming of seeds with zinc sulfate (5g.L-1) for 6 hours in soils with Zn deficiency and sufficiency, respectively.

 

Conclusion:

Nutripriming of rice seeds with zinc sulfate (5g.L-1) solution for 6 hours is an easy, quick and effective solution to remediate rice plant Zn requirment, improve seedlings quality and crop stablishment.

References

Adhikary, S., Biswas, B., Chakraborty, D., Timsina, J., Pal, S., Chandra Tarafdar, J., & Roy, S. (2022). Seed priming with selenium and zinc nanoparticles modifies germination, growth, and yield of direct-seeded rice (Oryza sativa L.). Scientific Reports12(1), 7103.
Akhgari, H., & Kaviani, B. (2019). Effect of priming on seed and plantlet vigor of two cultivars of rice (Oryza sativa L.). Seed Science and Technology8(1), 1-17. (In Persian).
Akhgari, H., Esfahani, M., Mohsenabadi, G., & Aalami, A. (2017). Evaluating the effect of seed priming on growth and yield of two rice (Oryza sativa L.) cultivars in direct seeding method. Cereal Research7(3), 315-329. (In Persian).
Akhondi, M., Safarnejad, A., & Lahouti, M. (2006). Effect of drought stress on proline accumulation and mineral nutrients change in alfalfa (Medicago sativa L.). JWSS-Isfahan University of Technology10(1), 165-175. (In Persian).
Ali, L. G., Nulit, R., Ibrahim, M. H., & Yien, C. Y. S. (2021). Efficacy of KNO3, SiO2 and SA priming for improving emergence, seedling growth and antioxidant enzymes of rice (Oryza sativa), under drought. Scientific Reports11(1), 1-11.
Ancy, L.U., & STANLY, N. (2022). Effect of nutripriming treatments on growth parameters of seedlings in tray nursery of rice: Effect of nutripriming on tray nursery of rice. Journal of AgriSearch, 9(1), 59-62.
Ashraf, M., & Foolad, M. R. (2005). Pre‐sowing seed treatment—A shotgun approach to improve germination, plant growth, and crop yield under saline and non‐saline conditions. Advances in Agronomy88, 223-271.
Attar, B., Uygur, V., & Sukuşu, E. (2020). Effects of priming with Copper, Zinc and Phosphorus on seed and seedling composition in Wheat and Barley. Türk Tarım ve Doğa Bilimleri Dergisi7(1), 104-111.
Basra, S. M. A., Farooq, M., Tabassam, R., & Ahmad, N. (2005). Physiological and biochemical aspects of pre-sowing seed treatments in fine rice (Oryza sativa L.). Seed Science and Technology33(3), 623-628.
Bates, R. G., & Vijh, A. K. (1973). Determination of pH: theory and practice. Journal of the Electrochemical Society, 120(8), 263C-263C.
Bremner, J. M. (1965). Total nitrogen. Methods of soil analysis: Book part 2 chemical and microbiological properties, 9, 1149-1178.
Broadley, M. R., White, P. J., Hammond, J. P., Zelko, I., & Lux, A. (2007). Zinc in plants. New Phytologist173(4), 677-702.
Brown, P. R., Tuan, V. V., Nhan, D. K., Dung, L. C., & Ward, J. (2018). Influence of livelihoods on climate change adaptation for smallholder farmers in the Mekong Delta Vietnam. International Journal of Agricultural Sustainability16(3), 255-271.
Cai, Y., Xu, W., Wang, M., Chen, W., Li, X., Li, Y., & Cai, Y. (2019). Mechanisms and uncertainties of Zn supply on regulating rice Cd uptake. Environmental Pollution253, 959-965.
Campbell, C. R., & Plank, C. O. (1998). Preparation of plant tissue for laboratory analysis. Methods for Plant Analysis37.
Chen, J., Dou, R., Yang, Z., You, T., Gao, X., & Wang, L. (2018). Phytotoxicity and bioaccumulation of zinc oxide nanoparticles in rice (Oryza sativa L.). Plant Physiology and Biochemistry130, 604-612.
Depar, N., Rajpar, I., Memon, M. Y., & Imtiaz, M. (2011). Mineral nutrient densities in some domestic and exotic rice genotypes. Pakistan Journal of Agriculture: Agricultural Engineering Veterinary Sciences (Pakistan).
Dobermann, A. and Fairhurst, T. (2000). Rice: Nutrient Disorders & Nutrient Management. Handbook Series, Potash & Phosphate Institute (PPI), Potash & Phosphate Institute of Canada (PPIC) and International Rice Research Institute, Philippine, 191.
Du, B., Luo, H., He, L., Zheng, L., Liu, Y., Mo, Z., Pan, S., Tian, H., Duan, M., & Tang, X. (2019). Rice seed priming with sodium selenate: Effects on germination, seedling growth, and biochemical attributes. Scientific Reports, 9(1), 4311.
Esper Neto, M., Britt, D. W., Lara, L. M., Cartwright, A., dos Santos, R. F., Inoue, T. T., & Batista, M. A. (2020). Initial development of corn seedlings after seed priming with nanoscale synthetic zinc oxide. Agronomy10(2), 307.
Faizan, M., Faraz, A., Yusuf, M., Khan, S. T., & Hayat, S. (2018). Zinc oxide nanoparticle-mediated changes in photosynthetic efficiency and antioxidant system of tomato plants. Photosynthetica56, 678-686.
FAO. 2018. Rice market monitor. Trade and Markets Division. Rome. Vol. XVI.
Farooq, M., Basra, S. M. A., Khalid, M., Tabassum, R., & Mahmood, T. (2006). Nutrient homeostasis, metabolism of reserves, and seedling vigor as affected by seed priming in coarse rice. Botany84(8), 1196-1202.
Farooq, M., Basra, S. M. A., Wahid, A., Khaliq, A., & Kobayashi, N. (2010). Rice seed invigoration: a review. Organic Farming, Pest Control and Remediation of Soil Pollutants: Organic farming, pest control and remediation of soil pollutants, 137-175.
Farooq, M., Wahid, A., & Siddique, K. H. (2012). Micronutrient application through seed treatments: a review. Journal of Soil Science and Plant Nutrition12(1), 125-142.
Gee, G. W., & Bauder, J. W. (1986). Particle-size analysis 1. Methods of soil analysis: Book part 1—physical and mineralogical methods, (methodsofsoilan1).
Guha, T., Mukherjee, A., & Kundu, R. (2021). Nano-scale zero valent iron (nZVI) priming enhances yield, alters mineral distribution and grain nutrient content of Oryza sativa L. cv. Gobindobhog: a field study. Journal of Plant Growth Regulation, 1-24.
Harris, D. (2006). Development and testing of “On‐Farm” seed priming. Advances in Agronomy90, 129-178.
Harris, D., Rashid, A., Miraj, G., Arif, M., & Shah, H. (2007). ‘On-farm’seed priming with zinc sulphate solution—A cost-effective way to increase the maize yields of resource-poor farmers. Field Crops Research102(2), 119-127.
Ibrahim, E. A. (2016). Seed priming to alleviate salinity stress in germinating seeds. Journal of Plant Physiology192, 38-46.
Imran, M., Mahmood, A., Römheld, V., & Neumann, G. (2013). Nutrient seed priming improves seedling development of maize exposed to low root zone temperatures during early growth. European Journal of Agronomy49, 141-148.
Imran, M., Neumann, G., & Römheld, V. (2004). Nutrient seed priming improves germination rate and seedling growth under submergence stress at low temperature. International Research on Food Security. Natural Resource Management and Rural Development Cuvillier Verlag Göttingen. 356-360.
International Rice Research Institute (IRRI). 2020. International Rice Research Institute. Available online: http://www.irri.org.
Johnson, S. E., Lauren, J. G., Welch, R. M., & Duxbury, J. M. (2005). A comparison of the effects of micronutrient seed priming and soil fertilization on the mineral nutrition of chickpea (Cicer arietinum), lentil (Lens culinaris), rice (Oryza sativa) and wheat (Triticum aestivum) in Nepal. Experimental Agriculture41(4), 427-448.
Latifi, S.A. & Omidi, H. (2020). Effect of priming on seed germination and rice seedling characteristics of Anbar Boo cultivar, under water deficit stress. Scientific Journal of Crop Physiology, 11(3), 5-21. (In Persian).
Li, Y., Liang, L., Li, W., Ashraf, U., Ma, L., Tang, X., ... & Mo, Z. (2021). ZnO nanoparticle-based seed priming modulates early growth and enhances physio-biochemical and metabolic profiles of fragrant rice against cadmium toxicity. Journal of Nanobiotechnology19(1), 1-19.
 Li, Y., Zhang, Y., Shi, D., Liu, X., Qin, J., Ge, Q., ... & Xu, J. (2013). Spatial‐temporal analysis of zinc homeostasis reveals the response mechanisms to acute zinc deficiency in Sorghum bicolor. New Phytologist200(4), 1102-1115.
Lindsay, W. L., & Norvell, W. (1978). Development of a DTPA soil test for zinc, iron, manganese, and copper. Soil Science Society of America Journal42(3), 421-428.
Mahmoudsoltani, S., 2020. Zn biofortification, grain protein content, and zinc and phosphorus content of rice tissues at different growth stages affected by zinc and phosphorus foliar application. Iran J Soil Water Res51(8), pp.2065-2083.
Mahmoudsoltani, S. 2018. Zinc deficiency, causes, symptoms and solutions. Technical Bulletin. Rice research institute of Iran.31p.
Mahmoudsoltani, S. and Poorsafar Tabalvandi, A. 2021. Nutripriming with micronutrients. Growth Improvement and grain biofortification. Technical bultein. Rice Research Institute of Iran. 46 Pp.
Mahmoud Soltani, S., Hossieni Chaleshtori, M., Tajaddodi Talab, K., Shokri Vahed, H. and Shakoori Katigari, M., 2023. Rice growth improvement, bio-fortification, and mitigation of macronutrient requirements through foliar application of zinc and iron-glycine chelate and zinc sulfate. Journal of Plant Nutrition46(8), pp.1777-1786.
Malakooti, M.J. & Kavoosi, M. 2004. Balanced Rice Nutrition. Sena Publication. Agricultural Minestry of Iran. 671 P. (In Persian).
Moghaddasi, S., Fotovat, A., Karimzadeh, F., Khazaei, H. R., Khorassani, R., & Lakzian, A. (2017). Effects of coated and non-coated ZnO nano particles on cucumber seedlings grown in gel chamber. Archives of Agronomy and Soil Science63(8), 1108-1120.
Nawaz, A., Farooq, M., Ahmad, R., Basra, S. M. A., & 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 Agronomy76, 130-137.
Nazari, S., Chaleshtori, M. H., & Allahgholipour, M. (2021). Effect of Seed Priming and Encrusting Coating on Yield and Yield Components of Two Rice Cultivars. Iranian Journal of Field Crops Research19(3). (In Persian).
Olsen, S. R., & Dean, L. A. (1965). Phosphorus. Chemical and microbiological properties. Methods of Soil Analysis, Part2, 1035-1048.
Ozturk, L., Yazici, M. A., Yucel, C., Torun, A., Cekic, C., Bagci, A., ... & Cakmak, I. (2006). Concentration and localization of zinc during seed development and germination in wheat. Physiologia plantarum128(1), 144-152.
Razak, U. N. A. A., Ong, C. B., Yu, T. S., & Lau, L. K. (2014). In vitro micropropagation of Stevia rebaudiana Bertoni in Malaysia. Brazilian Archives of Biology and Technology57, 23-28.
Roades, J. D. (1982). Soluble salts. P 167-178. Methods of soil analysis. Part2.
Roriz, M., Carvalho, S. M., & Vasconcelos, M. W. (2014). High relative air humidity influences mineral accumulation and growth in iron deficient soybean plants. Frontiers in Plant Science5, 726.
Sadeghizadeh, M., & Zarea, M. J. (2022). Effects of seed priming with zinc on germination, nursery seedling growth and paddy fields yield of two rice (Oryza sativa L.) cultivars. Journal of Crop Science and Biotechnology25(3), 313-324.
Sarkar, R. K., Chakraborty, K., Chattopadhyay, K., Ray, S., Panda, D., & Ismail, A. M. (2019). Responses of rice to individual and combined stresses of flooding and salinity. In Advances in rice research for abiotic stress tolerance, 281-297. Woodhead Publishing.
Sharma, A. D., Rathore, S. V. S., Srinivasan, K., & Tyagi, R. K. (2014). Comparison of various seed priming methods for seed germination, seedling vigour and fruit yield in okra (Abelmoschus esculentus L. Moench). Scientia horticulturae165, 75-81.
Shivankar, R. S., Deore, D. B., & Zode, N. G. (2003). Effect of pre-sowing seed treatment on establishment and seed yield of sunflower. Journal of Oilseeds Research.20, 299-300.
Silveira, V. C. D., Oliveira, A. P. D., Sperotto, R. A., Espindola, L. S., Amaral, L., Dias, J. F., ... & Fett, J. P. (2007). Influence of iron on mineral status of two rice (Oryza sativa L.) cultivars. Brazilian Journal of Plant Physiology19, 127-139.
Singh, M. V. (2007). Efficiency of seed treatment for ameliorating zinc deficiency in crops. Zinc crops, 24-26.
Sivritepe, N., Sivritepe, H. O., & Eris, A. (2003). The effects of NaCl priming on salt tolerance in melon seedlings grown under saline conditions. Scientia horticulturae97(3-4), 229-237.
Soltani, A. & Maddah, V. (2010). Simple, Applied Programs for Education and Research in Agronomy. Iran Scientific Society of Agroecology. Tehran. (In Persian). (In Persian).
Thomas, G. W. (1982). Exchangeable cations. Methods of soil analysis. Agronomy Monograph, Methods of Soil Analysis, Part2.
Tuiwong, P., Lordkaew, S., Veeradittakit, J., Jamjod, S., & Prom-u-thai, C. (2022). Seed priming and foliar application with nitrogen and zinc improve seedling growth, yield, and zinc accumulation in rice. Agriculture12(2), 144.
Varier, A., Vari, A. K., & Dadlani, M. (2010). The subcellular basis of seed priming. Current Science, 450-456.
Veena, M., & Puthur, J. T. (2022). Seed nutripriming with zinc is an apt tool to alleviate malnutrition. Environmental Geochemistry and Health44(8), 2355-2373.
Von Grebmer, K., Bernstein, J., Hossain, N., Brown, T., Prasai, N., Yohannes, Y., ... & Foley, C. (2017). 2017 Global Hunger Index: the inequalities of hunger (Report in Website). Intl Food Policy Res Inst.
Walkley, A., & Black, I. A. (1934). An examination of the Degtjareff method for determining soil organic matter, and a proposed modification of the chromic acid titration method. Soil Science37(1), 29-38.
Wissuwa, M., Ismail, A. M., & Yanagihara, S. (2006). Effects of zinc deficiency on rice growth and genetic factors contributing to tolerance. Plant Physiology142(2), 731-741.
Iranian Journal of Soil and Water Research
Volume 54, Issue 6
September 2023
Pages 895-914

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