Characterization of a Wheat Breeders’ Array suitable for high‐throughput SNP genotyping of global accessions of hexaploid bread wheat (<i>Triticum aestivum</i>)

Allen, Alexandra M.; Winfield, Mark; Burridge, Amanda J.; Downie, Rowena; Benbow, Harriet L; Barker, G. L.; Wilkinson, Paul; Coghill, Jane A.; Waterfall, Christy; Davassi, Alessandro; Scopes, Geoff; Pirani, Ali; Webster, Teresa A.; Brew, Fiona; Bloor, Claire; Griffiths, Simon; Bentley, Alison R.; Alda, Mark; Jack, Peter; Phillips, Andrew L.; Edwards, Keith J.

doi:10.1111/pbi.12635

Cited by 275 publications

(242 citation statements)

References 24 publications

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“…For example, array‐based SNP platforms improve the marker coverage and mapping resolution, and can more efficiently and accurately target R genes or define genomic regions associated with quantitative traits. SNPs are important contributors to phenotypic variation (Saxena et al , 2014), and the use of a high‐throughput SNP array in wheat is rapid, where a series of fixed SNP arrays were produced in wheat from 9K to 820K (Cavanagh et al , 2013; Wang et al , 2014; Winfield et al , 2016; Allen et al , 2017). Alternatively, an ever‐increasing throughput of next‐generation sequencing (NGS) technologies can be used to assess genome‐wide diversity.…”

Section: Advances In Genomics and High‐throughput Genotyping Technolomentioning

confidence: 99%

Mechanisms of powdery mildew resistance of wheat – a review of molecular breeding

et al. 2020

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Powdery mildew (Blumeria graminis f. sp. tritici) results in serious economic loss in wheat production. Exploration of plant resistance to wheat powdery mildew over several decades has led to the discovery of a wealth of resistance genes and quantitative trait loci (QTLs). We have provided a comprehensive summary of over 200 powdery mildew genes (permanently and temporarily designated genes) and QTLs reported in common bread wheat. This highlights the diverse and rich resistance sources that exist across all 21 chromosomes. To manage different data for breeders, here we also present a bridged mapping result from previously reported powdery mildew resistance genes and QTLs with the application of a published integrated wheat map. This will provide important insights to empower further breeding of powdery mildew resistant wheat via marker‐assisted selection (MAS).

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Section: Advances In Genomics and High‐throughput Genotyping Technolomentioning

confidence: 99%

Mechanisms of powdery mildew resistance of wheat – a review of molecular breeding

et al. 2020

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“…DArTseq is a sequencing-based platform, a modified version of the genotyping-by-sequencing (GBS) platform that combines genome complexity reduction with next-generation sequencing to generate SNP markers (Sansaloni et al, 2010(Sansaloni et al, , 2011. Other array-based platforms-wheat 660K Axiom (Zhou et al, 2018), wheat high-density genotyping array (820K) (Winfield et al, 2016), and wheat breeders' 35K genotyping array (Allen et al, 2017), all of them from Affymetrix-are also in use. In addition, crop-specific exome capture technologies were also added to the ever-increasing genotyping platforms (Allen et al, 2013;Henry et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Comparison of array‐ and sequencing‐based markers for genome‐wide association mapping and genomic prediction in spring wheat

Liu¹,

Sukumaran²,

Jarquín

et al. 2020

Crop Science

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Notwithstanding the rapid development of high‐throughput genotyping platforms in recent years, several plant research programs find themselves in a dilemma of which marker system to use while conducting genome‐wide association studies (GWAS) and genomic selection. To gain insight into this, we genotyped an elite spring wheat (Triticum aestivum L.) association mapping initiative (WAMI, 287 lines) panel with various array‐based platforms—(i) Diversity Arrays Technology (DArT), (ii) Illumina Infinium BeadChip wheat 9K iSelect (I9K), and (iii) wheat 90K iSelect (I90K)—and sequencing‐based platform DArTseq. The raw markers refined using a common set of protocols after the bioinformatics analysis were compared by performing a series of genetic analyses: estimates of genetic diversity through nucleotide diversity (π), population structure and familial relatedness, marker‐trait associations (MTAs), and genomic prediction. Results indicated that genetic data from DArTseq consisted of a high proportion of rare allele markers (1% < minor allele frequency < 5%). The nucleotide diversity statistic (π) was higher for the array‐based single nucleotide polymorphisms (SNPs) than sequencing‐based SNPs. The I9K detected population structure caused by the variety ‘Kauz’ and grouped the population into two subgroups, whereas I90K, DArT, and DArTseq detected five subgroups driven by key pedigrees. The I90K with the highest marker density identified a high number of significant MTAs. Genomic prediction accuracy varied among traits; DArTseq and I90K produced similar prediction accuracies. Among the marker platforms compared, I90K was the best genotyping platform for GWAS, and DArTseq—given the low cost per SNP—was the best platform for genomic prediction in spring wheat.

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“…The global demand for wheat yields has been estimated to increase by 50% in 2050, in order to feed the world's growing population (Grassini et al, 2013;Allen et al, 2017). To meet this demand, wheat production should be increased through agricultural intensification in cropping regions areas.…”

Section: Introductionmentioning

confidence: 99%

Genetic diversity of Cameroonian bread wheat (Triticum aestivum L.) cultivars revealed by microsatellite markers

Tekeu¹,

Ngonkeu²,

Djocgoué³

et al. 2017

Afr. J. Biotechnol.

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The assessment of genetic diversity is a key prerequisite for studying the adaptation of populations to new environmental conditions, and therefore for the selection of new varieties. The present investigation aimed to estimate the levels and genetic structure within bread wheat varieties grown in Cameroon. Thus, genetic diversity was assessed in 17 hexaploid wheat cultivars, using 11 microsatellite markers. Genetic resources were collected in the Northwest, Adamawa and North Regions. All pairs of specific marker loci used gave amplifications with allelic variations of size on all DNA of wheat accessions. A total of 77 alleles were detected among cultivars and the number of alleles per locus ranged from 2 to 13 with an average of 7, comparable to those observed in most previous studies. Gene diversity ranged from 0.46 (Xgdm 125) to 0.90 (Xgwm 177) with an average of 0.88, increasing with the number of alleles, with a correlation coefficient of 0.88 (Adamawa) and 0.76 (Northwest). Microsatellite markers used had an average value of polymorphic information content (PIC) of 0.69, indicating that these markers are highly informative in this study. These markers are valid and will make a contribution to the studies in hexaploid wheat. Moreover, cluster analysis at a genetic similarity of 80% and the principal component analysis, where the first two components explaining 59.86% of variation which structured 17 accessions in 5 main distinct groups. This high diversity revealed among wheat accessions, grown in Cameroon could be used in the breeding programs.

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Characterization of a Wheat Breeders’ Array suitable for high‐throughput SNP genotyping of global accessions of hexaploid bread wheat (Triticum aestivum)

Cited by 275 publications

References 24 publications

Mechanisms of powdery mildew resistance of wheat – a review of molecular breeding

Mechanisms of powdery mildew resistance of wheat – a review of molecular breeding

Comparison of array‐ and sequencing‐based markers for genome‐wide association mapping and genomic prediction in spring wheat

Genetic diversity of Cameroonian bread wheat (Triticum aestivum L.) cultivars revealed by microsatellite markers

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