Individual characterization of stably expanded T cell clones in ankylosing spondylitis patients.

Ankylosing spondylitis (AS) is commonly characterized by clonal expansions of T cells. However, these clonal populations are poorly studied and their role in disease initiation and progression remains unclear. Here, we performed mass sequencing of TCR V beta libraries to search for the expanded T cell clones for two AS patients. A number of clones comprising more than 5% of the corresponding TCR V beta family were identified in both patients. For the first time, expanded clones were shown to be stably abundant in blood samples of AS patients for the prolonged period (1.5 and 2.5 years for two patients, correspondingly). These clones were individually characterized in respect to their differentiation status using fluorescent cell sorting with CD27, CD28, and CD45RA markers followed by quantitative identification of each clone within corresponding fraction using real time PCR analysis. Stable clones differed in phenotype and several were shown to belong to the proinflammatory CD27 - /CD28 - population. Their potentially cytotoxic status was confirmed by staining with perforin-specific antibodies. Search for the TCR V beta CRD3 sequences homologous to the identified clones revealed close matches with the previously reported T cell clones from AS and reactive arthritis patients, thus supporting their role in the disease and proposing consensus TCR V beta CDR3 motifs for AS. Interestingly, these motifs were also found to have homology with earlier reported virus-specific CDR3 variants, indicating that viral infections could play role in development of AS.

[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. In the current review, we summarize published data and recent results of our research aimed at the analysis of the evolutionary impact of the young retroelements group on the function and variability of the human genome. We examine modern approaches of the polygenomic identification of polymorphic retroelements inserts. Using an original Internet resource, we analyze special features of the genomic polymorphic inserts of Alu repeats. We thoroughly characterize the strategy of large-scale functional analysis of polymorphic retroelement inserts. The presented results confirm the hypothesis of the roles of retroelements as active cis regulatory elements that are able to modulate surrounding genes.

[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. Using the RT PCR method, we analyzed the pre-mRNA (heterogeneous nuclear RNA) content of allele pairs of four genes in five human cell lines, heterozygous with respect to intronic inserts of L1 and Alu elements. We showed for the first time a tissue-specific decrease in the pre-mRNA content of the gene allele bearing L1 or Alu inserts relative to the other allele of the same gene lacking the retroelement.