[Regulatory T cells].

Regulatory T-cells are a subset of T cells that have beene extensively studied in modern immunology. They are important for the maintenance of peripheral tolerance, and have an important role in various clinical conditions such as allergy, autoimmune disorders, tumors, infections, and in transplant medicine. Basically, this population has a suppressive effect on the neighboring immune cells, thus contributing to the local modulation and control of immune response. There are two main populations of regulatory T cells - natural regulatory T cells, which form a distinct cellular lineage, develop in thymus and perform their modulatory action through direct intercellular contact, along with the secreted cytokines; and inducible regulatory T cells, which develop in the periphery after contact with the antigen that is presented on the antigen presenting cell, and their primary mode of action is through the interleukin 10 (IL-10) and transforming growth factor beta (TGF-alpha) cytokines. Natural regulatory T cells are activated through T cell receptor after contact with specific antigen and inhibit proliferation of other T cells in an antigen independent manner. One of the major difficulties in the research of regulatory T cells is the lack of specific molecular markers that would identify these cells. Natural regulatory T cells constitutively express surface molecule CD25, but many other surface and intracellular molecules (HLA-DR, CD122, CD45RO, CD62, CTLA-4, GITR, PD-1, Notch, FOXP3, etc.) are being investigated for further phenotypic characterization of these cells. Because regulatory T cells have an important role in establishing peripheral tolerance, their importance is manifested in a number of clinical conditions. In the IPEX syndrome (immunodysregulation, polyendocrinopathy and enteropathy, X-linked), which is caused by mutation in Foxp3 gene that influences the development and function of regulatory T cells, patients develop severe autoimmune reactions that involve autoimmune endocrine disorders (type 1 diabetes, thyroiditis), respiratory and nutritive allergy, eczema and severe infections. In different types of allergy (pollen allergy, dust mite, nutritive allergens, contact hypersensitivity, etc.) and autoimmune diseases (such as rheumatoid arthritis, multiple sclerosis and type 1 diabetes) a lower number or decreased functional capability of regulatory T cells have been described. In inflammatory conditions and infections, this cell population has an important task in restricting immune response and protecting the host from excessive damage. This ability of regulatory T cells can be used by some pathogens (Epstein Barr virus, Mycobacterium tuberculosis, Leishmania major, etc.) and tumor cells to avoid host response and therefore contribute to the development of some pathological conditions. The knowledge gained on the phenotype and function of regulatory T cells could be useful in many medical conditions. In allergy, autoimmune diseases and in transplant procedures in medicine it would be desirable to increase their function, thus to partially suppress the immune system activity. On the other hand, in some infections and tumors, it would be preferable to decrease the activity of regulatory T cells and boost the function of effector T cells. Regulatory T cells comprise a very active field of immunology, therefore monitoring and modulating of their activity is of great potential significance in a broad spectrum of clinical conditions. By developing and standardizing methods for their monitoring, it would be possible to follow additional parameters of certain clinical conditions and possibly utilize them in therapy.