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5. A Spontaneous Inversion of the X Chromosome Heterochromatin Provides a Tool for Studying the Structure and Activity of the Nucleolus in Drosophila melanogaster

Author

Kolesnikova, Tatyana D., primary, Klenov, Mikhail S., additional, Nokhova, Alina R., additional, Lavrov, Sergey A., additional, Pokholkova, Galina V., additional, Schubert, Veit, additional, Maltseva, Svetlana V., additional, Cook, Kevin R., additional, Dixon, Michael J., additional, and Zhimulev, Igor F., additional

Published
2022
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9. Additional file 3 of Mechanism and functional role of the interaction between CP190 and the architectural protein Pita in Drosophila melanogaster

Author

Sabirov, Marat, Kyrchanova, Olga, Pokholkova, Galina V., Bonchuk, Artem, Klimenko, Natalia, Belova, Elena, Zhimulev, Igor F., Maksimenko, Oksana, and Georgiev, Pavel

Abstract

Additional file 3. Co-localization of Pita with other DNA-binding proteins that interact with CP190. The table shows the total number of Pita + CP190 and Pita only peaks detected in the Pitawt line. These two groups of peaks were tested for co-localization with the dCTCF, Su(Hw), ZIPIC, Ibf1, Ibf2, and Insv peaks obtained from [17, 44–47].

Published
2021
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11. Additional file 4 of Mechanism and functional role of the interaction between CP190 and the architectural protein Pita in Drosophila melanogaster

Author

Sabirov, Marat, Kyrchanova, Olga, Pokholkova, Galina V., Bonchuk, Artem, Klimenko, Natalia, Belova, Elena, Zhimulev, Igor F., Maksimenko, Oksana, and Georgiev, Pavel

Subjects
TheoryofComputation_MATHEMATICALLOGICANDFORMALLANGUAGES
Abstract

Additional file 4. Reproducibility of Chip-seq experiments according to IDR pipeline.

Published
2021
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13. The SU(VAR) 3-9/HP1 complex differentially regulates the compaction state and degree of underreplication of X chromosome pericentric heterochromatin in Drosophila melanogaster

Author

Demakova, Olga V., Pokholkova, Galina V., Kolesnikova, Tatyana D., Demakov, Sergey A., Andreyeva, Eugenia N., Belyaeva, Elena S., and Zhimulev, Igor F.

Subjects
Drosophila -- Genetic aspects, X chromosome -- Research, Nucleotide sequence -- Research, Biological sciences
Abstract

In polytene chromosomes of Drosophila melanogaster, regions of pericentric heterochromatin coalesce to form a compact chromocenter and are highly underreplicated. Focusing on study of X chromosome heterochromatin, we demonstrate that loss of either SU (VAR)3-9 histone methyltransferase activity or HP1 protein differentially affects the compaction of different pericentric regions. Using a set of inversions breaking X chromosome heterochromatin in the background of the Su(var)3-9 mutations, we show that distal heterochromatin (blocks h26-h29) is the only one within the chromocenter to form a big 'puff'-like structure. The 'puffed' heterochromatin has not only unique morphology but also very special protein composition as well: (i) it does not bind proteins specific for active chromatin and should therefore be referred to as a pseudopuff and (ii) it strongly associates with heterochromatin-specific proteins SU (VAR)3-7 and SUUR, despite the fact that HP1 and HP2 are depleted particularly from this polytene structure. The pseudopuff completes replication earlier than when it is compacted as heterochromatin, and underreplication of some DNA sequences within the pseudopuff is strongly suppressed. So, we show that pericentric heterochromatin is heterogeneous in its requirement for SU(VAR)3-9 with respect to the establishment of the condensed state, time of replication, and DNA polytenization.

Published
2007

15. Effects of Mutations in the Drosophila melanogaster Rif1 Gene on the Replication and Underreplication of Pericentromeric Heterochromatin in Salivary Gland Polytene Chromosomes

Author

Kolesnikova, Tatyana D., primary, Kolodyazhnaya, Alexandra V., additional, Pokholkova, Galina V., additional, Schubert, Veit, additional, Dovgan, Viktoria V., additional, Romanenko, Svetlana A., additional, Prokopov, Dmitry Yu., additional, and Zhimulev, Igor F., additional

Published
2020
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18. Faint gray bands in Drosophila melanogaster polytene chromosomes are formed by coding sequences of housekeeping genes

Author

Demakova, Olga V., primary, Demakov, Sergey A., additional, Boldyreva, Lidiya V., additional, Zykova, Tatyana Yu., additional, Levitsky, Victor G., additional, Semeshin, Valeriy F., additional, Pokholkova, Galina V., additional, Sidorenko, Darya S., additional, Goncharov, Fedor P., additional, Belyaeva, Elena S., additional, and Zhimulev, Igor F., additional

Published
2019
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21. Genetic Organization of Interphase Chromosome Bands and Interbands in Drosophila melanogaster

Author

Zhimulev, Igor F., primary, Zykova, Tatyana Yu., additional, Goncharov, Fyodor P., additional, Khoroshko, Varvara A., additional, Demakova, Olga V., additional, Semeshin, Valeriy F., additional, Pokholkova, Galina V., additional, Boldyreva, Lidiya V., additional, Demidova, Darya S., additional, Babenko, Vladimir N., additional, Demakov, Sergey A., additional, and Belyaeva, Elena S., additional

Published
2014
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23. Interaction between theDrosophilaheterochromatin proteins SUUR and HP1

Author

Pindyurin, Alexey V., primary, Boldyreva, Lidiya V., additional, Shloma, Victor V., additional, Kolesnikova, Tatiana D., additional, Pokholkova, Galina V., additional, Andreyeva, Evgeniya N., additional, Kozhevnikova, Elena N., additional, Ivanoschuk, Igor G., additional, Zarutskaya, Ekaterina A., additional, Demakov, Sergey A., additional, Gorchakov, Andrey A., additional, Belyaeva, Elena S., additional, and Zhimulev, Igor F., additional

Published
2008
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26. Genetic Organization of Interphase Chromosome Bands and Interbands in Drosophila melanogaster.

Author

Zhimulev, Igor F., Zykova, Tatyana Yu., Goncharov, Fyodor P., Khoroshko, Varvara A., Demakova, Olga V., Semeshin, Valeriy F., Pokholkova, Galina V., Boldyreva, Lidiya V., Demidova, Darya S., Babenko, Vladimir N., Demakov, Sergey A., and Belyaeva, Elena S.

Subjects
INTERPHASE, DROSOPHILA melanogaster, CYTOLOGY, GIANT chromosomes, CHROMATIN, RNA sequencing
Abstract

Drosophila melanogaster polytene chromosomes display specific banding pattern; the underlying genetic organization of this pattern has remained elusive for many years. In the present paper, we analyze 32 cytology-mapped polytene chromosome interbands. We estimated molecular locations of these interbands, described their molecular and genetic organization and demonstrate that polytene chromosome interbands contain the 5′ ends of housekeeping genes. As a rule, interbands display preferential “head-to-head” orientation of genes. They are enriched for “broad” class promoters characteristic of housekeeping genes and associate with open chromatin proteins and Origin Recognition Complex (ORC) components. In two regions, 10A and 100B, coding sequences of genes whose 5′-ends reside in interbands map to constantly loosely compacted, early-replicating, so-called “grey” bands. Comparison of expression patterns of genes mapping to late-replicating dense bands vs genes whose promoter regions map to interbands shows that the former are generally tissue-specific, whereas the latter are represented by ubiquitously active genes. Analysis of RNA-seq data (modENCODE-FlyBase) indicates that transcripts from interband-mapping genes are present in most tissues and cell lines studied, across most developmental stages and upon various treatment conditions. We developed a special algorithm to computationally process protein localization data generated by the modENCODE project and show that Drosophila genome has about 5700 sites that demonstrate all the features shared by the interbands cytologically mapped to date. [ABSTRACT FROM AUTHOR]

Published
2014
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27. Late Replication Domains Are Evolutionary Conserved in the Drosophila Genome.

Author

Andreyenkova, Natalya G., Kolesnikova, Tatyana D., Makunin, Igor V., Pokholkova, Galina V., Boldyreva, Lidiya V., Zykova, Tatyana Yu., Zhimulev, Igor F., and Belyaeva, Elena S.

Subjects
DROSOPHILA, INSECT genomes, INSECT evolution, INSECT conservation, INSECT chromatin, INSECT chromosomes, GENETIC regulation, INSECTS
Abstract

Drosophila chromosomes are organized into distinct domains differing in their predominant chromatin composition, replication timing and evolutionary conservation. We show on a genome-wide level that genes whose order has remained unaltered across 9 Drosophila species display late replication timing and frequently map to the regions of repressive chromatin. This observation is consistent with the existence of extensive domains of repressive chromatin that replicate extremely late and have conserved gene order in the Drosophila genome. We suggest that such repressive chromatin domains correspond to a handful of regions that complete replication at the very end of S phase. We further demonstrate that the order of genes in these regions is rarely altered in evolution. Substantial proportion of such regions significantly coincide with large synteny blocks. This indicates that there are evolutionary mechanisms maintaining the integrity of these late-replicating chromatin domains. The synteny blocks corresponding to the extremely late-replicating regions in the D. melanogaster genome consistently display two-fold lower gene density across different Drosophila species. [ABSTRACT FROM AUTHOR]

Published
2013
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28. Three distinct chromatin domains in telomere ends of polytene chromosomes in Drosophila melanogaster Tel mutants.

Author

Andreyeva, Evgenia N., Belyaeva, Elena S., Semeshin, Valerii F., Pokholkova, Galina V., and Zhimulev, Igor F.

Subjects
DNA, DROSOPHILA melanogaster, CHROMOSOMES, GENETICS, ELECTRON microscopy, TELOMERES
Abstract

The article investigates the properties of the two domains of Drosophila melanogaster telomeric DNA in salivary gland polytene chromosomes using Tel mutants. The two DNA domains are the terminal tract of retrotransposons and telomere-associated sequences (TAS). Electron microscopy analysis identifies the telomeric cap and the tract of retroelements as a reticular material, having no discernible banding pattern, whereas TAS repeats appear as faint bands.

Published
2005
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29. Interaction between the Drosophila heterochromatin proteins SUUR and HP1.

Author

Pindyurin, Alexey V., Boldyreva, Lidiya V., Shloma, Victor V., Kolesnikova, Tatiana D., Pokholkova, Galina V., Andreyeva, Evgeniya N., Kozhevnikova, Elena N., Ivanoschuk, Igor G., Zarutskaya, Ekaterina A., Demakov, Sergey A., Gorchakov, Andrey A., Belyaeva, Elena S., and Zhimulev, Igor F.

Subjects
DROSOPHILA melanogaster, GIANT chromosomes, HETEROCHROMATIN, CELL nuclei, KARYOKINESIS, METHYLTRANSFERASES
Abstract

SUUR (Suppressor of Under-Replication) protein is responsible for late replication and, as a consequence, for DNA underreplication of intercalary and pericentric heterochromatin in Drosophila melanogaster polytene chromosomes. However, the mechanism by which SUUR slows down the replication process is not clear. To identify possible partners for SUUR we performed a yeast two-hybrid screen using full-length SUUR as bait. This identified HP1, the well-studied heterochromatin protein, as a strong SUUR interactor. Furthermore, we have determined that the central region of SUUR is necessary and sufficient for interaction with the C-terminal part of HP1, which contains the hinge and chromoshadow domains. In addition, recruitment of SUUR to ectopic HP1 sites on chromosomes provides evidence for their association in vivo. Indeed, we found that the distributions of SUUR and HP1 on polytene chromosomes are interdependent: both absence and overexpression of HP1 prevent SUUR from chromosomal binding, whereas SUUR overexpression causes redistribution of HP1 to numerous sites occupied by SUUR. Finally, HP1 binds to intercalary heterochromatin when histone methyltransferase activity of SU(VAR)3-9 is increased. We propose that interaction with HP1 is crucial for the association of SUUR with chromatin. [ABSTRACT FROM AUTHOR]

Published
2008
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30. Genetic Organization of Interphase Chromosome Bands and Interbands in Drosophila melanogaster.

Author

Zhimulev, Igor F., Zykova, Tatyana Yu., Goncharov, Fyodor P., Khoroshko, Varvara A., Demakova, Olga V., Semeshin, Valeriy F., Pokholkova, Galina V., Boldyreva, Lidiya V., Demidova, Darya S., Babenko, Vladimir N., Demakov, Sergey A., and Belyaeva, Elena S.

Subjects
*INTERPHASE, *DROSOPHILA melanogaster, *CYTOLOGY, *GIANT chromosomes, *CHROMATIN, *RNA sequencing
Abstract

Drosophila melanogaster polytene chromosomes display specific banding pattern; the underlying genetic organization of this pattern has remained elusive for many years. In the present paper, we analyze 32 cytology-mapped polytene chromosome interbands. We estimated molecular locations of these interbands, described their molecular and genetic organization and demonstrate that polytene chromosome interbands contain the 5′ ends of housekeeping genes. As a rule, interbands display preferential “head-to-head” orientation of genes. They are enriched for “broad” class promoters characteristic of housekeeping genes and associate with open chromatin proteins and Origin Recognition Complex (ORC) components. In two regions, 10A and 100B, coding sequences of genes whose 5′-ends reside in interbands map to constantly loosely compacted, early-replicating, so-called “grey” bands. Comparison of expression patterns of genes mapping to late-replicating dense bands vs genes whose promoter regions map to interbands shows that the former are generally tissue-specific, whereas the latter are represented by ubiquitously active genes. Analysis of RNA-seq data (modENCODE-FlyBase) indicates that transcripts from interband-mapping genes are present in most tissues and cell lines studied, across most developmental stages and upon various treatment conditions. We developed a special algorithm to computationally process protein localization data generated by the modENCODE project and show that Drosophila genome has about 5700 sites that demonstrate all the features shared by the interbands cytologically mapped to date. [ABSTRACT FROM AUTHOR]

Published
2014
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