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Beacon Immunoreactivity in the Rat HypothalamusNg, Y., Brailoiu, G. C., Dun, S. L., Ling, E. A., Yang, J., Chang, J. K., Dun, N. J. 01 May 2006 (has links)
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.
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The Impact of the Oxytocin and Vasopressin Systems on Sex-Specific Brain DevelopmentAulino, Elizabeth Ann Morningstar 29 April 2021 (has links)
No description available.
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Vasopressin Anatomy of the Mouse BrainRood, Benjamin D. 01 February 2010 (has links)
The nine amino acid peptide vasopressin acts as a neurohormone in the periphery and a neurotransmitter/neuromodulator in the central nervous system. Historically, research on vasopressin neurons and their projections to the pituitary has helped lay the groundwork for our understanding of peptidergic neurotransmission. Currently, our research on central vasopressin projections is driving a revolution in our understanding of social behavior. Vasopressin affects a number of social behaviors from social memory to aggression to affiliative behavior, such as pair-bonding. Further, with the addition of more and more transgenic mouse models of disease states, anxiety and depression related disorders, and social behavior dysfunction, it is important now more than ever to have a clear knowledge of the mouse vasopressin system, which derives from a number of distinct nuclei within the brain. Here, I map out vasopressin immunoreactivity in the mouse brain, and delineate the subset of brain regions with gonadal steroid hormone-dependent vasopressin immunoreactivity. Such projections are thought to derive from the bed nuclei of the stria terminalis and medial amygdala in the telencephalon. Finally, based on data from mice with lesions of the suprachiasmatic nucleus, I outline the subset of regions that likely receive vasopressin from this source. Our research on the anatomy of the vasopressin system of mice and our attempts to delineate the site of origin of the many vasopressin fibers found throughout the brain suggest that a significant amount of the vasopressin innervation deriving from cells in the bed nuclei of the stria terminalis and medial amygdala project to areas in the midbrain involved in serotonin and dopamine transmission, such as the dorsal raphe and ventral tegmental area. These transmitter systems play a crucial role in the control of anxiety and depression levels as well as motivated behavior and emotional regulation. Our results strongly suggest that a direct link exists between these systems, and future plans include an examination of this possibility. It is our hope that this work will further our understanding of the role of vasopressin and other transmitter systems in the regulation of social behaviors.
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Phase Regulation of the SCN Circadian Clock: Serotonergic and Neuropeptidergic MechanismsKaur, Gagandeep 06 November 2009 (has links)
No description available.
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avpr1a microsatellite length does not affect parental care in male prairie voles (Microtus ochrogaster)Kelley, Rebecca A. 02 May 2011 (has links)
No description available.
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La pathophysiologie de la maladie de Ménière au niveau du sac endolymphatique : une étude immunohistochimique de l’aquaporine-2, le récepteur de Vasopressine V2R, NKCC2 et TRPV4Asmar, Marc-Henri 08 1900 (has links)
Objectifs: La pathophysiologie de la maladie de Ménière (MM) demeure mal comprise. Nous avons identifié dans la littérature un groupe de protéines exprimées sur le sac endolymphatique (SEL) et impliquées dans la régulation du volume endolymphatique : l’Aquaporine-2 (AQP2), le récepteur V2R de vasopressine (AVP), le Co-transporteur de Sodium Potassium et Chlorure type 2 (NKCC2) et le canal TRP type V4 (TRPV4). Notre objectif est de déterminer si leur expression sur le SEL est altérée dans la MM, pour améliorer notre compréhension de la physiologie de l’hydrops endolymphatique.
Méthodes: Recrutement des cas de MM et schwannomes vestibulaires (SV) comme contrôles, le jour de leurs chirurgies respectives. Prélèvement de biopsies de SEL et sang pour AVP. L’immunohistochimie pour AQP2, V2R, NKCC2 et TRPV4 fut effectuée, et les lames scannées pour analyse digitale de densité d’expression par un logiciel spécialisé (VIS par Visiopharm®).
Résultats: Total de 27 cas MM et 23 contrôles. Les scores générés par le logiciel représentent la densité d’expression totale et relative des protéines, exclusivement sur l’épithélium du SEL. Les scores d’AQP2 sont élevés de façon significative dans la MM comparée aux contrôles (p = 0.018). Nous ne rapportons aucune variation significative pour AVP, V2R, NKCC2 et TRPV4.
Conclusion: Cette étude originale évalue l’expression simultanée de AQP2, V2R, NKCC2 et TRPV4 sur le SEL dans la MM, avec un groupe contrôle (SV). Nos résultats démontrent une augmentation isolée de l’AQP2 dans la MM. Nous proposons une surexpression constitutive de cette dernière, indépendante de son axe de régulation (AVP-V2R). Une mutation somatique au niveau des séquences régulatrices pourrait justifier nos observations. / Objectives: Endolymphatic sac (ELS) pathophysiology in Ménière’s Disease (MD) remains poorly understood. We identified from the literature a group of proteins expressed on the ELS and involved in endolymph volume regulation: Aquaporin-2 (AQP2), vasopressin receptor V2R, Sodium Potassium Chloride Cotransporter type 2 (NKCC2) and TRP channel type V4 (TRPV4). Our objective was to determine whether their ELS expression was altered in MD, to better understand the pathophysiology of endolymphatic hydrops.
Methods: Patients with definite MD undergoing endolymphatic duct blockage surgery were recruited, as well as controls undergoing surgery for vestibular schwannomas (VS). ELS biopsies and blood samples for plasma Arginine Vasopressin (AVP) were obtained. Immunohistochemistry for AQP2, V2R, NKCC2 and TRPV4 was performed. Slides were scanned digitally for highly sensitive pixel density analysis by specialized software (VIS by Visiopharm®).
Results: 27 definite MD patients and 23 VS controls were included. Global scores generated by the software represent total and relative protein expression density of 3 staining intensity levels, exclusively on ELS epithelium. AQP2 expression density was significantly elevated in MD compared to VS (p = 0.018). There was no significant difference in plasma AVP, V2R, NKCC2 and TRPV4 expression.
Conclusion: This original study evaluates simultaneous in-situ expression of AQP2, V2R, NKCC2 and TRPV4 on the human ELS in MD, with a VS control group. Our results show only AQP2 up regulation on the ELS of MD patients. We suggest a constitutively increased expression of AQP2 in MD, independent of its regulatory axis (AVP-V2R). Acquired regulator sequence mutations could support this model.
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Vasopressinmarkören Copeptin : Beskrivning av analysförfarande och användningsområde / The Vasopressin marker Copeptin : Description of the assay procedure and area of use.Börjesson, Linus January 2022 (has links)
Vasopressin är ett viktigt hormon som har många fysiologiska funktioner, däribland upprätthållandet av vätskebalansen i kroppen. Mätning av detta hormon är dock komplicerat och därför används ”skuggfragmentet” copeptin, som härstammar från samma prekursor. Genom användandet av metoden B·R·A·H·M·S KRYPTOR compact PLUS mäts copeptin. Studiens syfte är att beräkna variations-koefficienten och därmed undersöka de uppmätta värdenas reproducerbarhet. Vidare blir syftet att använda EpiHealth-kohortstudien för att validera den redan kända kopplingen mellan copeptin och förhöjt blodsocker genom en multivariant linjär regression. Vi kan i arbetet konstatera att copeptin metoden har en god reproducerbarhet, där majoriteten av de multipelt uppmätta copeptin-värdena har en inter-assay CV <8%. Vid undersökning av EpiHealth-kohorten fann vi att en ökning av copeptin var kross-sektionellt associerad med ett flertal metabola riskmarkörer, däribland fastande plasma-glukos, efter multivariant justering. Att copeptin var signifikant relaterat till denna potenta metabola riskmarkör kan tyda på att det finns ett orsakssamband mellan förhöjt vasopressin och förhöjt blodsocker, något som även tidigare studier har pekat på. Detta i sin tur visar att vasopressin kan spela en roll i utvecklandet av typ 2-diabetes. Om ett orsaks-samband föreligger undersöks nu i en stor randomiserad klinisk studie där vasopressin-nivåerna hos hälften av deltagarna sänks med hjälp av ökat vatten-intag (H2O-metab-studien). Det finns förhoppningar om att användandet av copeptin skall kunna användas i klinisk verksamhet för att riskbedöma individer avseende kardiometabola sjukdomar (däribland typ 2-diabetes). / Vasopressin is an important hormone that has many physiological functions, including the maintenance of fluid balance in the body. Measurement of this hormone is however complicated and therefore the "shadow fragment" copeptin is used, which is derived from the same precursor. Using the BRAHMS copeptin proAVP KRYPTOR method, copeptin was measured in this study. The purpose of the study is to calculate the coefficient of variation, and thus examine the reproducibility of the measured values . Furthermore, the aim will be to use the EpiHealth cohort study was used to validate the link between copeptin and elevated blood sugar through a multivariate linear regression. The majority of the multiple measurements of copeptin values had an inter-assay CV <8%, which indicates that the method has a good reproducibility. Examination of the EpiHealth cohort revealed that elevated copeptin was cross-sectionally associated with a number of metabolic risk markers, including fasting plasma glucose, after multivariate adjustment, a finding that is in line with previous findings from epidemiological studies. The fact that copeptin was significantly related to this potent metabolic risk marker may indicate a causal role of the vasopressin system in elevated blood glucose and may play a role in the development of type 2 diabetes metillus. Previous experimental and genetical studies have indicated a causal association between elevated vasopressin and diabetes development. Currently, a randomized clinical trial is ongoing (the H2O-metab-study) in order to investigate a possible causal association between elevated vasopressin and glucose. In the study, increased water intake is used to lower plasma vasopressin (measured as copeptin), and the glucose-lowering potential of this water treatment is tested. There are hopes that copeptin can in the future be used in clinical practice for risk assessment with respect to cardiometabolic diseases (including type 2 diabetes).
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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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Impact d'une neuroinflammation transitoire ou chronique à bas bruit sur le fonctionnement neuronal / Impact of a transient or a chronic and low grade neuroinflammation on neuronal functionMarcand-Sauvant, Julie 16 December 2010 (has links)
L’état fébrile et le vieillissement normal sont deux processus physiologiques conduisant à un déséquilibre hydrominéral de l'organisme. Ce déséquilibre se traduit par une déshydratation sévère qui peut être aggravée par des conditions climatiques comme nous l'avons vu durant l'été 2003. Dans les deux cas, fièvre et vieillissement, l'organisme répond par une stimulation du système hypothalamo-neurohypophysaire conduisant à l’augmentation de la libération de vasopressine ou hormone antidiurétique, qui pourrait prévenir une déshydratation possiblement critique. Cependant, les modalités d’activation des neurones vasopressinergiques (AVP) dans ces conditions restent inconnues.Le but des recherches réalisées dans cette thèse, a été de déterminer les mécanismes cellulaires et moléculaires responsables de l’activation des neurones vasopressinergiques (AVP) lors d’une réponse inflammatoire et au cours du vieillissement.Nous avons pu démontrer dans la première partie de ce travail que lors d’un épisode inflammatoire (mimé par une injection de lypopolysaccharide LPS) l’activité des neurones AVP est rapidement augmentée et cette activation est soutenue pendant plus de six heures. De plus, cette activation n’est pas due à un effet potentiel secondaire du LPS sur l'osmolarité plasmatique ou la pression artérielle. L’activation précoce des neurones AVP par le LPS semble être soutenue par l’IL-6 (qui mime les effets du LPS), puisque l’activation par le LPS est bloquée par une injection préalable d’anticorps anti-IL-6.Dans la seconde partie de ce travail, nous avons pu montrer le traitement chronique d’IGF-I chez le rat âgé permet de restaurer une fonction urinaire comparable à celle observée chez l’adulte, en agissant vraisemblablement directement sur les neurones AVP puisque le taux plasmatique d’AVP chez les rats âgés traités par l’IGF-I revient à des valeurs normales, i.e., équivalente à celle de rats adultes. Cette hypothèse est confortée par le fait que (i) les neurones AVP expriment le récepteur de l’IGF-I et qu’il n’y a pas de différence dans l’expression de ces récepteurs entre rats âgés et adultes, et (ii) les neurones AVP sont inhibés par l’IGF-I.Enfin, dans la dernière partie de ce travail, nous avons pu montrer que lors du vieillissement, les neurones AVP sont activés, ce qui se traduit par un taux plasmatique d’AVP élevé et un taux d’apeline très faible. De même, les astrocytes sont activés et ne présentent plus de plasticité morphofonctionelle. La microglie, en état d’alerte, ne semble pas jouer un rôle prépondérant dans cette suractivation neuronale et astrocytaire. De plus, cette suractivation neuronale est palliée par un traitement central par un anticorps anti-IL-6 ou un inhibiteur non sélectif des canaux TRPV. Cependant, un traitement central par un anticorps anti-IL-6 n’affecte pas l’expression des TRPV2 dans le noyau supra-optique (NSO). En conclusion générale, il apparait que :1/ L’IL-1 n’est pas le chef d’orchestre de tous les processus inflammatoires. En effet, dans le NSO, l’activation des neurones AVP est soutenue par l’IL-62/ La balance pro- / anti-inflammatoire est un élément importante du dysfonctionnement neuronal. Cependant, le facteur critique du dysfonctionnement des neurones AVP n’est pas la production excessive de facteurs inflammatoires mais l’insuffisante production compensatoire de facteurs anti-inflammatoires.3/ lors du vieillissement, la neuroinflammation responsable du dysfonctionnement des neurones AVP peut être qualifiée de type « chronique à bas bruit », processus dans lequel (i) la microglie, en alerte, voit sa réactivité décuplée lors d'une sollicitation inflammatoire supplémentaire; (ii) le cross-talk astrocytes-neurones est figé dans une configuration d'hyperactivité, semblable à celle observée à l'âge adulte en condition de stimulation physiologique soutenue (comme lors d'une déshydratation), mais qui empêche toute réponse appropriée du réseau à toute demande physiologique supplémentaire, quelle soit transitoire (comme la réponse à une injection aigüe de LPS ou de NaCl 9%) ou soutenue (déshydratation de 48h).Cependant, les données de la littérature montrent le rôle majeur de la microglie dans d'autres types de neuroinflammation dites à « haut bruit », et dont les effets délétères - qui vont du dysfonctionnement neuronal à la neuro-dégénérescence – trouvent leur origine dans la surexpression de molécules microgliales telles l'IL-1 ou le TNF. Pour tenter de comprendre les mécanismes cellulaires et moléculaires impliqués dans un tel dysfonctionnement et pour caractériser la nature du dysfonctionnement neuronal, nous avons mis au point un modèle pharmacologique de neuroinflammation à haut bruit, en injectant directement dans les NSO de l'IL-1. Nos données préliminaires montrent que le dysfonctionnement neuronal ainsi que les mécanismes cellulaires et moléculaires à l’origine de ce dysfonctionnement diffèrent de ceux observés lors du vieillissement : la microglie est activée et surexprime de nombreuses molécules inflammatoires, probablement à l’origine du dysfonctionnement neuronal (absence de pattern phasique, même lors d’une stimulation osmotique), puisque les astrocytes ne semblent pas être affectés. L’absence de pattern phasique à l’origine du faible taux d’AVP plasmatique traduit une perturbation des propriétés électrophysiologiques intrinsèques sous-tendant ce pattern phasique (récepteurs ; canaux ioniques) et/ou des afférences excitatrices (Glu ; ACh ; Na) ou inhibitrices (GABA) modulant cette activité phasique. / The fever and normal aging are two physiological processes leading to water and mineral imbalance in the body. This imbalance results in severe dehydration which can be aggravated by climatic conditions as we saw during the summer of 2003. In both cases, fever and age, the body responds by stimulating the hypothalamic-neurohypophysial system leading to increased release of vasopressin or antidiuretic hormone, which could possibly prevent dehydration criticism. However, the modalities of activation of vasopressinergic neurons (AVP) in these conditions remain unknown. The aim of the research done in this thesis was to determine the cellular and molecular mechanisms responsible for the activation of vasopressinergic neurons (AVP) during an inflammatory response and during aging. We showed ,in the first part of this work, that during an inflammatory episode (mimicked by an injection of lypopolysaccharide LPS) the activity of AVP neurons is rapidly increased and this activation is sustained for more than six hours. Moreover, this activation is not due to a potential secondary effect of LPS on plasma osmolarity and blood pressure. The early activation of AVP neurons by LPS seems to be supported by IL-6 (which mimics the effects of LPS), since activation by LPS is blocked by prior injection of anti-IL-6. In the second part of this work, we showed chronic treatment of IGF-I in old rats can restore bladder function similar to that observed in adults, presumably by acting directly on neurons AVP as the rate plasma AVP in aged rats treated with IGF-I returned to normal values, ie, equivalent to that of adult rats. This hypothesis is supported by the fact that (i) AVP neurons express the receptor for IGF-I and there is no difference in the expression of these receptors between adult and aged rats, and (ii) AVP neurons are inhibited by IGF-I. Finally, in the latter part of this work, we showed that during aging, the AVP neurons are activated, which results in increased serum AVP level and a very low rate of apelin. Similarly, astrocytes are activated and show more morphofunctional plasticity. Microglia does not seem to play a role in neuronal and astrocytic overactivation. Moreover, this neuronal overactivation is overcome by a central processing by an anti-IL-6 or a nonselective TRPV channels. However, an icv treatment by an anti-IL-6 does not affect the expression of TRPV2 in the supraoptic nucleus (SON). In general conclusion, it appears that: 1 / IL-1 is not the conductor of all inflammatory processes. Indeed, in the NSO, the activation of AVP neurons is sustained by IL-6 2 / the balance of pro-/ anti-inflammatory is significant in neuronal dysfunction. However, the critical factor in the dysfunction of AVP neurons is not the excessive production of inflammatory factors, but the insufficient production of compensatory anti-inflammatory factors. 3 / during aging, neuroinflammation responsible for the dysfunction of AVP neurons can be classified as type "chronic and low-grade" process in which (i) microglia, in alert, saw its reactivity increased tenfold during inflammatory additional solicitation; (ii) cross-talk astrocyte-neuron is stuck in a pattern of hyperactivity, similar to that observed in adulthood under conditions of sustained physiological arousal (such as in dehydration), but that would prevent the proper response network to any additional physiological demand, which is transient (as the response to acute injection of LPS or NaCl 9%) or sustained (48 h dehydration). However, literature data show the important role of microglia in other types of neuroinflammation called "high grade", and whose deleterious effects - ranging from neuronal dysfunction to neurodegeneration - are rooted in Microglial overexpression of molecules such as IL-1 or TNF . In an attempt to understand the cellular and molecular mechanisms involved in such dysfunction and to characterize the nature of neuronal dysfunction, we have developed a pharmacological model of neuroinflammation high grade by injecting IL-1 directly into the SON. Our preliminary data show that neuronal dysfunction and the cellular and molecular mechanisms behind this dysfunction differ from those observed during aging: activated microglia overexpressing many inflammatory molecules, probably at the origin of neuronal dysfunction ( absence of phasic pattern, even during osmotic stimulation), since astrocytes do not appear to be affected. The absence of phasic pattern causing the low plasma AVP reflects a disturbance of intrinsic electrophysiological properties underlying the phasic pattern (receptors, ion channels) and / or afferent excitatory (Glu, ACh, Na) or inhibitory (GABA) modulating the phasic activity.
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Oligomérisation des récepteurs couplés au protéines G de la famille de la vasopressine et de l’ocytocine : mise en évidence dans les tissus natifs / Vasopressin and oxytocin family G-protein coupled receptors oligomerization : proof in native tissuesCottet, Martin 21 January 2013 (has links)
Les récepteurs couplés aux protéines G forment une grande famille de récepteurs transmembranaires. De nombreuses études montrent que ces récepteurs présenteraient une tendance à interagir entre eux et à former des oligomères. Ces structures sont toutefois sujettes à controverse. En effet, très peu d'éléments permettent d'affirmer que ces oligomères existeraient dans les tissus natifs, la plupart des caractérisations se faisant en systèmes hétérologues. Nous avons donc développé une approche basée d'une part sur l'utilisation de ligands fluorescents pour marquer les récepteurs dans leur environnement natif et d'autre part sur le FRET (Fluorescence Resonance Energy Transfer) en temps résolu en utilisant des cryptates de lanthanides, en particulier le Lumi4-Tb. Nous avons ainsi pu montrer et publier l'existence d'oligomères du récepteur de l'ocytocine dans la glande mammaire. Le protocole de cette étude a aussi été publié et a été validé pour la mise en évidence d'hétéro-oligomères, plus précisément entre les récepteurs V1a et V2 de la vasopressine. La poursuite de l'étude de ce phénomène dans les tissus natifs nous a poussés à développer notre propre dispositif de microscopie FRET en temps résolu. Ce dispositif est basé sur un microscope en champ large auquel nous avons ajouté une source laser pour l'excitation pulsée et une caméra CCD Multigate pour la détection. Nous en présentons ici les premiers résultats ainsi que sa validation pour l'utilisation de multiples fluorophores accepteurs avec une contamination minimale par le Lumi4-Tb. Enfin, nous proposons un modèle pharmacologique montrant l'utilisation de ligands bivalents pour étudier le couplage des oligomères. / G-protein coupled receptors form a very large family of transmembrane receptors. Numerous studies have shown that these receptors showed a tendency to interact and form oligomers. These structures are however the matter of great debate. Indeed, very few elements allow us to maintain that these oligomers could exist in native tissues, most studies being carried out in heterologous systems. We have therefore developed an approach based for one part on the use of fluorescent ligands to label receptors in their native environment, and on the other part on time-resolved FRET (Fluorescence Resonance Energy Transfer) by using lanthanide cryptates, more specifically Lumi4-Tb. We have thus been able to show and publish the existence of oxytocin receptor oligomers in the mammary gland. The protocol used for this study was also published and validated for the study of hetero-oligomers, more specifically between vasopressin V1a and V2 receptors. Following on our study of oligomers in native tissues, we have developed our own setup to perform time-resolved FRET microscopy. This setup is based on a wide field microscope to which we added a laser source for the pulsed excitation and a Multigate CCD camera for imaging. We are here presenting the first results as well as its validation for the use of multiple acceptor fluorophores with minimal bleed through from the Lumi4-Tb. Lastly, we propose a pharmacological model showing the use of bivalent ligands to study oligomer coupling.
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