Proinflammatory cytokines and sickness behavior in rheumatic diseases.

This review describes mechanisms of immune-to-brain signaling that may contribute to disease-related changes in mood, affect and behavior in chronic inflammatory rheumatic diseases. The central nervous system (CNS) modulates immune function by signaling target cells of the immune system through autonomic and neuroendocrine pathways. These immune cells relay information back to autonomic, limbic and cortical areas of the CNS to affect neural activity and consequently modify behavior, hormone release and autonomic function. In this manner, immune cells function as a sense organ, informing the CNS of peripheral events relating to infection and injury. Equally important, homeostatic mechanisms are needed at all levels to turn off the immune response when the pathogen and injurious condition are eliminated and the repair process is completed. In individuals with chronic inflammatory diseases, such as rheumatoid arthritis (RA), there is a failure of the homeostatic regulation leading to long-term immune activation that has serious health consequences. Rheumatic disorders constitute a challenge to major psychological adaptation resources leading to higher rates of psychological disorders compared with the general population. Thus the relationship between disease pathology and psychological well being is complex.

Potential use of drugs that target neural-immune pathways in the treatment of rheumatoid arthritis and other autoimmune diseases.

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.

Strain differences in the expression of corticotropin-releasing hormone immunoreactivity in nerves that supply the spleen and thymus.

The existence of nerve fibers containing corticotropin-releasing hormone (CRH) immunoreactivity in primary and secondary lymphoid organs from three strains of young adult male rats was examined. Spleens and thymuses from Fischer 344 (F344), Sprague-Dawley (SD) and Lewis (LEW) rats were prepared for immunocytochemistry using antisera directed against CRH. In F344 and SD rats, we were unable to demonstrate CRH-immunoreactive nerves in either the thymus or the spleen. Despite the lack of CRH-containing nerves, CRH immunoreactivity was present in pleotropic cells in the septum, cortex and medulla of the thymus, and in the red and white pulp of spleens from F344 and SD rats. In contrast, CRH+ nerves were found in thymuses and spleens from LEW rats. CRH+ nerves coursed in the interlobular septa, capsule, cortex and medulla of the LEW rat thymus. Large CRH-immunoreactive nerve bundles were present in the hilar region of the LEW rat spleen, and individual CRH+ fibers coursed in the capsule, trabeculae, red pulp, venous sinuses and marginal zone of the white pulp of the spleen. These findings indicate strain differences in neurotransmitter-specific nerves that innervate the rat spleen and thymus under basal conditions.

Local application of capsaicin into the draining lymph nodes attenuates expression of adjuvant-induced arthritis.

Adjuvant-induced experimental arthritis (AA) was examined in adult male Lewis rats after isolated capsaicin (CAPS)-induced loss of small, nonmyelinated, afferent fibers in lymph nodes draining the site of adjuvant challenge. AA was induced by intradermal injection of Freund's complete adjuvant (CFA) into the subplantar area of the right hind paw. Controls received similar injections of mineral oil, the vehicle for CFA. One day later, half of the CFA-treated rats and half of the mineral oil-treated rats received injections of CAPS bilaterally into the draining lymph nodes (DLN). The DLN of remaining rats were injected with 50:50 ethanol/sterile physiological saline, the vehicle for CAPS. This paradigm resulted in four groups designated: CFA/CAPS, CFA/vehicle, vehicle/CAPS and vehicle/vehicle. Since substance P (SP) is present in small, nonmyelinated, afferent fibers, the target of the neurotoxin, CAPS, a radioimmunoassay specific for SP was used to verify the loss of these nerve fibers. CAPS injections into the DLN resulted in a loss in SP concentration in the DLN, with no depletion of SP in the spleen or sciatic nerve. These findings support the destruction of SP-containing nerves, which we interpret as verification of the selective loss of small, non-myelinated afferent nerves in the DLN with no significant spread of the neurotoxin to the nearby sciatic nerves which supply small, nonmyelinated, afferent fibers to the hind limb joints. Also, preservation of SP content in spleen indicates CAPS did not circulate via the lymphatic drainage. No chronic inflammation was observed in the fore or hind limbs from rats treated with the vehicle for CFA (vehicle/vehicle, vehicle/CAPS) at any time during the study. In CFA/vehicle-treated rats, bilateral, symmetrical inflammation of the hind limbs was apparent 14 days after challenge with CFA, and became progressively more inflamed through day 20. In contrast, hind limb inflammation in arthritic rats treated with CAPS was not symmetrical. On days 14 and 20 after challenge with CFA, the inflammatory response in the left hind limb, contralateral to the site of CFA injection, was significantly (p < 0.05) attenuated compared with the response seen on the right side of CFA/CAPS-treated rats, and with the response seen in left hind limb of CFA/vehicle-treated animals. In fact, the mean dorsoplantar width of contralateral hind limbs from CFA/CAPS-treated animals was not different from that measured in non-AA control groups. These findings support a role for small, nonmyelinated, sensory nerves that modulate immune responses in DLN in the development and progression of AA in Lewis rats.

Dual role for noradrenergic innervation of lymphoid tissue and arthritic joints in adjuvant-induced arthritis.

The role of noradrenergic innervation in the disease outcome of adjuvant-induced arthritis (AA) has been examined following (1) systemic administration of guanethidine and (2) local application of 6-hydroxydopamine (6-OHDA) into the lymph nodes that drain the hind limbs (DLN). Sympathetic denervation by these different neurotoxins produced directionally opposite effects on disease outcome. These conflicting findings could be explained from differential denervation of sympathetic nerves in key target tissues that result from different routes of neurotoxin administration. Alternatively, these conflicting data could be due to differences in the mechanisms by which guanethidine and 6-OHDA destroy sympathetic nerve terminals. In this study, we compared disease outcome in AA following systemic and local DLN application of 6-OHDA to determine whether the route of administration is important to the development and progression of AA. Bilateral local DLN application of 6-OHDA or vehicle was performed 1 day before injection of Freund's complete adjuvant (CFA) to induce arthritis. For systemic denervation, 6-OHDA or vehicle was given by ip injections on days 1, 3, and 5 prior to CFA challenge and then once a week. Local DLN application of 6-OHDA resulted in significant increases in dorsoplantar width in arthritic rats by 27 days following CFA treatment compared to those of non-denervated arthritic rats. In contrast, systemic denervation in arthritic rats significantly decreased dorsoplantar widths 27 days after CFA treatment compared to those in sympathetically intact arthritic animals. X-ray analysis confirmed these findings. Further, local DLN application of 6-OHDA exacerbated the disease regardless of whether the neurotoxin was administered prior to immunization with CFA or closer to the time of disease onset. Our findings indicate that the route of 6-OHDA administration for denervation of sympathetic innervation is an important parameter in determining disease outcome, presumably due to differential sympathetic denervation of target tissues that are involved in disease development and progression. 6-OHDA administration into local DLN denervated these lymph nodes, but spared sympathetic innervation of the hind limbs, a pattern of sympathetic denervation that resulted in disease exacerbation. In contrast, systemic 6-OHDA administration which denervated both the arthritic joints and the secondary lymphoid organs attenuated the severity of AA. This study supports a dual role for NA innervation in modulating the severity of AA by innervation of the arthritic joints and lymphoid organs.

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.