Mobility of Nuclear Components and Genome Functioning.

Cell nucleus is characterized by strong compartmentalization of structural components in its three-dimensional space. Certain genomic functions are accompanied by changes in the localization of chromatin loci and nuclear bodies. Here we review recent data on the mobility of nuclear components and the role of this mobility in genome functioning.

[Role of the Nucleolus in Rearrangements of the IGH Locus].

The review summarizes the results from a series of studies focusing on the role that the nucleolus plays in maturation of the IGH locus and the choice of its partner genes in leukemia-associated translocations. The role of nuclear compartmentalization and nuclear localization of translocated oncogenes in ectopic activation of their transcription is discussed.

Genetic and Epigenetic Mechanisms of ß-Globin Gene Switching.

Vertebrates have multiple forms of hemoglobin that differ in the composition of their polypeptide chains. During ontogenesis, the composition of these subunits changes. Genes encoding different α- and ß-polypeptide chains are located in two multigene clusters on different chromosomes. Each cluster contains several genes that are expressed at different stages of ontogenesis. The phenomenon of stage-specific transcription of globin genes is referred to as globin gene switching. Mechanisms of expression switching, stage-specific activation, and repression of transcription of α- and ß-globin genes are of interest from both theoretical and practical points of view. Alteration of balanced expression of globin genes, which usually occurs due to damage to adult ß-globin genes, leads to development of severe diseases - hemoglobinopathies. In most cases, reactivation of the fetal hemoglobin gene in patients with ß-thalassemia and sickle cell disease can reduce negative consequences of irreversible alterations of expression of the ß-globin genes. This review focuses on the current state of research on genetic and epigenetic mechanisms underlying stage-specific switching of ß-globin genes.

Effect of Environmental Factors on Nuclear Organization and Transformation of Human B Lymphocytes.

Chromosomal translocations have long been known for their association with malignant transformation, particularly in hematopoietic disorders such as B-cell lymphomas. In addition to the physiological process of maturation, which creates double strand breaks in immunoglobulin gene loci, environmental factors including the Epstein-Barr and human immunodeficiency viruses, malaria-causing parasites (Plasmodium falciparum), and plant components (Euphorbia tirucalli latex) can trigger a reorganization of the nuclear architecture and DNA damage that together will facilitate the occurrence of deleterious chromosomal rearrangements.

Dual Role of the Extracellular Domain of Human Mucin MUC1 in Metastasis.

Human mucin MUC1 plays an important role in cancer development. The increased level of this molecule expression during cancer cell progression induces metastasis and is associated with poor prognosis for patients. There is a large body of experimental data on the role of various functional domains of human mucin MUC1 in metastasis. While, the cytoplasmic domain determined to play a definitive role, the influence of extracellular domain on cancer cell invasiveness still remains unclear. The present paper reveals that the extracellular domain of MUC1 molecule consists of two functional subdomains-the region of tandem repeats (TR) and the region of irregular repeats (IR). We demonstrate the ability of each of these subdomains to alter the invasiveness of cancer cells. The presence of the MUC1 molecules containing TR subdomain (MUC1-TR) on the surface of low-invasive cancer cells leads to the increase in their transendothelial migration potency, while the addition of the IR subdomain to the MUC1-TR molecule (MUC1-IR-TR) restores their natural low invasiveness. J. Cell. Biochem. 118: 4002-4011, 2017. © 2017 Wiley Periodicals, Inc.

HIV Tat induces a prolonged MYC relocalization next to IGH in circulating B-cells.

With combined antiretroviral therapy (cART), the risk for HIV-infected individuals to develop a non-Hodgkin lymphoma is diminished. However, the incidence of Burkitt lymphoma (BL) remains strikingly elevated. Most BL present a t(8;14) chromosomal translocation which must take place at a time of spatial proximity between the translocation partners. The two partner genes, MYC and IGH, were found colocalized only very rarely in the nuclei of normal peripheral blood B-cells examined using 3D-FISH while circulating B-cells from HIV-infected individuals whose exhibited consistently elevated levels of MYC-IGH colocalization. In vitro, incubating normal B-cells from healthy donors with a transcriptionally active form of the HIV-encoded Tat protein rapidly activated transcription of the nuclease-encoding RAG1 gene. This created DNA damage, including in the MYC gene locus which then moved towards the center of the nucleus where it sustainably colocalized with IGH up to 10-fold more frequently than in controls. In vivo, this could be sufficient to account for the elevated risk of BL-specific chromosomal translocations which would occur following DNA double strand breaks triggered by AID in secondary lymph nodes at the final stage of immunoglobulin gene maturation. New therapeutic attitudes can be envisioned to prevent BL in this high risk group.

The microRNA-205-5p is correlated to metastatic potential of 21T series: A breast cancer progression model.

MicroRNA is a class of noncoding RNAs able to base pair with complementary messenger RNA sequences, inhibiting their expression. These regulatory molecules play important roles in key cellular processes including cell proliferation, differentiation and response to DNA damage; changes in miRNA expression are a common feature of human cancers. To gain insights into the mechanisms involved in breast cancer progression we conducted a microRNA global expression analysis on a 21T series of cell lines obtained from the same patient during different stages of breast cancer progression. These stages are represented by cell lines derived from normal epithelial (H16N2), atypical ductal hyperplasia (21PT), primary in situ ductal carcinoma (21NT) and pleural effusion of a lung metastasis (21MT-1 and 21MT-2). In a global microRNA expression analysis, miR-205-5p was the only miRNA to display an important downregulation in the metastatic cell lines (21MT-1; 21MT-2) when compared to the non-invasive cells (21PT and 21NT). The lower amounts of miR-205-5p found also correlated with high histological grades biopsies and with higher invasion rates in a Boyden chamber assay. This work pinpoints miR-205-5p as a potential player in breast tumor invasiveness.

Genome- and Cell-Based Strategies in Therapy of Muscular Dystrophies.

Muscular dystrophies are a group of heterogeneous genetic disorders characterized by progressive loss of skeletal muscle mass. Depending on the muscular dystrophy, the muscle weakness varies in degree of severity. The majority of myopathies are due to genetic events leading to a loss of function of key genes involved in muscle function. Although there is until now no curative treatment to stop the progression of most myopathies, a significant number of experimental gene- and cell-based strategies and approaches have been and are being tested in vitro and in animal models, aiming to restore gene function. Genome editing using programmable endonucleases is a powerful tool for modifying target genome sequences and has been extensively used over the last decade to correct in vitro genetic defects of many single-gene diseases. By inducing double-strand breaks (DSBs), the engineered endonucleases specifically target chosen sequences. These DSBs are spontaneously repaired either by homologous recombination in the presence of a sequence template, or by nonhomologous-end joining error prone repair. In this review, we highlight recent developments and challenges for genome-editing based strategies that hold great promise for muscular dystrophies and regenerative medicine.

Evolution of α- and ß-globin genes and their regulatory systems in light of the hypothesis of domain organization of the genome.

The α- and ß-globin gene domains are a traditional model for study of the domain organization of the eucaryotic genome because these genes encode hemoglobin, a physiologically important protein. The α-globin and ß-globin gene domains are organized in completely different ways, while the expression of globin genes is tightly coordinated, which makes it extremely interesting to study the origin of these genes and the evolution of their regulatory systems. In this review, the organization of the α- and ß-globin gene domains and their genomic environment in different taxonomic groups are comparatively analyzed. A new hypothesis of possible evolutionary pathways for segregated α- and ß-globin gene domains of warm-blooded animals is proposed.

Nuclear matrix and structural and functional compartmentalization of the eucaryotic cell nucleus.

Becoming popular at the end of the 20th century, the concept of the nuclear matrix implies the existence of a nuclear skeleton that organizes functional elements in the cell nucleus. This review presents a critical analysis of the results obtained in the study of nuclear matrix in the light of current views on the organization of the cell nucleus. Numerous studies of nuclear matrix have failed to provide evidence of the existence of such a structure. Moreover, the existence of a filamentous structure that supports the nuclear compartmentalization appears to be unnecessary, since this function is performed by the folded genome itself.

A requiem to the nuclear matrix: from a controversial concept to 3D organization of the nucleus.

The first papers coining the term "nuclear matrix" were published 40 years ago. Here, we review the data obtained during the nuclear matrix studies and discuss the contribution of this controversial concept to our current understanding of nuclear architecture and three-dimensional organization of genome.

Antagonistic functional duality of cancer genes.

Cancer evolution is a stochastic process both at the genome and gene levels. Most of tumors contain multiple genetic subclones, evolving in either succession or in parallel, either in a linear or branching manner, with heterogeneous genome and gene alterations, extensively rewired signaling networks, and addicted to multiple oncogenes easily switching with each other during cancer progression and medical intervention. Hundreds of discovered cancer genes are classified according to whether they function in a dominant (oncogenes) or recessive (tumor suppressor genes) manner in a cancer cell. However, there are many cancer "gene-chameleons", which behave distinctly in opposite way in the different experimental settings showing antagonistic duality. In contrast to the widely accepted view that mutant NADP(+)-dependent isocitrate dehydrogenases 1/2 (IDH1/2) and associated metabolite 2-hydroxyglutarate (R)-enantiomer are intrinsically "the drivers" of tumourigenesis, mutant IDH1/2 inhibited, promoted or had no effect on cell proliferation, growth and tumorigenicity in diverse experiments. Similar behavior was evidenced for dozens of cancer genes. Gene function is dependent on genetic network, which is defined by the genome context. The overall changes in karyotype can result in alterations of the role and function of the same genes and pathways. The diverse cell lines and tumor samples have been used in experiments for proving gene tumor promoting/suppressive activity. They all display heterogeneous individual karyotypes and disturbed signaling networks. Consequently, the effect and function of gene under investigation can be opposite and versatile in cells with different genomes that may explain antagonistic duality of cancer genes and the cell type- or the cellular genetic/context-dependent response to the same protein. Antagonistic duality of cancer genes might contribute to failure of chemotherapy. Instructive examples of unexpected activity of cancer genes and "paradoxical" effects of different anticancer drugs depending on the cellular genetic context/signaling network are discussed.

Tightly bound to DNA proteins: possible universal substrates for intranuclear processes.

Tightly bound to DNA proteins (TBPs) are a protein group that remains attached to DNA after its deproteinization by phenol, chloroform or salting-out. TBP are bound to DNA with covalent phosphotriester or non-covalent ion and hydrogen bonds. They appear to be a vast protein group involved in numerous intranuclear processes. The TBPs fraction co-purified with DNA deproteinized by mild procedures is extremely heterogeneous, tissue and species-specific. The protein fraction co-purified with DNA after harsh deproteinization procedures appears to be formed from few polypeptides common to different species and tissues. Interaction sites between DNA and TBPs depend on the physiological status of the cell. The binding sites of TBPs to DNA do not co-localize with the nuclear matrix attachment regions. We hypothesize that TBPs form a universal substrate for intranuclear processes.

Proteins tightly bound to DNA: new data and old problems.

Proteins tightly bound to DNA (TBP) comprise a group of proteins that remain bound to DNA after usual deproteinization procedures such as salting out and treatment with phenol or chloroform. TBP bind to DNA by covalent phosphotriester and noncovalent ionic and hydrogen bonds. Some TBP are conservative, and they are usually covalently bound to DNA. However, the TBP composition is very diverse and significantly different in different tissues and in different organisms. TBP include transcription factors, enzymes of the ubiquitin-proteasome system, phosphatases, protein kinases, serpins, and proteins of retrotransposons. Their distribution within the genome is nonrandom. However, the DNA primary structure or DNA curvatures do not define the affinity of TBP to DNA. But there are repetitive DNA sequences with which TBP interact more often. The TBP distribution within genes and chromosomes depends on a cell's physiological state, differentiation type, and stage of organism development. TBP do not interact with DNA in the sites of its association with nuclear matrix and most likely they are not components of the latter.

In embryonic chicken erythrocytes actively transcribed alpha globin genes are not associated with the nuclear matrix.

The spatial organization of a 250 Kb region of chicken chromosome 14, which includes the alpha globin gene cluster, was studied using in situ hybridization of a corresponding BAC probe with nuclear halos. It was found that in non-erythroid cells (DT40) and cultured erythroid cells of definite lineage (HD3) the genomic region under study was partially (DT40 cells) or fully (HD3 cells) associated with the nuclear matrix. In contrast, in embryonic red blood cells (10-day RBC) the same area was located in the crown of DNA loops surrounding the nuclear matrix, although both globin genes and surrounding house-keeping genes were actively transcribed in these cells. This spatial organization was associated with the virtual absence of RNA polymerase II in nuclear matrices prepared from 10-day RBC. In contrast, in HD3 cells a significant portion of RNA polymerase II was present in nuclear matrices. Taken together, these observations suggest that in embryonic erythroid cells transcription does not occur in association with the nuclear matrix.

Selective matrix attachment regions in T helper cell subsets support loop conformation in the Ifng gene.

Cytokine genes undergo progressive changes in chromatin organization when naïve CD4+ T helper (Th) cells differentiate into committed Th1 and Th2 lineages. Here, we analyzed nuclear matrix attachment regions (MARs) in the Ifng gene by DNA array technique in unactivated and activated CD4+ Th cells. This approach was combined with analysis of spatial organization of the Ifng gene by chromosome conformation capture approach to assess the relationship between the gene conformation and matrix attachment organization in functionally different cell subsets. We report that the Ifng gene in unactivated cells displays a linear conformation, but in T-cell receptor-activated cells, it adopts a loop conformation. The selective MARs support the spatial gene organization and characteristically define the Ifng gene in functionally different cell subsets. The pattern of interaction of the Ifng gene with the nuclear matrix dynamically changes in a lineage-specific manner in parallel with the changes in Ifng gene conformation. The data suggest that such structural dynamics provide the means for transcriptional regulation of the Ifng gene in the course of activation and differentiation of CD4+Th cells.

Chromatin remodelling and DNA replication: from nucleosomes to loop domains.

Organization of DNA into chromatin is likely to participate in the control of the timing and selection of DNA replication origins. Reorganization of the chromatin is carried out by chromatin remodelling machines, which may affect the choice of replication origins and efficiency of replication. Replication itself causes a profound rearrangement in the chromatin structure, from nucleosomes to DNA loop domains, allowing to retain or switch an epigenetic state. The present review considers the effects of chromatin remodelling on replication and vice versa.

Analysis of the chicken DNA fragments that contain structural sites of attachment to the nuclear matrix: DNA-matrix interactions and replication.

Ten short DNA fragments have been selected from a library of the nuclear matrix-attached DNA (nmDNA) from chicken erythrocytes by their ability to hybridize with the fraction of chicken replication origins isolated by nascent DNA strand extrusion. The primary structure of these fragments has been determined. Five of the sequences contained a topoisomerase II recognition site. Most of the studied DNA fragments also have a common eight-nucleotide motif, GCAGACCG/A. A sequence-specific DNA-binding protein with a MW of 55 kDa that interacted with this motif has been identified. Some of the cloned DNA fragments promoted an increased level of transient plasmid replication in transfected chicken cells. The ability of plasmid bearing nmDNA fragments to replicate correlated directly with their ability to target plasmids to the nuclear matrix compartment.

Rearrangement of chromatin domains during development in Xenopus.

A dynamic change in the organization of different gene domains transcribed by RNA polymerase I, II, or III occurs during the progression from quiescent [pre-midblastula transition (pre-MBT)] to active (post-MBT) embryos during Xenopus development. In the rDNA, c-myc, and somatic 5S gene domains, a transition from random to specific anchorage to the nuclear matrix occurs when chromatin domains become active. The keratin gene domain was also randomly associated to the nuclear matrix before MBT, whereas a defined attachment site was found in keratinocytes. In agreement with this specification, ligation-mediated (LM)-PCR genomic footprinting carried out on the subpopulation of 5S domains specifically attached to the matrix reveals the hallmarks of determined chromatin after the midblastula transition. In contrast, the same analysis performed on the total 5S gene population does not reveal specific chromatin organization, validating the use of nuclear matrix fractionation to unveil active chromatin domains. These data provide a means for the determination of active chromosomal territories in the embryo and emphasize the role of nuclear architecture in regulated gene expression during development.

Specification of chromatin domains and regulation of replication and transcription during development.

It is becoming increasingly clear that transcription control is carried out at several interconnecting levels. Besides nucleosomal organization and interaction between transcription factors and gene promoters and other regulatory elements, long-range organization of chromatin in loops or domains seems to play a role in transcriptional regulation. A similar organization is likely to be crucial in the control of the timing and selection of origins of DNA replication. This review considers the implications of domain organization of eukaryotic genome in developmental control of transcription and replication.