Hybridisation‐based target enrichment of phenology genes to dissect the genetic basis of yield and adaptation in barley

Hill, Camilla Beate; Angessa, Tefera Tolera; McFawn, Lee-Anne; Wong, Debbie; Tibbits, Josquin; Zhang, Xiaoqi; Forrest, Kerrie; Moody, D. Branch; Telfer, Paul; Westcott, Sharon; Diepeveen, Dean; Xu, Yonghong; Tan, Cong; Hayden, Matthew; Li, Chengdao

doi:10.1111/pbi.13029

Cited by 38 publications

(105 citation statements)

References 35 publications

(44 reference statements)

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“…Furthermore, a total of 246 MTAs were considered to be ‘stable’, 76 MTAs were considered to be ‘consistent’, and 73 MTAs were considered to be ‘robust’ (S13 File). More than 30% of the significant MTAs were also detected in our previous study [10], in which a GWAS was performed using 4,600 SNPs (in comparison to the 33,486 SNPs used in the present study) obtained from target enrichment sequencing data for phenology genes combined with field trial data from 2015 and 2016. Here, novel and highly significant MTAs were located within the genes HORVU5Hr1G096560 (disease resistance protein), HORVU5Hr1G095040 (beta glucosidase C), and HORVU5Hr1G104240 (zinc finger A20 and AN1 domain-containing stress-associated protein 6) on chromosome 5H (S13 File).…”

Section: Resultssupporting

confidence: 64%

“…To examine the origins and patterns of genetic diversity within the currently available barley cultivar gene pool, we assembled a global panel of 632 genotypes to represent barley genotypes from major global barley breeding programmes, including both historical cultivars and modern cultivars from 43 countries (S1 Fig, S1 File). The panel of 632 genotypes geographically diverse barley cultivars was genotyped using target capture [10, 11], low-coverage whole-genome sequencing (WGS), and genotyping-by-sequencing (GBS) by Diversity Arrays Technology (DArTseq). In total, 15,328 single-nucleotide polymorphisms (SNPs) and insertions and deletions (InDels) were detected via low-coverage WGS, 4,260 SNPs via target-enrichment sequencing, and 18,551 SNPs via DArTseq were distributed across 5,171 barley genes.…”

Section: Resultsmentioning

confidence: 99%

“…Across all field trials, we identified 1,132 significant unique marker-trait associations (MTAs) (false discovery rate [FDR] of P < 0.05) for flowering time located within 327 unique genes with functional annotations, each explaining up to 18.7% of the phenotypic variation (S13 File, S18 Figure). These regions include known phenology-related genes, such as HvPPD-H1 , PHYTOCHROME C ( HvPhyC ), PROTEIN KINASE 2A ( HvCK2A ), HvADA2, PHYTOCHROME-ASSOCIATED PROTEIN 2 ( HvPAP2 ), and VERNALIZATION H1 ( HvVRN-H1 ) [4,10–12]. Furthermore, a total of 246 MTAs were considered to be ‘stable’, 76 MTAs were considered to be ‘consistent’, and 73 MTAs were considered to be ‘robust’ (S13 File).…”

Section: Resultsmentioning

confidence: 99%

“…Notably, we also detected novel associations with candidate phenology-related genes that were not included in the previous target-enrichment sequencing study [10] but that have annotations linking them to roles in flowering time regulation, including CCT and PRR motifs characteristic of key phenology genes such as HvCO1 , HvVRN-H2 , and HvPPD-H1 [4]. These genes included HORVU1Hr1G011030 and HORVU5Hr1G125620 (both annotated as COP1-interacting protein-related), HORVU2Hr1G055130 and HORVU7Hr1G044380 (both annotated as CONSTANS, CO-like, and TOC1 [CCT] motif family protein, and HORVU3Hr1G092330 and HORVU6Hr1G008870 (both annotated as pentatricopeptide repeat-containing protein).…”

Section: Resultsmentioning

confidence: 99%

“…Population genetic studies have examined a variety of aspects of barley genetic variation on a global scale, and have identified a striking degree of variability in traits related to flowering time, grain yield, and tolerance to abiotic and biotic factors [10–14]. This suggests that current barley germplasm resources might be harnessed to meet future challenges imposed by climate change.…”

Section: Introductionmentioning

confidence: 99%

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A global barley panel revealing genomic signatures of breeding in modern cultivars

Hill

Angessa

Zhang

et al. 2020

Preprint

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18The future of plant cultivar improvement lies in the evaluation of genetic resources from 19 currently available germplasm. Recent efforts in plant breeding have been aimed at 20 developing new and improved varieties from poorly adapted crops to suit local environments. 21 However, the impact of these breeding efforts is poorly understood. Here, we assess the 22 contributions of both historical and recent breeding efforts to local adaptation and crop 23 improvement in a global barley panel by analysing the distribution of genetic variants with 24 respect to geographic region or historical breeding category. By tracing the impact breeding 25 had on the genetic diversity of barley released in Australia, where the history of barley 26 production is relatively young, we identify 69 candidate regions within 922 genes that were 27 under selection pressure. We also show that modern Australian barley varieties exhibit 12% 28 higher genetic diversity than historical cultivars. Finally, field-trialling and phenotyping for 29 agriculturally relevant traits across a diverse range of Australian environments suggests that 30 genomic regions under strong breeding selection and their candidate genes are closely 31 associated with key agronomic traits. In conclusion, our combined dataset and germplasm 32 collection provide a rich source of genetic diversity that can be applied to understanding and 33 improving environmental adaptation and enhanced yields. 35Author summary 36 Today's gene pool of crop genetic diversity has been shaped during domestication and more 37 recently by breeding. Genetic diversity is vital for crop species to be able to adapt to 38 changing environments. There is concern that recent breeding efforts have eroded the genetic 39 diversity of many domesticated crops including barley. The present study assembled a global 40 panel of barley genotypes with a focus on historical and modern Australian varieties.41 Genome-wide data was used to detect genes that are thought to have been under selection 3 42 during crop breeding in Australian barley. The results demonstrate that despite being more 43 extensively bred, modern Australian barley varieties exhibit higher genetic diversity than 44 historical cultivars, countering the common perception that intensive breeding leads to 45 genetic erosion of adaptive diversity in modern cultivars. In addition, some loci (particularly 46 those related to phenology) were subject to selection during the introduction of other barley 47 varieties to Australia -these genes might continue to be important targets in breeding efforts 48 in the face of changing climatic conditions. 49 50 51The diversity of the existing genetic pool for commercially important plant species has been 52 shaped during plant domestication, human migration, varietal selection processes and, more 53 recently, breeding. However, there is concern that breeding efforts have eroded genetic 54 variation, thereby resulting in a narrow range of genotypes in the current gene pools of 55 domesticated crops [1...

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Section: Resultssupporting

confidence: 64%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A global barley panel revealing genomic signatures of breeding in modern cultivars

Hill

Angessa

Zhang

et al. 2020

Preprint

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Genome-Wide Association Study (GWAS) for Trait Analysis in Crops

Kumari

Muduli

Meher

et al. 2022

Springer Protocols Handbooks

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Major flowering time genes of barley: allelic diversity, effects, and comparison with wheat

2021

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Key message This review summarizes the allelic series, effects, interactions between genes and with the environment, for the major flowering time genes that drive phenological adaptation of barley. Abstract The optimization of phenology is a major goal of plant breeding addressing the production of high-yielding varieties adapted to changing climatic conditions. Flowering time in cereals is regulated by genetic networks that respond predominately to day length and temperature. Allelic diversity at these genes is at the basis of barley wide adaptation. Detailed knowledge of their effects, and genetic and environmental interactions will facilitate plant breeders manipulating flowering time in cereal germplasm enhancement, by exploiting appropriate gene combinations. This review describes a catalogue of alleles found in QTL studies by barley geneticists, corresponding to the genetic diversity at major flowering time genes, the main drivers of barley phenological adaptation: VRN-H1 (HvBM5A), VRN-H2 (HvZCCTa-c), VRN-H3 (HvFT1), PPD-H1 (HvPRR37), PPD-H2 (HvFT3), and eam6/eps2 (HvCEN). For each gene, allelic series, size and direction of QTL effects, interactions between genes and with the environment are presented. Pleiotropic effects on agronomically important traits such as grain yield are also discussed. The review includes brief comments on additional genes with large effects on phenology that became relevant in modern barley breeding. The parallelisms between flowering time allelic variation between the two most cultivated Triticeae species (barley and wheat) are also outlined. This work is mostly based on previously published data, although we added some new data and hypothesis supported by a number of studies. This review shows the wide variety of allelic effects that provide enormous plasticity in barley flowering behavior, which opens new avenues to breeders for fine-tuning phenology of the barley crop.

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Hybridisation‐based target enrichment of phenology genes to dissect the genetic basis of yield and adaptation in barley

Cited by 38 publications

References 35 publications

A global barley panel revealing genomic signatures of breeding in modern cultivars

A global barley panel revealing genomic signatures of breeding in modern cultivars

Genome-Wide Association Study (GWAS) for Trait Analysis in Crops

Major flowering time genes of barley: allelic diversity, effects, and comparison with wheat

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