[Position Effect Variegation: Role of the Local Chromatin Context in Gene Expression Regulation].

Position effect variegation (PEV) is a phenomenon wherein the expression level of a gene strongly depends on its genomic position. PEV can be observed when a gene is moved via a chromosome rearrangement or identical genetic constructs are inserted into different regions of the genome. The eukaryotic genome has a domain organization, and gene activity within a domain depends not only on the nucleotide sequence of a gene, but also on the state of surrounding chromatin, thus being regulated epigenetically. Chromatin is a complex of DNA, RNA, and associated structural and regulatory proteins. The epigenetic status of chromatin depends on the replication time of a given genomic region, particular regulatory DNA motifs, and contacts with the inner nuclear envelope (lamina) and other chromosome regions (topologically associated domains). PEV results from the changes in the epigenetic state of a gene and provides a unique tool to study the molecular and biochemical processes that underlie the establishment and switching of epigenetic states. Understanding the molecular mechanisms of PEV in human is of clinical importance, in particular, for the detection and treatment of retroviral infections because the local chromatin state may determine the latent/active state transition of an infection, such as HIV. In addition, a large number of human neurodegenerative diseases are caused by epigenetic gene inactivation due to expansion of short repeats. Finally, to apply gene therapy methods, it is important to develop approaches that ensure a necessary level of transgene expression with sufficient accuracy.

Drosophila polytene chromosome bands formed by gene introns.

Genetic organization of bands and interbands in polytene chromosomes has long remained a puzzle for geneticists. It has been recently demonstrated that interbands typically correspond to the 5'-ends of house-keeping genes, whereas adjacent loose bands tend to be composed of coding sequences of the genes. In the present work, we made one important step further and mapped two large introns of ubiquitously active genes on the polytene chromosome map. We show that alternative promoter regions of these genes map to interbands, whereas introns and coding sequences found between those promoters correspond to loose grey bands. Thus, a gene having its long intron "sandwiched" between to alternative promoters and a common coding sequence may occupy two interbands and one band in the context of polytene chromosomes. Loose, partially decompacted bands appear to host large introns.

CHARACTERISTIC OF THE CHROMATIN TYPE CORRESPONDING TO THIN «GREY¼ BANDS IN POLYTHENE CHROMOSOMES OF DROSOPHILA MELANOGASTER.

Recently, we developed a bioinformatic algorithm dividing drosophila genome into 4 types of chromatin which differ in protein composition. This allows us to propose a model of structural and functional organization of interphase chromosomes which postulates an existence of correlation between the chromatin types and morphological structures of polytene chromosomes. So, constantly and everywhere open chromatin type named «aquamarine¼ is characteristic of interbands, while the combinations of the other three types («lazurite¼, «malachite¼ and «ruby¼) form the bands. In this study, we characterized protein composition, genetic organization and morphological features of 39 «lazurite¼-chromatin regions in polytene chromosomes. We found out that «lazurite¼-chromatin usually form thin «grey¼ bands and more rarely ­ boundary portions of large bands. This type of chromatin contains coding parts and 3R-ends of genes and is enriched with proteins and histone modifications associated with active transcription at the stage of elongation. The expression patterns of these genes differ greatly depending on the type of chromatin in their 5R-regions.

[Chromomeric organization of interphase chromosomes in Drosophila melanogaster].

As a result of treatment of bioinformatic data on the genome localization of structural proteins, histone modifications, DNase-hypersensitive regions, replication origins (taken from modENCODE) and their cytological localization to polytene chromosome structures, it is shown here that two types of interphase chromosomes -polytene chromosomes from salivary glands and from mitotically dividing cells cultures - demonstrate identical pictures of interband/band, i. e. the same localization and length on physical map and the same sets of proteins. In the interbands of both chromosome types we find the proteins that control initiation of transcription (RNA-polymerase II, transcription factors), replication (ORC2) as well as proteins modifying nucleosome structure (WDS, NURF) and proteins of insulators (BEAF). The nucleosome density and H1 histone concentration in the interbands are depleted; localization of DNase-hypersensitive regions corresponds strictly to the interbands. So, we conclude that both polytene and cell line interphase chromosomes are arranged according to general principle and polytene chromosomes represent precise model of interphase chromosomes. The interbands play a critical role in the initiation of transcription and replication. The interbands of interphase chromosomes are the sites of 5' parts of genes, while the 3' gene ends are located in the adjacent bands. The constancy of interbands decondensation results in the conclusion that the "interbands" genes are constantly active, i. e. they contain "house-keeping" genes. The large late replicating bands contain genes that do not have direct contact to the adjoining interbands are usually polygenic and contain tissue-specific genes.

[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. In polytene chromosomes, about a quarter of these regions have no enough time to complete replication. As a result, underreplication zones represented by fewer DNA copy number, appear. We studied 60 chromosome regions that demonstrated the most pronounced under-replication. By comparing the location of these regions on a molecular map with syntenic blocks found earlier for Drosophila species by von Grotthuss et al., 2010, we have shown that across the genus Drosophila, these regions tend to have conserved gene order. This forces us to assume the existence of evolutionary mechanisms aimed at maintaining the integrity of these regions.

[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., they are underreplicated. Late-replicating regions account for about 7% of the genome; genes are located there in clusters of as many as 40. In general, the gene density in the clusters is substantially lower than in the main part of the genome. Late-replicating regions have an inactivating capacity: genes incorporated into these regions as parts of transposons are inactivated with a higher probability. These regions contain a specific protein SUUR affecting the rate of replication completion.

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.

Effect of the Suppressor of Underreplication (SuUR) gene on position-effect variegation silencing in Drosophila melanogaster.

It has been previously shown that the SuUR gene encodes a protein located in intercalary and pericentromeric heterochromatin in Drosophila melanogaster polytene chromosomes. The SuUR mutation suppresses the formation of ectopic contacts and DNA underreplication in polytene chromosomes; SuUR+ in extra doses enhances the expression of these characters. This study demonstrates that heterochromatin-dependent PEV silencing is also influenced by SuUR. The SuUR protein localizes to chromosome regions compacted as a result of PEV; the SuUR mutation suppresses DNA underreplication arising in regions of polytene chromosomes undergoing PEV. The SuUR mutation also suppresses variegation of both adult morphological characters and chromatin compaction observed in rearranged chromosomes. In contrast, SuUR+ in extra doses and its overexpression enhance variegation. Thus, SuUR affects PEV silencing in a dose-dependent manner. However, its effect is expressed weaker than that of the strong modifier Su(var)2-5.

Influence of the SuUR gene on intercalary heterochromatin in Drosophila melanogaster polytene chromosomes.

Salivary gland polytene chromosomes of Drosophila melanogaster have a reproducible set of intercalary heterochromatin (IH) sites, characterized by late DNA replication, underreplicated DNA, breaks and frequent ectopic contacts. The SuUR mutation has been shown to suppress underreplication, and wild-type SuUR protein is found at late-replicating IH sites and in pericentric heterochromatin. Here we show that the SuUR gene influences all four IH features. The SuUR mutation leads to earlier completion of DNA replication. Using transgenic strains with two, four or six additional SuUR(+) doses (4-8xSuUR(+)) we show that wild-type SuUR is an enhancer of DNA underreplication, causing many late-replicating sites to become underreplicated. We map the underreplication sites and show that their number increases from 58 in normal strains (2xSuUR(+)) to 161 in 4-8xSuUR(+) strains. In one of these new sites (1AB) DNA polytenization decreases from 100% in the wild type to 51%-85% in the 4xSuUR (+) strain. In the 4xSuUR(+) strain, 60% of the weak points coincide with the localization of Polycomb group (PcG) proteins. At the IH region 89E1-4 (the Bithorax complex), a typical underreplication site, the degree of underreplication increases with four doses of SuUR(+) but the extent of the underreplicated region is the same as in wild type and corresponds to the region containing PcG binding sites. We conclude that the polytene chromosome regions known as IH are binding sites for SuUR protein and in many cases PcG silencing proteins. We propose that these stable silenced regions are late replicated and, in the presence of SuUR protein, become underreplicated.