Glutamate Receptor Subunit Immunoreactivity in Neurons of the Rat Rostral Ventrolateral Medulla

Brailoiu, G. Cristina, Dun, Siok L., Dun, Nae J.

28 June 2002

Immunohistochemical studies were conducted to assess the subunits of ionotropic and metabotropic glutamate receptor present in the rostral ventrolateral medulla (RVLM) of the rat. Double labeling the medullary sections with polyclonal GluR1, GluR2/3, GluR4, NMDAR1, NMDAR2A/B, mGluR1α, and mGluR2/3 antiserum and monoclonal tyrosine hydroxylase (TH) antiserum revealed nearly all TH immunoreactive (irTH) cells and many TH-negative neurons were immunoreactive to GluR2/3 (irGluR2/3), NMDAR1 (irNMDAR1), and NMDAR2A/B (irNMDAR2A/B). A few RVLM neurons were immunoreactive to GluR1 (irGluR1) and GluR4 (irGluR4), but they were generally TH-negative. Immunoreactivity to mGluR1α (irmGluR1α) appeared to be localized exclusively to fiber-like elements in the RVLM area. Our results show that neurons in the RVLM, including irTH, are endowed mainly with GluR2/3 and NMDAR1 or NMDAR2A/B ionotropic receptor subunits, and that irmGluR1α splice variant appears to be located on nerve fibers ramifying within the RVLM. Moreover, TH-negative neurons in the RVLM appear to bear similar subunits of ionotropic glutamate receptors.

ionotropic glutamate receptors

metabotropic glutamate receptors

tyrosine hydroxylase

The role of ionotropic glutamate receptors in the dorsomedial hypothalamus in the increase in core body temperature evoked by interoceptive and exteroceptive stresses in rats

Moreno, Maria.

January 2010

Thesis (Ph.D.)--Indiana University, 2010. / Title from screen (viewed on March 3, 2010). Department of Pharmacology and Toxicology, Indiana University-Purdue University Indianapolis (IUPUI). Advisor(s): Joseph A. DiMicco, Sherry F. Queener, Daniel E. Rusyniak, Michael R. Vasko. Includes vitae. Includes bibliographical references (leaves 126-147).

Papel dos receptores de glutamato tipo NMDA em macrófagos, células dendríticas e células T CD4  ativadas in vitro. / The role of NMDA glutamate receptors in T lymphocytes activated in vitro.

Fickinger, Andira Michele da Cruz

26 February 2014

A neuroimunologia é o ramo da imunologia que estuda a relação entre sistema imune e o sistema nervoso. Muitos estudos têm demonstrado a capacidade direta de neurotransmissores em modular a resposta imune, assim como de citocinas em influenciar funções cognitivas. Neste contexto, o glutamato possui papel de destaque, por se tratar do neurotransmissor excitatório mais importante e mais abundante no sistema nervoso central dos mamíferos. Sua função é exercida através de dois tipos de receptores principais: i) os receptores ionotrópicos (iGluR) e ii) os receptores metabotrópicos (mGluR). A descoberta da expressão de receptores de glutamato em células do sistema imune tem despertado interesse científico, levantando questões acerca de sua expressão e função. No presente trabalho, avaliamos parâmetros como viabilidade celular, linfoproliferação e ativação de MAP quinase pelo receptor NMDAR esplenócitos totais e linfócitos cultivados in vitro. Nossos resultados demonstram que linfócitos em repouso e ativados apresentam diferentes perfis de expressão do receptor NMDAR. O uso do antagonista deste receptor, o MK801, foi capaz de reduzir a proliferação de linfócitos T CD4 e T CD8 estimulados com anti-CD3 em cultura de esplenócitos. Tal redução pode ser explicada por um aumento na taxa de morte celular, o que foi avaliado através de marcação com anexina-V, indicador de apoptose, ou 7-AAD, indicador de necrose. Para entendermos um pouco a respeito da sinalização do receptor NMDAR no sistema imune, avaliamos a fosforilação da MAP quinase ERK 1,2 em linfócitos T CD4 ativados na presença do agonista (NMDA) ou do antagonista (MK801) do receptor. Observamos um aumento na ativação desta quinase na presença de NMDA, o que é revertido na presença do MK801. Ao avaliar o papel do receptor NMDAR in vivo, verificamos uma redução significativa na gravidade da encefalomielite experimental auto-imune em animais tratados com MK801. Mais interessante, esta redução se correlaciona também com uma redução na fosforilação de ERK 1,2 em esplenócitos totais obtidos ao dia 7 pós-imunização. Em resumo, nossos dados sugerem que o receptor NMDA possui o papel de ativador de vias intracelulares importantes, como as da MAP quinase ERK 1,2; e que o seu bloqueio resulta em morte celular in vitro. Logo, isso indica a importância do glutamato como modulador da intensidade da resposta e viabilidade de linfócitos T CD4 e T CD8 in vitro e in vivo. Sendo assim, nossos resultados contribuem para um melhor entendimento dos fenômenos de imunoregulação, especialmente aqueles no campo da neuroimunologia ou neuroimunomodulação. / Neuroimmunology is a field within immunology which studies the relationship between the nervous system and the immune system. Several studies have demonstrated the direct ability of neurotransmitters in modulating the immune response, as for cytokines in influencing cognitive functions. In this context, glutamate stands out for being the most important and abundant neurotransmitter in the mammal central nervous system. Its role is exerted through two main types of receptor: i) ionotropic receptors (iGluR) and ii) metabotropic receptors (mGluR). The discovery of glutamate receptor expression in immune cells has led to scientific interest, raising issues concerning its expression and function. In the present study, we evaluated parameters such as cell viability, lymphoproliferation, and activation of the MAP quinase pathway by the NMDA receptor on total splenocytes and lymphocytes cultured in vitro. Our results demonstrate that naive and activated lymphocytes present different profiles of NMDA receptor expression. The use of MK801, an antagonist for this receptor, was able to reduce the T CD4 and T CD8 lymphocyte proliferation stimulated with anti-CD3 in splenocyte culture. Such reduction may be explained by the increase of the cellular death rate, evaluated by annexin-V staining, indicator of apoptosis or 7-AAD, indicator of necrosis. With the intent of understanding part of the NMDA receptor signaling in the immune system, we evaluated the ERK 1,2 MAP quinase phosphorylation in T CD4 lymphocytes activated in the presence of the agonist (NMDA) or the antagonist (MK801) of the receptor. We observed an increase in this quinase activation in the presence of NMDA, which is reversed by the MK801. When evaluating the role of the NMDA receptor in vivo, we verified a significant reduction in the degree of experimental auto-immune encephalomyelitis in animals treated with MK801. More interesting, this reduction also correlates to a reduction on the phosphorilation of ERK 1,2 in total splenocytes obtained at the seventh day post-immunization. In sum, our data suggest that the NMDA receptor has the role of activating important intracellular pathways, such as the MAP quinases ERK 1,2; and that its blockage results in cellular death in vitro. As so, this indicates the importance of glutamate as a modulator of the intensity of response and the viability of T CD4 e T CD8 lymphocytes in vitro e in vivo. Thus, our result contribute for a better understanding of the immunoregulation phenomena, especially those in the neuroimmunology ou neuroimmunomodulation field.

Glutamate

Glutamato

Ionotropic glutamate receptors

Linfócitos T

Lymphocytes T

Neuroimmunomodulation

Neuroimunomodulação

Neurotransmissores

Neurotransmitters

NMDAR

NMDAR

Receptores ionotrópicos de glutamato

Papel dos receptores de glutamato tipo NMDA em macrófagos, células dendríticas e células T CD4  ativadas in vitro. / The role of NMDA glutamate receptors in T lymphocytes activated in vitro.

Andira Michele da Cruz Fickinger

26 February 2014

A neuroimunologia é o ramo da imunologia que estuda a relação entre sistema imune e o sistema nervoso. Muitos estudos têm demonstrado a capacidade direta de neurotransmissores em modular a resposta imune, assim como de citocinas em influenciar funções cognitivas. Neste contexto, o glutamato possui papel de destaque, por se tratar do neurotransmissor excitatório mais importante e mais abundante no sistema nervoso central dos mamíferos. Sua função é exercida através de dois tipos de receptores principais: i) os receptores ionotrópicos (iGluR) e ii) os receptores metabotrópicos (mGluR). A descoberta da expressão de receptores de glutamato em células do sistema imune tem despertado interesse científico, levantando questões acerca de sua expressão e função. No presente trabalho, avaliamos parâmetros como viabilidade celular, linfoproliferação e ativação de MAP quinase pelo receptor NMDAR esplenócitos totais e linfócitos cultivados in vitro. Nossos resultados demonstram que linfócitos em repouso e ativados apresentam diferentes perfis de expressão do receptor NMDAR. O uso do antagonista deste receptor, o MK801, foi capaz de reduzir a proliferação de linfócitos T CD4 e T CD8 estimulados com anti-CD3 em cultura de esplenócitos. Tal redução pode ser explicada por um aumento na taxa de morte celular, o que foi avaliado através de marcação com anexina-V, indicador de apoptose, ou 7-AAD, indicador de necrose. Para entendermos um pouco a respeito da sinalização do receptor NMDAR no sistema imune, avaliamos a fosforilação da MAP quinase ERK 1,2 em linfócitos T CD4 ativados na presença do agonista (NMDA) ou do antagonista (MK801) do receptor. Observamos um aumento na ativação desta quinase na presença de NMDA, o que é revertido na presença do MK801. Ao avaliar o papel do receptor NMDAR in vivo, verificamos uma redução significativa na gravidade da encefalomielite experimental auto-imune em animais tratados com MK801. Mais interessante, esta redução se correlaciona também com uma redução na fosforilação de ERK 1,2 em esplenócitos totais obtidos ao dia 7 pós-imunização. Em resumo, nossos dados sugerem que o receptor NMDA possui o papel de ativador de vias intracelulares importantes, como as da MAP quinase ERK 1,2; e que o seu bloqueio resulta em morte celular in vitro. Logo, isso indica a importância do glutamato como modulador da intensidade da resposta e viabilidade de linfócitos T CD4 e T CD8 in vitro e in vivo. Sendo assim, nossos resultados contribuem para um melhor entendimento dos fenômenos de imunoregulação, especialmente aqueles no campo da neuroimunologia ou neuroimunomodulação. / Neuroimmunology is a field within immunology which studies the relationship between the nervous system and the immune system. Several studies have demonstrated the direct ability of neurotransmitters in modulating the immune response, as for cytokines in influencing cognitive functions. In this context, glutamate stands out for being the most important and abundant neurotransmitter in the mammal central nervous system. Its role is exerted through two main types of receptor: i) ionotropic receptors (iGluR) and ii) metabotropic receptors (mGluR). The discovery of glutamate receptor expression in immune cells has led to scientific interest, raising issues concerning its expression and function. In the present study, we evaluated parameters such as cell viability, lymphoproliferation, and activation of the MAP quinase pathway by the NMDA receptor on total splenocytes and lymphocytes cultured in vitro. Our results demonstrate that naive and activated lymphocytes present different profiles of NMDA receptor expression. The use of MK801, an antagonist for this receptor, was able to reduce the T CD4 and T CD8 lymphocyte proliferation stimulated with anti-CD3 in splenocyte culture. Such reduction may be explained by the increase of the cellular death rate, evaluated by annexin-V staining, indicator of apoptosis or 7-AAD, indicator of necrosis. With the intent of understanding part of the NMDA receptor signaling in the immune system, we evaluated the ERK 1,2 MAP quinase phosphorylation in T CD4 lymphocytes activated in the presence of the agonist (NMDA) or the antagonist (MK801) of the receptor. We observed an increase in this quinase activation in the presence of NMDA, which is reversed by the MK801. When evaluating the role of the NMDA receptor in vivo, we verified a significant reduction in the degree of experimental auto-immune encephalomyelitis in animals treated with MK801. More interesting, this reduction also correlates to a reduction on the phosphorilation of ERK 1,2 in total splenocytes obtained at the seventh day post-immunization. In sum, our data suggest that the NMDA receptor has the role of activating important intracellular pathways, such as the MAP quinases ERK 1,2; and that its blockage results in cellular death in vitro. As so, this indicates the importance of glutamate as a modulator of the intensity of response and the viability of T CD4 e T CD8 lymphocytes in vitro e in vivo. Thus, our result contribute for a better understanding of the immunoregulation phenomena, especially those in the neuroimmunology ou neuroimmunomodulation field.

Glutamato

Linfócitos T

Neuroimunomodulação

Neurotransmissores

NMDAR

Receptores ionotrópicos de glutamato

Glutamate

Ionotropic glutamate receptors

Lymphocytes T

Neuroimmunomodulation

Neurotransmitters

NMDAR

The role of ionotropic glutamate receptors in the dorsomedial hypothalamus in the increase in core body temperature evoked by interoceptive and exteroceptive stresses in rats

Moreno, Maria

03 March 2010

Indiana University-Purdue University Indianapolis (IUPUI) / Brain responds to an array of diverse challenges that are defined as either exteroceptive stress, involving cognitive processing of sensory information from the external environment and or interoceptive stress, detected through sensory neural or chemical cues from the internal environment. The physiological response to most stresses consists of autonomic responses that are essential for animal survival in the face of a threatening circumstance. However, it is known that exposition to continuous situations of stress is involved in the development of a series of diseases such as hypertension, myocardial infarction and panic syndrome. Several studies have shown that cells in a specific area of the brain, the dorsomedial hypothalamus (DMH), are involved in the response produced during emotional stress. However, the role of glutamatergic transmission in the DMH in the increase in body temperature induced by experimental stress has not been examined. Research findings thus far indicate that neurons in the DMH play a role in thermoregulation and that local glutamate receptors may be involved. The hypothesis of this thesis is that activity at ionotropic glutamate receptors in the DMH is necessary for the thermogenic response induced by experimental stress. In the present work, microinjections of kynurenate, an excitatory amino acid antagonist, NBQX (2, 3-dihydroxy-6-nitro-7-sulfamoyl-benzo[f]quinoxaline-2,3-dione), an AMPA/kainate receptor antagonist, DL-2-amino-5-phosphonovaleric acid (APV), an NMDA receptor antagonist, and a mixture of NBQX and APV, were delivered to the DMH before exposure to experimental stress. The stress paradigms used include models for exteroceptive stress and interoceptive stress. The results show that inhibition of both NMDA and non-NMDA receptors is necessary to abolish the thermogenic response produced by all stress paradigms tested. Furthermore, there appears to be a difference in the degree of attenuation of the thermogenic response produced by either inhibition of NMDA receptors or non-NMDA receptors. Together these results support a definite role for ionotropic glutamate receptors within DMH region in the thermogenic response to stress. These results also finally show that the DMH is involved in all the major physiological stress responses including increase in plasma ACTH, increase in heart rate, blood pressure and now temperature as well.

Stress (Physiology) -- Testing

Body temperature -- Regulation

Hypothalamus

Neural receptors

GluR5 IS INVOLVED IN REGULATION OF THE HPA AXIS

VAN HOOREN, DANIELLA CHRISTINE

02 July 2004

No description available.

Biology, Neuroscience

GluR5

Ionotropic Glutamate Receptors

Corticotropin Releasing Hormone (CRH)

Corticosterone

ACTH

HPA Axis