Global ETD Search

31	In Vitro and In Vivo Studies with Measles Virus and its Interaction with the Mouse Innate Immune System Ha, Michael Neul 21 August 2012 (has links) Measles is one of the most contagious diseases known to mankind. Despite the availability of a safe and effective vaccine, approximately 164,000 measles-related deaths were recorded in 2008. The inherent restricted host tropism of MV means that the development of authentic rodent models will be a valuable research tool in testing new vaccines and antivirals. In addition to the receptor requirement, mouse innate immunity has been shown to inhibit MV growth. In this thesis, the contributions of several key components of the mouse innate immune system on the inhibition of MV replication were examined. The transcription factor interferon regulatory factor 3 (IRF3), which normally plays a key role in mediating innate immune signaling, contributed relatively little in inhibiting MV replication both in vitro and in vivo. In contrast, the JAK/STAT pathway and the double-stranded RNA inducible protein kinase, PKR, played more important roles in controlling virus replication. The resurgence of measles in areas where the virus was once thought to be eradicated makes the development of anti-MV treatments essential. Concurrent to the development of an animal model to better study its pathogenesis, we wanted to look at the effect of MV inhibitors on its replication. The MV fusion inhibitor, carbobenzoxy-D-phenylalanine-L-phenylalanine-glycine (ZfFG), was developed in the past to study fusion; however, its mechanism of action has not yet been elucidated. To examine this, spontaneous ZfFG-resistant mutants were generated and characterized. Mutations were found in the HRB region of the fusion (F) protein, and when these were modeled using published paramyxovirus F crystal structures, data suggested that ZfFG targeted a small pocket present between the head and stalk regions of its pre-fusion conformation. An authentic mouse model of measles developed from findings in this study may allow for in vivo efficacy testing of ZfFG in the future. molecular biology virology paramyxovirus measles innate immunity mouse models transgenic mouse fusion fusion inhibitor FIP IRF3 microbiology ZfFG plasmacytoid dendritic cell mouse embryonic fibroblast receptor 0720
32	In Vitro and In Vivo Studies with Measles Virus and its Interaction with the Mouse Innate Immune System Ha, Michael Neul 21 August 2012 (has links) Measles is one of the most contagious diseases known to mankind. Despite the availability of a safe and effective vaccine, approximately 164,000 measles-related deaths were recorded in 2008. The inherent restricted host tropism of MV means that the development of authentic rodent models will be a valuable research tool in testing new vaccines and antivirals. In addition to the receptor requirement, mouse innate immunity has been shown to inhibit MV growth. In this thesis, the contributions of several key components of the mouse innate immune system on the inhibition of MV replication were examined. The transcription factor interferon regulatory factor 3 (IRF3), which normally plays a key role in mediating innate immune signaling, contributed relatively little in inhibiting MV replication both in vitro and in vivo. In contrast, the JAK/STAT pathway and the double-stranded RNA inducible protein kinase, PKR, played more important roles in controlling virus replication. The resurgence of measles in areas where the virus was once thought to be eradicated makes the development of anti-MV treatments essential. Concurrent to the development of an animal model to better study its pathogenesis, we wanted to look at the effect of MV inhibitors on its replication. The MV fusion inhibitor, carbobenzoxy-D-phenylalanine-L-phenylalanine-glycine (ZfFG), was developed in the past to study fusion; however, its mechanism of action has not yet been elucidated. To examine this, spontaneous ZfFG-resistant mutants were generated and characterized. Mutations were found in the HRB region of the fusion (F) protein, and when these were modeled using published paramyxovirus F crystal structures, data suggested that ZfFG targeted a small pocket present between the head and stalk regions of its pre-fusion conformation. An authentic mouse model of measles developed from findings in this study may allow for in vivo efficacy testing of ZfFG in the future. molecular biology virology paramyxovirus measles innate immunity mouse models transgenic mouse fusion fusion inhibitor FIP IRF3 microbiology ZfFG plasmacytoid dendritic cell mouse embryonic fibroblast receptor 0720
33	The Dox-pDC - A murine conditionally immortalized plasmacytoid dendritic cell line with native immune profile Thieme, Sebastian, Holzbaur, Alexander, Wiedemuth, Ralf, Binner, Aline, Navratiel, Katrin, Anastassiadis, Konstantinos, Brenner, Sebastian, Richter, Cornelia 11 June 2018 (has links) (PDF) Plasmacytoid dendritic cells (pDC) constitute a very rare blood cell population and play a significant role in immune response and immune-mediated disorders. Investigations on primary pDCs are hindered not only due to their rarity but also because they represent a heterogeneous cell population which is difficult to culture ex vivo. We generated a conditionally immortalized pDC line (Dox-pDC) from mice with Doxycycline-inducible SV40 Large T Antigen with a comparable immune profile to primary pDCs. The Dox-pDC secrete pro- and anti-inflammatory cytokines upon Toll-like receptor 9 stimulation and upregulate their MHCI, MHCII and costimulatory molecules. Further, the Dox-pDC activate and polarize naïve T cells in vivo and in vitro in response to the model antigen Ovalbumin. Due to their long-term culture stability and their robust proliferation Dox-pDC represent a reliable alternative to primary mouse pDC. Plasmazytoide dendritische Zellen Blutzellpopulation TU Dresden Publikationsfonds Plasmacytoid dendritic cells blood cell population TU Dresden Publishing Fund ddc:610 rvk:XA 10000
34	Contribution du foie et des cellules dendritiques plasmacytoïdes dans la réponse humorale à Immunoglobines A / Contribution of the liver and plasmacytoid dendritic cells in IgA humoral response Moro-Sibilot, Ludovic 05 November 2015 (has links) La réponse humorale à immunoglobulines A (IgA) constitue un des principaux mécanismes immunologiques permettant de maintenir l'homéostasie intestinale. L'initiation de la réponse IgA se déroule dans les tissus lymphoides associés à l'intestin, où la reconnaissance des antigènes intestinaux entraine l'activation des lymphocytes B naïfs, la commutation isotypique vers IgA et leur différenciation en plasmocytes. Mon travail de thèse a consisté à étudier la contribution du foie et des cellules dendritiques plasmacytoides (pDC) dans la réponse IgA intestinale. L'utilisation de deux modèles murins permettant la déplétion sélective des pDC nous a permis de démontrer que, en dépit de données publiées montrant leur capacité à engager la réponse IgA in vitro, les pDC ne sont pas nécessaires in vivo pour l'induction ou le maintien de la réponse IgA homéostatique. Nous montrons ensuite que le foie abrite une population importante de plasmocytes à IgA. Chez la souris, nous montrons que ces cellules possèdent des caractéristiques phénotypiques distinctes des plasmocytes de l'intestin et proviennent de lymphocytes B récemment activés dans les plaques de Peyer. A l'homéostasie, ces plasmocytes hépatiques secrètent des IgA dirigées contre les bactéries de la flore intestinale. Enfin, dans un modèle murin de consommation chronique d'alcool, nous montrons une corrélation entre une augmentation de cette population cellulaire, une élévation sérique des IgA et des dépôts d'IgA hépatiques, deux désordres fréquemment observés chez les patients atteints d hépatopathies alcooliques. Nos données indiquent donc que le foie constitue un site effecteur alternatif de la réponse / IgA humoral response is one of the main mechanisms by which immune homeostasis is maintained in the intestine. The IgA response is initiated in gut-associated lymphoid tissues, where recognition of intestinal antigens drives naïve B cell activation, IgA class-switch recombination and plasma cell differentiation. My thesis work addressed the contribution of the liver and plasmacytoid dendritic cells (pDCs) in intestinal IgA response. By using two complementary mouse models allowing for selective depletion of pDCs, we have demonstrated that, in contrast to published work showing their ability to drive IgA response in vitro, pDCs are dispensable in vivo for the induction and the maintenance of homeostatic intestinal IgA responses.Then, we showed that the liver contains an important population of IgA plasma cells. In mice, we demonstrated that these cells harbor distinct phenotypic characteristics in comparison to intestinal IgA plasma cells, and are derived from B cells recently activated in Peyer’s patches. At homeostasis, hepatic IgA plasma cells secrete IgA directed against bacteria from intestinal flora. Finally, in a mouse model of chronic ethanol consumption, we found a correlation between an increase in hepatic igA plasma cell population, elevation of serum iGA and IgA deposits in liver sinusoids, two disorders frequently observed in alcoholic liver disease patients. Thus, our results indicate that the liver constitutes an alternative effector site for IgA response initiated in the intestine IgA Foie Cellules dendritiques plasmacytoïdes Plasmocytes Homéostasie intestinale Immunisation orale IgA Liver Plasmacytoid dendritic cells Plasma cells Intestinal homeostasis Oral immunization 571.96
35	Régulation de la survie des cellules dendritiques plasmacytoïdes dans un contexte inflammatoire non viral / Regulation of plasmacytoid dentritic cells survival in a non viral inflammatory context Mossu, Adrien 28 October 2015 (has links) Les cellules dendritiques plasmacytoïdes (pDC) sont spécialisées dans la lutte antivirale, notamment grâce à leur capacité à sécréter des IFN de type I. Néanmoins, elles sont aussi impliquées dans Pactivation des réponses immunitaires adaptatives, et des lymphocytes T (LT) en particulier. C'est pourquoi, lors d'épisodes inflammatoires chroniques ou incontrôlés, les pDC sont à l'origine de l'initiation ou du maintien de syndromes inflammatoires et du développement de pathologies auto-immunes. Il doit donc exister des mécanismes permettant de contrôler l'activité de ces cellules. À l'aide d'un modèle in vivo d'inflammation non virale induite par l'injection d'un anticorps anti-CD3 (Ac aCD3), nous avons observé une apoptose des pDC dans différents organes lymphoïdes, et ce de façon dépendante de l'activation des lymphocytes T. De plus, nous avons pu observer que la diminution de la survie des pDC dans ce contexte inflammatoire n'était pas associée à l'orage cytokinique induit par l'efièt mitogénique de l'Ac aCD3. En revanche nos résultats montrent que les LT CD8* et la voie cytotoxique de la perforine dans ce contexte inflammatoire aigu sont responsables de la déplétion des pDC. Nous avons également étendu ces résultats à d'autres situations inflammatoires stériles comme lors de la maladie du greffon contre l'hôte. Ces données suggèrent que cette voie de régulation pourrait être utilisée à des fins thérapeutiques, afin de contrôler la survie des pDC impliquées dans la physiopathologie de syndromes auto-immuns comme le lupus érythémateux disséminé, le psoriasis, la sclérose en plaques ou encore le diabète de type I. / Plasmacytoid dendritic cells (pDC) are specialized in type I interferons (IFN-I) secretion to control viral infections. However, these cells can also activate adaptive immune responses, and polarize T cells. Indeed, during chronic or uncontrolled inflammatory episodes, pDC can induce or maintain inflammatory syndromes and autoimmune diseases. So some mechanisms should exist to control the fonction of these cells. In an in vivo modcl of non viral inflammation induced by the injection a CD3-specific antibody (aCD3 Ab), we could observed pDC's apoptosis dependent of T cell activation in different lymphoid organs. Moreover, we could observe that this depletion of pDC was not associated with the cytokinic storm induced by the mitogenic effect after aCD3 Ab treatment. On the other hand our data shovved that CD8+ T cells and the perforin pathway in this acute inflammatory context are responsible for pDC depletion We also obtained the same results in other non viral inflammation settings such as graft versus host disease. Overall, these data suggesi that this regulation pathway could be used for therapeutic purposes, to control pDC survival and avoid their involvement in the physiopathology of autoimmune disorders like systemic lupus erythematosus, psoriasis, multiple sclerosis or type I diabetes. Cellules dendritiques plasmacytoïdes Anticorps anti-CD3 Inflammation Lymphocyte T CD8+ Perforine Plasmacytoid dendritic cells Anti-CD3 antibodies Inflammation T lymphocyte CD8 + Perforin 616
36	The Dox-pDC - A murine conditionally immortalized plasmacytoid dendritic cell line with native immune profile Thieme, Sebastian, Holzbaur, Alexander, Wiedemuth, Ralf, Binner, Aline, Navratiel, Katrin, Anastassiadis, Konstantinos, Brenner, Sebastian, Richter, Cornelia 11 June 2018 (has links) Plasmacytoid dendritic cells (pDC) constitute a very rare blood cell population and play a significant role in immune response and immune-mediated disorders. Investigations on primary pDCs are hindered not only due to their rarity but also because they represent a heterogeneous cell population which is difficult to culture ex vivo. We generated a conditionally immortalized pDC line (Dox-pDC) from mice with Doxycycline-inducible SV40 Large T Antigen with a comparable immune profile to primary pDCs. The Dox-pDC secrete pro- and anti-inflammatory cytokines upon Toll-like receptor 9 stimulation and upregulate their MHCI, MHCII and costimulatory molecules. Further, the Dox-pDC activate and polarize naïve T cells in vivo and in vitro in response to the model antigen Ovalbumin. Due to their long-term culture stability and their robust proliferation Dox-pDC represent a reliable alternative to primary mouse pDC. info:eu-repo/classification/ddc/610 ddc:610
37	Division of Labor Between Distinct Human Plasmacytoid Dendritic Cell Subsets Following Viral Activation / Partage des tâches entre différents sous-populations de cellules dendritiques plasmacytoïdes suite à une activation virale Alculumbre, Solana 07 October 2015 (has links) L’existence d’un partage des tâches a été démontrée au sein de nombreux systèmes biologiques et ce notamment en immunologie où il a été décrit dans le contexte de différentes sous-populations d’un même type cellulaire. Les cellules dendritiques plasmacytoïdes (pDC) jouent un rôle clé lors des infections virales. Les pDCs ont la capacité de sécréter de grandes quantités d’interférons de type I et de se différencier en cellules dendritiques matures capables d’activer une réponse immunitaire adaptative. Il a été proposé que ces fonctions innées et adaptatives soient séquentiellement induites après activation virale. Au cours de ma thèse, je me suis intéressée à ces deux fonctions principales des pDC et je suis arrivée à la description de différentes sous-populations de pDC activées : PD-L1+CD80- (P1), PD-L1+CD80+ (P2) and PD-L1-CD80+ (P3), démontrant qu’il existe un partage des tâches entre ces sous-types. P1 produit spécifiquement de l’IFN-α, indiquant une spécialisation en immunité innée, et promeut une réponse tolérogénique des cellules T CD4. Inversement, P3 induit une forte activation des cellules T CD4 naïves et une polarisation de type Th2, démontrant une spécialisation fonctionnelle dans l’immunité adaptative. P2 possède un profil fonctionnel intermédiaire. Plutôt qu’un lien séquentiel, nos résultats indiquent une exclusion réciproque des fonctions innées et adaptatives entre ces différents sous-types de pDC / Under microbial stimulation plasmacytoid pre-dendritic cells (pDC) secrete large amounts of type I interferon (IFN) and differentiate into mature dendritic cells capable of activating T cells. These innate and adaptive functions are thought to be induced sequentially in pDC through triggering of the IRF-7 and NFkB pathways, respectively. We found that viral activation of pDC induced their differentiation into three phenotypically distinct subsets: PD-L1+CD80- (P1), PD-L1+CD80+ (P2) and PD-L1-CD80+ (P3). P1 specifically produced IFN-α, indicating a specialization in innate immunity, while promoting weak activation and high IL-10 expression in CD4 T cells. Conversely, P3 showed increased expression of surface costimulatory molecules, improved migratory capacity, strong naïve CD4 T cell activation, and induction of Th2 differentiation. P2 had an intermediate functional profile. No conversion could be induced between subsets. We identified P1 in psoriatic skin, and blood from active lupus patients. Our results indicate reciprocal exclusion, rather than sequential link, of innate and adaptive pDC functions, with important implications in immune regulation and immunopathology. Cellule dendritique plasmacytoide Immunité Inée Immunite adaptative Interféron Sous-Populations Plasmacytoid dendritic cells Innate Immunity Adaptive Immunity Type I Interferon Subsets
38	TLR2 / 1 Orchestrent la réponse de les cellules dendritiques plasmacytoïdes humaines à les bactéries Gram + / TLR2/1 Orchestrate Human Plasmacytoid Dendritic Cells Response to Gram+ Bacteria Raieli, Salvatore 05 December 2016 (has links) Les maladies infectieuses dues aux bactéries Gram + sont causes de mortalité importante à travers le monde, et de récentes études ont mis en évidence le rôle pathologique de l’interféron de type I (I IFN) dans ces maladies. Les cellules dendritiques plasmacytoïdes (pDC) produisent des quantités importantes d’IFN de type I suite à la détection de virus. Des données récentes suggèrent que les pDC humaines pourraient également détecter des bactéries, mais les récepteurs impliqués restent inconnus. Au cours de ma thèse, j’ai caractérisé l’expression des récepteurs TLR2 / 1 par les pDC. Ces deux récepteurs permettent aux pDC de détecter les lipoprotéines bactériennes. Je montre que les pDC répondent aux bactéries Gram + (M. tuberculosis, S. aureus et L. monocytogenes) par la voie TLR2 / 1. Mon travail a montré que les pDC primaires humaines expriment TLR1 et TLR2 à la fois au niveau de l'ARNm et au niveau protéique. En réponse aux lipoprotéines bactériennes, la régulation des molécules costimulatrices par les pDCs est TLR1-dépendante tandis que la sécrétion d’I-IFN est TLR2-dépendante. De plus, TLR2 et TLR1 jouent des rôles distincts au cours du priming des cellules T CD4+ naïves par les pDCs, induisant une prolifération et différentiation en sous-populations Th1 / Th2 / Treg. Je démontre en outre que ces différences reposent sur les voies de signalisation distinctes de ces deux TLR. Ce travail de thèse pose ainsi les bases pour l’exploration du rôle des pDC dans les infections bactériennes humaines. / Infections by Gram+ bacteria are worldwide life-threatening diseases where new studies are highlighting the pathological role of Type I interferon (I IFN). Plasmacytoid dendritic cells (pDCs) are the main source of Type I IFN following viral sensing. Recent evidence suggests that human pDCs might sense bacteria. The receptors mediating bacterial sensing in pDCs are not known. During my thesis, I focused on the characterization of pDCs TLR2/1 receptors expression. These two receptors allow pDCs to sense Gram+ bacterial lipoproteins. My work showed that human primary pDCs express TLR1 and TLR2 at the mRNA and protein level. I show that pDCs respond to the Gram+ bacteria M. tuberculosis, S. aureus and L. monocytogenes through TLR2/1 pathway. In human primary pDC, I found that in response to bacterial lipoproteins up-regulation of costimulatory molecules is TLR1-dependent while IFN-I secretion is TLR2-dependent. TLR2 and TLR1 signalling play a different role in the pDCs priming of naïve CD4+ T-cells, inducing proliferation and differentiation to TH1/TH2/Treg subsets. I further demonstrate that these differences rely on the diverse signaling pathway activated by the two TLRs. This work provides the rationale to explore pDCs activity in human bacterial infection. Humain Les bactéries gram-Positives Toll like receptors Détection innée Human Plasmacytoid dendritic cells Toll like receptors GRAM positive bacteria Innate sensing
39	The Biology of Dendritic Cell Subsets in Allergen-Induced Asthma Dua, Benny 04 1900 (has links) <h4> </h4> / <p>Asthma is an inflammatory disorder of the airways, and there has been growing insight into the cellular and molecular mechanisms underlying the inflammatory basis of this disease. Research into the inflammatory mechanisms of asthma has progressively shifted focus from downstream effectors, such as mast cells and eosinophils, up to Th2 lymphocytes and their proallergic cytokines. Even more upstream in the allergic cascade are dendritic cells (DCs), potent APCs that orchestrate immune responses. Evidence supporting a role of DCs in regulating airway allergic inflammation is derived mainly from animal studies. In animal models of asthma, myeloid DCs (mDCs) induce and maintain airway inflammation, while plasmacytoid DCs (pDCs) mediate tolerance and lung homeostasis. It remains uncertain, however, whether this concept of pro-allergic mDCs and anti-allergic pDCs translates from animal to human models. The overall objective of this thesis was to investigate the biology of DC subsets in allergen-induced asthma in asthmatic subjects. Initially, we demonstrate that both mDCs and pDCs increase in the airways of subjects with mild asthma after allergen inhalation. Next, we describe a distinct subpopulation of mDCs, called mDC2s, and demonstrate their association with allergy and asthma severity. Expanding on these findings, we show that mDC2s increase in the airways of mild asthmatics after allergen challenge. Lastly, we explore the potential of pharmacological therapies, anti-OX40L MAb and anti-TSLP MAb, to affect DCs in subjects with mild asthma, and demonstrate no effect of either drug on circulating DC subsets. The studies presented here provide evidence for multiple DC subtypes being involved in the regulation of allergen-induced inflammatory responses, and support continued investigations into the biology of different DC subsets in allergen-induced asthma.</p> / Doctor of Philosophy (Medical Science) Asthma Allergy Antigen presenting cells Dendritic cells Myeloid dendritic cells Plasmacytoid dendritic cells Allergy and Immunology Circulatory and Respiratory Physiology Immunity Immunopathology Medical Immunology Respiratory Tract Diseases Allergy and Immunology
40	Les cellules dendritiques plasmacytoides dans le sang de cordon et après greffe de sang de cordon Charrier, Emily 08 1900 (has links) La greffe de sang de cordon est de plus en plus utilisée et a permis de traiter avec succès chez l’enfant des déficits immunitaires ainsi que des hémopathies malignes comme les leucémies. Malgré d’importants avantages tels que l’absence de risque pour le donneur ou la plus faible incidence de maladie du greffon contre l’hôte (GvHD), utiliser le sang de cordon comporte certains inconvénients. En effet, une reconstitution immunitaire retardée, des infections opportunistes en plus grand nombre et un risque de rechute sont des complications qui peuvent survenir et engendrer un risque pour le pronostic vital du patient. Par conséquent, de nouvelles stratégies d’immunothérapies doivent être envisagées. Dans le cadre de ce travail, nous nous sommes particulièrement intéressés aux cellules dendritiques plasmacytoides (pDC) dont les fonctions sont importantes pour l’initiation des réponses immunitaires innée et adaptative et particulièrement pour leur capacité à activer les cellules NK. Afin d’élucider le rôle et l’impact de ces cellules dans les greffes de sang de cordon, le nombre et la fonction des pDC et des NK a été suivi longitudinalement chez des patients ayant subi une greffe de sang de cordon comparativement à des patients transplantés avec de la moelle osseuse. Nous avons ainsi démontré que les pDC et les NK apparaissent précocement suite à une greffe de sang de cordon et que ces cellules sont fonctionnelles. Ces résultats mettent donc en lumière que ces cellules pourraient être de bons outils pour l’établissement d’une immunothérapie après greffe de sang de cordon. De plus, la caractérisation fonctionnelle des pDC du greffon de sang de cordon a permis de révéler une plus faible production d’IFN-α par les pDC, comparativement aux pDC de sang d’adulte. Cette différence pourrait jouer un rôle dans la plus faible incidence de GvHD après les greffes de sang de cordon. Dans le but de préciser les mécanismes moléculaires de régulation négative de la production d’IFN-α par les pDC de sang de cordon, nous avons étudié les protéines de la voie de signalisation TLR9-IRF7. L’expression similaire de l’ARN du TLR9, MyD88, IRAK1 et IRF7 contraste avec la plus faible expression des protéines correspondantes. De plus, l’expression des MicroARNs miR-146a et miR-155 est plus élevé dans les pDC de sang de cordon comparativement aux pDC de sang d’adultes. Ensemble, ces données pointent une régulation négative post-transcriptionnelle de la voie TLR9-IRF7 qui pourrait expliquer la plus faible production d’IFN-α des pDC du sang de cordon. L’ensemble des ces travaux suggère que les pDC pourraient représenter une cible de choix dans le développement de nouvelles approches thérapeutiques dans les greffes de sang de cordon. / Umbilical cord blood transplantation has increasingly been used as a source of hematopoietic stem cells to successfully treat immunodeficiencies and malignant diseases such as leukemia in pediatric patients. Despite important advantages, namely lack of risk for the donor and low incidence of GvHD, use of cord blood is associated with several drawbacks. Specifically, delayed immune reconstitution, more opportunistic infections and a relative risk of relapse are complications that may occur and lead to a poor prognosis. Consequently, new immunotherapeutic strategies should be considered. In this study, we were interested in plasmacytoid dendritic cells (pDC), whose functions are important for initiation of innate and adaptive immune responses and, in particular, for their ability to activate natural killer cells (NK). In order to elucidate the role and the impact of these cells in cord blood transplantation, pDC and NK numbers and function have been longitudinally followed in cord blood and bone marrow recipients. We showed that pDC and NK cells appeared early after umbilical cord blood transplantation and that these cells retained functional activity. Thus, these cells may constitute a good tool for immunotherapy in umbilical cord blood transplantation. Moreover, the functional characterization of pDC in cord blood revealed a lower production of IFN-α by cord blood pDC, which may play a role in the lower incidence of GvHD after umbilical cord blood transplantations. In order to determine the molecular mechanism for the negative regulation of IFN-α production by cord blood pDC, we studied the expression of TLR9-IRF7 pathway. The stable expression of TLR9, MyD88, IRAK1 and IRF7 mRNA contrasts with the lower expression of corresponding proteins. Interestingly, expression of microRNA miR-146a and miR-155 is higher in cord blood pDC. Together, these results point to a post-transcriptionnal negative regulation of TLR9-IRF7 pathway which may explain the lower IFN-α production by cord blood pDC. This work reinforces the idea that pDCs constitute a target of choice for developing new therapeutic approaches in cord blood transplantations. sang de cordon cord blood immunotherapie immunotherapy hematopoietic stem cell transplantation cellules dendritiques plasmacytoides plasmacytoid dendritic cells leucémie leukemia

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