Absence of MHC-II expression by lymph node stromal cells results in autoimmunity.

How lymph node stromal cells (LNSCs) shape peripheral T-cell responses remains unclear. We have previously demonstrated that murine LNSCs, lymphatic endothelial cells (LECs), blood endothelial cells (BECs), and fibroblastic reticular cells (FRCs) use the IFN-γ-inducible promoter IV (pIV) of the MHC class II (MHCII) transactivator CIITA to express MHCII. Here, we show that aging mice (>1 yr old) in which MHCII is abrogated in LNSCs by the selective deletion of pIV exhibit a significant T-cell dysregulation in LNs, including defective Treg and increased effector CD4 <sup>+</sup> and CD8 <sup>+</sup> T-cell frequencies, resulting in enhanced peripheral organ T-cell infiltration and autoantibody production. The proliferation of LN-Tregs interacting with LECs increases following MHCII up-regulation by LECs upon aging or after exposure to IFN-γ, this effect being abolished in mice in which LECs lack MHCII. Overall, our work underpins the importance of LNSCs, particularly LECs, in supporting Tregs and T-cell tolerance

Central nervous system and immune system regulation in stress condition : role of corticoprin-releasing hormone ans its receptors

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 systèmesIn 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 system

Régulations des systèmes nerveux central et immunitaire en condition de stress : rôle de la corticotropin-releasing hormone et de ses récepteurs

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 systemsLors 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 système

Effects of corticosterone injections in mid-to-late mouse postnatal development on adult motor activity and coordination

International audienceGlucocorticoids are involved in the developing brain but, in excessive amounts, may depress its growth and cause psychomotor development disorders. To test the long-term vulnerability of motor structures such as the cerebellum to supraphysiological corticosterone (CORT), the hormone was subcutaneously delivered at a dose of 20 mg/kg from postnatal day (P) 8 to P29 in C57BL/6 male mice evaluated for sensorimotor functions at P15, P22, P29, and 3 months. Relative to placebo, CORT increased motor activity in the open-field at P29 and 3 months as well as facilitating rotorod acquisition and visuomotor control necessary for swimming towards a visible goal without affecting spatial learning in the Morris water maze. CORT caused lobulespecific effects on cerebellar morphology by decreasing granule cell layer thickness in simplex lobule but increasing molecular and granule cell layer thickness in crus 2. The functional impact of these changes is indicated by significant correlations found between cerebellar size and activity levels or proficiency on the rotorod test of motor coordination

Lymph Node Stromal Cells: Mapmakers of T Cell Immunity

Stromal cells (SCs) are strategically positioned in both lymphoid and nonlymphoid organs to provide a scaffold and orchestrate immunity by modulating immune cell maturation, migration and activation. Recent characterizations of SCs have expanded our understanding of their heterogeneity and suggested a functional specialization of distinct SC subsets, further modulated by the microenvironment. Lymph node SCs (LNSCs) have been shown to be particularly important in maintaining immune homeostasis and T cell tolerance. Under inflammation situations, such as viral infections or tumor development, SCs undergo profound changes in their numbers and phenotype and play important roles in contributing to either the activation or the control of T cell immunity. In this review, we highlight the role of SCs located in LNs in shaping peripheral T cell responses in different immune contexts, such as autoimmunity, viral and cancer immunity

Tumor-associated macrophages: Shifting bad prognosis to improved efficacy in cancer therapies?

Macrophages are innate immune cells that play an important role in the response to damaged tissue and pathogenic infection. During activation, signals from the local environment induce macrophage polarization towards either the classical pro-inflammatory phenotype (M1) or towards the alternative anti-inflammatory phenotype (M2). In cancer, M2 tumor-associated macrophages (TAMs) are associated with a poor prognosis. Notably, the Tumor Microenvironment (TME) is known to promote the M2 phenotype by dampening anti-tumor immune responses and thus promoting tumoral growth. Recent studies have demonstrated that TAMs play a major role in cancer cells resistance to chemo- and radiotherapies leading to ineffective treatment strategies. This raises the importance of including macrophage targeting strategies, either to dampen their activities or to re-educate them toward pro-inflammatory phenotype, to improve the efficiency of current and future treatments. Therefore, this mini-review aims to highlight recent discoveries demonstrating how macrophages induce cancer resistance to therapies and how re-educated TAMs could be used to improve treatment outcomes.</p

Murine splenic B cells express corticotropin-releasing hormone receptor 2 that affect their viability during a stress response

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Emerging roles of DDB2 in cancer

International audienceDamage-specific DNA-binding protein 2 (DDB2) was originally identified as a DNA damage recognition factor that facilitates global genomic nucleotide excision repair (GG-NER) in human cells. DDB2 also contributes to other essential biological processes such as chromatin remodeling, gene transcription, cell cycle regulation, and protein decay. Recently, the potential of DDB2 in the development and progression of various cancers has been described. DDB2 activity occurs at several stages of carcinogenesis including cancer cell proliferation, survival, epithelial to mesenchymal transition, migration and invasion, angiogenesis, and cancer stem cell formation. In this review, we focus on the current state of scientific knowledge regarding DDB2 biological effects in tumor development and the underlying molecular mechanisms. We also provide insights into the clinical consequences of DDB2 activity in cancers

Repeated corticosterone injections in adult mice alter stress hormonal receptor expression in the cerebellum and motor coordination without affecting spatial learning

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