[Possible involvement of DNA breaks in epigenetic regulation of cell differentiation].

The review summarizes the authors' and literature data on accumulation of DNA breaks in differentiating cells. Large 50-kb free DNA fragments were observed by several research teams in non-apoptotic insect, mammal, and plant cells. More intense DNA breakage was observed during maturation of spermatides, embryo development, and differentiation of myotubes, epidermal cells, lymphocytes, and neutrophils. In general, accumulation of DNA breaks in differentiating cells cannot be attributed to a decrease in the DNA repair efficiency. Poly(ADP)ribose synthesis often follows the DNA breakage in differentiating cells. We hypothesize that DNA fragmentation is an epigenetic tool for regulating the differentiation process. Scarce data on localization of the differentiation-associated DNA breaks indicate their preferable accumulation in specific DNA sequences including the nuclear matrix attachment sites. he same sites are degraded at early stages of apoptosis. Recent data on non-apoptotic function of caspases provide more evidence for possible existence of a DNA breakage mechanism in differentiating cells, resembling the initial stage of apoptosis. Excision of methylated cytosine and recombination are other possible explanations of the phenomenon. Elucidation of mechanisms of differentiation-induced DNA breaks appears to be a prospective research direction.

Novel haplotype description and structural background of the eventual functional significance of the barley beta-amylase gene intron III rearrangements.

To extend the knowledge on the haplotype variability of the Bmy1 gene, region of the intron III was sequenced in a set of 20 Latvian accessions and Danish variety Maja, the data were compared to the previously reported allelic variants of the structural gene. Taking into account the polymorphisms of 59 loci and the microsatellite (MS) motif, 11 Latvian varieties turned out to have haplotype similar to cultivar Adorra, 1 - to Haruna Nijo, and 8 - to the newly described Abava Bmy1 intron III haplotype. High level of polymorphisms of (TG)(m) as well as (G)(n) component of MS was revealed for all the haplotypes studied. We conclude that the MS motif rather than the MS size length polymorphism correlates with mutations in the coding region of the beta-amylase gene. Five graphical haplotype-specific intron III structures were constructed on the basis of the co-localization of the transcription factor binding sites (TFBSs), remnants of the transposable elements, and intron III polymorphic loci. Inter- and intrahaplotype variability was analyzed on the eventual functional significance of the Bmy1 intron III rearrangements. Novel data on the intron III nucleotide sequences of the Bmy1 gene were deposited in the GenBank (http://www.ncbi.nlm.nih.gov/) under accession numbers DQ316895-DQ316905.

Development and genetic mapping of 127 new microsatellite markers in barley.

To enhance the marker density of existing genetic maps of barley ( Hordeum vulgare L.), a new set of microsatellite markers containing dinucleotide motifs was developed from genomic clones. Out of 254 primer pairs tested, a total of 167 primer pairs were classifed as functional in a panel of six barley cultivars and three H. spontaneum accessions, and of those, 127 primer pairs resulting in 133 loci were either mapped or located onto chromosomes. The polymorphism information content (PIC) ranged from 0.05 to 0.94 with an average of 0.60. The number of alleles per locus varied from 1 to 9. On average, 3.9 alleles per primer pair were observed. The RFLP frameworks of two previously published linkage maps were used to locate a total of 115 new microsatellite loci on at least one mapping population. The chromosomal assignment of 48 mapped loci was corroborated on a set of wheat-barley chromosome addition lines; 18 additional loci which were not polymorphic in the mapping populations were assigned to chromosomes by this method. The microsatellites were located on all seven linkage groups with four significant clusters in the centromeric regions of 2H, 3H, 6H and 7H. These newly developed microsatellites improve the density of existing barley microsatellite maps and can be used in genetic studies and breeding research.

Inheritance of microsatellite alleles in pedigrees of Latvian barley varieties and related European ancestors.

Genetic diversity and inheritance of 65 microsatellite (SSR) loci were studied in a set of 37 barley varieties involved in the pedigrees of seven Latvian barley varieties: Abava, Agra, Balga, Imula, Linga, Priekulu 1 and Stendes. Cluster analysis divided all the varieties into two large groups according to their geographic distribution. Moravian, Swedish and Danish varieties clustered separately from varieties from Norway and Finland. The pattern of subgroups of both European and Latvian varieties was in accordance with their pedigree information. Graphical genotypes of microsatellite alleles of all seven barley chromosomes were determined for all the 37 varieties studied. Parental inheritance and transmission of microsatellite alleles through the generations of the pedigrees were analysed. The results confirmed the importance and informative value of microsatellite markers for genetic studies in barley and their utility for barley breeding and other applications in fundamental and applied barley genetics.

[Structure of genomic domains of mammalian and avian globin genes]. / Struktura genomnykh domenov genov globinov mlekopitaiushchikh i ptits.

The data on the genomic domain structure of both mammalian and avian alpha- and beta-globin genes are reviewed. The specific features of chromatin, DNA binding to the nuclear matrix, and domain-specific transcripts are discussed. In humans, the beta-globin gene domain is located in the GC-depleted isochore and contains multiple nuclear matrix attachment regions. The locus is controlled by six chromatin regions hypersensitive to DNase located far upstream of the first structural gene. Some of these regions display enhancer activity to support normal transcription level in the domain. Other mammalian beta-globin domains are similarly organized. The avian beta-globin genes are specifically arranged and their expression is less dependent from the locus control region. The human alpha-globin gene is located in the GC-rich isochore. The nuclear matrix attachment sites are not identified in this gene. An analog of the locus control region is located 40 kb upstream of the zeta-globin gene. The avian alpha-globin gene domains contain numerous nuclear matrix attachment regions. In these domains, an element located far upstream the genes regulates positive rather than negative transcription. An unidentified housekeeping gene as well as some other transcripts not encoding the structural globin genes is transcribed in the direction opposite to that of the globin genes in both mammalian and avian domains.