Mapping causal mutations by exome sequencing in a wheat TILLING population: a tall mutant case study

Mo, Youngjun; Howell, T. A.; Vasquez-Gross, Hans; Haro, Luis Alejandro de; Dubcovsky, Jorge; Pearce, Stephen

doi:10.1007/s00438-017-1401-6

Cited by 71 publications

(43 citation statements)

References 45 publications

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“…Typically, for quantitative traits, phenotypes are clearer with successive backcross generations (Simmonds et al ., ). However, some qualitative traits can be studied directly in the initial mutant population (Mo et al ., ; Shorinola et al ., ). A caveat for the use of these populations is that not all genes will be present in the in silico database.…”

Section: Gene Validation In Polyploid Wheatmentioning

confidence: 96%

“…Instead, integrating known genetic mapping with new genomic approaches can accelerate trait discovery. Exome‐capture sequencing has been used to identify variation in the coding region of the wheat genome (Saintenac et al ., ) and can be used to identify candidate genes, often in combination with bulk‐segregant analysis (Gardiner et al ., ; Mo et al ., ). SNPs identified from the exome capture can be used to both develop new markers for genetic mapping and to identify mutations in putative candidate genes.…”

Section: New Strategies Accelerate Gene Discovery In Wheatmentioning

confidence: 97%

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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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Section: Gene Validation In Polyploid Wheatmentioning

confidence: 96%

Section: New Strategies Accelerate Gene Discovery In Wheatmentioning

confidence: 97%

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

2018

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“…To address this, different approaches have been developed to reduce such complexity in large‐genome species. One such approach is exome capture and sequencing, which greatly reduces sequencing volume and subsequently costs while giving good coverage of gene coding regions or sufficient mapping information of a genomic interval harbouring the causal gene (Mo et al , 2018). Exome capture assays yielded identification of gene candidates for plant height and resistance to leaf and yellow rust in wheat mutants (Hussain et al , 2018; Mo et al , 2018).…”

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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“…Genotyping-by-sequencing (GBS) entails restriction enzyme digests of genomic DNA to enrich for DNA fragments that begin with common restriction sites for high-throughput genome resequencing (Poland et al 2012;Truong et al 2012). Exome sequencing (exome-seq), on the other hand, enriches specifically for the genecontaining regions of the genome through affinity capture and purification of the predicted wheat coding regions for high throughput genome resequencing (Allen et al 2013;Henry et al 2014;Uauy et al 2017;Krasileva et al 2017;Mo et al 2017).…”

Section: Introductionmentioning

confidence: 99%

“…The RNA-seq approach has the drawback that relative gene expression levels vary in different tissues and times in development, leading to the possibility that the gene of interest might be underrepresented in the sampled tissue. Exome capture has enabled affinity-purification of the predicted wheat coding regions before performing whole genome DNA resequencing (Allen et al 2013;Henry et al 2014;Uauy et al 2017;Krasileva et al 2017;Mo et al 2017). This approach has been used to characterize the genome-sequence of EMS-mutagenized wheat TILLING populations (Harrington et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Exome sequencing of bulked segregants identified a novel TaMKK3-A allele linked to the wheat ERA8 ABA-hypersensitive germination phenotype

Martinez

Shorinola

Conselman

et al. 2019

Preprint

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Author contribution statement: SAM, OS, CMS, and CU designed the experiments. SAM and CMS developed the populations. SAM and SC performed the Louise/ZakERA8 QTL analysis. DZS and DS conducted GBS and analyzed the raw sequence data. SAM performed germination assays for the bulked segregant analysis, fine mapped ERA8, and introgressed ERA8 into breeding lines. OS performed the exome capture, BSA, and designed KASP markers. SAM and OS conducted the RNA sequencing and TaMKK3-A alignment. CMS and CU provided resources. SAM and CMS wrote the manuscript. All authors read and approved the final submission.Abstract: Preharvest sprouting (PHS) is the germination of mature grain on the mother plant when it rains before harvest. The ENHANCED RESPONSE TO ABA8 (ERA8) mutant increases seed dormancy and, consequently, PHS tolerance in soft white wheat 'Zak'. ERA8 was mapped to chromosome 4A in a Zak/'ZakERA8' backcross population using bulked segregant analysis of exome sequenced DNA (BSA-exome-seq). ERA8 was fine-mapped relative to mutagen-induced SNPs to a 4.6 Mb region containing 70 genes. In the backcross population, the ERA8 ABA hypersensitive phenotype was strongly linked to a missense mutation TaMKK3-A-G1093A (LOD 16.5), a gene associated with natural PHS tolerance in barley and wheat. The map position of ERA8 was confirmed in an 'Otis'/ZakERA8 but not in a 'Louise'/ZakERA8 mapping population. This is likely because Otis carries the same natural PHS susceptible MKK3-A-A660 S allele as Zak, whereas Louise carries the PHS tolerant MKK3-A-C660 R allele. Thus, the variation for grain dormancy and PHS tolerance in the Louise/ZakERA8 population likely resulted from segregation of other loci rather than segregation for PHS tolerance at the MKK3 locus. This inadvertent complementation test suggests that the MKK3-A-G1093A mutation causes the ERA8 phenotype. Moreover, MKK3 was a known ABA signaling gene in the 70-gene 4.6 Mb ERA8 interval. None of these 70 genes showed the differential regulation in wild-type Zak versus ERA8 expected of a promoter mutation. Thus, the working model is that the ERA8 phenotype results from the MKK3-A-G1093A mutation. Key MessageUsing bulked segregant analysis of exome sequence, we fine-mapped the ABA hypersensitive mutant ERA8 in a wheat backcross population to the TaMKK3-A locus of chromosome 4A.

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Mapping causal mutations by exome sequencing in a wheat TILLING population: a tall mutant case study

Cited by 71 publications

References 45 publications

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

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

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

Exome sequencing of bulked segregants identified a novel TaMKK3-A allele linked to the wheat ERA8 ABA-hypersensitive germination phenotype

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