Whole-genome variation of transposable element insertions in a maize diversity panel

Qiu, Yinjie; O’Connor, Christine H.; Coletta, Rafael Della; Renk, Jonathan S.; Monnahan, Patrick J.; Noshay, Jaclyn M.; Liang, Zhikai; Gilbert, Amanda M.; Anderson, Sarah N.; McGaugh, Suzanne E.; Springer, Nathan M.; Hirsch, Candice N.

doi:10.1093/g3journal/jkab238

Cited by 18 publications

(22 citation statements)

References 64 publications

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“…We speculate that this difference may result from the inclusion of local checks or lines of interest or changes in naming convention or transcription errors that we were unable to resolve. For the 1,014 unique genotypes named as part of the SAM population [ 3 ] or WiDiv population [ 8 ], raw whole-genome sequencing or RNA-seq sequence data were aggregated from a number of sources ( Supplementary Table S2 ) [ 8 , 9 , 18 ] as described in Sun et al. [ 13 ].…”

Section: Resultsmentioning

confidence: 99%

Association mapping across a multitude of traits collected in diverse environments in maize

et al. 2022

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Classical genetic studies have identified many cases of pleiotropy where mutations in individual genes alter many different phenotypes. Quantitative genetic studies of natural genetic variants frequently examine one or a few traits, limiting their potential to identify pleiotropic effects of natural genetic variants. Widely adopted community association panels have been employed by plant genetics communities to study the genetic basis of naturally occurring phenotypic variation in a wide range of traits. High-density genetic marker data—18M markers—from 2 partially overlapping maize association panels comprising 1,014 unique genotypes grown in field trials across at least 7 US states and scored for 162 distinct trait data sets enabled the identification of of 2,154 suggestive marker-trait associations and 697 confident associations in the maize genome using a resampling-based genome-wide association strategy. The precision of individual marker-trait associations was estimated to be 3 genes based on a reference set of genes with known phenotypes. Examples were observed of both genetic loci associated with variation in diverse traits (e.g., above-ground and below-ground traits), as well as individual loci associated with the same or similar traits across diverse environments. Many significant signals are located near genes whose functions were previously entirely unknown or estimated purely via functional data on homologs. This study demonstrates the potential of mining community association panel data using new higher-density genetic marker sets combined with resampling-based genome-wide association tests to develop testable hypotheses about gene functions, identify potential pleiotropic effects of natural genetic variants, and study genotype-by-environment interaction.

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Section: Resultsmentioning

confidence: 99%

Association mapping across a multitude of traits collected in diverse environments in maize

et al. 2022

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“…A subpanel of 102 diverse maize genotypes including stiff stalk, non-stiff stalk and iodent sub-populations representing the Wisconsin Diversity Panel (WiDiv) in maize 30,31 were selected for characterizing genotype responses to heat stress (Figure 1a). A set of 1,132,322 variants (1,032,834 SNPs + 99,488 InDels) was employed for this population (see methods for filtering details).…”

Section: Resultsmentioning

confidence: 99%

“…The SNP set of 509 inbreds from the WiDiv (Wisconsin Diversity) Panel was retrieved from a previous publication 31 for genotype subtraction. Biallelic SNPs were retained upon multiple thresholdings (no missing data across 509 inbreds; MAF > 0.05; heterozygosity <= 0.2).…”

Section: Methodsmentioning

confidence: 99%

Mapping Responsive Genomic Elements to Heat Stress in a Maize Diversity Panel

Liang

Myers

Petrella

et al. 2022

Preprint

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Many plant species exhibit genetic variation for tolerating environmental stress. A transcriptome investigation of over 100 maize inbreds revealed many cis- and trans-acting eQTLs that influence the expression response to heat stress. The cis-acting eQTL in response to heat stress are identified in genes with differential responses to heat stress between genotypes as well as genes that are only expressed under heat stress. The cis-acting variants for heat stress responsive expression likely result from distinct promoter activities and the differential heat responses of the alleles were confirmed for selected genes using transient expression assays. Global foot-printing of transcription factor binding was performed in control and heat stress conditions to document regions with heat-enriched transcription factor binding occupancies. Footprints enriched near proximal regions of characterized heat-responsive genes in a large association panel can be utilized for prioritizing functional regulatory regions that regulate genotype-specific responses under heat stress.

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“…Phenotypic values for all trait datasets employed in this study for all maize accessions evaluated are provided in Table S2 and S3. The sources of sequence data used to call genetic marker genotypes for each maize accession were NCBI BioProjects PR-JNA661271, PRJNA189400 & PRJNA437324 5,6,8 . The specific SRA IDs for individual maize accessions are indicated in Table S2.…”

Section: Data Availability Statementmentioning

confidence: 99%

“…The original MAP population which shares many genotypes with both the SAM and WiDiv panels was resequenced as part of the Maize HapMap3 project increasing the number of segregating genetic markers to 83M 7 . A subset of lines from the WiDiv panel were resequenced, resulting in a set of 3.1M SNPs scored across 511 genotypes 8 .…”

Section: Introductionmentioning

confidence: 99%

Association Mapping Across a Multitude of Traits Collected in Diverse Environments Identifies Pleiotropic Loci in Maize

Mural

Sun

Grzybowski

et al. 2022

Preprint

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Classical genetic studies have identified many cases of pleiotropy where mutations in individual genes alter many different phenotypes. Quantitative genetic studies of natural genetic variants frequently examine one or a few traits, limiting their potential to identify pleiotropic effects of natural genetic variants. Widely adopted community association panels have been employed by plant genetics communities to study the genetic basis of naturally occurring phenotypic variation in a wide range of traits. High-density genetic marker data -- 18M markers -- from two partially overlapping maize association panels comprising 1,014 unique genotypes grown in field trials across at least seven US states and scored for 162 distinct trait datasets enabled the identification of of 2,154 suggestive marker-trait associations and 697 confident associations in the maize genome using a resampling-based genome-wide association strategy. The precision of individual marker-trait associations was estimated to be three genes based a reference set of genes with known phenotypes. Examples were observed of both genetic loci associated with variation in diverse traits (e.g. above-ground and below-ground traits), as well as individual loci associated with the same or similar traits across diverse environments. Many significant signals are located near genes whose functions were previously entirely unknown or estimated purely via functional data on homologs. This study demonstrates the potential of mining community association panel data using new higher density genetic marker sets combined with resampling-based genome-wide association tests to develop testable hypotheses about gene functions, identify potential pleiotropic effects of natural genetic variants, and study genotype by environment interaction.

show abstract

Whole-genome variation of transposable element insertions in a maize diversity panel

Cited by 18 publications

References 64 publications

Association mapping across a multitude of traits collected in diverse environments in maize

Association mapping across a multitude of traits collected in diverse environments in maize

Mapping Responsive Genomic Elements to Heat Stress in a Maize Diversity Panel

Association Mapping Across a Multitude of Traits Collected in Diverse Environments Identifies Pleiotropic Loci in Maize

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