Spelling suggestions: "subject:"corticotropinreleasing hormone (CRH)"" "subject:"gonadotropinreleasing hormone (CRH)""
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Régulations des systèmes nerveux central et immunitaire en condition de stress : rôle de la corticotropin-releasing hormone et de ses récepteurs / Central nervous system and immune system regulation in stress condition : role of corticoprin-releasing hormone ans its receptorsHarlé, Guillaume 21 September 2016 (has links)
Lors d’un stress, l’activation de l’axe hypothalamo-hypophyso-surrénalien (HHS) conduit à une augmentation de la production de glucocorticoïdes (tel que la corticostérone) par les glandes surrénales. Le rôle de la corticotropin-releasing hormone (CRH), à l’origine de l’activation de l’axe HHS, est encore méconnu. En effet, les récepteurs à la CRH sont présents aussi bien au niveau du système nerveux central (SNC), notamment au niveau du cervelet, qu’au niveau du système immunitaire (SI). Cela suggère donc une action directe possible de cette hormone sur ces deux systèmes. Au cours de ce projet, nous avons étudié les régulations des SNC et SI lors d’un stress, et plus particulièrement le rôle de la CRH et de ses récepteurs dans ces régulations. Suite à des injections chroniques de corticostérone, mimant un stress, nous avons observé une altération des fonctions locomotrices qui semble être reversée lorsque le CRH-R1 est inhibé avec un antagoniste. Ces premiers résultats permettent de mettre en avant un éventuel rôle de la CRH dans la régulation des fonctions motrices au niveau du cervelet en conditions de stress. En parallèle, d’autres études in vitro réalisées sur des splénocytes murins stimulés avec de la CRH ont montré une diminution de la viabilité des lymphocytes B (LB). Suite à ces résultats, nous avons caractérisé pour la première fois la présence de récepteurs à la CRH sur cette population de LB murins. Ces résultats montrent l’importance de la CRH dans les régulations des SNC et SI en condition de stress et le rôle de cette hormone dans les interactions entre les deux systèmes / In stress conditions, the Hypothalamo-Pituitary-Adrenal (HPA) axis activation leads to an overproduction of glucocorticoïds (such as corticosterone in rodent) by adrenal glands and this activation is well characterized. However, various questions remain about the precise role of corticotropin-releasing hormone (CRH), which is at the beginning of the HPA activation. Indeed, CRH receptors are presents both in central nervous system (CNS), especially in cerebellum, and in immune system (IS). This suggest a possible direct action of this hormone on both system. In this project, we studied the regulations on CNS and IS in stress conditions and more particularly the CRH role and these receptors in these regulations. After chronic corticsterone injections, to mimic a stress, we observed a locomotor alteration which seems to be inverted when CRH-R1 were inhibited with an antagonist. These first results show an possible CRH role in locomotor regulation in cerebellum under stress condition. In parallel, others in vitro studies performed on murine splenocytes stimulated with CRH showed a B lymphocyte (LB) viability decrease. Furthermore, we are the first to characterise the CRH receptors on murine LB. This work show the CRH importance in CNS and IS regulations under stress conditions and its role in interactions between the two systems
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Stress state-dependent noradrenergic modulation of corticotropin-releasing hormone neuron excitability in the hypothalamic paraventricular nucleusJanuary 2014 (has links)
The stress response is an evolutionarily conserved mechanism critical for survival that requires orchestration of different systems in the body. Corticotropin-releasing hormone (CRH) neurons of the hypothalamic paraventricular nucleus (PVN) represent the final common pathway leading to HPA axis activation in response to stress. Noradrenergic inputs to CRH neurons in the PVN provide a powerful drive to activate the HPA axis. Previous anatomical studies have shown that noradrenergic afferents synapse directly on CRH neurons, but electrophysiological analyses indicate that the noradrenergic activation of CRH neurons is mediated primarily by the stimulation of presynaptic glutamatergic neurons. Here, using whole cell patch clamp recordings in identified CRH neurons, I demonstrate that norepinephrine (NE) stimulates excitatory synaptic inputs by activating postsynaptic α1 adrenergic receptors in CRH neurons and inducing the release of the retrograde messenger nitric oxide, which drives upstream glutamate neurons to elicit spike-dependent synaptic glutamate release onto the CRH neurons. Notably, the NE effect is dependent on ATP transmission and astrocytic function, suggesting that astrocytes serve as an intermediary in the retrograde activation of glutamateregic synaptic inputs to the CRH neurons. In addition, I also show that the NE-induced excitation of CRH neurons is stress-status sensitive and corticosterone dependent, in that stress-induced corticosterone causes internalization of membrane α1 adrenergic receptors to desensitize the CRH neurons to NE. Taken together, my findings provide evidence that NE excites CRH neurons in a stress state-dependent manner by a retrograde NO stimulation of local glutamate circuits that is dependent on glial activation. This retrograde trans-neuronal-glial regulation of excitatory synaptic inputs to CRH neurons by NE provides a mechanism for the NE activation of the HPA axis in the early stage of stress response. The stress-/corticosterone-induced desensitization of CRH neurons to NE modulation by the internalization of α1 adrenergic receptors confers a stress state-dependent resistance of the CRH neurons to repeated noradrenergic activation, which provides a mechanism for the negative feedback regulation of the CRH neurons and the HPA axis by stress and glucocorticoids, and a means to restore neuroendocrine homeostasis after stress exposure. / acase@tulane.edu
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Roles of Arginine-Vasotocin and Corticotropin-Releasing Hormone in Stress Responses and Agonistic Behaviour of Rainbow TroutBackström, Tobias January 2008 (has links)
The neuropeptides arginine-vasotocin (AVT) and corticotropin-releasing hormone (CRH) are involved in the hypothalamic-pituitary-interrenal (HPI) axis. During stress, the HPI axis is activated and cortisol is released into the blood. In addition to their role in the HPI axis, AVT and CRH also have behavioural effects. The roles of AVT and CRH in stress responses and agonistic behaviour were studied in this thesis, using two different models. In the first model, two strains of rainbow trout (Onchorhynchus mykiss) divergent in stress-induced release of cortisol were investigated. This was done by observing behaviour and stress responses under different conditions. These strains were found to have divergent stress coping strategies based on the observed behaviour and levels of plasma cortisol. This divergence in behaviour could be associated with the CRH system, since the mRNA levels of CRH differed between the strains during stress. However, no differences between strains were observed in AVT or its receptor expressions. In the second model, non-selected rainbow trout were paired and the effect of intracerebroventricular (icv) injections of an active substance (AVT, CRH or the CRH related peptide Urotensin-I (UI)) on fights for dominance was investigated. One fish of the pair received the active substance icv and the other received saline icv. Fish receiving AVT became subordinate in accordance with the suggestion that AVT attenuates aggression in territorial vertebrates. Fish receiving CRH became subordinate whereas UI showed no effect on fights for dominance. Further, both CRH and UI induced an anxiety-related behaviour similar to non-ambulatory motor activity in rats. In addition, CRH appeared to affect the dopaminergic and serotonergic systems. In this thesis, it is suggested that CRH is involved in the behavioural modulation of the stress coping strategies in teleost fish. Further, AVT and CRH seem to act inhibitory on aggressive behaviour.
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Ο ρόλος της λεπτίνης και της CRH στην παιδική ιδιοπαθή θρομβοπενική πορφύρα / The role of leptin and CRH in childhood idiopathic thrombopenic purpuraΔημονίτσα, Αλεξάνδρα 07 October 2011 (has links)
H ιδιοπαθής θρομβοπενική πορφύρα είναι ένα αυτοάνοσο νόσημα που χαρακτηρίζεται από χαμηλό αριθμό αιμοπεταλίων και αιμορραγίες. Επιπλέον αυτή η ασθένεια κατηγοριοποιείται σε οξεία (όταν διαρκεί λιγότερο από έξι μήνες) και χρόνια μορφή.
Η λεπτίνη είναι μια ορμόνη/κυτταροκίνη που παράγεται από τα αδιποκύτταρα και ρυθμίζει την όρεξη και τον μεταβολισμό. Ως κυτταροκίνη η λεπτίνη προάγει την Th1 απόκριση και παίζει πολύ σημαντικό ρόλο στα αυτοάνοσα νοσήματα όπως έχει παρατηρηθεί σε πολλά μοντέλα ζώων. Στην εργασία αυτή μελετήσαμε τον ρόλο της λεπτίνης στην παιδική ιδιοπαθή θρομβοπενική πορφύρα (ΙΘΠ). Από τα πειράματά μας διαπιστώσαμε ότι τα επίπεδα της λεπτίνης συσχετίζονται αρνητικά με τον αριθμό των αιμοπεταλίων των ασθενών. Επιπλέον αποδείξαμε ότι στην ασθένεια που μελετήσαμε η λεπτίνη έχει αντί-φλεγμονώδη ρόλο αφού επάγει την έκφραση της IL-10 από το μονοκύτταρα
Το μόριο της εκλυτικής ορμόνης της κορτικοτροπίνης (CRH) εκφράζεται κυρίως στον υποθάλαμο και ενεργοποιεί μέσω του άξονα υποθάλαμος-υπόφυση-επινεφρίδια τα γλυκοκορτικοειδή τα οποία έχουν ανοσοκατασταλτική δράση. Η CRH που εντοπίζεται στην περιφέρεια έχει αντιθέτως προ-φλεγμονώδη δράση. Εμείς μετρήσαμε τα επίπεδα της CRH στο πλάσμα υγιώς και ασθενών δοτών και παρατηρήσαμε ότι στους υγιείς δότες η CRH έχει την ικανότητα να ρυθμίζει αρνητικά την έκφραση της λεπτίνης. Ο έλεγχος όμως αυτός χάνεται στους ασθενείς με αποτέλεσμα τα επίπεδα τα λεπτίνης αυξάνονται στον ορό τους / Ιdiopathic thrombocytopenic purpura is an autoimmune disease characterized by a low platelet count and bleeding. Moreover this disorder is classified as acute (of six month or less duration) or chronic.
Leptin is an adipocyte-derived hormone/cytokine that regulates food intake and basal metabolism. As a cytokine leptin promotes T helper 1 (TH1)-cell differentiation and can modulate the onset and progression of autoimmune responses in several animal models of disease. Here, we review the role of leptin in childhood idiopathic thrombopenic purpura (ITP). We found that leptin levels negatively correlated with platelet numbersand also that it plays an active anti-inflammatory role by promoting IL-10 secretion by monocytes.
Corticotropin-Releasing Hormone (CRH) CRH, the hypothalamic component of the hypothalamic-pituitary,adrenal axis, attenuates inflammation through stimulation of glucocorticoid release, whereas peripherally expressed CRH acts as a proinflammatory mediator. We measured CRH levels in the plasma of children suffering from ITP and in the plasma of the paediatric controls, and we found that in controls CRH down-regulates leptin’s expression but not in patients.
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Neural mechanism of play fighting – neural circuitry, vasopressin, and CRH – in juvenile golden hamstersCheng, Shao-Ying 19 October 2009 (has links)
Play fighting is common in juvenile mammals as a peri-pubertal form of agonistic behavior preceding adult aggressive behavior. In golden hamsters, play fighting peaks in early puberty around postnatal day 35 (P-35), and gradually matures into adult aggression in late puberty. Though extensively studied, the neural mechanisms underlying play fighting remains poorly understood. My dissertation focuses on identifying the neural circuitry and neural transmitter systems that mediate this behavior in juvenile golden hamsters. Based on behavioral similarities between the offensive components of play fighting and adult aggression, I predicted that the neural circuitries mediating both behaviors shared common components. This possibility was tested by quantifying the immunolabeling of c-Fos expression in juvenile hamsters after the consummation of play fighting. In support of my hypothesis, I found that areas previously associated with offensive aggression in adult hamsters, including the ventrolateral hypothalamus (VLH), the posterior dorsal part of the medial amygdala (MePD), and the bed nucleus of the stria terminalis (BST), also showed enhanced c-Fos expression after play fighting, which supported my hypothesis. Vasopressin (AVP) facilitates aggression in adult hamsters. Therefore, I hypothesized that AVP also activates play fighting. To test my hypothesis, juvenile male golden hamsters were tested for play fighting after they received central microinjections of an AVP V1A-receptor antagonist into the anterior hypothalamus (AH). Also, immunocytochemistry was performed to identify possible AVP neurons associated with this behavior. I found that the AVP antagonist selectively inhibited the attack components of play fighting in experimental animals. In addition, AVP cells in the nucleus circularis (NC) and the medial division of the supraoptic nucleus (mSON), which were associated with offensive aggression, also showed increased c-Fos activity after play fighting. Together, these results show that AVP facilitates offensive behaviors throughout hamster development, from play fighting in juveniles to aggression in adults. A recent study shows that oral administration of a CRH receptor antagonist inhibits aggression in adult hamsters. Therefore, I predicted that CRH plays a similar role in play fighting. To test my prediction, juvenile hamsters were tested for play fighting after central microinjections of a CRH receptor antagonist. I found that microinjections of the CRH receptor antagonist within the lateral septum (LS) resulted in an inhibition of several aspects of play fighting. The possible source of CRH affecting the behavior was tested through combined immunocytochemistry to CRH and c-Fos. I found CRH neurons in the diagonal band of Broca (DBB), an area with extensive connections with the LS, were particularly activated in association with play fighting. In conclusion, I find that shared neural elements participating in the “vertebrate social behavior neural network” are associated with both aggression and play fighting in hamsters. This circuitry is activated before the onset of puberty and is affected by rising levels of steroid hormones during the developmental period leading to adult behaviors. Within the circuitry, vasopressin release in the AH appears to control the activation of play fighting attacks. In contrast, CRH release in the LS affects a broader range of aspects of play fighting, including not just consummatory aspects of the behavior, but apparently also appetitive components in the form of contact duration. / text
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GluR5 IS INVOLVED IN REGULATION OF THE HPA AXISVAN HOOREN, DANIELLA CHRISTINE 02 July 2004 (has links)
No description available.
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