The physical map of wheat chromosome 5DS revealed gene duplications and small rearrangements

Akpınar, Bala Anı; Magni, Federica; Yüce, Meral; Lucas, Stuart J.; Šimková, Hana; Šafář, Jan; Bergès, Hélène; Cattonaro, Federica; Doležel, Jaroslav; Budak, Hikmet

doi:10.1186/s12864-015-1641-y

Cited by 18 publications

(11 citation statements)

References 56 publications

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“…Thanks to the inclusion of the short contigs, we achieved one of the highest chromosome-arm coverages (94%) among all wheat physical maps published to date. In comparison with other physical maps assembled by FPC, our full assembly's N50 value (555 kb) is higher than that obtained for 3DS (445 kb) [20], 1AL (460 kb) [13] or 5A (296 kb and 252 kb for 5AS and 5AL) [19] but lower than the N50 value for 1BS (1033 kb) [14] or 5DS (1141 kb) [18]. Excluding contigs < 6 clones, the N50 of the 7DS assembly increased up to 616 kb, which brings the value closer to that obtained for 3 B (783 kb) [10].…”

Section: Physical Map Assembly and Anchoringcontrasting

confidence: 73%

“…Several projects [12,14,19,20] also exploited syntenybased approaches and anchored physical map assemblies to so called genome zippers [42], which predict a virtual gene order on the basis of synteny with three grass genomes (rice, brachypodium and sorghum). The limitation of this approach can be a relatively high proportion of genes (or non-recognized pseudogenes) in non-syntenic positions [12] and also low quality or different origin of genetic map used to build the zipper [18].…”

Section: Physical Map Assembly and Anchoringmentioning

confidence: 99%

“…Chromosomal BAC libraries were then constructed from all wheat chromosome arms of cv. Chinese Spring [11] (http://olomouc.ueb.cas.cz/dna-libraries/cereals) and laid the basis for constructing chromosomal physical maps for the whole wheat genome [10,[12][13][14][15][16][17][18][19][20] (www.wheatgenome.org). They proved a favorable resource for map-based gene cloning [21] as well as generating a whole-chromosome sequence [22].…”

Section: Introductionmentioning

confidence: 99%

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Integrated physical map of bread wheat chromosome arm 7DS to facilitate gene cloning and comparative studies

et al. 2019

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Bread wheat (Triticum aestivum L.) is a staple food for a significant part of the world's population. The growing demand on its production can be satisfied by improving yield and resistance to biotic and abiotic stress. Knowledge of the genome sequence would aid in discovering genes and QTLs underlying these traits and provide a basis for genomics-assisted breeding. Physical maps and BAC clones associated with them have been valuable resources from which to generate a reference genome of bread wheat and to assist map-based gene cloning. As a part of a joint effort coordinated by the International Wheat Genome Sequencing Consortium, we have constructed a BAC-based physical map of bread wheat chromosome arm 7DS consisting of 895 contigs and covering 94% of its estimated length. By anchoring BAC contigs to one radiation hybrid map and three high resolution genetic maps, we assigned 73% of the assembly to a distinct genomic position. This map integration, interconnecting a total of 1713 markers with ordered and sequenced BAC clones from a minimal tiling path, provides a tool to speed up gene cloning in wheat. The process of physical map assembly included the integration of the 7DS physical map with a whole-genome physical map of Aegilops tauschii and a 7DS Bionano genome map, which together enabled efficient scaffolding of physical-map contigs, even in the non-recombining region of the genetic centromere. Moreover, this approach facilitated a comparison of bread wheat and its ancestor at BAC-contig level and revealed a reconstructed region in the 7DS pericentromere.

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Section: Physical Map Assembly and Anchoringcontrasting

confidence: 73%

Section: Physical Map Assembly and Anchoringmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Integrated physical map of bread wheat chromosome arm 7DS to facilitate gene cloning and comparative studies

et al. 2019

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“…Although this was unexpected observation, such inconsistencies in measurements of chromosomal deletions were reported previously (Qi et al, 2003; Dilbirligi et al, 2004; Sourdille et al, 2004; Philippe et al, 2013; Belova et al, 2014; Akpinar et al, 2015). In this study, a single bin 4AL – 0.66–0.73 previously defined by three lines 4AL-05 (LPGKU1147), 4AL-07 (LPGKU1149), and 4AL-11 (LPGKU1152) was split to three bins containing 43, 72, and 88 SNP loci, respectively ( Figure 1 ; Supplementary Table S2).…”

Section: Discussionsupporting

confidence: 60%

A High Resolution Radiation Hybrid Map of Wheat Chromosome 4A

et al. 2017

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Bread wheat has a large and complex allohexaploid genome with low recombination level at chromosome centromeric and peri-centromeric regions. This significantly hampers ordering of markers, contigs of physical maps and sequence scaffolds and impedes obtaining of high-quality reference genome sequence. Here we report on the construction of high-density and high-resolution radiation hybrid (RH) map of chromosome 4A supported by high-density chromosome deletion map. A total of 119 endosperm-based RH lines of two RH panels and 15 chromosome deletion bin lines were genotyped with 90K iSelect single nucleotide polymorphism (SNP) array. A total of 2316 and 2695 markers were successfully mapped to the 4A RH and deletion maps, respectively. The chromosome deletion map was ordered in 19 bins and allowed precise identification of centromeric region and verification of the RH panel reliability. The 4A-specific RH map comprises 1080 mapping bins and spans 6550.9 cR with a resolution of 0.13 Mb/cR. Significantly higher mapping resolution in the centromeric region was observed as compared to recombination maps. Relatively even distribution of deletion frequency along the chromosome in the RH panel was observed and putative functional centromere was delimited within a region characterized by two SNP markers.

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“…The MTP clones of the CS-dt-5DS BAC library (42) were screened at Sabanci University (Turkey) with three pairs of primers for VRN-D4 listed in SI Appendix, Table S8. The selected BAC and 11 overlapping BACs belonging to two overlapping contigs (SI Appendix, Table S2) were sequenced using a combination of Illumina and 454 sequencing (SI Appendix, Method S2).…”

Section: Methodsmentioning

confidence: 99%

Identification of the VERNALIZATION 4 gene reveals the origin of spring growth habit in ancient wheats from South Asia

Kippes

Debernardi

Vasquez-Gross

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

132

106

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Wheat varieties with a winter growth habit require long exposures to low temperatures (vernalization) to accelerate flowering. Natural variation in four vernalization genes regulating this requirement has favored wheat adaptation to different environments. The first three genes (VRN1-VRN3) have been cloned and characterized before. Here we show that the fourth gene, VRN-D4, originated by the insertion of a ∼290-kb region from chromosome arm 5AL into the proximal region of chromosome arm 5DS. The inserted 5AL region includes a copy of VRN-A1 that carries distinctive mutations in its coding and regulatory regions. Three lines of evidence confirmed that this gene is VRN-D4: it cosegregated with VRN-D4 in a high-density mapping population; it was expressed earlier than other VRN1 genes in the absence of vernalization; and induced mutations in this gene resulted in delayed flowering. VRN-D4 was found in most accessions of the ancient subspecies Triticum aestivum ssp. sphaerococcum from South Asia. This subspecies showed a significant reduction of genetic diversity and increased genetic differentiation in the centromeric region of chromosome 5D, suggesting that VRN-D4 likely contributed to local adaptation and was favored by positive selection. Three adjacent SNPs in a regulatory region of the VRN-D4 first intron disrupt the binding of GLYCINE-RICH RNA-BINDING PROTEIN 2 (TaGRP2), a known repressor of VRN1 expression. The same SNPs were identified in VRN-A1 alleles previously associated with reduced vernalization requirement. These alleles can be used to modulate vernalization requirements and to develop wheat varieties better adapted to different or changing environments.wheat | flowering | vernalization | VRN1 | Triticum aestivum ssp. sphaerococcum

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The physical map of wheat chromosome 5DS revealed gene duplications and small rearrangements

Cited by 18 publications

References 56 publications

Integrated physical map of bread wheat chromosome arm 7DS to facilitate gene cloning and comparative studies

Integrated physical map of bread wheat chromosome arm 7DS to facilitate gene cloning and comparative studies

A High Resolution Radiation Hybrid Map of Wheat Chromosome 4A

Identification of the VERNALIZATION 4 gene reveals the origin of spring growth habit in ancient wheats from South Asia

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