Literature DB >> 17712541

Genetic dissection of grain yield in bread wheat. II. QTL-by-environment interaction.

H Kuchel1, K Williams, P Langridge, H A Eagles, S P Jefferies.   

Abstract

The grain yield of wheat is influenced by genotype, environment and genotype-by-environment interaction. A mapping population consisting of 182 doubled haploid progeny derived from a cross between the southern Australian varieties 'Trident' and 'Molineux', was used to characterise the interaction of previously mapped grain yield quantitative trait locus (QTL) with specific environmental covariables. Environments (17) used for grain yield assessment were characterised for latitude, rainfall, various temperature-based variables and stripe rust infection severity. The number of days in the growing season in which the maximum temperature exceeded 30 degrees C was identified as the variable with the largest effect on site mean grain yield. However, the greatest QTL-by-environmental covariable interactions were observed with the severity of stripe rust infection. The rust resistance allele at the Lr37/Sr38/Yr17 locus had the greatest positive effect on grain yield when an environment experienced a combination of high-stripe rust infection and cool days. The grain yield QTL, QGyld.agt-4D, showed a very similar QTL-by-environment covariable interaction pattern to the Lr37/Sr38/Yr17 locus, suggesting a possible role in rust resistance or tolerance. Another putative grain yield per se QTL, QGyld.agt-1B, displayed interactions with the quantity of winter and spring rainfall, the number of days in which the maximum temperature exceeded 30 degrees C, and the number of days with a minimum temperature below 10 degrees C. However, no cross-over interaction effect was observed for this locus, and the 'Molineux' allele remained associated with higher grain yield in response to all environmental covariables. The results presented here confirm that QGyld.agt-1B may be a prime candidate for marker-assisted selection for improved grain yield and wide adaptation in wheat. The benefit of analysing the interaction of QTL and environmental covariables, such as employed here, is discussed.

Entities:  

Mesh:

Year:  2007        PMID: 17712541     DOI: 10.1007/s00122-007-0628-8

Source DB:  PubMed          Journal:  Theor Appl Genet        ISSN: 0040-5752            Impact factor:   5.574


  14 in total

1.  Interpreting genotype × environment interaction in tropical maize using linked molecular markers and environmental covariables.

Authors:  J Crossa; M Vargas; F A van Eeuwijk; C Jiang; G O Edmeades; D Hoisington
Journal:  Theor Appl Genet       Date:  1999-08       Impact factor: 5.699

2.  Mapping quantitative trait loci controlling agronomic traits in the spring wheat cross RL4452x'AC Domain'.

Authors:  C A McCartney; D J Somers; D G Humphreys; O Lukow; N Ames; J Noll; S Cloutier; B D McCallum
Journal:  Genome       Date:  2005-10       Impact factor: 2.166

3.  A simple regression method for mapping quantitative trait loci in line crosses using flanking markers.

Authors:  C S Haley; S A Knott
Journal:  Heredity (Edinb)       Date:  1992-10       Impact factor: 3.821

4.  Quantitative trait loci for yield and related traits in the wheat population Ning7840 x Clark.

Authors:  F Marza; G-H Bai; B F Carver; W-C Zhou
Journal:  Theor Appl Genet       Date:  2005-12-21       Impact factor: 5.699

5.  Genetic analysis of grain protein-content, grain yield and thousand-kernel weight in bread wheat.

Authors:  C Groos; N Robert; E Bervas; G Charmet
Journal:  Theor Appl Genet       Date:  2002-10-03       Impact factor: 5.699

6.  A mixed-model approach to mapping quantitative trait loci in barley on the basis of multiple environment data.

Authors:  H P Piepho
Journal:  Genetics       Date:  2000-12       Impact factor: 4.562

7.  Mapping of quantitative trait loci determining agronomic important characters in hexaploid wheat ( Triticum aestivum L.).

Authors:  A. Börner; E. Schumann; A. Fürste; H. Cöster; B. Leithold; S. Röder; E. Weber
Journal:  Theor Appl Genet       Date:  2002-06-21       Impact factor: 5.699

8.  "Perfect" markers for the Rht-B1b and Rht-D1b dwarfing genes in wheat.

Authors:  H. Ellis; W. Spielmeyer; R. Gale; J. Rebetzke; A. Richards
Journal:  Theor Appl Genet       Date:  2002-09-13       Impact factor: 5.699

9.  Advanced backcross QTL analysis in progenies derived from a cross between a German elite winter wheat variety and a synthetic wheat (Triticum aestivum L.).

Authors:  X Q Huang; H Kempf; M W Ganal; M S Röder
Journal:  Theor Appl Genet       Date:  2004-09       Impact factor: 5.699

10.  Mapping of a novel QTL for resistance to cereal cyst nematode in wheat.

Authors:  K J Williams; K L Willsmore; S Olson; M Matic; H Kuchel
Journal:  Theor Appl Genet       Date:  2006-03-15       Impact factor: 5.699
View more
  17 in total

1.  Using probe genotypes to dissect QTL × environment interactions for grain yield components in winter wheat.

Authors:  Bing Song Zheng; Jacques Le Gouis; Martine Leflon; Wen Ying Rong; Anne Laperche; Maryse Brancourt-Hulmel
Journal:  Theor Appl Genet       Date:  2010-08-10       Impact factor: 5.699

2.  Population structure in a wheat core collection and genomic loci associated with yield under contrasting environments.

Authors:  Miroslav Zorić; Dejan Dodig; Borislav Kobiljski; Steve Quarrie; Jeremy Barnes
Journal:  Genetica       Date:  2012-09-12       Impact factor: 1.082

3.  Quantifying Wheat Sensitivities to Environmental Constraints to Dissect Genotype × Environment Interactions in the Field.

Authors:  Boris Parent; Julien Bonneau; Lance Maphosa; Alex Kovalchuk; Peter Langridge; Delphine Fleury
Journal:  Plant Physiol       Date:  2017-05-25       Impact factor: 8.340

4.  Genomic regions associated with the nitrogen limitation response revealed in a global wheat core collection.

Authors:  Jacques Bordes; C Ravel; J P Jaubertie; B Duperrier; O Gardet; E Heumez; A L Pissavy; G Charmet; J Le Gouis; F Balfourier
Journal:  Theor Appl Genet       Date:  2012-11-29       Impact factor: 5.699

5.  Allelic response of yield component traits to resource availability in spring wheat.

Authors:  Brittney H Jones; Nancy K Blake; Hwa-Young Heo; John M Martin; Jessica A Torrion; Luther E Talbert
Journal:  Theor Appl Genet       Date:  2020-11-04       Impact factor: 5.699

6.  Genetic analysis of wheat (Triticum aestivum) adaptation to heat stress.

Authors:  Paul Telfer; James Edwards; Adam Norman; Dion Bennett; Alison Smith; Jason A Able; Haydn Kuchel
Journal:  Theor Appl Genet       Date:  2021-03-06       Impact factor: 5.699

7.  Expression of a rice soluble starch synthase gene in transgenic wheat improves the grain yield under heat stress conditions.

Authors:  Bin Tian; Shyamal K Talukder; Jianming Fu; Allan K Fritz; Harold N Trick
Journal:  In Vitro Cell Dev Biol Plant       Date:  2018-03-06       Impact factor: 2.252

Review 8.  The role of seasonal flowering responses in adaptation of grasses to temperate climates.

Authors:  Siri Fjellheim; Scott Boden; Ben Trevaskis
Journal:  Front Plant Sci       Date:  2014-08-29       Impact factor: 5.753

9.  Genetic basis of nitrogen use efficiency and yield stability across environments in winter rapeseed.

Authors:  Anne-Sophie Bouchet; Anne Laperche; Christine Bissuel-Belaygue; Cécile Baron; Jérôme Morice; Mathieu Rousseau-Gueutin; Jean-Eric Dheu; Pierre George; Xavier Pinochet; Thomas Foubert; Olivier Maes; Damien Dugué; Florent Guinot; Nathalie Nesi
Journal:  BMC Genet       Date:  2016-09-15       Impact factor: 2.797

10.  Identification of manganese efficiency candidate genes in winter barley (Hordeum vulgare) using genome wide association mapping.

Authors:  Florian Leplat; Pai Rosager Pedas; Søren Kjærsgaard Rasmussen; Søren Husted
Journal:  BMC Genomics       Date:  2016-10-04       Impact factor: 3.969
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.