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 as focused on neural-immune modulation in secondary lymphoid organs, and have 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.
This review describes mechanisms of immune-to-brain and brain-to-immune signaling involved in mediating physiological sleep and altered sleep with disease. The central nervous system (CNS) modulates immune function by signaling target cells of the immune system through autonomic and neuroendocrine pathways. Neurotransmitters and hormones produced and released by these pathways interact with immune cells to alter immune functions, including cytokine production. Cytokines produced by cells of the immune and nervous systems regulate sleep. Cytokines released by immune cells, particularly interleukin-1β and tumor necrosis factor-α, signal neuroendocrine, autonomic, limbic and cortical areas of the CNS to affect neural activity and modify behaviors (including sleep), hormone release and autonomic function. In this manner, immune cells function as a sense organ, informing the CNS of peripheral events related to infection and injury. Equally important, homeostatic mechanisms, involving all levels of the neuroaxis, are needed, not only to turn off the immune response after a pathogen is cleared or tissue repair is completed, but also to restore and regulate natural diurnal fluctuations in cytokine production and sleep. The immune system’s ability to affect behavior has important implications for understanding normal and pathological sleep. Sleep disorders are commonly associated with chronic inflammatory diseases and chronic age- or stress-related disorders. The best studied are rheumatoid arthritis, fibromyalgia and chronic fatigue syndromes. This article reviews our current understanding of neuroimmune interactions in normal sleep and sleep deprivation, and the influence of these interactions on selected disorders characterized by pathological sleep.
Adjuvant-induced arthritic (AA) differentially affects norepinephrine concentrations in immune organs, and in vivo
β-adrenergic receptor (β-AR) agonist treatment distinctly regulates ex vivo cytokine profiles in different immune organs. We examined the contribution of altered β-AR functioning in AA to understand these disparate findings. Twenty-one or 28 days after disease induction, we examined β
2-AR expression in spleen and draining lymph nodes (DLNs) for the arthritic limbs using radioligand binding and western blots and splenocyte β-AR-stimulated cAMP production using enzyme-linked immunoassay (EIA). During severe disease, β-AR agonists failed to induce splenocyte cAMP production, and β-AR affinity and density declined, indicating receptor desensitization and downregulation. Splenocyte β
2-AR phosphorylation (pβ
2-AR) by protein kinase A (pβ
2-ARPKA) decreased in severe disease, and pβ
2-AR by G protein-coupled receptor kinases (pβ
2-ARGRK) increased in chronic disease. Conversely, in DLN cells, pβ
2-ARPKA rose during severe disease, but fell during chronic disease, and pβ
2-ARGRK increased during both disease stages. A similar pβ
2-AR pattern in DLN cells with the mycobacterial cell wall component of complete Freund's adjuvant suggests that pattern recognition receptors (i.e., toll-like receptors) are important for DLN pβ
2-AR patterns. Collectively, our findings indicate lymphoid organ- and disease stage-specific sympathetic dysregulation, possibly explaining immune compartment-specific differences in β
2-AR-mediated regulation of cytokine production in AA and rheumatoid arthritis.
The sympathetic nervous system (SNS) regulates host defense responses and restores homeostasis. SNS-immune regulation is altered in rheumatoid arthritis (RA) and rodent models of RA, characterized by nerve remodeling in immune organs and defective adrenergic receptor (AR) signaling to immune cell targets. The SNS typically promotes or suppresses inflammation via α- and β2-AR activation, respectively, and indirectly drives humoral immunity by blocking Th1 cytokine secretion. Here, we investigate how β2-AR stimulation and/or α-AR blockade at disease onset affects disease pathology and cytokine profiles in relevant immune organs from male Lewis rats with adjuvant-induced arthritis (AA). Rats challenged to induce AA were treated with terbutaline (TERB), a β2-AR agonist (600 μg/kg/day) and/or phentolamine (PHEN), an α-AR antagonist (5.0 mg/kg/day) or vehicle from disease onset through severe disease. We report that in spleen, mesenteric (MLN) and draining lymph node (DLN) cells, TERB reduces proliferation, an effect independent of IL-2. TERB also fails to shift T helper (Th) cytokines from a Th1 to Th2 profile in spleen and MLN (no effect on IFN-γ) and DLN (greater IFN-γ) cells. In splenocytes, TERB, PHEN, and co-treatment (PT) promotes an anti-inflammatory profile (greater IL-10) and lowers TNF-α (PT only). In DLN cells, drug treatments do not affect inflammatory profiles, except PT, which raised IL-10. In MLN cells, TERB or PHEN lowers MLN cell secretion of TNF-α or IL-10, respectively. Collectively, our findings indicate disrupted β2-AR, but not α-AR signaling in AA. Aberrant β2-AR signaling consequently derails the sympathetic regulation of lymphocyte expansion, Th cell differentiation, and inflammation in the spleen, DLNs and MLs that is required for immune system homeostasis. Importantly, this study provides potential mechanisms through which reestablished balance between α- and β2-AR function in the immune system ameliorates inflammation and joint destruction in AA.
Many autoimmune disorders share two common features, dysregulation of the immune system and stress pathways. Two stress pathways, the hypothalamic-pituitary-adrenal (HPA) axis and the sympathetic nervous system (SNS), regulate immune system responses, through release of corticosteroids and norepinephrine (NE), respectively. These neuromediators act on immune cells via specific receptors on their surface to modulate the production of key regulatory cytokines. Glucocorticoids modulate immune responses by glucocorticoid binding to cytoplasmic glucocorticoid receptors within target cells. NE regulates immune responses through interaction with plasma membrane beta- or alpha-adrenergic receptors (AR). Both NE and glucocorticoids promote humoral immunity by altering macrophages and T cell cytokine production after an antigen challenge. Glucocorticoids and NE do this by inhibiting interleukin (IL)-12, and interferon (IFN)-gamma, which drives cell-mediated immunity. Additionally, catecholamines drive humoral immunity by stimulating macrophage IL-10 production. These catecholamine effects are mediated largely via beta(2)-AR activation. Both glucocorticoids and NE inhibit inflammation. However, under some circumstances NE promotes inflammation through interaction with macrophage alpha1-AR and subsequent increases in tumor necrosis factor alpha (TNFalpha production. Although macrophages do not normally express alpha(1)-AR, expression of this receptor on macrophages and monocytes occurs in some disease states, including rheumatoid arthritis (RA). Through these mechanisms the HPA axis and the SNS influence the course and progression of RA. Thus, the HPA axis and the SNS are likely to play key roles in the pathology of RA. Furthermore, therapeutic agents targeting the neural pathways that normally regulate immune system homeostasis may prove beneficial for treating RA and other autoimmune diseases.
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