The genetic architecture of genome‐wide recombination rate variation in allopolyploid wheat revealed by nested association mapping

Jordan, Katherine; Wang, Shichen; He, Fei; Chao, Shiaoman; Lun, Yanni; Paux, Etienne; Sourdille, Pierre; Sherman, Jamie; Akhunova, Alina; Blake, N. K.; Pumphrey, Michael O.; Glover, Karl D.; Dubcovsky, Jorge; Talbert, L. E.; Akhunov, Eduard

doi:10.1111/tpj.14009

Cited by 94 publications

(108 citation statements)

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“…As expected, pairwise LD is consistently higher in peri‐centromeric regions (Figure b), even though markers are preferentially located in telomeric regions (Figure S7). These results are in agreement with the recombination frequency distribution observed in a bread wheat NAM (Jordan et al ., ). It is likely that the areas of high LD around centromeres are more extensive then what is apparent using the current marker set.…”

Section: Discussionmentioning

confidence: 97%

“…The EtNAM will side the multiparental populations available (Milner et al, 2016;Huang et al, 2012;Jordan et al, 2018;Mackay et al, 2014) and those in development in the Triticum species complex. It has been shown that the parallel employment of NAM families developed in closely related species can reinforce QTL findings (Mace et al, 2013), increasing their potential use in breeding efforts.…”

Section: The Etnam As a Qtl Mapping And Pre-breeding Toolmentioning

confidence: 99%

“…Conversely, nested association mapping (NAM) populations are produced by intercrossing one recurrent founder line with n other founder lines, which results in n recombinant inbred line (RIL) families that share the recurrent founder haplotype. The NAM design was developed in maize (McMullen et al, 2009) and later applied to several maize genetic backgrounds (Bauer et al, 2013) and different crops including soybean , sorghum (Bouchet et al, 2017), barley (Maurer et al, 2015;Nice et al, 2016), and bread wheat (Bajgain et al, 2016;Jordan et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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A large nested association mapping population for breeding and quantitative trait locus mapping in Ethiopian durum wheat

Kidane

Gesesse

Hailemariam

et al. 2019

Plant Biotechnology Journal

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Summary The Ethiopian plateau hosts thousands of durum wheat ( Triticum turgidum subsp. durum ) farmer varieties ( FV ) with high adaptability and breeding potential. To harness their unique allelic diversity, we produced a large nested association mapping ( NAM ) population intercrossing fifty Ethiopian FV s with an international elite durum wheat variety (Asassa). The Ethiopian NAM population (Et NAM ) is composed of fifty interconnected bi‐parental families, totalling 6280 recombinant inbred lines ( RIL s) that represent both a powerful quantitative trait loci ( QTL ) mapping tool, and a large pre‐breeding panel. Here, we discuss the molecular and phenotypic diversity of the Et NAM founder lines, then we use an array featuring 13 000 single nucleotide polymorphisms ( SNP s) to characterize a subset of 1200 Et NAM RIL s from 12 families. Finally, we test the usefulness of the population by mapping phenology traits and plant height using a genome wide association ( GWA ) approach. Et NAM RIL s showed high allelic variation and a genetic makeup combining genetic diversity from Ethiopian FV s with the international durum wheat allele pool. Et NAM SNP data were projected on the fully sequenced AB genome of wild emmer wheat, and were used to estimate pairwise linkage disequilibrium ( LD ) measures that reported an LD decay distance of 7.4 Mb on average, and balanced founder contributions across Et NAM families. GWA analyses identified 11 genomic loci individually affecting up to 3 days in flowering time and more than 1.6 cm in height. We argue that the Et NAM is a powerful tool to support the production of new durum wheat varieties targeting local and global agriculture.

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Section: Discussionmentioning

confidence: 97%

Section: The Etnam As a Qtl Mapping And Pre-breeding Toolmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A large nested association mapping population for breeding and quantitative trait locus mapping in Ethiopian durum wheat

Kidane

Gesesse

Hailemariam

et al. 2019

Plant Biotechnology Journal

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“…We can now use this knowledge to break these negative correlations by purposely generating haplotypes that combine both beneficial traits. This will be facilitated by ongoing studies into the genetic basis of recombination in wheat, which could provide the knowledge to manipulate recombination rate distribution across chromosomes (Jordan et al ., ). With clearly defined haplotypes, we can also leverage the multiple layers of genomic information (e.g.…”

Section: Moving From Snps To Haplotypes In Breedingmentioning

confidence: 97%

“…Much of this variation is studied through genetic populations composed of cultivars that differ for the trait(s) of interest. These include bi‐parental populations between two cultivars (Saintenac et al ., ), multi‐parent advanced generation inter‐cross (MAGIC) populations composed of between 4 and 16 cultivars (Huang et al ., ; Mackay et al ., ; Milner et al ., ; Dixon et al ., ), nested association mapping panels of multiple cultivars to a common parent (Jordan et al ., ), and association panels of 100 or more cultivars (Sukumaran et al ., ; Liu et al ., ). All of these types of populations are available in wheat and their relative merits are discussed elsewhere (Huang and Han, ).…”

Section: Use Of Natural Variation For Trait Discoverymentioning

confidence: 99%

Applying the latest advances in genomics and phenomics for trait discovery in polyploid wheat

2018

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Summary Improving traits in wheat has historically been challenging due to its large and polyploid genome, limited genetic diversity and in‐field phenotyping constraints. However, within recent years many of these barriers have been lowered. The availability of a chromosome‐level assembly of the wheat genome now facilitates a step‐change in wheat genetics and provides a common platform for resources, including variation data, gene expression data and genetic markers. The development of sequenced mutant populations and gene‐editing techniques now enables the rapid assessment of gene function in wheat directly. The ability to alter gene function in a targeted manner will unmask the effects of homoeolog redundancy and allow the hidden potential of this polyploid genome to be discovered. New techniques to identify and exploit the genetic diversity within wheat wild relatives now enable wheat breeders to take advantage of these additional sources of variation to address challenges facing food production. Finally, advances in phenomics have unlocked rapid screening of populations for many traits of interest both in greenhouses and in the field. Looking forwards, integrating diverse data types, including genomic, epigenetic and phenomics data, will take advantage of big data approaches including machine learning to understand trait biology in wheat in unprecedented detail.

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Identification and validation of Fusarium head blight resistance QTL in the U.S. soft red winter wheat cultivar ‘Jamestown’

Carpenter

Wright

Malla³

et al. 2020

Crop Science

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Use of genetic resistance is one of the most important strategies to manage the devastating disease Fusarium head blight (FHB) in wheat. Numerous quantitative trait loci (QTL) having varying effects on reducing FHB and the mycotoxin deoxynivalenol (DON) accumulation have been reported from Asian, European, or distant sources such as wild relatives of wheat (Triticum aestivum L.). However, coming from nonadapted backgrounds, the incorporation of such QTL into regional breeding programs has often resulted in the simultaneous transfer of other undesirable traits. Therefore, it is important to identify, characterize, and deploy sources of genetic resistance that do not suffer from poor adaptability and/or linkage drag. In the present work, QTL associated with FHB resistance in a high‐yielding, moderately resistant soft red winter wheat cultivar ‘Jamestown’ were mapped and validated. The QTL mapping was done using a recombinant inbred line (RIL) population of Pioneer ‘25R47’ × Jamestown having 186 individuals. Phenotyping over 2 yr at three locations, and genotyping using the 90K single nucleotide polymorphism (SNP) platform identified two new QTL, named QFHB.vt‐1B.1 and QFHB.vt‐1B.2, on the chromosome 1B long arm. The QTL contributed to FHB incidence, FHB severity, Fusarium‐damaged kernels, and DON content. Independent mapping of these QTL using two additional RIL populations of FG95195 × Jamestown (170 RILs) and Jamestown × LA97113UC‐124 (77 RILs) validated their stability and effectiveness in different genetic backgrounds. Kompetitive allele specific polymerase chain reaction (KASP) assays were developed using linked SNPs for marker‐assisted selection of the QTL. These QTL are being used in breeding programs to develop FHB‐resistant, high‐yielding varieties.

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The genetic architecture of genome‐wide recombination rate variation in allopolyploid wheat revealed by nested association mapping

Cited by 94 publications

References 73 publications

A large nested association mapping population for breeding and quantitative trait locus mapping in Ethiopian durum wheat

A large nested association mapping population for breeding and quantitative trait locus mapping in Ethiopian durum wheat

Applying the latest advances in genomics and phenomics for trait discovery in polyploid wheat

Identification and validation of Fusarium head blight resistance QTL in the U.S. soft red winter wheat cultivar ‘Jamestown’

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