The evolution of 2 tandemly repeated sequences Spelt1 and Spelt52 was studied in Triticum species representing 2 evolutionary lineages of wheat and in Aegilops sect. Sitopsis, putative donors of their B/G genomes. Using fluorescence in situ hybridization we observed considerable polymorphisms in the hybridization patterns of Spelt1 and Spelt52 repeats between and within Triticum and Aegilops species. Between 2 and 28 subtelomeric sites of Spelt1 probe were detected in Ae. speltoidies, depending on accession. From 8 to 12 Spelt1 subtelomeric sites were observed in species of Timopheevi group (GAt genome), whereas the number of signals in emmer/aestivum accessions was significantly less (from 0 to 6). Hybridization patterns of Spelt52 in Ae. speltoides, Ae. longissima, and Ae. sharonensis were species specific. Subtelomeric sites of Spelt52 repeat were detected only in T. araraticum (T. timopheevii), and their number and chromosomal location varied between accessions. Superimposing copy number data onto our phylogenetic scheme constructed from RAPD data suggests 2 major independent amplifications of Spelt52 and 1 of Spelt1 repeats in Aegilops divergence. It is likely that the Spelt1 amplification took place in the ancient Ae. speltoides before the divergence of polyploid wheats. The Spelt52 repeat was probably amplified in the lineage of Ae. speltoides prior to divergence of the allopolyploid T. timopheevii but after the divergence of T. durum. In a separate amplification event, Spelt52 copy number expanded in the common ancestor of Ae. longissima and Ae. sharonensis.
The synthetic allotetraploid Aegilops sharonensis x Ae. umbellulata (genomic formula S(sh)U) was used to study inheritance and expression of 45S rDNA during early stages of allopolyploid formation. Using silver staining, we revealed suppression of the NORs (nucleolar organizing regions) from the S(sh) genome in response to polyploidization. Most allopolyploid plants of the S(2)-S(4) generations retained the chromosomal location of 45S rDNA typical for the parental species, except for two S(3) plants in which a deletion of the rDNA locus on one of the homologous 6S(sh) chromosomes was revealed. In addition, we found a decrease in NOR signal intensity on both 6S(sh) chromosomes in a portion of the S(3) and S(4) allopolyploid plants. As Southern hybridization showed, the allopolyploid plants demonstrated additive inheritance of parental rDNA units together with contraction of copy number of some rDNA families inherited from Ae. sharonensis. Also, we identified a new variant of amplified rDNA unit with MspAI1 restriction sites characteristic of Ae. umbellulata. These genetic alterations in the allopolyploid were associated with comparative hypomethylation of the promoter region within the Ae. umbellulata-derived rDNA units. The fast uniparental elimination of rDNA observed in the synthetic allopolyploid agrees well with patterns observed previously in natural wheat allotetraploids.
The variation of the vernalization (VRN-1) and photoperiod (PPD-1) genes offers opportunities to adjust heading time and to maximize yield in crop species. The effect of these genes on heading time was studied based on a set of 245 predominantly spring cultivars of bread wheat from the main eco-geographical regions of Europe. The genotypes were screened using previously published diagnostic molecular markers for detecting the dominant or recessive alleles of the major VRN-1 loci such as: VRN-A1, VRN-B1, VRN-D1 as well as PPD-D1. We found that 91% of spring wheat cultivars contain the photoperiod sensitive PPD-D1b allele. Photoperiod insensitive PPD-D1a allele has been found mainly in southern region of Europe. For this region the monogenic control of vernalization by VRN-B1 or VRN-D1 dominant alleles is common, whereas in the remaining part of Europe, the combination of photoperiod sensitive PPD-D1b allele with dominant VRN-A1, VRN-B1 and recessive vrn-D1 alleles represents the most frequent genotype. Also, we revealed a significantly later (5-8 days) heading of the monogenically dominant genotypes at VRN-B1 as compared to the digenic VRN-A1 VRN-B1 genotypes.
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