Evaluation of Relationship Between Auxin and Cytokinine Hormones on Yield and Yield Components of Maize under Drought Stress Condition

Document Type : Research Article

Authors

1 Chamran University of Ahwaz

2 -

3 Seed and Plant Improvement Institute, Karaj

Abstract

Introduction
Drought is one of the major environmental conditions that adversely affects plant growth and crop yield. In the face of a global scarcity of water resources, water stress has already become a primary factor in limiting crop production worldwide. Drought is the major restriction in maize production. The plant growth reduction under drought stress conditions could be an outcome of altered hormonal balance and hence the exogenous application of growth regulators under stress conditions could be the possible means for reversing the effects of abiotic stress. Phytohormones such as auxine and cytokinine are known to be involved in the regulation of plant response to the adverse effects of stress conditions. Previous studies have shown that endogenous hormones are essential regulators for translocation and partitioning of photoassimilates for grain filling in cereal crops, and therefore could be involved in the regulation of grain weight and yield.
Materials and Methods
The experiment was carried out in three separately environments included non-drought stress environment (irrigation after soil moisture reached to 75% field capacity), drought stress in vegetative stage (irrigation after soil moisture reached to 50% field capacity in V4 to tasseling stage, but irrigation after soil moisture reached to 75% field capacity in pollination to physiological maturity stage) and drought stress in reproductive stage (irrigation after soil moisture reached to 75% field capacity in V4 to tasseling stage and irrigation after soil moisture reached to 50% field capacity in pollination to physiological maturity stage). Cytokinin hormone in three levels (control, spraying in V5 –V6 and V8-V10 stages) and auxin hormone in three levels (control, spraying in silk emergence stage and 15 days after that) were laid out as a factorial design based on randomized complete block with three replications in each environment at Seed and Plant Improvement Institute (SPII), Karaj, Iran, in 2013. Indole-3-butyric acid and N6-benzyladenin were used as auxin and cytokinin hormones, respectively. Concentration of auxine and cytokinine hormones were 10 and 50 mg per liter, respectively. Harvesting was done from 4.5 m2 at field maturity stage with 14 % grain moisture for estimating grain yield and yield components. SAS software (version 9.1) was used for statistical analysis. Traits means were compared by Duncan's multiple range tests in 5% probably level.
Results and Discussion
Drought stress effect was significant (P≤0.01) for ear number per plant, row/ear, grain number per m2, 1000 kernels weight and grain yield and it wasn’t significant for kernels/row. Spraying cytokinine hormone was significant (P≤0.01) on ear number per plant, row/ear, grain number per m2 and it was also (P≤0.05) significant for 1000 kernels weight but it wasn’t significant for kernels/row and grain yield. Spraying auxine hormone was significant (P≤0.01) for1000 kernels weight and grain yield and it wasn’t significant forother yield components. The maximum yield was obtained 12.80 and 12.24 tons per hectare in non-stress environment and using auxin hormone in silk emergence stage, respectively. Grain yield was decreased 49.21% under reproductive drought stress and grain yield difference between non drought stress and vegetative drought stress was not significant. Spraying cytokinine hormone increased ear number by 10% in V8-V10 stage. The maximum row/ear was 16.16 kernels per row which was obtained by spraying cytokinine hormone in V8-V10 stage. Spraying cytokinine hormone increased grain number per m2 up to 20.75% in V8-V10 stage but it decreased 1000 kernels weight up to 13.76% in the same stage. The maximum 1000 kernels weight was 313.87 gr that was obtained by spraying auxine hormone in silk emergence stage. Spraying auxine hormone increased grain yield up to 23.38% in silk emergence stage.
Conclusions
Based on the results of this experiment, maize was tolerant to drought stress up to 50% field capacity in vegetative stage, but grain yield was decreased by 48.04% under drought stress condition in reproductive stage, and spraying cytokinine and auxine hormones in V8-V10 and silk emergence stages respectively, could prevent about 20% of decreasing of grain yield. Therefore, under drought stress condition, spraying cytokinine and auxin hormones in V8 –V10 and silk emergence stage can be recommended as the best time for using these hormones respectively, because they can balance hormones rate disturbs under drought stress condition.

Keywords


1- Ahmadi, A., and Baker D. A. 1999. Effects of abscisic acid (ABA) on grain filling processes in wheat. Plant Growth Regulation. 28: 187–197. “The Role of Plant Hormones in Plants under Salinity Stress,” Book Salinity and Water Stress 44:1. pp. 45-50.
2- Athar, H. R. and Ashraf, M. 2005. Photosynthesis under drought stress. In: Pessarakli, M. (ed.), Handbook of Photosynthesis, pp: 793–804. Taylor and Francis, New York.
3- Choukan, R. 2012. Maize and Maize properties. SPII, Iran (In Persian).
4- Claassen, M. M., and Shaw, R. H .1970. Water deficit effects on corn. II. Grain components. Agronomy Journal 62: 652-655.
5- Doorenbos, J., Kassam, A.K., 1979. Yield response to water. Irrigation and Drainage Paper 33. FAO, United Nations, Rome, p. 176.
6- Emeadeas, G.O., Banziger, M. and Ribaut, T.M. 2000. Maize improvement for drought limited environments. In: Physiological Basis for Maize Improvement, pp: 75–111. Food Products Press, New York.
7- Farooq, M., Wahid, A. Kobayashi, N. Fujita, D. and Basra, S.M.A. 2009. Plant drought stress, effects, mechanisms and management. Agronomy for Sustainable Development 29: 185–212.
8- Karmoker, JL and Van Steveninck, FM .1979. The effect of abscisic acid on the uptake and distribution of ions in intact seedlings of Phaseolus vulgaris cv. Redland Pioneer. Plant Physiology 45: 453-459.
9- Kawai, M. and Uchimiga, H. 2000. Coleoptile senescence in rice (Oryza sativa L.). Annals of Botany 86:405–14.
10- Kowles, RV, Phillips RL .1988. Endosperm development in maize. International Review Cytology 112: 97-136.
11- Lur’, H. S. and Setter, T. 1993. Role of Auxin in Maize Endosperm Development’ Timing of Nuclear DNA Endoreduplication, Zein Expression, and Cytokinin. Plant Physiology 103: 273-280.
12- Marks, MD, Lindell, JS, Larkins, B.A .1985. Quantitative analysis of the accumulation of zein mRNA during maize endosperm development. Journal of Biological Chemistry 260: 16445-16450.
13- Muraro, D. Byrne, H., King, J., VoB, U., Kiber, J. and Bennett, M. 2011. The influence of cytokinin–auxin cross-regulationon cell-fate determination in Arabidopsis thaliana root development. Journal of Theoretical Biology 283:152–167.
14- Nabipour M., Khamady, N. Khamady F. Mahrokh A. Davani D., Nasiri M., Ahmadpour S.R., and sayahi N. 2013. Plasmodesmata. Vasef Lahiji Publications (In Persian).
15- Nabipour, M. Atlasi Pak, V. Abdeshahian, M. and Hasibi, P. 2011. Crop responses and adaptation to temperature stress. Ahwaz Shahid Chamran University Puplication (In Persian).
16- Ober, E. S., Setter, T. L, Madison, J. T., Thompson, J. F., and Shapiro, P. S. 1991. Influence of Water Deficit on Maize Endosperm Development. Plant Physiology 97:154-164.
17- POSPisILOVA, J. 2003. Participation of phytohormones in the stomatal regulation of gas exchange during water stress. Biologia plantarum 46(4): 491-506.
18- Sallah, P.Y.K., Antwi K.O. and Ewool, M.B. 2002. Potential of elite maize composites for drought tolerance in stress and non-drought stress environments. African Crop Science Journal 10: 1–9.
19- Shaddad, M. A. K., Hamdia Abd El-Samad, M. and Mohammed, H. T. 2011. Interactive Effects of Drought Stress and Phytohormones or Polyamines on Growth and Yield of Two M (Zea maize L.) Genotypes. American Journal of Plant Sciences 2: 790-807.
20- Slovin, J.P., Bandurski, R.S., Cohen, J.D. 1999. Auxin. In: Hooykaas, P.J.J., Hall, M.A., Libbenga, K.R. (ed.): Biochemistry and Molecular Biology of Plant Hormones. Pp. 115-140. Elsevier, Amsterdam.
21- Walker, M. A. and Dumbroff, B.1981. “Effect of Salt Stress on Abscisic and Cytokinin Levels,” Zeitschrift für Pflanzen Physiologie, Vol. 101, p. 661.
22- Wang R.Y., Yu Z.W. and Pan Q.M. 1999. Changes of endogenous plant hormone contents during grain development in wheat. Acta Agronmica Sinica 25(3): 227–231.
23- Wang, C. A. Yang, H. Yin and Zhang, J. 2008. Influence of Water Stress on Endogenous Hormone Contents and Cell Damage of Maize Seedlings. Journal of Integrative Plant Biology 50 (4): 427–434.
24- Yang, J., Zhang, J., Wang, Z. and Zhu, Q. 2003. Hormones in the grains in relation to sink strength and postanthesis development of spikelets in rice. Plant Growth Regulation 41: 185–195.
25- Zažimalova, E., Kaminek, M., Březinova, A., Motyka, V. 1999. Control of cytokinin biosynthesis and metabolism. - In: Hooykaas, P.J.J., Hall, M.A., Libbenga, K.R. (ed.): Biochemistry and Molecular Biology of Plant Hormones. Pp. 141-160. Elsevier, Amsterdam.
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