High-Resolution Radiation Hybrid Map of Wheat Chromosome 1D

Kalavacharla, Venu; Hossain, Khwaja; Gu, Yong; Riera‐Lizarazu, Oscar; Vales, M. I.; Bhamidimarri, Suresh; Gonzalez-Hernandez, Jose L.; Maan, S. S.; Kianian, Shahryar F.

doi:10.1534/genetics.106.056481

Cited by 52 publications

(57 citation statements)

References 65 publications

(101 reference statements)

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“…TILLING [Till et al, 2007] and RNA interference [Lukens and Zhan, 2007]). In polyploid species, high-resolution mapping using radiation-induced deletion lines (Kalavacharla et al, 2006) offers a useful route to cloning QTLs in regions that are low in polymorphism or recombination. In maize, a substantial advancement in QTL discovery and cloning has been made possible through the adoption of the nested-association mapping (NAM) system (Yu et al, 2008).…”

Section: The Way Aheadmentioning

confidence: 99%

Quantitative Trait Loci and Crop Performance under Abiotic Stress: Where Do We Stand?: Table I.

Collins

Tardieu²,

Tuberosa³

2008

Plant Physiol.

492

330

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Section: The Way Aheadmentioning

confidence: 99%

Quantitative Trait Loci and Crop Performance under Abiotic Stress: Where Do We Stand?: Table I.

Collins

Tardieu²,

Tuberosa³

2008

Plant Physiol.

492

330

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“…Genome-wide high-density genotyping of several hundred or even thousands of individuals has been made possible by cost-effective genotyping by sequencing (Elshire at al., 2011;Poland et al, 2012). Apart from recombination-based mapping, radiation hybrid panels similar to those implemented in wheat (Kalavacharla et al, 2006) or obtained for barley by the activity of gametocidal chromosomes (Masoudi-Nejad et al, 2005) may be of value. Similarly, fluorescent in situ hybridization mapping (Cheng et al, 2001) and optical mapping (Zhou et al, 2009) hold some promise and may be used to order markers in recombinogenically inert regions.…”

Section: Discussionmentioning

confidence: 99%

A Sequence-Ready Physical Map of Barley Anchored Genetically by Two Million Single-Nucleotide Polymorphisms

et al. 2013

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Barley (Hordeum vulgare) is an important cereal crop and a model species for Triticeae genomics. To lay the foundation for hierarchical map-based sequencing, a genome-wide physical map of its large and complex 5.1 billion-bp genome was constructed by high-information content fingerprinting of almost 600,000 bacterial artificial chromosomes representing 14-fold haploid genome coverage. The resultant physical map comprises 9,265 contigs with a cumulative size of 4.9 Gb representing 96% of the physical length of the barley genome. The reliability of the map was verified through extensive genetic marker information and the analysis of topological networks of clone overlaps. A minimum tiling path of 66,772 minimally overlapping clones was defined that will serve as a template for hierarchical clone-by-clone map-based shotgun sequencing. We integrated whole-genome shotgun sequence data from the individuals of two mapping populations with published bacterial artificial chromosome survey sequence information to genetically anchor the physical map. This novel approach in combination with the comprehensive whole-genome shotgun sequence data sets allowed us to independently validate and improve a previously reported physical and genetic framework. The resources developed in this study will underpin fine-mapping and cloning of agronomically important genes and the assembly of a draft genome sequence.

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“…One of the methods to achieve the high resolution mapping in the recombination-depleted region of genome is the radiation hybrid (RH) mapping (Goss and Harris, 1975;Riera-Lizarazu et al, 2008). Kalavacharla et al (2006) constructed a high-resolution physical map of chromosome 1D by irradiation treatment to wheat seed. This RH mapping approach allowed ordering molecular markers previously unordered within a chromosomal bin, and RH maps with the required resolution can be produced by altering the dosage of radiation.…”

Section: Discussionmentioning

confidence: 99%

Molecular mapping of the suppressor gene Igc1 to the gametocidal gene Gc3-C1 in common wheat

et al. 2010

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Several species of the genus Aegilops, wild relatives of wheat (Triticum aestivum, 2n = 6x = 42, AABBDD) carry gametocidal (Gc) genes. Gc genes kill the gametes without themselves by causing chromosomal breakage during postmeiotic cell divisions, and therefore are strong segregation distorters. The Gc gene Gc3-C1 derived from chromosome 3C of Ae. triuncialis (2n = 4x = 28, CCUU) induces chromosomal breakage in wheat cultivar 'Chinese Spring' (CS) but not in cultivar 'Norin 26' (N26). This cultivar-specific inhibition of Gc function is caused by a suppressor gene Igc1 located on chromosome 3B of N26. Igc1 is presumed to be a modified Gc gene without breakage function because of its homoeology to Gc3-C1. Here we report the results of linkage and physical mapping of Igc1 to help elucidate the molecular mechanisms underlying Gc action. Segregation analysis of the phenotypic data in BC 1 F 1 mapping population of the cross between (CSxN26)F 1 and CS + 3C" showed a 1:1 segregation ratio indicating that Igc1 is a dominant gene. In the linkage analysis, three molecular marker loci Xgwm285, Xgwm376, and Xcfp1886 cosegregated with the Igc1 locus. Bin mapping assigned the loci Xgwm285 and Xcfp1886 to bin C-3BS1-0.33 and Xgwm376 to bin C-3BL2-0.22. Physical mapping using Gc-induced chromosomal deletion lines of chromosome 3B of N26 revealed that the Igc1 locus resides in 52.0% or 2.1% of bins C-3BS1-0.33 and C-3BL2-0.22, respectively. Pericentromeric localization of Igc1 in chromosome 3B of N26 may have a positive effect to keep the two-component system of the Gc action. Map-based cloning approach to isolate the Igc1 may be difficult because recombination is depleted in the pericentromeric region. As is shown in this study, the combination of genetic and physical mapping offers high efficiency to identify the regions where genes are located especially in regions with low levels of recombination.

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High-Resolution Radiation Hybrid Map of Wheat Chromosome 1D

Cited by 52 publications

References 65 publications

Quantitative Trait Loci and Crop Performance under Abiotic Stress: Where Do We Stand?: Table I.

Quantitative Trait Loci and Crop Performance under Abiotic Stress: Where Do We Stand?: Table I.

A Sequence-Ready Physical Map of Barley Anchored Genetically by Two Million Single-Nucleotide Polymorphisms

Molecular mapping of the suppressor gene Igc1 to the gametocidal gene Gc3-C1 in common wheat

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