Sorghum Association Panel Whole-Genome Sequencing Establishes Pivotal Resource for Dissecting Genomic Diversity

Boatwright, J. Lucas; Sapkota, Sirjan; Jin, Hongyu; Schnable, James C.; Brenton, Zachary; Boyles, Richard; Kresovich, Stephen

doi:10.1101/2021.12.22.473950

Cited by 5 publications

(5 citation statements)

References 91 publications

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“…Genome-wide markers for the inbred parents were generated from whole genome resequencing using Illumina NovaSeq 6000. The sequenced reads were aligned to version 3.1.1 of sorghum reference genome BTx623 ( McCormick et al 2018 ), single nucleotide polymorphism variants were called using joint calling in GATK pipeline and imputed using Beagle at

99% accuracy [for details see Boatwright et al (2021) ]. The phased genotypic data were filtered using vcftools ( Danecek et al 2011 ) to only allow 1% missingness and 2% minor allele frequency resulting in 7,804,754 total SNPs, which was further thinned using vcftools to only include one SNP marker every 100 bp to a total SNP count of 2,687,342 for computational efficiency.…”

Section: Methodsmentioning

confidence: 99%

Genomic prediction of hybrid performance for agronomic traits in sorghum

Sapkota

Boatwright

Kumar

et al. 2022

G3: Genes, Genomes, Genetics

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Hybrid breeding in sorghum [Sorghum bicolor (L.) Moench] utilizes the cytoplasmic nuclear male sterility (CMS) system for seed production and subsequently harnesses heterosis. Since the cost of developing and evaluating inbred and hybrid lines in the CMS system is costly and time consuming, genomic prediction of parental lines and hybrids based on genetic data would reduce breeding cycle length and increase probability of recovering exceptional product genotype. We generated 602 hybrids by crossing two female (A) lines with 301 diverse and elite male (R) lines from the sorghum association panel and collected phenotypic data for agronomic traits over two years. We genotyped the inbred parents using whole genome resequencing and used 2,687,342 high quality (minor allele frequency > 2%) single nucleotide polymorphisms for genomic prediction. For grain yield, the experimental hybrids exhibited an average mid-parent heterosis of 40%. Genomic best linear unbiased prediction (GBLUP) for hybrid performance yielded an average prediction accuracy of 0.76 to 0.93 under the prediction scenario where both parental lines in validation sets were included in the training sets (T2). However, when only female tester was shared between training and validation sets (T1F), prediction accuracies declined by 12% to 90%, with plant height showing the greatest decline. Mean accuracies for predicting general combining ability (GCA) of male parents ranged from 0.33 to 0.62 for all traits. Our results showed hybrid performance for agronomic traits can be predicted with high accuracy, and optimizing genomic relationship is essential for optimal training population design for genomic selection in sorghum breeding.

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Section: Methodsmentioning

confidence: 99%

Genomic prediction of hybrid performance for agronomic traits in sorghum

Sapkota

Boatwright

Kumar

et al. 2022

G3: Genes, Genomes, Genetics

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“…MATs and the genetic architecture driving them in sorghum are likely to be far more complex than the ten QTL identified in our study because genetic diversity of the BTx623 and IS3620C parents represents only a fraction of the total genetic diversity of the Sorghum bicolor species (40,41). Indeed, genetic analysis of MATs in populations such as the Sorghum Association Panel (41)(42)(43), which captures genetic diversity of sorghum from all four of the major subpopulations that appear to represent two independent domestication events, will help provide a more comprehensive picture of MATs in sorghum and the underlying genetics.…”

Section: Genetic Architecture Of Mats In the Btx623 X Is3620c Ril Pop...mentioning

confidence: 76%

Complex Trait Analysis of Human Gut Microbiome-Active Traits in Sorghum bicolor: a new category of human health traits in food crops

Yang¹,

Haute²,

Korth³

et al. 2022

Preprint

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Several bioactive components of the human diet have major effects on composition and function of the gut microbiome, but no systematic framework exists for understanding variation in microbiome-active components amid the vast amount of genotypic and phenotypic variation within a given species of food crop. Here we present a powerful new approach for complex trait analysis of Microbiome-Active Traits (MATs) in food crops. Capitalizing on a novel automated in vitro microbiome screening (AiMS) methodology to quantify human gut microbiome phenotypes after fermentation of grain from genetically diverse lines, we show how microbiome phenotypes can be used as quantitative traits for genetic analysis. Quantitative Trait Locus (QTL) analysis of AiMS-based phenotypes across grain samples from 294 sorghum (Sorghum bicolor) recombinant inbred lines identified significant QTLs at 10 different genomic regions that collectively control MATs affecting 16 different microbial taxa. Segregation analysis and validation in Near-Isogenic Lines (NILs) confirmed that overlapping QTL peaks for microbiome phenotypes, seed color, and tannin concentration are driven by variation in the Tan2 (chromosome 2) and Tan1 (chromosome 4) regulators of the tannin biosynthetic pathway. Candidate genes at other QTLs suggest that variation in a diverse array of plant molecules can drive MATs.

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“…The SAP is also extensively sequenced providing vital data for downstream resistance breeding. Based on our analysis and previous work (Boatwright et al 2022), the SAP comprises all major botanical races of sorghum (caudatum, kafir, guinea, and durra) and a mixed population believed to have originated from bicolor -one of the earliest races to undergo domestication (Harlan & Stemler, 1976). We adopted a simple methodology for discovery of Strigaresistance alleles in sorghum based on PCR screening using two sets of primers -making it applicable in basic laboratories without the need for sophisticated equipment and resources for advanced molecular screening.…”

Section: Discussionmentioning

confidence: 99%

“…For this study, we selected a large collection of sorghum accessions, the Sorghum Accession Panel (SAP), maintained by the United States Department of Agriculture Agricultural Research Service (USDA-ARS) (https://www.ars-grin.gov/). High quality genotypic data is available for the SAP including genotyping by sequencing, single nucleotide polymorphism (SNP) markers (Morris et al 2013) and whole genome sequencing (WGS) (Boatwright et al 2022) making the SAP suitable for subsequent molecular breeding studies. The SAP provides a further advantage because it comprises converted tropical lines (Kleinet al 2008) of diverse genotypes and geographic origin as well as breeding lines that are photoperiod-insensitive, elite inbred, improved cultivars, and landraces selected to capture maximum genetic and phenotypic diversity (Casa et al 2008).…”

Section: Introductionmentioning

confidence: 99%

Harnessing the strigolactone biosynthesis mutant lgs1 to combat food insecurity in Africa

Mutinda

Jamil

Wang

et al. 2023

Preprint

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Sorghum is a food staple for millions of people in sub-Saharan Africa, but its production is greatly diminished by parasitic weeds of the Striga genus. An efficient and cost-effective way of managing Striga in smallholder farms of Africa is to deploy resistant varieties. Here, we leverage genomics and the vast genetic diversity of sorghum – evolutionarily adapted to cope with Striga parasitism in Africa – to identify new Striga resistant sorghum genotypes. We exploit a Striga resistance mechanism that hinges on essential communication molecules – strigolactones exuded by hosts to trigger parasite seed germination. We used the Sorghum Association Panel (SAP) to search for sorghum genotypes with a mutation on the LOW GERMINATION STIMULANT 1 ( LGS1) locus that make them ineffective in inducing Striga germination. Our analysis led us to identify new lgs1 sorghum genotypes which we named SAP lgs1. SAP lgs1 had the SL exudation profile of known lgs1 sorghum whose hallmark is production of the low inducer of germination, orobanchol. Laboratory and field resistance screens showed that the SAP lgs1 genotypes also exhibited remarkable resistance against Striga. By potentially reducing crop losses due to Striga parasitism, our findings have far-reaching implications for improving food security in Africa.

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Sorghum Association Panel Whole-Genome Sequencing Establishes Pivotal Resource for Dissecting Genomic Diversity

Cited by 5 publications

References 91 publications

Genomic prediction of hybrid performance for agronomic traits in sorghum

Genomic prediction of hybrid performance for agronomic traits in sorghum

Complex Trait Analysis of Human Gut Microbiome-Active Traits in Sorghum bicolor: a new category of human health traits in food crops

Harnessing the strigolactone biosynthesis mutant lgs1 to combat food insecurity in Africa

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