Microsatellite high‐density mapping of the stripe rust resistance gene <i>YrH52</i> region on chromosome 1B and evaluation of its marker‐assisted selection in the F<sub>2</sub> generation in wild emmer wheat

Peng, Junhua; Fahima, Tzion; Röder, Marion S.; Li, Y. C.; Grama, A.; Nevo, Eviatar

doi:10.1046/j.1469-8137.2000.00617.x

Cited by 56 publications

(33 citation statements)

References 42 publications

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“…Recently, Röder et al (1998) developed a set of hexaploid wheat microsatellite markers, and constructed a molecular map consisting of 279 microsatellite loci amplified by 230 primer sets. The efficiency of these primer sets in analysis of T. dicoccoides genomic DNA was demonstrated previously both for mapping (Chagué et al 1999;Peng et al 1999Peng et al , 2000 and population genetics purposes (Fahima et al 1998;Li et al 2000). Seventy-nine of these microsatellite markers were integrated into the above-mentioned RFLP-linkage map in durum wheat (Korzun et al 1999).…”

Section: Org]mentioning

confidence: 86%

Molecular Genetic Maps in Wild Emmer Wheat, Triticum dicoccoides: Genome-Wide Coverage, Massive Negative Interference, and Putative Quasi-Linkage

Peng¹,

Korol²,

Fahima³

et al. 2000

Genome Res.

162

103

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The main objectives of the study reported here were to construct a molecular map of wild emmer wheat, Triticum dicoccoides, to characterize the marker-related anatomy of the genome, and to evaluate segregation and recombination patterns upon crossing T. dicoccoides with its domesticated descendant Triticum durum(cultivar Langdon). The total map length exceeded 3000 cM and possibly covered the entire tetraploid genome (AABB). Clusters of molecular markers were observed on most of the 14 chromosomes. AFLP (amplified fragment length polymorphism) markers manifested a random distribution among homologous groups, but not among genomes and chromosomes. Genetic differentiation between T. dicoccoidesand T. durum was attributed mainly to the B genome as revealed by AFLP markers. The segregation-distorted markers were mainly clustered on 4A, 5A, and 5B chromosomes. Homeoalleles, differentially conferring the vigor of gametes, might be responsible for the distortion on 5A and 5B chromosomes. Quasilinkage, deviation from free recombination between markers of nonhomologous chromosomes, was discovered. Massive negative interference was observed in most of the chromosomes (an excess of double crossovers in adjacent intervals relative to the expected rates on the assumption of no interference). The general pattern of distribution of islands of negative interference included near-centromeric location, spanning the centromere, and median/subterminal location.[An appendix describing the molecular marker loci is available as an online supplement athttp://www.genome.org.]

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Section: Org]mentioning

confidence: 86%

Molecular Genetic Maps in Wild Emmer Wheat, Triticum dicoccoides: Genome-Wide Coverage, Massive Negative Interference, and Putative Quasi-Linkage

Peng¹,

Korol²,

Fahima³

et al. 2000

Genome Res.

162

103

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“…The effectiveness of markers for MAS was evaluated by calculating accuracy and efficiency using the empirical formula proposed by Peng et al (2000). Accuracy of a marker is calculated by the number of homozygous resistant plants among the total number of plants containing the resistant parent-type marker multiplied by 100.…”

Section: Linkage Analysis and Evaluation Of Markersmentioning

confidence: 99%

DNA and morphological markers for a Russian wheat aphid resistance gene

2004

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The Russian wheat aphid (RWA), Diuraphis noxia (Mordvilko), is a significant insect pest of wheat worldwide. Morphological and molecular markers associated with RWA resistance could be used to increase the accuracy and efficiency of selection of resistant germplasm and facilitate transfer to desirable wheat genotypes. The objective of this work was to identify microsatellite (SSR) markers linked to the RWA resistance gene (Dn4) and glume-colour gene (Rg2) using a population of F 2 -derived F 3 families originating from a cross between a susceptible line (synthetic hexaploid-11) and a resistance cultivar (Halt). Two microsatellite markers Xgwm106 and Xgwm337 flanked Dn4 on the short arm of chromosome 1D at 5.9 and 9.2 cM, respectively. Two other microsatellite markers, Xpsp2999 and Xpsp3000, at the distal part of this chromosome arm are linked to Dn4 and to Rg2. The accuracy and efficiency of marker-assisted selection were calculated for homozygous Dn4Dn4 genotypes in the F 2 generation. The gene Rg2 for red glume colour can also be used for marker-assisted selection of Dn4 gene individually and in combination with microsatellite markers. When used together, the closest markers Xgwm106 and Xgwm337, provide 100% accuracy and 75% efficiency. One hundred percent accuracy is also achieved when the morphological marker red glume is used in combination with either Xgwm106 or Xgwm337. Using these flanking markers, it may be possible to fix resistance to RWA in the first segregating generation of an F 2 population without infestation with aphids.

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“…This being the purpose, many molecular markers, such as Restriction Fragment Length Polymorphisms (RFLPs) (Helentjaris et al 1986), Random Amplified Polymorphic DNAs (RAPDs) (Williams et al 1990), Amplified Fragment Length Polymorphisms (AFLPs) (Vos et al 1995), Resistance Gene Analogs (RGAs) (Kanazin et al 1996) and Simple Sequence Repeats (SSRs) (Akkaya et al 1992) have been widely used in plants. The successful utility of DNA markers has been shown in different wheat breeding programmes, namely SCAR marker (SC-Y15) for Yr17 (Sharp et al 2001), SSR markers (Xgwm413 and Xgwm273) for YrH52 (Peng et al 2000) and SSR marker (Xgwm498) for Yr26 (Yildirim et al 2004), for developing resistant wheat cultivars. Worldwide, yellow rust resistance genes Yr1-Yr48 and many provisionally designated genes have been identified in wheat and its relatives (Huang et al 2011).…”

mentioning

confidence: 99%

An EST-SSR marker, bu099658, and its potential use in breeding for yellow rust resistance in wheat

Hasançebi¹,

Mert²,

Ertuğrul³

et al. 2014

CZECH J GENET PLANT

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Hasancebi S., Mert Z., Ertugrul F., Akan K., Aydin Y., Senturk Akfirat F., Altinkut Uncuoglu A. (2014): An EST-SSR marker, bu099658, and its potential use in breeding for yellow rust resistance in wheat. Czech J. Genet. Plant Breed., 50: 11-18.EST-SSR markers, derived from the A and B genomes of wheat were used to identify molecular markers associated with yellow rust resistance. For this purpose, bulk segregant analysis was performed using 114 EST-SSR primer pairs. They were screened on the parent genotypes and resistant/susceptible DNA pools from the cross between Izgi2001 (resistant male parent) × ES14 (susceptible female parent) at the seedling and adult plant stage. An EST-SSR marker, bu099658, generated the 206 bp DNA fragment that was present in the resistant parent and resistant bulk, but it was not present in the susceptible parent and the susceptible bulk. To investigate its association with Yr genes, 20 individuals of NILs were also amplified with BU099658 and the 206 bp marker fragment was obtained only in Yr1/6 × Avocet S. Additionally, bu099658 was screened on 65 genotypes which possessed different Yr genes/gene combination(s) and Yr1. The results indicate a close linkage of bu099658 with the Yr1 gene.

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Microsatellite high‐density mapping of the stripe rust resistance gene YrH52 region on chromosome 1B and evaluation of its marker‐assisted selection in the F₂ generation in wild emmer wheat

Cited by 56 publications

References 42 publications

Molecular Genetic Maps in Wild Emmer Wheat, Triticum dicoccoides: Genome-Wide Coverage, Massive Negative Interference, and Putative Quasi-Linkage

Molecular Genetic Maps in Wild Emmer Wheat, Triticum dicoccoides: Genome-Wide Coverage, Massive Negative Interference, and Putative Quasi-Linkage

DNA and morphological markers for a Russian wheat aphid resistance gene

An EST-SSR marker, bu099658, and its potential use in breeding for yellow rust resistance in wheat

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Microsatellite high‐density mapping of the stripe rust resistance gene YrH52 region on chromosome 1B and evaluation of its marker‐assisted selection in the F2 generation in wild emmer wheat

Cited by 56 publications

References 42 publications

Molecular Genetic Maps in Wild Emmer Wheat, Triticum dicoccoides: Genome-Wide Coverage, Massive Negative Interference, and Putative Quasi-Linkage

Molecular Genetic Maps in Wild Emmer Wheat, Triticum dicoccoides: Genome-Wide Coverage, Massive Negative Interference, and Putative Quasi-Linkage

DNA and morphological markers for a Russian wheat aphid resistance gene

An EST-SSR marker, bu099658, and its potential use in breeding for yellow rust resistance in wheat

Contact Info

Product

Resources

About

Microsatellite high‐density mapping of the stripe rust resistance gene YrH52 region on chromosome 1B and evaluation of its marker‐assisted selection in the F₂ generation in wild emmer wheat