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:: Volume 10, Issue 1 (2023) ::
pgr 2023, 10(1): 61-78 Back to browse issues page
Gene Actions Controlling of grain yield and its Contributing traits in Hybrid Maize under Water Deficiency
Mozhgan Shirinpour , Ehsan Atazadeh , Ahmad Bybordi , Saeid Aharizad , Ali Asghari * , Ashkboos Amini
Department of Production Engineering and Plant Genetics, University of Mohaghegh Ardabili, Ardabil, Iran , a_asghari@uma.ac.ir
Abstract:   (2663 Views)
Considering the importance of maize production and the impact of water deficit stress on reducing the yield of maize, estimating the genetic components and heritability of traits for determine the breeding method under water deficit stress is essential in breeding programs. The generations drived from a cross between two inbred lines of maize including B73 (maternal line) and MO17 (paternal line), SC704 (F1) as well as F2, BC1, BC2 and F3 generations in order to estimate the genetic effects and heritability of yield, yield components and morphological traits were studied. Seven maize generations using the generations mean analysis under the full irrigation, mild and severe water deficit conditions were evaluated. The experiment was conducted in the form of randomized complete block design with 20 replications per experimental unit during two cropping seasons (2018-2019) at the Agricultural Research Station of University of Tabriz. The results of two-year combined analysis of variance and mean comparisons under three different irrigation regimes showed that water deficit stress significantly reduced all of the studied traits (except root/shoot ratio). The generations mean analysis showed the high contribution of non-additive gene effects for the genetic control of grain yield, ear diameter, number of kernel row, ear weight (in full irrigation conditions), 100 grain weight, plant height, fresh shoot weight and biological yield traits. According to these results, selection in the advanced generations and the breeding method based on hybridization can be effective to improve these traits. Also, the significant contribution of additive gene effects in controlling the inheritance of ear length, ear weight (in both stress conditions) and root/shoot ratio traits indicated that selection in early segregating generations and inbred parents can be effective for breeding of these traits and taking advantage of additive variance. Hybrid SC704 and inbred MO17 compared with the inbred B73 showed the lowest variation percentage under the water deficit stress conditions, which indicated their high yield potential and stability in the stress conditions.
Keywords: Genetic analysis, Heritability, Maize generations, Water deficit stress
Full-Text [PDF 945 kb]   (966 Downloads)    
Type of Study: Research | Subject: Plant improvement
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Shirinpour M, Atazadeh E, Bybordi A, Aharizad S, Asghari A, Amini A. Gene Actions Controlling of grain yield and its Contributing traits in Hybrid Maize under Water Deficiency. pgr 2023; 10 (1) :61-78
URL: http://pgr.lu.ac.ir/article-1-284-en.html


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