Studies on the maturation of thymus stem cells. The effects of catecholamines, histamine and peptide hormones on the expression of T cell alloantigens

Neuro-Immune Cell Units: A New Paradigm in Physiology

The interplay between the immune and nervous systems has been acknowledged in the past, but only more recent studies have started to unravel the cellular and molecular players of such interactions. Mounting evidence indicates that environmental signals are sensed by discrete neuro-immune cell units (NICUs), which represent defined anatomical locations in which immune and neuronal cells colocalize and functionally interact to steer tissue physiology and protection. These units have now been described in multiple tissues throughout the body, including lymphoid organs, adipose tissue, and mucosal barriers. As such, NICUs are emerging as important orchestrators of multiple physiological processes, including hematopoiesis, organogenesis, inflammation, tissue repair, and thermogenesis. In this review we focus on the impact of NICUs in tissue physiology and how this fast-evolving field is driving a paradigm shift in our understanding of immunoregulation and organismal physiology.

Relevance of Immune-Sympathetic Nervous System Interplay for the Development of Hypertension

Historically, the sympathetic nervous system (SNS) has been mostly associated with the 'fight or flight' response and the regulation of cardiovascular function. However, evidence over the past 30 years suggests that SNS may also influence the function of immune cells. In this review we describe the basic research being done in the area of SNS regulation of immune function. Further, we show that the SNS-immune interplay during circadian rhythm may modulate the robustness of the inflammatory response, critical for survival during periods of increased activity. Finally, new concepts of a close relationship between these systems in the pathogenesis of hypertension are discussed.

Bidirectional communication between the neuroendocrine system and the immune system: relevance to health and diseases

In the past century, physiological, molecular, and cellular-based studies have proved that the functions of the nervous system, endocrine system, and immune system are dependent upon each other and that this interaction among these systems determines the maintenance of health or susceptibility to infections. The release of neurotransmitters and neuropeptides from the brain is a response to external environmental stimuli that influences the release of hormones from the pituitary in order to regulate the functions such as metabolism and growth, reproduction, etc. In addition, there are direct sympathetic noradrenergic and peptidergic innervations of primary (bone marrow and thymus) and secondary (spleen, lymph nodes, and lymphoid tissues) lymphoid organs. The neurotransmitters and neuropeptides released in these lymphoid organs then bind to specific receptors on the cells of the immune system to modulate their functions. Another circuit in this bidirectional communication involves the products of the immune system, for e.g., cytokines that can cross the blood-brain barrier to alter the activities of the neuronal function in the central nervous system especially during fever and inflammation in infectious diseases and cancer. Dysregulation of the interactions between the neuroendocrine and immune system due to alterations in the neural activity, secretion of hormones and cytokines, and synthesis of growth factors has been demonstrated to promote the pathogenesis and progression of infectious and autoimmune diseases, cancer, and neurodegenerative diseases. It is imperative that further research is carried out to understand the mechanisms of neuroendocrine-immune interactions to facilitate development of better treatment strategies for neurodegenerative diseases.

End-point effector stress mediators in neuroimmune interactions: their role in immune system homeostasis and autoimmune pathology

Much evidence has identified a direct anatomical and functional link between the brain and the immune system, with glucocorticoids (GCs), catecholamines (CAs), and neuropeptide Y (NPY) as its end-point mediators. This suggests the important role of these mediators in immune system homeostasis and the pathogenesis of inflammatory autoimmune diseases. However, although it is clear that these mediators can modulate lymphocyte maturation and the activity of distinct immune cell types, their putative role in the pathogenesis of autoimmune disease is not yet completely understood. We have contributed to this field by discovering the influence of CAs and GCs on fine-tuning thymocyte negative selection and, in particular, by pointing to the putative CA-mediated mechanisms underlying this influence. Furthermore, we have shown that CAs are implicated in the regulation of regulatory T-cell development in the thymus. Moreover, our investigations related to macrophage biology emphasize the complex interaction between GCs, CAs and NPY in the modulation of macrophage functions and their putative significance for the pathogenesis of autoimmune inflammatory diseases.

The role of the sympathetic nervous system in the thymus in health and disease

The existence of a network of immunoneuroendocrine interactions that results in the reciprocal modulation of the classical functions of each system is well established at present. Most of the evidence derives from studies on secondary lymphoid organs, such as the spleen and lymph nodes. In this article, several aspects relevant to understand the role of the sympathetic nervous system in the establishment of these interactions in the thymus are discussed. At present, the sympathetic innervation of the thymus, the expression of adrenergic receptors in thymic cells, particularly of β-adrenergic receptors, and the effect of sympathetic neurotransmitters, although mainly derived from in vitro or pharmacological studies, seem to be relatively well studied. However, other aspects, such as the relevance that immune-sympathetic interactions at the thymic level may have for certain diseases, specially autoimmune or other diseases that primarily involve the activation of the immune system, as well as how the integration of sympathetic and hormonal signals at local levels may affect thymic functions, certainly deserve further investigation.

Age-associated remodeling of neural and nonneural thymic catecholaminergic network affects thymopoietic productivity

Ageing is associated with a progressive decline in thymic cytoarchitecture followed by a less efficient T cell development and decreased emigration of naïve T cells to the periphery. These thymic changes are linked to increased morbidity and mortality from infectious, malignant and autoimmune diseases in old age. Therefore, it is of paramount importance to understand the thymic homeostatic processes across the life span, as well as to identify factors and elucidate mechanisms driving or contributing to the thymic involution. Catecholamines (CAs) derived from sympathetic nerves and produced locally by thymic cells represent an important component of the thymic microenvironment. In young rats, they provide a subtle tonic suppressive influence on T cell development acting via β(2)- and α(1)-adrenoceptors (ARs) expressed on thymic nonlymphoid cells and thymocytes. In the face of thymic involution, a progressive increase in the thymic noradrenaline level, reflecting a rise in the density of noradrenergic nerve fibers and CA-synthesizing cells, occurs. In addition, the density of β(2)- and α(1)-AR-expressing thymic nonlymphoid cells and the α(1)-AR thymocyte surface density also exhibit a pronounced increase with age. The data obtained from studies investigating effects of AR blockade on T cell development indicated that age-related changes in CA-mediated thymic communications, certainly those involving α(1)-ARs, may contribute to diminished thymopoietic efficiency in the elderly. Having in mind thymic plasticity in the course of ageing, and broadening possibilities for pharmacological modulation of CA signaling, we here present and discuss the progress in research related to a role of CAs in thymic homeostasis and age-related decay in the thymic naïve T cell output.

Human immunoglobulin allotypes: possible implications for immunogenicity

More than twenty recombinant monoclonal antibodies are approved as therapeutics. Almost all of these are based on the whole IgG isotype format, but vary in the origin of the variable regions between mouse (chimeric), humanized mouse and fully human sequences; all of those with whole IgG format employ human constant region sequences. Currently, the opposing merits of the four IgG subclasses are considered with respect to the in vivo biological activities considered to be appropriate to the disease indication being treated. Human heavy chain genes also exhibit extensive structural polymorphism(s) and, being closely linked, are inherited as a haplotype. Polymorphisms (allotypes) within the IgG isotype were originally discovered and described using serological reagents derived from humans; demonstrating that allotypic variants can be immunogenic and provoke antibody responses as a result of allo-immunization. The serologically defined allotypes differ widely within and between population groups; therefore, a mAb of a given allotype will, inevitably, be delivered to a cohort of patients homozygous for the alternative allotype. This publication reviews the serologically defined human IgG allotypes and considers the potential for allotype differences to contribute to or potentiate immunogenicity.

Sympathetic modulation of immunity: relevance to disease

Optimal host defense against pathogens requires cross-talk between the nervous and immune systems. This paper reviews sympathetic-immune interaction, one major communication pathway, and its importance for health and disease. Sympathetic innervation of primary and secondary immune organs is described, as well as evidence for neurotransmission with cells of the immune system as targets. Most research thus far has focused on neural-immune modulation in secondary lymphoid organs, has revealed complex sympathetic modulation resulting in both potentiation and inhibition of immune functions. SNS-immune interaction may enhance immune readiness during disease- or injury-induced 'fight' responses. Research also indicate that dysregulation of the SNS can significantly affect the progression of immune-mediated diseases. However, a better understanding of neural-immune interactions is needed to develop strategies for treatment of immune-mediated diseases that are designed to return homeostasis and restore normal functioning neural-immune networks.

Autonomic denervation of lymphoid organs leads to epigenetic immune atrophy in a mouse model of Krabbe disease

Lysosomal beta-galactosylceramidase deficiency results in demyelination and inflammation in the nervous system causing the neurological Krabbe disease. In the Twitcher mouse model of this disease, we found that neurological symptoms parallel progressive and severe lymphopenia. Although lymphopoiesis is normal before disease onset, primary and secondary lymphoid organs progressively degenerate afterward. This occurs despite preserved erythropoiesis and leads to severe peripheral lymphopenia caused by reduced numbers of T cell precursors and mature lymphocytes. Hematopoietic cell replacement experiments support the existence of an epigenetic factor in mutant mice reconcilable with a progressive loss of autonomic axons that hampers thymic functionality. We propose that degeneration of autonomic nerves leads to the irreversible thymic atrophy and loss of immune-competence. Our study describes a new aspect of Krabbe disease, placing patients at risk of immune-related pathologies, and identifies a novel target for therapeutic interventions.

Early postnatal castration affects thymic and thymocyte noradrenaline levels and beta-adrenoceptor-mediated influence on the thymopoiesis in adult rats

The interactions among the nervous, endocrine and immune system were studied by examining: i) thymic and thymocyte catecholamine levels in adult rats castrated (Cx) at postnatal day 3 and ii) effects of 14-day-long propranolol (P) treatment on main thymocyte differentiational molecule expression in adult non-Cx and Cx rat. The results demonstrated that castration in early postnatal period lowers levels of both neurally- and thymocyte-derived noradrenaline in adult rats, and thereby diminishes beta-adrenoceptor-mediated fine tuning of the T-cell differentiation/maturation. In non-Cx rats P affected TCRalphabeta-dependent stages of thymocyte differentiation/maturation decreasing frequency of CD4+8+ double positive (DP) TCRalphabeta(low) cells entering selection processes and increasing relative number of positively selected DP TCRalphabeta(high) (most likely due to an increased thymocyte surface density of Thy-1 that is involved in negative control of TCRalphabeta-mediated signaling/selection thresholds) and the most mature CD4+8- TCRalphabeta(high) cells (including CD4+25+ regulatory cells). However, in Cx rats P failed to produce any significant changes in thymocyte subset composition.

Characterization of thymocyte phenotypic alterations induced by long-lasting beta-adrenoceptor blockade in vivo and its effects on thymocyte proliferation and apoptosis

Adult male Wistar rats were subjected to propranolol (P, 0.40 mg/100 g/day) or saline (S) administration (controls) over 14 days. The expression of major differentiation molecules on thymocytes and Thy-1 (CD90) molecules, which are shown to adjust thymocyte sensitivity to TCRalphabeta signaling, was studied. In addition, the sensitivity of thymocytes to induction of apoptosis and concanavalin A (Con A) signaling was estimated. The thymocytes from P-treated (PT) rats exhibited an increased sensitivity to induction of apoptosis, as well as to Con A stimulation. Furthermore, P treatment produced changes in the distribution of thymocyte subsets suggesting that more cells passed positive selection and further differentiated into mature CD4+ or CD8+ single positive (SP) TCRalphabeta(high) cells. These changes may, at least partly, be related to the markedly increased density of Thy-1 surface expression on TCRalphabeta(low) thymocytes from these rats. The increased frequency of cells expressing the CD4+25+ phenotype, which has been shown to be characteristic for regulatory cells in the thymus, may also indicate alterations in thymocyte selection following P treatment. Inasmuch as positive and negative selections play an important role in continuously reshaping the T-cell repertoire and maintaining tolerance, the hereby presented study suggests that pharmacological manipulations with beta-AR signaling, or chemically evoked alterations in catecholamine release, may interfere with the regulation of thymocyte selection, and consequently with the immune response.

Amygdaloid kindled seizures can induce functional and pathological changes in thymus of rat: role of the sympathetic nervous system

The present study sought to determine the effects of long-term kindled seizures of the basal amygdala upon immune function in rat, utilizing the thymus, as a principal target for study. Histopathology from kindled Sprague-Dawley rats revealed the presence of epithelial cell thymoma in 70% of these rats. The results revealed an increased rate of apoptosis and proliferation in thymic epithelial cells. Analysis of thymocytes indicated a decrease in the ratio of CD4 to CD8 positive T cells and reduced proliferative response to T-cell mitogens. To determine whether these effects were mediated through the sympathetic nervous system, animals were treated with guanethidine, which blocked the development of epithelial cell thymomas, while mifepristone treatment, employed to determine the possible role of the hypothalamic-pituitary axis, was ineffective in attenuating thymoma development. Thus, the present study demonstrated that functional and pathological changes in the thymus during kindled seizures are mediated through the sympathetic nervous system.

The effects of chronic stress on thymus innervation in the adult rat

Various stressors induce changes in the immune system. However, it has not yet been analyzed how stressors affect thymus innervation. To examine whether chronic stress alters the morphology of the thymus by changing the nerve components of the thymus, adult male rats, 9-weeks old, were exposed to forced swimming during 21 successive days. The animals were sacrificed by decapitation after the last session and their thymuses were used for analysis of (i) the thymus compartments, (ii) distribution patterns of monoamine-containing nerve profiles and (iii) distribution patterns of acetylcholinesterase (AChE)-containing nerve profiles. Our results show that chronic stress in rats reduces the volume of both thymus cortex and medulla, numbers of thymocytes in the deep cortex and medulla and the density of fluorescent nerve profiles, whereas it increases density of fluorescent cells. The distribution patterns of nerve profiles containing monoamine and AChE were not affected. These changes indicate that chronic stress affects thymus development and T cell maturation by altering the sympathetic nerve component.

Autonomic innervation of immune organs and neuroimmune modulation

1. Increasing evidence indicates the occurrence of functional interconnections between immune and nervous systems, although data available on the mechanisms of this bi-directional cross-talking are frequently incomplete and not always focussed on their relevance for neuroimmune modulation. 2. Primary (bone marrow and thymus) and secondary (spleen and lymph nodes) lymphoid organs are supplied with an autonomic (mainly sympathetic) efferent innervation and with an afferent sensory innervation. Anatomical studies have revealed origin, pattern of distribution and targets of nerve fibre populations supplying lymphoid organs. 3. Classic (catecholamines and acetylcholine) and peptide transmitters of neural and non-neural origin are released in the lymphoid microenvironment and contribute to neuroimmune modulation. Neuropeptide Y, substance P, calcitonin gene-related peptide, and vasoactive intestinal peptide represent the neuropeptides most involved in neuroimmune modulation. 4. Immune cells and immune organs express specific receptors for (neuro)transmitters. These receptors have been shown to respond in vivo and/or in vitro to the neural substances and their manipulation can alter immune responses. Changes in immune function can also influence the distribution of nerves and the expression of neural receptors in lymphoid organs. 5. Data on different populations of nerve fibres supplying immune organs and their role in providing a link between nervous and immune systems are reviewed. Anatomical connections between nervous and immune systems represent the structural support of the complex network of immune responses. A detailed knowledge of interactions between nervous and immune systems may represent an important basis for the development of strategies for treating pathologies in which altered neuroimmune cross-talking may be involved.

Age-dependent morphometrical changes in the thymus of male propranolol-treated rats

In order to elucidate a putative role of neurally derived noradrenaline in the thymus development, and in maintenance of adult thymus structure, sexually immature male rats (21-day-old at the beginning of treatment) and young adult animals (75-day-old on the beginning of treatment) were treated with the non-selective beta-adrenoceptor antagonist propranolol (0.40 mg/100 g BW/day, s.c.) for 15 consecutive days, and their thymuses were analyzed stereologically. The effects of beta-adrenoceptor blockade were much more pronounced in sexually immature than in adult rats. In immature propranolol-treated rats the thymus size and volumes of both the main compartments (cortex and medulla) were significantly decreased reflecting, at least partly, a reduction in the overall number of thymocytes. Furthermore, in both the cortical subcompartments (outer and deep cortex) the mean diameter of thymocytes was increased. However, in adult rats exposed to propranolol treatment, only the volume of interlobular connective tissue was enlarged, whereas in the outer part of the cortex the mean thymocyte diameter was increased. These results indicate that the lack of sympathetic input (via beta-adrenoceptors) during the prepubertal period of development diminishes the normal thymus growth and/or accelerates the thymic involution that starts at puberty, immediately after its maximum size is reached, while it is less significant for the maintenance of the thymus size and structure in adults. Additionally, they suggest that distinct cell types, as well as thymocyte subsets, are sensitive to lack of beta-adrenoceptor-mediated influences in sexually immature and adult rats.

Thymopoiesis following chronic blockade of beta-adrenoceptors

The present study was undertaken in order to further clarify putative role of the adrenergic innervation in the regulation of the intrathymic T-cell maturation. For this purpose adult male DA rats were subjected to either 4-day- or 16-day-long propranolol treatment (0.40 mg propranolol/100 g/day, s.c.) and the expression of CD4/8/TCRalphabeta on thymocytes, as well as thymocyte proliferative and apoptotic index, was assessed in these animals by flow cytometric analysis. Propranolol treatment, in spite of duration, increased both the thymocyte proliferative and apoptotic index (vs. respective vehicle-treated controls). In 4-day-treated animals the thymus cellularity and thymus weight remained unaltered, while in 16-day-treated rats the values of both of these parameters were reduced (since increase in the thymocyte apoptotic index overcame that in the proliferative index). The treatments of both durations affected the thymocyte phenotypic profile in a similar pattern, but the changes were more pronounced in rats exposed to the treatment of longer duration. The relative proportion of the least mature CD4-8- double negative (DN) TCRalphabeta- cells was increased, those of thymocytes at distinct differentiational stages on the transitional route to the CD4+8+ double positive (DP) TCRalphabetalow stage decreased (all subsets of TCRalphabeta- in both groups of rats, and those with low expression of TCRalphabeta in rats subjected to 16-day-long treatment) or unaltered (all subsets of TCRalphabetalow cells in 4-day-treated rats). Furthermore, the percentage of CD4+8+ DP TCRalphabetalow cells was significantly elevated, as well as those of the most mature CD4+8- TCRalphabetahigh and CD4-8+ TCRalphabetahigh cells (the increase in the percentage of former was much more conspicuous than that of the latter), while the relative proportion of their direct detectable precursors (CD4+8+ DP TCRalphabetahigh) was reduced. Thus, the present study: i) further supports notion of pharmacological manipulation of adrenergic action as an efficient means in modulation of the T-cell development, and hence T-cell-dependent immune response, and ii) provides more specific insight into T-cell maturation sequence point/s particularly sensitive to beta-adrenoceptor ligand action.

Differential effects of chronic propranolol treatment on the phenotypic profile of thymocytes from immature and adult rats

To elucidate a putative role of beta-adrenoceptors in the modulation of intrathymic T-cell maturation, the expression of major differentiational antigens (CD4/CD8 and TCR alphabeta) on the thymocytes from both immature (aged 21 day at the beginning of the treatment) and adult (aged 75 days at the beginning of treatment) male rats subjected to a 15-day-long propranolol treatment (0.40 mg/100 g/day, s.c.) was analyzed by two- and one-color flow cytometry, respectively. Rats of matched age injected with saline served as controls. The propranolol treatment in immature but not adult rats caused a significant reduction in both the relative thymus weight and total thymocyte yield. In addition, a significant increase in the percentage of CD4+ 8+ double-positive cells, with a proportional decrease in the relative proportion of CD4+ 8- single positive cells, was found in immature rats. In contrast, a slight but significant decrease in the percentage of CD4+ 8+ cells with a parallel increase in the relative proportion of CD4+ 8- cells was found in adult rats. In both groups of rats, the percentage of TCR alphabeta(total) thymocytes was increased: in immature rats this was due to an increase in the percentage of TCR alphabeta(low) thymocytes, while in the adult rats it reflected a rise in the relative proportion of TCR alphabeta(high) cells. In conclusion, the study revealed that propranolol treatment in both immature and adult rats alters the relative proportion of CD4+ 8+ and CD4+ 8- thymocytes, but in opposite fashion, and the data suggest that this treatment affects distinct fractions within the population of CD4+ 8+ thymocytes with respect to expression of TCR alphabeta. The results also indicate that, regardless of rat sexual maturity, the development of thymocytes towards CD4- 8+ T-cells is relatively insensitive to long-lasting beta-adrenoceptor blockade.

Orchidectomy affects the innervation of the rat thymus

To assess a putative role of the neural pathways in transfer of information from the gonads to the thymus, adult AO rats were orchidectomized (ORX) or sham ORX (controls); sacrificed 1, 3, 7, or 15 days later and their thymi were analyzed for: (a) the concentrations of noradrenaline (NA), dopamine (DA) and serotonin (5-HT) and distribution of monoamine-containing nerve profiles and (b) the acetylcholinesterase (AChE) activity and distribution of AChE-containing nerve profiles. Three days after the castration, an elevation in the level of both catecholamines, reflecting an increase in the overall intensity of nerve fibers autofluorescence, was found. Seven days post castration neither NA nor DA concentration differed from the appropriate control values, while 15 days after the surgery the concentration of NA was lower than that in the controls, most likely, due to diminished density of noradrenergic nerve profiles. In both the rats sacrificed 7 and 15 days after orchidectomy the concentration of 5-HT was reduced as result of a decrease in the density of 5-HT-containing autofluorescent cells. The activity of AChE was depressed one day after the surgery; then increased, so that 3 days post castration its value was higher than that in the sham ORX. After this increase, AChE activity decreased being, at postoperative day 7 and 15, lower than that in the controls. It seems that this decrease in AChE activity reflected, not only a reduction in the density of AChE-containing nerve fibers, but also a decrease in the density of AChE positive cells. Thus, the results indicate that orchidectomy can evoke changes in the T-cell maturation altering modulatory influences on this process coming via neural route, as well as those coming from the mast cells and AChE positive epithelial cells which constitute important component of the thymus microenvironment.

Beta-adrenoceptor-mediated effects in rat cultured thymic epithelial cells

1. Sympathetic nerves were visualized in sections from rat thymus by immunostaining of tyrosine hydroxylase, the rate-limiting enzyme of catecholamine biosynthesis, and by glyoxylic acid-induced fluorescence of catecholamines. Catecholaminergic nerve fibres were detected in close connection to thymic epithelial cells which therefore might be preferred target cells. To evaluate this, rat immunocytochemically defined, cultured thymic epithelial cells were investigated for adrenoceptors and adrenergic effects. 2. In rat cultured thymic epithelial cells mRNA for beta 1- and beta 2-adrenoceptors was detected by reverse transcription-polymerase chain reaction by use of sequence-specific primers. Specific, saturable binding to the cultivated cells was observed with the beta-adrenoceptor agonist CGP 12177. 3. Adrenaline, noradrenaline or the beta-adrenoceptor agonist, isoprenaline, increased intracellular adenosine 3':5'-cyclic monophosphate (cyclic AMP) levels in cultivated thymic epithelial cells dose-dependently about 25 fold. The pharmacological properties revealed that this response was mediated by receptors of the beta 1- and the beta 2-subtypes. The selective beta 3-adrenoceptor agonist BRL 37344 had no effect on cyclic AMP levels. The increase in cyclic AMP was downregulated by preincubation with glucocorticoids like dexamethasone or cortisol which also changed the relative importance of beta 1-/beta 2-adrenoceptors to the response. 4. Incubation with isoprenaline or the adenylate cyclase activator forskolin decreased basal and serum-stimulated proliferation of thymic epithelial cells. However, adrenergic stimulation of thymic epithelial cells did not induce interleukin 1 production. Since thymic epithelial cells create a microenvironment which influences the maturation and differentiation of thymocytes to T-lymphocytes, their observed capacity to respond to catecholamines provides novel evidence for the suggestion that adrenergic stimulation may interfere with the regulation of immune functions.

Norepinephrine content in primary and secondary lymphoid organs is altered in rats with adjuvant-induced arthritis

Chemical sympathectomy of secondary lymphoid organs with sparing of the hind limbs exacerbates adjuvant-induced arthritis (AA) in Lewis rats supporting a role for noradrenergic (NA) innervation of the immune system in AA pathology. The present study examines sympathetic innervation of lymphoid organs from Lewis rats 32 days after treatment with complete Freund's adjuvant (CFA) or vehicle using fluorescence histochemistry for localization of catecholamines (CA) and high-performance liquid chromatography with electrochemical detection (LCEC) for measurement for norepinephrine. The thymus from AA rats was significantly reduced in size, while secondary lymphoid organs, i.e., spleen and draining lymph nodes (DLN), were significantly enlarged compared with that seen in vehicle-treated controls. Fluorescence histochemistry revealed no apparent differences in the density of NA innervation, or the intensity of staining in sympathetic nerves in any of the secondary lymphoid organs from AA rats compared with that observed in control animals. However, there was an apparent increase in the density of NA nerve fibers in the thymus of AA rats. Norepinephrine (NE) concentration (pmol NE per g or mg wet weight), in the thymus from AA rats was significantly increased. Conversely, a significant decrease in splenic and lymph node NE concentration was measured in adjuvant-treated animals compared with that seen in vehicle-treated rats. Total NE content (pmol NE per whole organ weight) in lymphoid organs was not altered, except in popliteal lymph nodes (PLN), where it was increased. Collectively, our findings suggest that changes in NA innervation of lymphoid organs from AA rats result largely from increases or decreases in organ mass. Since NE released from NA nerves acts in a paracrine fashion, changes in lymphoid tissue volume that result from enhanced proliferation, migration, or cell death can make a significant difference in the availability of NE for interaction with immune target cells in these organs, even in the absence of a change in NE metabolism. Decreased thymic weight and increased spleen and lymph node weight should increase and decrease NE availability for interaction with target cells, respectively. Additionally, in PLN (a site where the highest concentration of antigen is encountered) an increase in total NE content suggests compensatory changes in NE metabolism.

The immune effects of neuropeptides

Current evidence indicates that the neuroendocrine system is the highest regulator of immune/inflammatory reactions. Prolactin and growth hormone stimulate the production of leukocytes, including lymphocytes, and maintain immunocompetence. The hypothalamus-pituitary-adrenal axis constitutes the most powerful circuit regulating the immune system. The neuropeptides constituting this axis, namely corticotrophin releasing factor, adrenocorticotrophic hormone, alpha-melanocyte stimulating hormone, and beta-endorphin are powerful immunoregulators, which have a direct regulatory effect on lymphoid cells, regulating immune reactions by the stimulation of immunoregulatory hormones (glucocorticoids) and also by acting on the central nervous system which in turn generates immunoregulatory nerve impulses. Peptidergic nerves are major regulators of the inflammatory response. Substance P and calcitonin gene-related peptide are pro-inflammatory mediators and somatostatin is anti-inflammatory. The neuroendocrine regulation of the inflammatory response is of major significance from the point of view of immune homeostasis. Malfunction of this circuit leads to disease and often is life-threatening. The immune system emits signals towards the neuroendocrine system by cytokine mediators which reach significant blood levels (cytokine-hormones) during systemic immune/inflammatory reactions. Interleukin-1, -6, and TNF-alpha are the major cytokine hormones mediating the acute phase response. These cytokines induce profound neuroendocrine and metabolic changes by interacting with the central nervous system and with many other organs and tissues in the body. Corticotrophin releasing factor functions under these conditions as a major co-ordinator of the response and is responsible for activating the ACTH-adrenal axis for regulating fever and for other CNS effects leading to a sympathetic outflow. Increased ACTH secretion leads to glucocorticoid production. alpha-melanocyte stimulating hormone functions under these conditions as a cytokine antagonist and an anti-pyretic hormone. The sympathetic outflow, in conjunction with increased adrenal activity. leads to the elevation of catecholamines in the bloodstream and in tissues. Current evidence suggests that neuroimmune mechanisms are essential in normal physiology, such as tissue turnover, involution, atrophy, intestinal function, and reproduction. Host defence against infection, trauma and shock relies heavily on the neuroimmunoregulatory network. Moreover, abnormalities of neuroimmunoregulation contribute to the aetiology of autoimmune disease, chronic inflammatory disease, immunodeficiency, allergy, and asthma. Finally, neuroimmune mechanisms play an important role in regeneration and healing.

Neurochemical, electrophysiological and immunocytochemical evidence for a noradrenergic link between the sympathetic nervous system and thymocytes

The object of these experiments was to investigate whether noradrenaline is the signal neurotransmitter between the sympathetic nervous system and rat thymocytes. Using immunocytochemistry, evidence was obtained that the rat thymus (thymic capsule, subcapsular region and connective tissue septa) is innervated by noradrenergic varicose axons terminals (tyrosine hydroxylase- and dopamine-beta-hydroxylase-immunostained nerve fibres). This innervation is mainly associated with the vasculature and separately from vessels along the thymic tissue septa it branches into the thymic parenchyma. Using electron microscopy, classical synapses between thymocytes and neuronal elements were not observed. The neurochemical study revealed that these nerve terminals are able to take up, store and release noradrenaline upon axonal stimulation in a [Ca2+]o-dependent manner. The release was tetrodotoxin (1 microM)-sensitive, and reserpine pretreatment prevented axonal stimulation to release noradrenaline, indicating vesicular origin of noradrenaline. In addition, it was found that the release of noradrenaline was subjected to negative feedback modulation via presynaptic alpha 2-adrenoreceptors. Using a patch-clamp technique, electrophysiological evidence was obtained showing that noradrenaline inhibits in a concentration-dependent manner outward voltage-dependent potassium (k+) current recorded from isolated thymocytes. Since noradrenergic varicose axon terminals enter the parenchyma thymocytes and the boutons are not in close apposition to their target cells, noradrenaline released from these terminals diffuses away from release site to reach its targets, thymocytes, and to exert its inhibitory effect on voltage-dependent K+ -current. Since K+ channels are believed to be involved in T cell proliferation and differentiation, the modulation of K+ channel gating by noradrenaline released in response to axonal activity suggests that signals from blood-born or locally released hormones and cytokines. In this respect, noradrenaline released from non-synaptic neuronal varicosities and exerting its effect within the radius of diffusion may serve as a chemical link between the sympathetic nervous system and thymocytes and may have physiological and pathological importance in the thymus during stress and inflammatory/immune responses.

Presynaptic receptors involved in the modulation of release of noradrenaline from the sympathetic nerve terminals of the rat thymus

In a previous study we have shown that, in response to electrical stimulation, there is a substantial release of noradrenaline (NA) from the sympathetic nerve terminals of the rat thymus which is of axonal, vesicular origin. In the present study neurochemical evidence was obtained that the release of NA is subject to presynaptic modulation. This modulation operates through stimulation of alpha 2B-adrenoreceptors, N-nicotinic, P1-purinergic and prostaglandin E2 presynaptic receptors. Through these receptors the release of NA, i.e., the message from the central nervous system to the thymus, can be affected by endogenous ligands or drugs. A novel, potent and highly selective competitive antagonist of the alpha 2-adrenoreceptor, CH-38083, significantly enhanced the release of NA, suggesting that its release in the thymus is under tonic inhibitory control exerted by endogenously released NA. Since adrenoreceptors on thymocytes involved in the modulation of certain thymocyte functions have recently been described, it is suggested that the presynaptic modulation of the release of NA in the thymus is involved in neuro-immune communication.

Regulation of IL-4 and IL-5 secretion by histamine and PGE2

This study was designed to study the effects of autacoids on IL-4 and IL-5 secretion. IL-4 and IL-5 are secreted by TH2 cells. TH2 cells were generated by the culture of peripheral blood lymphocytes from atopic individuals in the presence of ragweed or dustmite antigen. The cloned TH2 lymphocytes were then stimulated with PMA (10 ng/ml) and alpha-CD3 (50 ng/ml) in the presence and absence of histamine (10(-4) - 10(-8)M) and PGE2 (10(-6) - 10(-8)M) for 48 hours. Other cAMP elevating agents were used as control. The supernatants were then assayed for the presence of IL-4 and IL-5 by ELISA. Both histamine and PGE2 suppressed the secretion of IL-4 in a dose dependent manner. Other cAMP elevating agents did not affect IL-4 secretion. In contrast, histamine upregulated the secretion of IL-5, whereas the effects of PGE2 on IL-5 secretion were not conclusive. Chloride channels have been implicated in the secretory processes. The effects of a chloride channel blocker, DIDS, were studied on histamine-induced suppression of IL-4 secretion. DIDS (10(-7) - 10(-12)M) abrogated the inhibitory effects of histamine on IL-4 secretion. The observations suggest that histamine may inhibit IL-4 secretion via activation of chloride channels.

A novel fluorescein-histamine reagent to quantitate histamine receptor expression on leucocytes

The expression of histamine receptors on the surface of rat lymph node cells was studied using a reagent made by directly coupling fluorescein isothiocyanate (FITC) to histamine. This approach contrasts with the use of previous reagents, made by coupling histamine and fluorescein separately to a protein carrier, which bind non-specifically to cells and cause staining unrelated to histamine receptor expression. The new reagent was used, in combination with a panel of monoclonal antibodies, for the dual staining of rat lymph node cells for two-colour flow cytometric analysis to investigate the distribution of histamine receptors on different leucocyte subsets. The majority of cells were stained by the FITC-histamine reagent and these constituted two distinct populations, those with the properties of small lymphocytes and a second population which included macrophages. Inhibition studies with the drugs mepyramine and cimetidine, which are antagonists of H1 and H2 receptors, respectively, showed that most lymphocytes possess H1 receptors while the macrophages have H2 receptors. It seems that macrophages have a higher number of histamine receptors than the majority of lymphocytes, but that they are of lower affinity.

Relationships between monoaminergic and cholinergic innervation of the rat thymus during aging

The present study has been undertaken in order to investigate whether aging is accompanied by alterations in the thymic autonomic innervation. The results showed that in aged rats compared to young adult rats the density of monoaminergic histofluorescent nerve profiles decreased remarkably, while their pattern of intrathymic distribution remained unchanged. The thymic concentrations of noradrenaline (NA) and dopamine (DA) also significantly decreased between the age of 12 and 18 months. However, the density of thymic autofluorescent cells (afc) markedly increased over the same period, as well as the concentration of 5-hydroxytryptamine (5-HT). The aged rat thymus seemed to be able to maintain its cholinergic innervation in terms of density and pattern of distribution, while the density of cells with intracytoplasmic acetylcholinesterase (AChE) staining even increased. The neurochemical measurement showed an increase in the activity of AChE between the age of 9 to 18 months. The results indicate an altered relation between the components of thymic autonomic innervation of aged rats that might be related to the reduced immunocompetence of their T cells.

The role of prolactin in the pathogenesis of autoimmune disease

Prolactin has emerged in recent years as a major regulator of both the maturation and the function of lymphocytes. Prolactin abnormalities, which include elevated serum levels, decreased bioactivity, abnormal circadian rhythm, and exaggerated secretion after stimulation by TRH, are associated with various autoimmune conditions in humans. Some animal experiments and observations in humans indicate that proiactin has an important role in the pathogenesis of autoimmune disease. There are several mechanisms through which prolactin could promote the development of autoimmunity. It is concluded that prolactin abnormalities alone are not likely to cause autoimmunity, but rather additional regulatory defects are perhaps also required for disease to develop.

Prenatal exposure to diazepam causes sex-dependent changes of the sympathetic control of rat spleen

Prenatal exposure to low doses of benzodiazepines has been found to affect immune functions (25,26). Because the immune system is controlled by the autonomic nervous system, we investigated the sympathetic activity in the spleen for a possible contribution to impaired immune function. Twenty-eight-day-old offspring of prenatally diazepam- or vehicle-treated Long-Evans rats (diazepam 1.25 mg/kg/day SC, gestational day 14-20) were injected IP with sheep red blood cells (SRBC) to evoke an immune reaction. Baseline splenic noradrenaline (NA) turnover was higher in females than in males. Prenatal diazepam treatment resulted in reduced NA turnover in the spleen of SRBC-stimulated female, but not male, offspring. beta-Adrenergic binding sites in spleen membrane fractions, studied with 3H-dihydroalprenolol, showed no differences, indicating that changes in NA turnover were not compensated by changes in receptor expression. Sex-specific developmental effects of diazepam have been described earlier, e.g., in selective effects on perinatal corticosterone levels in female offspring (26).

Immune system of the spontaneously hypertensive rat: II. Morphology and function

The spontaneously hypertensive rat (SHR) is a stress-sensitive animal which exhibits moderate immune dysfunction that has been implicated in the onset of hypertension. In this study, we examined the morphology of SHR thymus and spleen and further characterized the immune deficiency using Wistar-Kyoto (WKY) and Fisher 344 (F-344) rats for comparison. The adult SHR thymus does not display the increase in medullary volume typically noted with aging and the volume density of the marginal zone is decreased in the spleen. In vivo tritiated-thymidine incorporation is also decreased in the spleen of unstimulated SHR. In mixed lymphocyte reactions (MLR), the proliferative response of SHR splenocytes is significantly decreased relative to controls, WKY and F-344. Addition of interleukin-1 (IL-1), interleukin-2 (IL-2), or indomethacin to the MLR cultures does not increase proliferation. The proliferative response to T cell receptor monoclonal antibody (mAb-TCR) or interleukin-2 (IL-2) are similarly impaired in the SHR. The depressed proliferative T cell response is reversed by prolactin. It is suggested that the SHR is a valuable model for the study of immune deficiency.

Locus ceruleus and immunity. III. Compromised immune function (antibody production, hypersensitivity skin reactions and experimental allergic encephalomyelitis) in rats with lesioned locus ceruleus is restored by magnetic fields applied to the brain

This study deals with the relationship between the immunosuppression induced by electrolytic lesions placed into the nucleus locus cerules and the immunopotentiation produced by micromagnets implanted to the parietal area of the skull. The following groups of rats were set up: LC, rats with lesioned locus ceruleus; ShL, sham-lesioned animals bearing non-magnetic beads in the brain parietal region; M, rats with micromagnets of 60 mT influx density in the parietal part of the skull; LCM, animals with impaired locus ceruleus and magnetic beads placed in the parietal area of the skull; and IC, intact control rats. Animals of all groups were tested for plaque-forming cell response, circulating antibodies to sheep red blood cells and bovine serum albumin, Arthus and delayed hypersensitivity skin reactions to bovine serum albumin and old tuberculin, and experimental allergic encephalomyelitis. In LC-rats, humoral and cell-mediated immune reactions were compromised. On the other hand, immune responses in M-rats were significantly potentiated. In LCM-rats, however, the immunosuppression induced by destruction of the locus ceruleus was abrogated by prolonged exposure of the brain parietal region to the magnetic fields, i.e. immune reactivity of LCM-rats was quite similar to that of control IC- and ShL-animals. Several mechanisms may account for the immunomodulating effects produced by lesioning of the locus ceruleus and exposure of the brain to magnetic fields. Noradrenergic, serotoninergic, dopaminergic and peptidergic neurotransmitters, as well as growth hormones and immunopeptides, produced within the central nervous system or elsewhere, may be implicated as necessary for the interactions among the brain, immune apparatus and magnetic fields.

Neuroimmune modulation: signal transduction and catecholamines

In recent years, much interest has centered on the commonalities and bi-directional interactions between the nervous system and the immune system. This review focuses on mechanisms through which, catecholamines, a class of neuro-endocrine molecules, modulate immune functions. Catecholamines can be immune suppressive and inhibit lymphocyte activation of both T and B cells as well as the generation of immune-mediated anti-tumor responses. Some of these catecholamine-regulated activities appear to be modulated through the second messenger, cyclic AMP, whereas others appear to be catecholamine-dependent but cyclic AMP independent. Further delineation of the interacting ligand-receptor complexes, populations of responding cells and signal transduction mechanisms leading to the activation of specifically involved genes and gene products, will lead to enhanced understanding of the integratory functions of the nervous system in immune responses, the biology of stress, the role of stress-associated molecular mechanisms in perturbations of physiological homeostasis and the development of a new biological psychiatry with accompanying rational therapeutic modalities.

Immune system of the spontaneously hypertensive rat. I. Sympathetic innervation

Extensive bidirectional interactions are believed to exist between the sympathetic nervous system and the immune system. The spontaneously hypertensive rat (SHR) is known to possess both increased sympathetic nervous system activity with increased tissue catecholamine levels in several peripheral organs and a moderate T lymphocyte immune deficiency. We examined the development of innervation in both primary (thymus) and secondary (spleen) organs of the immune system of the SHR compared to immunocompetent Wistar-Kyoto (WKY), Fisher 344 (F-344), and Long Evan (LE) rats from birth through 24 weeks. Using glyoxylic acid-induced histofluorescence to visualize monoaminergic nerve fibers, coded specimens were examined and morphologically evaluated for the extent and distribution of innervation. The innervation of the SHR thymus was significantly increased at 2 and 12 weeks of age over the other strains. Unlike the control strains, splenic innervation in SHR was delayed until 2 weeks of age when it suddenly became exuberant. At 12 weeks, the innervation of the SHR spleen was increased over all control strains. By 24 weeks the innervation had regressed to a level comparable to the levels of the other rat strains in these tissues. During the suckling period, the size (weight) of the WKY spleen was larger and the level of innervation was decreased compared to the other strains. These strain-related differences in the development of sympathetic innervation of thymus and spleen likely reflect the complex, bidirectional interplay between the nervous and the immune systems.(ABSTRACT TRUNCATED AT 250 WORDS)

Neonatal sympathetic denervation alters the development of in vitro spleen cell proliferation and differentiation

The ontogeny of spleen cell proliferation to T and B cell mitogens and immunoglobulin secretion, measured in vitro, was examined in neonatally sympathectomized Fischer 344 (F344) rats, administered the neurotoxic drug 6-hydroxydopamine (6-OHDA) from 1 to 3 days of age. Compared to cells from age-matched controls, spleen cells from neonatally sympathectomized animals, aged 7-14 days, exhibited a shift in the proliferative response to the T cell mitogen, concanavalin A (Con A), with reduced proliferation in the presence of low doses of Con A, but increased proliferation with higher doses. During the same period, from 7 to 14 days, the B cell mitogen STM/DxS inhibited proliferation by spleen cells from all rats, and no effect of sympathectomy was observed. As adult-like patterns of mitogen responsiveness emerged from 21 to 42 days of age, neonatally sympathectomized rats showed reduced proliferative responses of both T and B cells. This effect dissipated by 56 days of age. Polyclonal immunoglobulin (Ig) production by B cells was assessed in vitro in the presence or absence of STM/DxS. Neonatal sympathectomy resulted in reduced spontaneous IgM production throughout development. From 28 to 42 days of age, when mitogen-triggered IgM secretion first developed, neonatal sympathectomy decreased the magnitude of the response. By 56 days of age, mitogen-induced IgM secretion was no longer affected by sympathectomy, similar to the proliferative response. Gender influenced the time course of sympathectomy-induced changes in spleen cell proliferation and differentiation; however, the magnitude and direction of these changes were similar in both males and females. Desipramine, administered prior to 6-OHDA, prevented both sympathetic denervation and the 6-OHDA-induced changes in spleen cell responsiveness. This indicates that the alterations in immune function were dependent on NA nerve fiber destruction and were not simply the result of direct 6-OHDA action on other cells. The results of this study suggest that sympathetic innervation may play an important potentiating role in the development of the lymphoid system, through effects on lymphocyte proliferation and differentiation.

Survey of thymic hormone effects on physical and immunological parameters in C57BL/6NNia mice of different ages

Immunosenescence occurs with aging, which is seen in decline in response to mitogens PHA, ConA, decline in cell-mediated immunity, increase in anemia, and increase in autoimmune antibodies to erythrocytes and DNA. These studies compared FTS, TP5, TM4, and TF5 in C57BL/6NNia mice. Mice aged 4, 26, 52, 78 and 104 wk were treated with various hormones 5x/wk for 3 wk and monitored for hormonal effects on weight; hematocrit; peripheral blood, spleen, and thymic cell numbers; spleen and peripheral blood cell mitogen responses to PHA, ConA, LPS; IgM hemolysin autoantibody; and cell-mediated cytotoxicity to P815 allogenic cells. Hormone treatments altered mitogen responses, enhanced IgM hemolysin autoantibody production, and modulated cell-mediated immune responses. The effects were not consistent for every hormone. There was a tendency for enhancement in younger mice and suppression in older animals. Treatment with FTS showed the greatest changes in either enhancing or suppressing the different parameters measured. The hormonal effects appeared to be age specific in that certain activities were altered for certain age groups but not in others. Hormone treatment did not restore any immune parameters in old mice to the level of young animals. In general, the different hormones did not consistently produce the same effects in C57BL/6NNia mice of different age groups. Even though all animals received from National Institutes on Aging (NIA) animal models program were held under strictly controlled conditions, intrinsic variations between cohorts of different ages are difficult to control. Cohorts of aging animals tested at different times might be intrinsically different. This inherent variability in the cohorts could affect the range of activity, specificity and reproducibility of hormone effects in vivo. Most importantly, it should be emphasized that cross-sectional data identifies age differences rather than age changes. There is no assurance that age changes in any individual or in all subpopulations follow this pattern. In our studies only healthy animals were used. Old, sick, or tumor-bearing animals were culled out prior to being sent to us. Therefore, the 78- and 104-wk-old mice represent selected healthy cohorts. The age changes that take place can be answered only from repeated measurements made in the same individual over time.

Effect of thymic hormone treatment on several immune functions of nude mice

Studies of the effect of short-term, intense treatment with thymic hormone on mitogen response, cytotoxicity to EL-4 lymphoma and natural killer cell (NK) activity was investigated Balb/c nude mice (about 12-16-week-old) were treated 5 times per week for 3 weeks with: Facteur Thymic Serique (FTS) and Thymopentin (TP5, Thymopoietin 32-36) at 1 microgram and 10 ng; TM4 1 ng (an enzyme resistant variant of FTS); Thymosin Fraction V (TF5), 10 and 1 microgram; and 0.1 ml saline, and killed 2 days after the last treatment. The animals were monitored for changes in weight, hematocrit, peripheral blood lymphocyte (PBL) and spleen mitogen response. Additional groups of nude mice were immunized with 1 x 10(7) 5000 R irradiated EL-4 cells 10 days before sacrifice and tested for the presence of cytotoxic T-lymphocytes (CTL). The results show that weight and hematocrit were similar among the groups. Treatment with FTS significantly elevated the number of PBL. Spleen stimulation in mice treated with 1 microgram TP5 was depressed to mitogen concanavalin A (ConA) and lipopolysaccharide (LPS) stimulation. The phytohemagglutinin (PHA) response was not different among the treatment groups. The PBL mitogen response to ConA and LPS was generally increased over saline control in the hormone treated groups but was not statistically significant. The PHA response was only slightly elevated. No CTL was generated in nude mice in any of the groups. However, there was a statistically significant general depression of NK activity in all of the hormone treated animals compared with saline. The results indicate that the basic differentiation defect of the T-cells of nude mice cannot be restored to full functional activity by short-term treatment.

Histamine and its congener derivatives as immune modulators

Our knowledge of the function of histamine as an immunoregulatory autacoid is expanding. The presence of histamine in many tissues in which the immune response takes place and its release during immune response lend credibility to the notion that histamine's role in the immune response could be an important one. In this report we present data that demonstrate the immune modulatory role of histamine. We also describe the synthesis and novel pharmacologic effects of congener derivatives of histamine. These new lymphocyte specific histamine H1 and/or H2 agonists make it feasible to assess the potential of histamine as a selective in vivo immune modulator.

Neuroimmunopharmacologic effects of drugs of abuse

Direct studies linking drugs of abuse with changes in neurotransmitters and subsequent effects on the immune system are not abundant. One can, however, hypothesize that an indirect effect can occur since a variety of neurotransmitters known to be acted on by various drugs of abuse can, in turn, be correlated with changes in immunity. These changes most likely are mediated via alterations in the autonomic nervous system or the ratio of hormones regulated by the pituitary gland. In addition, there is sound evidence to suspect that the immune system might be capable of altering either the induction of tolerance or the severity of withdrawal symptoms. An increasing body of evidence indicates that IL-1, IFN-alpha, as well as C3a and C5a of the complement cascade, are capable of acting on central catecholamines within the brain. The possibility that immune system peptides are capable of regulating neurotransmitters is further suggested by the evidence of neuropsychiatric side effects during the course of clinical trials. Since a variety of drugs of abuse can directly alter immunocompetence as evidenced by the results of in vitro protocols described elsewhere in this volume, one could speculate that certain behavioral manifestations of drug addiction may be modulated, in part, by immunologic status.

Substance P innervation of the rat thymus

Immunohistochemistry for substance P (SP) in the rat thymus revealed fine varicose neural profiles in specific regions of the thymus. Thymic SP innervation was abundant within the capsule and interlobular septa. The majority of SP+ nerve fibers within the septa were free of vascular association, although some fibers were associated with the vasculature deep within the septa. SP+ nerve fibers entered the thymic cortex from the septa and distributed among cortical thymocytes and mast cells. Along the corticomedullary junction, SP+ nerve fibers were found in association with the vasculature. The medullary region of the thymus received only a sparse innervation of SP+ fibers. In addition, SP+ nerve fibers coursed adjacent to OX-8+ cells and mast cells in the extrathymic connective tissue surrounding the thymus. The present study provides evidence that SP is present in nerve fibers in the thymus, and may be available to interact with thymocytes, mast cells, and other cells in the thymus, and affect their development and function.

Psychoneuroimmunology: An area of interest for the psychopharmacologist?

Anecdotal evidence suggesting a causal relationship between psychiatric illness, environmental stress and a malfunctioning immune system goes back to antiquity. Recently, clinical and experimental studies have established the interrelationship between neuro- endocrine regulation, the immune system and abnormalities in central neurotransmission which may be deranged as a consequence of stressful events. This short review is an attempt to assess the evidence implicating altered immune responsiveness in depression and to consider the impact of different types of environmental stress in triggering the immune malfunction. While these findings are of considerable biological importance, it is presently unclear whether the immunological changes are primary or secondary to the disease states.

Thymic hormones and prostaglandins. I. Lack of stimulation of prostaglandin production by thymic hormones

Prostaglandins (PGs) have been implicated as possible mediators of the biological activity of thymic hormones. It has been shown that type E-PGs are able to mimic the action of several thymic hormones and that indomethacin prevents in vivo or in vitro the appearance of Thy-1+ antigen induced by some of these factors. We thus investigated a possible role for PGs in the mechanism of action of different thymic extracts and peptides. Attempts to modulate prostaglandin production showed that neither thymosin fraction 5 (0.01-100 micrograms/ml), nor thymosin alpha 1 (1-10 micrograms/ml), thymulin (0.001-100 ng/ml), thymopoietin II (10-1000 ng/ml) or TP5 (10-1000 ng/ml) affect PGE2, 6-keto-PGF1 alpha, PGF2 alpha and TXB2 production by spleen cells from control and thymectomized mice. These results do not support the hypothesis that prostaglandins could act as mediators of thymic hormones.

Possible underlying mechanisms of sexual dimorphism in the immune response, fact and hypothesis

It is a confirmed fact that in females both the humoral and cell mediated immune response is more active than in males. A large amount of information supports the view that hormones of the endocrine system are intimately involved in this immunological dimorphism. Such hormones include the gonadal steroids, the adrenal glucocorticoids, growth hormone (GH) and prolactin (Prl) from the pituitary, thymic hormones, and substances generated by activated lymphocytes. It is suggested that a complex medley of these hormonal interactions effect both developing lymphocytes within the microenvironment and regulate adult effector cells. The most important of these hormonal interactions leading to immunological dimorphism are the effects elicited by estrogen (E) elaborated at elevated levels from the female ovary after puberty. Elevated E leads to basal GH secretion, increased Prl, and increased thymosin release, all of which are hypothesized to effect lymphocyte development and stimulate adult T- and B-cell function in females. Interactions of hormonal regulatory axes involving the hypothalamus, pituitary, gonads, adrenals, and thymus are also thought to be involved. Factors elaborated by activated immune cells including IL-1 and IL-2 may also play a role in down regulation of these responses. Finally, genetic components are also considered pertinent especially under conditions of pathological disequilibrium leading to autoimmune disease. While the benefits provided by immunological dimorphism are still not entirely clarified, since sex hormones are intimately involved in immunological regulation it is quite possible that the increased immune response in females allows them to compensate for the increased physiological stress which accompanies reproduction. The final outcome would thus be the assurance of reproductive success of the species.

Involvement of peripheral and central catecholamine systems in neural-immune interactions

In this review, we have attempted to delineate the current state of knowledge of the relationships between the immune system and one chemically specific component of the nervous system, the noradrenergic system, both in the brain and the periphery. We have discussed recent work describing the presence of noradrenergic innervation in lymphoid tissues in the major lymphatic organs. Our findings demonstrate clearly that the regions in which lymphocytes (mainly T cells) reside, and through which they recirculate, receive direct sympathetic neural input. The immune system can, therefore, be considered 'hard-wired' to the brain. The evidence for receptors on cells of the immune system capable of receiving signals from the brain is discussed. The significance of this 'hard-wiring' to the function of the immune system is considered, both with regard to the effect of its disruption on immune responses, and to the direct and indirect effects of sympathetic neurotransmitter substances on lymphocytes and their behavior in vitro and in vivo. Finally, our detailed analysis of changes occurring in central noradrenergic pathways as a result of stimulation of the immune system leads to an emerging picture of feedback loops from the immune system to the brain. Such circuits employ endocrine, and probably autonomic, outflow to modulate and regulate immune responses.

Endocrine control of thymic serum factor production in young-adult and old mice

The influence of different endocrinological manipulations on the blood concentration of serum thymic factor (FTS) was studied in young-adult and old mice. Among the experimentally induced endocrinopathies in youth, hypothyroidism and diabetes caused strong reductions of FTS levels, which were restored to normal by the appropriate hormonal substitutive therapy. Removal of adrenals or gonads has no significant effect on FTS level. Old mice, which show undetectable levels of FTS and low levels of thyroxine, can regain the capacity to produce FTS, provided they are treated with thyroxine. The variations of FTS blood levels in the course of endocrinological manipulations were due to a direct or indirect effect exerted on the recipient thymus. Hormonal treatment of thymectomized mice did not induce any FTS-like activity in their sera, nor did hormones interfere in vitro with the bioassay used to test for FTS. These data suggest that the neuroendocrine balance modulates the synthesis and/or the release of FTS from the thymus during the whole life of the organism and that the decline of FTS production with advancing age is largely dependent on age-associated endocrinological imbalances.

Sympathetic innervation of lymph nodes in mice

Noradrenergic innervation of popliteal and mesenteric lymph nodes in mice was examined with fluorescence histochemistry. Dense varicose plexuses entered the nodes with the vasculature in the hilar region and continued with the vasculature into the medullary region. Fine, delicate varicosities and small vascular plexuses continued into the cortical and paracortical regions surrounding the germinal centers; some varicosities ended among lymphocytes. A subcapsular plexus contributed fibers into the cortical and paracortical regions. Chemical measurements revealed the presence of norepinephrine in lymph nodes that was depletable with 6-hydroxydopamine. Depletion of norepinephrine from lymph nodes with this agent resulted in a diminished primary immune response in draining lymph nodes following subcutaneous injection of an antigen in two mouse strains, but had no effect in two other strains. These findings suggest that noradrenergic fibers innervate both the vasculature and parenchymal regions of lymph nodes, and may participate in the modulation of immune responses in these organs.