Molecular and cytogenetic characterization of a common wheat-Agropyron cristatum chromosome translocation conferring resistance to leaf rust

Ochoa, Virginia; Madrid, Eva; Said, Mahmoud; Rubiales, Diego; Cabrera, Adoración

doi:10.1007/s10681-014-1190-5

Cited by 39 publications

(48 citation statements)

References 32 publications

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“…Similar spontaneous chromosomal rearrangements have also been reported in wheat-rye and wheat-A. cristatum translocation line (Ren et al 1991;Ochoa et al 2015).…”

Section: R a F Tsupporting

confidence: 78%

“…The conventional chromosomal manipulation by crossing between common wheat and the amphiploid carrying alien desirable genes is an effective method to induce chromosome translocation (Jiang et al 1994;Friebe et al 1996;Qi et al 2007). The amphiploids between wheat and species from genera Secale, Thinopyrum, Agropyron, Dasypyrum, Leymus and Psathyrostachys have been synthesized to produce many translocation genotypes in wheat breeding (Jiang et al 1994;Lukaszewski 1995;Qi et al 2007;Kang 2011;Ochoa et al 2015;). However, it has been a challenge to transfer a small amount of alien chromatin containing the gene of interest from one genome to another non-homologous genome (Niu et al 2011).…”

Section: R a F Tmentioning

confidence: 99%

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Characterization of wheat – Psathyrostachys huashanica small segment translocation line with enhanced kernels per spike and stripe rust resistance

Kang

Zhang

et al. 2016

Genome

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Psathyrostachys huashanica Keng (2n = 2x = 14, NsNs), a distant wild relative of common wheat, possesses rich potentially valuable traits, such as disease resistance and more spikelets and kernels per spike, that could be useful for wheat genetic improvement. Development of wheat - P. huashanica translocation lines will facilitate its practical utilization in wheat breeding. In the present study, a wheat - P. huashanica small segmental translocation line, K-13-835-3, was isolated and characterized from the BC1F5 population of a cross between wheat - P. huashanica amphiploid PHW-SA and wheat cultivar CN16. Cytological studies showed that the mean chromosome configuration of K-13-835-3 at meiosis was 2n = 42 = 0.10 I + 19.43 II (ring) + 1.52 II (rod). GISH analyses indicated that chromosome composition of K-13-835-3 included 40 wheat chromosomes and a pair of wheat - P. huashanica translocation chromosomes. FISH results demonstrated that the small segment from an unidentified P. huashanica chromosome was translocated into wheat chromosome arm 5DS, proximal to the centromere region of 5DS. Compared with the cultivar wheat parent CN16, K-13-835-3 was highly resistant to stripe rust pathogens prevalent in China. Furthermore, spikelets and kernels per spike in K-13-835-3 were significantly higher than those of CN16 in two growing seasons. These results suggest that the desirable genes from P. huashanica were successfully transferred into CN16 background. This translocation line could be used as novel germplasm for high-yield and, eventually, resistant cultivar breeding.

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“…Similar spontaneous chromosomal rearrangements have also been reported in wheat-rye and wheat-A. cristatum translocation line (Ren et al 1991;Ochoa et al 2015).…”

Section: R a F Tsupporting

confidence: 78%

Section: R a F Tmentioning

confidence: 99%

Characterization of wheat – Psathyrostachys huashanica small segment translocation line with enhanced kernels per spike and stripe rust resistance

Kang

Zhang

et al. 2016

Genome

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“…Numerous genes providing tolerance to biotic stress (i.e., resistance to barley yellow dwarf virus, wheat streak mosaic virus, yellow rust, leaf rust, stem rust, and powdery mildew) and abiotic stresses (i.e., cold‐, salinity‐ and drought tolerance) as well as genes improving yield were identified in crested wheatgrass (Shukle et al, 1987; Brettell et al, 1988; Littlejohn, 1988; Whelan, 1988; Friebe et al, 1992; Luan et al, 2010; Song et al, 2013; Ceoloni et al, 2015; Ochoa et al, 2015). In the present study, we extended the chromosome‐based approach to the complex P‐genome of crested wheatgrass (Said et al, 2018a) to produce genomic resources for chromosome‐mediated gene transfer into wheat.…”

Section: Discussionmentioning

confidence: 99%

“…As the wild‐crop relatives have not been subjected to human selection, they exhibit large genetic variation and offer a rich source of alleles and genes for crop improvement (Tanksley and McCouch, 1997). Alien gene transfer through chromosome engineering is an effective strategy to exploit this wild genetic diversity for wheat improvement (Feuillet et al, 2008; Luan et al, 2010; Molnár‐Láng et al, 2015; Ochoa et al, 2015; Zhang et al, 2017).…”

mentioning

confidence: 99%

Dissecting the Complex Genome of Crested Wheatgrass by Chromosome Flow Sorting

et al. 2019

Self Cite

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Core Ideas Flow sorting enabled to dissect the genome of crested wheatgrass into chromosomes. This is a powerful approach to access the complex genome of a wheat wild relative. Chromosome genomics will support alien introgression breeding of the crop. Wheatgrass (Agropyron sp.) is a potential source of beneficial traits for wheat improvement. Among them, crested wheatgrass [A. cristatum (L.) Gaertn.] comprises a complex of diploid, tetraploid, and hexaploid forms with the basic genome P, with some accessions carrying supernumerary B chromosomes (Bs). In this work, we applied flow cytometry to dissect the complex genome of crested wheatgrass into individual chromosomes to facilitate its analysis. Flow karyotypes obtained after the analysis of 4ʹ,6‐diamidino‐2‐phenylindole (DAPI)‐stained mitotic chromosomes of diploid and tetraploid accessions consisted of three peaks, each corresponding to a group of two or three chromosomes. To improve the resolution, bivariate flow karyotyping after fluorescent labeling of chromosomes with fluorescein isothiocyanate (FITC)‐conjugated probe (GAA)7 microsatellite was applied and allowed discrimination and sorting of P genome chromosomes from wheat–crested wheatgrass addition lines. Chromosomes 1P–6P and seven telomeric chromosomes could be sorted at purities ranging from 81.7 to 98.2% in disomics and from 44.8 to 87.3% in telosomics. Chromosome 7P was sorted at purities reaching 50.0 and 39.5% in diploid and tetraploid crested wheatgrass, respectively. In addition to the whole complement chromosomes (A), Bs could be easily discriminated and sorted from a diploid accession at 95.4% purity. The sorted chromosomes will streamline genome analysis of crested wheatgrass, facilitating gene cloning and development of molecular tools to support alien introgression into wheat.

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“…For example, the disomic addition line 4844 shows superior numbers of florets and kernels per spike, and the alien chromosomes were designated as 6P of A. cristatum (Wu et al 2006). Recently an A. cristatumwheat compensating Robertsonian translocation conferring resistance to leaf rust was reported (Ochoa et al 2015). The detection of alien chromosome/fragment/gene in the wheat background can provide a guide to utilize the wheat-A.…”

Section: Introductionmentioning

confidence: 99%

A high-density genetic map for P genome of Agropyron Gaertn. based on specific-locus amplified fragment sequencing (SLAF-seq)

Yan

Zhang

Huang

et al. 2015

Planta

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This genetic map for Agropyron Gaertn. contained 1023 markers on seven linkage groups, with a total of 907.8 cM and an average distance of 1.5 cM between adjacent loci. Many wheat- Agropyron cristatum derivative lines exhibit superior agronomic traits, and part of them are valuable for future wheat breeding. To date, no high-density genetic map for Agropyron Gaertn. has been published. Specific-locus amplified fragment sequencing (SLAF-seq), a recently developed strategy for large scale de novo discovery and genotyping of single nucleotide polymorphisms (SNPs), was employed in this study to develop sufficient markers for a segregating Agropyron F1 population derived from an interspecific cross between two cross-pollinated diploid collections A. cristatum (L.) Beauv. 'Z1842' and A. mongolicum Keng 'Z2098'. In total, we obtained raw data consisting of 128,932,358 pair-end reads of ~80 bp long after sequencing. Then 69,325 high-quality SLAFs were detected, of which 26,248 SLAFs were polymorphic and 1752 of the polymorphic markers were used for the genetic map construction. The final map contained 1023 markers on the seven linkage groups (LGs), which spanned a total of 907.8 cM with an average number of 146 markers and 89 loci per LG and an average distance of 1.5 cM between adjacent loci. To our knowledge, this map is the densest genetic linkage map for Agropyron so far. Through BLAT alignment of Agropyron SLAF marker sequences with the draft genome assemblies of wheat and barley, the Agropyron LGs were assigned as LG1-7 according to their corresponding homoeologous chromosomal groups of wheat. Results of this study will not only provide a platform for gene/QTL fine mapping, but also serve as a reference to assist the assembling of the P genome sequence in future.

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Molecular and cytogenetic characterization of a common wheat-Agropyron cristatum chromosome translocation conferring resistance to leaf rust

Cited by 39 publications

References 32 publications

Characterization of wheat – Psathyrostachys huashanica small segment translocation line with enhanced kernels per spike and stripe rust resistance

Characterization of wheat – Psathyrostachys huashanica small segment translocation line with enhanced kernels per spike and stripe rust resistance

Dissecting the Complex Genome of Crested Wheatgrass by Chromosome Flow Sorting

A high-density genetic map for P genome of Agropyron Gaertn. based on specific-locus amplified fragment sequencing (SLAF-seq)

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