Sergey B. Akopov

Long terminal repeats of human endogenous retrovirus K family (HERV-K) specifically bind host cell nuclear proteins

Solitary long terminal repeats (LTRs) of the human endogenous retroviruses, scattered in several thousand copies throughout the human genome, are potentially capable of affecting the expression of closely located genes. To assess their regulatory potential, the LTR sequences of one of the most abundant HERV families (HERV‐K) were screened for the presence of binding sites for the host cell nuclear factors using mobility shift and UV‐crosslinking assays. It was shown that the LTR sequences of two subfamilies harbor a specific binding site for a complex consisting of at least three proteins, ERF1, ERF2 and ERF3 of 98, 91 and 88 kDa apparent molecular mass, respectively. This binding site is located in the 5′ region of the LTR U3 element. The preservation of the specific protein binding site in different HERV‐K LTR sequences suggests their possible role in regulation of nearby located genes.

Induction of transcription within chromosomal DNA loops flanked by MAR elements causes an association of loop DNA with the nuclear matrix.

The spatial organization of an ∼170 kb region of human chromosome 19, including CD22 and GPR40–GPR43 genes, was studied using in situ hybridization of a set of cosmid and PAC probes with nuclear halos prepared from proliferating and differentiated HL60 cells. The whole region under study was found to be looped out into the nuclear halo in proliferating cells. It is likely that the loop observed was attached to the nuclear matrix via MAR elements present at the flanks of the area under study. Upon dimethyl sulfoxide-induced differentiation of the cells the looped fragment became associated with the nuclear matrix. This change in the spatial organization correlated with the activation of transcription of at least two (CD22 and GPR43) genes present within the loop. The data obtained are discussed in the framework of the hypothesis postulating that the spatial organization of chromosomal DNA is maintained via constitutive (basic) and facultative (transcription-related) interactions of the latter with the nuclear matrix.

Vertebrate Protein CTCF and its Multiple Roles in a Large-Scale Regulation of Genome Activity

The CTCF transcription factor is an 11 zinc fingers multifunctional protein that uses different zinc finger combinations to recognize and bind different sites within DNA. CTCF is thought to participate in various gene regulatory networks including transcription activation and repression, formation of independently functioning chromatin domains and regulation of imprinting. Sequencing of human and other genomes opened up a possibility to ascertain the genomic distribution of CTCF binding sites and to identify CTCF-dependent cis-regulatory elements, including insulators. In the review, we summarized recent data on genomic distribution of CTCF binding sites in the human and other genomes within a framework of the loop domain hypothesis of large-scale regulation of the genome activity. We also tried to formulate possible lines of studies on a variety of CTCF functions which probably depend on its ability to specifically bind DNA, interact with other proteins and form di- and multimers. These three fundamental properties allow CTCF to serve as a transcription factor, an insulator and a constitutive dispersed genome-wide demarcation tool able to recruit various factors that emerge in response to diverse external and internal signals, and thus to exert its signal-specific function(s).

Identification, genome mapping, and CTCF binding of potential insulators within the FXYD5-COX7A1 locus of human chromosome 19q13.12.

Identification of insulators is one of the most difficult problems in functional mapping of genomes. For this reason, up to now only a few insulators have been described. In this article we suggest an approach that allows direct isolation of insulators by a simple positive-negative selection based on blocking enhancer effects by insulators. The approach allows selection of fragments capable of blocking enhancers from mixtures of genomic fragments prepared from up to 1-Mb genomic regions. Using this approach, a 1-Mb human genome locus was analyzed and eight potential insulators were selected. Five of the eight sequences were positioned in intergenic regions and two were within introns. The genes of the α-polypeptide H+/K+ exchanging ATPase (ATP4A) and amyloid β (A4) precursor-like protein 1 (APLP1) within the locus studied were found to be flanked by insulators on both sides. Both genes are characterized by distinct tissue-specific expression that differs from the tissue specificity of the surrounding genes. The data obtained are consistent with the conception that insulators subdivide genomic DNA into loop domains that comprise genes characterized by similar expression profiles. Using chromatin immunoprecipitation assay, we demonstrated also that at least six of the putative insulators revealed in this work could bind the CTCF transcription factor in vivo. We believe that the proposed approach could be a useful instrument for functional analysis of genomes.

Structure and Functions of Nuclear Matrix Associated Regions (S/MARs)

Modern concepts on the chromatin loop–domain organization and the role of the DNA regions specifically binding the nuclear matrix or nuclear scaffold (S/MARs) during its formation, maintenance, and regulation are discussed. Some S/MAR structural features, properties of binding the nuclear matrix, and probable mechanisms of their involvement in the gene regulation of activity are considered.

The clustering of CpG islands may constitute an important determinant of the 3D organization of interphase chromosomes

We used the 4C-Seq technique to characterize the genome-wide patterns of spatial contacts of several CpG islands located on chromosome 14 in cultured chicken lymphoid and erythroid cells. We observed a clear tendency for the spatial clustering of CpG islands present on the same and different chromosomes, regardless of the presence or absence of promoters within these CpG islands. Accordingly, we observed preferential spatial contacts between Sp1 binding motifs and other GC-rich genomic elements, including the DNA sequence motifs capable of forming G-quadruplexes. However, an anchor placed in a gene/CpG island-poor area formed spatial contacts with other gene/CpG island-poor areas on chromosome 14 and other chromosomes. These results corroborate the two-compartment model of the spatial organization of interphase chromosomes and suggest that the clustering of CpG islands constitutes an important determinant of the 3D organization of the eukaryotic genome in the cell nucleus. Using the ChIP-Seq technique, we mapped the genome-wide CTCF deposition sites in the chicken lymphoid and erythroid cells that were used for the 4C analysis. We observed a good correlation between the density of CTCF deposition sites and the level of 4C signals for the anchors located in CpG islands but not for an anchor located in a gene desert. It is thus possible that CTCF contributes to the clustering of CpG islands observed in our experiments.

Tissue specificity of methylation of cytosines in regulatory regions of four genes located in the locus FXYD5-COX7A1 of human chromosome 19: correlation with their expression level.

In this study, we compared degree of methylation of selected CpG sites in CCGG sequences located in promoter regions of four human genes with expression level of these genes in several human cell lines and tissues. These genes were subdivided into two groups according to the dependence of their expression on CpG methylation in the 5′-regions. The first group, characterized by clear correlation of methylation with the transcription level, includes housekeeping gene COX6B (the absence of methylation unambiguously correlates with expression) and urothelium-specific uroplakin gene (the methylation coincides with absence of expression). The second group includes genes that are expressed in many, but not all tissues and cells. For these genes (LEAP-1 and ATP4A), there was no correlation between methylation and expression. It is possible that methylation provides some basal level of gene repression, which is overcome by binding of tissue-specific transcription factors, whereas lack of methylation gives the opportunity for gene expression in various cells and tissues.

Human PSENEN and U2AF1L4 genes are concertedly regulated by a genuine bidirectional promoter

Head-to-head genes with a short distance between their transcription start sites may constitute up to 10% of all genes in the genomes of various species. It was hypothesized that this intergenic space may represent bidirectional promoters which are able to initiate transcription of both genes, but the true bidirectionality was proved only for a few of them. We present experimental evidence that, according to several criteria, a 269 bp region located between the PSENEN and U2AF1L4 human genes is a genuine bidirectional promoter regulating a concerted divergent transcription of these genes. Concerted transcription of PSENEN and U2AF1L4 can be necessary for regulation of T-cell activity.

[Regulatory potential of S/MAR elements in transient expression].

S/MARs (scaffold/matrix attachment regions) are the DNA regions that are involved in the interaction with the nuclear matrix and are identified by in vitro methods. According to the available information, S/MARs possess an insulating activity, i.e., the ability to block the interaction between the enhancer and promoter in vivo, and are, probably, intact insulators or their fragments. Nevertheless, there is still no direct proof for this correspondence. To obtain additional information on the insulator activity of S/MARs, we selected five DNA fragments of different lengths and affinities for the nuclear matrix from a previously constructed library of S/MARs and tested their ability to serve as insulators. Two of five elements exhibited an insulator (enhancer blocking) activity upon the transient transfection of CHO cells. None of the S/MARs displayed either promoter or enhancer/silencer activities in these cells.

Dam methylase accessibility as an instrument for analysis of mammalian chromatin structure.

For a 140-kb human genome locus, an analysis of the distribution of Dam methylase accessible sites, DNase I sensitive and resistant regions, unmethylated CpG sites and acetylated histone H3 molecules was performed and compared with transcriptional activity of the genes within the locus. A direct correlation was found between the extent of Dam methylation and C5 cytosine (CpG) methylation. It was also demonstrated that promoter regions of all highly and moderately transcribed genes are highly accessible to methylation by Dam methylase. In contrast, promoters of non-transcribed genes showed a very low extent of Dam methylation. Promoter regions of non-transcribed genes were also highly CpG methylated, and the promoter and more distant 5‘-regions of the housekeeping gene COX6B1 were substantially CpG-demethylated. Some highly Dam methylase accessible regions are present in the intergenic regions of the locus suggesting that the latter contain either unidentified non-coding transcripts or extended regulatory elements like locus control regions.