Repeated DNA sequences of Aegilops markgrafii (Greuter) Hammer var. markgrafii‘. Cloning, sequencing and analysis of distribution in Poaceae species

Development of Aegilops comosa and Aegilops caudata-specific molecular markers and fluorescence in situ hybridization probes based on specific-locus amplified fragment sequencing

As tertiary gene pools of wheat, Aegilops comosa and Ae. caudata contain many excellent genes/traits and gradually become important and noteworthy wild resources for wheat improvement worldwide. However, the lack of molecular markers and cytological probes with good specificity and high sensitivity limits the development and utilization of Triticum aestivum-Ae. comosa (Ta. Aeco)/Ae. caudata (Ta. Aeca) introgression lines. Using specific-locus amplified fragment sequencing, two Ae. comosa and one Ae. caudata accessions, Chinese Spring, and three Ta. Aeco and Ta. Aeca introgression lines each were sequenced to develop new molecular markers and cytological probes. After strict sequence comparison and verification in different materials, a total of 39 molecular markers specific to three chromosomes in Ae. comosa (nine, seven, and 10 markers for 1M, 2M, and 7M, respectively) and Ae. caudata (two, six, and five markers for 3C, 4C, and 5C, respectively) and 21 fluorescence in situ hybridization (FISH) probes (one centromeric probe with signals specific to the M chromosomes, two centromeric probes with signals in all the tested genomes, and six, eight, and four FISH probes specific to the M, C, and M, C, and U chromosomes, respectively) were successfully exploited. The newly developed molecular markers and cytological probes could be used in karyotype studies, centromere evolutionary analyses of Aegilops, and had the ability to detect the fusion centromeres and small-fragment translocations in introgression lines.

Development of Wheat-Aegilops caudata Introgression Lines and Their Characterization Using Genome-Specific KASP Markers

Aegilops caudata L. [syn. Ae. markgrafii (Greuter) Hammer], is a diploid wild relative of wheat (2n = 2x = 14, CC) and a valuable source for new genetic diversity for wheat improvement. It has a variety of disease resistance factors along with tolerance for various abiotic stresses and can be used for wheat improvement through the generation of genome-wide introgressions resulting in different wheat-Ae. caudata recombinant lines. Here, we report the generation of nine such wheat-Ae. caudata recombinant lines which were characterized using wheat genome-specific KASP (Kompetitive Allele Specific PCR) markers and multi-color genomic in situ hybridization (mcGISH). Of these, six lines have stable homozygous introgressions from Ae. caudata and will be used for future trait analysis. Using cytological techniques and molecular marker analysis of the recombinant lines, 182 KASP markers were physically mapped onto the seven Ae. caudata chromosomes, of which 155 were polymorphic specifically with only one wheat subgenome. Comparative analysis of the physical positions of these markers in the Ae. caudata and wheat genomes confirmed that the former had chromosomal rearrangements with respect to wheat, as previously reported. These wheat-Ae. caudata recombinant lines and KASP markers are useful resources that can be used in breeding programs worldwide for wheat improvement. Additionally, the genome-specific KASP markers could prove to be a valuable tool for the rapid detection and marker-assisted selection of other Aegilops species in a wheat background.

Agronomic Traits and Molecular Marker Identification of Wheat-Aegilops caudata Addition Lines

Aegilops caudata is an important gene source for wheat breeding. Intensive evaluation of its utilization value is an essential first step prior to its application in breeding. In this research, the agronomical and quality traits of Triticum aestivum-Ae. caudata additions B-G (homoeologous groups not identified) were analyzed and evaluated. Disease resistance tests showed that chromosome D of Ae. caudata might possess leaf rust resistance, and chromosome E might carry stem rust and powdery mildew resistance genes. Investigations into agronomical traits suggested that the introduction of the Ae. caudata chromosome in addition line F could reduce plant height. Grain quality tests showed that the introduction of chromosomes E or F into wheat could increase its protein and wet gluten content. Therefore, wheat-Ae. caudata additions D-F are all potentially useful candidates for chromosome engineering activities to create useful wheat-alien chromosome introgressions. A total of 55 EST-based molecular markers were developed and then used to identify the chromosome homoeologous group of each of the Ae. caudata B-G chromosomes. Marker analysis indicated that the Ae. caudata chromosomes in addition lines B to G were structurally altered, therefore, a large population combined with intensive screening pressure should be taken into consideration when inducing and screening for wheat-Ae. caudata compensating translocations. Marker data also indicated that the Ae. caudata chromosomes in addition lines C-F were 5C, 6C, 7C, and 3C, respectively, while the homoeologous group of chromosomes B and G of Ae. caudata are as yet undetermined and need further research.

Genome analysis of South American Elymus (Triticeae) and Leymus (Triticeae) species based on variation in repeated nucleotide sequences

Variation in repeated nucleotide sequences (RNSs) at the level of entire families assayed by Southern blot hybridization is remarkably low within species and is a powerful tool for scrutinizing the origin of allopolyploid taxa. Thirty-one clones from RNSs isolated from different Triticeae genera were used to investigate the genome constitution of South American Elymus. One of these clones, pHch2, preferentially hybridized with the diploid H genome Hordeum species. Hybridization of this clone with a worldwide collection of Elymus species with known genome formulas showed that pHch2 clearly discriminates Elymus species with the H genome (StH, StHH, StStH, and StHY) from those with other genome combinations (StY, StStY, StPY, and StP). Hybridization with pHch2 indicates the presence of the H genome in all South American Elymus species except Elymus erianthus and Elymus mendocinus. Hybridization with additional clones that revealed differential restriction fragments (marker bands) for the H genome confirmed the absence of the H genome in these species. Differential restriction fragments for the Ns genome of Psathyrostachys were detected in E. erianthus and E. mendocinus and three species of Leymus. Based on genome constitution, morphology, and habitat, E. erianthus and E. mendocinus were transferred to the genus Leymus.