Ion currents regulated by acute and chronic osmotic stimuli in rat supraoptic nucleus neurons

Zhang, Wenbo

25 February 2009

The magnocellular neurosecretory cells (MNCs) of the hypothalamus are able to change their firing rate and pattern in response to small changes in external osmolality due to the involvement of osmosensitive ion channels. The firing rate and pattern determine the release of vasopressin (VP), a primary hormone regulating osmolality by controlling water excretion from the kidney. Both VP- and oxytocin (OT)-MNCs display irregular and infrequent fire when plasma osmolality is near normal, and they progressively increase the frequency of firing to fast continuous firing with increases in osmolality. VP-MNCs also respond to osmotic stimulation by adopting a phasic pattern of firing, which maximizes neuropeptide secretion. Sustained dehydration also causes structural and functional adaptations in MNCs.<p> Voltage-dependent Ca2+ channels play many important roles not only in the regulation of cell excitability but also in intracellular signal transduction, and L-type Ca2+ channel-mediated Ca2+ signals initiate intracellular signal transduction events that activate long-lasting changes in brain function and behavior. Our electrophysiological and immunocytochemical studies demonstrate that 16-24 h of water deprivation causes a significant increase in the amplitude of L-type Ca2+ current (from 55.5 ± 6.2 to 99.1 ± 10.0 pA) but not in other types of Ca2+ current. This increase occurred in both VP- and OT-MNCs. Such an increase in L-type Ca2+ current may contribute to modulation of firing rate and pattern, regulation of vasopressin release, structural adaptation in MNCs during sustained dehydration.<p> The mechanisms underlying the transition of the electrical behaviour are not completely understood. Ion channels, especially osmosensitive ion channels, play key roles in the modulation of MNC firing. A voltage-gated, 4-AP- and TEA-insensitive slowly activating outward current displayed a significant increase in about 66% of MNCs when the osmolality of the external solution was acutely increased from 295 to 325 mosmol kg-1. The responding cells showed an increase in net outward current from 12.3 ± 1.3 pA/pF to 21.4 ± 1.8 pA/pF. The reversal potential of this current was near the equilibrium for K+ and shifted with changes of K+ concentrations in external solution, suggesting that this current is a K+-selective current. The KCNQ/M current selective blockers linopirdine (150 µM) and XE991 (5 µM) suppressed this current. The IC50 of XE991 blockade was 3.9 ìM. The KCNQ/M channel openers retigabine (10 µM) and flupirtine (10 µM) significantly increased the current and shifted its activation curve toward more negative potentials. E4031, a specific blocker of ERG K+ channels, did not significantly block this current. The results from immunocytochemistry suggest that MNCs express KCNQ2, KCNQ3, KCNQ4, and KCNQ5, but not KCNQ1. These data suggest that this osmosensitive current could be a KCNQ/M current. Studies using single unit extracellular recording in hypothalamic explants showed that 10 µM XE991 increased MNC firing rate and that 20 µM retigabine decreased firing rate or caused a cessation of firing. These data suggest that a KCNQ/M current contributes to the regulation of MNC firing. KCNQ/M channels play key roles in regulating neuronal excitability in many types of central neurons. Slow activation of this current during firing might suppress activity by hyperpolarizing the cells and thus contribute to a transition between fast continuous and burst firing.<p> Our studies will be beneficial to understand the mechanisms that control VP and OT in response to acute changes in osmolality and also the mechanisms underlying MNC adaptation during sustained dehydration.

Osmosensitivity

Vasopressin

Supraoptic nucleus

L-type Ca2+ channel

KCNQ/M channel

Comparison of Pyramidal and Magnocellular Neuroendocrine Cell Volume Responses to Osmotic Stress and Stroke - Like Stress

Ranepura, Nipuni

14 February 2011

Acute brain cell swelling (cytotoxic edema) can occur in the first minutes of stroke, presumably as a result of brain cells taking up water. In extreme hypo-osmotic situations such as excessive water-loading by patients, uptake by brain cells can expand the brain, causing seizures. But is ischemic brain cell swelling the same as hypo-osmotic swelling? Water can passively diffuse across the plasma membrane. However the presence of water channels termed aquaporins (AQP) facilitates passive water diffusion by 10-100 times. Unlike astrocytes, there is no evidence of water channels on neuronal plasma membrane. However, there is still much debate about which cells (neurons or astrocytes) swell during over-hydration or during stroke and if neurons and astrocytes can volume-regulate during osmotic stress. The purpose of this study was to examine and compare the volume responses of PyNs and magnocellular neuroendocrine cells (MNCs) to acute osmotic challenge and to OGD. We examined MNCs because they are intrinsically osmosensitive to small changes (2-3 mOsm) of plasma osmolality. We also examined if the same neurons behave similarly in brain slices or when dissociated and if they respond differently to acute osmotic stress and stroke-like stress. Our results indicate that during acute osmotic stress (±40 mOsm) half of dissociated PyNs and MNCs tended to show appropriate responses. MNCs in brain slices showed similar responses to when they were dissociated, while brain slice PyNs were less responsive than when dissociated. Exposure to OGD resulted in obvious differences between the two types of in vitro preparations. Dissociated PyNs and MNCs showed no consistency in their volume responses to 10 minutes of OGD. Dissociated neurons swelled, shrunk or were unchanged in about equal numbers. In contrast, brain slice PyNs underwent profound swelling whereas, brain slice MNCs showed minor volume decreases. We conclude that about half of our dissociated neurons were too variable and unpredictable in their osmotic volume responses to be useful for osmotic studies. They also were too resistant to stroke-like stress to be good models for ischemia. Brain slice neurons were similar in their osmotic responses to dissociated neurons but proved to have consistent and predictable responses to stroke-like stress. / Thesis (Master, Neuroscience Studies) -- Queen's University, 2011-02-07 17:55:08.333

Pyramidal Neurons

Magnocellular Neuroendocrine Cell

Osmotic Stress

Oxygen Glucose Deprivation

Paraventricular Nucleus

Supraoptic Nucleus

Modulatory role of the suprachiasmatic nucleus on the OVLT-SON pathway

Trudel, Eric, 1978-

January 2009

When an organism is dehydrated, neurons in the Organum vasculosum lamina terminalis (OVL T) sense this variation in plasma osmolality (OSM) and excite magnocellular neurosecretory cells (MNCs) in the supraoptic nucleus (SON) via glutamatergic synapses. The resulting action potential firing of MNCs will result in the secretion of vasopressin (VP) into the blood, which will promote water reabsorption from the kidney. The relationship between plasma VP and OSM (know as the VP-OSM ratio) is known to change in sensitivity during the course of a day. / Lorsqu'un organisme est déshydraté, les neurones dans l'Organum vasculosum lamina terminalis (OVL T) détectent le changement dans l'osmolalité du plasma (OSM) et excitent les cellules magnocellulaires neurosécrétoires (MNCs) dans le noyau supraoptique (SON) avec des synapses glutamatergique. La décharge des potentiels d'action qui survient dans les MNCs génère la sécrétion de vasopressine (VP) dans le sang, qui permettra la réabsorption d'eau au niveau du rein. Le rapport entre la VP et OSM (connu comme étant le rapport VP/OSM) subit des changements de sensibilité durant une journée.

Suprachiasmatic Nucleus -- metabolism.

Hypothalamus -- metabolism.

Supraoptic Nucleus -- metabolism.

Rats.

Rats, Long-Evans.

Arginine Vassopressin--metabolism.

Avaliação do comprometimento hipotalâmico na secreção de vasopressina durante a sepse / Evaluation of hypothalamic impairment in vasopressin secretion during sepsis

Luís Henrique Angenendt da Costa

18 December 2015

Sepse e suas complicações (sepse grave e choque séptico) ainda são a principal causa de morte nas unidades de terapia intensiva em todo o mundo. Estudos clínicos e experimentais têm demonstrado que na fase inicial da sepse a concentração plasmática de arginina vasopressina (AVP) está elevada. No entanto, durante o processo fisiopatológico os níveis plasmáticos da mesma permanecem inadequadamente baixos, apesar de haver hipotensão persistente. Uma das hipóteses sugeridas para essa deficiência relativa de AVP é a apoptose de neurônios vasopressinérgicos. Nosso objetivo foi identificar elementos envolvidos na morte celular hipotalâmica, além de avaliar o comportamento de células gliais e da barreira hematoencefálica (BHE) durante a sepse. Ratos Wistar foram submetidos à sepse por ligadura e punção cecal (CLP) ou não manipulados (naive) como controle e então divididos em dois grupos. No primeiro, foram perfundidos e os cérebros coletados para imunohistoquímica. Outro grupo foi decapitado para a retirada de sangue para dosagem de interferon- gama (IFN-?) e encéfalo para análise da expressão de proteínas no hipotálamo ou nos núcleos supraópticos (SON) e paraventriculares (PVN). Um terceiro foi separado para investigação da permeabilidade da BHE. Apesar de aumento da imunomarcação de CD8 e MHC-I no SON dos animais sépticos, não encontramos indícios de morte celular mediada por células imunes. No SON e PVN de animais sépticos, a expressão de fatores envolvidos na ativação da via extrínseca de apoptose (tBID, caspase-8 clivada) se manteve inalterada, enquanto fatores anti-apoptóticos relacionados à via intrínseca (BCL-2, BCL-xL) estavam diminuídos no hipotálamo. No SON destes animais a micróglia assumiu uma morfologia associada à sua ativação, concomitante com o aumento plasmático de IFN-?. Houve rompimento transitório da BHE no hipotálamo após 6 horas do CLP. Os resultados indicam que a via intrínseca de apoptose parece ser a responsável pela morte celular que é observada nos núcleos vasopressinérgicos e essa condição está temporalmente associada à ativação microglial e rompimento da BHE / Sepsis and its complications (severe sepsis and septic shock) remain as the main cause of death in intensive care units worldwide. Clinical and experimental studies have shown that in the early phase of sepsis the plasma concentration of arginine vasopressin (AVP) is increased. However, during the pathophysiological process the plasma levels remain inadequately low, despite of persistent hypotension. One of the hypothesis suggested for this relative deficiency is the apoptosis of vasopressinergic neurons. Our objective was to identify elements involved in the hypothalamic cellular death and evaluate the modifications of glial cells and blood-brain-barrier (BBB) during sepsis. Wistar rats were submitted to sepsis by cecal ligation and puncture (CLP) or non-manipulated (naïve), as control and then divided in two groups. In the first one, they were perfused and brains were collected for immunohistochemistry. In another one they were decapitated for blood collection and further plasma interferongama (IFN-?) analysis by ELISA. Brain was also collected for apoptosis-related proteins expression analysis in the hypothalamus or in the supraoptic (SON) and paraventricular (PVN) nuclei. A third set was separated for the investigation of BBB permeability. Despite of increased immunostaining for CD8 and MHC-I in the SON of septic animals, we did not find evidence of cell death mediated by immune cells. In the SON and PVN of septic animals, the expression of proteins involved in the activation of the extrinsic apoptosis pathway (tBID, cleaved caspase-8) was not altered, whereas anti-apoptotic factors related to the intrinsic pathway (BCL-2, BCLxL) were decreased. In the SON of these animals, microglia assumed a morphology related to its activation, associated with the increase of plasma IFN-?. There was a transitory breakdown of BBB in hypothalamus after 6 hours following CLP. The results indicate that the intrinsic apoptosis pathway seems to be responsible for the cell death observed in vasopressinergic nuclei and this condition is temporally associated with microglial activation and BBB leaking

Apoptose

Barreira hematoencefálica

Micróglia

Núcleo supraóptico

Apoptosis

Blood-brain barrier

Microglia

Supraoptic nucleus

Neuropeptide W-Immunoreactivity in the Hypothalamus and Pituitary of the Rat

Dun, Siok L., Brailoiu, G. Cristina, Yang, Jun, Chang, Jaw Kang, Dun, Nae J.

02 October 2003

Neuropeptide W-23 (NPW23) and neuropeptide W-30 (NPW30) are 23- and 30-amino acid peptides recently isolated from the porcine hypothalamus. Immunohistochemical studies using a rabbit polyclonal antiserum against the rat NPW23 peptide revealed a limited distribution in the rat brain. NPW23-immunoreactive (irNPW) cells were detected in the paraventricular nucleus (PVH), mainly in the parvocellular division, supraoptic nucleus (SO), accessory neurosecretory nuclei, dorsal and lateral hypothalamic areas, perifornical nucleus, arcuate nucleus, and anterior and posterior pituitary; whereas, irNPW fibers were noted in the PVH and SO, retrochiasmatic nucleus, dorsal and lateral hypothalamic areas, median eminence, amygdala, and posterior pituitary. The pattern of distribution of irNPW in the hypothalamus corroborates a possible role of NPW on prolactin release and feeding behavior reported by others.

accessory neurosecretory nucleus

anterior pituitary

arcuate nucleus

median eminence

paraventricular nucleus

posterior pituitary

supraoptic nucleus

Beacon Immunoreactivity in the Rat Hypothalamus

Ng, Y., Brailoiu, G. C., Dun, S. L., Ling, E. A., Yang, J., Chang, J. K., Dun, N. J.

01 May 2006

Beacon (BC) is a peptide of 73 amino acids, whose gene expression was first reported in the hypothalamus of Psammomys obesus (or Israeli sand rat). To appreciate better the functional role of BC in normal rats and sand rats, the distribution of BC immunoreactivity (irBC) and its subcellular localization were studied in the brain of Sprague-Dawley rats. In the hypothalamus, intense staining was present in neurons of the supraoptic (SO), paraventricular (PVH), and accessory neurosecretory nuclei and in cell processes of median eminence. Double labeling of the hypothalamic sections with mouse monoclonal oxytocin (OT) antibody and rabbit polyclonal BC antiserum revealed that nearly all OT-immunoreactive cells from SO, PVH, and accessory neurosecretory nuclei were irBC. Double labeling of the sections with guinea pig vasopressin (VP) antiserum and BC antiserum showed that a population of VP-immunoreactive neurons was irBC. By immunoelectron microscopy, immunoreactive product was associated with mitochondrial membranes or appeared as electron-dense bodies in many PVH and SO neurons. Most of the neurosecretory granules were unstained for BC. Taken together, our results indicate the presence of beacon in the OT-containing neurons and a population of VP-containing neurons, mostly associated with mithocondrial membrane. Insofar as the amino acids sequence of beacon is identical to that of ubiquitin-like 5, it is possible that the distribution of BC immunoreactivity noted in our study is that of ubiquitin-like 5 peptide in the rat hypothalamus.

beacon

oxytocin

paraventricular nucleus

supraoptic nucleus

ubiquitin-like 5 peptide

vasopressin

Beacon-Like Immunoreactivity in the Hypothalamus of Sprague-Dawley Rats

Brailoiu, G. Cristina, Dun, Siok L., Yang, Jun, Chang, Jaw Kang, Castellino, Sonya, Dun, Nae J.

14 January 2002

Distribution of the novel peptide beacon in the hypothalamus of Sprague-Dawley rats was examined by immunohistochemical methods. Beacon-immunoreactive (irBC) neurons were found in the paraventricular, supraoptic, and accessory neurosecretory nuclei, and intensely labeled fibers in the median eminence and infundibulo-pituitary stalk. Scattered cells and/or fibers were noted in the suprachiasmatic nucleus, arcuate nucleus, retrochiasmatic area, lateral and medial preoptic area, as well as anterior and lateral hypothalamic area. The wide distribution of irBC in the hypothalamus of Sprague-Dawley rats suggests that the peptide may influence, in addition to a proposed role in feeding, a multitude of biological activities associated with the hypothalamic-pituitary axis.

feeding behavior

median eminence

paraventricular nucleus

psammomys obesus

sand rat

supraoptic nucleus

Role of the hypothalamus in sociality : possible contribution to autism spectrum disorders / Rôle de l'hypotalamus dans la sociabilité : une contribution possible à la compréhension des troubles du spectre autistique

Wolfe, Farah

12 December 2016

La sociabilité de l’homme est un phénomène complexe. Les théories dominantes essayant d'expliquer les mécanismes neurobiologiques de cette sociabilité ont largement impliqué l'ocytocine (OXT), un neuropeptide qui facilite de nombreuses fonctions et comportements sociaux. L'hypothalamus, parmi ses nombreuses fonctions, synthétise et sécrète l’OXT via son noyau supraoptique (SON) et le noyau paraventriculaire (PVN), faisant de lui un candidat intéressant pour comprendre les bases neurales de cette sociabilité. Dans cette thèse, qui combine trois études en imagerie par résonance magnétique (IRM), nous avons examiné 1) les différences anatomiques au sein de l'hypothalamus entre des participants contrôles et des patients autistes; 2) l’activité de l'hypothalamus, et plus spécifiquement des sous-régions hypothalamiques incluant le SON et le PVN, en réponse à des visages portant différents niveaux de sociabilité; 3) les connections fonctionnelles que ces sous-régions hypothalamiques entretiennent avec d'autres réseaux cérébraux. Nos résultats révèlent une spécificité, tant dans leur activité fonctionnelle que dans leurs connections anatomiques, des deux sous-régions hypothalamiques (SON et PVN) en fonction du niveaux de sociabilité. Ce travail de thèse fournit donc non seulement de nouvelles méthodes pour explorer les petites sous-régions hypothalamiques mais confirme également le rôle de l’hypothalamus dans la sociabilité et ses anomalies, apportant ainsi un nouvel éclairage sur l’origine des dysfonctionnements sociaux dans l’autisme et d'autres pathologies. / Human sociality is a complex phenomenon. Prevailing theories attempting to explain the neurobiological mechanisms of human sociality have implicated neuropeptide oxytocin (OXT), which facilitates numerous social functions and behaviors. The hypothalamus, among its many functions, also synthesizes and secretes OXT via its supraoptic nucleus (SON) and the paraventricular nucleus (PVN), making them viable candidates to understand the underpinnings of various social processes. This thesis combines three magnetic resonance imaging (MRI) studies investigating 1) anatomical difference of the hypothalamus between neurotypics and patients with Autism Spectrum Disorders (ASD); 2) functional MRI of the hypothalamus, specifically in hypothalamic subregions containing SON and PVN in response to faces of individuals with varying social significance; 3) functional connectivity of these hypothalamic subregions to other brain networks. Results revealed differential activity of hypothalamic subregions in response to various faces and distinctive patterns of connectivity to other brain areas that are involved in social cognition, as well as anatomical abnormalities of the hypothalamus in ASD. Altogether, the work in this thesis provides novel methods of measuring small hypothalamic subregions and supporting evidence of hypothalamic involvement in social functions that may also shed some light on social dysfunctions in ASD and other pathologies.

Hypothalamus

Autisme

Interaction sociale

Irm

Noyau supraoptique

Noyau paraventriculaire

Oxytocine

Hypothalamus

Autism

Social interaction

Mri

Supraoptic nucleus

Paraventricular nucleus

Oxytocin

Expressão do fator de transcrição nuclear kB (NF-kB) em neurônios ocitocinérgicos de ratos submetidos à sobrecarga salina : influência da dexametasona / Expression of nuclear transcription factor kB (NF-kB) in rat ocxytocinergic neurons submitted to salt loading : the influence of dexamethasone

Santos, Patricia Rabelo dos

27 January 2014

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / The hypothalamic-neurohypophysial system is the main system through which the brain maintains homeostasis of bodily fluids. Specifically, the supraoptic (SON) and paraventricular (PVN) hypothalamic nuclei are directly involved with hydroelectrolytic equilibrium and are specialized in the synthesis and secretion of vasopressin and oxytocin (OT). Changes in the milieu intérieur are conceived as stressors by the central nervous system (CNS) and are modulated by the hypothalamic-pituitary-adrenal axis (HPA). Nuclear transcription factor kappa B (NF-κB) mediates immunosuppressant and anti-inflammatory of glucocorticoids. Thus, the aim of this study was to verify the expression profile of component p65 of the NF-κB classical pathway in SON and PVN oxytocinergic neurons in response to dehydration, glucocorticoid treatment, and in normal conditions. Methods: Wistar rats (250-300g) were maintained in controlled environment with temperature (23 ± 2ºC), light/dark cycle of 12 hours and water and food specific for rodents ad labitum until the beginning of experimental period. All procedures were approved by Ethical Comitee of Research with Animals from UFS (Protocol # 60/2012). Animals were grouped into Control (water ad libitum for 4 days, n = 6-7); Control + Dexa (water ad libitum and treated with dexamethasone, n = 6-7); SL4 (salt overloading ad libitum, 1.8% NaCl for 4 days, n = 6-7); SL4 + Dexa (salt overloading ad libitum, 1.8% NaCl for 4 days and dexamethasone, n = 6-7). Dexamethasone (10 mg/kg i.p.) was administered 12 and 2 hours before perfusion and removal of brains for OT/p65 immunofluorescence, or before sacrifice for blood sampling and angiotensin II (ANGII) dosage. We applied two-way ANOVA and Bonferroni posthoc test to analyze behavioral and hormonal dosage data. Results obtained from imunohistochemestry for evaluation of oxytocin and/or p65 neuronal activity, were subjected to qualitative evaluation. We verified SL4 animals ingested more fluid than control, on second (p<0.01), third (p<0.01) and forth (p<0.001) experimental day. SL4 also increased plasmatic concentration of ANGII (p<0.01). Qualitative analysis of double labeling OT/p65 on PVN and SON revealed a weak immunoreactivity for oxytocin on SL4 and SL4 + Dexa groups, when compared to control and Control + Dexa groups. Was observed expression of p65 subunit of NF-κB in all hypothalamic studied areas, with predominant cytoplasmic imunoreactivity in all groups. These data demonstrate that p65 subunit of NF-κB are present in oxytocinergic neurons from the most important hypothalamic areas that integrates the stress axis (HPA) and hidroelectrolyte balance (SHNH). More studies are necessary to clarify the real participation of NF-κB intracellular pathway evoked by intracellular dehydration on endocrines and behavioral hidroelectrolyte adjustments. / O sistema hipotálamo neuro-hipofisário (SHNH) é o principal sistema pelo qual o cérebro mantém a homeostase dos líquidos corporais. Especificamente, os núcleos supra-óptico (SON) e paraventricular (PVN) do hipotálamo estão diretamente envolvidos com o controle do balanço hidroeletrolítico e são especializados na síntese e secreção de vasopressina (AVP) e ocitocina (OT). Alterações no milieu intérieur são vistas como estressoras pelo sistema nervoso central (SNC) e moduladas pelo eixo hipotálamo-hipófise-adrenal (HHA). O fator de transcrição nuclear kappa B (NF-κB) é conhecido por mediar os efeitos imunossupressores e anti-inflamatórios dos glicocorticoides. Sendo assim, o objetivo do presente estudo foi verificar o perfil de expressão do componente p65 da via clássica do NF-κB em neurônios ocitocinérgicos do PVN e SON, em resposta à desidratação crônica, associada, ou não, ao tratamento com glicocorticoides. Métodos: Ratos wistar (250-300 g) foram mantidos em ambiente com temperatura (23 ± 2ºC) e luminosidade, ciclo claro-escuro de 12 horas (luz das 6 às 18 horas), controladas, com água e ração específica para roedores (Labina®- Purina) ad libitum até o início dos experimentos. Todos os procedimentos foram aprovados pelo Comitê de Ética em Pesquisa com Animais da UFS (Protocolo # 60/2012). Os animais foram divididos de modo a constituir os grupos Controle (ratos com acesso à água ad libitum, durante quatro dias, n = 6 - 7); Controle + Dexa (ratos com acesso à água ad libitum, durante quatro dias, e tratados com dexametasona, n = 6 - 7); SL4 (ratos com acesso à sobrecarga salina ad libitum, solução de NaCl 1,8%, durante quatro dias, n = 6 - 7); SL4 + Dexa (ratos com acesso à sobrecarga salina ad libitum, NaCl 1,8%, durante quatro dias e tratados com dexametasona, n = 6 - 7). A dexametasona (10 mg / kg, i.p.) foi administrada apenas no 4º dia, 12h e 2 h antes da perfusão para coleta do cérebro e realização da dupla imunofluorescência OT/p65 ou eutanásia para coleta de sangue do tronco e posterior dosagem de angiotensina II (ANGII). Os dados comportamentais e de dosagem hormonal obtidos foram submetidos ao teste ANOVA de duas vias e pós-teste Bonferroni. Os resultados obtidos da imuno-histoquímica, para a marcação de neurônios expressando ocitocina e/ou p65, foram submetidos à avaliação qualitativa. Verificou-se que os animais SL4 ingeriram mais fluido que seus controles, no segundo (p < 0,01), terceiro (p < 0,001) e quarto (p < 0,001) dia experimental. A SL4 elevou a concentração plasmática de ANGII (p < 0,01). A análise qualitativa da dupla imunofluorescência OT/p65 no PVN e SON revelou uma fraca imunorreatividade à ocitocina nos grupos SL4 e SL4 + Dexa, quando comparados aos grupos Controle e Controle + Dexa. Observou-se expressão da subunidade p65 do NF-κB em todas áreas hipotalâmicas estudadas, com imunorreatividade predominantemente citoplasmática em todos os grupos. Estes dados mostram que a subunidade p65 do NF-κB está presente em neurônios ocitocinérgicos das principais áreas hipotalâmicas que integram os eixos do estresse (HHA) e do equilíbrio hidroeletrolítico (SHNH). Mais estudos são necessários a fim de esclarecer sobre a real participação da via intracelular do NF-κB evocada pela desidratação intracelular, nos ajustes hidroeletrolíticos endócrinos e comportamentais.

Fisiologia

Ocitocina

Dexametasona

Equilíbrio hidro-eletrolítico

P65/RelA

Sobrecarga salina

Núcleo supra-óptico

Núcleo paraventricular

Paraventricular nucleus

Oxytocin

Dexamethasone

Salt loading

Supraoptic nucleus

CIENCIAS BIOLOGICAS::FISIOLOGIA

Vápníková signalizace magnocelulárních neuronů supraoptického jádra potkanů. / Ca2+ signalling in magnocellular neurones of the rat supraoptic nucleus.

Kortus, Štěpán

January 2019

The magnocellular neurosecretory cells (MNCs) of the hypothalamus project axons from the supraoptic nucleus to the posterior pituitary gland, where they secrete either oxytocin or vasopressin into the circulation. Oxytocin is important for delivery at birth and is essential for milk ejection during suckling. Vasopressin primarily promotes water reabsorption in the kidney to maintain body fluid balance. The profile of oxytocin and vasopressin secretion is principally determined by the pattern of action potentials initiated at the cell bodies in the hypothalamus. MNCs principally secrete hormones from terminals in the pituitary, but the secretion also occurs from their dendrites in the supraoptic nucleus, where they diffuse and affect the neighbouring cells. Mechanisms controlling the oxytocin and vasopressin secretion from MNCs have been extensively studied over the last decades and it is assumed that the relationship between Ca2+ signalling, secretion from dendrites, and the firing patterns is essential in understanding the magnocellular neurosecretory system. In this project, we combine mathematical analysis and experimental measurements of Ca2+ activity of MNCs of transgenic rats expressing an arginine vasopressin-enhanced green fluorescent protein (AVP-eGFP) or oxytocin-monomeric red fluorescent...