Integrating Coexpression Networks with GWAS to Prioritize Causal Genes in Maize

Schaefer, Robert J.; Michno, Jean Michel; Jeffers, Joseph; Hoekenga, Owen A.; Dilkes, Brian P.; Baxter, Ivan; Myers, Chad L.

doi:10.1105/tpc.18.00299

Cited by 150 publications

(148 citation statements)

References 72 publications

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“…A key challenge remains in prioritizing GWAS signals and improving weak signals obtained from low frequency causative variants (Lee and Lee, 2018). The availability of whole-genome assemblies and corresponding protein-coding gene annotations, alongside additional layers of information, such as expression profiles from RNA-Seq experiments, now facilitate the integration of multiple data layers to improve GWAS results (Shim et al , 2017; Lee and Lee, 2018; Schaefer et al , 2018). Our example of the CmAPRR2 gene suggests that adding functional annotation prediction to GWAS SNPs and treating predicted genes as integral functional units could potentially be used as an informative layer that can boost the signal of causative weak associations.…”

Section: Discussionmentioning

confidence: 99%

Multi-allelic APRR2 Gene is Associated with Fruit Pigment Accumulation in Melon and Watermelon

Oren

Tzuri

Vexler

et al. 2019

Preprint

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23Color and pigment content are important aspects of fruit quality and consumer 24 acceptance of cucurbit crops. Here, we describe the independent mapping and cloning 25 of a common causative APRR2 gene regulating pigment accumulation in melon and 26 watermelon. We initially show that the APRR2 transcription factor is causative for the 27 qualitative difference between dark and light green rind in both crops. Further analyses 28 establish the link between sequence or expression level variations in the CmAPRR2 29 gene and pigments content in the rind and flesh of mature melon fruits. GWAS of young 30 fruit rind color in a panel composed of 177 diverse melon accessions did not result in 31 any significant association, leading to an earlier assumption that multiple genes are 32 involved in shaping the overall phenotypic variation at this trait. Through resequencing 33 of 25 representative accessions and allelism tests between light rind accessions, we 34 show that multiple independent SNPs in the CmAPRR2 gene are causative for the light 35 rind phenotype. The multi-haplotypic nature of this gene explain the lack of detection 36 power obtained through GBS-based GWAS and confirm the pivotal role of this gene in 37 shaping fruit color variation in melon. This study demonstrates the power of combining 38 bi-and multi-allelic designs with deep sequencing, to resolve lack of power due to high 39 haplotypic diversity and low allele frequencies. Due to its central role and broad effect 40 on pigment accumulation in fruits, the APRR2 gene is an attractive target for 41 carotenoids bio-fortification of cucurbit crops.42 43

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Section: Discussionmentioning

confidence: 99%

Multi-allelic APRR2 Gene is Associated with Fruit Pigment Accumulation in Melon and Watermelon

Oren

Tzuri

Vexler

et al. 2019

Preprint

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“…Therefore, the coexpression modules we observed were shaped by genetic perturbations, not tissue or developmental differences. While coexpression measured across multiple timepoints ('developmental networks') has been linked to functional relationships (Eisen et al 1998;Stuart et al 2003) , coexpression modules generated from genetically distinct individuals have different properties than those generated from different tissue types (Mähler et al 2017;Schaefer et al 2018) . In some cases, this difference is helpful: analyses combining GWAS and coexpression networks have the most power when using coexpression networks made from genetically distinct samples (Schaefer et al 2018) .…”

Section: Discussionmentioning

confidence: 99%

The evolutionary forces shaping cis and trans regulation of gene expression within a population of outcrossing plants

Josephs

Lee

Wood³

et al. 2019

Preprint

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AbstractUnderstanding the persistence of genetic variation within populations has long been a goal of evolutionary biology. One promising route towards achieving this goal is using population genetic approaches to describe how selection acts on the loci associated with trait variation. Gene expression provides a model trait for addressing the challenge of the maintenance of variation because it can be measured genome-wide without information about how gene expression affects traits. Previous work has shown that loci affecting the expression of nearby genes (local or cis-eQTLs) are under negative selection, but we lack a clear understanding of the selective forces acting on variants that affect the expression of genes in trans. Here, we identify loci that affect gene expression in trans using genomic and transcriptomic data from one population of the obligately outcrossing plant, Capsella grandiflora. The allele frequencies of trans-eQTLs are consistent with stronger negative selection acting on trans-eQTLs than cis-eQTLs, and even more strongly on trans-eQTLs associated with the expression of multiple genes. However, despite this general pattern, we still observe the presence of a trans-eQTL at intermediate frequency that affects the expression of a large number of genes in the same coexpression module. Overall, our work highlights the different selective pressures shaping variation in cis- and trans- gene regulation.

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“…These information may lead to increased efficiency of crop breeding, and accelerate the development of new cultivars for sustainable food production. gene co-expression network analysis is a powerful approach toward understanding the molecular processes controlling the phenotype (Kobayashi et al, 2016;Li et al, 2018;Schaefer et al, 2018), in which large expression data would be acquired from accessions under GWAS than public database to explain the GWAS phenotype. Recently, public databases for plant phenotype have been established (Arabidopsis: AraPheno [Seren et al, 2017], rice: RiceVarMap [Zhao et al, 2015], Maize: Panzea [Zhao et al, 2006]).…”

Section: Conclusion and Perspectivementioning

confidence: 99%

Genome-wide Association Studies of Agronomic Traits Consisting of Field- and Molecular-based Phenotypes

Nakano

Kobayashi

2020

RAS

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Genome-wide association study (GWAS) is a powerful approach to identify the genetic factors underlying the intraspecific phenotypic variations. Recent advances in DNA sequencing technology, including next generation sequencing has enabled us to easily genotype high density genome-wide SNPs. In addition, many accessions of various plant species have been widely collected in recent years. These genetic resources have made GWAS a markedly more popular approach for investigation of natural variations occurring in various traits using large populations. In addition to genotyping technology, advances in high-throughput phenotyping technologies have enabled us to acquire variation data on a large number of accessions characterized for various traits, including not only the field traits (e.g., yield and disease resistance) but also molecular traits (e.g., gene expression level and metabolite content). Thus, it is possible to expand the range of application of GWAS and enhance the detection power of genomic association. In this review, we summarize recent GWAS of various agronomic traits at field and molecular scale, following which we highlight the integration approach involving GWAS and high-throughput phenotyping technologies including transcriptome, ionome and metabolome.

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Integrating Coexpression Networks with GWAS to Prioritize Causal Genes in Maize

Cited by 150 publications

References 72 publications

Multi-allelic APRR2 Gene is Associated with Fruit Pigment Accumulation in Melon and Watermelon

Multi-allelic APRR2 Gene is Associated with Fruit Pigment Accumulation in Melon and Watermelon

The evolutionary forces shaping cis and trans regulation of gene expression within a population of outcrossing plants

Genome-wide Association Studies of Agronomic Traits Consisting of Field- and Molecular-based Phenotypes

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