Parasitism, host immune function, and sexual selection.

Parasite-mediated sexual selection may arise as a consequence of 1) females avoiding mates with directly transmitted parasites, 2) females choosing less-parasitized males that provide parental care of superior quality, or 3) females choosing males with few parasites in order to obtain genes for parasite resistance in their offspring. Studies of specific host-parasite systems and comparative analyses have revealed both supportive and conflicting evidence for these hypotheses. A meta-analysis of the available evidence revealed a negative relationship between parasite load and the expression of male secondary sexual characters. Experimental studies yielded more strongly negative relationships than observations did, and the relationships were more strongly negative for ectoparasites than for endoparasites. There was no significant difference in the magnitude of the negative effect for species with and without male parental care, or between behavioral and morphological secondary sexual characters. There was a significant difference between studies based on host immune function and those based on parasite loads, with stronger effects for measures of immune function, suggesting that the many negative results from previous analyses of parasite-mediated sexual selection may be explained because relatively benign parasites were studied. The multivariate analyses demonstrating strong effect sizes of immune function in relation to the expression of secondary sexual characters, and for species with male parental care as compared to those without, suggest that parasite resistance may be a general determinant of parasite-mediated sexual selection.

Innate immune sensing of modified vaccinia virus Ankara (MVA) is mediated by TLR2-TLR6, MDA-5 and the NALP3 inflammasome.

Modified vaccinia virus Ankara (MVA) is an attenuated double-stranded DNA poxvirus currently developed as a vaccine vector against HIV/AIDS. Profiling of the innate immune responses induced by MVA is essential for the design of vaccine vectors and for anticipating potential adverse interactions between naturally acquired and vaccine-induced immune responses. Here we report on innate immune sensing of MVA and cytokine responses in human THP-1 cells, primary human macrophages and mouse bone marrow-derived macrophages (BMDMs). The innate immune responses elicited by MVA in human macrophages were characterized by a robust chemokine production and a fairly weak pro-inflammatory cytokine response. Analyses of the cytokine production profile of macrophages isolated from knockout mice deficient in Toll-like receptors (TLRs) or in the adapter molecules MyD88 and TRIF revealed a critical role for TLR2, TLR6 and MyD88 in the production of IFNbeta-independent chemokines. MVA induced a marked up-regulation of the expression of RIG-I like receptors (RLR) and the IPS-1 adapter (also known as Cardif, MAVS or VISA). Reduced expression of RIG-I, MDA-5 and IPS-1 by shRNAs indicated that sensing of MVA by RLR and production of IFNbeta and IFNbeta-dependent chemokines was controlled by the MDA-5 and IPS-1 pathway in the macrophage. Crosstalk between TLR2-MyD88 and the NALP3 inflammasome was essential for expression and processing of IL-1beta. Transcription of the Il1b gene was markedly impaired in TLR2(-/-) and MyD88(-/-) BMDM, whereas mature and secreted IL-1beta was massively reduced in NALP3(-/-) BMDMs or in human THP-1 macrophages with reduced expression of NALP3, ASC or caspase-1 by shRNAs. Innate immune sensing of MVA and production of chemokines, IFNbeta and IL-1beta by macrophages is mediated by the TLR2-TLR6-MyD88, MDA-5-IPS-1 and NALP3 inflammasome pathways. Delineation of the host response induced by MVA is critical for improving our understanding of poxvirus antiviral escape mechanisms and for designing new MVA vaccine vectors with improved immunogenicity.

LIGHT/HVEM/LTβR interaction as a target for the modulation of the allogeneic immune response in transplantation.

The exchange of information during interactions of T cells with dendritic cells, B cells or other T cells regulates the course of T, B and DC-cell activation and their differentiation into effector cells. The tumor necrosis factor superfamily member LIGHT (homologous to lymphotoxin, exhibits inducible expression and competes with HSV glycoprotein D for binding to herpesvirus entry mediator, a receptor expressed on T lymphocytes) is transiently expressed upon T cell activation and modulates CD8 T cell-mediated alloreactive responses upon herpes virus entry mediator (HVEM) and lymphotoxin β receptor (LTβR) engagement. LIGHT-deficient mice, or WT mice treated with LIGHT-targeting decoy receptors HVEM-Ig, LTβR-Ig or sDcR3-Ig, exhibit prolonged graft survival compared to untreated controls, suggesting that LIGHT modulates the course and severity of graft rejection. Therefore, targeting the interaction of LIGHT with HVEM and/or LTβR using recombinant soluble decoy receptors or monoclonal antibodies represent an innovative therapeutic strategy for the prevention and treatment of allograft rejection and for the promotion of donor-specific tolerance.

Surface assembly of poly(I:C) on PEGylated microspheres to shield from adverse interactions with fibroblasts.

By expressing an array of pattern recognition receptors (PRRs), fibroblasts play an important role in stimulating and modulating the response of the innate immune system. The TLR3 ligand polyriboinosinic acid-polyribocytidylic acid, poly(I:C), a mimic of viral dsRNA, is a vaccine adjuvant candidate to activate professional antigen presenting cells (APCs). However, owing to its ligation with extracellular TLR3 on fibroblasts, subcutaneously administered poly(I:C) bears danger towards autoimmunity. It is thus in the interest of its clinical safety to deliver poly(I:C) in such a way that its activation of professional APCs is as efficacious as possible, whereas its interference with non-immune cells such as fibroblasts is controlled or even avoided. Complementary to our previous work with monocyte-derived dendritic cells (MoDCs), here we sought to control the delivery of poly(I:C) surface-assembled on microspheres to human foreskin fibroblasts (HFFs). Negatively charged polystyrene (PS) microspheres were equipped with a poly(ethylene glycol) (PEG) corona through electrostatically driven coatings with a series of polycationic poly(L-lysine)-graft-poly(ethylene glycol) copolymers, PLL-g-PEG, of varying grafting ratios g from 2.2 up to 22.7. Stable surface assembly of poly(I:C) was achieved by incubation of polymer-coated microspheres with aqueous poly(I:C) solutions. Notably, recognition of both surface-assembled and free poly(I:C) by extracellular TLR3 on HFFs halted their phagocytic activity. Ligation of surface-assembled poly(I:C) with extracellular TLR3 on HFFs could be controlled by tuning the grafting ratio g and thus the chain density of the PEG corona. When assembled on PLL-5.7-PEG-coated microspheres, poly(I:C) was blocked from triggering class I MHC molecule expression on HFFs. Secretion of interleukin (IL)-6 by HFFs after exposure to surface-assembled poly(I:C) was distinctly lower as compared to free poly(I:C). Overall, surface assembly of poly(I:C) may have potential to contribute to the clinical safety of this vaccine adjuvant candidate.

Coevolutionary arms races: increased host immune defense promotes specialization by avian fleas.

We investigated the relationship between host defense and specialization by parasites in comparative analyses of bird fleas and T-cell mediated immune response of their avian hosts, showing that fleas with few main host species exploited hosts with weak or strong immune defenses, whereas flea species that parasitized a large number of host species only exploited hosts with weak immune responses. Hosts with strong immune responses were exploited by a larger number of flea species than hosts with weak responses. A path analysis model with an effect of T-cell response on the number of host species, or a model with host coloniality directly affecting host T-cell response, which in turn affected the number of host species used by fleas, best explained the data. Therefore, parasite specialization may have evolved in response to strong host defenses.

The fate and persistence of Leishmania major in mice of different genetic backgrounds: an example of exploitation of the immune system by intracellular parasites.

Leishmania spp. are intracellular protozoan parasites that are delivered within the dermis of their vertebrate hosts. Within this peripheral tissue and the draining lymph node, they find and/or rapidly create dynamic microenvironments that determine their ultimate fate, namely their more or less successful expansion, and favour their transmission to another vertebrate host though a blood-feeding vector. Depending on their genetic characteristics as well as the genetic make-up of their hosts, once within the dermis Leishmania spp. very rapidly drive and maintain sustained T cell-dependent immune responses that arbitrate their ultimate fate within their hosts. The analysis of the parasitism exerted by Leishmania major in mice of different genetic backgrounds has allowed us to recognize some of the early and late mechanisms driven by this parasite that lead to either uncontrolled or restricted parasitism. Uncontrolled parasitism by Leishmania major characterizing mice from a few inbred strains (e.g. BALB/c) is associated with the expansion of parasite reactive Th2 CD4 lymphocytes and results from their rapid and sustained activity. In contrast, restricted parasitism characteristic of mice from the majority of inbred strains results from the development of a polarized parasite-specific Th1 CD4 response. This murine model of infection has already been and will continue to be particularly instrumental in dissecting the rules controlling the pathway of differentiation of T cells in vivo. In the long run, the understanding of these rules should contribute to the rational development of novel immunotherapeutic interventions against severe infectious diseases.

Endothelial cells as key determinants of the tumor microenvironment: interaction with tumor cells, extracellular matrix and immune killer cells.

Besides tumor cells, the tumor microenvironment harbors a variety of host-derived cells, such as endothelial cells, fibroblasts, innate and adaptive immune cells. It is a complex and highly dynamic environment, providing very important cues to tumor development and progression. Tumor-associated endothelial cells play a key role in this process. On the one hand, they form tumor-associated (angiogenic) vessels through sprouting from locally preexisting vessels or recruitment of bone marrow-derived endothelial progenitor cells, to provide nutritional support to the growing tumor. On the other hand, they are the interface between circulating blood cells, tumor cells and the extracellular matrix, thereby playing a central role in controlling leukocyte recruitment, tumor cell behavior and metastasis formation. Hypoxia is a critical parameter modulating the tumor microenvironment and endothelial/tumor cell interactions. Under hypoxic stress, tumor cells produce factors that promote tumor angiogenesis, tumor cell motility and metastasis. Among these factors, VEGF, a main angiogenesis modulator, can also play a critical role in the control of immune tolerance. This review discusses some aspects of the role of endothelial cells within tumor microenvironment and emphasizes their interaction with tumor cells, the extracellular matrix and with immune killer cells. We will also address the role played by circulating endothelial progenitor cells and illustrate their features and mechanism of recruitment to the tumor microenvironment and their role in tumor angiogenesis.

Role of neutrophils in the early shaping of the Leishmania major specific immune response in experimental murine cutaneous Leishmaniasis

The development of a protective immune response to microorganisms involves complex interactions between the host and the pathogen. The murine model of infection with Leishmania major (L. major) allows the study of the factors leading to the development of a protective immune response. Following infection with the protozoan parasite L. major, most strains of mice heal their lesions, while a few fail to control infection, both processes linked to the development of specific T helper subsets. The early events occurring during the first days following parasite inoculation are thought to be critical in the development of the Leishmania-specific immune response. Neutrophils are the first cells arriving massively to the site of infection, and recent evidence points to their role as organizers of the immune response, yet their specific role in this process remains elusive. Through interactions with cells present at the parasite inoculation site, and possibly within the draining lymph nodes, neutrophils could have an impact not only on the recruitment of inflammatory cells but also on the activation of local as well as newly migrated cells that will be crucial in shaping the Leishmania-specific immune response.

Synergistic and antagonistic interaction between different branches of the immune system is related to melanin-based coloration in nestling tawny owls.

When exposed to parasites, hosts often mount energetically expensive immune responses, and this may alter resource allocation between competing life history traits including other components of the immune system. Here, we investigated whether a humoral immune challenge towards a vaccine reduces or enhances the cutaneous immune responses towards an injection of lipopolysaccharid (LPS, innate immunity) and phytohaemagglutinin (PHA, T-cell immunity) in nestling tawny owls in interaction with the degree of plumage melanin-based coloration. The humoral immune challenge enhanced the response to LPS similarly in differently coloured nestlings. In contrast, the same humoral immune challenge enhanced immune response to PHA in dark reddish melanic nestlings while reducing it in pale reddish melanic nestlings. Our results highlight that both antagonistic and synergistic interactions can take place among branches of immune system, and that the sign and magnitude of these interactions can vary with immune responses involved and the degree of melanin-based coloration.

From pathogen defence to food allergy; The multiple facets of the mucosal immune system

Résumé destiné à un large public Le système immunitaire associé aux muqueuses gastro-intestinales doit être capable de protéger notre organisme contre l'invasion de pathogènes. Parallèlement, il doit identifier en Cant que tels, des composés inoffensifs comme la nourriture ou les milliards de bactéries qui résident dans notre intestin. Le travail présenté ici aborde ces deux aspects essentiels au bon fonctionnement de notre muqueuse intestinale. Dans une première partie, la protéine nommée pièce sécrétoire a été étudiée pour ses propriétés protectrices contre le pathogène viral rotavirus. Le rôle de la pièce sécrétoire est de transporter les anticorps que nous produisons vers la surface des muqueuses. En dehors de cette fonction bien connue, il se peut que cette protéine soit également capable de protéger notre organisme contre certains virus. L'hypothèse de travail était donc que la pièce sécrétoire se lie directement au virus, l'empêchant ainsi d'infecter des cellules épithéliales de l'intestin. En utilisant différentes techniques biochimiques, cette hypothèse s'est révélée fausse car aucune interaction entre la pièce sécrétoire et le virus n'a pu être observée, et logiquement, aucune protection n'a pu prendre place. En revanche, la pièce sécrétoire se lie à d'autres structures pathogéniques et permet ainsi de neutraliser leurs effets néfastes. La pièce sécrétoire participe donc activement à la protection de nos muqueuses, en plus de son rôle de transporteur. La deuxième partie de ce travail avait pour sujet les réactions inappropriées que le système immunitaire induit parfois contre un aliment, ou, autrement dit, les allergies alimentaires. Un modèle d'allergie alimentaire à donc été développé chez la souris et a permis de mesurer plusieurs symptômes et facteurs liés à l'allergie. Puis, ce modèle a été utilisé afin de tester les effets bénéfiques d'une bactérie lactique, dite probiotique, sur le développement de l'allergie. Il a été observé que, sous certaines circonstances, l'administration de la bactérie lactique protégeait entièrement les souris contre les réactions allergiques. L'effet bénéfique dépend donc du probiotique mais également d'autres facteurs encore inconnus â ce jour. Cette étude ouvre la voie sur la compréhension des mécanismes liés aux allergies alimentaires et sur l'impact que peuvent avoir les bactéries probiotiques sur cette maladie. Résumé Le système immunitaire associé aux muqueuses intestinales doit être capable de différencier les antigènes inoffensifs tels que 1a nourriture ou les bactéries commensales des microorganismes potentiellement dangereux. Cet aspect est essentiel pour le maintien de l'homéostase intestinale et fait l'objet du travail présenté ici. Dans un premier projet, les propriétés protectrices de la protéine appelée pièce sécrétoire (SC) ont été étudiées. SC est une protéine connue pour le transport des immunoglobulines à la surface des muqueuses. Cette protéine est fortement glycosylée paz des sucres complexes, ce qui nous a mené à postuler que SC puisse interagir avec le pathogène rotavirus. Cette hypothèse était soutenue par le fait que ce virus adhère aux cellules épithéliales par des résidus glycosylés. Des analyses biochimiques et biologiques ont démontré qu'aucune interaction entre SC et le virus ne prenait place, et que par conséquent SC n'offrait aucune protection contre ce pathogène. En revanche, SC interagit avec d'autres structures pathogéniques, comme la toxine A de Clostridium difficile, et la molécule d'adhésion intimine de la bactérie entéropathogène Escherichia coli. La liaison se fait par l'intermédiaire des sucres et confère ainsi une protection contre ces pathogènes. Ainsi, SC a été identifié comme agent neutralisant au niveau de l'intestin. La deuxième partie de ce travail abordait le sujet des allergies alimentaires, et avait pour but de tester les effets bénéfiques potentiels d'une bactérie probiotique, Lactobacillus paracasei NCC2461, contre les réactions allergiques. Un modèle marin d'allergie alimentaire a été mis au point, permettant de mesurer des immunoglobulines E, des symptômes allergiques, et la dégranulation de mastocytes. Lorsque le probiotique a été administré aux souris, celles-ci ont été complètement protégées des réactions allergiques dans une première expérience. Cependant, cette protection n'a pas été reproduite et suggère que des facteurs environnementaux encore inconnus sont critiques pour que le probiotique agisse positivement. Ce travail a permis de mettre en évidence la complexité de l'approche des traitements liés aux probiotiques et ouvre la voie sur la compréhension des mécanismes liés à l'allergie. Abstract The mucosal immune system associated to the gastrointestinal mucosa must efficiently distinguish between innocuous antigens, such as food proteins and commensal bacteria and potentially infectious agents. The work presented here deals with these two essential aspects guaranteeing intestinal homeostasis. In the first part of this work, the protective properties of secretory component (SC) toward the pathogen rotavirus were investigated. SC, which allows the transport of polymeric immunoglobulins (Ig) to mucosal surfaces, is highly glycosylated with complex glycan structures. The abundance and the nature of these carbohydrates led us to speculate that SC might interact with rotavirus, which is known to bind target cells with glycan receptors. Using various biological and biochemical techniques, we demonstrated that SC did not interact with rotaviruses, nor protected epithelial cells from infection. However, SC was shown to bind to Clostridium difficile toxin A and to the enteropathogenic Echerischia coli adhesion molecule intimin in a glycan-dependent fashion. These interactions allow in vitro protection of epithelial cells using physiological concentrations of SC. These data identify SC as a microbial scavenger at mucosal surfaces, and in the context of secretory IgA, further enhance the neutralising properties of the complex. The second project was inscribed in the domain of food allergy and aimed to test the modulatory functions of a probiotic strain of Lactobacillus paracasei toward allergic reactions. A model of food-mediated allergy was developed in the mouse using mucosal sensitisation. Several parameters associated to allergy were quantified after allergen challenge, and included allergen-specific IgE, allergic signs like diarrhea and temperature drop, and degranulation of mast cells. Administration of the probiotic strain was shown to completely protect mice from allergic reactions. However, these data were not reproduced, suggesting that unknown environmental factors are required so that protection mediated by the probiotic strain occurs. This study paves the way to the understanding of the mechanisms associated to allergy, and highlights the tremendous complexity that probiotic treatments will have to face.

Early life host-microbe interactions : implications for the development of asthma

Plus de 300 millions de personnes dans le monde souffrent de l'asthme. L'asthme est une maladie inflammatoire chronique des voies respiratoires caractérisée par des symptômes variables et récurrents, une obstruction bronchique réversible et des bronchospasmes. Les symptômes communs incluent une respiration sifflante, de la toux, une oppression thoracique et de la dyspnée. Normalement, la maladie commence à se manifester pendant l'enfance. Pourtant, facteurs génétiques héréditaires et événements environnementaux survenant au cours de la petite enfance sont responsables de sa manifestation, indiquant que le développement de la maladie est lié à des événements qui se produisent bien avant son déclenchement. L'infection respiratoire virale aiguë constitue un de ces facteurs environnementaux jouant un rôle prépondérant. Un des virus les plus communs est le virus respiratoire syncytial (VRS), qui infecte presque tous les enfants avant l'âge de 2 ans. Ce virus, s'il infecte des tout-petits, peut en effet provoquer une bronchiolite aiguë, un phénomène qui a été épidémiologiquement lié à l'apparition d'asthme plus tard dans la vie. Dans le premier chapitre de cette thèse, nous avons étudié, chez la souris, comment une infection avec le VRS influe sur l'asthme allergique. Nous avons constaté que seule l'infection des souris à l'état de nouveau-né prédispose à un asthme allergique plus sévère chez l'adulte. En effet, si des souris adultes étaient infectées, elles étaient protégées contre l'apparition des symptômes asthmatiques. Cela nous a mené à investiguer les mécanismes immunitaires spécifiques durant cette courte période du début de la vie. Deux événements se produisent en parallèle au cours de la petite enfance: (1) Le système immunitaire, qui est encore immature immédiatement après la naissance, commence à se développer pour être en mesure de jouer son rôle protecteur contre les agents infectieux. (2) Le corps, y compris les poumons, est colonisé par des bactéries commensales, qui vivent en symbiose avec leur hôte humain. Chez l'adulte, ces bactéries sont connues pour influencer notre système immunitaire, l'éduquant à générer des réponses immunitaires adéquates et efficaces. Dans la deuxième partie de cette thèse, nous avons voulu déterminer si ces bactéries symbiotiques étaient impliquées dans l'éducation du système immunitaire du nouveau-né et quelles conséquences cela pourrait avoir sur les réponses immunitaires engendrées par ce dernier. Pour étudier l'effet de ces bactéries symbiotiques, nous avons utilisé des souris stériles, en d'autres termes des souris qui n'hébergent pas ces bactéries symbiotiques. En comparant ces souris stériles à des souris qui abritent une flore microbienne normale, nous avons constaté que les bactéries symbiotiques sont vitales pour la bonne éducation du système immunitaire du nouveau-né. Nous avons démontré que le contact direct des cellules immunitaires avec la flore microbienne dans les poumons modifie le phénotype de ces cellules immunitaires, ce qui change probablement leur réaction au cours de réponses immunitaires. Nous avons donc vérifié si l'éducation immunitaire induite par cette microflore est importante pour prévenir les maladies pulmonaires telles que l'asthme allergique, affections qui sont causées par une réaction excessive du système immunitaire envers des agents inoffensifs. En effet, nous avons observé que le processus de maturation du système immunitaire néonatal, lequel a été déclenché et façonné par la flore microbienne, est important pour éviter une réaction asthmatique exagérée chez la souris adulte. Ce phénomène est dû aux lymphocytes T régulateurs. Ces cellules, dont la présence est induite dans les poumons, ont des capacités immunosuppressives et atténuent donc les réponses immunitaires pour prévenir une inflammation excessive. En conclusion, nous avons montré dans cette thèse que la colonisation par des bactéries symbiotiques tôt dans la vie est un événement décisif pour la maturation du système immunitaire et pour prévenir le développement de l'asthme. Dans l'avenir, il serait intéressant de découvrir quelles bactéries sont présentes dans les poumons du nouveau-né et lesquelles sont directement impliquées dans ce processus de maturation immunitaire. Une prochaine étape serait alors de favoriser la présence de ces bactéries au début de la vie au moyen d'un traitement avec des agents pré- ou probiotiques, ce qui pourrait éventuellement contribuer à une prévention précoce du développement de l'asthme. -- L'asthme est une maladie chronique inflammatoire des voies respiratoires affectant près de 300 millions d'individus dans le monde. Bien que les traits caractéristiques du phénotype asthmatique s'établissent généralement pendant l'enfance, la prédisposition au développement de la maladie est intimement liée à des événements survenant durant la petite enfance, comme le sont par exemple les infections virales respiratoires aiguës. Les mécanismes par lesquels ces événements provoquent un dysfonctionnement immunitaire et, par conséquent, conduisent au développement de l'asthme n'ont pas encore été entièrement décelés. La dysbiose du microbiote des voies respiratoires a été récemment associes au phénotype asthmatique, touisTcis, la cuûoboiatioî! d un lien cause à effet entre la dysbiose microbienne et l'apparition des symptômes asthmatiques reste à être démontrée. Dans cette thèse, nous avons étudié le rôle que joue la colonisation microbienne des voies respiratoires au cours de la petite enfance dans la maturation du système immunitaire ainsi que dans la protection contre l'inflammation pulmonaire de type allergique. Nous avons de surcroît développé un modèle expérimental pour comprendre comment les infections virales respiratoires interfèrent avec ce processus. Dans la première partie de cette thèse, nous avons évalué l'effet d'infections causées par le virus respiratoire syncytial (VRS) sur le développement de l'asthme. En accord avec des études épidémiologiques, nous avons constaté qu'une infection au VRS lors de la période néonatale exacerbait les réponses pulmonaires allergiques ultérieures. Par contraste, une infection à l'âge adulte avait un effet protecteur. Nous avons ainsi démontré que l'influence d'une infection à VRS sur l'issue et la sévérité de l'asthme respiratoire était strictement dépendante de l'âge. Ces résultats nous ont conduit à émettre l'hypothèse que des différences dans le phénotype homéostatique des cellules immunitaires pourraient être responsables de ces disparités liées à l'âge. Par conséquent, dans la deuxième partie de cette thèse, nous avons suivi et caractérisé le processus de maturation des cellules immunitaires dans les poumons du nouveau-né en condition d'homéostasie. Nous avons découvert que leur phénotype change de façon dynamique pendant le développement néonatal et que la colonisation par des microbes était déterminante pour la maturation des cellules immunitaires dans les poumons. Dans la dernière partie de cette thèse, nous avons démontré comment le microbiote pulmonaire éduque le développement immunitaire durant la période néonatale l'orientant de manière à induire une tolérance face aux aéroallergènes. Nous avons découvert que la colonisation microbienne des voies respiratoires provoque une expression transitoire de PD-L1 sur les cellules dendritiques (CD) pulmonaires du type CD11b+ dans les deux premières semaines de la vie. Cet événement engendre par la suite la génération de lymphocytes T régulateurs (TREG) dans les poumons, lesquels sont responsables de la protection contre une réponse inflammatoire allergique exagérée chez la souris adulte. Par conséquent, nous proposons un rôle pivot de la maturation immunitaire induite par le microbiote pulmonaire dans l'établissement de la tolérance aux aéroallergènes. En conclusion, les résultats présentés dans cette thèse fournissent de nouveaux indices révélant comment des événements se produisant lors de la petite enfance peuvent façonner les réponses du système immunitaire dirigées contre les allergènes et soulignent le rôle central joué par le microbiote pulmonaire dans l'édification d'une réponse immunitaire équilibrée. En résumé, notre travail met en évidence le microbiote pulmonaire comme étant une cible potentielle pour la prévention de certaines maladies respiratoires. -- Asthma is a chronic inflammatory disorder of the respiratory tract and affects approximately 300 million individuals world-wide. Although the asthmatic phenotype commonly establishes during childhood, predisposition towards disease development has been linked to events in early infancy, such as severe respiratory viral infections. However, the mechanisms by which these events cause immune dysfunction and, therefore, lead to the development of asthma have yet to be fully deciphered. Dysbiosis of the airway microbiota has recently been associated with the asthmatic phenotype; however, conclusive evidence for a causal link between microbial dysbiosis in the ail ways and asthma development is still missing. In this thesis we investigated the role of early-life microbial airway colonization in immune maturation and the protection against allergic airway inflammation and established an experimental model to address how respiratory viral infections interfere in this process. In the first part of this thesis we evaluated the effect of Respiratory syncytial virus (RSV) infections on the development of asthma. In concurrence with epidemiological studies, we found that neonatal infection exacerbated subsequent allergic airway inflammation. In contrast, adult infection was protective in the same context. Thus, we could demonstrate that the influence of RSV infection on subsequent allergic airway responses was strictly age-dependent. These findings led us to the hypothesis that differences in the homeostatic phenotype of immune cells could be responsible for the age-related disparities seen within the context of RSV. Therefore, in a second part of this thesis, we followed the process of homeostatic immune cell maturation in the neonatal lung. Immune cell phenotypes changed dynamically during neonatal development. We discovered that the colonization with microbes was central to the maturation of immune cells in the lung. In the last part of this thesis, we demonstrated how microbiota-driven immune development during the neonatal period induces tolerance against aeroallergens. We discovered that microbial colonization led to a transient programmed death-ligand (PD-L) 1 expression on CD11b+ pulmonary dendritic cells (DCs) during the first two weeks of life. This in turn induced regulatory T (TREG) cells in the lung, which were responsible for the protection against exaggerated allergic airway inflammation in adult mice. Thus, we propose a key role for microbiota-driven immune maturation in the establishment of tolerance towards aeroallergens. In conclusion, the results presented in this thesis provide new insights into how early-life events shape pulmonary immune responses towards allergens and suggest the airway microbiota as a key player in establishing a balanced immune response. Overall, our work highlights the airway microbiota as potential target for disease prevention.

Do the interactions between glucocorticoids and sex hormones regulate the development of the metabolic syndrome?

The metabolic syndrome is basically a maturity-onset disease. Typically, its manifestations begin to flourish years after the initial dietary or environmental aggression began. Since most hormonal, metabolic, or defense responses are practically immediate, the procrastinated response do not seem justified. Only in childhood, the damages of the metabolic syndrome appear with minimal delay. Sex affects the incidence of the metabolic syndrome, but this is more an effect of timing than absolute gender differences, females holding better than males up to menopause, when the differences between sexes tend to disappear. The metabolic syndrome is related to an immune response, countered by a permanent increase in glucocorticoids, which keep the immune system at bay but also induce insulin resistance, alter the lipid metabolism, favor fat deposition, mobilize protein, and decrease androgen synthesis. Androgens limit the operation of glucocorticoids, which is also partly blocked by estrogens, since they decrease inflammation (which enhances glucocorticoid release). These facts suggest that the appearance of the metabolic syndrome symptoms depends on the strength (i.e., levels) of androgens and estrogens. The predominance of glucocorticoids and the full manifestation of the syndrome in men are favored by decreased androgen activity. Low androgens can be found in infancy, maturity, advanced age, or because of their inhibition by glucocorticoids (inflammation, stress, medical treatment). Estrogens decrease inflammation and reduce the glucocorticoid response. Low estrogen (infancy, menopause) again allow the predominance of glucocorticoids and the manifestation of the metabolic syndrome. It is postulated that the equilibrium between sex hormones and glucocorticoids may be a critical element in the timing of the manifestation of metabolic syndrome-related pathologies.

MHC/Peptide-Specific Interaction of the Humoral Immune System: A New Category of Antibodies.

Abs bind to unprocessed Ags, whereas cytotoxic CD8(+) T cells recognize peptides derived from endogenously processed Ags presented in the context of class I MHC complexes. We screened, by ELISA, human sera for Abs reacting specifically with the influenza matrix protein (IMP)-derived peptide58-66 displayed by HLA-A*0201 complexes. Among 653 healthy volunteers, blood donors, and women on delivery, high-titered HLA-A*0201/IMP58-66 complex-specific IgG Abs were detected in 11 females with a history of pregnancies and in 1 male, all HLA-A*0201(-). These Abs had the same specificity as HLA-A*0201/IMP58-66-specific cytotoxic T cells and bound neither to HLA-A*0201 nor the peptide alone. No such Abs were detected in HLA-A*0201(+) volunteers. These Abs were not cross-reactive to other self-MHC class I alleles displaying IMP58-66, but bound to MHC class I complexes of an HLA nonidentical offspring. HLA-A*0201/IMP58-66 Abs were also detected in the cord blood of newborns, indicating that HLA-A*0201/IMP58-66 Abs are produced in HLA-A*0201(-) mothers and enter the fetal blood system. That Abs can bind to peptides derived from endogenous Ags presented by MHC complexes opens new perspectives on interactions between the cellular and humoral immune system.

Impact of Early-Life Exposures on Immune Maturation and Susceptibility to Disease.

Exiting from the largely sterile environment of the womb, the neonatal immune system is not fully mature, and thus neonatal immune cells must simultaneously mount responses against environmental stimuli while maturing. This dynamic process of immune maturation is driven by a variety of cell-intrinsic and extrinsic factors. Recent studies have focused on some of these factors and have shed light on the mechanisms by which they drive immune maturation. We review the interactions and consequences of immune maturation during the pre- and perinatal period. We discuss environmental signals in early life that are needed for healthy immune homeostasis, and highlight detrimental factors that can set an individual on a path towards disease. This early-life period of immune maturation could hold the key to strategies for setting individuals on trajectories towards health and reduced disease susceptibility.

Analysis of a Plant Complex Resistance Gene Locus Underlying Immune-Related Hybrid Incompatibility and Its Occurrence in Nature

Mechanisms underlying speciation in plants include detrimental (incompatible) genetic interactions between parental alleles that incur a fitness cost in hybrids. We reported on recessive hybrid incompatibility between an Arabidopsis thaliana strain from Poland, Landsberg erecta (Ler), and many Central Asian A. thaliana strains. The incompatible interaction is determined by a polymorphic cluster of Toll/interleukin-1 receptor-nucleotide binding-leucine rich repeat (TNL) RPP1 (Recognition of Peronospora parasitica1)-like genes in Ler and alleles of the receptor-like kinase Strubbelig Receptor Family 3 (SRF3) in Central Asian strains Kas-2 or Kond, causing temperature-dependent autoimmunity and loss of growth and reproductive fitness. Here, we genetically dissected the RPP1-like Ler locus to determine contributions of individual RPP1-like Ler (R1R8) genes to the incompatibility. In a neutral background, expression of most RPP1-like Ler genes, except R3, has no effect on growth or pathogen resistance. Incompatibility involves increased R3 expression and engineered R3 overexpression in a neutral background induces dwarfism and sterility. However, no individual RPP1-like Ler gene is sufficient for incompatibility between Ler and Kas-2 or Kond, suggesting that co-action of at least two RPP1-like members underlies this epistatic interaction. We find that the RPP1-like Ler haplotype is frequent and occurs with other Ler RPP1-like alleles in a local population in Gorzów Wielkopolski (Poland). Only Gorzów individuals carrying the RPP1-like Ler haplotype are incompatible with Kas-2 and Kond, whereas other RPP1-like alleles in the population are compatible. Therefore, the RPP1-like Ler haplotype has been maintained in genetically different individuals at a single site, allowing exploration of forces shaping the evolution of RPP1-like genes at local and regional population scales.