Genetic Diversity and Population Structure of F3:6 Nebraska Winter Wheat Genotypes Using Genotyping-By-Sequencing

Eltaher, Shamseldeen; Sallam, Ahmed; Belamkar, Vikas; Emara, Hamdy A.; Nower, Ahmed A.; Salem, Khaled F. M.; Poland, Jesse; Baenziger, P. Stephen

doi:10.3389/fgene.2018.00076

Cited by 191 publications

(223 citation statements)

References 46 publications

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“…www.nature.com/scientificreports www.nature.com/scientificreports/ in wheat contains comparatively fewer polymorphic markers than the A and B genomes due to low recombination attributed to its evolutionary and domestication history. Consistent with previous findings, the B genome contains a greater number of polymorphisms than the A and D genomes, which is attributed to a greater number of effective recombination events in the B genome [24][25][26] . The average number of SNPs per chromosome was 304, and the value ranged from 147 (4B) to 500 (7D) ( Supplementary Fig.…”

Section: Distribution Of Snp Markers Genetic Diversity and Populatiosupporting

confidence: 90%

GWAS revealed a novel resistance locus on chromosome 4D for the quarantine disease Karnal bunt in diverse wheat pre-breeding germplasm

Singh

Sehgal

Kumar

et al. 2020

Sci Rep

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This study was initiated to identify genomic regions conferring resistance to Karnal Bunt (KB) disease in wheat through a genome-wide association study (GWAS) on a set of 179 pre-breeding lines (PBLs). A GWAS of 6,382 high-quality DArTseq SNPs revealed 15 significant SNPs (P-value <10 −3) on chromosomes 2D, 3B, 4D and 7B that were associated with KB resistance in individual years. In particular, two SNPs (chromosome 4D) had the maximum R 2 values: SNP 1114200 | F | 0-63:T > c at 1.571 cM and R 2 of 12.49% and SNP 1103052 | F | 0-61:C > A at 1.574 cM and R 2 of 9.02%. These two SNPs displayed strong linkage disequilibrium (LD). An in silico analysis of SNPs on chromosome 4D identified two candidate gene hits, TraesCS4D02G352200 (TaNox8; an NADPH oxidase) and TraesCS4D02G350300 (a rhomboid-like protein belonging to family S54), with SNPs 1103052 | F | 0-61:C > A and 1101835 | F | 0-5:C > A, respectively, both of which function in biotic stress tolerance. The epistatic interaction analysis revealed significant interactions among 4D and 7B loci. A pedigree analysis of confirmed resistant PBLs revealed that Aegilops species is one of the parents and contributed the D genome in these resistant PBLs. These identified lines can be crossed with any elite cultivar across the globe to incorporate novel KB resistance identified on 4B.

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Section: Distribution Of Snp Markers Genetic Diversity and Populatiosupporting

confidence: 90%

GWAS revealed a novel resistance locus on chromosome 4D for the quarantine disease Karnal bunt in diverse wheat pre-breeding germplasm

Singh

Sehgal

Kumar

et al. 2020

Sci Rep

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“…Population genetic studies are essential for understanding the evolution of wheat under natural hybridization, allopolyploid speciation, natural selection, domestication, and other factors (Fahima et al ., , ; Novoselović et al ., ; Perez‐Lara et al ., ; Wang et al ., ; Eltaher et al ., ). Studies that are based on large amounts of high‐throughput genetic markers are preferable as they are aiming to characterize the general pattern of gene flow between and within populations.…”

Section: Discussionmentioning

confidence: 97%

“…The characterization of population genetic structure provides important information contributing to a better understanding of spacial distribution, adaptation, and evolution of natural plant populations. In wheat, diverse technologies that are based on randomly distributed markers were used for genotyping both natural WEW populations and domesticated wheat collections, such as RAPDs (Fahima et al ., ), microsatellites (Fahima et al ., ; Wang et al, 2017) DArTs (Novoselović et al ., ), and SNPs (GBS, Eltaher et al ., ; 90K SNP array, Perez‐Lara et al ., ). Various studies have been conducted also based on sequence variation of a single gene in WEW populations and cultivated wheat collections aimed to understand the evolutionary processes that shaped the allelic variation, structure and function of pivotal genes, including the NAM‐B1 ( Gpc‐B1 ) high grain protein and mineral content gene (Lundström et al ., ), the Pm3 powdery mildew resistance gene (Yahiaoui et al ., ), the Lr10 leaf rust‐resistance gene (Sela et al ., ), and the WKS stripe rust‐resistance genes (Huang et al ., ).…”

Section: Introductionmentioning

confidence: 99%

Wheat tandem kinases provide insights on disease‐resistance gene flow and host–parasite co‐evolution

2019

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Summary Stripe (yellow) rust, caused by the fungus Puccinia striiformis f. sp. tritici (Pst), is a destructive disease of wheat spread globally. Wild emmer wheat (Triticum turgidum ssp. dicoccoides; WEW) is known as a source for novel Pst resistance genes (R‐gene), but our knowledge on wheat‐Pst co‐evolution in natural populations is limited. Yr15 is a WEW (accession G25) gene, which confers a broad‐spectrum resistance to Pst, and encodes a tandem kinase‐pseudokinase protein designated as WTK1. Exon–intron comparisons of multiple WTK1 homoeologous and paralogous copies scattered in allopolyploid wheat genomes enabled us to develop functional molecular markers (FMMs), which were used for population genetic study. The functional allele (Wtk1) was absent in a worldwide collection of 513 wheat cultivars, except for 32 introgression lines with Yr15 from G25, as well as in 84% of the 382 tested WEW accessions collected across the Fertile Crescent. Yr15 was found to be distributed along a narrow axis from Mt Carmel to the Anti‐Lebanon Mountains ridge, mostly at elevations above c. 500 m, where the climatic conditions are favorable for disease development, therefore providing insights on gene flow and host–parasite co‐evolution in WEW natural habitats. Moreover, the worldwide absence of Wtk1 in cultivated wheat and in WEW natural populations from southeast Turkey, where wheat is believed to have been domesticated, proposes that Yr15 was rather left behind, than lost during domestication. Our results highlight the importance of conservation of WEW populations in their natural habitats for discovery of novel R‐genes and studies of host–parasite co‐evolution.

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“…As more diverse genomes are included in a panel and LD decreases, a denser set of SNPs will be necessary to ensure that all the relevant variants in the genome fall within the LD block of a marker. High‐density SNP panels already exist for a variety of plant species (Bayer et al ., ; Shirasawa et al ., ; Eltaher et al ., ).…”

Section: Workflowmentioning

confidence: 97%

Genome‐wide association studies on the phyllosphere microbiome: Embracing complexity in host–microbe interactions

et al. 2019

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Summary Environmental sequencing shows that plants harbor complex communities of microbes that vary across environments. However, many approaches for mapping plant genetic variation to microbe‐related traits were developed in the relatively simple context of binary host–microbe interactions under controlled conditions. Recent advances in sequencing and statistics make genome‐wide association studies (GWAS) an increasingly promising approach for identifying the plant genetic variation associated with microbes in a community context. This review discusses early efforts on GWAS of the plant phyllosphere microbiome and the outlook for future studies based on human microbiome GWAS. A workflow for GWAS of the phyllosphere microbiome is then presented, with particular attention to how perspectives on the mechanisms, evolution and environmental dependence of plant–microbe interactions will influence the choice of traits to be mapped.

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Genetic Diversity and Population Structure of F3:6 Nebraska Winter Wheat Genotypes Using Genotyping-By-Sequencing

Cited by 191 publications

References 46 publications

GWAS revealed a novel resistance locus on chromosome 4D for the quarantine disease Karnal bunt in diverse wheat pre-breeding germplasm

GWAS revealed a novel resistance locus on chromosome 4D for the quarantine disease Karnal bunt in diverse wheat pre-breeding germplasm

Wheat tandem kinases provide insights on disease‐resistance gene flow and host–parasite co‐evolution

Genome‐wide association studies on the phyllosphere microbiome: Embracing complexity in host–microbe interactions

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