Effect of the inhibition of triiodothyronine (T3) production by thiamazole on the T3 and serotonin content of immune cells

Triiodothyronine (T3) and serotonin are present in the cells of immune system (blood, peritoneal and thymic lymphocytes, monocytes and granulocytes of the blood and peritoneal fluid, mast cells). In the present experiments the effect of thiamazole, an antithyroid drug was studied on the content of these two hormones in immune cells after one and two weeks of continuous treatment (by drinking water, containing 30 mg/100 ml thiamazole, ad libitum) in adult male rats, using flow cytometric and confocal microscopic analysis. In thymic lymphocytes both hormone contents significantly increased in both time points. A significant decrease of T3 was observed in peritoneal monocytes and granulocytes also in both time points, in peritoneal mast cells after one week and in blood lymphocytes after two weeks. Serotonin content in addition to the elevated thymic values (in both measurements) was significantly reduced in blood lymphocytes after two weeks. Confocal microscopy demonstrated heterogeneous cell populations with disparate hormone content and mostly diffuse localization The experiments call attention to the presence of T3 in the immune cells and to its variable concentration under the effect of a thyrostatic drug as well, as to the T3-serotonin relationship in the cells of the immune system.     

Single treatment (hormonal imprinting) of newborn rats with serotonin increases the serotonin content of cells in adults

Hormonal imprinting takes place perinatally at the first encounter between the hormone and its target receptor, causing the finishment of the maturation of receptor-signal transduction system. In the presence of an excess of the target hormone or related molecules faulty imprinting develops with life-long consequences. In earlier experiments single neonatal treatment with minute dose of IL-6 caused also prolonged stimulation of IL-6 production. In the present experiment newborn female and male rats were treated with 20 microg serotonin (hormonal imprinting) and were studied for serotonin content of different cell types in adult age. Serotonin content was measured by flow cytometry and its localization was determined by confocal microscopy. Serotonin content was detected in white blood cells (lymphocytes, monocytes and granulocytes); in lymphocytes, monocytes (macrophages), granulocytes and mast cells of peritoneal fluid and thymic lymphocytes. Serotonin was present in all cell types of control animals studied. Serotonin content extremely elevated in the white blood cells and also increased in the peritoneal cells of neonatally treated female animals. There was no elevation in thymic lymphocytes. The mean values of male animals remained at the control level. The experiments call attention to the life-long effect of the perinatal hormonal imprinting manifested presently in the elevation of serotonin content and point to the gender differences of serotonin imprinting. Considering the role of serotonin in mood and psychiatric diseases, the observations could have some clinical importance.     

Prolonged effect of a single serotonin treatment in adult age on the serotonin and histamine content of white blood cells and mast cells of rats

Hormonal imprinting was provoked by serotonin treatment in adult age. Three weeks after treatment with 100 microg serotonin, the serotonin and histamine content of peritoneal cells (mast cells, lymphocytes and the monocyte-macrophage-granulocyte group), white blood cells (lymphocytes, granulocytes and monocytes) and thymic lymphocytes was studied by flow cytometry. The content of both amines was significantly higher in the mast cells of males and lower in females. Blood lymphocytes contained a higher serotonin and histamine level in males, and a lower serotonin level in females. The peritoneal monocyte-macrophage-granulocyte group contained less serotonin in both males and females. Thymocytes contained higher levels of both amines in females and higher histamine level in males. The experiments demonstrate that a single treatment at adult age can provoke imprinting, which alters-in the present case-the serotonin and histamine content of immune cells durably.     

Effect of single neonatal or repeated benzpyrene exposure on the serotonin content of immune cells in young male rats

In earlier experiments single benzpyrene treatment of newborn rats caused strong alterations in the endorphin content of adult rats' immune cells. In the present experiments young (4-6 weeks old) male rats were studied for demonstrating the effect of the single neonatal or repeated (neonatally and at weanling) benzpyrene exposure on the serotonin content of immune cells (blood lymphocytes, monocytes, granulocytes; peritoneal fluid lymphocytes, mast cells, monocytes and granulocytes, thymic lymphocytes). Flow cytometric analysis showed that 50 microg benzpyrene treatment of five-week-old animals was ineffective after 5 days and this was the situation four weeks after single neonatal (20 microg) benzpyrene exposure. However, the repeated treatment of neonatally benzpyrene exposed 4 weeks old animals after 5 days resulted in elevated blood and thymic lymphocyte serotonin amount and in one index (peritoneal monocyte-granulocyte group) reduced serotonin content. This means that neonatal benzpyrene treatment does not influence directly the serotonin content (production or transport) of immune cells (unlike to the endorphin content) however, sensitizes them to a following benzpyrene exposure. The results widen the list of harmful effects (influencing steroid receptor binding, sexual behavior and immune cells' endorphin content) of perinatal benzpyrene exposure.     

Effect of endorphin exposure at weaning on the endorphin and serotonin content of white blood cells and mast cells in adult rat

Hormonal imprinting takes place perinatally at the first encounter between the developing receptor and its target hormone, resulting in the accomplishment of normal receptor development. In the presence of an excess of target hormone or the absence of it, or an excess of related molecules which can be bound by the receptor, faulty imprinting develops with life-long consequences. In previous experiments neonatal endorphin exposure caused a decrease in endorphin and serotonin content of peritoneal mast cells of adult animals. In the present experiment 25-day-old (weaned) female rats received 2 microg endorphin, and the endorphin as well as serotonin content of adult mast cells and white blood cells was studied by flow cytometry and confocal microscopy. Peritoneal lymphocytes and blood monocytes contained significantly (p<0.01) less endorphin and peritoneal mast cells less serotonin (p<0.07, i.e. of questionable significance) than the untreated control. The results bring attention to the possibility of durable imprinting of differentiating cells later in life and to the durable (possibly life-long) effect of an endorphin excess (perhaps caused by injury) manifested in the change of endorphin and serotonin content of immune cells.     

Impact of neonatal imprinting with vitamin A or D on the hormone content of rat immune cells

Neonatal single vitamin A (retinol; 3 mg) or vitamin D3 (cholecalciferol; 0.05 mg) treatment (imprinting) was done in male and female rats and 2 months later the endorphin, triiodothyronine (T3) and ACTH content of immune cells (peritoneal lymphocytes, monocyte-granulocyte-macrophage group [mo-gran], mast cells and thymic lymphocytes) were studied immunocytochemically by using flow cytometry and confocal microscopy. The T3 content was significantly decreased in peritoneal lymphocytes and in mo-gran and the endorphin content decreased in thymocytes of male animals, while ACTH was decreased in female lymphocytes and mo-gran. Vitamin D treatment was absolutely ineffective. The imprinting effects of vitamins A and D and their differences are discussed. The results call attention to the possible harmful effect of vitamin treatments during the perinatal critical period.     

Prolonged effect of an H1-receptor blocker antihistamine on the histamine content of white blood cells and mast cells

Hormonal imprinting usually takes place perinatally at the first encounter between the developing receptor and its target hormone, determining the future binding capacity of the receptor for life. Molecules similar to a hormone can cause faulty imprinting also with life-long consequences. Hormone production of the imprinted cell is also durably influenced. In cytogenic organs imprinting can also be provoked in adulthood. At present the effect of a single terfenadine treatment in adult rats on the histamine content of peritoneal cells (lymphocytes, mast cells and the monocyte-macrophage-granulocyte group), white blood cells (lymphocytes, granulocytes, monocytes) and thymic lymphocytes was studied 3 weeks after treatment to clarify the effect of prolonged treatment with an antihistamine in adulthood.The cells were studied by flow cytometric analysis. Peritoneal mast cells contained significantly more and thymic lymphocytes significantly less histamine than controls. In the other cells the differences were not significant. The results support earlier observations on the effect of antihistamines on mast cell histamine release (inhibition) and call attention to the fact that this effect is durable (hormonal imprinting provoked in adults).     

Prolonged effect of stress (water and food deprivation) at weaning or in adult age on the triiodothyronine and histamine content of immune cells.

We used two days of total water and food deprivation as stress for female rats at weaning (three weeks old) and at adult age (two and a half months old). Triiodothyronine (T3) and histamine content of immune cells (lymphocytes, mast cells and monocyte-macrophage-granulocyte group in peritoneal fluid; lymphocytes, granulocytes and monocytes in blood; and lymphocytes in thymus) were studied three weeks after stress application using specific antibodies for flow cytometry and confocal microscopy. The stress at weaning increased T3 content of thymus lymphocytes. In case of adult T3, there was a cell type independent significant effect of stress, decreasing values in peritoneal fluid and slightly increasing effect in the blood. Histamine content of granulocytes was also significantly elevated. The experiments demonstrate that not only fetal or neonatal stress has long-lasting consequences, but also stress events in later periods of life in cells (organs) that are continuously differentiating. We will go on to discuss the importance of T3 and histamine in connection with stress and immunity.     

Effect of concanavalin A (Con-A) on the hormone production of the unicellular Tetrahymena and the immune cells of the rat. A comparative study

Tetrahymena populations were treated with 10(-15) g ml(-1) or 10(-6) g ml(-1) concanavalin-A (Con-A) in tryptone-yeast medium for 1 h. Rat peritoneal immune cells (mast cells, lymphocytes, monocyte-granulocyte group) were also treated with 10(-6) g ml(-1) Con-A, for 1 h. The cells' hormone (ACTH, histamine, serotonin, endorphin, triiodothyronine (T(3))) content was measured by using immunocytochemistry and flow cytometry. The extremely low dose of Con-A universally and significantly elevated the hormone contents, while the result of higher dose was uncertain. In the immune cells, Con-A significantly decreased the ACTH level in each cell type and histamine level in mast cells. The results demonstrate the very high sensitivity of Tetrahymena receptors for a non-hormone (lectin) molecule, which can bind to the insulin receptors and mimics the effect of insulin. The results also show that Tetrahymena receptors are more sensitive to lower concentrations of molecules than to higher ones. The universal hormone-production stimulating effect of Con-A-which is observed in Tetrahymena-is specified in rat.     

Thymus dependency of neonatal tolerance induction in the absence of detectable suppressor cells

Neonatal thymectomy prevents tolerance induction with bovine serum albumin (BSA) in Wistar Furth (WF) rats whose thymus-derived (T) cell deficit is reconstituted with adult nonadherent peripheral blood lymphocytes (PBL). Sham-thymectomized (STx) rats given PBL become tolerant. To establish whether the adult T cells become tolerant in STx rats, their carrier-reactivity was studied in a cooperative immune response following challenge with methylated BSA (mBSA). The results indicate that carrier-reactive cells, derived from PBL, do become tolerant of BSA in the presence, but not in the absence, of the thymus. To determine whether thymic function during tolerance induction is mediated by suppressor T cells, attempts were made to replace the thymus with various populations of thymocytes or lymphoid cells from neonatal or adult normal rats or neonatal BSA-injected rats. No cell population tried could substitute for the thymus during tolerance induction. In addition, it was found that BSA-tolerant rats with intact thymi do not contain either nonspecific suppressor cells whose activity can be boosted with mBSA or specific suppressor activity demonstrable on transfer to normal rats. Timed thymectomy experiments showed that the thymus is required for more than 2, but less than 5 to 7 days after tolerogen injection for significant tolerance induction. These results imply that the thymus itself is necessary for tolerance induction in a peripheral T-cell population and that its effect is not mediated by suppressor cells. It is suggested that peripheral T helper cells may periodically recirculate through the thymus, at least in young rats, and become tolerant of antigen complexed with Ia antigens in the thymic epithelium. Such a mechanism may be of great importance in the development of self-recognition.     

Insulin regulation of amino acid transport in mesenchymal cells from avian and mammalian tissues.

Insulin regulation of amino acid transport across the cell membrane was studied in a variety of mesenchymal cell directly isolated from avian and mammalian tissues or collected from confluent cultures. Transport activity of the principal systems of mediation in the presence and absence of insulin was evaluated by measuring the uptake of representative amino acids under conditions approaching initial entry rates. Insulin enhanced the transport rate of substrate amino acids from the A system(alpha-aminoisobutyric acid, L-proline, glycine, L-alanine and L-serine) in fibroblasts and osteoblasts from chick-embryo tissues, in mesenchymal cells (fibroblasts and smooth muscle cells) from immature rat uterus, in thymic lymphocytes from young rats and in chick-embryo fibroblasts from confluent secondary cultures. In these tissues, the uptake of amino acid substrates of transport systems L and Ly+ (L-leucine, L-phenylalanine, L-lysine) was not affected by the presence of the hormone. No insulin control of amino acid transport was detected in chick-embryo chondroblasts and rat peritoneal macrophages. These observations identify the occurrence of hormonal regulatory patterns of amino acid transport for different mesenchymal cells types and indicate that these properties emerge early during cell differentiation.     

Prolonged effect of endorphin treatment during pregnancy in the rat on the histamine content of immune cells of F1 and F2 offspring generations

Female rats were treated with beta-endorphin on the 19th day of pregnancy and the histamine content of immune cells (blood lymphocytes; peritoneal lymphocytes, monocyte-macrophage-granulocyte group, mast cells; thymic lymphocytes) of the 7-week-old progenies (F1 generation) was studied using a flow-cytometric immunocytochemical technique. In an other group, female F1 progenies of endorphin-treated mothers were mated with control males and the F2 generation was monitored for histamine content similar to the F1. In the F1 generation each cell type, except peritoneal and blood lymphocytes, contained significantly more histamine than the control cells. In the F2 generation only mast cells contained significantly more histamine relative to the appropriate control. This means that the effect of endorphin (hormonal) imprinting is transmitted transgenerationally, but with decreasing intensity however. Mast cells retained the effect of imprinting for longer than the other cells. The results are compared with the levels of serotonin in similarly treated animals, studied in earlier experiments. As the endorphin level can be elevated during pregnancy (by pain, traumatization, or other stress conditions) this can the set biogenic amine content of adult immune cells.     

Endorphin content of white blood cells and peritoneal cells in neonatally benzpyrene treated adult rats

White blood cells of rats (lymphocytes, monocytes, macrophages, granulocytes and mast cells) contain beta-endorphin. Two months after a single neonatal benzpyrene treatment (imprinting) there is an elevated level of immunoreactive endorphin in the blood and peritoneal cells of female animals and blood cells of males. The endorphin content decreased in the peritoneal cells of males. In the blood, the granulocytes of female, and the lymphocytes of male rats contained the highest amount of endorphin. In the peritoneal fluid also the granulocytes of females contained the highest amount of endorphin, in contrast to males, where the endorphin content of cells decreased and the lowest level of it was present in the lymphocytes. The experiments justify that benzpyrene treatment can durably influence endorphin levels of white blood cells and gives new data to the already known lifelong health destroying effects of perinatal benzpyrene exposition (alterations of hormone receptor binding capacity and sexual behavior).     

Effect of a single neonatal endorphin treatment on the hormone content of adult rat white blood cells and mast cells

Using flow cytometry and confocal microscopy, the presence of endorphin, serotonin and chorionic gonadotropin (hCG) was demonstrated in rat white blood cells and peritoneal mast cells. After a single neonatal treatment with beta-endorphin (hormonal imprinting), the mast cells of female rats reaching adulthood contained significantly less endorphin and serotonin, as well as slightly less hCG, than control cells. There was no change in the hormone content of the mast cells of males. The lymphocytes, monocytes and granulocytes of both sexes also contained the three hormones, but endorphin imprinting had no effect on these cells.     

Acute and delayed effect of (-) deprenyl and (-) 1-phenyl-2-propylaminopentane (PPAP) on the serotonin content of peritoneal cells (white blood cells and mast cells)

Acute and delayed (hormonal imprinting) effect of (-) deprenyl and its derivative without MAO-B inhibitory activity (-) PPAP, were studied on cells of the peritoneal fluid (lymphocytes, monocytes, granulocytes and mast cells) by flow cytometric and confocal microscopic analysis. Thirty minutes after treatment of 6-week-old female animals, deprenyl was ineffective while PPAP significantly increased the serotonin level of these cells. Three weeks after treatment at weaning, deprenyl drastically decreased the serotonin level of each cell type, while PPAP moderately but significantly increased the serotonin level of monocytes, granulocytes and mast cells. This means that the two related molecules have different effects on the immune cells, which seem to be independent of MAO-B inhibition. The experiments emphasize the necessity of studying the prolonged effects of biologically active molecules, even if they are without acute effects. As serotonin is a modulator of the immune system, the influence on immune cells of the molecules studied can contribute to their enhancing effect.     

Influence of in vitro and in vivo insulin treatment on the hormone (histamine, serotonin, endorphin and triiodothyronine) content of thymus and spleen cells

Thymic and spleen cells were treated in vitro or in vivo with insulin. The in vitro treatments were done with 10(-6), 10(-9), 10(-12) and 10(-15) M concentrations for 30 min and after that histamine, serotonin, endorphin and triiodothyronine (T3) content of the cells were detected by using antibodies to the hormones and flow cytometry as well as confocal microscopy. For in vivo treatment 1 IU/kg insulin was given for adult rats and 1 h after that the target hormone contents were determined by the same manner. Histamine and T3 content radically decreased in the thymus after in vitro treatment independent on the insulin concentrations administered. In vivo treatment halved histamine and T3 content. Serotonin content also decreased after in vitro treatment with the two higher concentrations, however the in vivo treatment did not cause a change. Histamine content was elevated after in vitro treatment in the spleen, independent on the insulin concentration. Endorphin level was not influenced at all. The experiments demonstrate that insulin is a factor which regulates the content (production, storage, secretion?) of some immunologically important molecules of the immune cells. Since each hormone molecule studied has important immunomodulatory role, the experiment points to the indirect immunomodulatory role of insulin.     

In vitro effect of biogenic amines on the hormone content of immune cells of the peritoneal fluid and thymus. Is there a hormonal network inside the immune system?

Immune cells contain different hormones and hormone-like molecules, such as insulin, endorphin, triiodothyronine (T3) histamine, serotonin. In earlier in vitro experiments insulin down-regulated histamine, serotonin and T3 content of thymus cells. Now we studied the effect of biogenic amines on the endorphin, T3, serotonin and histamine content of rat peritoneal and thymic cells. Cells were obtained from male rats of 100g body weight. 100 ng/ml serotonin or 300 ng/ml histamine was added for 30 min. After that the cells were prepared for flow cytometric analysis with antibodies to endorphin, T3, histamine and serotonin as primary antibodies and anti-rabbit IgG as secondary antibody. Finishing the measurements the cells were also studied by confocal microscopy. T3 concentration (binding of anti-T3 antibody) increased in peritoneal mast cells after serotonin treatment and in the monocyte-macrophage-granulocyte group after histamine treatment. Thymocytes' T3 content radically decreased after both treatments. Serotonin and histamine treatment also radically reduced the amine content of each other. Endorphin level was resistant to hormonal treatments. The results call attention to a possible hormonal network inside the immune system in which hormones produced by the immune cells themselves can influence each other.     

Imbalance of peripheral B lymphocytes and NK cells in rheumatoid arthritis

The study was focused on several cellular immune disorders correlated with the imbalance between peripheral blood B lymphocytes and NK cells in severe rheumatoid arthritis. By flow cytometry we calculated the proportions of T, T helper, T cytotoxic/suppressor, B lymphocytes and natural killer cells in peripheral blood. The mitogen-induced proliferation of peripheral lymphocytes was measured by tritium-labeld uridine incorporation. Experimental data highlight a connection between annomal values of the B to natural killer cells ratio and disorders of the peripheral mononuclear cells concentration. We also showed that the polyclonal proliferation capacity of peripheral lymphocytes in rheumatoid arthritis is solely related to the B to natural killer cells ratio or to the natural killer cells proportion. The study reveals a potential role of the imbalance between proportions of peripheral B lymphocytes and natural killer cells in the immune pathogenesis of rheumatoid arthritis, thus pointing out an interrelation between the adaptive and innate immune systems.     

Three-generation investigation on serotonin content in rat immune cells long after beta-endorphin exposure in late pregnancy.

Female rats were treated with beta-endorphin on the 19th day of pregnancy. Serotonin content of immune cells (peritoneal lymphocytes, monocyte-macrophage-granulocyte group (mo-gran), mast cells, blood lymphocytes, granulocytes and monocytes, thymus lymphocytes) were studied in the mothers (P-generation four weeks after delivery), in the male offspring (F1) generation (at seven weeks), in the female offspring (four weeks after their own delivery) and in their offspring (F2 generation, at seven weeks). P-mother cells' serotonin content was not influenced by endorphin treatment, while F1 generation's mo-gran and blood lymphocyte serotonin content was reduced (in contrast, histamine content of mo-gran increased). Four weeks after delivery, an increase in serotonin content was observed in the F1 generation in the peritoneal lymphocytes and mast cells as well as in blood lymphocytes. In contrast, serotonin content was reduced in blood granulocytes and monocytes. In the F2 (grandson) generation, a reduction in mast cell serotonin content and sensitization of blood and thymic lymphocytes to repeated endorphin treatment was provoked. The significant changes were more expressed in the F2 generation compared to F1, also appearing earlier. The results unequivocally suggest that the increase in endorphin levels during late pregnancy can cause permanent changes in the F1 and F2 generations, which means that the imprinting effect can be transgenerationally transmitted.     

Thymosin-beta 4 gene. Preliminary characterization and expression in tissues, thymic cells, and lymphocytes

A cDNA for rat thymosin-beta 4 was used to investigate the expression of this gene in different tissues, thymic cells, and lymphocytes. Hybridization analysis of total RNA from 13 rat tissues demonstrated the presence of an 800 nucleotides-long mRNA in all the tissues surveyed, with the highest levels in spleen, thymus, and lung. Examination of thymic cells showed that the thymosin-beta 4 gene is predominantly expressed in thymocytes. The thymosin-beta 4 mRNA was also studied in Ig+ and Ig- lymphocytes, being fourfold more abundant in Ig- than Ig+ splenic lymphocytes, whereas similar levels were found in both types of blood cells. The analysis of RNA from T cells at different maturation stages evidenced slight differences in their thymosin-beta 4 mRNA content, indicating that thymosin-beta 4 gene expression is not clearly related to the differentiation process of T cells. All these results do not support the roles for thymosin-beta 4 in cellular immunity and differentiation of lymphoid cells, suggesting a more general function for this peptide. Preliminary characterization of the human beta 4 gene by restriction analysis disclosed a complicated pattern consistent with multiple genes and/or introns. The analysis of genomic DNA from different species ranging from humans to Escherichia coli showed that this gene is only highly conserved in mammals.