Thymic hormone containing cells--IX. Steroids in vitro modulate thymulin secretion by human and murine thymic epithelial cells

Oestrogen receptor distribution related to functional thymus anatomy of the European sea bass, Dicentrarchus labrax

In jawed vertebrates, the crosstalk between immune and endocrine system as well as many fundamental mechanisms of T cell development are evolutionary conserved. Oestrogens affect mammalian thymic function and plasticity, but the mechanisms of action and the oestrogen receptors involved remain unclear. To corroborate the oestrogenic regulation of thymic function in teleosts and to identify the implicated oestrogen receptor subtypes, we examined the distribution of nuclear and membrane oestrogen receptors within the thymus of the European Sea bass, Dicentrarchus labrax, in relation to its morpho-functional organisation. Immunohistological analysis specified thymus histology and organisation in teleosts and described, for the first time, Hassall's corpuscle like structures in the medulla of sea bass. All oestrogen receptors were expressed at the transcript and protein level, both in T cells and in stromal cells belonging to specific functional areas. These observations suggest complex regulatory actions of oestrogen on thymic function, notably through the stromal microenvironment, comprising both, genomic and non-genomic pathways that are likely to affect T cell maturation and trafficking processes. Comparison with birds, rodents and humans supports the thymic localization of oestrogen receptors and suggests that oestrogens modulate T cell maturation in all gnathostomes.

Effects of GnRH immunization on the reproductive axis and thymulin

The bidirectional regulation of thymulin in the reproductive-endocrine function of the hypothalamic-pituitary-gonadal (HPG) axis of rats immunized against GnRH remains largely unclear. We explored the alterations in hormones in the HPG axis in immunized rats to dissect the repressive effect of immunization on thymulin, and to clarify the interrelation of reproductive hormones and thymulin in vivo. The results showed that, in the first 2 weeks of booster immunization, thymulin was repressed when reproductive hormones were severely reduced. The self-feedback regulation of thymulin was then stimulated in later immune stages: the rising circulating thymulin upregulated LH and FSH, including GnRH in the hypothalamus, although the levels of those hormones were still significantly lower than in the control groups. In astrocytes, thymulin produced a feedback effect in regulated GnRH neurons. However, in the arcuate nucleus (Arc) and the median eminence (ME), the mediator of astrocytes and other glial cells were also directly affected by reproductive hormones. Thus, in immunized rats, the expression of glial fibrillary acidic protein was distinctly stimulated in the Arc and ME. This study demonstrated that thymulin was downregulated by immunization against GnRH in early stage. Subsequently, the self-feedback regulation was provoked by low circulating thymulin. Thereafter, rising thymulin levels promoted pituitary gonadotropins levels, while acting directly on GnRH neurons, which was mediated by astrocytes in a region-dependent manner in the hypothalamus.

Thymulin-based gene therapy and pituitary function in animal models of aging

Thymulin is a thymic hormone exclusively produced by the thymic epithelial cells. After its discovery and initial characterization in the 1970s, it was demonstrated that thymulin production and secretion is strongly influenced by the neuroendocrine system. Conversely, a growing core of information, to be reviewed here, points to thymulin as a hypophysiotropic peptide. Additionally, thymulin was shown to possess anti-inflammatory and analgesic properties in the brain. In recent years, a synthetic DNA sequence coding for a biologically active analog of thymulin, metFTS, was constructed and cloned in different adenoviral vectors. These include bidirectional regulatable Tet-Off vector systems that simultaneously express metFTS and green fluorescent protein and that can be downregulated reversibly by the addition of the antibiotic doxycycline. A number of recent studies suggest that thymulin gene therapy may be a suitable therapeutic strategy to prevent some of the endocrine and reproductive alterations that typically appear in congenitally athymic (nude) mice, taken as a suitable model of neuroendocrine and reproductive aging. The present article briefly reviews the literature on the physiology of the thymulin-pituitary axis as well as on the new molecular tools available to exploit the therapeutic potential of thymulin.

Thymus hormones as prospective anti-inflammatory agents

IMPORTANCE OF THE FIELD

Inflammatory diseases are characterized by severe immune imbalances, leading to excessive or inappropriate release of mediators, which, in turn, result in massive damage to organs and systems. Effective means to control inappropriate immune reactions are often life-critical needs. Available data on the role of thymus-derived hormones in inflammation show their great potential.

AREAS COVERED IN THIS REVIEW

The review aims to systematize information for the last two decades on immune system regulation by thymic peptide hormones, with a primary focus on the role of these hormones in the systemic inflammatory response and inflammatory diseases. Anti-inflammatory potential of three thymic hormones - thymulin, thymosin-alpha, and thymopoietin - is discussed, reviewing recently published clinical and experimental studies.

WHAT THE READER WILL GAIN

Our analysis revealed the regulation of inflammatory processes via thymic hormones that could be prospective for therapeutic application. This regulation may be mediated through thymic hormone effects on peripheral immune cell activities and bidirectional coupling between thymic hormones and the hypothalamic-pituitary-adrenal axis.

TAKE-HOME MESSAGE

In view of the role of thymic hormones in immune and neuroendocrine systems, they could be suitable as therapeutic agents for inflammation.

The thymus-neuroendocrine axis: physiology, molecular biology, and therapeutic potential of the thymic peptide thymulin

Thymulin is a thymic hormone exclusively produced by the thymic epithelial cells. It consists of a nonapeptide component coupled to the ion zinc, which confers biological activity to the molecule. After its discovery in the early 1970s, thymulin was characterized as a thymic hormone involved in several aspects of intrathymic and extrathymic T cell differentiation. Subsequently, it was demonstrated that thymulin production and secretion is strongly influenced by the neuroendocrine system. Conversely, a growing core of information, to be reviewed here, points to thymulin as a hypophysotropic peptide. In recent years, interest has arisen in the potential use of thymulin as a therapeutic agent. Thymulin was shown to possess anti-inflammatory and analgesic properties in the brain. Furthermore, an adenoviral vector harboring a synthetic gene for thymulin, stereotaxically injected in the rat brain, achieved a much longer expression than the adenovirally mediated expression in the brain of other genes, thus suggesting that an anti-inflammatory activity of thymulin prevents the immune system from destroying virus-transduced brain cells. Other studies suggest that thymulin gene therapy may also be a suitable therapeutic strategy to prevent some of the endocrine and metabolic alterations that typically appear in thymus-deficient animal models. The present article briefly reviews the literature on the physiology, molecular biology, and therapeutic potential of thymulin.

Thymulin, a thymic peptide, prevents the overproduction of pro-inflammatory cytokines and heat shock protein Hsp70 in inflammation-bearing mice

The effects of synthetic analogue of peptide hormone thymulin, which is normally produced by thymic epithelial cells, on immune cells activity and blood cytokine profile had been studied in male NMRI mice with acute inflammation induced by injection of lipopolysaccharide from gram-negative bacteria (LPS, 250 microg/100 g of body weight). Inflammation induced by LPS resulted in accumulation of several plasma pro-inflammatory cytokines, IL-1 beta, IL-2, IL-6, TNF-alpha, interferon-gamma, and also IL-10, anti-inflammatory cytokine. Thymulin previously injected in dose of 15 microg/100 g body weight, prevented the accumulation of proinflammatory cytokines in plasma. Thymulin also prevented LPS-induced up-regulation of production of several cytokines by spleen lymphocytes and peritoneal macrophages. Added in vitro, thymulin decreased the peak of TNF-alpha production in macrophages cultivated with LPS. In addition, thymulin lowered the peak of Hsp70 production induced by LPS treatment. The results indicate that thymulin having significant anti-inflammatory effect may be promising in clinical application.

Regeneration of the adult thymus is preceded by the expansion of K5+K8+ epithelial cell progenitors and by increased expression of Trp63, cMyc and Tcf3 transcription factors in the thymic stroma

Studies of HIV-1-infected individuals on anti-retroviral therapies and of patients receiving lymphoablating treatments indicate that the thymus retains restorative capacity even in adults. The contributions of the thymic epithelial cells (TECs) to the regeneration of the thymus and the identity of epithelial cell progenitors were evaluated in murine models of transient thymic atrophy followed by a complete regeneration. Using microarray approach, we analyzed the pattern of gene expression in TECs sorted from mice that were depleted of thymocytes by steroid treatment or by irradiation. The initial analysis identified significant increases in the mRNA for cMyc, Trp63 and Tcf3 transcription factors known to be expressed in early epithelial cell progenitors in tissues other than the thymus. Immunohistochemistry showed that in involuted thymuses, the cMyc and Trp63 proteins were expressed in a subset of cortical thymic epithelial cells (cTECs) that were keratin 5 positive (K5(+)), typifying cTEC precursors. Importantly, confocal microscopy established that epithelial cells with the phenotype of putative TEC progenitors (i.e. K5(+)K8(+)) expressed the Trp63 protein and confirmed that K5(+)K8(+) TEC progenitors expanded significantly during atrophy and prior to the thymic regeneration. Thus, our data demonstrated for the first time that critical steps in the recovery of the adult thymus include expansion of TEC progenitors and elevated expression of Trp63, cMyc and Tcf3 transcription factors in the thymic stroma. These results suggest that TEC progenitors could be reactivated in the adult thymus and, therefore, reactivation of TEC progenitors could provide a new approach for thymic reconstitution.

Immunomodulatory Effects of Estradiol and Cadmium in Adult Female Rats

A wide range of toxic effects has been associated with cadmium (Cd) exposure in mammals. However, the physiological factors that modulate these effects have received limited attention. We have previously demonstrated that neonatal exposure of rats to Cd during lactation results in sex-specific immunotoxic effects in both juvenile and adult rats. The objectives of this study were to determine the effects of 17beta-estradiol (E(2)) on the immunotoxicity of Cd in female rats. We compared the effects of 28 days of exposure to 0, 5, and 25 ppm cadmium chloride (CdCl(2)) through drinking water on ovariectomized Sprague-Dawley rats and on ovariectomized rats with E(2) implant which mimicked the physiological level of E(2) in female rat. Our results clarify the control of important immune functions by E(2) at physiological level and demonstrate significant interactions between Cd and E(2) effects on the cytotoxic activity of natural killer cells and phagocytosis of splenic cells as well as on the total number of thymocytes and of the four subpopulations of the thymocytes as defined by the expression of the cell-surface markers CD4 and CD8. Cd and E(2) share several mechanisms of action that may account for these interactions. The estrogenic potential of Cd could also account for some of the observed effects. These interactions have to be taken into consideration in evaluating the risk of Cd immunotoxicity and the possible interactions with hormonal treatments.

Thymulin and the neuroendocrine system

Thymulin is a thymic hormone exclusively produced by the thymic epithelial cells. It consists of a nonapeptide component coupled to the ion zinc, which confers biological activity to this molecule. After its discovery in the early 1970, thymulin was characterized as a thymic hormone involved in several aspects of intra- and extrathymic T-cell differentiation. Subsequently, it was demonstrated that thymulin production and secretion is strongly influenced by the neuroendocrine system. Conversely, an emerging core of information points to thymulin as a hypophysotropic peptide. Here we review the evidence supporting the hypothesis that thymulin is an important player in the hypophyso-thymic axis.

Estrogen deficiency results in enhanced expression of Smoothened of the Hedgehog signaling in the thymus and affects thymocyte development

Aromatase is an essential enzyme for estrogen synthesis. We investigated the role of estrogen in thymocyte development using aromatase-deficient (ArKO) mice. Like its role as a regulator of bone metabolism through regulating osteoprotegerin (OPG) production, estrogen is involved in the processes of thymocyte development although aromatase mRNA was not detectable in the thymus. Thymic regression and reduced cellularity were evident in ArKO mice. The major difficulties in thymocyte development of ArKO mice were observed during the CD44+ CD25- stage at the cortico-medullary junction and during the CD44- CD25- stage at the subcapsular region where the estrogen receptor was expressed in the stromal cells. The proportion of thymocytes during the CD44+ CD25- stage was reduced. The progression of CD44- CD25+ cells to the CD44- CD25- stage was accelerated in ArKO mice possibly due to insufficient osteoprotegerin production in estrogen-deficiency. However, the expression of Smoothened of the Hedgehog signaling was enhanced in CD4- CD8- double negative cells. This enhancement may result in impaired progression of CD44- CD25- cells to the CD4+ CD8+ double positive stage and impaired proliferation of CD4+ CD8+ double positive cells since Smoothened (Smo) is known to arrest cells as non-proliferating cells. This could be the reason why the proportion of CD3+ TCRbeta(high) cells during the late phase of thymocyte maturation was reduced in ArKO mice. From these observations, we propose that estrogen supports thymocyte development and maturation at many stages through many regulatory pathways including the sonic hedgehog- and the osteoprotegerin ligand (OPGL)-mediated signaling.

Neuroendocrine control of thymus physiology

The thymus gland is a central lymphoid organ in which bone marrow-derived T cell precursors undergo differentiation, eventually leading to migration of positively selected thymocytes to the peripheral lymphoid organs. This differentiation occurs along with cell migration in the context of the thymic microenvironment, formed of epithelial cells, macrophages, dendritic cells, fibroblasts, and extracellular matrix components. Various interactions occurring between microenvironmental cells and differentiating thymocytes are under neuroendocrine control. In this review, we summarize data showing that thymus physiology is pleiotropically influenced by hormones and neuropeptides. These molecules modulate the expression of major histocompatibility complex gene products by microenvironmental cells and the extracellular matrix-mediated interactions, leading to enhanced thymocyte adhesion to thymic epithelial cells. Cytokine production and thymic endocrine function (herein exemplified by thymulin production) are also hormonally controlled, and, interestingly in this latter case, a bidirectional circuitry seems to exist since thymic-derived peptides also modulate hormonal production. In addition to their role in thymic cell proliferation and apoptosis, hormones and neuropeptides also modulate intrathymic T cell differentiation, influencing the generation of the T cell repertoire. Finally, neuroendocrine control of the thymus appears extremely complex, with possible influence of biological circuitry involving the intrathymic production of a variety of hormones and neuropeptides and the expression of their respective receptors by thymic cells.

Inhibitory effect of natural and environmental estrogens on thymic hormone production in thymus epithelial cell culture

The present study was carried out to assess the direct effect of natural estrogen and environmental estrogens on thymus epithelial cell (TEC) production/secretion of the thymic hormone thymosin-alpha 1 by using the technique of quantitative high-performance liquid chromatography. The presence of estrogen receptors in the TECs was also investigated. Murine TECs were cultured in the experimental DMEM medium containing various concentrations of natural or environmental estrogens, which was followed by determining the production of thymosin-alpha 1. The production of thymosin-alpha 1 by TECs was significantly inhibited by increasing concentrations of 17beta-estradiol (natural estrogen) over 3 x 10(-11) M, genistein (phytoestrogen) over 3 x 10(-9) M, coumestrol (phytoestrogen) over 3 x 10(-9) M, alpha-zearalanol (livestock anabolic) over 3 x 10(-7) and bisphenol-A (plastic) over 3 x 10(-6) M. Small amounts of estrogen receptor were present in the TECs. The above results clearly indicate that natural and environmental estrogens directly modulate TECs to produce thymic hormone probably through an estrogen receptor mechanism. Furthermore, our finding may be useful for evaluating biological effects of chemicals with estrogenic activity.

Estrogen Receptor α Is Necessary in Thymic Development and Estradiol-Induced Thymic Alterations

Estrogens affect the development, maturation, and function of multiple organ systems, including the immune system. One of the main targets of estrogens in the immune system is the thymus, which undergoes atrophy and phenotypic alterations when exposed to elevated levels of estrogen. To determine how estrogens influence the thymus and affect T cell development, estrogen receptor α (ERα) knockout (ERKO) mice were examined. ERKO mice have significantly smaller thymi than their wild-type (WT) littermates. Construction of ER radiation bone marrow chimeras indicated that the smaller thymi were due to a lack of ERα in radiation-resistant tissues rather than hemopoietic elements. ERKO mice were also susceptible to estradiol-induced thymic atrophy, but the extent of their atrophy was less than what was seen in WT mice. The estradiol-treated ERKO mice failed, however, to manifest alterations in their thymic CD4/CD8 phenotypes compared with WT mice. Therefore, ERα is essential in nonhemopoietic cells to obtain a full-sized thymus, and ERα also mediates some of the response of the thymus to elevated estrogen levels. Finally, these results suggest that in addition to ERα, another receptor pathway is involved in estradiol-induced thymic atrophy.

Use of cultured thymic tissues for the regeneration of the thymus

An account of research conducted on the transplantation of thymic cells and tissues in order to restore the functional activity of the thymus is reviewed, and discussed in the context of current concepts. Although most rodent work has been conducted on the transplantation of cultured fragments under the kidney capsule, human transplantation studies and models have used other sites or other species such as the severe combined immunodeficient mouse as hosts. The factors affecting the growth of thymic cells in culture is considered in detail since the methodology can strongly influence the cells favoured under culture conditions. An extension of this work to characterize both thymic fragments implanted under the kidney capsule of rats and cultured thymic cells has recently led to the appreciation that the adult thymus must contain a small number of neural crest-like cells. These cells have a high level of proliferation in the implanted fragments, expand in culture, and belong to a family of cytokeratin-positive cells exhibiting immunoreactivity for a wide range of neuropeptides and transmitters. Thus primary cultures of thymus can contain a wide range of glia-like cells. This can be explained by the fact that the thymus, in addition to having a mesenchymal neural crest component, is probably derived from cardiac neural crest. Closely associated neural crest also has glia-like properties (the supporting cells of the enteric nervous system). These finding can account for the large number of reports of epithelial cells of the adult thymus being immunoreactive to antibodies raised to neuroendocrine and neurotransmitters. Neuroimmune interactions in the thymus are more fundamental than previous work had suggested.

Repeated in vivo hydrocortisone treatment promotes a dual modulation of cytokeratin expression by mouse thymic epithelial cells

Previous studies showed that a single dose of hydrocortisone in mice was able to transiently upregulate the expression of cytokeratins (CKs) 3 and 10 by medullary epithelial cells of the mouse thymus. Herein we studied these cells (specifically recognized by immunocytochemistry with the anti-CK monoclonal antibody KL1) following a series of repeated injections of the glucocorticoid hormone. A progressive dual (up and down) modulation of KL1+ medullary epithelial cells was observed with a late appearance of KL1 immunoreactivity in the thymic cortex. The data indicate that a single versus repeated exposure to high doses of glucocorticoid hormone may trigger different circuits regulating intrathymic CK expression. Lastly, the model described herein may be regarded as promising in studies concerning the effect of repeated stress conditions upon the thymus.

In vitro and in vivo effects of thymulin on rat testicular steroid synthesis

Although the stimulatory effects of immunological hormone thymulin on ovarian function are documented, responses of the testis to thymulin are unknown. Effects of thymulin and thymulin augmentation of human chorionic gonadotropin (hCG) stimulation of testicular steroidogenesis were analyzed via incubation of testis from 3-, 6-, and 9-week-old rats with 0.1, 1, 10, and 100 ng/ml of thymulin or thymulin plus hCG (1 IU/ml). At three weeks of age, thymulin decreased testosterone and estrone synthesis. By 6 and 9 weeks of age, lower doses of thymulin (0.1 and 1 ng/ml) stimulated testosterone and estrone synthesis. Increased doses of thymulin (100 ng/ml) resulted in decreased testicular steroid synthesis. No thymulin augmentation of hCG stimulation of testicular steroidogenesis was noted in vitro. Responses in vitro may have been confounded with the endocrine status at the time of incubation. Thymulin levels are increased at 3 weeks of age and decline at 6 and 9 weeks of age whereas gonadotropin levels are just the opposite pattern; these in vivo endocrine changes may have influenced the in vitro responses. Analysis of in vivo response to thymulin was pursued in pituitary intact, hypophysectomized and hCG primed (12 h before thymulin injection) hypophysectomized rats (5 weeks of age) with 1 and 10 microg of thymulin injected intravenously. Thymulin had no effect on testicular steroidogenesis in hypophysectomized rats 30, 60, and 120 min post injection). In pituitary intact rats, thymulin reduced testosterone and estrone concentrations. In hCG primed hypophysectomized rats, thymulin injection was followed by significant increases in testosterone levels and declines in estrone concentrations. These studies indicated that any increases in testicular steroidogenesis from thymulin required gonadotropin stimulation and increased concentrations of thymulin had inhibitory effects on testicular steroidogenesis.

Reduced ability of hypothalamic and pituitary extracts from old mice to stimulate thymulin secretion in vitro

There is substantial evidence that growth hormone (GH) is particularly important in the control of the age-related decline of thymus function. It was therefore of interest: (a) to assess the overall capacity of tissue extracts from mediobasal hypothalamus (MBH), anterior pituitary (AP) and testis, obtained from young (3 months, Yc), middle-aged (13 months, MAc) and old (18 months, Oc) intact C57BL/6 mice to stimulate in vitro the release of thymulin, a Zn-bound immunoregulatory thymic peptide, from pure cultures of mouse thymic epithelial cells (TEC); (b) to perform the same evaluation utilizing MBH, AP and testicular extracts from mice of the same age-range but treated for 45 days with a sc dose of ovine GH (2 micrograms/g body wt) known to stimulate thymulin secretion in vivo. Pituitary hormones were measured by heterologous rat RIAs, whereas thymulin release was estimated by a rosette assay. Untreated animals showed a significant age-dependent increase in the AP content of follicle stimulating hormone but not in other AP hormones. In both control and treated animals, pituitary GH content decreased significantly with age. MBH extracts from C57BL/6 males evidenced thymulin-releasing activity on mouse TEC lines. This activity was maximal in the MBH from young animals and declined with the age of the MBH donors. The thymulin-releasing activity of MBHs from GH-treated mice was higher than that of the control animals and showed a less pronounced decline with age. AP extracts from the same animals showed a higher thymulin-releasing activity than did MBH preparations. This activity showed a progressive age-associated reduction in the APs from untreated mice, whereas in the GH-treated group, an age-related decline was only seen in the old donors. Control testicular extracts had little effect on thymulin release whereas GH treatment induced a definite thymulin-release inhibiting activity in the testicular homogenates of our animals which increased progressively with the age of the testis donors. We conclude that the MBH, AP and testis of the young mouse contain factors able to affect directly the endocrine activity of the thymic epithelium. The amount of these substances declines with age and seems to be modulated by GH.

Effects of sex steroids on the proliferation of thymic epithelial cells in a culture model: a role of protein kinase C

Using a rat thymic epithelial cell line (TEC; IT-45R1), the present study attempted to elucidate the mechanism of action of sex steroid hormones (SH) on the proliferation of TEC. The findings were as follows: (a) the proliferation of TEC in response to SH was mediated through protein kinase C activity introduced as a result of interaction between SH and plasma-borne inhibitors; (b) the strong inhibitory effect of SH on TEC proliferation might be mediated through the SH receptor pathway because the proliferative response was triggered by progesterone (P) and androgen (A), whereas the inhibitory response was triggered by P, A and oestrogen. These results clearly suggest that the control of TEC proliferation is a 'shut-off' mechanism triggered by high plasma levels of SH. This further refers to the speculation that the development of the normal thymus may be due to a lack of this 'shut-off' mechanism so that development occurs at the adequate plasma SH levels that are often observed before puberty. However, this development is inhibited at the high plasma SH levels after puberty and/or during pregnancy.

Oestrogen retards the development of spontaneous thymomas in BUF/Mna rats

BUF/Mna rats develop spontaneous thymomas with nearly 100% incidence in both sexes. While the thymomas in males develop from around 9 months of age, those in females start from 13-15 months of age. To clarify the mechanism of the delay of thymomagenesis in females, the effect of sex hormones on the development of thymomas was examined after either gonadectomy or oestrogen treatment. Prepubertal ovariectomy accelerated the thymoma development in females, whereas orchiectomy did not affect it. An intraperitoneal injection of oestriol (20 mg) into males at 2 months of age remarkably diminished the thymic weight to about one-tenth of age-matched controls at 16 months of age. These results suggest that oestrogen can actually retard the onset of thymoma in spite of genetic control of its incidence. However, oestrogen did not cause thymic involution when it was injected into rats over 9 months of age. Immunohistochemically, there seemed to be no distinct difference in distribution of oestrogen-receptor-bearing epithelial cells between thymomas and 2- to 3-month-old thymuses. The oestrogen sensitivity of the thymus might be destined to be lost, as the thymic epithelial cells start neoplastic changes with the impairment of oestrogen-receptor function.

Thymulin and its role in immunomodulation

Even though thymulin was isolated, sequenced and characterised some 20 years ago and later identified as a thymic hormone involved in immunomodulation, much more work is still required to further understanding of the mechanisms of action(s) of this peptide. Since the observation, by a semiquantitative bioassay, of diminished levels of thymulin in immunodeficiency and autoimmune disease, new data obtained by radioimmunoassay have not only confirmed previous observations but also demonstrated that thymulin plays a role in the interaction between the immune system and the neuro-endocrine system. In this paper we give an up to date account of recent developments in research into the role of thymulin in immunomodulation.

Interleukin 1 regulates secretion of zinc-thymulin by human thymic epithelial cells and its action on T-lymphocyte proliferation and nuclear protein kinase C

Thymic epithelial cells (TEC) are known to secrete thymic hormones that influence maturation of T lymphocytes. One of these peptides, thymulin, requires zinc in an equimolar ratio for biological activity. A previous study [Cousins, R. J. & Leinart, A. S. (1988) FASEB J. 2, 2884-2890] showed that interleukin 1 (IL-1) in vivo stimulates zinc uptake by the thymus. Both the alpha and beta forms of IL-1, which stimulate proliferation of human TEC, also stimulate their uptake of zinc in vitro, and this latter stimulation is both dependent and independent of proliferation. Zinc induces zinc accumulation without proliferation. Two other stimulants of proliferation, bovine pituitary extract and epidermal growth factor, stimulate zinc uptake by TEC, but only in a manner dependent on proliferation. Utilizing in situ hybridization, we show that the IL-1 alpha and beta forms and zinc induce metallothionein mRNA expression TEC. Metallothionein is thought to be involved in the transfer of zinc to thymulin. IL-1 was shown to stimulate the secretion of thymulin as measured both by its ability to stimulate induction of IL-2 receptor-positive lymphocytes from human peripheral blood lymphocytes and by the azathioprine-sensitive rosette assay. In addition, the zinc-thymulin complex in the presence, but not absence, of IL-1 stimulates nuclear protein kinase C in isolated lymphocyte nuclei. IL-1 apparently regulates the synthesis or secretion and delivery of zinc-thymulin complex to the T-lymphocyte system.

Interactions between the hypothalamo-pituitary adrenal axis and the thymus in the rat: a role for corticotrophin in the control of thymulin release

Our recent observations in man suggested that the secretion of the thymic peptide, thymulin, is influenced by hormones of the pituitary-adrenal axis. In the present study, we have used the rat as a model in order to examine 1) the effects of corticotrophin (ACTH) and glucocorticoids on the release of thymulin in vivo and in vitro, and 2) the influence of an acute rise in plasma thymulin on the secretion of corticosterone and luteinizing hormone. Immunoreactive thymulin was readily detectable in plasma from male Sprague-Dawley rats(≃200 g). Chronic bilateral adrenalec-tomy, which effectively removed endogenous corticosterone, produced highly significant (P<0.01) increases in the plasma concentrations of both ACTH and thymulin. Treatment of the adrenalectomized rats with dexamethasone, in a dose sufficient to suppress the hypersecretion of ACTH, maintained the plasma thymulin at a low level which did not differ significantly (P > 0.2) from that in sham-operated controls. In vitro, two non-specific depolarizing agents, K(+) (56 mM) and veratridine (10 ≃M), caused significant (P<0.01) Ca(2+) -dependent increases in thymulin release from segments of rat thymic tissue. Their effects were mimicked by ACTH(1-39) . The secretory responses to ACTH (0.025 to 1 ng/ml) were concentration-dependent but a very high concentration (2 ng/ml) of the peptide was without effect. Dexamethasone (0.1 μM) reduced (P<0.05) the spontaneous release of thymulin in vitro but potentiated markedly (P<0.01) the secretory responses to ACTH (0.5 to 1.0 ng/ml). Administration of thymulin (0.1 and 10 μg/kg ip) produced, within 10 min, striking increases in the plasma thymulin concentration which were still evident at 30 min. The peptide concentration then declined rapidly and, within 24 h, was lower than that in the corresponding vehicle-treated controls. The serum concentrations of corticosterone and luteinizing hormone were unaffected by the thymulin treatment. The saline vehicle (2.0 ml/kg ip) also produced a small increase in plasma thymulin concentration which was maximal at 10 min; a further small rise was evident 6 h after the injection but thereafter the thymulin values were indistinguishable from those in uninjected controls. A similar biphasic profile of serum corticosterone was apparent after the saline injection but the serum luteinizing hormone was unaffected. The results suggest that ACTH is a physiological enhancer of thymulin release and that, in certain circumstances, its effects may be potentiated by glucocorticoids.

Thymic endocrinology

Thymus endocrinology is characterized by the action of various hormones on the thymus endocrine milieu consisting of thymocytes, thymic epithelial cells and thymic stromal cells. Extrathymic hormonal influences include pituitary-derived hormones, such as prolactin and indirectly by ACTH via hydrocortisone from the adrenal, by thyroid-stimulating hormone (TSH) via thyroid hormones from the thyroid, and by LH and RH via sex steroids from gonads and adrenal. In addition, the thymus produces several putative thymic hormones: thymosin alpha 1, thymulin and thymopoietin, which have been reported to circulate and to act on both prothymocytes and mature T-cells in the periphery thus maintaining their commitment to the T-cell system and its functions. These endocrine influences decline with age and are associated with "thymic menopause" and cellular immune senescence contributing to the development of diseases in the aged. The intrathymic environment is characterized by a complex network of paracrine and autocrine endocrine signals involving both interleukins and thymic peptides. Thymic epithelial cells respond to IL-1 with proliferation and secretion of IL6 and GM-CSF. They similarly respond to cellular interactions with the production of IL1. Thymic epithelial cells also secrete thymic hormones, as exemplified by the zinc-thymulin complex, under stimulation with IL1 and other hormonal influences. Thymic stromal cells contribute, at minimum, IL1. These various interleukin and thymic hormone influences can be envisioned to operate in a synergistic interactive network to carry the evolving T-cell through its stepwise development to a mature T-cell.(ABSTRACT TRUNCATED AT 250 WORDS)

Endocrine relationships of thymosin-alpha 1, thymosin-beta 4, and luteinizing hormone throughout the prepubertal period of development in heifers, ovariectomized heifers and ovariectomized heifers with estradiol implants

To monitor the relationships of luteinizing hormone (LH) and thymosin-alpha 1 and -beta 4 in conjunction with possible gonadal feedback mechanisms that could alter thymic function (thymosin secretion), circulating thymosin-alpha 1 and -beta 4 and LH concentrations of control heifers (n = 6), ovariectomized heifers (n = 5) and ovariectomized heifers implanted with estradiol (n = 5) were determined during the prepubertal period (initiated at 266 days of age). Sequential blood samples were collected at 12-min intervals for 8 h before ovariectomy on day 0 and on days 8, 36, 50, 64, 78, 92, 106, 120 and 134 of the experiment. Thymosin-beta 4 concentrations were not different between treatments. Thymosin-beta 4 concentrations gradually decreased until day 92 of the study, then increased two-fold by day 134 of experimental sampling (400 days of age) when all control animals had attained puberty. Concentrations of thymosin-alpha 1 changed little as animals matured, but peak amplitude did increase over time (0.287 ng/ml at day 0 to 0.403 ng/ml at day 120; P less than 0.05). Mean concentration, number of episodic peaks and peak amplitude of thymosin-alpha 1 was increased in ovariectomized heifers in comparison to ovariectomized plus estradiol implants (P less than 0.05). Prior to cyclic ovarian function (prepuberty), changes in circulating thymosin-beta 4 concentrations seem to be independent of effects of gonadal steroids but thymosin-alpha 1 was responsive to estradiol.

An age-dependent thymic secretion modulates testicular function

The acetone extract obtained from the thymuses of 14-day-old rats contains a factor that interacts with hCG in the adult testis cells and inhibits testosterone production. Experiments were designed to investigate the possible secretion of this factor. The media from the incubation of thymuses from 14-day-old rats were processed by molecular sieve chromatography and the fractions assayed using a bioassay with testicular cells in vitro. A fraction of approx. 30 kDa was found to inhibit the hCG-stimulated production of testosterone. In addition, the influence of age on the release of the active fraction was investigated. The inhibitory effect of this thymus product was greatest in the neonatal period (1-14 days) and declined thereafter towards the onset of puberty. The age-related decline of the inhibitory activity correlated with relative thymus weight and also with the amount of protein released to the incubation media. Thymic fraction activity is, however, present in the adult gland. These results suggest that the thymus secretes active agents that are able to modulate the response of testicular cells to hCG and that their release seems to be age-related.