[Plasticity of nervous and immune systems in different species: the role of proteasomes].

Nervous and immune systems have many general features in their organization and functioning in various animal species from insects to mammals. These systems are capable to regulate effectively each other by exchange of information through rather small molecules like oligopeptides, cytokines, and neuropeptides. For many such molecules, that function as transmitters or signaling peptides, their origin and receptors are common within nervous and immune systems. Development of nervous and immune systems during ontogenesis and their functions in various species are controlled by the ubiquitous HYPERLINK "http://slovari.yandex.ru/proteolytic/en-ru/Medical/" \1 "longvo/" proteolytic ubiquitin-proteasome system (UPS). UPS regulates key biochemical processes in both systems by providing formation of synaptic connections and synaptic plasticity, and governs immune responses. In the review, the molecular mechanisms of functioning and interaction between nervous and immune systems are considered in different species of invertebrats and vertebrats. The role of UPS in these processes in the main subject of this review.

[Immune proteasomes in the development of rat immune system].

The dynamics of the expression of LMP7 and LMP2 proteasome subunits in embryonic and early postnatal development of rat spleen and liver is investigated in comparison with the dynamics of chymotrypsin-like and caspase-like proteasome activities and expression of MHC (major histocompatibility complex) class I molecules. The immune subunits LMP7 and LMP2 distribution in spleen and liver cells in the development process is also studied. A mutual for both organs tendency to the increase of the expression of both LMP7 subunit and LMP2 one on P21 (the 21st postnatal day) as compared to the embryonic period is discovered. However, the total proteasome level is shown to be constant. At definite development stages, the dynamics of immune subunits expression in the spleen and liver was different. In the spleen gradual enhancement of both immune subunits level being detected on P1, P18 and P21, in the liver gradual enhancement periods on E16 (the 16th embryonic day) and E18 changed to the stage of the shrink of immune subunits level on P5. This level did not reliably change till P18 and was augmented on P21. The alterations revealed were accompanied by chymotrypsin-like activity raise and caspase-like activity drop in spleen by P21 as compared with the embryonic period, which proves the enlargement of proteasome ability to form antigenic epitopes for MHC class I molecules. In the liver, both activities increased by P21 in comparison with the embryonic period. Such dynamics of caspase-like activity can be explained not only by the change of proteolytic constitutive and immune subunits, but also by additional regulatory mechanisms. Besides, it is discovered that the increment of immune subunits expression in the early spleen development is connected with the process of successive forming the white pulp by B- and T-lymphocytes enriched by immune subunits. In the liver, the growth of immune subunits level by P21 was accompanied by their expression expansion in hepatocytes, while their plunge by P5 may be related to the loss of liver function of a primary lymphoid organ of the immune system by this stage and disappearance of B-lymphocytes enriched by immune proteasomes in it. In the spleen and liver, MHC class I molecules were revealed at the periods of the raise of proteasome immune subunits level. On E21 , the liver was enriched by neuronal NO-synthase, its level decreased after birth and enhanced to P18. This fact indicates the possibility of the induction of the immune subunits LMP7 [character: see text] LMP2 expression in hepatocytes in signal way with neuronal NO-synthase participation. The results obtained prove that T-cell immune response with spleen participation as regards rat liver cells is possible starting with P19-P21 stage. First, at this period, white pulp T-area is formed in the spleen. Second, enhanced immune proteasomes and MHC class I molecules levels in hepatocytes can procure antigenic epitopes formation from foreign proteins and their delivery to cell surface for their subsequent presentation for cytotoxic T-lymphocytes.

[Changes in the proteasome function after induction of donor-specific tolerance in rats with ovarian allograft].

Induction of donor-specific tolerance in a recipient is one of the methods for enhancing acceptance of the grafts of endocrine glands in the absence of immunodepressants, which interfere with hormone production. This paper describes changes in the proteasome pool in the rat liver, spleen, and graft during the development of donor-specific tolerance after intraportally infusing the recipient with donor splenocytes with subsequent allografting of ovarian tissue into the renal capsule. It has been demonstrated that the shift in the balance in the liver and graft proteasome pools towards the variants with the LMP2 subunit determines the development of immunological tolerance and graft retention. On the contrary, an increase in the forms with the LMP7 subunit induces the immune response and graft rejection.

[Immune proteasomes in the developing rat spleen].

Changes in the structure of the rat spleen and the distribution of immune proteasomes in it during early postnatal development have been studied using double immunofluorescent staining of tissue sections with antibodies to the LMP7 immune proteasome subunit and to specific markers of T and B lymphocytes. It has been shown that the white pulp on postnatal day 5 is not yet colonized by lymphocytes and contains a smaller amount of immune proteasomes than the red pulp. At this stage, T and B lymphocytes concentrate mainly in the red pulp. On day 8, B lymphocytes occupy the marginal zone, while T lymphocytes aggregate into dense strands close to the white pulp. By day 18, T lymphocytes form periarteriolar sheaths in the white pulp, and the contents of immune proteasomes in the red and white pulp become equally high. An increase in the total content of immune proteasomes in the spleen on the third postnatal week was revealed in our previous study by Western blotting. In addition to T and B lymphocytes, immune proteasomes have also been revealed in other spleen cell types, probably in macrophages and reticular cells of the white pulp. Thus, the postnatal development of the spleen is associated with an increase in the contents of immune proteasomes in it.