Innate Immune Sensing of Fusarium culmorum by Mouse Dendritic Cells.

Chronic inhalation of grain dust is associated with asthma and chronic bronchitis in grain worker populations. Exposure to fungal particles was postulated to be an important etiologic agent of these pathologies. Fusarium species frequently colonize grain and straw and produce a wide array of mycotoxins that impact human health, necessitating an evaluation of risk exposure by inhalation of Fusarium and its consequences on immune responses. Data showed that Fusarium culmorum is a frequent constituent of aerosols sampled during wheat harvesting in the Vaud region of Switzerland. The aim of this study was to examine cytokine/chemokine responses and innate immune sensing of F. culmorum in bone-marrow-derived dendritic cells and macrophages. Overall, dendritic cells and macrophages responded to F. culmorum spores but not to its secreted components (i.e., mycotoxins) by releasing large amounts of macrophage inflammatory protein (MIP)-1α, MIP-1β, MIP-2, monocyte chemoattractant protein (MCP)-1, RANTES, and interleukin (IL)-12p40, intermediate amounts of tumor necrosis factor (TNF), IL-6, IL-12p70, IL-33, granulocyte colony-stimulating factor (G-CSF), and interferon gamma-induced protein (IP-10), but no detectable amounts of IL-4 and IL-10, a pattern of mediators compatible with generation of Th1 or Th17 antifungal protective immune responses rather than with Th2-dependent allergic responses. The sensing of F. culmorum spores by dendritic cells required dectin-1, the main pattern recognition receptor involved in β-glucans detection, but likely not MyD88 and TRIF-dependent Toll-like receptors. Taken together, our results indicate that F. culmorum stimulates potently innate immune cells in a dectin-1-dependent manner, suggesting that inhalation of F. culmorum from grain dust may promote immune-related airway diseases in exposed worker populations.

Controlling complexity: the clinical relevance of mouse complex genetics.

Experimental animal models are essential to obtain basic knowledge of the underlying biological mechanisms in human diseases. Here, we review major contributions to biomedical research and discoveries that were obtained in the mouse model by using forward genetics approaches and that provided key insights into the biology of human diseases and paved the way for the development of novel therapeutic approaches.

Meeting report of the European mouse complex genetics network SYSGENET.

The second scientific meeting of the European systems genetics network for the study of complex genetic human disease using genetic reference populations (SYSGENET) took place at the Center for Cooperative Research in Biosciences in Bilbao, Spain, December 10-12, 2012. SYSGENET is funded by the European Cooperation in the Field of Scientific and Technological Research (COST) and represents a network of scientists in Europe that use mouse genetic reference populations (GRPs) to identify complex genetic factors influencing disease phenotypes (Schughart, Mamm Genome 21:331-336, 2010). About 50 researchers working in the field of systems genetics attended the meeting, which consisted of 27 oral presentations, a poster session, and a management committee meeting. Participants exchanged results, set up future collaborations, and shared phenotyping and data analysis methodologies. This meeting was particularly instrumental for conveying the current status of the US, Israeli, and Australian Collaborative Cross (CC) mouse GRP. The CC is an open source project initiated nearly a decade ago by members of the Complex Trait Consortium to aid the mapping of multigenetic traits (Threadgill, Mamm Genome 13:175-178, 2002). In addition, representatives of the International Mouse Phenotyping Consortium were invited to exchange ongoing activities between the knockout and complex genetics communities and to discuss and explore potential fields for future interactions.

Ultra-high-resolution 3D imaging of atherosclerosis in mice with synchrotron differential phase contrast: a proof of concept study.

The goal of this study was to investigate the performance of 3D synchrotron differential phase contrast (DPC) imaging for the visualization of both macroscopic and microscopic aspects of atherosclerosis in the mouse vasculature ex vivo. The hearts and aortas of 2 atherosclerotic and 2 wild-type control mice were scanned with DPC imaging with an isotropic resolution of 15 μm. The coronary artery vessel walls were segmented in the DPC datasets to assess their thickness, and histological staining was performed at the level of atherosclerotic plaques. The DPC imaging allowed for the visualization of complex structures such as the coronary arteries and their branches, the thin fibrous cap of atherosclerotic plaques as well as the chordae tendineae. The coronary vessel wall thickness ranged from 37.4 ± 5.6 μm in proximal coronary arteries to 13.6 ± 3.3 μm in distal branches. No consistent differences in coronary vessel wall thickness were detected between the wild-type and atherosclerotic hearts in this proof-of-concept study, although the standard deviation in the atherosclerotic mice was higher in most segments, consistent with the observation of occasional focal vessel wall thickening. Overall, DPC imaging of the cardiovascular system of the mice allowed for a simultaneous detailed 3D morphological assessment of both large structures and microscopic details.

A mouse peritonitis model for the study of glycopeptide efficacy in GISA infections

In recent years, the emergence of Staphylococcus aureus strains with reduced susceptibility to glycopeptides has raised considerable concern. We studied the efficacy of vancomycin and teicoplanin, as well as cloxacillin and cefotaxime, against the infection caused by four S. aureus strains with different glycopeptide and β-lactam susceptibilities (strains A, B, C, and D; MICs for vancomycin of 1, 2, 4, and 8 µg/ml respectively), using a modified model of mouse peritonitis. This optimized model appeared to be straightforward and reproducible, and was able to detect low differences in bacterial killing between antibiotics and also between different S. aureus strains. Bactericidal activities in peritoneal fluid for vancomycin, teicoplanin, cloxacillin, and cefotaxime decreased from -2.98, -2.36, -3.22, and -3.57 log10 cfu/ml, respectively, in infection by strain A (MICs for vancomycin and cloxacillin of 1 and 0.38 µg/ml, respectively) to -1.22, -0.65, -1.04, and +0.24 in peritonitis due to strain D (MICs for vancomycin and cloxacillin of 8 and 1,024 µg/ml). Our data confirm the superiority of β-lactams against methicillin-susceptible S. aureus and show that bactericidal activity of glycopeptides decreases significantly with slight increases in MICs; this finding suggests a reduced efficacy of glycopeptides in the treatment of serious glycopeptide-intermediate S. aureus infections

A mouse peritonitis model for the study of glycopeptide efficacy in GISA infections

In recent years, the emergence of Staphylococcus aureus strains with reduced susceptibility to glycopeptides has raised considerable concern. We studied the efficacy of vancomycin and teicoplanin, as well as cloxacillin and cefotaxime, against the infection caused by four S. aureus strains with different glycopeptide and β-lactam susceptibilities (strains A, B, C, and D; MICs for vancomycin of 1, 2, 4, and 8 µg/ml respectively), using a modified model of mouse peritonitis. This optimized model appeared to be straightforward and reproducible, and was able to detect low differences in bacterial killing between antibiotics and also between different S. aureus strains. Bactericidal activities in peritoneal fluid for vancomycin, teicoplanin, cloxacillin, and cefotaxime decreased from -2.98, -2.36, -3.22, and -3.57 log10 cfu/ml, respectively, in infection by strain A (MICs for vancomycin and cloxacillin of 1 and 0.38 µg/ml, respectively) to -1.22, -0.65, -1.04, and +0.24 in peritonitis due to strain D (MICs for vancomycin and cloxacillin of 8 and 1,024 µg/ml). Our data confirm the superiority of β-lactams against methicillin-susceptible S. aureus and show that bactericidal activity of glycopeptides decreases significantly with slight increases in MICs; this finding suggests a reduced efficacy of glycopeptides in the treatment of serious glycopeptide-intermediate S. aureus infections

Micrornas involvement in cortical plasticity in adult mouse barrel cortex

In rodents, sensory experience alters the whisker representation in layer IV of the barrel cortex (Woolsey and Van der Loos, 1970). Excitatory and inhibitory interneurons, together with the astrocytic network, modify the functional representation in an integrated manner. Our group showed that continuous whisker stimulation induces structural and functional changes in the corresponding barrel. These modifications include the depression of neuronal responses and an insertion of new inhibitory synapses on dendritic spines (Knott et al., 2002; Genoud et al., 2006; Quairiaux et al., 2007). This form of cortical plasticity is controlled by several gene regulatory mechanisms including the activation of genetic programs controlling the expression of microRNAs (miRNAs). The transitory and localized expression of miRNAs in dendrites and their capacity to respond in an activity-dependent manner make them ideal candidates for the fine tuning of gene expression associated with neural plasticity. In a previous study of our group (Johnston- Wenger, 2010) using microarray analysis on laser-dissected barrels in order to compare the gene expression levels in stimulated and non-stimulated barrels after whisker stimulation, 261 genes were found significantly regulated, among these genes there were two miRNAs (miR- 132 and miR-137). In this study I tested the initial observation on the up-regulation of miR-132 and miR-137 after whisker stimulation and the possible involvement of two other miRNAs (miR-138 and miR-125b) that are known play a role in other form of synaptic plasticity. I used in situ hybridization (ISH) after unilateral stimulation of three whiskers (Cl-3) in the adult mouse. We found that sensory stimulation increases the expression, of miR-132 after 3hours of stimulation (p<0.01) and miR-137 (pO.Ol; 24 hrs of stim.), whereas it reduces the level of miR-125b (pO.Ol; 9 hrs of stim.). No significant difference was detected for miR-138. We further determined a correlation between the level of expression of the four selected miRNAs in the cortical barrels (measured by ISH) and in blood plasma (measured by qPCR). In addition to this quantitative comparison, we combined miRNAs ISH and immunolabeling for various neuronal markers that were chosen for the localization in both excitatory and inhibitory circuits as well as in astrocytes. Analysis of three-dimensional confocal acquisitions showed that stimulation alters significantly the degree of co-localization in the stimulated barrel of miR-132 with GAD65/67 and VGLUT2; miR-125b with GAD65/67 and parvalbumin; miR-138 with parvalbumin, VGLUT1 and PSD95; and miR-137 with VGLUT1 and astrocytic markers (GS; GFAP and SlOOß). To conclude, using increased neuronal activity in the whisker-to-barrel pathway; our results suggest that miRNAs can be regulated in an activity-dependent manner and they may regulate local mRNA translation to shape neuronal responses. These findings motivate further investigation of the different modes in which miRNAs may regulate cortical plasticity. -- Chez les rongeurs, l'expérience sensorielle modifie la représentation des vibrisses au niveau du cortex somatosensoriel primaire (Woolsey and Van der Loos, 1970). Les interneurones excitateurs et inhibiteurs, en collaboration avec le réseau astrocytaire, modifient la représentation fonctionnelle d'une manière intégrée. Notre groupe a montré que la stimulation continue des vibrisses induit des changements structuraux et fonctionnels dans le tonneau correspondant. Ces modifications incluent la dépression des réponses neuronales et une insertion de nouvelles synapses inhibitrices sur les épines dendritiques (Knott et al., 2002 ; Genoud et al., 2006 ; Quairiaux et al., 2007). Cette forme de plasticité corticale est contrôlée par plusieurs mécanismes de régulation génique dont l'activation des programmes géniques contrôlant l'expression des microARNs (miARNs). Par leur expression transitoire et localisée dans les dendrites et leur capacité à réagir d'une manière dépendante de l'activité, les miARNs sont des candidats idéaux pour le réglage fin de l'expression des gènes associée à la plasticité neuronale. Afin de comparer le niveau d'expression des gènes dans les tonneaux stimulés et non-stimulés après stimulation des vibrisses, une étude antérieure dans notre groupe (Johnston-Wenger, 2010), utilisant l'analyse par microarray sur des tonneaux disséqués par laser, a montré l'altération significative de 261 gènes. Parmi ces gènes, il y avait deux miARNs (miR-132 et miR-137). Dans la présente étude, j'ai testé l'observation initiale sur la régulation de miR-132 et miR-137 après stimulation des vibrisses et la possible implication de deux autres miARNs (miR-138 et miR-125b) connus avoir jouer un rôle important dans d'autres formes de plasticité synaptique. J'ai utilisé l'hybridation in situ (ISH) après stimulation unilatérale de trois vibrisses (Cl-3) chez la souris adulte. J'ai trouvé que la stimulation sensorielle augmente l'expression, de miR-132 après 3 heures de stimulation (p < 0.01) et miR-137 (p < 0.01 ; 24 hrs de stim.), alors qu'elle réduit le niveau de miR-125b (p < 0.01; 9 hrs de stim.). Aucune différence significative n'a été détectée pour miR-138. J'ai aussi déterminé une corrélation entre le niveau d'expression des quatre miARNs sélectionnés dans les tonneaux (mesurés par ISH) et dans le plasma sanguin (mesuré par qPCR). En plus de cette comparaison quantitative, j'ai combiné le miR-ISH et l'immunomarquage pour divers marqueurs neuronaux qui ont été choisis pour étudier la localisation dans les circuits excitateurs et inhibiteurs, ainsi que dans les astrocytes. Les acquisitions tridimensionnelles montrent que la stimulation modifie considérablement le degré de co-localisation dans le tonneau stimulé de miR-132 avec GAD65/67 et VGLUT2; miR-125b avec GAD65/67 et parvalbumine; miR-138 avec parvalbumine, VGLUT1 et PSD95; et miR-137 avec VGLUT1 et les marqueurs astrocytaires (GS ; GFAP et SlOOß). En conclusion, à l'aide de l'activité neuronale accrue dans la voie de vibrisses-au-baril; les résultats suggèrent que les miARNs peuvent être régulé d'une manière dépendante de l'activité et peuvent résulter la stabilité des ARNm et la traduction pour façonner les réponses neuronales ultérieures. Ces résultats incitent d'investiguer davantage les voies importantes par lesquels les miARNs peuvent réguler la plasticité corticale.

STRATEGIC-1: A multiple-lines, randomized, open-label GERCOR phase III study in patients with unresectable wild-type RAS metastatic colorectal cancer.

BACKGROUND: The management of unresectable metastatic colorectal cancer (mCRC) is a comprehensive treatment strategy involving several lines of therapy, maintenance, salvage surgery, and treatment-free intervals. Besides chemotherapy (fluoropyrimidine, oxaliplatin, irinotecan), molecular-targeted agents such as anti-angiogenic agents (bevacizumab, aflibercept, regorafenib) and anti-epidermal growth factor receptor agents (cetuximab, panitumumab) have become available. Ultimately, given the increasing cost of new active compounds, new strategy trials are needed to define the optimal use and the best sequencing of these agents. Such new clinical trials require alternative endpoints that can capture the effect of several treatment lines and be measured earlier than overall survival to help shorten the duration and reduce the size and cost of trials. METHODS/DESIGN: STRATEGIC-1 is an international, open-label, randomized, multicenter phase III trial designed to determine an optimally personalized treatment sequence of the available treatment modalities in patients with unresectable RAS wild-type mCRC. Two standard treatment strategies are compared: first-line FOLFIRI-cetuximab, followed by oxaliplatin-based second-line chemotherapy with bevacizumab (Arm A) vs. first-line OPTIMOX-bevacizumab, followed by irinotecan-based second-line chemotherapy with bevacizumab, and by an anti-epidermal growth factor receptor monoclonal antibody with or without irinotecan as third-line treatment (Arm B). The primary endpoint is duration of disease control. A total of 500 patients will be randomized in a 1:1 ratio to one of the two treatment strategies. DISCUSSION: The STRATEGIC-1 trial is designed to give global information on the therapeutic sequences in patients with unresectable RAS wild-type mCRC that in turn is likely to have a significant impact on the management of this patient population. The trial is open for inclusion since August 2013. TRIAL REGISTRATION: STRATEGIC-1 is registered at Clinicaltrials.gov: NCT01910610, 23 July, 2013. STRATEGIC-1 is registered at EudraCT-No.: 2013-001928-19, 25 April, 2013.

Dendritic Spine Abnormalities in Hippocampal CA1 Pyramidal Neurons Underlying Memory Deficits in the SAMP8 Mouse Model of Alzheimer's Disease

SAMP8 is a strain of mice with accelerated senescence. These mice have recently been the focus of attention as they show several alterations that have also been described in Alzheimer"s disease (AD) patients. The number of dendritic spines, spine plasticity, and morphology are basic to memory formation. In AD, the density of dendritic spines is severely decreased. We studied memory alterations using the object recognition test. We measured levels of synaptophysin as a marker of neurotransmission and used Golgi staining to quantify and characterize the number and morphology of dendritic spines in SAMP8 mice and in SAMR1 as control animals. While there were no memory differences at 3 months of age, the memory of both 6- and 9-month-old SAMP8 mice was impaired in comparison with age-matched SAMR1 mice or young SAMP8 mice. In addition, synaptophysin levels were not altered in young SAMP8 animals, but SAMP8 aged 6 and 9 months had less synaptophysin than SAMR1 controls and also less than 3-month-old SAMP8 mice. Moreover, while spine density remained stable with age in SAMR1 mice, the number of spines started to decrease in SAMP8 animals at 6 months, only to get worse at 9 months. Our results show that from 6 months onwards SAMP8 mice show impaired memory. This age coincides with that at which the levels of synaptophysin and spine density decrease. Thus, we conclude that together with other studies that describe several alterations at similar ages, SAMP8 mice are a very suitable model for studying AD.

Developmental expression of the oligodendrocyte myelin glycoprotein in the mouse telencephalon

The oligodendrocyte myelin glycoprotein is a glycosylphosphatidylinositol-anchored protein expressed by neurons and oligodendrocytes in the CNS. Attempts have been made to identify the functions of the myelin-associated inhibitory proteins (MAIPs) after axonal lesion or in neurodegeneration. However, the developmental roles of some of these proteins and their receptors remain elusive. Recent studies indicate that NgR1 and the recently discovered receptor PirB restrict cortical synaptic plasticity. However, the putative factors that trigger these effects are unknown. Since Nogo-A is mostly associated with the endoplasmic reticulum and MAG appears late during development, the putative participation of OMgp should be considered. Here we examine the pattern of development of OMgp immunoreactive elements during mouse telencephalic development. OMgp immunoreactivity in the developing cortex follows the establishment of the thalamo-cortical barrel-field. At cellular level, we located OMgp neuronal membranes in dendrites and axons as well as in brain synaptosome fractions and axon varicosities. Lastly, the analysis of the barrel-field in OMgp-deficient mice revealed that although thalamo-cortical connections were formed, their targeting in layer IV was altered and numerous axons ectopically invaded layer II-III. Our data support the idea that early-expressed MAIPs play an active role during development and point to OMgp participating in thalamo-cortical connections.

N-acetylcysteine treatment ameliorates the skeletal phenotype of a mouse model of diastrophic dysplasia.

Diastrophic dysplasia (DTD) is a recessive chondrodysplasia caused by mutations in SLC26A2, a cell membrane sulfate-chloride antiporter. Sulfate uptake impairment results in low cytosolic sulfate, leading to cartilage proteoglycan (PG) undersulfation. In this work, we used the dtd mouse model to study the role of N-acetyl-l-cysteine (NAC), a well-known drug with antioxidant properties, as an intracellular sulfate source for macromolecular sulfation. Because of the important pre-natal phase of skeletal development and growth, we administered 30 g/l NAC in the drinking water to pregnant mice to explore a possible transplacental effect on the fetuses. When cartilage PG sulfation was evaluated by high-performance liquid chromatography disaccharide analysis in dtd newborn mice, a marked increase in PG sulfation was observed in newborns from NAC-treated pregnancies when compared with the placebo group. Morphometric studies of the femur, tibia and ilium after skeletal staining with alcian blue and alizarin red indicated a partial rescue of abnormal bone morphology in dtd newborns from treated females, compared with pups from untreated females. The beneficial effect of increased macromolecular sulfation was confirmed by chondrocyte proliferation studies in cryosections of the tibial epiphysis by proliferating cell nuclear antigen immunohistochemistry: the percentage of proliferating cells, significantly reduced in the placebo group, reached normal values in dtd newborns from NAC-treated females. In conclusion, NAC is a useful source of sulfate for macromolecular sulfation in vivo when extracellular sulfate supply is reduced, confirming the potential of therapeutic approaches with thiol compounds to improve skeletal deformity and short stature in human DTD and related disorders.

Contribution of estrogen and GluN2B subunit to the HtraKO mouse phenotype

Htr1a is one of the most widespread serotonin receptor across the brain, strongly expressed in CAI region of hippocampus. Our laboratory studies the phenotypic alteration in 5HTla- deficient mice (Htr1aK0), characterized an abnormal anxious-like behavior. Our aim is to evaluate the regulation of this cognitive process by understanding the circuitry involved. This phenotype sets up early during development and has durable effect in adulthood. Our laboratory showed that adult Htr1aK0 male mice displaying exuberant dendritic growth of oblique dendrites in a specific layer of a CAI pyramidal neurons, the stratum radiatum. Application of drugs in organotypic cultures and by in vivo injections revealed that GluN2B, a subunit of NMDA receptor highly expressed during development, is responsible for this dendritic exuberance. Immunohistochemistry highlighted in particular a synaptic enrichment of GluN2B in stratum radiatum of Htr1aK0 CAI pyramidal neurons at puberty. Finally, original analysis of Htr1aK0 mouse behavior showed a different response to anxiety between male and female. Htr1a activation down-regulates the CaMKII activity in the CAI pyramidal neurons. CaMKII directly favors the membrane conductance and stability of GluN2B at the synapse. In the context of the Htr1aK0 mouse, GluN2B is the final common pathway of our phenotype. This subunit is well known to regulate the threshold of LTD/LTP and the dendritogenesis during development. In my thesis, I establish a link between the gender differences in the morphology and the physiology in the Htr1aK0 mice during development to understand how these characteristics shape the circuit with prominent cognitive impacts in adulthood. My study highlighted that during development, Htr1aK0 male mice show a constant increase of the dendritic growth of oblique dendrites from early ages until adulthood associated with an increased physiological impact of altered GluN2A/GluN2B ratio. Whereas during puberty, synaptic contribution of GluN2B to NMDA response is higher in Htr1aK0 compared to WT male mice, this ratio comes back to normal values towards adulthood. However, this recovery of the ratio of GluN2A/GluN2B located at the synaptic level is concomitant with the lateral diffusion of excess GluN2B subunits, leading to extrasynaptic enrichment. The main impact was a lowering of the LTP threshold characterized by strong increased potentiation of synaptic strength after 5 Hz low frequency stimulation. Moreover, the extrasynaptic GluN2B overexpression leads to a shift of the maturation phase switch explaining the exuberant morphology. However, Htr1aK0 females characterized during the 3 first weeks of development by an increase of the dendritic growth of oblique dendrites showed starting at puberty that the dendrite arborization returns progressively to WT values. The physiological impact of GluN2B was investigated and directly linked to this morphology, since Htr1aK0 female mice does not show alteration of the synaptic strength during development. These observations show a compensation occurring in Htr1aK0 female, responsible for a rescue of the phenotype morphologically, physiologically and to be tested behaviorally. We highlighted then the biological processes underlying this compensation. During development, sexual hormones such as testosterone and estrogen are responsible to induce sexual differentiation of specific brain regions. I demonstrated that estrogen, but not testosterone, was able to reduce both in vitro and in vivo the dendritic arborization early during development, through activation of GPER-1, a G-coupled protein estrogen receptor, which phenocopy the activation of Htr1a by reducing GluN2B conductance and stability. I then identified a pathway, parallel to Htr1a, able to regulate GluN2B and responsible for the morphological and physiological phenotype in Htr1aK0 female mice. The specific rise of estrogen occurring at puberty in female is responsible for the compensation observed and induces a late rescue of the Htr1aK0 phenotype by activation GPER-1. -- Htr1a est un des récepteurs à la sérotonine les plus répandus dans le cerveau, fortement exprimé dans la région CAI de l'hippocampe. Notre laboratoire étudie les altérations phénotypiques de souris déficientes pour ce récepteur (Htr1aK0), caractérisées par un comportement avec des traits anxieux. Notre objectif est d'évaluer la régulation de ces processus cognitifs en comprenant les connexions nerveuses impliquées. Ce phénotype se met en place tôt au cours du développement et présente un effet durable à l'âge adulte. Notre laboratoire a montré que les souris Htr1aK0 mâles adultes se caractérisent par une croissance exubérante des dendrites obliques dans une couche spécifique des neurones pyramidaux du CAI, le stratum radiatum. L'application de drogues sur cultures organotypiques et par injections in vivo ont révélé que GluN2B, une sous-unité du récepteur NMDA fortement exprimée au cours du développement, est responsable de cette exubérance dendritique. Des expériences d'immunohistochimie ont notamment mis en évidence un enrichissement synaptique de GluN2B durant la puberté dans le stratum radiatum des neurones de la région CAI des souris Htr1aK0. Finalement, l'analyse originale du comportement des souris Htr1aK0 a montré une différence de réponse à l'anxiété entre mâles et femelles. L'activation de Htr1a diminue l'activité de la CaMKII dans les neurones pyramidaux du CAI. La CaMKII favorise directement la conductance et la stabilité de la sous-unité GluN2B à la synapse. Dans le contexte de la souris Htr1aK0, GluN2B est le « médiateur » de notre phénotype. Cette sous-unité est particulièrement connue pour réguler le seuil de LTD-LTP ainsi que la dendritogénèse durant le développement. Dans ma thèse, j'ai établi le lien entre les différences dépendant du genre dans la morphologie et physiologie des souris Htr1aK0 au cours du développement pour comprendre comment ces caractéristiques modulent le circuit accompagnés d'impacts cognitifs visibles à l'âge adulte. Mon étude a mis en évidence que durant le développement, les souris mâles Htr1aK0 montrent une constante augmentation de la croissance des dendrites obliques entre les premières semaines et l'âge adulte associée à une augmentation de l'impact physiologique du ratio GluN2A/GluN2B altéré. Alors que durant la puberté, la contribution synaptique de GluN2B à la réponse NMDA est plus haute chez la souris mâle Htr1aK0 que le WT, ce ratio revient à des valeurs normales à l'âge adulte. Cependant, cette récupération de l'expression du récepteur au niveau synaptique est concomitante avec la diffusion des sous-unités GluN2B excédantes, amenant alors à un enrichissement extrasynaptique. Le principal impact est une diminution du seuil de la LTP caractérisée par une forte potentiation de la plasticité après une stimulation basse fréquence à 5 Hz. De plus, la surexpression des GluN2B extrasynaptiques conduit à un décalage de la bascule à la phase de maturation, expliquant la morphologie dendritique exubérante. Cependant, les femelles Htr1aK0 initialement caractérisées pendant les 3 premières semaines du développement par une augmentation de la croissance des dendrites obliques montrent à partir de la puberté que cette arborisation dendritique retourne à des valeurs WT. L'impact physiologique de GLuN2B a été investigué et mis en lien avec cette morphologie, étant donné que les femelles Htr1aK0 ne montrent pas d'altération de la plasticité durant le développement. Ces observations montrent une compensation se produisant chez la femelle Htr1aK0, responsable d'une récupération du phénotype morphologique, physiologique et peut-être comportemental. Nous avons souligné les processus biologiques sous-jacent à cette compensation. Au cours du développement, les hormones sexuelles telles que la testostérone et l'estrogène sont responsables de la différentiation sexuelle de régions du cerveau spécifiques. J'ai démontré que l'estrogène, mais pas la testostérone, était capable de réduire in vitro et in vivo l'arborisation dendritique tôt dans le développement au travers de l'activation du récepteur GPER-1, un récepteur aux estrogènes couplés à un protéine G, qui phénocopie l'activation de Htr1a en réduisant la conductance et la stabilité de GluN2B à la membrane. J'ai identifié une voie de signalisation parallèle à celle de Htr1a, capable de réguler GluN2B et responsable du phénotype morphologique et physiologique de la souris femelle Htr1aK0. La montée spécifique d'estrogène se déroulant à la puberté chez la femelle est responsable de cette compensation et implique une récupération tardive du phénotype Htr1aK0 par l'activation de GPER-1.