Nicola Fabris

Reversibility of the thymic involution and of age-related peripheral immune dysfunctions by zinc supplementation in old mice.

With advanced ageing the zinc pool undergoes progressive reduction as shown by the low zinc plasma levels and the negative crude zinc balance, both in humans and in rodents. It has been suggested that such zinc deficiency might be involved in many age-related immunological dysfunctions, including thymic failure. The relevance of zinc for good functioning of the entire immune system is, at present, well documented. In particular, zinc is required to confer biological activity to one of the best-known thymic peptides, thymulin, which is responsible for cell-mediated immunity. In deep zinc deficiencies, in humans and other animals, the low thymulin levels are due not to a primary failure of the thymus, but to a reduced peripheral saturation of thymic hormones by zinc ions. In aged mice both a reduced peripheral saturation of the hormone and a decreased production by the thymus were present. Oral zinc supplementation in old mice (22 months old) for 1 month induced a complete recovery of crude zinc balance from negative (-1.82) to positive values (+1.47), similar to those of young animals (+1.67). A full recovery of thymic functions with a regrowth of the organ and a partial restoration of the peripheral immune efficiency, as measured by mitogen responsiveness (PHA and ConA) and natural killer cell (NK) activity, were observed after zinc supplementation. These findings clearly pin-point for relevance of zinc for immune efficiency and suggest that the age-related thymic involution and peripheral immunological dysfunctions are not intrinsic and irreversible events but are largely dependent on the altered zinc pool.

Benefit of oral zinc supplementation as an adjunct to zidovudine (AZT) therapy against opportunistic infections in aids

Abstract Zinc is perhaps the most important trace element for immune function. Congenital or acquired zinc deficiencies are associated with immune abnormalities and increased susceptibility to infectious diseases. AIDS subjects suffer from reduced zinc bioavailability, more severe in stage IV than in stage III. Such zinc deficiency causes, among other effects, a profound reduction in the biological activity of one of the thymic hormones, thymulin (zinc-facteur-timique-serique, ZnFTS). With these premises, zinc sulphate was administered orally at a daily dose of 200 mg for 30 days to AZT-treated stage III subjects with generalized lymphadenopathy (17 subjects) and stage IV subgroup C1 (12 subjects) AIDS patients. 18 stage III subjects with generalized lymphoadenopathy and 10 stage IV subgroup C1 subjects treated only with AZT served as controls. Zinc sulphate supplementation of stage III and in stage IV CI patients was followed by an increase or a stabilization in the body weight and an increase of the number of CD4+ cells and the plasma level of active zinc-bound thymulin. The frequency of opportunistic infectious episodes in the 24 months following entry into the study was reduced after zinc supplementation in stage IV C1 subjects (11 infections vs 25 in controls) and delayed in stage III zinc-treated subjects (1 infection/24 months vs 13 infections/24 months in controls). The effect of zinc on opportunistic infections is restricted to infections due to Pneumocystis carinii and Candida, whereas no variations have been observed in the frequencies of cytomegalovirus and toxoplasma infections. These data may support the benefit of zinc as an adjunct to AZT therapy in AIDS pathology.

Plasticity of neuroendocrine-thymus interactions during aging.

Thymic regrowth and reactivation of thymic endocrine activity may be achieved even in old animals by different endocrinological or nutritional manipulations such as, (a) intrathymic transplantation of pineal gland or treatment with melatonin, (b) implantation of a growth hormone (GH) secreting tumor cell line or treatment with exogenous GH, (c) castration or treatment with exogenous luteinizing hormone-releasing hormone (LH-RH), (d) treatment with exogenous thyroxine or triiodothyronine, and (e) nutritional interventions such as arginine or zinc supplementation. These data strongly suggest that thymic, involution is a phenomenon secondary to age-related alterations in neuroendocrine-thymus interactions and that it is the disruption of such interactions in old age that is responsible for age-associated dysfunction. With regard to the mechanisms involved in hormone-induced thymic reconstitution, it is at present, difficult to draw any definitive conclusions. The effect of GH, thyroid hormones, and LH-RH may be due to the presence on thymic epithelial cells supposed to produce thymic peptides, of the specific hormone receptors. Melatonin or other pineal factors may also act through specific receptors, but experimental evidence is still lacking. The role of zinc, whose turnover is usually reduced in old age, is diverse. The effects range from the reactivation of zinc-dependent enzymes, required for both cell proliferation and apoptosis, to the reactivation of thymulin, a zinc-dependent thymic hormone. The role of zinc may even be more crucial. According to recent preliminary data obtained both in animal and human studies, it appears that the above reported endocrinological manipulations capable of restoring thymic activity in old age, may act also by normalizing the altered zinc pool.

Pituitary-thyroid axis and immune system: a reciprocal neuroendocrine-immune interaction.

A good body of experimental and clinical results has supported the existence of numerous reciprocal interactions among the nervous, endocrine and immune systems. Increasing evidence has been accumulated in the last years on the interaction between pituitary-thyroid hormones and the immune system on the basis of either the existence of receptors for thyreotropic and thyroid hormones on lymphocytes or the frequent immune alteration in physiological and pathological fluctuations of thyroid hormones. The data were obtained either in animals with experimentally induced hyper- or hypothyroidism or in humans with various hyperthyroid or hypothyroid situations. Conversely, immune-derived products such as lymphokines and monokines have been shown able to influence the pituitary-thyroid axis modulating either the thyroid hormone levels or the hormone/cytokine production by thyrocytes. The present paper aims at summarizing the data available on the existence of thyroid-immune interactions, and at analyzing the possible integration between pituitary-thyroid hormones and immune factors in favoring the development and maintenance of both thymic and peripheral immune efficiency. The relevance of pituitary-thyroid-immune interactions is discussed for its implication in the ageing process.

Dose-dependent opposite effect of zinc on apoptosis in mouse thymocytes

Zinc is a crucial nutritional component required for the normal development and maintenance of immune functions. It has been reported that zinc is a potent inhibitor of DNA fragmentation, the specific marker of apoptosis. The effect of zinc on apoptotic cell death has been previously studied in a narrow range of high zinc concentrations, and the role of physiological zinc doses has not yet been elucidated. In this paper we evaluate the effect of in vitro Zn2+ administration at concentrations higher than, corresponding to, and lower than the physiological concentration, in thymocytes from young mice. We demonstrate that Zn2+ has an opposite effect on apoptosis, inhibiting or increasing it depending on the Zn2+ concentration used. High Zn2+ concentrations (from 600 to 75 microM) inhibit both serum-free medium and DEX-induced thymocyte apoptosis. Low Zn2+ concentrations (from 15 to 7.5 microM) induce apoptosis or increase serum-free medium-induced apoptosis. The effect of low Zn2+ concentrations on DEX-induced apoptosis is dependent on the length of incubation, since Zn2+ has an additive effect with DEX in inducing DNA fragmentation at 8 h of culture, whereas it blocks DEX-induced apoptosis after 20 h incubation. Both DEX and 15 microM Zn(2+)-induced DNA fragmentation require protein synthesis, being blocked through cycloheximide. The inhibiting and inducing effects of Zn2+ on apoptosis are exerted on G0/G1 phase thymocytes. The inhibiting effect of Zn2+ on apoptosis is related to an increase in the number of CD4+CD8+ thymocytes. Concentrations of Zn2+ inducing apoptosis sometimes cause a decrease of CD4+CD8+ cells with a corresponding increase of CD4+CD8-thymocytes. These data show that in vitro Zn2+ has a dose-dependent opposite effect on apoptosis, suggesting that Zn2+ not only acts as an inhibitor but also plays a more complex role in physiological intrathymic cell selection.

Effect of melatonin and pineal grafting on thymocyte apoptosis in aging mice.

We have evaluated the effect of chronic melatonin (MEL) treatment or pineal grafting (PG) in old mice on the apoptosis of both thymocytes and spleen lymphocytes under conditions of either serum deprivation or glucocorticoid or zinc administration. The apoptosis was correlated with the modulation of thymus and adrenal weight and corticosterone and zinc plasma levels induced by MEL treatment or PG in old mice. Balb/c mice (17-18 months old) were given supplements of MEL (40-50 micrograms/day/mouse) or grafted with a young pineal gland and then sacrificed after 8 months. Both the MEL treatment and PG partially prevented thymic involution in very old mice. Both treatments protected the thymic and spleen lymphocytes in old mice from the apoptosis induced by serum deprivation and recovered the reduced thymocyte sensitivity to the apoptosis induced by dexamethasone (DEX), present in old untreated animals, to the values found in young mice. DEX caused a bigger loss of G D /G 1 phase cells in MEL treated mice than in old untreated mice. The protective action of MEL treatment or PG on serum deprivation induced apoptosis was correlated with increased thymus weight, reduced adrenal weight and corticosterone levels and increased zinc plasma levels. The greater DEX-induced apoptosis found in MEL treated and PG mice was correlated with reduced adrenal weight and function. In vitro MEL did not affect thymocyte apoptosis in young or old mice. These results suggest that MEL treatment or PG prevent age-related thymus involution through regulation of thymocyte apoptosis which, in turn, occurs through modulation of the pituitary-adrenal axis and zinc turnover determined by the pineal hormone.

Zinc, thymic endocrine activity and mitogen responsiveness (PHA) in piglets exposed to maternal aflatoxicosis B1 and G1

Growth retardation, thymic involution and impaired peripheral immune efficiency are constant events in piglets exposed to maternal aflatoxicosis. Zinc may play a key role because of its requirement for good immune responses, including thymic endocrine activity. Zinc is required to activate a thymic hormone, i.e. thymulin (ZnFTS), which is responsible for cell-mediated immunity. Zinc deficiency and decreased thymic endocrine activity are present in piglets fed from sows exposed to aflatoxins (AF) B1 and G1 as compared with healthy control piglets. In particular, active ZnFTS is decreased while concentrations of inactive thymulin (FTS) are high. The in vitro addition of zinc up to the plasma samples induces a reduction of inactive thymulin. The lymphocytes mitogen responsiveness (PHA) is decreased and a thymic cortical lymphocyte depletion is also present. These data suggest that the thymic defect, followed by impaired peripheral immune efficiency, may largely depend by the low peripheral zinc bioavailability to saturate all thymulin molecules produced.

Influence of growth hormone on thymic endocrine activity in humans

The thymus produces humoral factors that induce the proliferation and differentiation of T cells which are responsible for cell-mediated immunity. Experimental data have suggested that this thymic hormone production is modulated by the neuroendocrine network and, in particular, by growth hormone (GH) and thyroid hormones. To study the role played by GH in thymic endocrine activity in humans, the circulating level of one of the best known thymic peptides, i.e. thymulin (Zn-FTS), has been determined, after a washout period of 2 weeks without GH treatment, in GH-deficient children before and after a single injection of GH. The basal thymulin level is consistently lower in GH-deficient children than in healthy age-matched controls. A single injection of GH induces a significant increment of the thymulin level for at least 48 h. Since thymulin activity may also depend on zinc bioavailability, on thyroid hormone turnover and on the eventual presence of thymulin-inhibitory substances, all these aspects have been checked. No supporting evidence regarding the existence of these kinds of interferences in GH-deficient children has been substantiated. A positive correlation has been found between the serum level of insulin-like growth factor I, but not of GH, and thymulin activity. These data suggest that GH may directly or indirectly modulate the thymic endocrine function in humans. Whether and to what extent such a modulation is relevant to the functioning of the immune system remains to be ascertained.

Improvement in the proliferative capacity and natural killer cell activity of murine spleen lymphocytes by thyrotropin

In the present study we investigated the effect of thyrotropin (TSH) on both the proliferative capacity and the natural killer (NK) cell activity of murine spleen lymphocytes. It was found that TSH at various concentrations significantly increased the proliferative response of mouse lymphocytes to both concanavalin A (Con A) and phytohemagglutinin (PHA). This increase was particularly evident when suboptimal concentrations of mitogens were used (40-50% increase). The administration to cell cultures of TSH alone could not induce a significant stimulation of proliferative capacity. In order to provide a better knowledge about the mechanism by which TSH improved the mitogen-induced lymphocyte proliferation, the effect of the pituitary hormone on lymphocytes directly stimulated with recombinant interleukin-2 (RIL-2), was examined. It was observed that there was a great increase in IL-2-induced lymphocyte proliferation by TSH. The improvement in proliferative capacity of lymphocytes was particularly evident by using suboptimal rIL-2 concentrations (25-30% increase). The studies carried out on the cytotoxic activity of NK cells showed that TSH was able to significantly increase the IL-2-induced NK cell activity without modifying the basal levels of cytotoxicity. The results support the immunoregulatory role of TSH and contribute towards understanding the mechanisms of interaction between neuroendocrine and immune systems.

Zinc-Dependent Low Thymic Hormone Level in Type I Diabetes

Zinc is required for optimal functioning of the immune system. It was recently reported that one of the best-known thymic hormones responsible for the maturation and differentiation of the thymus-derived T-lymphocyte line, i.e., serum thymic factor (STF), is biologically active only when bound to zinc ions; in this form it has been called thymulin (Zn-STF). Because low serum and tissue zinc values have been reported to occur in diabetic conditions, and because defects of T-lymphocyte–dependent functions are also present in diabetic patients, even metabolically well-controlled diabetic patients, we investigated the serum level of zinc and the plasma level of both active Zn-STF and inactive STF thymic hormones in 15 young patients suffering from type I (insulin-dependent) diabetes. Serum zinc levels were significantly reduced in diabetic conditions and did not correlate with the degree of metabolic compensation measured by glycosylated hemoglobin. In diabetes, the active form of thymulin is strongly reduced, whereas the inactive form is abnormally elevated. In vitro zinc addition to diabetic plasma samples also induces zinc saturation of inactive thymic hormone molecules: the total thymic hormone measured in these experimental conditions shows values in diabetic patients comparable with those observed in healthy age-matched individuals, suggesting that low thymulin levels recorded in diabetic conditions are due not to a thymic failure in synthesizing and secreting thymic hormone but to a peripheral defect in zinc saturation of the hormone molecules. The zinc-dependent failure of thymic hormone, present even in fairly compensated diabetic conditions, might account for the apparent insulin-independent immunological abnormalities associated with type I diabetes.