Investigation of chromosomal genetic characteristics and identification of structural variation in the offspring of hexaploid triticale×hexaploid wheat.

Hexaploid triticale is an important genetic resource for genetic improvement of common wheat, which can broaden the genetic basis of wheat. In order to lay a foundation for the subsequent research and utilization of triticale germplasm materials, the chromosomal genetic characteristics of cross and backcross offspring of hexaploid triticale×hexaploid wheat were investigated in the process of transferring rye chromatin from hexaploid triticale to hexaploid wheat. Hybrid and backcross combinations were prepared with hexaploid triticale 16yin171 as the maternal parent and hexaploid wheat Chuanmai62 as the paternal parent. The chromosomes in root tip cells of F1, BC1F1 and BC1F2 plants were traced and identified non-denaturing florescence in situ hybridization (ND-FISH). The results indicated that the backcross setting rate of hybrid F1 was 2.61%. The transmission frequency of 2R chromosome was the highest in BC1F1 plants while the transmissibility of rye chromosome in BC1F2 plant was 6R>4R>2R, and the 5B-7B wheat translocation in BC1F2 plants showed severe segregation. A total of 24 structural variant chromosomes were observed both in BC1F1 and BC1F2 plants, including chromosome fragments, isochromosomes, translocations, and dicentric chromosomes. In addition, the seed length and 1000-grain weight of some BC1F2 plants were better than that of the hexaploid wheat parent Chuanmai 62. Therefore, multiple backcrosses should be adopted as far as possible to make the rapid recovery of group D chromosomes, ensuring the recovery of fertility in offspring, when hexaploid tritriale is used as a bridge to introduce rye genetic material into common wheat. At the same time, the potential application value of chromosomal structural variation materials should be also concerned.

[Pedigree and development of wheat varieties in Sichuan Province].

Variety pedigree contains a lot of information, including parental origin, breeding methods, genetic relationship, and so on. Studying them could reveal the evolution characteristics and rules of breeding and ultimately guide practice. The pedigrees of 326 wheat varieties from 1936 to 2017 in the history of the Sichuan Province was collected and analyzed in terms of breeding methods, parental composition, changes of high frequency parents and backbone parents, genetic contribution, distribution of translocation lines and synthetic germplasms. Over the past 80 years since 1930s, breeders have selected 387 direct parents from a large number of materials, made 256 combinations by means of cross breeding, and have released 314 varieties from them, which contributed directly to wheat breeding and production in Sichuan. Wheat breeding experienced a process from utilizing landraces, introducing foreign germplasm to creating breeding materials independently; high-frequency parents and backbone parents used for breeding gradually changed in different stage of the breeding history. Synthetic germplasms contributed greatly to wheat breeding in recent years. The consistency of breeding objectives will inevitably lead to the loss of genetic diversity and the fragility of genetic basis. In the future, the protection and utilization of genetic resources should be strengthened. In this review, the development of wheat breeding in Sichuan was summarized through pedigree analysis, in order to provide a reference for future research.

A novel wheat-Dasypyrum breviaristatum substitution line with stripe rust resistance.

The introduction of genetic variation from wild and cultivated Triticeae species has been a long-standing approach for wheat improvement. Dasypyrum breviaristatum species harbor novel and agronomically important genes for resistance against multi-fungal diseases. The development of new wheat-D. breviaristatum introgression lines offers chances for the identification of stripe rust resistance gene(s). A wheat line, D11-5, was selected from a cross between wheat line MY11 and wheat-D. breviaristatum partial amphiploid TDH-2. It was characterized by FISH and PCR-based molecular markers. Chromosome counting revealed that the D11-5 line shows a hexaploid set of 2n = 6x = 42 chromosomes. FISH analysis using the Dasypyrum repetitive sequence pDb12H as a probe demonstrated that D11-5 contained a pair of D. breviaristatum chromosomes, while FISH with wheat D-genomic repetitive sequences revealed that the chromosome 2D was absent in D11-5. The functional molecular markers confirmed that the introduced D. breviaristatum chromosomes belong to the homoeologous group 2, indicating that D11-5 was a 2V(b) (2D) disomic substitution line. Field resistance showed that the introduced D. breviaristatum chromosomes 2V(b) were responsible for the stripe rust resistance at the adult plant stage. FISH, C-banding, and PCR-based molecular marker analysis indicated that the chromosome 2V(b) of D. breviaristatum was completely different from the chromosome 2V of D. villosum. The identified wheat-D. breviaristatum chromosome substitution line D11-5 may be applied to produce agronomically desirable stripe rust resistance germplasm.

Characterization and phylogenetic analysis of α-gliadin gene sequences reveals significant genomic divergence in Triticeae species.

Although the unique properties of wheat α-gliadin gene family are well characterized, little is known about the evolution and genomic divergence of α-gliadin gene family within the Triticeae. We isolated a total of 203 α-gliadin gene sequences from 11 representative diploid and polyploid Triticeae species, and found 108 sequences putatively functional. Our results indicate that α-gliadin genes may have possibly originated from wild Secale species, where the sequences contain the shortest repetitive domains and display minimum variation. A miniature inverted-repeat transposable element insertion is reported for the first time in α-gliadin gene sequence of Thinopyrum intermedium in this study, indicating that the transposable element might have contributed to the diversification of α-gliadin genes family among Triticeae genomes. The phylogenetic analyses revealed that the α-gliadin gene sequences of Dasypyrum, Australopyrum, Lophopyrum, Eremopyrum and Pseudoroengeria species have amplified several times. A search for four typical toxic epitopes for celiac disease within the Triticeae α-gliadin gene sequences showed that the α-gliadins of wild Secale, Australopyrum and Agropyron genomes lack all four epitopes, while other Triticeae species have accumulated these epitopes, suggesting that the evolution of these toxic epitopes sequences occurred during the course of speciation, domestication or polyploidization of Triticeae.