Social behavior regulation through sequential actions of oxytocin and vasopressin in the lateral septum

Contexte : L’ocytocine (OT) et la vasopressine (VP) modulent les comportements sociaux. Leurs rôles ont été étudiés indépendamment l’un de l’autre mais des effets combinatoires de ces deux peptides sont à envisager puisqu’ils sont tous les deux libérés au cours des comportements sociaux. Dans le septum latéral (SL), une structure cérébrale intégrant des informations sociales, l’ocytocine et la vasopressine sont libérées au cours des interactions sociales et modulent la reconnaissance ainsi que la discrimination sociale.Objectif : Comprendre la fonction duale de l’ocytocine et de la vasopressine mise en jeu lors des interactions sociales dans un cadre physiologique et pathologique. Méthode : Chez la souris mâle, nous avons utilisé l’activité électroencéphalographique (EEG) comme marqueur et avons caractérisé des traces EEG dépendantes de l’OT et de la VP. Nous avons manipulé le système OT et le système VP au sein du septum au cours d’un protocole de reconnaissance/discrimination sociale en utilisant des outils pharmacologiques ou optogénétiques. Des expériences d’électrophysiologie sur tranche ont permis de caractériser la réponse électrophysiologique des neurones du septum latéral à l’application de chacun de ces peptides.Résultats : L’étude de l’activité EEG nous a permis de discriminer des effets induits par l’action septale de l’OT et la VP dans la bande de fréquence theta. Ces résultats suggèrent que la VP serait libérée dans le septum au cours de la première rencontre avec un juvénile alors que l’OT serait libérée au cours du processus d’habituation. La modulation de l’action de l’OT et de la VP sur le SL démontre que l’activation des récepteurs V1a au cours de la première rencontre est essentielle à la discrimination sociale tandis que l’activation des récepteurs à l’OT au cours du processus d’habituation permet de regain d’intérêt lorsqu’un nouveau juvénile sera présenté. Nous montrons aussi que l’OT et la VP modulent l’activité électrique de la quasi-totalité des neurones septaux. La nature de ces modulations définit 3 catégories de neurones qui communiquent entre eux via des signaux GABAergiques. Chez la souris Magel2KO, un modèle murin de troubles des comportements sociaux, la balance des effets septaux de l’OT et de la VP est altérée. Ceci suggère que cette régulation pourrait être impliquée dans certaines conditions pathologiques.Conclusion : Ces résultats mettent en évidence qu’il est essentiel, lorsque l’on étudie l’ocytocine, d’étudier le système vasopressinergique. Avec cette approche, nous avons montré que l’activation séquentielle du SL par l’OT et la VP est importante pour la régulation des interactions sociales. De plus, cette séquence d’évènements est altérée dans un modèle animal présentant des troubles sociaux.Context : Oxytocin (OT) and vasopressin (VP) modulate social behaviors. The roles of OT and VP have been interrogated so far in isolation whereas combinatorial effects are anticipated as both hormones are secreted during social behavior. In the lateral septum (LS), a brain area processing behavioral social cues, OT and VP are released during social interaction and modulate social recognition or discrimination. Aim : To understand the dual function of OT and VP during social behavior in physiological and pathological conditions. Methods : In male mice, we used electroencephalographic (EEG) activity as a readout to characterize OT and VP dependent electrophysiological signatures and their sequence. We manipulated OT and VP systems to LS during social recognition/discrimination paradigm using pharmacology and optogenetic tools. Using slice electrophysiology, we characterized electrophysiological responses of LS neurons to both of these hormons.Results : Measurement of EEG theta activity allowed us to discriminate between OT and VP dependent LS modulation and indicated that VP would be released in the LS during 1st encounter with a juvenile while OT would be released during the habituation process. Modulation of OT and VP actions on the LS demonstrate that V1a activation during 1st encounter is essential for social discrimination and OT receptor activation during the habituation process allows the regain of interest for a new juvenile. We also demonstrated that OT and VP modulate electrical activity of almost all LS neurons. The nature of this modulation define 3 neuronal categories that communicate with each other through GABAergic signalling. Magel2KO mouse, which features social deficits, presents an altered balance of LS regulation by OT and VP. It suggests that this regulation could be involved in some pathological symptomatology.Conclusions : These results shed a light on the necessity to study vasopressin along with oxytocin. Doing this, we showed that vasopressinergic and oxytocinergic activation of the LS are sequentially important during the social recognition paradigm. Futhermore, this sequence of events is impaired in a mouse model featuring deficits of OT and social disabilities

Régulation des comportements sociaux par l'action séquentielle de l'ocytocine et de la vasopressine dans le septum latéral

Context : Oxytocin (OT) and vasopressin (VP) modulate social behaviors. The roles of OT and VP have been interrogated so far in isolation whereas combinatorial effects are anticipated as both hormones are secreted during social behavior. In the lateral septum (LS), a brain area processing behavioral social cues, OT and VP are released during social interaction and modulate social recognition or discrimination. Aim : To understand the dual function of OT and VP during social behavior in physiological and pathological conditions. Methods : In male mice, we used electroencephalographic (EEG) activity as a readout to characterize OT and VP dependent electrophysiological signatures and their sequence. We manipulated OT and VP systems to LS during social recognition/discrimination paradigm using pharmacology and optogenetic tools. Using slice electrophysiology, we characterized electrophysiological responses of LS neurons to both of these hormons.Results : Measurement of EEG theta activity allowed us to discriminate between OT and VP dependent LS modulation and indicated that VP would be released in the LS during 1st encounter with a juvenile while OT would be released during the habituation process. Modulation of OT and VP actions on the LS demonstrate that V1a activation during 1st encounter is essential for social discrimination and OT receptor activation during the habituation process allows the regain of interest for a new juvenile. We also demonstrated that OT and VP modulate electrical activity of almost all LS neurons. The nature of this modulation define 3 neuronal categories that communicate with each other through GABAergic signalling. Magel2KO mouse, which features social deficits, presents an altered balance of LS regulation by OT and VP. It suggests that this regulation could be involved in some pathological symptomatology.Conclusions : These results shed a light on the necessity to study vasopressin along with oxytocin. Doing this, we showed that vasopressinergic and oxytocinergic activation of the LS are sequentially important during the social recognition paradigm. Futhermore, this sequence of events is impaired in a mouse model featuring deficits of OT and social disabilities.Contexte : L’ocytocine (OT) et la vasopressine (VP) modulent les comportements sociaux. Leurs rôles ont été étudiés indépendamment l’un de l’autre mais des effets combinatoires de ces deux peptides sont à envisager puisqu’ils sont tous les deux libérés au cours des comportements sociaux. Dans le septum latéral (SL), une structure cérébrale intégrant des informations sociales, l’ocytocine et la vasopressine sont libérées au cours des interactions sociales et modulent la reconnaissance ainsi que la discrimination sociale.Objectif : Comprendre la fonction duale de l’ocytocine et de la vasopressine mise en jeu lors des interactions sociales dans un cadre physiologique et pathologique. Méthode : Chez la souris mâle, nous avons utilisé l’activité électroencéphalographique (EEG) comme marqueur et avons caractérisé des traces EEG dépendantes de l’OT et de la VP. Nous avons manipulé le système OT et le système VP au sein du septum au cours d’un protocole de reconnaissance/discrimination sociale en utilisant des outils pharmacologiques ou optogénétiques. Des expériences d’électrophysiologie sur tranche ont permis de caractériser la réponse électrophysiologique des neurones du septum latéral à l’application de chacun de ces peptides.Résultats : L’étude de l’activité EEG nous a permis de discriminer des effets induits par l’action septale de l’OT et la VP dans la bande de fréquence theta. Ces résultats suggèrent que la VP serait libérée dans le septum au cours de la première rencontre avec un juvénile alors que l’OT serait libérée au cours du processus d’habituation. La modulation de l’action de l’OT et de la VP sur le SL démontre que l’activation des récepteurs V1a au cours de la première rencontre est essentielle à la discrimination sociale tandis que l’activation des récepteurs à l’OT au cours du processus d’habituation permet de regain d’intérêt lorsqu’un nouveau juvénile sera présenté. Nous montrons aussi que l’OT et la VP modulent l’activité électrique de la quasi-totalité des neurones septaux. La nature de ces modulations définit 3 catégories de neurones qui communiquent entre eux via des signaux GABAergiques. Chez la souris Magel2KO, un modèle murin de troubles des comportements sociaux, la balance des effets septaux de l’OT et de la VP est altérée. Ceci suggère que cette régulation pourrait être impliquée dans certaines conditions pathologiques.Conclusion : Ces résultats mettent en évidence qu’il est essentiel, lorsque l’on étudie l’ocytocine, d’étudier le système vasopressinergique. Avec cette approche, nous avons montré que l’activation séquentielle du SL par l’OT et la VP est importante pour la régulation des interactions sociales. De plus, cette séquence d’évènements est altérée dans un modèle animal présentant des troubles sociaux

Bridging the Gap between Brain-Derived Neurotrophic Factor and Glucocorticoid Effects on Brain Networks

International audienceBehavioral choices made by the brain during stress depend on glucocorticoid and brain-derived neurotrophic factor (BDNF) signaling pathways acting in synchrony in the meso-limbic (reward) and corticolimbic (emotion) neural networks. Deregulated expression of BDNF and glucocorticoid receptors in brain valuation areas may compromise the integration of signals. Glucocorticoid receptor phosphorylation upon BDNF signaling in neurons represents one mechanism underlying the integration of BDNF and glucocorticoid signals that when off balance may lay the foundation of malad-aptations to stress. Here, we propose that BDNF signaling conditions glucocorticoid responses impacting neural plasticity in the mesocorticolimbic system. This provides a novel molecular framework for understanding how brain networks use BDNF and glucocorticoid signaling contingencies to forge receptive neuronal fields in temporal domains defined by behavioral experience, and in mood disorders

La vasopressine

International audienceLes troubles du spectre de l’autisme sont caractérisés par des défauts de communication et d’interaction sociale associés à des intérêts restreints et stéréotypés. Ces troubles apparaissent tôt au cours du développement, et conduisent à une dégradation de la qualité de vie. Alors qu’au moins 670 000 personnes en sont atteintes en France, leur substrat neurobiologique reste mal compris. Les traitements disponibles sont limités et présentent des effets indésirables. La vasopressine, un neuropeptide produit par le cerveau, a récemment été mise en avant comme un possible traitement contre les troubles du comportement social, et l’utilisation d’un modèle préclinique a permis d’élucider des mécanismes d’action [1]

Persistence of learning-induced synapses depends on neurotrophic priming of glucocorticoid receptors

International audienceSignal transduction upon activation of receptor tyrosine kinases by neurotrophins and nuclear receptors by glucocorticoids is essential for homeostasis. Phosphorylation (PO4) is one way these receptors communicate with one another to support homeostatic reactions in learning and memory. Using a newly developed glucocorticoid receptor (GR)-PO4–deficient knock-in mouse, we show that consolidation of learning-induced neuroplasticity depends on both GR-PO4 and neurotrophic signaling. Cross-talk between these pathways affects experience-dependent neuroplasticity and behavior, extending previous implications of neurotrophic priming of glucocorticoid response for adaptive plasticity to chronic stress and antidepressant response. Therefore, a disruption of cross-talk between these pathways by, for example, the misalignment of circadian glucocorticoid release and experience-dependent neurotrophic signaling may contribute to the pathophysiology of stress-related disorders

Correction of vasopressin deficit in the lateral septum ameliorates social deficits of mouse autism model

International audienceIntellectual and social disabilities are common comorbidities in adolescents and adults with MAGE family member L2 (MAGEL2) gene deficiency characterizing the Prader-Willi and Schaaf-Yang neurodevelopmental syndromes. The cellular and molecular mechanisms underlying the risk for autism in these syndromes are not understood. We asked whether vasopressin functions are altered by MAGEL2 deficiency and whether a treatment with vasopressin could alleviate the disabilities of social behavior. We used Magel2-knockout mice (adult males) combined with optogenetic or pharmacological tools to characterize disease modifications in the vasopressinergic brain system and monitor its impact on neurophysiological and behavioral functions. We found that the activation of vasopressin neurons and projections in the lateral septum were inappropriate for performing a social habituation/discrimination task. Mechanistically, the lack of vasopressin impeded the deactivation of somatostatin neurons in the lateral septum, which predicted social discrimination deficits. Correction of vasopressin septal content by administration or optogenetic stimulation of projecting axons suppressed the activity of somatostatin neurons and ameliorated social behavior. This preclinical study identified vasopressin in the lateral septum as a key factor in the pathophysiology of Magel2-related neurodevelopmental syndromes

Neuroanatomical distribution and function of the vasopressin V-1B receptor in the rat brain deciphered using specific fluorescent ligands

It is now accepted that vasopressin, through V-1A/V-1B receptors, centrally regulates cognitive functions such as memory, affiliation, stress, fear and depression. However, the respective roles of these receptor isoforms and their contribution to stress-related pathologies remain uncertain. The development of new therapeutic treatments requires a precise knowledge of the distribution of these receptors within the brain, which has been so far hampered by the lack of selective V-1B markers. In the present study, we have determined the pharmacological properties of three new potent rat V-1B fluorescent ligands and demonstrated that they constitute valuable tools for simultaneous visualization and activation of native V-1B receptors in living rat brain tissue. Thus, d[Leu(4),Lys-Alexa 647)(8)]VP (analogue 3), the compound with the best affinity-selectivity/fluorescence ratio for the V-1B receptor emerged as the most promising. The rat brain regions most concerned by stress such as hippocampus, olfactory bulbs, cortex and amygdala display the highest V-1B fluorescent labelling with analogue 3. In the hippocampus CA(2), V-1B receptors are located on glutamatergic, not GABAergic neurones, and are absent from astrocytes. Using AVP-EGFP rats, we demonstrate the presence of V-1B autoreceptors on AVP-secreting neurones not only in the hypothalamus, but also sparsely in the hippocampus. Finally, using both electrophysiology and visualization of ERK phosphorylation, we show analogue 3-induced activation of the V-1B receptor in situ. This will help to analyse expression and functionality of V-1B receptors in the brain and contribute to further explore the AVPergic circuitry in normal and pathological conditions. (C) 2017 Elsevier Inc. All rights reserved

Neuroanatomical distribution and function of the vasopressin V1B receptor in the rat brain deciphered using specific fluorescent ligands

International audienceIt is now accepted that vasopressin, through V1A/V1B receptors, centrally regulates cognitive functions such as memory, affiliation, stress, fear and depression. However, the respective roles of these receptor isoforms and their contribution to stress-related pathologies remain uncertain. The development of new therapeutic treatments requires a precise knowledge of the distribution of these receptors within the brain, which has been so far hampered by the lack of selective V1B markers. In the present study, we have determined the pharmacological properties of three new potent rat V1B fluorescent ligands and demonstrated that they constitute valuable tools for simultaneous visualization and activation of native V1B receptors in living rat brain tissue. Thus, d[Leu4,Lys-Alexa 647)8]VP (analogue 3), the compound with the best affinity-selectivity/fluorescence ratio for the V1B receptor emerged as the most promising. The rat brain regions most concerned by stress such as hippocampus, olfactory bulbs, cortex and amygdala display the highest V1B fluorescent labelling with analogue 3. In the hippocampus CA2, V1B receptors are located on glutamatergic, not GABAergic neurones, and are absent from astrocytes. Using AVP-EGFP rats, we demonstrate the presence of V1B autoreceptors on AVP-secreting neurones not only in the hypothalamus, but also sparsely in the hippocampus. Finally, using both electrophysiology and visualization of ERK phosphorylation, we show analogue 3-induced activation of the V1B receptor in situ. This will help to analyse expression and functionality of V1B receptors in the brain and contribute to further explore the AVPergic circuitry in normal and pathological conditions

Control of Social Withdrawal of Mice Deficient for the Autism Gene Magel2 by Restoration of Vasopressin-Oxytocin Dialogue in Septum

Intellectual and social disabilities are common comorbidities in adolescents and adults with Magel2 gene deficiency characterizing the Prader-Willi and Schaaf-Yang neurodevelopmental syndromes. The cellular and molecular mechanisms underlying the risk for autism in these syndromes are unexplored. Here we used Magel2 knockout mice combined with optogenetic/pharmacological tools to characterize disease modifications in the social brain network. We find that the degree of social novelty moderates a dialogue between vasopressin and oxytocin in the lateral septum, a region organizing sequential content of sensory experiences. Social withdrawal of mice lacking Magel2 is alleviated by restoration of dialogue-lead by vasopressin. This preclinical study identifies the collective actions of vasopressin and oxytocin in the lateral septum as a key factor in the pathophysiology