Mapping‐by‐sequencing in complex polyploid genomes using genic sequence capture: a case study to map yellow rust resistance in hexaploid wheat

Gardiner, Laura‐Jayne; Bansept-Basler, Pauline; Olohan, Lisa; Joynson, Ryan; Brenchley, Rachel; Hall, Neil; O’Sullivan, Donal M.; Hall, Anthony

doi:10.1111/tpj.13204

Cited by 27 publications

(35 citation statements)

References 39 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…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: 98%

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

2018

View full text Add to dashboard Cite

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.

show abstract

Section: New Strategies Accelerate Gene Discovery In Wheatmentioning

confidence: 98%

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

2018

View full text Add to dashboard Cite

show abstract

“…To date, such diversity has been profiled in wheat using capture probe sets that have not been able to make use of the recent advances in wheat genome sequencing and annotation. Most of the diversity studies have implemented either cDNA/exon-based probe sets of 56 and 84 Mb (Winfield et al, 2012;Krasileva et al, 2016) or the gene-based probe set of 107 Mb (Jordan et al, 2015;Gardiner et al, 2016). Aligning the 107 Mb capture probe set to the current wheat genome annotations (BLASTN, e-value 1e-05, identity 95%, minimum length 40bp), we can see that it represents only 32.9% of the high confidence gene-set or 21.2% of the gene-set plus promoters defined as 2Kbp upstream (Clavijo et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Integrating genomic resources to present full gene and promoter capture probe sets for bread wheat

Gardiner

Brabbs

Akhunova

et al. 2018

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…We conclude with recommendations for how some of these challenges might be overcome using deep sequencing approaches. We reiterate the recommendation from others (Salmon et al, 2012;Jupe et al, 2013;Gardiner et al, 2016;Van Weymers et al, 2016;Krasileva et al, 2017) that non-amplicon based targeted sequence capture (e.g., whole genome exon capture or targeting of particular gene families) is the most promising method for tackling the full complexity of gene family evolution in complex genomes but suggest cautionary strategies that should be considered when interpreting evolutionary patterns.…”

Section: Introduction Background and Aimsmentioning

confidence: 99%

“…Fortunately, rapid advances in sequencing technology and bioinformatic processing mean that the toolbox available to resolve such challenges continues to improve. Targeted sequence capture, for example, has been used effectively to investigate genomic changes in polyploids (Salmon et al, 2012;Gardiner et al, 2016;Krasileva et al, 2017). However, even with these advances in technology there are important issues to consider when resolving and interpreting evolutionary dynamics of gene families, particularly for systems in which recent polyploidization and hybridization could complicate accurate assembly into orthologs and subsequent genotyping within and between copies.…”

Section: Introduction Background and Aimsmentioning

confidence: 99%

Adding Complexity to Complexity: Gene Family Evolution in Polyploids

et al. 2018

View full text Add to dashboard Cite

Comparative genomics of non-model organisms has resurrected whole genome duplication (WGD) from being viewed as a somewhat obscure process that happens in plants to a primary driver of eukaryotic diversification. The shadow of past ploidy increases has left a strong signature of duplicated genes organized into gene families, even in small genomes that have undergone effectively complete rediploidization. Nevertheless, despite continually advancing technologies and bioinformatics pipelines, resolving the fate of duplicate genes remains a substantial challenge. For example, many important recognition processes are driven not only by allelic expansion through retention of duplicates but also by diversification and copy number variation. This creates technical difficulties with assembly to reference genomes and accurate interpretation of homology. Thus, relatively little is known about the impacts of recent polyploidization and hybridization on the evolution of gene families under selective forces that maintain diversity, such as balancing selection. Here we use a complex of species and ploidy levels in the genus Arabidopsis (A. lyrata and A. arenosa) as a model to investigate the evolutionary dynamics of a large and complicated gene family known to be under strong balancing selection: the receptor-like kinases, which include the female component of genetically controlled self-incompatibility. Specifically, we question: (1) How does diversity of S-receptor kinase (SRK) alleles in tetraploids compare to that in their close diploid relatives? (2) Is there increased trans-specific polymorphism (i.e., sharing of alleles that transcend speciation, characteristic of balancing selection) in tetraploids compared to diploids due to the higher number of copies they carry? (3) Do these highly variable loci show evidence of introgression among extant species/ploidy levels within or outside known zones of hybridization? (4) Is there evidence for copy number variation among paralogs? We use this example to highlight specific issues to consider when interpreting gene family evolution, particularly in relation to polyploids but also more generally in diploids. We conclude with recommendations for strategies to address the challenges of resolving such complex loci in the future, using advances in deep sequencing approaches.

show abstract

Mapping‐by‐sequencing in complex polyploid genomes using genic sequence capture: a case study to map yellow rust resistance in hexaploid wheat

Cited by 27 publications

References 39 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

Integrating genomic resources to present full gene and promoter capture probe sets for bread wheat

Adding Complexity to Complexity: Gene Family Evolution in Polyploids

Contact Info

Product

Resources

About