Genome-wide trait-trait dynamics correlation study dissects the gene regulation pattern in maize kernels

Xu, Xiuqin; Wang, Min; Li, Lianbo; Che, Ronglin; Pei, Laming; Li, Hui

doi:10.1186/s12870-017-1119-y

Cited by 5 publications

(4 citation statements)

References 47 publications

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“…Since the metabolic phenotype provides a link between gene sequence and visible phenotypes, metabolites can be used as markers for trait prediction relevant for crop genetic improvement [132,133]. Strategies known as association mapping studies including genome-wide association (GWAS) and linking studies have been developed for the identification of genes underlying quantitative trait loci (QTL) (a region of the genome associated with the control of a quantitative trait) [5,134,135]. GBS profiling combined with different omics technologies are currently applied to understand the genetic and biochemical regulation of metabolism linked to relevant agronomic and nutritional traits in corn.…”

Section: Metabolomic-assisted Molecular Breeding Strategies For the Imentioning

confidence: 99%

The Application of Metabolomics for the Study of Cereal Corn (Zea mays L.)

Ranilla

2020

Metabolites

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Corn (Zea mays L.) is an important cereal crop indigenous to the Americas, where its genetic biodiversity is still preserved, especially among native populations from Mesoamerica and South America. The use of metabolomics in corn has mainly focused on understanding the potential differences of corn metabolomes under different biotic and abiotic stresses or to evaluate the influence of genetic and environmental factors. The increase of diet-linked non-communicable diseases has increased the interest to optimize the content of bioactive secondary metabolites in current corn breeding programs to produce novel functional foods. This review provides perspectives on the role of metabolomics in the characterization of health-relevant metabolites in corn biodiversity and emphasizes the integration of metabolomics in breeding strategies targeting the enrichment of phenolic bioactive metabolites such as anthocyanins in corn kernels.

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Section: Metabolomic-assisted Molecular Breeding Strategies For the Imentioning

confidence: 99%

The Application of Metabolomics for the Study of Cereal Corn (Zea mays L.)

Ranilla

2020

Metabolites

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“…Among these, GWAS provides us an effective approach to explore the genetic mechanisms of phenotype formation between individuals ( Xiao et al., 2016 ; Liu and Yan, 2018 ). Since the release of the maize B73 reference genome, GWAS has been widely used in maize genetics research such as traditional agronomic traits such as maize plant height (PH) and ear height (EH) ( Li et al., 2016 ), kernel length ( Dai et al., 2018 ), and moisture content ( Zhou et al., 2018 ), typical traits such as microscopic phenotypes ( Mazaheri et al., 2019 ; Zhang et al., 2021 ), nutrient composition ( Li et al., 2013 ; Xu et al., 2017 ; Baseggio et al., 2019 ), metabolism ( Chen et al., 2016 ), physiological and biochemical properties ( Liu et al., 2016 ; Xu et al., 2018 ), and heavy metal enrichment ( Zhao et al., 2017 ), and stress resistance ( Zhang et al., 2016 ; Shi et al., 2018 ; Cooper et al., 2019 ; Wang et al., 2019 ; Xie et al., 2019 ). GWAS has contributed significantly to the elucidation of the genetic mechanism of phenotype formation in maize.…”

Section: Introductionmentioning

confidence: 99%

Characterization and genetic dissection of maize ear leaf midrib acquired by 3D digital technology

Wang

Zhao

et al. 2022

Front. Plant Sci.

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The spatial morphological structure of plant leaves is an important index to evaluate crop ideotype. In this study, we characterized the three-dimensional (3D) data of the ear leaf midrib of maize at the grain-filling stage using the 3D digitization technology and obtained the phenotypic values of 15 traits covering four different dimensions of the ear leaf midrib, of which 13 phenotypic traits were firstly proposed for featuring plant leaf spatial structure. Cluster analysis results showed that the 13 traits could be divided into four groups, Group I, -II, -III and -IV. Group I contains HorizontalLength, OutwardGrowthMeasure, LeafAngle and DeviationTip; Group II contains DeviationAngle, MaxCurvature and CurvaturePos; Group III contains LeafLength and ProjectionArea; Group IV contains TipTop, VerticalHeight, UpwardGrowthMeasure, and CurvatureRatio. To investigate the genetic basis of the ear leaf midrib curve, 13 traits with high repeatability were subjected to genome-wide association study (GWAS) analysis. A total of 828 significantly related SNPs were identified and 1365 candidate genes were annotated. Among these, 29 candidate genes with the highest significant and multi-method validation were regarded as the key findings. In addition, pathway enrichment analysis was performed on the candidate genes of traits to explore the potential genetic mechanism of leaf midrib curve phenotype formation. These results not only contribute to further understanding of maize leaf spatial structure traits but also provide new genetic loci for maize leaf spatial structure to improve the plant type of maize varieties.

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“…For a typical genomic study, a pathway‐based or a genome‐wide screening strategy can be implemented as presented in several studies to effectively identify potential dynamic correlation changes (Dawson and Kendziorski, 2012; Gunderson and Ho, 2014; Wang et al ., 2017; Yu, 2018; Kinzy et al ., 2019). Li's study and other studies since then have evidently established its biological validity and popularized it to be a useful tool for analyzing genomic data (Li, 2002; Li et al ., 2004; Ho et al ., 2007; Zhang et al ., 2007; Ho et al ., 2011; Wang et al ., 2013; Khayer et al ., 2017; Wang et al ., 2017; Xu et al ., 2017; Ai et al ., 2019; Kong and Yu, 2019; Wen et al ., 2020).…”

Section: Introductionmentioning

confidence: 99%

Modeling dynamic correlation in zero‐inflated bivariate count data with applications to single‐cell RNA sequencing data

Yang

2021

Biometrics

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Interactions between biological molecules in a cell are tightly coordinated and often highly dynamic. As a result of these varying signaling activities, changes in gene coexpression patterns could often be observed. The advancements in next‐generation sequencing technologies bring new statistical challenges for studying these dynamic changes of gene coexpression. In recent years, methods have been developed to examine genomic information from individual cells. Single‐cell RNA sequencing (scRNA‐seq) data are count‐based, and often exhibit characteristics such as overdispersion and zero inflation. To explore the dynamic dependence structure in scRNA‐seq data and other zero‐inflated count data, new approaches are needed. In this paper, we consider overdispersion and zero inflation in count outcomes and propose a ZEro‐inflated negative binomial dynamic COrrelation model (ZENCO). The observed count data are modeled as a mixture of two components: success amplifications and dropout events in ZENCO. A latent variable is incorporated into ZENCO to model the covariate‐dependent correlation structure. We conduct simulation studies to evaluate the performance of our proposed method and to compare it with existing approaches. We also illustrate the implementation of our proposed approach using scRNA‐seq data from a study of minimal residual disease in melanoma.

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Genome-wide trait-trait dynamics correlation study dissects the gene regulation pattern in maize kernels

Cited by 5 publications

References 47 publications

The Application of Metabolomics for the Study of Cereal Corn (Zea mays L.)

The Application of Metabolomics for the Study of Cereal Corn (Zea mays L.)

Characterization and genetic dissection of maize ear leaf midrib acquired by 3D digital technology

Modeling dynamic correlation in zero‐inflated bivariate count data with applications to single‐cell RNA sequencing data

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