Neuropeptides as signal molecules in common with leukocytes and the hypothalamic-pituitary-adrenal axis

There exists a bidirectional regulatory circuit between the nervous and immune systems. This regulation has been shown to be mediated in part through neuroendocrine hormones and cytokines. Both systems have receptors for both types of signal molecules. The nervous system has receptors for cytokines and it also synthesizes cytokines. The immune system synthesizes and responds to cytokines. So, it is not too far-fetched to believe that neuroendocrine peptide hormones could bind to leukocytes and modulate immune functions. However, it is not widely known that the immune system also synthesizes functional, neuropeptide hormones. This will be discussed in this paper citing a plethora of evidence. The aim of this paper is to summarize this evidence by using three neuropeptides that are synthesized by leukocytes and modulate immune functions as examples; corticotropin (ACTH), endorphin (END), and corticotropin releasing factor (CRF). The production and action of these three neuropeptides in the immune system will be explained. Finally, the potential physiological role of leukocyte-derived ACTH, END, and CRF in inflammation as a localized hypothalamic-pituitary-like axis is discussed.     

Receptor regulation in neuroendocrine-immune communication: current knowledge and future perspectives

Immune cells express receptors for every hormone or neurotransmitter we know so far. The neuroendocrine system signals to the immune system via the release of hormones and neurotransmitters that regulate cellular activity via these receptors. Much attention has been focused on the effect of glucocorticoids and catecholamines on the immune system. Glucocorticoids communicate with immune cells via glucocorticoid receptors of which the activity itself changes during immune activation. Many neuroendocrine mediators are ligands for G-protein coupled receptors on immune cells. Cytokines, oxygen-radicals, and catecholamines can influence the responsiveness of G-protein coupled receptors via decreasing the intracellular level of so-called G-protein coupled receptor kinases, of which the subtype GRK2 is highly expressed in immune cells. Therefore, changes in only one kinase can modulate the sensitivity of many receptors. We describe here that sensitivity of neuroendocrine receptors on immune cells is constantly regulated by inflammatory processes or chronic stress, which implies that not only the activity of the neuroendocrine system determines communication but that the sensitivity of receptors is a major factor in determining the final immune response. Finally, consequences of alterations in GRK2 during (neuro)-inflammatory diseases are discussed.     

The importance of being receptive

Neuroendocrine system and immune system can communicate via the use of soluble mediators like hormones, neurotransmitters and cytokines. The level of mediators secreted by either of these systems creates the milieu in which immune and neuroendocrine responses take place. For adequate communication between the systems, receptors for hormones, neurotransmitters and cytokines are required. This review describes the role of regulated expression and function of receptors for hormones and neurotransmitters within the immune system in neuroendocrine-immune communication.     

Impact of the neuroendocrine system on thymus and bone marrow function

The nervous, endocrine, and immune systems interact to adapt to infection, inflammation, and tissue injury. Neural control is mediated in several ways, one of them being through the neuroendocrine regulation of the secretion of hypothalamic and pituitary hormones. The hormonal effects on the immune system range from the impact of steroidal hormones, which exhibit inhibitory effects over immune functions, to growth hormone, prolactin and neurohypophyseal hormones, known to stimulate and modulate humoral and cellular aspects of the immune system. This review will discuss the mechanisms behind the immunomodulatory role of the neuroendocrine system, including the critically important feedback loops required to maintain balance for these bidirectional interactions and alterations that occur with age.     

Conditioned immunomodulation: research needs and directions

Considering the brief time that psychoneuroimmunology has existed as a bona fide field of research, a great deal of data has been collected in support of the proposition that homeostatic mechanisms are the product of an integrated system of defenses of which the immune system is a critical component. It is now clear that immune function is influenced by autonomic nervous systems activity and by the release of neuroendocrine substances from the pituitary. Conversely, cytokines and hormones released by an activated immune system influence neural and endocrine processes. Regulatory peptides and receptors, once confined to the brain, are expressed by both the nervous and immune systems enabling each system to monitor and modulate the activities of the other. It is hardly surprising, then, that immunologic reactivity can be influenced by stressful life experiences or by Pavlovian conditioning.     

Protein hormones and immunity

A number of observations and discoveries over the past 20 years support the concept of important physiological interactions between the endocrine and immune systems. The best known pathway for transmission of information from the immune system to the neuroendocrine system is humoral in the form of cytokines, although neural transmission via the afferent vagus is well documented also. In the other direction, efferent signals from the nervous system to the immune system are conveyed by both the neuroendocrine and autonomic nervous systems. Communication is possible because the nervous and immune systems share a common biochemical language involving shared ligands and receptors, including neurotransmitters, neuropeptides, growth factors, neuroendocrine hormones and cytokines. This means that the brain functions as an immune-regulating organ participating in immune responses. A great deal of evidence has accumulated and confirmed that hormones secreted by the neuroendocrine system play an important role in communication and regulation of the cells of the immune system. Among protein hormones, this has been most clearly documented for prolactin (PRL), growth hormone (GH), and insulin-like growth factor-1 (IGF-I), but significant influences on immunity by thyroid-stimulating hormone (TSH) have also been demonstrated. Here we review evidence obtained during the past 20 years to clearly demonstrate that neuroendocrine protein hormones influence immunity and that immune processes affect the neuroendocrine system. New findings highlight a previously undiscovered route of communication between the immune and endocrine systems that is now known to occur at the cellular level. This communication system is activated when inflammatory processes induced by proinflammatory cytokines antagonize the function of a variety of hormones, which then causes endocrine resistance in both the periphery and brain. Homeostasis during inflammation is achieved by a balance between cytokines and endocrine hormones.     

A molecular basis for interactions between the immune and neuroendocrine systems

Homeostatic and psychologic alterations associated with infections and tumors are very interesting yet poorly understood pathophysiologic responses. Numerous anecdotal and indirect examples suggest that these responses occur through a link between the central nervous and immune systems (for review see Blalock, Bost, & Smith, 1985; Spector & Korneva, 1981; Maestroni & Pierpaoli, 1981; Felton et al., 1985; Jankovic, 1985). Interactions between the two systems are just now being described. One possible mechanism is direct modulation of the immune system by the sympathetic nervous system. This could occur in innervated immune organs such as spleen, thymus, and bone marrow (Felton et al., 1985). The evidence for this is that sympathectomy and lesioning of specific regions of the brain can be shown to both enhance and/or suppress immune responses (Miles et al., 1985; Roszman et al., 1985). Also, the firing rate of hypothalamic neurons is altered during an immune response (Besedovsky et al., 1977). Alternatively, hormonal involvement in immune reactions has been known for some time, in particular the immunosuppressive effects of glucocorticoids (for review see Cupps & Fauci, 1982). Recently, we and others found that neuroendocrine peptide hormones will modulate T and B lymphocytes plus other immunocyte responses (Besedovsky et al., 1977; Cupps & Fauci, 1982; Johnson et al., 1982; Wybran et al., 1979; Hazum, Chang & Cuatrecasas, 1979; O'Dorisio et al., 1981; Gilman et al., 1982; McCain et al., 1982; Mathews et al., 1983; Plotnikoff et al., 1985; Johnson et al., 1984). Furthermore, lymphocytes themselves can synthesize biologically active neuroendocrine hormones (Blalock & Smith, 1980; O'Dorisio et al., 1980; Smith & Blalock, 1981; Smith et al., 1983; Lolait et al., 1984; Ruff & Pert, 1984), as well as possess specific hormone receptors (Blalock et al., 1985; Johnson et al., 1982; Wybran et al., 1979; Hazum et al., 1979; O'Dorisio et al., 1981; Lopker et al., 1980; Payan, Brewster & Goetzl, 1984; Pert et al., 1985). Immune responses (Besedovsky, del Rey & Sorkin, 1981), thymic hormones (Healy et al., 1983), and lymphokines (Lotze et al., 1985; Woloski et al., 1985) have all been shown to exert hormonal effects. Thus, another method for communication between the immune and neuroendocrine systems seems to be through soluble factors such as neuroendocrine hormones. This review will concentrate on the latter topic, in particular on work this laboratory has done over the past few years to show the lymphocyte production and immunoregulatory actions of neuroendocrine hormones.     

Evidence of conserved neuroendocrine interactions in the thymus: intrathymic expression of neuropeptides in mammalian and non-mammalian vertebrates

The function of lymphoid organs and immune cells is often modulated by hormones, steroids and neuropeptides produced by the neuroendocrine and immune systems. The thymus intrinsically produces these factors and a comparative analysis of the expression of neuropeptides in the thymus of different species would highlight the evolutionary importance of neuroendocrine interaction in T cell development. In this review, we highlight the evidence which describes the intrathymic expression and function of various neuropeptides and their receptors, in particular somatostatin, substance P, vasointestinal polypeptide, calcitonin gene-related peptide and neuropeptide Y, in mammals (human, rodent) and non-mammals (avian, amphibian and teleost), and conclude that neuropeptides play a conserved role in vertebrate thymocyte development.     

Neuroendocrine–immune interactions in homeostasis and autoimmunity

Recent experimental evidence confirms the interrelationships between the central nervous, neuroendocrine and immune systems. Indeed, extensive duality exists in the use of neurotransmitters, hormones and receptors each system displays. In the present annotation, the effect of cytokines, soluble mediators of immune function, on the CNS and neuroendocrine systems is addressed and conversely, we discuss the modification of the immune compartment by the sympathetic nervous and neuroendocrine systems, with particular reference to the role of noradrenaline and corticosterone. Dysfunction between the systems is considered in the context of autoimmune conditions, with emphasis on experimental allergic encephalomyelitis and the contribution of corticosterone–driven T–cell apoptosis to recovery from the disease. Finally, we speculate on the relevance of neuroimmune interactions in the pathogenesis of multiple sclerosis.     

Psychoneuroimmunology--cross-talk between the immune and nervous systems

Psychoneuroimmunology is a relatively new field of study that investigates interactions between behaviour and the immune system, mediated by the endocrine and nervous systems. The immune and central nervous system (CNS) maintain extensive communication. On the one hand, the brain modulates the immune system by hardwiring sympathetic and parasympathetic nerves (autonomic nervous system) to lymphoid organs. On the other hand, neuroendocrine hormones such as corticotrophin-releasing hormone or substance P regulate cytokine balance. Vice versa, the immune system modulates brain activity including sleep and body temperature. Based on a close functional and anatomical link, the immune and nervous systems act in a highly reciprocal manner. From fever to stress, the influence of one system on the other has evolved in an intricate manner to help sense danger and to mount an appropriate adaptive response. Over recent decades, reasonable evidence has emerged that these brain-to-immune interactions are highly modulated by psychological factors which influence immunity and immune system-mediated disease.     

The immune-hypothalamo-pituitary-adrenal axis and autoimmunity.

Immunoendocrinology is a rapidly expanding field, uncovering numerous bilateral interactions between the immune system and neuroendocrine circuits. Various hormones and neurotransmitters appear to modulate cells of the immune system and likewise cytokines control the function of neuroendocrine system. In the present paper, we discuss some lines of evidence indicating that an immunoendocrine feedback loop, which we term 'immune-hypothalamo-pituitary-adrenal system' is an integral part of the regulation of self tolerance. The finding that pathology of this immunoendocrine feedback loop is related to development of autoimmunity may lead to new prophylactic and therapeutic strategies.     

How cancer hijacks the body’s homeostasis through the neuroendocrine system

During oncogenesis, cancer not only escapes the body’s regulatory mechanisms, but also gains the ability to affect local and systemic homeostasis. Specifically, tumors produce cytokines, immune mediators, classical neurotransmitters, hypothalamic and pituitary hormones, biogenic amines, melatonin, and glucocorticoids, as demonstrated in human and animal models of cancer. The tumor, through the release of these neurohormonal and immune mediators, can control the main neuroendocrine centers such as the hypothalamus, pituitary, adrenals, and thyroid to modulate body homeostasis through central regulatory axes. We hypothesize that the tumor-derived catecholamines, serotonin, melatonin, neuropeptides, and other neurotransmitters can affect body and brain functions. Bidirectional communication between local autonomic and sensory nerves and the tumor, with putative effects on the brain, is also envisioned. Overall, we propose that cancers can take control of the central neuroendocrine and immune systems to reset the body homeostasis in a mode favoring its expansion at the expense of the host.     

Neuroendocrine actions of nicotine and of exposure to cigarette smoke: medical implications

Over many years a large number of studies have demonstrated that nicotine and exposure to cigarette smoke produce marked neuroendocrine changes in animals and in man. The initial effects of nicotine are characterized by a marked hypersecretion of ACTH, vasopressin, beta-endorphin, prolactin and LH. Many of these very acute stimulatory effects of nicotine rapidly disappear, probably due to a desensitization of the central nicotinic cholinergic receptors involved. Instead, upon acute intermittent treatment with nicotine or exposure to cigarette smoke, an inhibition of prolactin, LH and TSH secretion occurs, which is associated with maintained hypersecretion of corticosterone. These effects are probably mediated via activation of central cholinergic receptors of the ganglionic type. Evidence indicates that the inhibitory effects of nicotine on LH and prolactin secretion are produced via an activation by these nicotinic receptors of the tubero-infundibular dopamine neurons, releasing dopamine as a prolactin inhibitory factor. Dopamine inhibits LHRH release via an axonic interaction involving D1-like dopamine receptors in the median eminence. It therefore seems possible that the reduced fertility found in heavy smokers may be counteracted by D1 receptor antagonists. The symptoms associated with glucocorticoid hypersecretion induced by nicotine is discussed considering not only the peripheral side effects but also permanent deficits in hippocampal glucocorticoid receptors and loss of hippocampal neurons. In view of the important influence of hormones on immune functions, it seems likely that smoking will cause disturbances in immune responsiveness. Finally, the nicotine-induced alterations of neuroendocrine function, especially in the pituitary-adrenal axis and in vasopressin release, may also lead to behavioural consequences in smokers, especially in the withdrawal phase.     

Neural-immune interactions: an integrative view of the bidirectional relationship between the brain and immune systems

This review briefly summarizes a part of the relevant knowledge base of neuroimmunology, with particular emphasis on bidirectional neural-immune interactions. These complex systems interact at multiple levels. Both neuroendocrine (the primary hormonal pathway is hypothalamic-pituitary-adrenal axis) and neuronal (direct sympathetic innervation of the lymphoid organs) pathways are involved in the control of the humoral and cellular immune responses. Although, the recent evidence has been made on immunosuppressive effect of acetylcholine-secreting neurons of the parasympathetic nervous system. The immune system, in turn, influences the central nervous system primarily through cytokines. At the molecular level, neuro- and immune signal molecules (hormones, neurotransmitters, neuropeptides, cytokines) or their receptors are member of the same superfamily which enable the mutual neuroimmune communication. Most extensively studied are cytokine-neuropeptide/neurotransmitter interactions and the subcellular and molecular mechanisms of these interactions. At the system (neuroanatomical) level, advances in neural-immune communication have been made in the role of discrete brain areas related to emotionality. The immunoenhancement, including the antiviral and antitumor cytotoxic activity, related to the "brain reward system", limbic structures and neocortex, offers a new directions for therapy in immune disorders.     

Hormonal Regulation of Cerebellar Development and Plasticity

Cerebellar development and plasticity is involved in various epigenetic processes that activate specific genes at different time point. The epigenetic influences include humoral influences from endocrine cells of peripheral organs. A number of hormone receptors are expressed in cerebellum, and cerebellar function is greatly influenced by hormonal status. Furthermore, recent studies have shown that some of such substances are produced locally and affect through their specific hormone receptors. The aim of this special issue was to introduce several key features of hormones and their receptors to regulate cerebellar development and plasticity. The contribution covers thyroid/steroid hormone systems including orphan receptors and co-regulators, neurosteroids, and transporters. It also covers environmental signal that may affect cerebellar hormonal environment. Furthermore, several neuropeptides, which are initially found as neuroendocrine hormones but later identified as neurotransmitters that play an important role in cerebellar function, are also covered.     

Scenarios for a viral etiology of schizophrenia

Recent discoveries in the field of virus receptors have revolutionized our concepts of viral pathogenesis. The lysis of cells resulting from virus infection or immune recognition of infected cells is seen as merely one facet of a spectrum of pathogenic mechanisms which may be subtle and complex. This is particularly relevant to the central nervous and immune systems which share cell-surface receptors for various neuropeptides and neurotransmitters. A number of viruses are now known to share receptors for such endogenous ligands; indeed, some viruses (e.g., human immunodeficiency virus and vaccinia) may themselves be structural analogs of these ligands. There is, therefore, considerable scope for interference by viruses in the normal functioning of the brain and neuroendocrine systems. Brief reactive psychoses are occasionally reported as acute sequels to viral infections, but generally these are regarded as unrelated to schizophrenia. An opposite viewpoint is presented in the article: i.e., that the only reason these reactive psychoses do not progress to schizophrenia is that the majority of individuals affected are not predisposed genetically to schizophrenia. Conceivably, therefore, the genetic predisposition to schizophrenia may be attributable to genes which determine idiosyncratic differences in immune responsiveness to common viral pathogens.     

Cascading effects of stressors and inflammatory immune system activation: implications for major depressive disorder

Activation of the inflammatory immune system provokes numerous neuroendocrine and neurotransmitter changes, many of which are similar to those provoked by physical or psychological stressors. These findings, among others, have led to the suggestion that the brain translates immune activation much as if it were a stressor. In this review, I provide synopses of the effects of traditional stressors on the release of corticotropin-releasing hormones at hypothalamic and extrahypothalamic sites, variations of serotonin and its receptors and changes of brain-derived neurotrophic factor (BDNF). These effects are similar to those elicited by activation of the inflammatory immune system, particularly the impact of the immune-signalling molecules interleukin-1β, interleukin-6, tumour necrosis factor-α and interferon-α on neuroendocrine, neurotransmitter and BDNF function. In addition, it is reported that stressors and cytokines may synergistically influence biological and behavioural processes and that these treatments may have long-term ramifications through the sensitization of processes associated with stress responses. Finally, I present an overview of the depressogenic actions of these cytokines in rodent models and in humans, and I provide provisional suggestions (and caveats) about the mechanisms by which cytokines and stressors might culminate in major depressive disorder.     

The relationship between interleukin-6 and herpes simplex virus type 1: implications for behavior and immunopathology.

Cytokines are hormones once thought to be restricted to the immune system produced solely by hematopoietic-derived cells and acting on receptors expressed by cells of the immune system. However, it is now clear that many cytokines are produced not only by lymphocytes, monocytes, granulocytes, and dendritic cells but are also synthesized by cells outside the realm of the immune system in response to stimuli that may not be associated with immune homeostasis. In fact, there is evidence supporting a role of selected cytokines modifying behavior and neuroendocrine function. Recently, a potential relationship between the cytokine interleukin (IL)-6 and herpes simplex virus type 1 (HSV-1) reactivation has been found. This article discusses the relevance of these findings and considers the potential impact that HSV-1 infection has on behavior and chronic inflammatory processes that can occur in the nervous system during "latent" virus infection as a result of chronic IL-6 expression.