Characterization of maize inbred lines for drought and heat tolerance

Chen, J.; Xu, Wenwei; Velten, Jeff; Xin, Zhanguo; Stout, John E.

doi:10.2489/jswc.67.5.354

Cited by 147 publications

(132 citation statements)

References 33 publications

(49 reference statements)

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“…Potential variations exist in maize genetic stocks for drought-tolerance. Identification and characterization of genotypes for the said purpose is the primary step in developing droughttolerant cultivars (Chen et al, 2012;Naveed et al, 2016a). This requires an understanding of gene action controlling various seedling and morphological plant traits.…”

Section: Studies At Physiological Plant Maturitymentioning

confidence: 99%

Genetics of drought tolerance at seedling and maturity stages in Zea mays L.

Khan

Ahsan

Naveed

et al. 2016

Span. j. agric. res.

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Shortage of irrigation water at critical growth stages of maize is limiting its production worldwide. Breeding drought-tolerant cultivars is one possible solution while identification of potential genotypes is crucial for genetic improvement. To assess genetic variation for seedling-stage drought tolerance, we tested 40 inbred lines in a completely randomized design under glasshouse conditions. From these, two contrasting inbred lines were used to develop six basic generations (P1, P2, F1, F2, BC1F1, BC2F2). These populations were then evaluated in a triplicated factorial randomized complete block design under non-stressed and drought-stressed conditions. For statistical analyses, a nested block design was employed to ignore the replication effects. Significant differences (p≤0.01) were recorded among the genotypes for investigated seedling-traits. Absolute values of fresh root length, fresh root weight, and dry root weight lead to select two genotypes, one tolerant (WFTMS) and one susceptible (Q66). Estimates of heritability, genetic advance, and genotypic correlation coefficients were higher and significant for most of the seedling-traits. Generation variance analysis revealed additive gene action. Narrow-sense heritability [F2 ≥ 65; F∞ ≥ 79] revealed the same results. Generation mean analysis signified additive genetic effects in the inheritance of cob girth, non-additive for plant height, grains per ear row and grain yield per plant, and environmental for ear leaf area, cob length, grain rows per ear, biomass per plant, and 100-grain weight under drought-stressed conditions. For conferring drought-tolerance in maize, breeders can adopt the recombinant breeding strategy to pyramid the desirable genes.

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Section: Studies At Physiological Plant Maturitymentioning

confidence: 99%

Genetics of drought tolerance at seedling and maturity stages in Zea mays L.

Khan

Ahsan

Naveed

et al. 2016

Span. j. agric. res.

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“…In this respect, greater reductions have been observed when water deficit occurs between the end of the vegetative stages up to reproductive stage 3 (R3), which may cause reductions of up to 100% (Chen et al, 2012). In this study, in all years, water restriction was imposed at 45 days after sowing, coinciding with the critical periods of water deficit for the maize plant, which allowed evaluation and discrimination of the hybrids.…”

Section: Resultsmentioning

confidence: 99%

Maize hybrid stability in environments under water restriction using mixed models and factor analysis

et al. 2017

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ABSTRACT. In several crops, the water deficit is perhaps the main limiting factor in the search for high yields. The objective of this study was to evaluate the phenotypic stability of maize hybrids in environments with and without water restriction using the analytical factor (AF) approach. We evaluated 171 maize hybrids in 14 environments, divided into environments with (A1, A2, A3, A4, A5, A6, and A7) and without (A8, A9, A10, A11, A12, A13, and A14) water restriction, over a period of 7 years. Each year, 36 hybrids were evaluated. A square lattice design (6 x 6) was used, with common treatments between years. The characteristics of grain yield (GY), male flowering (MF) and female flowering (FF), plant height (PH), and ear height (EH) were evaluated. Phenotypic adaptability and stability of the hybrids were also verified. Hybrids G66, G99, G86, and G26 were the most stable and showed potential for use in environments with and without water restriction. The AF models showed to be useful for evaluating hybrids over many years, allowing selection of better hybrids with adaptability, specific and general stability, and correlation of hybrids with their production components, in addition to allowing identification of mega-environments that permit stability in the response of the adapted hybrids.

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“…DNA was extracted from young leaves using the standard cetyltrimethylammonium bromide (CTAB) method [19]. The concentrations of the DNA samples were determined with a spectrophotometer, and the DNA samples were diluted to 50 ng/μl for analysis using SSR markers.…”

Section: Dna Extraction and Ssr Analysismentioning

confidence: 99%