Genomic prediction of seedling root length in maize (<i>Zea mays</i> L.)

Pace, Jordon; Yu, Xiaoqing; Lübberstedt, Thomas

doi:10.1111/tpj.12937

Cited by 35 publications

(30 citation statements)

References 51 publications

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“…With the advanced technology, such as liquid chromatography-mass spectrometry (LC-MS), it becomes routine to obtain high throughput and reproducible quantitative metabolomic data. Recently, there have been many researches on metabolomics in humans (Draisma et al 2015;Gieger et al 2008;Rhee et al 2013) as well as in plants, such as Arabidopsis thaliana (Lisec et al 2008;Meyer et al 2007;Steinfath et al 2010), maize (Pace et al 2015;Riedelsheimer et al 2012aRiedelsheimer et al , 2012bWen et al 2014) and rice (Chen et al 2014;Gong et al 2013;Matsuda et al 2015Matsuda et al , 2012Xu et al 2016).…”

Section: Introductionmentioning

confidence: 99%

Metabolome-wide association studies for agronomic traits of rice

Wei

Wang

et al. 2017

Heredity

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Identification of trait-associated metabolites will advance the knowledge and understanding of the biosynthetic and catabolic pathways that are relevant to the complex traits of interest. In the past, the association between metabolites (treated as quantitative traits) and genetic variants (e.g., SNPs) has been extensively studied using metabolomic quantitative trait locus (mQTL) mapping. Nevertheless, the research on the association between metabolites with agronomic traits has been inadequate. In practice, the regular approaches for QTL mapping analysis may be adopted for metabolites-phenotypes association analysis due to the similarity in data structure of these two types of researches. In the study, we compared four regular QTL mapping approaches, i.e., simple linear regression (LR), linear mixed model (LMM), Bayesian analysis with spike-slab priors (Bayes B) and least absolute shrinkage and selection operator (LASSO), by testing their performances on the analysis of metabolome-phenotype associations. Simulation studies showed that LASSO had the higher power and lower false positive rate than the other three methods. We investigated the associations of 839 metobolites with five agronomic traits in a collection of 533 rice varieties. The results implied that a total of 25 metabolites were significantly associated with five agronomic traits. Literature search and bioinformatics analysis indicated that the identified 25 metabolites are significantly involved in some growth and development processes potentially related to agronomic traits. We also explored the predictability of agronomic traits based on the 839 metabolites through cross-validation, which showed that metabolomic prediction was efficient and its application in plant breeding has been justified.

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Section: Introductionmentioning

confidence: 99%

Metabolome-wide association studies for agronomic traits of rice

Wei

Wang

et al. 2017

Heredity

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“…In earlier studies, mostly SL-GWAS methods were adopted to dissect complex traits, but only few SNPs for each trait have been identi ed due to its procedural limitations. GLM has an obvious shortcoming of high false positive rate due to the absence of kinship among materials as covariate [70]. In MLM, due to the setting of very high threshold, many smalleffect loci are missed [71].…”

Section: Signi Cance Of Gwas Using High-density Genotypingmentioning

confidence: 99%

Uncovering genomic regions controlling plant architectural traits in hexaploid wheat using GWAS

Wang¹,

Ali²,

Hu³

et al. 2020

Preprint

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Background: Wheat is a staple food crop worldwide. Plant height is a key factor in plant architecture as it plays a crucial role in lodging and thus affects yield and quality. Genome-wide studies are mostly applied in crop plants, due to its advanced genotyping technologies, identification of novel loci, and improved statistical approaches. Results: In this study, the population was genotyped by using Illumina iSelect 90K single nucleotide polymorphism (SNP) assay and finally 22,905 high-quality SNPs were used to perform a genome-wide association study (GWAS) for plant architectural traits employing four multi-locus GWAS (ML-GWAS) and three single-locus GWAS (SL-GWAS) models. As a result, 174 and 97 significant SNPs controlling plant architectural traits were detected by four ML-GWAS and three SL-GWAS methods, respectively. Among these SNP makers, 43 SNPs were commonly detected, including seven across multiple environments and thirty-six across multiple methods. Interestingly, five most stable SNPs (Kukri_c34553_89, RAC875_c8121_1490, wsnp_Ex_rep_c66315_64480362, Ku_c5191_340, and tplb0049a09_1302) consistently detected across multiple environments and methods, possibly played a role in modulating plant height and flag leaf length. When comparing ML-GWAS methods, pLARmEB was the most powerful and accountable for the detection of 49 significant SNPs that mostly contributed to plant height (36 SNPs). However, in SL-GWAS the FarmCPU model detected most of the significant SNPs. Moreover, a total of 152 candidate genes were found that are likely to be involved in plant growth and development which may provide insightful information related to plant architectural traits.Conclusion: Altogether, our results reveal 174 and 97 significant SNPs controlling plant architectural traits using four ML-GWAS and three SL-GWAS methods, respectively. The detection of the stable loci across multiple environments and methods, possibly play a role in modulating plant architectural traits in hexaploid wheat, and finally will contribute to the discovery of valuable SNP loci for marker-assisted selection (MAS) in wheat molecular breeding.

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“…The SeeD (Seeds of Discovery; http:// seedsofdiscovery.org) project has successfully characterized untapped variation in maize landraces and developed bridging germplasm with 75% or more elite and 25% or less landrace genome proportions, with the objective to provide early breeding lines carrying novel, landracederived genetic variation, and to breed for high-value characteristics such as nutritional quality, heat and drought tolerance, disease resistance, and tolerance to soil infertility. At the discovery phase, genotype data are used to discover the best landraces to initiate pre-bridging germplasm, based on genomic estimated breeding values (GEBVs) from genomic selection models, using well-characterized core collections as a training population, to maximize the number of beneficial alleles incorporated into pre-breeding materials [32,95,96]. Selected accessions are subsequently crossed with elite germplasm to create pre-breeding populations for future improvement of complex traits (Figure 1).…”

Section: Improvement Of Complex Traitsmentioning

confidence: 99%

Emerging Avenues for Utilization of Exotic Germplasm

Wang

Gardner

et al. 2017

Trends in Plant Science

Self Cite

108

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Breeders have been successful in increasing crop performance by exploiting genetic diversity over time. However, the reported annual yield increases are not sufficient in view of rapid human population growth and global environmental changes. Exotic germplasm possesses high levels of genetic diversity for valuable traits. However, only a small fraction of naturally occurring genetic diversity is utilized. Moreover, the yield gap between elite and exotic germplasm widens, which increases the effort needed to use exotic germplasm and to identify beneficial alleles and for their introgression. The advent of high-throughput genotyping and phenotyping technologies together with emerging biotechnologies provide new opportunities to explore exotic genetic variation. This review will summarize potential challenges for utilization of exotic germplasm and provide solutions.

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Genomic prediction of seedling root length in maize (Zea mays L.)

Cited by 35 publications

References 51 publications

Metabolome-wide association studies for agronomic traits of rice

Metabolome-wide association studies for agronomic traits of rice

Uncovering genomic regions controlling plant architectural traits in hexaploid wheat using GWAS

Emerging Avenues for Utilization of Exotic Germplasm

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