[A novel approach to identification of somatic retroelements' insertions in human genome].

The activity of retroelements is one of the factors leading to genetic variability of the modern humans. Insertions of retroelements may result in alteration of gene expression and functional diversity between cells. In recent years an increasing amount of data indicating an elevated level of retroelements' mobilisation in some human and animal tissues has been reported.

[The functional analysis of polymorphic insertions of Alu retroelements at acute lymphoblastic leukemia].

Human genome variability observed within patient cohorts is considered as a goal of functional genomics essential for personalized medicine progress. In the current research we implement functional analysis of 31 polymorphic Alu insertions located within gene introns for individual genomes of patients with acute lymphoblastic leukemia (ALL). As a result we demonstrated a decrease of the primary transcripts content for 21 Alu-containing alleles.

[The oligoclonal expansion of T cells: study of its stability over time].

A novel experimental approach to the investigation of the repertoire of peripheral T lymphocytes of patients suffering from ankylosing spondylitis (AS) is proposed. This approach is based on the wide-range sequencing of cDNA of the beta-chain of the T-cellular receptor (TcR). The results of the analysis of the diversity of sequences of the TcR antigen-binding domain (CDR3) inside the total pool of one patient with AS are presented by the example of the second V family (BV2) of TcR.

[Retroposons in modern human genome evolution].

The ascertainment of the rates and driving forces of human genome evolution along with the genetic diversity of populations or separate population groups remains a topical problem of fundamental and applied genomics. According to the results of comparative analysis, the most numerous human genome structure peculiarities are connected with the distribution of mobile genetic retroelements - LTR, LINE1, SVA, and Alu repeats. Due to the wide distribution in different genome loci, conversed retropositional activity, and the retroelements regulatory potential, let us regard them as one of the significant evolutionary driving forces and the source of human genome variability.

[A new database on polymorphic retroelements in human genome (PRED)].

Comparison of primate genomes sequences has confirmed the evidence that substantial part of intra- and interspecies differences is provided by retroelements. Human genome contains thousands of polymorphic retroelement copies considered to be perspective molecular genetic markers of new generation. However utilization of polymorphic retroelements as molecular genetic markers is limited due to lack of systematic data on their number, genomic context and distribution among human populations.

[A tissue-specific decrease in the pre-mRNA level of L1- and alu-containing alleles of human genes].

LINE1 and Alu retroelements occupy approximately 17 and 13% of the human genome, respectively. They include the evolutionarily youngest element groups Ta-L1, AluYa5, and AluYb8, many inserts of which are polymorphous in the Homo sapiens population. Despite the data on the ability of L1 and Alu elements to cause various modifications of the genome, the effects of these retroelements on gene expression have yet not been studied.

[The tissue-specific methylation of human-specific endogenous retroviral long terminal repeats].

A possible involvement of retroelements in the epigenetic regulation of human gene expression was considered by the example of methylation of long terminal repeats (LTRs) of the human endogenous retrovirus family K (HERV-K). The methylation status of six HERV-K LTRs was determined in various gene-enriched regions of the human genome. The methylation of four LTRs was shown to be tissue-specific.

[Genetic structure of people from the Volga-Ural region and Central Asia from data of Alu-polymorphism].

Nine Alu loci (Ya5NBC5, Ya5NBC27, Ya5NBC148, Ya5NBC182, YA5NBC361, ACE, ApoA1, PV92, TPA25) were analyzed in six ethnic populations (Trans-Ural Bashkirs, Tatars-Mishars, Mordovians-Moksha, Mountain Maris, Udmurts, and Komi-Permyaks) of the Volga-Ural region and in three Central Asian populations (Uzbeks, Kazakhs, and Uigurs). All Alu insertions analyzed appeared to be polymorphic in all populations examined. The frequency of insertion varied from 0.

[Nucleotide sequences of long terminal repeats of the human endogenous retrovirus (LTR HERV-K) on the short arm of chromosome 7: identification, analysis and evaluation of transcriptional activity].

Six clones containing long terminal repeat (LTR) sequences of human endogenous retrovirus of the HERV-K family were found in the YAC library (1200 kb) of the short arm of human chromosome 7. The sequence sizes of the three clones corresponded to the full-length LTR (969 bp). The LTR localization was determined using FISH and verified by comparison with the GenBank database.

[Human genome-specific HERV-K intron LTR genes have a random orientation relative to the direction of transcription, and, possibly, participated in antisense gene expression regulation].

A consensus nucleotide sequence of long terminal repeats (LTRs) of endogenous human-specific retroviruses of the K family (HERV-K) was constructed and used for the genome-wide search for homologies in international databases. There were revealed 142 LTRs, 12 of which were localized in introns of unique human genes. It was found for the first time that ten intron LTRs are absent in the orthologic loci of the chimpanzee genome and the orientation of nine of them is opposite to the transcription direction of the corresponding human genes.

[Enhancer activity of solitary long terminal repeat of the human endogenous retrovirus of the HERV-K family].

The transient expression of the luciferase reporter gene helped us to detect a tissue-specific enhancer activity of the solitary extraviral long terminal repeat (LTR) of the human endogenous retrovirus K (HERV-K). The LTR was previously mapped to the 19q13.2 locus.

[Long terminal repeat of the human endogenous retrovirus HERV-K in the intron of the ZNF91 gene].

The relative positions of the ZNF91 gene (exon-intron organization) and the HERV-K human endogenous virus long terminal repeat (LTR), which was earlier found to be located in the ZNF91 gene locus, on the EcoRI restriction metric map of the human chromosome 19 were determined with a high resolution. The direction of the ZNF91 gene transcription relative to the chromosome 19 telomeres was determined. The HERV-K LTR was localized to the ZNF91 gene intron 19.

[New putative gene from human retrovirus-containing locus on chromosome 19].

By means of cDNA selection, a cDNA clone corresponding to a putative gene was isolated. The identified gene was mapped to human chromosome 19 (region 19q12) to the locus containing the human endogenous retrovirus HERV-K LTR. The distance between the LTR and the cDNA fragment is about 20 kb.

[Structural characteristics of four long terminal repeats (LTR) of human endogenous retroviruses and features of their integration sites].

Four LTR-containing regions of human chromosome 19 were sequenced by the primer walking technique using strings of short oligonucleotides tightly bound to the template. A comparative and evolutionary analysis of sequences homologous to human endogenous retroviruses (HERV) was performed, and the prototypes of the LTRs were determined. Analysis of the chromosome 19 sequences adjacent to LTR revealed that LTRs of HERV-K share a common location with other retroposons.

[Isolation and characteristics of an ordered library of transcribed sequences of human chromosome 19 from hybrid human-hamster cells].

A new technique based on Alu-PCR amplification of hn-RNA is described for the extraction of human-specific transcribed sequences from a hybrid cell line. Arrayed library of hn-cDNA was constructed and characterized by sequencing about 80 individual clones. A high enrichment by human-specific sequences (about 95%) was demonstrated.

[Primary structure of the E. coli DNA region preceding the tryptophan operon genes].

The nucleotide sequence of 1179 b.p. preceding the trp operon genes has been established.