Karyotype reconstruction modulates the sensitivity of barley genome to radiation-induced DNA and chromosomal damage.

The potential of cytologically reconstructed barley line D-2946 to cope with the major lesions that hamper genome integrity, namely DNA single- and double-strand breaks was investigated. Strand breaks induced by γ-rays and Li ions were assessed by neutral and alkaline comet assay. Repair capacity after bleomycin treatment was evaluated by agarose gel electrophoresis under neutral and alkaline conditions. Frequencies of radiation-induced chromosome aberrations were also determined. Results indicate that radiation-mediated constitutive rearrangement of the chromosome complement has led to a substantial modulation of the sensitivity of barley genome towards DNA strand breaks, produced by ionising radiation, Li ion implantation and bleomycin in an agent-specific manner, as well as of the clastogenic response to γ-rays. Based on these findings, reconstructed barley karyotype D-2946 can be considered a candidate radio-sensitive line with reduced ability to maintain genome integrity with respect to both DNA and chromosomal damage.

DNA methylation pattern in a barley reconstructed karyotype with deleted ribosomal gene cluster of chromosome 6H.

A reconstructed barley karyotype (T-35) was utilised to study the influence of chromosomal rearrangements on the DNA methylation pattern at chromosome level. Data obtained were also compared with the distribution of Giemsa N-bands and high gene density regions along the individual chromosomes that have been previously described. In comparison to the control karyotype (T-1586), the DNA methylation pattern was found to vary not only in the reconstructed chromosomes but also in the other chromosomes of the complement. Significant remodelling process of methylation pattern was found also in the residual nucleolus organiser regions (NOR) on chromosome 5H as a consequence of deletion comprising the whole NOR of chromosome 6H in T-35. Moreover, differences between corresponding segments of the homologues with respect to some other chromosome locations were also observed. Repositioning of genomic DNA methylation along the metaphase chromosomes following chromosomal reconstruction in barley seems to be essential to ensure correct chromatin organisation and function.

Efficient repair of bleomycin-induced double-strand breaks in barley ribosomal genes.

Ability of barley ribosomal genes to cope with damage produced in vivo by the radiomimetic agent bleomycin was investigated. Repair kinetics of bleomycin-induced double-strand breaks in ribosomal and total genomic DNA was compared. Induction and repair of double-strand breaks in defined regions of the ribosomal genes was also analyzed. Preferential sensitivity of barley linker DNA towards bleomycin treatment in vivo was established. Relatively higher yield of initially induced double-strand breaks in genomic DNA in comparison to ribosomal DNA was also found. Fragments containing intergenic spacers of barley rRNA genes displayed higher sensitivity to bleomycin than the coding sequences. No heterogeneity in the repair of DSB between transcribed and non-transcribed regions of ribosomal genes was detected. Data indicate that DSB repair in barley rDNA, although more efficient than in genomic DNA, does not correlate with the activity of nucleolus organizer regions.