4 research outputs found
THE BASIC DIRECTIONS OF SCIENTIFIC AND TECHNICAL PROGRESS IN THE AGRICULTURE
In this article technical advance and economic indicators of agricultural enterprise are coordinated together. It is justified, that lowering equipment branch crop production and cattle breeding will result in loss productiveness and rise expense. The necessity of cost cutout determines an application of more high-performance machine and state-of-the-art technology on output of products agricultural industry. The practicability of active state support of the farmers is underlined
Mapping of genomic double-strand breaks by ligation of biotinylated oligonucleotides to forum domains: Analysis of the data obtained for human rDNA units
DNA double-strand breaks (DSBs) are associated with different physiological and pathological processes in different organisms. To understand the role of DSBs in multiple cellular mechanisms, a robust method for genome-wide mapping of chromosomal breaks at one-nucleotide resolution is required. Many years ago, we detected large DNA fragments migrating from DNA-agarose plugs in pulsed-field gels, which we named āforum domainsā [1,2]. Recently, we developed a method for genome-wide mapping of DSBs that produces these 50ā150Ā kb DNA domains using microarrays or 454 sequencing (Tchurikov et al., 2011; 2013). Now we have used Illumina sequencing to map DSBs in repetitive rDNA units in human HEK293T cells. Here we describe in detail the experimental design and bioinformatics analysis of the data deposited in the Gene Expression Omnibus with accession number GSE49302 and associated with the study published in the Journal of Molecular Cell Biology (Tchurikov et al., 2014)
Genome-wide mapping of hot spots of DNA double-strand breaks in human cells as a tool for epigenetic studies and cancer genomics
Hot spots of DNA double-strand breaks (DSBs) are associated with coordinated expression of genes in chromosomal domains (Tchurikov et al., 2011 [1]; 2013). These 50ā150-kb DNA domains (denoted āforum domainsā) can be visualized by separation of undigested chromosomal DNA in pulsed-field agarose gels (Tchurikov et al., 1988; 1992) and used for genome-wide mapping of the DSBs that produce them. Recently, we described nine hot spots of DSBs in human rDNA genes and observed that, in rDNA units, the hot spots coincide with CTCF binding sites and H3K4me3 marks (Tchurikov et al., 2014), suggesting a role for DSBs in active transcription. Here we have used Illumina sequencing to map DSBs in chromosomes of human HEK293T cells, and describe in detail the experimental design and bioinformatics analysis of the data deposited in the Gene Expression Omnibus with accession number GSE53811 and associated with the study published in DNA Research (Kravatsky et al., 2015). Our data indicate that H3K4me3 marks often coincide with hot spots of DSBs in HEK293T cells and that the mapping of these hot spots is important for cancer genomic studies