Andrey B. Shcherban

The impact of Ty3-gypsy group LTR retrotransposons Fatima on B-genome specificity of polyploid wheats

BackgroundTransposable elements (TEs) are a rapidly evolving fraction of the eukaryotic genomes and the main contributors to genome plasticity and divergence. Recently, occupation of the A- and D-genomes of allopolyploid wheat by specific TE families was demonstrated. Here, we investigated the impact of the well-represented family of gypsy LTR-retrotransposons, Fatima, on B-genome divergence of allopolyploid wheat using the fluorescent in situ hybridisation (FISH) method and phylogenetic analysis.ResultsFISH analysis of a BAC clone (BAC_2383A24) initially screened with Spelt1 repeats demonstrated its predominant localisation to chromosomes of the B-genome and its putative diploid progenitor Aegilops speltoides in hexaploid (genomic formula, BBAADD) and tetraploid (genomic formula, BBAA) wheats as well as their diploid progenitors. Analysis of the complete BAC_2383A24 nucleotide sequence (113 605 bp) demonstrated that it contains 55.6% TEs, 0.9% subtelomeric tandem repeats (Spelt1), and five genes. LTR retrotransposons are predominant, representing 50.7% of the total nucleotide sequence. Three elements of the gypsy LTR retrotransposon family Fatima make up 47.2% of all the LTR retrotransposons in this BAC. In situ hybridisation of the Fatima_2383A24-3 subclone suggests that individual representatives of the Fatima family contribute to the majority of the B-genome specific FISH pattern for BAC_2383A24. Phylogenetic analysis of various Fatima elements available from databases in combination with the data on their insertion dates demonstrated that the Fatima elements fall into several groups. One of these groups, containing Fatima_2383A24-3, is more specific to the B-genome and proliferated around 0.5-2.5 MYA, prior to allopolyploid wheat formation.ConclusionThe B-genome specificity of the gypsy-like Fatima, as determined by FISH, is explained to a great degree by the appearance of a genome-specific element within this family for Ae. speltoides. Moreover, its proliferation mainly occurred in this diploid species before it entered into allopolyploidy.Most likely, this scenario of emergence and proliferation of the genome-specific variants of retroelements, mainly in the diploid species, is characteristic of the evolution of all three genomes of hexaploid wheat.

Genetic and epigenetic changes of rDNA in a synthetic allotetraploid, Aegilops sharonensis × Ae. umbellulata

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.

Isolation and sequence analysis of the wheat B genome subtelomeric DNA

BackgroundTelomeric and subtelomeric regions are essential for genome stability and regular chromosome replication. In this work, we have characterized the wheat BAC (bacterial artificial chromosome) clones containing Spelt1 and Spelt52 sequences, which belong to the subtelomeric repeats of the B/G genomes of wheats and Aegilops species from the section Sitopsis.ResultsThe BAC library from Triticum aestivum cv. Renan was screened using Spelt1 and Spelt52 as probes. Nine positive clones were isolated; of them, clone 2050O8 was localized mainly to the distal parts of wheat chromosomes by in situ hybridization. The distribution of the other clones indicated the presence of different types of repetitive sequences in BACs. Use of different approaches allowed us to prove that seven of the nine isolated clones belonged to the subtelomeric chromosomal regions. Clone 2050O8 was sequenced and its sequence of 119 737 bp was annotated. It is composed of 33% transposable elements (TEs), 8.2% Spelt52 (namely, the subfamily Spelt52.2) and five non-TE-related genes. DNA transposons are predominant, making up 24.6% of the entire BAC clone, whereas retroelements account for 8.4% of the clone length. The full-length CACTA transposon Caspar covers 11 666 bp, encoding a transposase and CTG-2 proteins, and this transposon accounts for 40% of the DNA transposons. The in situ hybridization data for 2050O8 derived subclones in combination with the BLAST search against wheat mapped ESTs (expressed sequence tags) suggest that clone 2050O8 is located in the terminal bin 4BL-10 (0.95-1.0). Additionally, four of the predicted 2050O8 genes showed significant homology to four putative orthologous rice genes in the distal part of rice chromosome 3S and confirm the synteny to wheat 4BL.ConclusionSatellite DNA sequences from the subtelomeric regions of diploid wheat progenitor can be used for selecting the BAC clones from the corresponding regions of hexaploid wheat chromosomes. It has been demonstrated for the first time that Spelt52 sequences were involved in the evolution of terminal regions of common wheat chromosomes. Our research provides new insights into the microcollinearity in the terminal regions of wheat chromosomes 4BL and rice chromosome 3S.

Analysis of 5S rDNA changes in synthetic allopolyploids Triticum × Aegilops

Changes of 5S rDNA at the early stage of allopolyploidization were investigated in three synthetic allopolyploids: Aegilops sharonensis × Ae. umbellulata (2n = 28), Triticum urartu × Ae. tauschii (2n = 28), and T. dicoccoides × Ae. tauschii (2n = 42). Fluorescent in situ hybridization (FISH) revealed quantitative changes affecting separate loci of one of the parental genomes in S3 plants of each hybrid combination. Southern hybridization with genomic DNA of the allopolyploid T. urartu × Ae. tauschii (TMU38 × TQ27) revealed a lower intensity of signals from Ae. tauschii fragments compared with those derived from T. urartu. This confirmed the signal reduction revealed for chromosome 1D of this hybrid by FISH. Neither Southern hybridization nor PCR testing of 5–15 plants of the S2-S3 generations revealed an appearance of new 5S rDNA fragments or a complete disappearance of parental fragments from the allopolyploids under study. No changes were found by aligning nine 5S rDNA sequences of the allopolyploid TMU38 × TQ27 with corresponding sequences of the parental species. The similarity between one of the synthetic allopolyploids examined and a natural allopolyploid with the same genome composition points to an early formation of the 5S rDNA organization unique for each allopolyploid.

Intraspecific divergence in wheats of the Timopheevi group as revealed by in situ hybridization with tandem repeats of the Spelt1 and Spelt52 families

Fluorescent in situ hybridization (FISH) was used to study the distribution of the Spelt1 and Spelt52 repetitive DNA sequences on chromosomes of ten accessions representing three polyploid wheat species of the Timopheevi group: Triticum araraticum (7), T. timopheevii (2), and T. kiharae (1). Sequences of both families were found mostly in the subtelomeric chromosome regions of the G genome. The total number of Spelt1 sites varied from 8 to 14 in the karyotypes of the species under study; their number, location, and size differed among the seven T. araraticum accessions and were the same in the two T. timopheevii accessions and T. kiharae, an amphidiploid T. timopheevii-Aegilops tauschii hybrid. The Spelt52 tandem repeat was detected in the subtelomeric regions of chromosomes 1-4; its sites did not coincide with the Spelt1 sites. The chromosome distribution and signal intensity of the Spelt52 repeats varied in T. araraticum and were the same in T. timopheevii and T. kiharae. The chromosome distributions of the Spelt1 and Spelt52 repeats were compared for the polyploid wheats of the Timopheevi group and diploid Ae. speltoides, a putative donor of the G genome. The comparison revealed a decrease in hybridization level: both the number of sites per genome and the size of sites were lower. The decrease was assumed to result from repeat elimination during polyploidization and subsequent evolution of wheat and from the founder effect, since the origin of Timopheevi wheats might involve the genotype of Ae. speltoides, which is highly polymorphic for the distribution of Spelt1 and Spelt52 sequences and is similar in the chromosome location of the repeats to modern wheat.

Impact of Ty3/Gypsy group retrotransposon Lila on the D-Genome specificity of common wheat Triticum aestivum L.

An analysis of the primary structure of BAC clone 112D20 T. aestivum, that contains D-genome specific Ty3-Gypsy-retrotransposon Lila is presented. PCR analysis of nulli-tetrasomic and deletion lines of T. aestivum allowed to localize this BAC clone in the distal region of the long arm of chromosome 5D. Characteristic feature of BAC clone 112D20 is a high concentration of Ty3-Gypsy-retrotransposons (61.7%), and low content of the genes (1.2%). Only a single open reading frame was revealed homologous to an unknown gene of Ae. tauschii. Specific to the D-genome Ty3-Gypsy-retrotransposon Lila in the BAC clone 112D20 is 14 kb in length and contains unequal in size long terminal repeats. The data of in situ hybridization and PCR analysis of different Triticeae species suggest that this retroelement was amplified within the ancestral species of Ae. tauschii, the donor D-genome. The suggested time of amplification based on estimation of insertion time of Lila 112D20 is 1.7 million years, which corresponds to the formation of the first allopolyploid forms of wheat. Based on comparison with the previously obtained data, it is concluded that the amplification of retroelements specific to each genome of wheat took place during formation of the diploid progenitors of these genomes.

Dataset of the HOX1 gene sequences of the wheat polyploids and their diploid relatives

The TaHOX-1 gene of common wheat Triticum aestivum L. (BAD-genome) encodes transcription factor (HD-Zip I) which is characterized by the presence of a DNA-binding homeodomain (HD) with an adjacent Leucine zipper (LZ) motif. This gene can play a role in adapting plant to a variety of abiotic stresses, such as drought, cold, salinity etc., which strongly affect wheat production. However, its both functional role in stress resistance and divergence during wheat evolution has not yet been elucidated. This data in brief article is associated with the research paper “Structural and functional divergence of homoeologous copies of the TaHOX-1 gene in polyploid wheats and their diploid ancestors”. The data set represents a recent survey of the primary HOX-1 gene sequences isolated from the first wheat allotetraploids (BA-genome) and their corresponding Triticum and Aegilops diploid relatives. Specifically, we provide detailed information about the HOX-1 nucleotide sequences of the promoter region and both nucleotide and amino acid sequences of the gene. The sequencing data used here is available at DDBJ/EMBL/GenBank under the accession numbers MG000630-MG000698.

Genomic changes at early stages of formation of allopolyploid Aegilops longissima × Triticum urartu

Using the model of synthetic allopolyploid Aegilops longissima TL05 × Triticum urartu TMU06 of the first generation, the degree and character of changes in subtelomeric, microsatellite and random amplified DNA sequences (RAPD) on early stage of polyploidization was estimated. Study of genome changes was performed by comparing PCR fragments of the allopolyploid and its parental forms. For analysis of subtelomeric DNA, we used 66 pairs of primers composed of 11 singular primers designed for these chromosomal regions sequences of cereals. RAPD analysis was performed with usage of 38 primers, in microsatellite (SSR) analysis 23 primer pairs were used. RAPD analysis appeared to be a more effective PCR-based method to identify genome changes. Absence of some RAPD fragments typical for parental genome in allopolyploid TL05 × TMU06 was shown using 13 primers of 38 (34%), and with usage of subtelomeric primers the changes in PCR fragments were shown only for one of 66 pairs of primers (1.5%). SSR loci were stable during the polyploidization process. Subsequent analysis of PCR fragments absent in the synthetic allopolyploid showed that high level of genome changes in RAPD analysis is probably connected with more effective ability of this method to reveal point mutations. Some data was found suggesting that not all genome changes observed in experimentally synthesized allopolyploids of the first generation are consequences of coadaptation of few genomes in one nucleus.