Papel dos adrenoceptores β em células dendríticas derivadas de monócitos humanos / Role of β-adrenoceptors in human monocyte-derived dendritic cells

Cruz, Daniel Sanzio Gimenes da

24 March 2017

O sistema nervoso simpático (SNS) inerva a maioria dos órgãos linfoides e durante situações de estresse, por meio da liberação da noradrenalina de seus ramos eferentes, emitem sinais capazes de modular as repostas imunes. Nossa hipótese foi de que esta via poderia alterar a função de células dendríticas (DCs) derivadas de monócitos humanos, uma vez que receptores adrenérgicos já foram demonstrados em DCs murinas e pelo fato de que as estas células são chave na iniciação de respostas imunes adaptativas, bem como indutoras de tolerância. Desta forma, DCs diferenciadas a partir de monócitos sanguíneos provenientes de doadores saudáveis tratadas com ligantes adrenérgicos foram analisadas quanto a expressão de marcadores de membrana, atividade fagocítica, apresentação antigênica em ensaio de reação mista de linfócitos, expressão gênica de marcadores de diferenciação e ativação, bem como produção de citocinas. Os resultados revelaram que as DCs apresentam transcritos apenas para o adrenoceptor β2, e esta expressão é similar à de macrófagos, mas inferior a de linfócitos. A análise dos marcadores fenotípicos de membrana, atividade fagocítica, apresentação antigênica e produção de citocinas não mostraram alterações nas células tratadas com agonistas adrenérgicos. No entanto, o tratamento com ligantes adrenérgicos foi capaz de alterar a expressão dos genes CD40, CD80, CD83, CXCL1, TGFB1, FCGR3A, CCR7 e CCL5 em DCs e macrófagos estimulados com LPS ou TNF-α. Embora os efeitos dos ligantes adrenérgicos não tenham sido fortemente evidenciados nos testes realizados, os resultados sugerem que pequenas alterações podem ser provocadas pela ligação das catecolaminas em DCs, sugerindo que estas possam ser moduladas pelo SNS, modificando as respostas imunes / The sympathetic nervous system (SNS) innervates most of the lymphoid organs and during stress situations, by releasing norepinephrine from its efferent branches, emit signals capable of modulating immune responses. Our hypothesis was that this pathway could alter the function of human monocyte-derived dendritic cells (DCs), since adrenergic receptors have already been demonstrated in murine DCs, and by the fact that these cells are key in initiating adaptive immune responses as well as tolerance inducers. Thus, differentiated DCs from blood monocytes from healthy donors treated with adrenergic ligands were analyzed for expression of membrane markers, phagocytic activity, antigenic presentation in a mixed lymphocyte reaction assay, gene expression of differentiation and activation markers and cytokine production. The results revealed that DCs present transcripts only for the β2 adrenoceptor, and this expression is similar to that observed in macrophages, but lower than what it is found in lymphocytes. The analysis of phenotypic membrane markers, phagocytic activity, antigenic presentation and cytokine production did not revealed any changes in the cells treated with adrenergic agonists. However, treatment with the adrenergic ligands was able to alter the expression of CD40, CD80, CD83, CXCL1, TGFB1, FCGR3A, CCR7 and CCL5 genes in DCs and macrophages stimulated with LPS or TNF-α. Although the effects of adrenergic ligands have not been strongly demonstrated in the tests performed, the results suggest that small changes can be caused by the binding of catecholamines in DCs, suggesting that they can be modulated by the SNS, modifying immune responses.

Células dendríticas (DCs)

Dendritic cells (DCs)

Estresse

Neuroimmunomodulation

Neuroimunomodulação

Sistema nervoso simpático (SNS)

Stress

Sympathetic nervous system (SNS)

Papel dos adrenoceptores β em células dendríticas derivadas de monócitos humanos / Role of β-adrenoceptors in human monocyte-derived dendritic cells

Daniel Sanzio Gimenes da Cruz

24 March 2017

O sistema nervoso simpático (SNS) inerva a maioria dos órgãos linfoides e durante situações de estresse, por meio da liberação da noradrenalina de seus ramos eferentes, emitem sinais capazes de modular as repostas imunes. Nossa hipótese foi de que esta via poderia alterar a função de células dendríticas (DCs) derivadas de monócitos humanos, uma vez que receptores adrenérgicos já foram demonstrados em DCs murinas e pelo fato de que as estas células são chave na iniciação de respostas imunes adaptativas, bem como indutoras de tolerância. Desta forma, DCs diferenciadas a partir de monócitos sanguíneos provenientes de doadores saudáveis tratadas com ligantes adrenérgicos foram analisadas quanto a expressão de marcadores de membrana, atividade fagocítica, apresentação antigênica em ensaio de reação mista de linfócitos, expressão gênica de marcadores de diferenciação e ativação, bem como produção de citocinas. Os resultados revelaram que as DCs apresentam transcritos apenas para o adrenoceptor β2, e esta expressão é similar à de macrófagos, mas inferior a de linfócitos. A análise dos marcadores fenotípicos de membrana, atividade fagocítica, apresentação antigênica e produção de citocinas não mostraram alterações nas células tratadas com agonistas adrenérgicos. No entanto, o tratamento com ligantes adrenérgicos foi capaz de alterar a expressão dos genes CD40, CD80, CD83, CXCL1, TGFB1, FCGR3A, CCR7 e CCL5 em DCs e macrófagos estimulados com LPS ou TNF-α. Embora os efeitos dos ligantes adrenérgicos não tenham sido fortemente evidenciados nos testes realizados, os resultados sugerem que pequenas alterações podem ser provocadas pela ligação das catecolaminas em DCs, sugerindo que estas possam ser moduladas pelo SNS, modificando as respostas imunes / The sympathetic nervous system (SNS) innervates most of the lymphoid organs and during stress situations, by releasing norepinephrine from its efferent branches, emit signals capable of modulating immune responses. Our hypothesis was that this pathway could alter the function of human monocyte-derived dendritic cells (DCs), since adrenergic receptors have already been demonstrated in murine DCs, and by the fact that these cells are key in initiating adaptive immune responses as well as tolerance inducers. Thus, differentiated DCs from blood monocytes from healthy donors treated with adrenergic ligands were analyzed for expression of membrane markers, phagocytic activity, antigenic presentation in a mixed lymphocyte reaction assay, gene expression of differentiation and activation markers and cytokine production. The results revealed that DCs present transcripts only for the β2 adrenoceptor, and this expression is similar to that observed in macrophages, but lower than what it is found in lymphocytes. The analysis of phenotypic membrane markers, phagocytic activity, antigenic presentation and cytokine production did not revealed any changes in the cells treated with adrenergic agonists. However, treatment with the adrenergic ligands was able to alter the expression of CD40, CD80, CD83, CXCL1, TGFB1, FCGR3A, CCR7 and CCL5 genes in DCs and macrophages stimulated with LPS or TNF-α. Although the effects of adrenergic ligands have not been strongly demonstrated in the tests performed, the results suggest that small changes can be caused by the binding of catecholamines in DCs, suggesting that they can be modulated by the SNS, modifying immune responses.

Células dendríticas (DCs)

Estresse

Neuroimunomodulação

Sistema nervoso simpático (SNS)

Dendritic cells (DCs)

Neuroimmunomodulation

Stress

Sympathetic nervous system (SNS)

Central Nervous System Regulation of Fat Cell Lipid Mobilization: The Role of the Sympathetic Nervous System

Foster, Michelle Tranace

12 January 2006

Obesity is a growing disorder in the United States, affecting over 60% of the population. We previously defined sympathetic nervous system (SNS) outflow from brain to white adipose tissue (WAT) using a viral transneuronal tract tracer. SNS innervation of WAT is the principle initiator of lipolysis, whereas decreases in sympathetic drive promote lipid accumulation. Which of the many origins of SNS outflow from brain to WAT results in SNS-mediated changes in lipid mobilization (increases in drive) or accumulation (decrease in drive) is unknown. Previous research indicates that sympathetic denervation blocks lipid mobilization; thus, rostral sites in the neuroaxis connected to WAT via the SNS may promote WAT lipid mobilization. The hypothalamic paraventricular nucleus (PVN) may play a role via its descending projections to the intermediolateral horn of the spinal cord. Therefore, the consequences of PVN lesions (PVNx) on WAT mobilization or accumulation were tested. PVNx resulted in increased lipid accumulation, indicated by increases in retroperitoneal (RWAT) , epididymal (EWAT) , and inguinal WAT (IWAT) pad masses, in fed hamsters, but PVNx did not block fasting (56 h)-induced lipid mobilization. Because adrenal medullary catecholamines, especially epinephrine, also play a minor role in lipid mobilization, we tested the contribution of catecholamine release on lipid mobilization through adrenal demedullation (ADMEDx), with and without PVNx, and found fastinginduced lipid mobilization was not blocked. There was, however, a suggestion that distal denervation of IWAT, with and without ADMEDx, partially blocked lipid mobilization. In addition, evidence suggests SNS also may be an important controller of fat cell proliferation. Surgical denervation of WAT triggers increases in fat cell number (FCN), but have not determined if this FCN increase is due to preadipocyte proliferation or differentiation of preadipocytes into mature fat cells. We also have not demonstrated what role sensory innervation may have in regulating white adipocyte proliferation. Therefore, the role of WAT sympathetic or sensory innervation on adipocyte proliferation was tested. The SNS but not sensory denervation triggered bona fide proliferation as indicated by bromodeoxyuridine plus AD3, a specific adipocyte membrane protein, colabeling. These and previous data suggest that the SNS plays a role in regulating adiposity.

Sympathetic Nervous System (SNS)

Lipid Mobilization

Sympathetic Denervation

Bromodeoxyuridine (BrdU)

Paraventricular Nucleus (PVN)

Obesity

White Adipose Tissue (WAT)

Biology, general