Mechanisms of Secondary Leukemia Development Caused by Treatment with DNA Topoisomerase Inhibitors.

Leukemia is a blood cancer originating in the blood and bone marrow. Therapy-related leukemia is associated with prior chemotherapy. Although cancer therapy with DNA topoisomerase II inhibitors is one of the most effective cancer treatments, its side effects include development of secondary leukemia characterized by the chromosomal rearrangements affecting AML1 or MLL genes. Recurrent chromosomal translocations in the therapy-related leukemia differ from chromosomal rearrangements associated with other neoplasias. Here, we reviewed the factors that drive chromosomal translocations induced by cancer treatment with DNA topoisomerase II inhibitors, such as mobility of ends of double-strand DNA breaks formed before the translocation and gain of function of fusion proteins generated as a result of translocation.

rs71327024 Associated with COVID-19 Hospitalization Reduces CXCR6 Promoter Activity in Human CD4+ T Cells via Disruption of c-Myb Binding.

Single-nucleotide polymorphism rs71327024 located in the human 3p21.31 locus has been associated with an elevated risk of hospitalization upon SARS-CoV-2 infection. The 3p21.31 locus contains several genes encoding chemokine receptors potentially relevant to severe COVID-19. In particular, CXCR6, which is prominently expressed in T lymphocytes, NK, and NKT cells, has been shown to be involved in the recruitment of immune cells to non-lymphoid organs in chronic inflammatory and respiratory diseases. In COVID-19, CXCR6 expression is reduced in lung resident memory T cells from patients with severe disease as compared to the control cohort with moderate symptoms. We demonstrate here that rs71327024 is located within an active enhancer that augments the activity of the CXCR6 promoter in human CD4+ T lymphocytes. The common rs71327024(G) variant makes a functional binding site for the c-Myb transcription factor, while the risk rs71327024(T) variant disrupts c-Myb binding and reduces the enhancer activity. Concordantly, c-Myb knockdown in PMA-treated Jurkat cells negates rs71327024's allele-specific effect on CXCR6 promoter activity. We conclude that a disrupted c-Myb binding site may decrease CXCR6 expression in T helper cells of individuals carrying the minor rs71327024(T) allele and thus may promote the progression of severe COVID-19 and other inflammatory pathologies.

Visualizing the Genome: Experimental Approaches for Live-Cell Chromatin Imaging.

Over the years, our vision of the genome has changed from a linear molecule to that of a complex 3D structure that follows specific patterns and possesses a hierarchical organization. Currently, genomics is becoming "four-dimensional": our attention is increasingly focused on the study of chromatin dynamics over time, in the fourth dimension. Recent methods for visualizing the movements of chromatin loci in living cells by targeting fluorescent proteins can be divided into two groups. The first group requires the insertion of a special sequence into the locus of interest, to which proteins that recognize the sequence are recruited (e.g., FROS and ParB-INT methods). In the methods of the second approach, "programmed" proteins are targeted to the locus of interest (i.e., systems based on CRISPR/Cas, TALE, and zinc finger proteins). In the present review, we discuss these approaches, examine their strengths and weaknesses, and identify the key scientific problems that can be studied using these methods.

Analysis of Activity of Human Steroidogenic Acute Regulatory Protein (STARD1) Expressed in Escherichia coli Cells.

One of the main obstacles to the successful use of Escherichia coli cells for steroid transformation in biotechnological processes is inefficient transport of steroid substrates into the cells. Here, we tested the possibility of using human cholesterol transfer protein STARD1 (steroidogenic acute regulatory protein) to increase the efficiency of steroid uptake by bacterial cells. Genetic constructs were obtained for the synthesis in E. coli BL21 (DE3) cells of a truncated version of STARD1 containing protein functional domain (residues 66-285) and STARD1 (66-285)-GFP fusion protein, both carrying bacterial periplasmic targeting sequence pelB at the N-terminus. Analysis of preparations of E. coli/pET22b/STARD1-GFP cells by fluorimetry and Western blotting confirmed that the used expression system ensured the synthesis of the heterologous protein. Using fluorescence spectroscopy, it was demonstrated that the presence of STARD1 in the cells increased the efficiency of assimilation of NBD-labeled cholesterol analogues by E. coli/pET22b/STARD1 cells 1.3-1.6 times (p < 0.05) compared to the wild-type cells, thus demonstrating that human STARD1 exhibits its functional activity in bacterial cells. This opens prospects for optimizing and using a fundamentally new approach to increase the efficiency of steroid uptake by cells - the inclusion of a specific carrier protein in the cell membrane, which can expand the arsenal of methods used to obtain strains of microorganisms for synthesis.

Recurrent Translocations in Topoisomerase Inhibitor-Related Leukemia Are Determined by the Features of DNA Breaks Rather Than by the Proximity of the Translocating Genes.

Topoisomerase inhibitors are widely used in cancer chemotherapy. However, one of the potential long-term adverse effects of such therapy is acute leukemia. A key feature of such therapy-induced acute myeloid leukemia (t-AML) is recurrent chromosomal translocations involving AML1 (RUNX1) or MLL (KMT2A) genes. The formation of chromosomal translocation depends on the spatial proximity of translocation partners and the mobility of the DNA ends. It is unclear which of these two factors might be decisive for recurrent t-AML translocations. Here, we used fluorescence in situ hybridization (FISH) and chromosome conformation capture followed by sequencing (4C-seq) to investigate double-strand DNA break formation and the mobility of broken ends upon etoposide treatment, as well as contacts between translocation partner genes. We detected the separation of the parts of the broken AML1 gene, as well as the increased mobility of these separated parts. 4C-seq analysis showed no evident contacts of AML1 and MLL with loci, implicated in recurrent t-AML translocations, either before or after etoposide treatment. We suggest that separation of the break ends and their increased non-targeted mobility-but not spatial predisposition of the rearrangement partners-plays a major role in the formation of these translocations.

Cytogenetic and molecular genetic methods for chromosomal translocations detection with reference to the KMT2A/MLL gene.

Acute leukemias (ALs) are often associated with chromosomal translocations, in particular, KMT2A/MLL gene rearrangements. Identification or confirmation of these translocations is carried out by a number of genetic and molecular methods, some of which are routinely used in clinical practice, while others are primarily used for research purposes. In the clinic, these methods serve to clarify diagnoses and monitor the course of disease and therapy. On the other hand, the identification of new translocations and the confirmation of known translocations are of key importance in the study of disease mechanisms and further molecular classification. There are multiple methods for the detection of rearrangements that differ in their principle of operation, the type of problem being solved, and the cost-result ratio. This review is intended to help researchers and clinicians studying AL and related chromosomal translocations to navigate this variety of methods. All methods considered in the review are grouped by their principle of action and include karyotyping, fluorescence in situ hybridization (FISH) with probes for whole chromosomes or individual loci, PCR and reverse transcription-based methods, and high-throughput sequencing. Another characteristic of the described methods is the type of problem being solved. This can be the discovery of new rearrangements, the determination of unknown partner genes participating in the rearrangement, or the confirmation of the proposed rearrangement between the two genes. We consider the specifics of the application, the basic principle of each method, and its pros and cons. To illustrate the application, examples of studying the rearrangements of the KMT2A/MLL gene, one of the genes that are often rearranged in AL, are mentioned.

Using a viral 2A peptide-based strategy to reconstruct the bovine P450scc steroidogenic system in S. cerevisiae: Bovine P450scc system expression using 2A peptides.

Cytochrome P450scc system performs the first rate-limiting stage of steroidogenesis in mammals. The bovine P450scc system was reconstructed in Saccharomyces cerevisiae, using a foot-and-mouth disease virus 2A peptide (F2A)-based construct, to co-express cytochrome P450scc, adrenodoxin (Adx), and adrenodoxin reductase (AdR). During the translation of the self-processing fusion protein P450scc-F2A-Adx-F2A-AdR, the first and the second linkers are cleaved with different efficiencies (96 % and 11 %, respectively), resulting in the unbalanced expression of individual proteins. The low cleavage efficiency and the relative Adx and AdR protein levels were increased through replacing the second F2A peptide with different sequences and changing the order of Adx and AdR. The P450scc, AdR, and Adx sequences located upstream of the F2A affected F2A processing, to various degrees. Moreover, using molecular dynamics (MD) simulations, we showed that the 2A peptide fused to the C-terminus of Adx formed the steric hindrance during enzymatic complex formation, resulting in the reduction of catalytic activity. Thus, the functional activity of the reconstructed P450scc system was determined not only by the efficiency of 2A peptides but also by the overall sequence of the expressed 2A-polyprotein. Our results can be applied to the development of 2A-based co-translation strategies, to produce other multicomponent protein systems.

Direct ENIT: An easy and reliable tool for gRNA efficacy verification by tracking induced chromosomal translocation.

CRISPR/Cas systems (Clustered regularly interspaced palindromic repeats / CRISPR-associated) are rapidly becoming a commonplace and popular tool for gene editing in research and clinical contexts. However, the quality of CRISPR/Cas experiments depends heavily on the guide RNA (gRNA) design; therefore, a reliable, easy, and rapid method for verifying gRNA cleavage efficacy is necessary. Engineered nuclease-induced translocations (ENIT) are an easy and cost-efficient method for the verification of gRNA efficacy, which involves tracking induced chromosomal mutations, using polymerase chain reaction (PCR). We have customized this method using both direct PCR and nested PCR approaches and have been able to reduce the sample preparation time. We present a simple and reliable gRNA testing approach that requires no specific enzymes or equipment.•The approach requires only routinely used enzymes and equipment.•Cost- and time-efficient, requiring approximately 30 min for PCR sample preparation, without requiring DNA purification.•High sensitivity, with induced translocation detected in 100 of 10,000 cells in the general population.

New 20-hydroxycholesterol-like compounds with fluorescent NBD or alkyne labels: Synthesis, in silico interactions with proteins and uptake by yeast cells.

20-hydroxycholesterol is a signaling oxysterol with immunomodulating functions and, thus, structural analogues with reporter capabilities could be useful for studying and modulating the cellular processes concerned. We have synthesized three new 20-hydroxycholesterol-like pregn-5-en-3ß-ol derivatives with fluorescent 7-nitrobenzofurazan (NBD) or Raman-sensitive alkyne labels in their side-chains. In silico computations demonstrated the compounds possess good membrane permeability and can bind within active sites of known 20-hydroxycholesterol targets (e.g. Smoothened and yeast Osh4) and some other sterol-binding proteins (human LXRß and STARD1; yeast START-kins Lam4S2 and Lam2S2). Having found good predicted membrane permeability and binding to some yeast proteins, we tested the compounds on microorganisms. Fluorescent microscopy indicated the uptake of the steroids by both Saccharomyces cerevisiae and Yarrowia lipolytica, whereas only S. cerevisiae demonstrated conversion of the compounds into 3-O-acetates, likely because 3-O-acetyltransferase Atf2p is present only in its genome. The new compounds provide new options to study the uptake, intracellular distribution and metabolism of sterols in yeast cells as well as might be used as ligands for sterol-binding proteins.

Ile351, Leu355 and Ile461 residues are essential for catalytic activity of bovine cytochrome P450scc (CYP11A1).

Cytochrome P450scc (CYP11A1) is a mammalian mitochondrial enzyme which catalyzes cholesterol side chain cleavage to form pregnenolone. Along with cholesterol, some other steroids including sterols with a branched side chain like ß-sitosterol are the substrates for the enzyme, but the activity towards ß-sitosterol is rather low. Modification of the catalytic site conformation could provide more effective ß-sitosterol bioconversion by the enzyme. This study was aimed to find out the amino acid residues substitution of which could modify the conformation of the active site providing possible higher enzyme activity towards ß-sitosterol. After structural and bioinformatics analysis three amino acid residues I351, L355, I461 were chosen. Molecular dynamics simulations of P450scc evidenced the stability of the wild type, double (I351A/L355A) and triple (I351A/L355A/I461A) mutants. Mutant variants of cDNA encoding P450scc with the single, double and triple mutations were obtained by site-directed mutagenesis. However, the experimental data indicate that the introduced single mutations Ile351A, Leu355A and Ile461A dramatically decrease the target catalytic activity of CYP11A1, and no activity was observed for double and triple mutants obtained. Therefore, isoleucine residues 351 and 461, and leucine residue 355 are important for the cytochrome P450scc functioning towards sterols both with unbranched (cholesterol) and branched (sitosterol) side chains.

Polycistronic expression of the mitochondrial steroidogenic P450scc system in the HEK293T cell line.

The cholesterol hydroxylase/lyase (CHL) system, consisting of cytochrome P450scc, adrenodoxin (Adx) and adrenodoxin reductase (AdR), initiates mammalian steroidogenesis, converting cholesterol to pregnenolone. The foot-and-mouth disease virus 2A-based method allows to express multiple proteins from a single transcript. We developed a 2A-based multicistronic system for the coexpression of three bovine CHL system proteins as the self-processing polyprotein pCoxIV-P450scc-2A-Adx-2A-AdR-GFP (pCoxIV-CHL-GFP), with a cleavable N-terminal mitochondrial targeting presequence. HEK293T cells transfected with plasmid, containing complementary DNA (cDNA) for pCoxIV-CHL-GFP, efficiently performed the expression of P450scc-2A, targeted to mitochondria, and Adx-2A, AdR-GFP and the fusion protein Adx-2A-AdR-GFP, which were predominantly localized in the cytosol. Despite the spatial separation of expressed P450scc and redox partners, the transfected HEK293T cells were able to convert the steroid substrates of cytochrome P450scc to pregnenolone, whereas control HEK293T cells were not catalytically active. The presence of 2А peptide residue on the C-terminus of P450scc did not preclude its enzymatic activity. HEK293T cells transfected with a vector directing the synthesis of only P450scc-2A demonstrated cytochrome P450scc activity comparable to that of cells expressing all three CHL system components, and to that of nature steroidogenic cells. Thus, the P450scc activity detected in cells transfected with both constructed plasmids was the result of the effective functional coupling of the bovine cytochrome P450scc and endogenous mitochondrial electron transport proteins of HEK293T cells. The produced pregnenolone did not undergo further conversion to progesterone, which indicates the absence of catalytically active 3ß-hydroxysteroid dehydrogenase. Therefore, HEK293T cells may be suitable for the expression of steroidogenic enzymes and the study of their characteristics.

MUC1 Story: Great Expectations, Disappointments and the Renaissance.

In the course of studying human mucin MUC1, the attitude towards this molecule has been changing time and again. Initially, the list of presumable functions of MUC1 was restricted to protecting and lubricating epithelium. To date, it is assumed to play an important role in cell signaling as well as in all stages of oncogenesis, from malignant cell transformation to tumor dissemination. The story of MUC1 is full of hopes and disappointments. However, the scientific interest to MUC1 has never waned, and the more profoundly it has been investigated, the clearer its hidden potential turned to be disclosed. The therapeutic potential of mucin MUC1 has already been noted by various scientific groups at the early stages of research. Over forty years ago, the first insights into MUC1 functions became a strong ground for considering this molecule as potential target for anticancer therapy. Therefore, this direction of research has always been of particular interest and practical importance. More than 200 papers on MUC1 were published in 2016; the majority of them are dedicated to MUC1-related anticancer diagnostics and therapeutics. Here we review the history of MUC1 studies from the very first attempts to reveal its functions to the ongoing renaissance.

Expression of Cholesterol Hydroxylase/Lyase System Proteins in Yeast S. cerevisiae Cells as a Self-Processing Polyprotein.

2A peptide discovered in Picornaviridae is capable of self-cleavage providing an opportunity to carry out synthesis of several proteins using one transcript. Dissociation in the 2A sequence during translation leads to the individual proteins formation. We constructed cDNA including genes of the bovine cholesterol hydroxylase/lyase (CHL) system proteins-cytochrome P450scc (CYP11A1), adrenodoxin (Adx) and adrenodoxin reductase (AdR), that are fused into a single ORF using FMDV 2A nucleotide sequences. The constructed vectors direct the expression of cDNA encoding polyprotein P450scc-2A-Adx-2A-AdR (CHL-2A) in Escherichia coli and Saccharomyces cerevisiae. The induced bacterial cells exhibit a high level of CHL-2A expression, but polyprotein is not cleaved at the FMDV sites. In yeast S. cerevisiae, the discrete proteins P450scc-2A, Adx-2A and AdR are expressed. Moreover, a significant proportion of AdR and Adx is present in a fusion Adx-2A-AdR. Thus, the first 2A linker provides an efficient cleavage of the polyprotein, while the second 2A linker demonstrates lower efficiency. Cholesterol hydroxylase/lyase activity registered in the recombinant yeast cell homogenate indicates that the catalytically active CHL system is present in these cells. Consequently, for the first time the mammalian system of cytochrome P450 has been successfully reconstructed in yeast cells through expressing the self-processing polyprotein.

Rational Design of Recombinant Papain-Like Cysteine Protease: Optimal Domain Structure and Expression Conditions for Wheat-Derived Enzyme Triticain-α.

Triticain-α is a papain-like cysteine protease from wheat (Triticumaestivum L.) that possesses activity towards toxic gluten-derived peptides, and was thus proposed as a novel therapeutic tool for celiac disease. We report an original approach employing rational design of domain architecture of Triticain-α and selection of the appropriate expression system for development of cheap and efficient protocol yielding active recombinant enzyme. The segregated catalytic domain of Triticain-α did not adopt native structure in bacteria, neither being expressed as a single protein nor upon conjugation or co-expression with extrinsic chaperones. Meanwhile, its attachment to prodomain of the enzyme resulted in generation of insoluble (inclusion bodies) product that can be transformed into active protease upon refolding in vitro. The estimated yield of the product was affected by affinity six-histidine tag required for its single-step purification with the preferable N-terminal position of the tag. Expression of the two-domain Triticain-α construct in yeast (Pichiapastoris) strain GS115 and bacterial (Escherichia coli) strain Rosetta gami B (DE3) led to the accumulation of a soluble protein, which underwent autocatalytic maturation during expression (in yeast)/purification (in bacteria) procedures and exhibited pronounced protease activity. Furthermore, expression and solubility of such construct in Rosetta gami B (DE3) cells was improved by reducing the temperature of the bacterial growth yielding more active enzyme than yeast counterpart presumably due to facilitated formation of a characteristic disulfide bond critical for maintaining the catalytic site. We suggest that these findings are helpful for obtaining active Triticain-α preparations for scientific or medical applications, and can be employed for the design and production of beneficial recombinant products based on other papain-like cysteine proteases.

RGD-based Therapy: Principles of Selectivity.

Design of selective anticancer drugs that are targeting RGD-binding integrin receptors which are known to be one of the perspective directions in the field of oncology. Significant progress in the development and application of these types compounds is already demonstrated. The accumulating body of basic and clinical evidence demonstrates potential significant effects on both in vitro and in vivo experimental models. However, the specific mechanism of action of these compounds is generally not a fully elucidated or the exact target responsible for the achievement of stated effects hasn't yet been defined sufficiently. To date eight types of integrin receptors, which are capable to recognize RGD-motif in natural ligands, has in fact been identified as (namely αIIbß3, αvß1, αvß3, αvß5, αvß6, αvß8, α5ß1, α8ß1). Even so, the estimation of the affinity of one particular RGD-bearing anticancer agent is often based on the determination of the binding efficacy to only one or rarely two integrin receptors. Traditionally the range of targets is restricted by the integrins, which are known to be highly expressed in a particular model system. While potential interactions of such an agent with other RGD-recognizing receptors usually remain beyond the research. Nonetheless, such interactions may also affect the viability and behavior of cancer cells. In this review we attempt to critically analyze the principles of selectivity achievement in the case of RGD-bearing natural ligands and the applicability of these principles in the context of the anticancer drug design.

The broken MLL gene is frequently located outside the inherent chromosome territory in human lymphoid cells treated with DNA topoisomerase II poison etoposide.

The mixed lineage leukaemia (MLL) gene is frequently rearranged in secondary leukaemias, in which it could fuse to a variety of different partners. Breakage in the MLL gene preferentially occurs within a ~8 kb region that possesses a strong DNA topoisomerase II cleavage site. It has been proposed that DNA topoisomerase II-mediated DNA cleavage within this and other regions triggers translocations that occur due to incorrect joining of broken DNA ends. To further clarify a possible mechanism for MLL rearrangements, we analysed the frequency of MLL cleavage in cells exposed to etoposide, a DNA topoisomerase II poison commonly used as an anticancer drug, and positioning of the broken 3'-end of the MLL gene in respect to inherent chromosomal territories. It was demonstrated that exposure of human Jurkat cells to etoposide resulted in frequent cleavage of MLL genes. Using MLL-specific break-apart probes we visualised cleaved MLL genes in ~17% of nuclei. Using confocal microscopy and 3D modelling, we demonstrated that in cells treated with etoposide and cultivated for 1 h under normal conditions, ~9% of the broken MLL alleles were present outside the chromosome 11 territory, whereas in both control cells and cells inspected immediately after etoposide treatment, virtually all MLL alleles were present within the chromosomal territory. The data are discussed in the framework of the "breakage first" model of juxtaposing translocation partners. We propose that in the course of repairing DNA topoisomerase II-mediated DNA lesions (removal of stalled DNA topoisomerase II complexes and non-homologous end joining), DNA ends acquire additional mobility, which allows the meeting and incorrect joining of translocation partners.

Preparation and functional evaluation of RGD-modified streptavidin targeting to integrin-expressing melanoma cells.

The vertical growth stage is the most dangerous stage of melanoma and is often associated with a poor prognosis. The increased invasiveness and metastasis that is typical for vertically growing melanoma are mediated by the molecules of cell adhesion (particularly, integrins). Integrin αvß3, which is abundantly expressed on melanoma cells with high metastatic potentials and is characterized by low expression levels in normal melanocytes, is potentially an attractive target for melanoma diagnostics and therapy. Integrin αvß3 is known to recognize the arginine-glycine-aspartic (RGD) sequence, which has been found in a wide variety of its natural ligands. Here expression vectors bearing the genes of fusion proteins have been constructed for producing these proteins in Escherichia coli. Such fusion proteins consist of a peptidic 'address,' targeting the integrins on melanoma cells, linked to an 'adaptor' for the attachment of a diagnostic or toxic agent. The peptidic 'address' contains the RGD motif, which is stabilized by a disulfide bond to achieve the optimal receptor binding conformation. The 'adaptor' is a tetrameric protein, namely, streptavidin, that is able to achieve high-affinity binding of d-biotin (K(d) = 10(-15) M) and confer avidity to the address peptide. This binding ability facilitates the generation of anti-melanoma diagnostic and therapeutic agents using the appropriate biotin derivatives. These recombinant proteins were purified from the periplasm of E.coli using columns with 2-iminobiotin agarose and demonstrated an ability to adhere to the surface of murine and human melanoma cells.

Repositioning of ETO gene in cells treated with VP-16, an inhibitor of DNA-topoisomerase II.

The translocation t(8;21)(q22;q22) affecting AML1 and ETO genes is known to be one of the frequent chromosome translocations in acute myeloid leukemia. But no data have been available up to date concerning mutual positioning of these particular genes in the nucleus of a living cell as well as the mechanism of their rapprochement and realignment. Here we show that there is no proximity between these two genes in the primary nuclei of normal human male fibroblasts and moreover that these genes are located in different nuclear layers. But we further show that treatment of cells with VP-16 (etoposide), an inhibitor of DNA topoisomerase II widely used in anticancer chemotherapy, causes the ETO gene repositioning which allows AML1 and ETO genes to be localized in the same nuclear layer. Inhibitor studies demonstrate that such an effect is likely to be connected with the formation of stalled cleavable complexes on DNA. Finally, inhibition of ETO gene repositioning by 2,3-butanedione monoxime (BDM) suggests that this process depends on nuclear myosin. Together, our data corroborate the so called "breakage first" model of the origins of recurrent reciprocal translocation.

Biochemical analysis of enhancer-promoter communication in chromatin.

Regulation of many biological processes often occurs by DNA sequences positioned over a large distance from the site of action. Such sequences, capable of activating transcription over a distance, are termed enhancers. Several experimental approaches for analysis of the mechanisms of communication over a distance between DNA regions positioned on the same molecule and, in particular, for analysis of enhancer-promoter communication were developed recently. Most of these methods are technically complicated and not applicable for studies of various important aspects of distant interactions in chromatin. As an alternative, we propose a more efficient and versatile method for the study of enhancer-promoter communication in chromatin using a prokaryotic model enhancer-promoter system that recapitulates most of the key aspects of eukaryotic transcriptional enhancer action (including action over a large distance) both in vivo and in vitro. Below we describe the application of this highly efficient experimental system to analyze the structural and dynamic properties of chromatin that allow communication between DNA regulatory regions over a distance.

Chromatin structure can strongly facilitate enhancer action over a distance.

Numerous DNA transactions in eukaryotic nuclei are regulated by elements (enhancers) that can directly interact with their targets over large regions of DNA organized into chromatin. The mechanisms allowing communication over a distance in chromatin are unknown. We have established an experimental system allowing quantitative analysis of the impact of chromatin structure on distant transcriptional regulation. Assembly of relaxed or linear DNA templates into subsaturated chromatin results in a strong increase of the efficiency of distant enhancer-promoter E-P communication and activation of transcription. The effect is directly proportional to the efficiency of chromatin assembly and cannot be explained only by DNA compaction. Transcription activation on chromatin templates is enhancer- and activator-dependent, and must be accompanied by direct E-P interaction and formation of a chromatin loop. Previously we have shown that DNA supercoiling can strongly facilitate E-P communication on histone-free DNA. The effects of chromatin assembly and DNA supercoiling on the communication are quantitatively similar, but the efficiency of enhancer action in subsaturated chromatin does not depend on the level of unconstrained DNA supercoiling. Thus chromatin structure per se can support highly efficient communication over a distance and functionally mimic the supercoiled state characteristic for prokaryotic DNA.