Linkage Disequilibrium with Linkage Analysis of Multiline Crosses Reveals Different Multiallelic QTL for Hybrid Performance in the Flint and Dent Heterotic Groups of Maize

Giraud, Héloïse; Lehermeier, Christina; Bauer, Eva; Falque, Matthieu; Segura, Vincent; Bauland, Cyril; Camisan, Christian; Campo, Laura; Meyer, Nina; Ranc, Nicolas; Schipprack, Wolfgang; Flament, Pascal; Melchinger, Albrecht E.; Menz, Monica A.; Moreno-González, J.; Ouzunova, Milena; Charcosset, Alain; Schön, Chris‐Carolin; Moreau, Laurence

doi:10.1534/genetics.114.169367

Cited by 83 publications

(147 citation statements)

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“…To map QTL in the NAM population (NAM2214), we used a JL model (Buckler et al 2009; Tian et al 2011) and a multi-locus linear regression model (MLLM) (Giraud et al 2014) adapted from Segura et al (2012). The model can be denoted as:

y = F α + \underset{c}{140%true \sum} M_{c} β_{c} + e,

where y is the vector ( N × 1) of adjusted phenotypic means for N RILs; F is a ( N × P ) matrix of 0 and 1 that linked each RIL to the family it belonged, P being the number of families, α is the vector ( P × 1) of family means; M c is the vector of genotypes of cofactor c that entered the model and β c its effect; and e is the vector of residual effects.…”

Section: Methodsmentioning

confidence: 99%

Increased Power To Dissect Adaptive Traits in Global Sorghum Diversity Using a Nested Association Mapping Population

et al. 2017

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y = F α + \underset{c}{140%true \sum} M_{c} β_{c} + e,

Section: Methodsmentioning

confidence: 99%

Increased Power To Dissect Adaptive Traits in Global Sorghum Diversity Using a Nested Association Mapping Population

et al. 2017

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“…2013 or Giraud et al. 2014). These studies restricted the model to a single type of QTL effect, keeping the same type of incidence matrix across all loci.…”

Section: Methodsmentioning

confidence: 99%

How do the type of QTL effect and the form of the residual term influence QTL detection in multi-parent populations? A case study in the maize EU-NAM population

et al. 2017

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Key message In the QTL analysis of multi-parent populations, the inclusion of QTLs with various types of effects can lead to a better description of the phenotypic variation and increased power. AbstractFor the type of QTL effect in QTL models for multi-parent populations (MPPs), various options exist to define them with respect to their origin. They can be modelled as referring to close parental lines or to further away ancestral founder lines. QTL models for MPPs can also be characterized by the homo- or heterogeneity of variance for polygenic effects. The most suitable model for the origin of the QTL effect and the homo- or heterogeneity of polygenic effects may be a function of the genetic distance distribution between the parents of MPPs. We investigated the statistical properties of various QTL detection models for MPPs taking into account the genetic distances between the parents of the MPP. We evaluated models with different assumptions about the QTL effect and the form of the residual term using cross validation. For the EU-NAM data, we showed that it can be useful to mix in the same model QTLs with different types of effects (parental, ancestral, or bi-allelic). The benefit of using cross-specific residual terms to handle the heterogeneity of variance was less obvious for this particular data set.Electronic supplementary materialThe online version of this article (doi:10.1007/s00122-017-2923-3) contains supplementary material, which is available to authorized users.

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“…The protection against false positives was ensured by backward elimination of candidate QTLs from a multilocus ME mixed model. Physical positions of significant SNPs were projected on the consensus genetic map for Dent genetic material (Giraud et al, 2014). Candidate SNPs distant less than 0.1 cМ were considered as belonging to a common QTL, described via the most significant SNP in the QTL and the interval between all SNPs belonging to the QTL.…”

Section: Gwas Analysismentioning

confidence: 99%

Genome-wide analysis of yield in Europe: allelic effects as functions of drought and heat scenarios

et al. 2016

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Assessing the genetic variability of plant performance under heat and drought scenarios can contribute to reduce the negative effects of climate change. We propose here an approach that consisted of (1) clustering time courses of environmental variables simulated by a crop model in current (35 years 3 55 sites) and future conditions into six scenarios of temperature and water deficit as experienced by maize (Zea mays L.) plants; (2) performing 29 field experiments in contrasting conditions across Europe with 244 maize hybrids; (3) assigning individual experiments to scenarios based on environmental conditions as measured in each field experiment; frequencies of temperature scenarios in our experiments corresponded to future heat scenarios (+5°C); (4) analyzing the genetic variation of plant performance for each environmental scenario. Forty-eight quantitative trait loci (QTLs) of yield were identified by association genetics using a multi-environment multi-locus model. Eight and twelve QTLs were associated to tolerances to heat and drought stresses because they were specific to hot and dry scenarios, respectively, with low or even negative allelic effects in favorable scenarios. Twenty-four QTLs improved yield in favorable conditions but showed nonsignificant effects under stress; they were therefore associated with higher sensitivity. Our approach showed a pattern of QTL effects expressed as functions of environmental variables and scenarios, allowing us to suggest hypotheses for mechanisms and candidate genes underlying each QTL. It can be used for assessing the performance of genotypes and the contribution of genomic regions under current and future stress situations and to accelerate breeding for drought-prone environments.With climate changes, crops will be subjected to more frequent episodes of drought and high temperature that may threaten food security (IPCC, 2014). Reducing the impacts of these effects is an urgent priority that (not exclusively) involves the genetic progress of plant performance under heat and drought stresses (Tester and Langridge, 2010;Lobell et al., 2011). Because hundreds of new genotypes of most cereals are commercialized every year, a generic approach is needed to avoid an endless series of experiments assessing the performances of the newly released genotypes. A systematic exploration of the natural genetic diversity used in breeding can provide information usable for large groups of genotypes. This entails the identification, among the thousands of accessions existing in gene banks, of allelic variants exhibiting specific adaptation traits by addressing three questions: (1) Is there a genetic variability for yield and related traits in dry and hot environments? (2) Can this genetic variability be dissected into the effect of genomic regions (quantitative trait loci, QTLs), and (3) have these genomic

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Linkage Disequilibrium with Linkage Analysis of Multiline Crosses Reveals Different Multiallelic QTL for Hybrid Performance in the Flint and Dent Heterotic Groups of Maize

Cited by 83 publications

References 56 publications

Increased Power To Dissect Adaptive Traits in Global Sorghum Diversity Using a Nested Association Mapping Population

Increased Power To Dissect Adaptive Traits in Global Sorghum Diversity Using a Nested Association Mapping Population

How do the type of QTL effect and the form of the residual term influence QTL detection in multi-parent populations? A case study in the maize EU-NAM population

Genome-wide analysis of yield in Europe: allelic effects as functions of drought and heat scenarios

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