Point Mutations in the M Domain of PCID2 Impair Its Function in mRNA Export in Drosophila melanogaster.

The PCID2 protein is a component of the eukaryotic TREX-2 complex, which is responsible for mRNA export from the nucleus into the cytoplasm. We have previously shown that Drosophila melanogaster PCID2 is involved in specific mRNA recognition and identified the key amino acids responsible for its interaction with the ras2 RNA. In this work, point mutations of the amino acids were shown to disrupt the PCID2 interaction with cell RNAs and to distort the export of polyA-containing mRNAs from the nucleus into the cytoplasm in Drosophila cells.

Xmas-2 Protein, the Core Protein of the TREX-2 mRNA Export Complex, Does not Determine the Specificity of ras2 mRNA Binding by the Complex.

The TREX-2 complex of eukaryotes is responsible for the export of a wide range of mRNAs from the nucleus to the cytoplasm. Previously, we showed that a subunit of the D. melanogaster TREX-2 complex, the PCID2 protein, has a domain that specifically interacts with RNA. However, it remains unknown whether other components of the complex are involved in interaction with and recognition of the target mRNA. In the present study, we determined the role of Xmas-2, the core structural subunit of the complex, in the specific recognition of ras2 mRNA fragments. In this work, we showed that Xmas-2 interacts with ras2 mRNA independently of other subunits of the complex. We showed that RNA-binding domains are located in both the N-terminal domain and the C-terminal domain of Xmas-2. However, the interaction of the protein with ras2 mRNA fragments is independent of RNA sequence and structure and is nonspecific. Thus, the Xmas-2 subunit is not involved in the recognition of specific RNA sequences by the complex.

TREX-2-ORC Complex of D. melanogaster Participates in Nuclear Export of Histone mRNA.

The TREX-2-ORC protein complex of D. melanogaster is necessary for the export of the bulk of synthesized poly(A)-containing mRNA molecules from the nucleus to the cytoplasm through the nuclear pores. However, the role of this complex in the export of other types of RNA remains unknown. We have shown that TREX-2-ORC participates in the nuclear export of histone mRNAs: it associates with histone mRNPs, binds to histone H3 mRNA at the 3'-terminal part of the coding region, and participates in the export of histone mRNAs from the nucleus to the cytoplasm.

Neuronal and Muscle Differentiation of Mammalian Cells Is Accompanied by a Change in PHF10 Isoform Expression.

The PBAF chromatin remodeling complex of the SWI/SNF family plays a critical role in the regulation of gene expression during tissue differentiation and organism development. The subunits of the PBAF complex have domains responsible for binding to N-terminal histone sequences. It determines the specificity of binding of the complex to chromatin. PHF10, a specific subunit of the PBAF complex, contains a DPF domain, which is a unique chromatin interaction domain. A PHF10 isoform that lacks the DPF domain is also present in vertebrate cells. This work shows that during neuronal and muscle differentiation of human and mouse cells, the expression of PHF10 isoforms changes: the form that does not have DPF replaces the form in which it is present. Replacement of PHF10 isoforms in the PBAF complex may affect its selectivity in the regulation of genes in differentiating cells.

Interaction of mRNA with the C-Terminal Domain of PCID2, a Subunit of the TREX-2 Complex, Is Required for Its Export from the Nucleus to the Cytoplasm in Drosophila melanogaster.

Following the transcription step, the newly synthesized mRNA is exported from the nucleus to the cytoplasm and further to the translation site. The TREX-2 complex is involved in the step of mRNA export from the nucleus to the cytoplasm. This complex in Drosophila melanogaster consists of four proteins: Xmas-2, PCID2, ENY2, and Sem1p. In our work, we have shown that deletion of the C-terminal sequence of PCID2 leads to a decrease in the interaction of the protein with RNA and to impaired mRNA export from the nucleus to the cytoplasm in D. melanogaster.

Chromatin Remodeling Complex PBAF Activates and Represses Inflammatory Genes.

The PBAF chromatin remodeling complex regulates chromatin state and gene transcription in higher eukaryotes. In this work, we studied the role of PBAF in the regulation of NF-κB-and JAK/STAT-dependent activation of inflammatory genes. We performed knockdown of specific module subunit BAF200, which resulted in destruction of the entire PBAF specific module and changed the level of the genes transcription of both pathways. PBAF can be both an activator and a repressor of inflammatory genes. Thus, PBAF is an important regulator of inflammatory gene expression.

The Human TREX-2 Complex Interacts with Subunits of the ORC Complex.

The TREX-2 protein complex is the key complex involved in the export of mRNA from the nucleus to the cytoplasm through the nuclear pores. Previously, a joint protein complex of TREX-2 with ORC was isolated in D. melanogaster. It was shown that the interaction of TREX-2 with ORC is necessary for efficient mRNA export from the nucleus to the cytoplasm. In this work, we showed that the TREX-2-ORC joint complex is also formed in human cells.

[Assembly and Disassembly of the Nuclear Pore Complex: A View from the Structural Side].

Nucleocytoplasmic exchange in the cell occurs through the nuclear pore complexes (NPCs). NPCs are large multiprotein complexes with octagonal symmetry about their axis and imperfect mirror symmetry about a plane parallel with the nuclear envelop (NE). NPC fuses the inner and outer nuclear membranes and opens up a channel between nucleus and cytoplasm. NPC is built of nucleoporins. Each nucleoporin occurs in at least eight copies per NPC. Inside the NPC a permeability barrier forms by which NPCs can provide fast and selectable transport of molecules from one side of the nuclear membrane to the other. NPC architecture is based on hierarchical principle of organization. Nucleoporins are integrated into complexes that oligomerizes into bigger octomeric high-order structures. These structures are the main components of NPCs. In the first part of this work, the main attention is paid to NPC structure and nucleoporin properties. The second part is dedicated to mechanisms of NPC assembly and disassembly at different stages of the cell cycle.

The Xmas-2 Protein of Drosophila melanogaster Undergoes Cleavage into Two Fragments.

The TREX-2 complex integrates several stages of gene expression, such as transcriptional activation and mRNA export. In D. melanogaster, TREX-2 consists of four major proteins: Xmas-2, ENY2, PCID2, and Sem1p. The Xmas-2 protein is the core subunit of the complex, with which other TREX-2 subunits interact. Xmas-2 homologues were found in all higher eukaryotes. Previously, it was shown that the human Xmas-2 homologue, GANP protein, can undergo cleavage into two parts, probably during apoptosis. We showed that the Xmas-2 protein of D. melanogaster can also split into two fragments. The resulting fragments of the protein correspond to the two large Xmas-2 domains. Protein splitting is observed both in vivo and in vitro. However, Xmas-2 cleavage in D. melanogaster is observed under normal conditions and is probably a part of the mechanism of transcription and mRNA export regulation in D. melanogaster.

[Diversity of MLE Helicase Functions in the Regulation of Gene Expression in Higher Eukaryotes].

The Drosophila melanogaster Maleless (MLE) protein is a conserved helicase involved in a wide range of gene expression regulation processes. A MLE ortholog, named DHX9, was found in many higher eukaryotes, including humans. DHX9 is involved in diverse processes, such as genome stability maintenance, replication, transcription, splicing, editing and transport of cellular and viral RNAs, and translation regulation. Some of these functions are understood in detail today, while most of them remain uncharacterized. Study of the functions of the MLE ortholog in mammals in vivo is limited by the fact that the loss of function of this protein is lethal at the embryonic stage. In D. melanogaster, helicase MLE was originally discovered and studied for a long time as a participant in dosage compensation. Recent evidence indicates that helicase MLE is involved in the same cell processes in D. melanogaster and mammals and that many of its functions are evolutionarily conserved. Experiments in D. melanogaster revealed new important MLE functions, such as a role in hormone-dependent regulation of transcription and interactions with the SAGA transcription complex, other transcriptional cofactors, and chromatin remodeling complexes. Unlike in mammals, MLE mutations do not cause embryonic lethality in D. melanogaster, and the MLE functions are possible to study in vivo throughout ontogenesis in females and up to the pupal stage in males. The human MLE ortholog is a potential target for anticancer and antiviral therapies. Further investigation of the MLE functions in D. melanogaster is therefore of both basic and applied importance. The review discusses the systematic position, domain structure, and conserved and specific functions of MLE helicase in D. melanogaster.

Contact Inhibition of Proliferation Is Accompanied by Expression of the PHF10D Subunit of the Chromatin Remodeling Complex PBAF in Mouse and Human Cell Lines.

PHF10 is a subunit of the PBAF complex, which regulates the expression of many genes in developing and maturing organisms. PHF10 has four isoforms that differ in domain structure. The PHF10A isoform, containing a DPF domain at the C-terminus and 46 amino acids at the N-terminus, is necessary for the expression of proliferation genes; the functions of the other isoforms are less studied. In this work, we have established that, upon contact inhibition of mouse and human cell proliferation caused by the establishment of a tight junction and adherence junction between cells, the expression of the PHF10A isoform stops and instead the PHF10D isoform is expressed, which does not contain DPF-domain and N-terminal sequence. The function of the PHF10D isoform may be associated with the establishment of intercellular contacts.

[Reduced Expression of the Tissue-Specific Oct-IL Isoform Exerts an Antitumor Effect on Namalwa Burkitt's Lymphoma Cells].

Increased expression levels of the Oct-1 transcription factor is considered to be one of the key markers of poor cancer prognosis. In addition to the ubiquitous Oct-1A isoform, which is found in all cells, there also exists a tissue-specific Oct-1L isoform, which is expressed in hematopoietic cells. Oct-1L increases cell resistance to different stresses and also regulates the expression of genes controlling differentiation of hematopoietic and immune system cells. The tissue-specific Oct-1L isoform levels are significantly increased in the B-cell lymphoblastoma Namalwa and Raji lines and the T-cell lymphoblastoma Jurkat line compared to normal B and T cells. Apparently, aberrant Oct-1L overexpression not only enhances stress resistance but also leads to the disruption of developmental pathways in the cells promoting their malignant transformation. We report here that targeted suppression of the tissue-specific Oct-1L isoform expression reduces the proliferation rate of Namalwa B-lymphoblastic Burkitt's lymphoma cells, significantly increases cell death rate under hypoxic conditions, and makes cells more sensitive to chemotherapeutic agents such as docetaxel and doxorubicin. These results indicate that targeted therapy aimed at the suppression of the Oct-1 isoforms with increased expression levels in tumor cells rather than the total Oct-1, thus avoiding the traumatic effects of total Oct-1 knockdown, may be promising. Selective suppression of Oct-1 isoforms is a promising strategy in the treatment of lymphoid tumors and may contribute to mitigating the disease course and increasing survival rates in cancer patients.

5-Azacytidine Suppresses the Expression of Tissue-Specific Oct-1 Isoform in Namalwa Burkitt's Lymphoma Cell Culture.

Overexpression of the transcription factor POU2F1 (Oct-1) increases the malignant potential of the tumor and determines the unfavorable prognosis for both solid and hematological cases of the disease in human carcinogenesis. The Oct-1 level determines the rate of development of the disease in acute myelodysplastic leukemia (AML), and a decrease in its expression significantly delays the development of leukemia in mice; however, a complete knockout of Oct-1 leads to the death of the animals. POU2F1 (Oct-1) is expressed as several isoforms transcribed from alternative promoters. They include both ubiquitous and tissue-specific isoforms. It was shown that in Burkitt's lymphoma Namalwa cells 5-azacytidine specifically suppresses the expression of the tissue-specific isoform Oct-1L mRNA (level of Oct-1L is abnormally increased in these cells), while not causing changes in the amount of the ubiquitous isoform Oct-1A mRNA. These results show that it is possible to selectively reduce the transcription level of the Oct-1L isoform aberrantly expressed in human tumor cells.

The Emergence of a New Isoform of POU2F1 in Primates through the Use of Egoistic Mobile Genetic Elements.

The emergence of new genes and functions is of paramount importance in the emergence of new animal species. For example, the insertion of the mobile element Tigger 2 into the sequence of the functional gene POU2F1 in primates led to the formation of a new chimeric primate-specific isoform POU2F1Z, the translation of which is activated under cellular stress. Its mRNA was found in all species of monkeys, starting with macaques. Analysis of the fragments of the Tigger2 copy corresponding to the human exon Z showed that the splicing sites of exon Z are homologous in humans and in most monkeys, with the exception of lemurs and galagos. The stop codon introduced into the mRNA by the Tigger2 sequence is present in all primates, starting with macaques. The internal ATG codon is also present in all primates, with the exception of lemurs and galagos. In the course of evolution, other MGEs, mainly of the SINE type, were inserted into the Tigger2 copy. In the course of evolution, both the location and the number of mobile SINE elements within the POU2F1 gene changed. Starting with macaques, the pattern of the arrangement of SINE elements within the Tigger2 copy in the studied region of the POU2F1 gene was fixed and then remained unchanged in other primates and humans, which may indicate its functional significance.

[Role of the SWI/SNF Chromatin Remodeling Complex in Regulation of Inflammation Gene Expression].

The process of inflammation is the body's natural defense response to the penetration of foreign substances and molecules from the outside. Many proteins, signaling cascades, and transcription factors are involved in the activation of inflammation genes. Their coordinated activity leads to a change in the expression of proinflammatory genes. The chromatin state of genes responding to the inflammation stimulus is the main factor determining the binding of transcriptional activators to the gene regulatory elements and a key mechanism in the induction of inflammatory genes. The rapid change in the state of chromatin, the creation of an open structure and the removal of the "nucleosome barrier" facilitates the binding of transcription factors and the initiation of transcription. This process is realized by attracting complexes to the gene that modify and remodel chromatin. One of the most important complexes restructuring the chromatin structure during gene activation is the SWI/SNF multisubunit complex. SWI/SNF regulates the expression of inflammation genes through interaction with transcription factors, including factors of the NF-κВ signaling pathway. The variability of the subunits of this complex determines the specificity of its binding to the chromatin and various transcriptional activators. This review considers the role of SWI/SNF in the regulation of inflammation genes, describes its interactions with chromatin, and the molecular mechanisms of its recruitment to the promoters.

[POU2F1 (Oct-1) Differently Autoregulates the Alternative Promoters of Its Own Gene by Binding to Different Regulatory Sites].

The POU2F1 gene, which plays an important role in regulating the mammalian genome and development, has both a ubiquitous (U) and a tissue-specific (L) promoter and is subject to intricate regulation. Regions of POU2F1 gene were found to contain multiple binding sites for its product POU2F1 (Oct-1), a transcription factor. Interspecies homology in these regions was found to exceed 90% among the human, mouse, rat, pig, and dog genomes, almost all of the Oct-1 binding sites being identical. Some of the sites cluster in the vicinity of each of the two alternative promoters, while others are in the 5' noncoding region 6 kb upstream of the transcription start site. The presence of Oct-1 at the sites was demonstrated by chromatin immunoprecipitation and the electrophoretic mobility shift assay (EMSA). A POU2F1 knockdown activated the U promoter and downregulated the L promoter in Namalwa cells, while Oct-1 overexpression exerted an opposite effect. Thus, Oct-1 acts via negative feedback to autoregulate the U promoter through low-affinity Oct-1 binding sites and positive feedback to autoregulate the L promoter through high-affinity canonical (oct) sites when increasing in concentration in a natural context.

[PHF10, a Subunit of the PBAF Chromatin Remodeling Complex, Changes Its Localization and Interacts with c-FOS during the Initiation of Long-Term Potentiation in Neuronal Culture].

The PBAF chromatin remodeling complex interacts with many transcriptional activators and is recruited to target chromatin regions. PBAF plays an important role in maintaining and modifying the chromatin structure in mammalian cells. A subunit of the PBAF complex, the PHF10 transcription factor, is required for proliferation of neuronal precursors in the early stages of mouse brain development and gene expression in differentiated neurons. We showed that PHF10 interacts with the protein product of the early response gene c-FOS, the c-FOS transcriptional activator, which is expressed in response to the induction of long-term potentiation (LTP). LTP induction triggers the transcription of genes and the synthesis of proteins that provide changes that lead to the establishment of long-term contacts between neurons. We showed that in cells in differentiated neuronal culture, after the induction of LTP, expression of c-FOS, which is initially localized in the cytoplasm and then moves to the nucleus, begins. PHF10 is expressed in neuronal cells prior to LTP induction and has nuclear localization. However, 1 h after LTP induction, PHF10 is detected in the cytoplasm together with c-FOS, and then moves into the nucleus with it. Importantly, this behavior of PHF10 in response to KC1 stimulation is specific for neuronal cultures. It is assumed that during LTP, PHF10 together with c-FOS participates in the activation of secondary response genes that regulate the maintenance of plastic modifications and homeostasis of neuronal synapses. The PHF10 export from the nucleus and its rapid return together with c-FOS to the nucleus is possibly necessary for the rapid modulation of expression of target secondary response genes during LTP.

PHF10 subunit of PBAF complex mediates transcriptional activation by MYC.

The PBAF complex, a member of SWI/SNF family of chromatin remodelers, plays an essential role in transcriptional regulation. We revealed a disease progression associated elevation of PHF10 subunit of PBAF in clinical melanoma samples. In melanoma cell lines, PHF10 interacts with MYC and facilitates the recruitment of PBAF complex to target gene promoters, therefore, augmenting MYC transcriptional activation of genes involved in the cell cycle progression. Depletion of either PHF10 or MYC induced G1 accumulation and a senescence-like phenotype. Our data identify PHF10 as a pro-oncogenic mechanism and an essential novel link between chromatin remodeling and MYC-dependent gene transcription.

Differentiation of IMR32 Neuroblastoma Is Accompanied by a Global Change in the Transcriptome.

Neuroblastoma is one of the most common cancers in infants and is often multidrug-resistant. One of the methods of treating neuroblastomas is to create conditions for their differentiation. In this work, we performed a full-transcriptome analysis of gene expression in an undifferentiated and differentiated in vitro human neuroblastoma cell line IMR-32 and identified the signaling pathways and biological processes that undergo the greatest changes during differentiation. The results obtained show that a complex heterogeneous population of nerve cells is formed at different stages of differentiation. In the cell population of differentiating neuroblastoma, the expression of genes in which cortical neuronal progenitor cells are enriched increases; at the same time, there are cells expressing markers of early postmitotic neurons. Cells differentiate in several different directions according to the type of synaptic mediator. At the same time, the differentiation of IMR-32 cells is accompanied by an increase in the transcription of genes that suppress the differentiation of nerve cells, Sox2 and PROM1, the expression of which is normally suppressed during in vivo differentiation.

MLE Helicase Is a New Participant in the Transcription Regulation of the ftz-f1 Gene Encoding Nuclear Receptor in Higher Eukaryotes.

MLE helicase is an evolutionarily conserved eukaryotic protein involved in a wide range of processes in the regulation of gene expression. Previously, we studied the properties of MLE on the Drosophila melanogaster model. In the present work we continue studying the functions of MLE and show that MLE interacts with the components of the SWI/SNF chromatin remodelling complex. To clarify the work of MLE, the profile of MLE binding to the regulatory elements of the SWI/SNF-dependent ftz-f1 gene was analyzed. The effect of MLE on the expression of this gene, the transcription of which occurs by the RNA polymerase II pausing mechanism, was investigated. The data obtained indicate the important role of MLE in ensuring timely activation and high level of expression of the ftz-f1 gene in vivo.