Otu and Rif1 Double Mutant Enables Analysis of Satellite DNA in Polytene Chromosomes of Ovarian Germ Cells in Drosophila melanogaster.

Polytene chromosomes in Drosophila serve as a classical model for cytogenetic studies. However, heterochromatic regions of chromosomes are typically under-replicated, hindering their analysis. Mutations in the Rif1 gene lead to additional replication of heterochromatic sequences, including satellite DNA, in salivary gland cells. Here, we investigated the impact of the Rif1 mutation on heterochromatin in polytene chromosomes formed in ovarian germ cells due to the otu gene mutation. By the analysis of otu11; Rif11 double mutants, we found that, in the presence of the Rif1 mutation, ovarian cells undergo additional polytenization of pericentromeric regions. This includes the formation of large chromatin blocks composed of satellite DNA. Thus, the effects of the Rif1 mutation are similar in salivary gland and germ cells. The otu11; Rif11 system opens new possibilities for studying factors associated with heterochromatin during oogenesis.

[Participation of the piRNA pathway in recruiting a component of RNA polymerase I transcription initiation complex to germline cell nucleoli].

Proteins of the Piwi family and short Piwi-interacting RNAs (piRNAs) ensure the protection of the genome from transposable elements. We have previously shown that nuclear Piwi protein tends to concentrate in the nucleoli of the cells of Drosophila melanogaster ovaries. It could be hypothesized that the function of Piwi in the nucleolus is associated with the repression of R1 and R2 retrotransposons inserted into the rDNA cluster. Here, we show that Piwi participates in recruiting Udd protein to nucleoli. Udd is a component of the conserved Selectivity Factor I-like (SL1-like) complex, which is required for transcription initiation by RNA polymerase I. We found that Udd localization depends on Piwi in germline cells, but not in somatic cells of the ovaries. In contrast, knockdowns of the SL1-like components (Udd or TAF1b) do not disrupt Piwi localization. We also observed that the absence of Udd or TAF1b in germline cells, as well as the impairment of Piwi nuclear localization lead to the accumulation of late stage egg chambers in the ovaries, which could be explained by reduced rRNA transcription. These results allow us to propose for the first time a role for Piwi in the nucleolus that is not directly associated with transposable element repression.

Induction of Transposon Silencing in the Drosophila Germline.

In this review we consider the role of the piRNA system in transposable element silencing in the Drosophila melanogaster germline. We focus on new data that demonstrate the mechanisms of initiation of piRNA biogenesis in ovarian germinal cells and the role of Piwi protein in this process, including our own results.

[The role of Piwi nuclear localization in the differentiation and proliferation of germline stem cells].

The Piwi protein and its orthologs are considered as the key components of the piRNA machinery implicated in transcriptional silencing of transposons. Неre, we show that nuclear localization of the Piwi protein is required not only for transposon repression, but also for proper differentiation of germline stem cells (GSCs). piwi^(Nt) mutation that causes loss of nuclear Piwi and its retention in the cytoplasm leads to the accumulation of undifferentiated GSC-like cells. The analysis of piwi^(Nt) mutation in combination with a bam gene mutation blocking GSC differentiation shows that the loss of nuclear Piwi decreases GSC proliferation rate. This is accompanied by the accumulation of DNA double-strand breaks in GSCs that may be caused by transposition events. Here, for the first time a set of transposons repressed by Piwi in GSCs and surrounding niche cells has been identified. The present study together with our previous data show that nuclear and cytoplasmic Piwi can regulate different stages of the functioning of germinal cells: cytoplasmic Piwi is sufficient to maintain GSCs, while nuclear Piwi localization is necessary for their proper proliferation and differentiation.

[Functions of piRNAs and the Piwi Protein in Drosophila].

Short (25-35 nucleotides) regulatory piPHK, along with RNA-binding proteins of the Piwi family, constitute an evolutionarily conserved system that functions mainly in eukaryotic gonads. The system can be regarded as a variant of the mechanism of RNA interference, which is based on the recognition of target RNA as a result of complementary interactions with piRNA. The variants of this regulatory system function in the germline cells, including stem cells and somatic cells of the niche, ensuring maintenance of the germline stem cells and their differentiation. One of the most important functions (but not the only one) of this system is the repression of transposons, which guarantees genome stability in germline cells. This review focuses on the works of the authors of the review in the context of outstanding international achievements in a rapidly evolving re- search area, the biology of piRNA and the function of the Piwi protein.

[PIWI protein as a nucleolus visitor in Drosophila melanogaster].

The evolutionarily conserved nuclear Piwi protein of Drosophila melanogaster is a representative of the Argonaute small RNA binding protein family. Guided by small piRNAs, Piwi functions in transposon silencing in somatic and germ cells of the gonad. We found that in ovarian somatic and germ cells, as well as in the established ovarian somatic cell line, Piwi is concentrated predominantly in the nucleolus--the main nuclear compartment, participating not only in rRNA synthesis, but also in various cell stress responses. We demonstrated the colocalization of Piwi with nucleolar marker proteins--fibrillarin and Nopp140. A mutation preventing Piwi transport to the nucleus and disturbing transposon silencing (piwi(Nt)) leads to 6-8-fold upregulation of rRNA genes expression, as evaluated by the level of transcripts of transposon insertions in 28S rRNA genes. RNase treatment of live cultured ovarian somatic cells depletes Piwi from the nucleolus. The same effect is observed upon inhibiting RNA polymerase I which transcribes rRNA, but not RNA polymerase II. In contrast, upon heat shock Piwi is concentrated in the nucleolus and is depleted from the nucleoplasm. These results implicate Piwi in RNA polymerase activity modulation and stress response in the nucleolus. We discuss possible noncanonical Piwi functions along with its canonical role in transposon silencing by piRNAs.

Multifunctionality of PIWI proteins in control of germline stem cell fate.

PIWI proteins interacting with specific type of small RNAs (piRNAs) repress transposable elements in animals. Besides, they have been shown to participate in various cellular processes: in the regulation of heterochromatin formation including telomere structures, in the control of translation and the cell cycle, and in DNA rearrangements. PIWI proteins were first identified by their roles in the self-renewal of germline stem cells. PIWI protein functions are not limited to gonadogenesis, but the role in determining the fate of stem cells is their specific feature conserved throughout the evolution of animals. Molecular mechanisms underlying these processes are far from being understood. This review focuses on the role of PIWI proteins in the control of maintenance and proliferation of germinal stem cells and its relation to the known function of PIWI in transposon repression.

[The interplay of transposon silencing genes in the Drosophila melanogaster germline].

Complexes of Piwi proteins and Piwi-interacting RNAs (piRNAs) carry out the repression of transposable elements in animal gonads. The Piwi protein clade is represented in D. melanogaster by three members: Piwi, Aub and Ago3. Piwi protein functions in the nuclei of somatic and germinal ovarian cells, whereas Aub and Ago3 are cytoplasmic proteins of germinal cells. Aub and Ago3 interact with each other in the perinuclear nuage organelle to perform piRNA amplification via the ping-pong mechanism. Previously, derepression of several transposable elements as a result of mutations in the piRNA silencing system was shown. Here we quantify the increase in expression level of an enlarged number of retrotransposons due to the mutations in the piwi gene, nuage components coding aub, mael and spn-E genes and the RNA helicase armi gene mutation that impairs Piwi nuclear localization, but not the ping-pong cycle. We reveal that piwi, armi, aub, spn-E and mael genes participate together in the repression of several transposons (HMS-Beagle, Gate and HeT-A), whereas silencing of land G elements requires the same genes except piwi. We suggest that Armi has other functions besides the localizing of Piwi protein in the nuclei. Our data suggest also a role of cytoplasmic Aub, Spn-E and Mael nuage proteins in Piwi-mediated repression of Gate and HMS-Beagle transposons in the germline nuclei. As a whole, our results corroborate the idea that genome stabilization in the germline is realized by different silencing strategies specific for different transposable elements. At the same time, our data suggest the existence of yet unknown mechanisms of interplay between nuclear and cytoplasmic components of the piRNA machinery in the germline.

Heterochromatin formation: role of short RNAs and DNA methylation.

The role of small double-stranded RNAs is considered in formation of silent chromatin structure. Small RNAs are implicated in the regulation of individual gene transcription, suppression of transposon expression, and in maintaining functional structure of extended heterochromatic regions. Interrelations between short RNA-dependent gene silencing, histone modifications, and DNA methylation are discussed. Specific features of RNA-induced chromatin repression in various eucaryotes are also described.

[The phenomenon of RNA interference and development of organism]. / Iavlenie RNK-interferentsii i razvitie organizma.

RNA interference consists in specific mRNA degradation in response to introduction of a double-stranded RNA, homologous in nucleotide sequence. RNA interference was found in eukaryotes and is used in genomics as a powerful method to determine the functions of genes with known nucleotide sequences. RNA interference is considered as a tool of protection against viruses and harmful consequences of mobile elements' transposals. The involvement of the components of RNA interference is considered in spermatogenesis of Drosophila melanogaster and regulation of the expression of genes in Caenorhabditis elegans responsible for temporal patterns of development. The role of RNQA interference in stem cell formation and functioning is also considered.

[Role of double-stranded RNA in eukaryotic gene silencing]. / Rol' dvukhtsepochechnoi RNK v podavlenii ékspressii genov éukariot.

Data on RNA interference, that is, posttranscriptional gene silencing by homologous double-stranded (ds) RNA, are reviewed. Gene silencing caused by exogenous dsRNA in artificial systems and observed in transgenic organisms carrying additional gene copies is considered. Data are summarized on the mechanism that arose during evolution of the Drosophila melanogaster genome to suppress repetitive genes with the use of dsRNA and thereby to prevent male sterility. The role of dsRNA in inhibiting expression and transposition of mobile elements is discussed on the basis of authors own and published findings.

[The study of interaction between paralogous tandem repeats stellate and suppressor of stellate in the genome of Drosophila melanogaster]. / Issledovaniie vzaimodeistviia paralogichnykh tandemnykh povtorov Stellate i Suppressor of stellate v genome Drosophila melanogaster.

Testis-specific expression of tandemly repeated Stellate genes, located in eu- and heterochromatin regions of the X chromosome of Drosophila melanogaster, is suppressed by homologous Suppressor of Stellate repeats located on the Y chromosome. Using transgenic lines, we have demonstrated that three Su(Ste) copies failed to change the expression of the reporter construction carrying the bacterial beta-galactosidase gene under control of the Stellate gene regulatory sequence. Possible mechanisms of the Su(Ste) repeat suppressor activity are discussed.