Literature DB >> 22057118

Mapping QTL controlling maize deep-seeding tolerance-related traits and confirmation of a major QTL for mesocotyl length.

Hongwei Zhang1, Pan Ma, Zhengnan Zhao, Guangwu Zhao, Baohua Tian, Jianhua Wang, Guoying Wang.   

Abstract

Deep-seeding tolerant seeds can emerge from deep soil where the moisture is suitable for seed germination. Breeding deep-seeding tolerant cultivars is becoming increasingly important in arid and semi-arid regions. To dissect the quantitative trait loci (QTL) controlling deep-seeding tolerance traits, we selected a tolerant maize inbred line 3681-4 and crossed it with the elite inbred line-X178 to generate an F(2) population and the derivative F(2:3) families. A molecular linkage map composed of 179 molecular markers was constructed, and 25 QTL were detected including 10 QTL for sowing at 10 cm depth and 15 QTL for sowing at 20 cm depth. The QTL analysis results confirmed that deep-seeding tolerance was mainly caused by mesocotyl elongation and also revealed considerable overlap among QTL for different traits. To confirm a major QTL on chromosome 10 for mesocotyl length measured at 20 cm depth, we selected and self-pollinated a BC(3)F(2) plant that was heterozygous at the markers around the target QTL and homozygous at other QTL to generate a BC(3)F(3) population. We found that this QTL explained more phenotypic variance in the BC(3)F(3) population than that in the F(2) population, which laid the foundation for fine mapping and NIL (near-isogenic line) construction.

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Year:  2011        PMID: 22057118     DOI: 10.1007/s00122-011-1700-y

Source DB:  PubMed          Journal:  Theor Appl Genet        ISSN: 0040-5752            Impact factor:   5.699


  17 in total

1.  LIGHT AND THE ELONGATION OF THE MESOCOTYL IN CORN.

Authors:  L H Flint
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2.  Genetic dissection of intermated recombinant inbred lines using a new genetic map of maize.

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3.  Inclusive composite interval mapping (ICIM) for digenic epistasis of quantitative traits in biparental populations.

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4.  Conserved noncoding genomic sequences associated with a flowering-time quantitative trait locus in maize.

Authors:  Silvio Salvi; Giorgio Sponza; Michele Morgante; Dwight Tomes; Xiaomu Niu; Kevin A Fengler; Robert Meeley; Evgueni V Ananiev; Sergei Svitashev; Edward Bruggemann; Bailin Li; Christine F Hainey; Slobodanka Radovic; Giusi Zaina; J-Antoni Rafalski; Scott V Tingey; Guo-Hua Miao; Ronald L Phillips; Roberto Tuberosa
Journal:  Proc Natl Acad Sci U S A       Date:  2007-06-26       Impact factor: 11.205

5.  Identification of quantitative trait loci for cold response of seedling vigor traits in rice.

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6.  GGT 2.0: versatile software for visualization and analysis of genetic data.

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7.  The location of genes governing long first internode of corn.

Authors:  A F Troyer
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8.  Comparison of QTL controlling seedling vigour under different temperature conditions using recombinant inbred lines in rice (Oryza sativa).

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9.  QTL controlling root and shoot traits of maize seedlings under cold stress.

Authors:  A Hund; Y Fracheboud; A Soldati; E Frascaroli; S Salvi; P Stamp
Journal:  Theor Appl Genet       Date:  2004-06-04       Impact factor: 5.699

10.  A QTL on chromosome 6A in bread wheat (Triticum aestivum) is associated with longer coleoptiles, greater seedling vigour and final plant height.

Authors:  W Spielmeyer; J Hyles; P Joaquim; F Azanza; D Bonnett; M E Ellis; C Moore; R A Richards
Journal:  Theor Appl Genet       Date:  2007-04-11       Impact factor: 5.574
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  11 in total

1.  24-epibrassinolide confers tolerance against deep-seeding stress in Zea mays L. coleoptile development by phytohormones signaling transduction and their interaction network.

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Journal:  Plant Signal Behav       Date:  2021-08-23

2.  Mapping and characterization of quantitative trait loci for mesocotyl elongation in rice (Oryza sativa L.).

Authors:  Hyun-Sook Lee; Kazuhiro Sasaki; Atsushi Higashitani; Sang-Nag Ahn; Tadashi Sato
Journal:  Rice (N Y)       Date:  2012-06-26       Impact factor: 4.783

3.  Quantitative Trait Locus Analysis for Deep-Sowing Germination Ability in the Maize IBM Syn10 DH Population.

Authors:  Hongjun Liu; Lin Zhang; Jiechen Wang; Changsheng Li; Xing Zeng; Shupeng Xie; Yongzhong Zhang; Sisi Liu; Songlin Hu; Jianhua Wang; Michael Lee; Thomas Lübberstedt; Guangwu Zhao
Journal:  Front Plant Sci       Date:  2017-05-22       Impact factor: 5.753

4.  Natural selection of a GSK3 determines rice mesocotyl domestication by coordinating strigolactone and brassinosteroid signaling.

Authors:  Shiyong Sun; Tao Wang; Linlin Wang; Xiaoming Li; Yancui Jia; Chang Liu; Xuehui Huang; Weibo Xie; Xuelu Wang
Journal:  Nat Commun       Date:  2018-06-28       Impact factor: 14.919

5.  2-DE-based proteomic analysis of protein changes associated with etiolated mesocotyl growth in Zea mays.

Authors:  Liangjie Niu; Zhaokun Wu; Hui Liu; Xiaolin Wu; Wei Wang
Journal:  BMC Genomics       Date:  2019-10-22       Impact factor: 3.969

6.  Transcriptome Analysis Revealed the Key Genes and Pathways Involved in Seed Germination of Maize Tolerant to Deep-Sowing.

Authors:  Yang Wang; Jinna He; Haotian Ye; Mingquan Ding; Feiwang Xu; Rong Wu; Fucheng Zhao; Guangwu Zhao
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7.  Transcriptomic and Metabolic Profiling Reveals a Lignin Metabolism Network Involved in Mesocotyl Elongation during Maize Seed Germination.

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8.  The Combination of Conventional QTL Analysis, Bulked-Segregant Analysis, and RNA-Sequencing Provide New Genetic Insights into Maize Mesocotyl Elongation under Multiple Deep-Seeding Environments.

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9.  Genome-wide Association Study (GWAS) of mesocotyl elongation based on re-sequencing approach in rice.

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Review 10.  Primary Root and Mesocotyl Elongation in Maize Seedlings: Two Organs with Antagonistic Growth below the Soil Surface.

Authors:  Mery Nair Sáenz Rodríguez; Gladys Iliana Cassab
Journal:  Plants (Basel)       Date:  2021-06-23
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