Evaluation of Drought Stress Tolerance in Advanced Lines Durum Wheat Using the Selection Index of Ideal Genotype (SIIG)
Subject Areas : Journal of Crop EcophysiologySahar Tadili 1 , Ali Asghari 2 , Rahmatollah Karimizadeh 3 , Omid Sofalian 4 , Hamidreza Mohammaddoust Chamanabad 5
1 - MS.c. Student, Plant Breeding, University of Mohaghegh Ardabili, Ardabil, Iran
2 - Associate Professor, Department of Agronomy and Plant Breeding, University of Mohaghegh Ardabili, Ardabil, Iran
3 - Assistant Professors, Dryland Agricultural Research Institute,Agricultural Research, Education and Extension Organization (AREEO), Ghachsaran, Iran
4 - Professor, Department of Agronomy and Plant Breeding, University of Mohaghegh Ardabili, Ardabil, Iran
5 - Professor, Department of Agronomy and Plant Breeding, University of Mohaghegh Ardabili, Ardabil, Iran
Keywords: durum wheat, drought, SIIG index, Ti index, Tolerant line,
Abstract :
Drought tolerance of 18 advanced lines durum wheat were evaluated in a randomized complete block design with four replications under dryland and complementary irrigation conditions in GachsaranAgriculturalResearchCenter at 2016-2017. In this study, traits like days to spike formation, days to maturity, plant height, peduncle length, spike length, 1000 seed weight, seed yield, spike number, spike number per m2, canopy temperature reduction of two stages of spike and seed filling, rate of greenness at two stages of spike and grain filling, were measured. Analysis of variance showed that there were significant differences among lines under study for days to spike formation, plant height, peduncle length, spike length, 1000 seed weight, seed yield, crop score, number of seeds per spike, temperature reductions of canopy at two spike stages seed and greenery content in two stages of spike and grain filling were significantly different. Mean comparisons showed that lines 4, 9, 13, 15, 16 and 17 were better than other lines in most traits. Evaluation of sensitive and tolerant lines according to tolerance index (Ti) showed that lines 1, 2, 4, 6, 9, 15 and 17, had high Ti index in most traits, were tolerant. Selection for superior lines, based on SIIG and selection of ideal genotype (SIIG) index, were performed. The results of variance analysis of traits based on Ti index showed that difference among lines in terms of 1000 seed weight, reduction of canopy temperature at grain filling stage, seed yield, grain filling period, chlorophyll content at both clustering and grain filling stage, days to reach and number of days to clustering were significant at 1% probability level. Lines 4, 5, 9 and 15 were the highest values of this index and were suitable for growing under dryland conditions. Lines 7, 8, 10 and 14 having lowest value of the SIIG index were sensitive to rainfed condition. The results of this ranking are similar to the results of cluster decomposition based on Ti index.
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_||_· Anonymous. 2017. World grain statistics. International Grains Council. [on-line] Available at https:// www.igc.int/en/subscriptions/subscription.aspx.
· Anonymous. 2018. Grain market report. International Grains Council. GMR483-23. November 2017. [on-lin] Available at https://www.igc.int/downloads/gmrsummary /gmrsumme.
· Balota, M., W.A. Payne, S.R. Evett, and M.D. Lazar. 2007. Canopy temperature depression sampling to assess grain yield and genotypic differentiation in winter wheat. Crop Science. 47: 1518–1529.
· Biglouie, M.H., M.H. Assimi, and A. Akbarzadeh. 2010. Effect of water stress at different stages on quantity and quality traits of Virginia (flue cured) tobacco type. Plant Soil Environment. 2: 67-75.
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· Bonwell, E.S. 2008. Determination of endosperm protein secondary structure in hard wheat breeding lines using synchrotron infrared microspectroscopy and revelation of secondary structure changes in protein films with thermal processing. MS.c. Thesis, Dpartment of Grain Science and Industry, College of Agriculture, Kansas Stat University. USA.
· Dastfal, M., V. Barati, Y. Emam, H. Haghighatnia, and M. RamezanPour. 2012. Evaluation of grain yield and yield component in wheat genotypes under late drought stress in Darab zone. Seed and Plant Production Journal. 27: 195-217. (In Persian).
· Gharbi, A., V. Rashidi, A.R. Tarinejad, and S. Chalabi Yani. 2014. Evaluation of durum wheat lines tolerance to salinity and drought stress under greenhouse conditions. Journal of Crop Ecophysiology. 7(4): 393-410.
· Hwang, C.L., and K.P. Yoon. 1981. Multiple attribute decision making methods and applications. Springer, New York, 350 pp.
· Lesk, C., P. Rowhani, and N. Ramankutty. 2016. Influence of extreme weather disasters on global crop production. Nature. 529: 84–87.
· Mitra, J. 2001. Genetics and genetic improvement of drought resistance in crop plants. Current Science. 80: 758-763.
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· Ramzi, E., A. Asghari, S. Khomari, and H. Mohammad doust Chamanabad. 2018. Investigation of durum wheat (Triticum turgidum L. subsp. durum Desf) lines for tolerance to aluminum stress condition. Journal of Crop Breeding. 10: 63-72. (In Persian).
· Reynolds, M., F. Dreccer, and R. Trethowan. 2007. Drought-adaptive traits derived from wheat wild relatives and landraces. Journal of Experimental Botany. 58: 177–186.
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· Soleimani fard, A., and N. Naseri. 2013. Genetic diversity of durum wheat Lines from agronomic traits under dryland conditions. Jornal of Crop Ecophysiology. 28: 469-478. (In Persian).
· Stone, L.R., and A.J. Schlegel. 2006. Yield water supply relationships of grain sorghum and winter wheat. Agronomy Journal. 98: 1359-1366.
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· Zali, H., O. Sofalian, T. Hasanloo, A. Asghari, and M. Zeinalabedini. 2016. Appropriate strategies for selection of drought tolerant genotypes in canola. Journal of Crop Breeding. 20: 77- 90. (In Persian).
Zali, H., O. Sofalian, T. Hasanloo, A. Asghari, and S.M. Hoseini. 2015. Appraising of drought tolerance relying on stability analysis indices in canola genotypes simultaneously, using selection index of ideal genotype (SIIG) technique, Introduction of new method. Biological Forum. 7: 703-711. (In Persian).
