Molecular identification of powdery mildew resistance genes in common wheat (Triticum aestivum L.)

Hartl, L.; Weiß, H.; Stephan, U.; Zeller, F. J.; Jahoor, A.

doi:10.1007/bf00222121

Cited by 65 publications

(30 citation statements)

References 36 publications

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“…Therefore both the accuracy and efficiency for selection on the dominant homozygous genotypes of single dominant gene based on a single marker are obviously higher than when based on phenotypic performance, and a map distance of 5.0 cM or less is sufficient for markerassisted selection in breeding programmes (Hartl et al, 1995).…”

Section: Molecular Marker-assisted Selectionmentioning

confidence: 99%

“…Results from QTL studies cannot be reimplemented through marker-assisted selection because of uncertainty about whether the QTLs identified are real, and whether the identified QTLs segregate in the breeding population (Spelman & Bovenhuis, 1998b). Marker-assisted selection of economically important traits conferred by single major genes has also been mentioned or generally discussed in many publications (Talbert, 1993 ;Williams et al, 1994 ;Feuillet et al, 1995 ;Hartl et al, 1995 ;McCouch et al, 1997 ;Sun et al, 1997 ;Hausner et al, 1999) and even conducted in tomato for the Tm-2 locus (Young & Tanksley, 1989) and for the nematode resistance gene Gro1 (Ballvora et al, 1995). Markers associated with stress responses have practical application in accelerating breeding programmes (marker-assisted selection) aimed at improving the barley crop by introgressing genes from selected wild genotypes (Forster et al, 1997).…”

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confidence: 99%

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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

et al. 2000

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A new stripe rust resistance gene, YrH52, derived from the unique Mount Hermon population of wild emmer wheat (Triticum dicoccoides) in Israel, was previously located on chromosome 1B. The main objectives of the present study were to increase marker density in the vicinity of the YrH52 gene using additional microsatellite markers, and to evaluate the accuracy and efficiency of marker-assisted selection on this gene in the F # generation. By means of 70 additional microsatellite primer pairs, 150 individuals of the F # mapping population were genotyped. Among 202 marker loci, 20 were found to be linked to the YrH52 gene with log-likelihood (LOD) scores ranging from 3.84 to 58.82, and linkage distances ranging from 0.33 to 41.39 cM. A genetic map was constructed of chromosome 1B, consisting of 23 markers and the YrH52 gene, with a total map length of 149.5 cM. Most of the markers were located in the region close to YrH52, which was flanked by Xgwm413 and Xgwm273a with map distances of 1.3 and 2.7 cM, respectively. The accuracy and efficiency of marker-assisted selection were calculated as AMAS and EMAS, respectively, for homozygous resistant genotypes of YrH52 gene in the F # generation. AMAS and EMAS for homozygous resistant genotypes of the YrH52 gene in the F # generation showed linear and significant negative correlation with the map distance between marker and target gene or between the two bracketing markers. It was concluded that the YrH52 region on chromosome 1B is significantly more enriched by microsatellite markers than the previously published map ; that a single microsatellite marker is efficient for marker-assisted selection of homozygous resistant genotypes of YrH52 gene in the F # generation when the map distance is 5.0 cM ; and that when two markers are used AMAS can be dramatically improved and becomes relatively stable, whereas EMAS will not be obviously improved and will still vary linearly with map distance.

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Section: Molecular Marker-assisted Selectionmentioning

confidence: 99%

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confidence: 99%

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

et al. 2000

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“…RFLP, RAPD and AFLP markers linked to wheat powdery mildew resistance genes Pm1 (Hartl et al 1995(Hartl et al , 1999Hu et al 1997), Pm2 (Ma et al 1994), Pm3 (Hartl et al 1993), Pm4 (Ma et al 1994), Pm6 (Tao et al 2000), Pm8 (Hsam et al 2000), Pm12 (Jia et al 1996), Pm13 (Donini et al 1995;Cenci et al 1999), Pm18 (Hartl et al 1993), Pm21 (Qi et al 1996), Pm24 (Huang et al 2000b), Pm25 (Shi et al 1998), Pm26 (Rong et al 2000), Pm27 (Järve et al 2000), Pm29 (Zeller et al 2002) and Pm30 (Liu et al 2002) have been identified. Microsatellites, also termed simple sequence repeats (SSRs) as a new type of genetic marker reveal a much higher polymorphism in wheat than any other marker system (Plaschke et al 1995;Huang et al 2002).…”

Section: Introductionmentioning

confidence: 97%

Microsatellite mapping of the powdery mildew resistance gene Pm5e in common wheat (Triticum aestivum L.)

et al. 2003

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Powdery mildew, caused by Erysiphe graminis DM f. sp. tritici (Em. Marchal), is one of the most important diseases of common wheat world-wide. Chinese wheat variety 'Fuzhuang 30' carries the powdery mildew resistance gene Pm5e and has proven to be a valuable resistance source of powdery mildew for wheat breeding. Microsatellite markers were employed to identify the gene Pm5e in a F(2) progeny from the cross 'Nongda 15' (susceptible) x 'Fuzhuang 30' (resistant). The gene Pm5e was mapped in the distal region of chromosome 7BL. Seven microsatellite markers were found to be linked to the gene Pm5e, of which two codominant markers Xgwm783 and Xgwm1267 were relatively close to Pm5e with a linkage distance of 11.0 cM and 6.6 cM, respectively. It is possible to use the 136-bp allele of Xgwm1267 in 'Fuzhuang 30' for marker-assisted selection during the wheat resistance breeding process for facilitation of gene pyramiding. The mapping information in the present study provides a starting point for fine mapping of the Pm5 locus and map-based cloning to clarify the molecular structure and function of the different alleles at the Pm5 locus. A microsatellite linkage map of chromosome 7B was constructed with 20 microsatellite loci, nine on the short arm and 11 on the long arm. This information will be very useful for further mapping of agronomically important genes of interest on chromosome 7B.

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“…Therefore we need to search for new sources of genetic resistance to powdery mildew for cultivated wheat and the wild relatives of cultivated wheats. Molecular marker technology is widely used to fi nd markers linked to target genes (Hartl et al, 1995, Schachermayr et al, 1995, Hu et al, 2001). Molecular marker analysis in wheat appears to be particularly suited for identifying markers linked to the powdery mildew resistance gene (Devos and Gale, 1992;Wang et al, 2000) and has been used for marker-assisted selection and gene pyramiding in wheat resistance breeding (Liu et al, 1998;Myburg, et al, 1998;Hu et al, 2000;Liu and Liu, 2000).…”

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confidence: 99%

Identification of RAPD Markers and Development of SCAR Markers Linked to a Powdery Mildew Resistance Gene, and their Location on Chromosome in Wheat Cultivar Brock

Wang

Zhao

Hong

et al. 2005

Plant Production Science

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: Wheat cultivar Jing 411 which is susceptible to powdery mildew, and wheat cultivar Brock and NILs of Jing 411, which are resistant to powdery mildew were analysized for polymophisms using 213 random amplifi ed polymorphic DNA primers. Only one primer (S2092) stably produced a polymorphic band between the resistant and susceptible plants. Linkage analysis of this marker (S2092 972 ) revealed that the polymorphism existed in a 131 F 2 segregating population. S2092 972 was closely linked to a powdery mildew resistance gene in wheat cultivar Brock, at a linkage distance was 4.9 cM. S2092 972 was converted to sequence characterized amplifi ed region (SCAR) markers SCAR 860 and SCAR 200 . The two SCAR markers were used for detecting F 2 segregating population. SCAR 860 and SCAR 200 existed in resistant plants but were absent in the susceptible plants. We concluded that S2092 972 was located on the chromosome 3BL. These markers will be useful for marker-assisted selection and gene pyramiding in wheat resistance breeding.

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Molecular identification of powdery mildew resistance genes in common wheat (Triticum aestivum L.)

Cited by 65 publications

References 36 publications

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

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

Microsatellite mapping of the powdery mildew resistance gene Pm5e in common wheat (Triticum aestivum L.)

Identification of RAPD Markers and Development of SCAR Markers Linked to a Powdery Mildew Resistance Gene, and their Location on Chromosome in Wheat Cultivar Brock

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Molecular identification of powdery mildew resistance genes in common wheat (Triticum aestivum L.)

Cited by 65 publications

References 36 publications

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

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

Microsatellite mapping of the powdery mildew resistance gene Pm5e in common wheat (Triticum aestivum L.)

Identification of RAPD Markers and Development of SCAR Markers Linked to a Powdery Mildew Resistance Gene, and their Location on Chromosome in Wheat Cultivar Brock

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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

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