Role of thymus-eicosanoids in the immune response.

The present review deals with the role(s) of thymus-eicosanoids in the immune response. It reports the production of cyclooxygenase and lipoxygenase metabolites of arachidonic acid by cells of the thymus microenvironment and the role(s) of these eicosanoids in the differentiation and the maturation of immature T-cells. The possibility that these products may be involved in tolerance to self is discussed. Briefly, it is likely that cells from the monocyte-macrophage lineage which constitute a part of the thymus microenvironment could contribute to the education of immature thymocytes by both presenting self-antigens and producing eicosanoids. Tolerance to self might result from PGE2-driven apoptosis and/or LTB4-induced generation of suppressor cells.     

Site-specific recombination in the immune system.

Site-specific DNA recombination has been identified in a wide variety of biological systems. In vertebrates, however, the only identified use of this genetic device is in the immune system. Here it plays a critical role in generating a diverse repertoire of surface receptors to intercept invading microbes and parasites. The mechanism and orchestration of this reaction are intriguing and are relevant to a broad array of related biological and biomedical issues.     

Experimental immune complex glomerulonephritis in the mouse with two types of immune complexes.

Immune complex glomerulonephritis was induced in three groups of mice by long-term immunization. Two antigens of similar molecular weight were used. The first group was immunized with ferritin (mol wt 480,000). In altered glomeruli deposits of immune complexes were seen in the subendothelial and subepithelial spaces of the glomerular basement membrane (GBM) and in the mesangium. The immune complex deposits were formed by amorphous matrix with marked dense molecules of ferritin. The second group was immunized with human fibrinogen (mol wt 450,000). The immune complex deposits were present in the intramembranous, subepithelial and subendothelial spaces of the GBM and in the mesangium. These deposits were relatively less electron-dense and had a fine granular structure. The third group of mice were immunized with both ferritin and fibrinogen simultaneously. Two types of deposits situated subendothelially in the GBM and in the mesangium were seen in one animal of this group. One type of deposit resembled structurally the ferritin-antiferritin complex deposits, the other resembled the fibrinogen-antifibrinogen complex deposits. The individual deposits in the GBM and in the mesangium formed discrete homogeneous masses. The two types of deposit were occassionally in direct contact with one another, but were more often completely separate and were never mixed. It can be assumed that in at least some phase of the experiment both types of complex were present in the circulating blood simultaneously. However, since none of the complexes deposited in the GBM or in the mesangium were mixed, it seems probable that each type of complex is deposited separately in the form of "clusters" composed of a single type of complex. The phagocytic activity of mesangial cells of animals with complex glomerulonephritis was not increased when compared with control animals.     

Splenic role in the regulation of immune responses.

Evidence for a splenic role in regulating antibody production in other lymphoid tissue was obtained in a system in which cyclical fluctuations of splenic plaque-forming cells (PFC) occur following a single intravenous injection of aggregated human γ-globulin in rabbits. First, PFC arising simultaneously in the mesenteric nodes, peripheral blood, and spleen appear to be derived from the spleen since splenectomy prior to antigen injection abrogated these responses. Second, a noncyclical appearance of PFC in popliteal nodes of rabbits responding to subcutaneous injection of antigen was converted to a cyclical response by simultaneous intravenous injection of antigen, an effect which was abolished by splenectomy prior to antigen injection. It is suggested that, following an intravenous injection of antigen, both suppressor cells as well as antibody-forming precursors may be activated in the spleen and disseminated to other lymphoid tissue.     

Life-or-death fate in the adaptive immune system.

The tissue homeostasis is essentially realized through a precise control of cellular proliferation and death. The constant balance between expansion and contraction of different cell populations is a critical hallmark of the mammalian adaptive immune system. Immune-competent cells have to confront the survival-or-demise dilemma in primis during ontogenesis and, thereafter, in their mature life in order to maintain homeostasis, since the cellular proliferation occurring during the immune response must be counterbalanced by programmed death as the immune reaction attenuates. The programmed cell death is mainly realized through apoptosis. Perturbations in precise control of lymphocyte life-or-death balance may lead to pathological processes, such as immunodeficiencies, autoimmunity or lymphoproliferative disorders. The life-or-death fate in the human adaptive immune system is reviewed and discussed.     

Complementary idiotypy in the regulation of the immune response.

A new concept is presented for the interactions of two complementary antibodies in the immune response. These antibodies bind to each other by means of their variable sequence determinants and therefore are designated as complementary idiotypes. Under certain conditions, both complementary idiotypes are produced by the same animal at the same time. An idiotype can drastically affect the expression of the complementary idiotype in the animal, inducing a peripheral quench effect of antibody-binding activity and a central effect on the immunocompetent cell, which produces the complementary idiotype. It is proposed that complementary idiotypes might be induced during every immune response, thus playing an essential role in the regulation of the immune response.     

Maturation of the immune response in germinal centers.

Germinal centers develop in peripheral lymphatic tissue during the primary immune response and may play a crucial role in affinity maturation. We have compared the diversification of the antigen-specific repertoire of B cells, both from within and from outside the germinal centers, during the murine response to 2-phenyloxazolone (phOx). By sequencing V kappa Ox1 L-chains characteristic of phOx-specific antibodies, we show that somatic mutations accumulate in germinal center B cells and that a mutation conferring high affinity binding is found with increasing frequency. An analysis of V/D/J rearrangements suggests that this mutation occurred independently in many B cells, which were then preferentially expanded. We conclude that, although the hypermutation mechanism may be activated before germinal centers develop, affinity maturation by hypermutation and selection takes place in the germinal centers.     

Genetics of the immune response of Karakul sheep immunized with E. coli and Salmonella vaccines. I. Individual differences in the immune response

The capacity for immune response after immunization with E. coli and Salmonella vaccines has been analyzed in a population of astrakhan sheep, depending on their genotype. Sharply defined individual differences in immune response to the same antigen have been shown, and oppositely reacting animals have been selected. Among the animals showing highly pronounced reaction to one antigen (E. coli) the presence of the animals with a low level of reaction to the other antigen (Salmonella), and vice versa, has been established.