Tethering of CHROMATOR and dCTCF proteins results in decompaction of condensed bands in the Drosophila melanogaster polytene chromosomes but does not affect their transcription and replication timing.

Instulator proteins are central to domain organization and gene regulation in the genome. We used ectopic tethering of CHROMATOR (CHRIZ/CHRO) and dCTCF to pre-defined regions of the genome to dissect the influence of these proteins on local chromatin organization, to analyze their interaction with other key chromatin proteins and to evaluate the effects on transcription and replication. Specifically, using UAS-GAL4DBD system, CHRO and dCTCF were artificially recruited into highly compacted polytene chromosome bands that share the features of silent chromatin type known as intercalary heterochromatin (IH).

ECTOPIC TETHERING OF THE CHROMATOR PROTEIN IN UASDBD(GAL4) SYSTEM AS APPROACH FOR STUDYING OF THE INSULATOR PROTEINS IN DROSOPHILA MELANOGASTER POLYTENE CHROMOSOMES.

Chromatin insulator proteins are one of the major components that determine the domain organization of the genome. According to the latest data, they can mark the boundaries of topological domains and prevent the spread of silent chromatin to adjacent areas. One approach to the analysis of the actions of these proteins is to use the ectopic involvement in the UAS>DBD(GAL4).

[Late-replicating regions in salivary gland polytene chromosomes of Drosophila melanogaster].

About 240 specific regions that are replicated at the very end of the S-phase have been identified in D. melanogaster polytene chromosomes. These regions have a repressive chromatine state, low gene density, long intergenic distances and are enriched in tissue specific genes.

[Molecular combing method in the research of DNA replication parameters in isolated organs of Drosophyla melanogaster].

Methods of physical DNA mapping and direct visualization of replication and transcription in specific regions of genome play crucial role in the researches of structural and functional organization of eukaryotic genomes. Since DNA strands in the cells are organized into high-fold structure and present as highly compacted chromosomes, the majority of these methods have lower resolution at chromosomal level. One of the approaches to enhance the resolution and mapping accuracy is the method of molecular combing.

[Intercalary heterochromatin in the genome of Drosophila].

The modern concept of intercalary heterochromatin as polytene chromosome regions exhibiting a number of specific characteristics is formulated. DNA constituting these regions is replicated late in the S period; therefore, some strands of polytene chromosomes are underrepresented; i.e.