Effect of Aerosols and Drought Stresses on Some Physiological Traits of Mungbean (Vigna radiata L.)

doi:10.22092/aj.2018.109025.1109

	Effect of Aerosols and Drought Stresses on Some Physiological Traits of Mungbean (Vigna radiata L.)
پژوهش های کاربردی زراعی
Article 2, Volume 30, Issue 2 - Serial Number 115, June 2017, Pages 19-30 PDF (507.77 K)
Document Type: Research Paper
DOI: 10.22092/aj.2018.109025.1109
Abstract
Introduction: Mungbean (Vigna radiata L.) is affected by some different stresses. Aerosol is one of the new problems that is accompanied by a drought stress in some Western and Southern parts of Iran (Marsafari, 2011). The increase of irrigation intervals reduces chlorophyll a and b and increases proline amino acid content of basil leaf (Gholdani, 2012). Zadeh Bagheri (2014) has indicated that the accumulation of sugar, chlorophyll, potassium and proline content in beans can be cause of drought-resistance in plants. The objective of this study was the evaluate aerosols along with drought stress effects on mungbean photosynthetic pigments, nitrogen compounds, soluble sugars and grain yield. Materials and Methods: The research was conducted to study the effect of drought and aerosol stresses on physiological traits of mungbean (Vigna radiata L.) in the Lorestan Agricultural and Natural Resources Research and Education Center which lies at latitude 33° and 29' N, longitude 48° and 18' E, and an altitude of 1195 m above sea level in 2015. Before the beginning of the experiment, soil samples were taken in order to determine the physical and chemical properties. A split plot design based on RCBD was used with four replications. Four different irrigation regimes after 70 (well irrigated treatment), 80 , 90 and 100 mm evaporation from pan class A were assigned to main plot, and three aerosol levels did not contain aerosols (control) and using 50 and 100 mg m-3 aerosols in clay soil sours were randomized in subplots. Chlorophyll a, chlorophyll b, chlorophyll a + b, soluble sugars and protein content in leaves were measured at flowering period and grain yield was measured at harvesting time. The data were statistically analyzed using the MSTAT-C and SAS softwares. Comparison of means was performed using the Least Significant Difference test at 5% probability level. Results & Discussion: Result showed that chlorophyll a, chlorophyll b, chlorophyll a+b was significantly affected by drought stress. Aerosol only affects chlorophyll a. Drought and aerosol stresses interaction had a significant effect on chlorophyll a and decreased it. The highest amount of chlorophyll a (0.015 mg g-1 FW) in leaves was achieved by normal irrigation in different levels of the aerosol. Chlorophyll b, chlorophyll a + b significantly reduced by drought stress from 0.0083 and 0.024 in normal irrigation condition to 0.0037 and 0.01 mg g-1 FW in severe drought stress, respectively. Sugar of leaves was also significantly reduced by drought stress from 1.86 in normal irrigation condition to 4.62 mg g-1 FW in severe drought stress. Protein content was also significantly affected by drought stress and decreased from 0.15 in normal irrigation condition to 0.05 mg g-1 DW in severe drought stress. Significant and negative linear relationship was found between drought stress and grain yield, but found a significant and positive linear relationship between drought stress and leaf proline. Conclusion In addition, according to data analysis in this experiment, the synergistic effect was found in higher levels of drought stress and aerosols on chlorophyll a. Chlorophyll b, chlorophyll a + b, soluble sugars and protein contents significantly decreased by drought stress. Also, Significant and negative linear relationship was found between drought stress and grain yield, but between drought stress and leaf proline was found to be significant and positive. Therefore, it seems that provision of water requirement of mungbean plant in the region, while preventing the decrease in grain yield, does not have a negative effect of aerosols on the plant. Key words: chlorophyll a, chlorophyll b, chlorophyll a+b, osmatic adjustment, grain yield. References Gholdani, M. 2012. Effect of irrigation intervals on some morphophysiological traits of basil (Ocimum basilicum L.) ecotypes. Iranian Journal of Field Crops Research, 10(2):412-420 (In Persian with English Summary). Marsafari, M., Asoudar, M.A. and Kordi, S. 2011. Aerosol resources and adjust their harm effects. Second national conference on critical management. Tehran. Iran. doi: http://www.civilica.com/Paper-NCEVSLL02-NCEVSLL02_388 (In Persian). Nourian, M.H., Zabihi, H. R. and Oveisi, M. 2015. Evalution of biofertilizers and B foliar application effects on grain yield in drought stress condition. Soil researches (Soil and Water Scince), 29(4): 179-186 (In Persian with English Summary).
Keywords
Chlorophyll a; chlorophyll b; chlorophyll a + b; osmatic adjustment; Grain yield

References
Ali, M. and Kumar, S. 2004. Prospects of mungbean in rice-wheat cropping systems in Indo-Gangetic Plains of India. In: Proceedings of the Final Workshop and Planning Meeting. Improving Income and Nutrition by Incorporating Mungbean in Cereal Fallows in the Indo-Gangetic Plains of South Asia, S. Shanmugasundaram (ed.). DFID Mungbean Project for 2002–2004, 27–31 May 2004, Ludhiana, Punjab,India, pp. 246-254. Arnon, D.I. 1949. Copper enzymes in isolated chloroplasts. Polyphenoloxidase in Beta vulgaris. Plant Phisiology, 24: 1-15. Bahramichegeni, Z., Amiri, H. and LariYazdi, H. 2013. Effect of drought stress on some physiological parameters of basil. Agricultural Science and Tecnology,419-430 (In Persian with English Summary). Bates, L.S., Waldren, R.P. and Teare, I.D. 1973. Rapid determination of free proline for water-stress studies. Plant and Soil, 39: 205-207. Belayet, H.M., Rahman, W., Rahman, M.N., Noorul Anwar, A.H.M. and Hossen, A.K.M.M. 2010. Effects of water stress on yield attributes and yield of different mungbean genotypes. African Journal of Biochemistry Research,5:19-24. Chameides, W.L. 1999. Case study of the effects of atmospheric aerosols and regional haze on agriculture: An opportunity to enhance crop yields in China through emission controls? Proceeding of the national Academy of Science of the United State of America, 96, 13, 326-13, 633. Cha-um, S., and Kirdmanee, Ch. 2009. Proline accumulation, photosynthetic abilities and growth characters of sugarcane (Saccharum officinarum L.) plantlets in response to iso-osmotic salt and water-deficit stress. Agricultural Sciences in China, 8(1): 51-58. Chaves, M.M., Pereira, J.S., Maroco, J., Rodrigues, M.L., Ricardo, C.P.P., Osorio, M.L., Carvalho, I., Faria, T. and Pinheiro, C. 2002. How plants cope with water stress in the field. Photosynthesis and growth. Journal of Annals Botany, 89: 907-916. Cornic, G. and Briantais, J.M. 1991. Partitioning of photosynthetic electron flow between and reduction in a leaf (Phasiolus vulgaris L. ) at different concentration and during water sue. Planta, 183: 178-184. Ehdaie, B., Alloush, G.A., Madore, M.A. and Waines, J.G. 2006. Genotypic variation for stem reserves and mobilization in wheat: I. postanthesis changes in internode dry matter. Journal of Crop Science, 46: 735- 746. Gholdani, M. 2012. Effect of irrigation intervals on some morphophysiological traits of basil (Ocimum basilicum L.) ecotypes. Iranian Journal of Field Crops Research, 10(2):412-420 (In Persian with English Summary). Ghorbanli, M. and Niakan, M. 2006. The Effect of Drought Stress on Soluble Sugar, Total Protein, Proline, Phenolic Compound, Chlorophyll Content and rate Reductase Activity in Soybean (Glycine max L.cv.Gorgan3). Materials and Energy, 18 (56): 537-550 (In Persian with English Summary). Kochert, G. 1978. Carbohydrate determination by the phenol sulfuric acid method. In: Helebust, Journal of Agricultural Craig, J.S.(ed): Hand book of Physiological Method, 56-97, Cambridge University Press, Cambridge. Lowry, O.H., Rosebrough, N.J. and Rand, R.J. 1951. Protein measurement with the folin- phenol reagent. Journal of Biological Chemistry, 193: 265-273. Li, Q., Wang-Li, L., Jayanty, R.K.M. and Shah, S.B. 2013. Organic and elemental carbon in atmospheric fine particulate matter in an animal agriculture intensive area in north carolina: Estimation of secondary organic carbon concentrations. Open Journal of Air Pollution, 2: 7-18. Mahajan, S. and Tuteja, N. 2005. Cold, salinity and drought stresses: An overview. Archives in Biochemistry and Biophysics, 444, 139-158. Marsafari, M., Asoudar, M.A. and Kordi, S. 2011. Aerosol resources and adjust their harm effects. Second national conference on critical management. Tehran. Iran. doi: http://www.civilica.com/Paper-NCEVSLL02-NCEVSLL02_388 (In Persian). Martin, M.F., Miceli, J. Morgan, A., Scalet, M. and Zerbi, G. 1993. Synthesis of osmotically active substrates in winter wheat leaves as related to drought resistance of different genotypes. Journal of Agricultural Crop Science, 171: 176-184. Meywerk, J. and Ramanathan, V. 2002. Influence of Anthropogenic Aerosols on the Total and Spectral Irradiance on the Sea Surface During INDOEX, J. Geophys. Res. Atmospheres, 107, D19, 8018, doi: 10.1029/2000JD000022,2002.17-1to17-14,1999. Nabizade, M., Tayeb, S.N. and Mani, M. 2011. Effect of irrigation on the yield of mungbean cultivars. Journal of American Science, 7(7):86-90. Naresh, R.K., Purushottam, S.P., Dwivedi, A. and Kumar, V. 2013. Effects of water stress on physiological processes and yield attributes of different mungbean (L.) varieties. African Journal of Biochemistry Researc, 7(5): 55-62. Natali, S., Bignami, C. and Fusari, A. 1991. Water consumption, photosynthesis, transpiration and leaf water potential in Olea europaea L. cv. “Frantoio” at different levels of available water. Agricotura Mediterranea, 121(3): 205-212. Nourian, M.H., Zabihi, H. R. and Oveisi, M. 2015. Evalution of biofertilizers and B foliar application effects on grain yield in drought stress condition. Soil researches (Soil and Water Scince, 29(4): 179-186 (In Persian with English Summary). Pandey, R.K., Herrera, W. A.T., Villegas, A.W. and Penletion, J.W. 1984. Drought response of grain legumes under irrigation gradient. III. Plant growth. 76: 557-560. Sanchez, F.J., Manzanares, M., De Andres, E.F., Tenorio, J.L. and Ayerbe, L. 1998. Turgor maintenance, osmotic adjustment and soluble sugar and prolin Baccumulation in 49 pea cultivars in response to water stress. Field Crop Research, 59: 225-235. Shomaili, M. 2012. Aerosols, Resources and their effects on crops. A case study: sugarcane farms in south Khoozestan province. Second national conference on critical management. Tehran. Iran. doi: http://www.civilica.com/Paper-NCEVSLL02-NCEVSLL02_388 (In Persian). Thomas, M.J., Robertson, S. and Fukai, M.B. 2003. The effect of timing and severity of water deficit on growth development, yield accumulation and nitrogen fixation of mungbean. Crop Research, 86 (1): 67-80. Verbruggen, N. and Hermans, C. 2008. Proline accumulation in plants: a review. Amino Acids. 35(4): 753-759. Wakrim, R.S., Wahbi, H., Tahi, B. and Aganchich, R. 2005. Comparative effects of partial root drying and regulated deficit errigation (RDI) on water relations and water use efficiency in common bean (Phaseolus vulgaris L.). Agriculture Ecosystem and Environment, 106: 275-287. Wang, W., Vinocur, B., Shoseyov, O. and Altman, A. 2001. Biotechnology of plant osmotic stress tolerance: physiological and molecular considerations. Acta Horticulturae, 560:285-292. Zadeh-Bagheri, M., Javanmardi, Sh., Alozadeh, O. and Kamelmanesh, M.M. 2014. Effects of drought on grain yield and some physiological characteristics of red bean genotypes. Journal of Plant Ecophysiology, 6(18): 2-11 (In Persian with English Summary).
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