[Insulator Protein CP190 Regulates Expression of Spermatocyte Differentiation Genes in Drosophila melanogaster Male Germline].

CP190 protein is one of the key components of Drosophila insulator complexes, and its study is important for understanding the mechanisms of gene regulation during cell differentiation. However, Cp190 mutants die before reaching adulthood, which significantly complicates the study of its functions in imago. To overcome this problem and to investigate the regulatory effects of CP190 in adult tissues development, we have designed a conditional rescue system for Cp190 mutants. Using Cre/loxP-mediated recombination, the rescue construct containing Cp190 coding sequence is effectively eliminated specifically in spermatocytes, allowing us to study the effect of the mutation in male germ cells. Using high-throughput transcriptome analysis we determined the function of CP190 on gene expression in germline cells. Cp190 mutation was found to have opposite effects on tissue-specific genes, which expression is repressed by CP190, and housekeeping genes, that require CP190 for activation. Mutation of Cp190 also promoted expression of a set of spermatocyte differentiation genes that are regulated by tMAC transcriptional complex. Our results indicate that the main function of CP190 in the process of spermatogenesis is the coordination of interactions between differentiation genes and their specific transcriptional activators.

[A genetic system for somatic and germinal lineage tracing in the Drosophila melanogaster gonads].

Significant progress in the developmental biology of Drosophila is largely due to the improvement of methods of genetic manipulation and, in particular, development of ways to create mosaic organisms. The main characteristic of the mosaic organisms is the presence of genetically different populations of cells. For example, some tissues express a transgenic reporter gene that is absent in other cells of the body. This principle is used in a variety of the methods with the common name lineage tracing. The essence of these approaches is to perform the targeted changes in the genetic apparatus of progenitor cells that give rise to cell lines or organs and tissues. Genetic modification in progenitor cells, such as the ability to express a fluorescent protein, will be inherited by the next cell generations, and, as a result, the entire cell line or tissue will have a tag, which distinguishes it from the rest of the body. The lineage tracing methods allow tracking the cell generations, studying the cell proliferation process, tracing their origin and investigating the function of genes of interest in the development of a single tissue or organ. We have designed an approach to selectively label germ line or somatic cells in the gonads of Drosophila.

[Contribution of the SuUR gene to the organization of epigenetically repressed regions of Drosophila melanogaster chromosomes].

A significant portion of a eukaryotic genome is silent (epigenetically repressed). In Drosophila melanogaster, this portion includes mainly regions of pericentric and intercalary heterochromatin and euchromatin regions subject to position-effect variegation. Detailed study of the organization of intercalary heterochromatin regions of Drosophila melanogaster polytene chromosomes started from the discovery of the SuUR gene (Suppressor of UnderReplication). The ability of the SuUR mutation to suppress underreplication in intercalary heterochromatin regions was used for molecular tagging of these regions. We showed that underreplicated intercalary heterochromatin regions contained silent unique genes and retained the features of late replication and transcriptionally inactive chromatin state in various cell types. Over 50% of these regions contain unique genes clustered on the base of coordinated expression. The origin of clusters and putative mechanisms of their gene expression are discussed. Data on the SuUR gene, its expression, and effect on polytene chromosome structure and replication are summarized.

The Drosophila dosage compensation complex binds to polytene chromosomes independently of developmental changes in transcription.

In Drosophila, the dosage compensation complex (DCC) mediates upregulation of transcription from the single male X chromosome. Despite coating the polytene male X, the DCC pattern looks discontinuous and probably reflects DCC dynamic associations with genes active at a given moment of development in a salivary gland. To test this hypothesis, we compared binding patterns of the DCC and of the elongating form of RNA polymerase II (PolIIo). We found that, unlike PolIIo, the DCC demonstrates a stable banded pattern throughout larval development and escapes binding to a subset of transcriptionally active areas, including developmental puffs. Moreover, these proteins are not completely colocalized at the electron microscopy level. These data combined imply that simple recognition of PolII machinery or of general features of active chromatin is either insufficient or not involved in DCC recruitment to its targets. We propose that DCC-mediated site-specific upregulation of transcription is not the fate of all active X-linked genes in males. Additionally, we found that DCC subunit MLE associates dynamically with developmental and heat-shock-induced puffs and, surprisingly, with those developing within DCC-devoid regions of the male X, thus resembling the PolIIo pattern. These data imply that, independently of other MSL proteins, the RNA-helicase MLE might participate in general transcriptional regulation or RNA processing.

[Use of immunogold labelling technique for immunoelectron microscope localization of proteins in Drosophila polytene chromosomes]. / Immunoélektronno-mikroskopicheskaia lokalizatsiia belkov na politennykh khromosomakh drozofily s pomoshch'iu immunnoi tekhniki mecheniia zolotom.

Using gold labeled antibodies, we developed and tested an immunoelectron microscope (IEM) method for detection of protein localization in Drosophila melanogaster polytene chromosomes. This method is based on procedures widely used for indirect immunofluorescent (IF) staining of salivary gland polytene chromosome squashes. The application of IEM was evaluated by using specific antibodies against proteins earlier localized in both decondensed (interbands and puffs) and compact (bands) regions of polytene chromosomes. In all the experiments, IEM and IF images for homologous chromosome regions were compared. When applied to regions of loose structures, IEM enabled us to localize, with high precision, signals in fine bands, interbands and puffs. There was a good correspondence between immunogold EM and IF data. However, there was no correspondence for dense bands: gold particles were distributed at their boundaries, while the entire bands showed bright fluorescence. This discrepancy probably resulted from a poor penetration of antibodies conjugated to gold particles in the tightly packaged structures. From the results obtained it may by concluded that the IEM method is advantageous for studying the fine protein topography of loose decompacted regions of polytene chromosomes. And this must be taken into consideration when protein localization in polytene chromosomes is performed.

Formation and morphology of dark puffs in Drosophila melanogaster polytene chromosomes.

The formation of unusual dark puffs in Drosophila melanogaster polytene chromosomes has been studied by electron microscopic (EM) analysis. Fly stocks transformed by the P[ry; Prat:bw] and P[hs-BRC-z1] constructs were used. In the former the bw gene is under the promoter of a housekeeping gene, Prat; in the latter the Br-C locus, mapping to the dark puff 2B, is under the promoter of a heat-shock gene, hsp70. Inserted into region 65A of the 3L chromosome, the Prat:bw copies give rise to structures which are morphologically reminiscent of the so-called "dark" puffs. In contrast, insertion of P[hs-BRC-z1] into region 99B of the 3R chromosome causes a regular "light" puff of form. Comparative analysis of the dark puffs--both transgenic and natural--suggests that there might be at least two mechanisms underlying their formation. One is a local incomplete decondensation of activated bands, characteristic of the so-called small puffs. The other is the formation of ectopic-looking contacts between the bands adjacent to the puffing zone. Transposition of the DNA, from which such a puff develops, causes a regular light puff to form at the new location. Heterochromatic regions do not appear to be directly involved in puffing.

[Modeling dark puffs using P-transposons in Drosophila melanogaster polytene chromosomes]. / Modelirovanie temnykh pufov s pomoshch'iu P-transpozonov v politennykh khromosomakh Drosophila melanogaster.

Modeling of morphologically unusual "dark" puffs was conducted using Drosophila melanogaster strains transformed by construct P[ry; Prat:bw], in which gene brown is controlled by the promoter of the housekeeping gene Prat. In polytene chromosomes, insertions of this type were shown to form structures that are morphologically similar to small puffs. By contrast, the Broad-Complex (Br-C) locus, which normally produce a dark puff in the 2B region of the X chromosome, forms a typical light-colored puffs when transferred to the 99B region of chromosome 3R using P[hs-BRC-z1]. A comparison of transposon-induced puffs with those appearing during normal development indicates that these puff types are formed via two different mechanisms. One mechanism involves decompaction of weakly transcribed bands and is characteristic of small puffs. The other mechanism is associated with contacts between bands adjacent to the puffing zone, which leads to mixing of inactive condensed and actively transcribed decondensed material and forming of large dark puffs.

[Electron microscopic in situ hybridization of dUTP-digoxigenin labeled probes with polytene chromosomes of Drosophila melanogaster]. / Elektronno-mikroskopicheskaia gibridizatsiia i situ prob, mechennykh dUTP-digoksigenninom, s politennymi khromosomami Drosophila melanogaster.

Using DNA probes labeled with digoxygenin-11-dUTP, a simplified method of electron microscopic (EM) in situ hybridization was developed for standard squashes of Drosophila melanogaster polytene chromosomes. The developed method is efficient and reproducible: its high resolution and specificity was shown for the transformed strain 148, in which the insertion was localized by EM as a new thin band. The method was applied for fine mapping of the developmentally regulated complex gene, muscleblind (mbl), which was shown to cover the 54B1-2 large band and the adjacent interbands in 2R polytene chromosome.

Electron microscopic in situ hybridization of digoxigenin-dUTP-labelled DNA probes with Drosophila melanogaster polytene chromosomes.

We report a simplified method of electron microscopic (EM) in situ hybridization for standard squashes of Drosophila melanogaster polytene chromosomes using digoxigenin-11-dUTP labelled DNA probes. The method is efficient and reproducible: its high resolution and specificity were demonstrated for the transformed strain 148, in which the insertion was localized precisely as a new thin band both by conventional EM and according to our method. In addition, the method was applied to the fine mapping of the developmentally regulated gene muscle-blind (mbl). On the one hand, mbl was shown to cover the 54B1-2 large band and the adjacent interbands in the 2R polytene chromosome. On the other hand, the use of distantly located DNA probes in the mbl gene allowed us to orientate the transcription unit in the chromosome.