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Innate Immune Memory and Pulmonary Exposure to Lipopolysaccharides / Examination of Phenotypic and Functional Changes in Innate Immune Memory Following Local Mucosal Exposure to LipopolysaccharideYe, Gluke January 2022 (has links)
Innate immune memory has become an increasingly popular area of research in the last decade. However, much of the work done on innate immune memory using inflammatory agents such as BCG, C. albicans, and β-glucan has been pursued through systemic administration, which has been shown to induce training in circulating monocytes. In addition, little is known about whether microbial ligands can induce training. Here, we show that local mucosal exposure to an acute dose of LPS induces long-lasting phenotypic changes in airway macrophage populations. LPS-exposed macrophages display increased glycolytic metabolism and differential cytokine expression upon restimulation, whereas circulating monocytes are not affected. Finally, we show that LPS exposure provides long-lasting protection against Streptococcus pneumoniae in the lung, likely due to the higher acquisition of CD11b, which is indicative of macrophage activation and phagocytosis. As much of the work on innate immune memory has been done through systemic administration of training agents, this project aims to fill existing knowledge gaps in the induction of innate immune memory upon local mucosal exposure to inflammatory agents. / Thesis / Master of Science in Medical Sciences (MSMS) / The innate immune system is one of the first defenders in our bodies that fight against a variety of pathogens. In the last decade, the innate immune system was found to be capable of having memory, meaning it reacts faster or at a heightened magnitude in response to a wide range of subsequent pathogens after it is trained by an agent. This project explores the effect a bacteria wall component, LPS, has on the lung environment and examines if it will induce memory in the lung. Our findings show that intranasal exposure to LPS changes the cellular landscape in the lung. LPS-exposed airway innate immune cells become more activated and provide subsequent protection against bacterial infections. This work has implications for using LPS as a vaccine adjuvant in order to provide protection against a variety of pathogens in addition to specific protection brought by the vaccine.
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Aspects fonctionnel et évolutif de l'immunité mémoire chez les invertébrés : l'escargot vecteur de la Bilharziose intestinale Biomphalaria glabrata comme nouvel organisme modèle ? / Evolutive and Functional aspects of immune memory in Invertebrates : the Schistosomiasis vector snail Biomphalaria glabrata as a new model organism ?Pinaud, Silvain 19 October 2017 (has links)
Le clade des invertébrés cristallise en 2017 de grandes problématiques sociétales à la fois économiques et sanitaires. En effet un certain nombre des organismes présent dans ce groupe phylétique sont des vecteurs des grandes pandémies infectieuses telles que le paludisme (Anopheles sp), Zika, Chinkungunya, Fièvre jaune, etc (Aedes sp), Chagas (Triatoma sp) ou encore la bilharziose (Biomphalaria sp, Bulinus sp). La compréhension du système immunitaire de ces organismes vecteurs doit aider la communauté scientifique à proposer des solutions pour réduire la transmission de toutes ces maladies sur le terrain. Biomphalaria glabrata est le vecteur unique de la Bilharziose intestinale (Schistosomamansoni) en Amérique Latine. Depuis un premier cas de résistance induite par une première infection en 1998, de nombreux travaux ont exploré la réponse immunitaire mémoire innée de cet escargot tropical d’eau douce. Dans le cadre de ce travail de thèse, différents aspects de cette immunité (également appelé priming, résistance acquise) ont été explorés, de la mise en place phénotypiques, aux bases moléculaires et cellulaires. En premier lieu,nous avons pu démontrer qu’elle était dépendante d’une bascule phénotypique (d’une réponse cellulaire d’encapsulation à une réponse humorale) et transcriptomique qui lui permet de mieux répondre lors d’une seconde infection. La spécificité de cette réponse est portée par la production de répertoire complexe de récepteurs et d’effecteurs immunitaire spécifiques qui sont capables de différencier jusqu’aux différents stades de développement parasitaire d’une même espèce de parasite. Nous avons également pu montrer que cette interaction dépendait de microARN circulants ainsi que de Biomphalysines, des ß-PFT acquises par transferts horizontaux depuis le monde bactérien. Enfin, cette résistance semble posséder une proximité avec l’immunité mémoire entraînée des cellules immunitaires innées des vertébrés en particulier sur la base des mécanismes moléculaires sous-jacent qui seraient liés chez Biomphalaria comme chez les Vertébrés à unereprogrammation épigénétique des cellules du système immunitaire innée. / Invertebrates focus in 2017 among the major economical and societal issuesacross Earth. Some members are vectors of important infectious pandemic as malaria(Anopheles sp), Zika, Chinkungunya, Yellow fever, etc (Aedes sp), Chagas (Triatoma sp) andtrematodes (Biomphalaria sp, Bulinus sp). Comprehension of immune system of thesevectors has to help scientist to decrease transmission on endemic area. Biomphalariaexposed first failure to be reinfected following first infection as soon as 1998. In my thesiswe explore this immune priming (innate immune memory) and describe an immune shiftfrom cellular to humoral immune response both in phenotype and transcriptomic response.A specificity is handle by specific immune receptor and effector repertoire to distinguish upto different developmental stage of same parasite species. This interaction is alsodependent of mRNAs and Biomphalysin, a ß-PFT coming from bacterial kingdom. Finally,this resistance seems to look alike the trained immune memory of innate cells in vertebrates.
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Pathways Involved in Recognition and Induction of Trained Innate Immunity by Plasmodium falciparumSchrum, Jacob E. 07 August 2017 (has links)
Malarial infection in naïve individuals induces a robust innate immune response, but our understanding of the mechanisms by which the innate immune system recognizes malaria and regulates its response remain incomplete. Our group previously showed that stimulation of macrophages with Plasmodium falciparum genomic DNA (gDNA) and AT-rich oligodeoxynucleotides (ODNs) derived from this gDNA induces the production of type I interferons (IFN-I) through a STING/TBK1/IRF3-dependent pathway; however, the identity of the upstream cytosolic DNA receptor remained elusive. Here, we demonstrate that this IFN-I response is dependent on cyclic GMP-AMP synthase (cGAS). cGAS produced the cyclic dinucleotide 2’3’-cGAMP in response to P. falciparum gDNA and AT-rich ODNs, inducing IRF3 phosphorylation and IFNB transcription. In the recently described model of innate immune memory, an initial stimulus primes the innate immune system to either hyperrespond (termed “training”) or hyporespond (“tolerance”) to subsequent immune challenge. Previous work in mice and humans demonstrated that infection with malaria can both serve as a priming stimulus and promote tolerance to subsequent infection. In this study, we demonstrate that initial stimulation with P. falciparum-infected red blood cells (iRBCs) or the malaria crystal hemozoin (Hz) induced human adherent peripheral blood mononuclear cells (PBMCs) to hyperrespond to subsequent Toll-like receptor (TLR) challenge. This hyperresponsiveness correlated with increased H3K4me3 at important immunometabolic promoters, and these epigenetic modifications were also seen in monocytes from Kenyan children naturally infected with malaria. However, the use of epigenetic and metabolic inhibitors indicated that malaria-induced trained immunity may occur via previously unrecognized mechanism(s).
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Examination of induction of innate immune memory of alveolar macrophages and trained innate immunity following respiratory exposure to infectious agentsSingh, Ramandeep January 2022 (has links)
In the last decade, the potential of β-glucan, a fungal cell wall component, to induce epigenetic and functional modification of innate immune cells, signified as trained innate immunity (TII) has been demonstrated in several pre-clinical and clinical studies. Parenteral administration of β-glucan has resulted in centrally induced TII in the bone marrow/circulating monocytes. Such trained innate immune cells play a critical role in protection against secondary infections. However, there are now indications that inducing local long-lasting immunity at mucosal barrier tissues such as the lung is warranted for protective immunity against respiratory pathogens. Currently, it remains unclear whether respiratory mucosal administration of β-glucan will induce long-lasting resident-memory macrophages and TII and if so, what are the underlying mechanisms of development and maintenance of memory macrophages at respiratory mucosa. To address this, and kinetics of immune responses in the lung were studied. Profound changes in airway macrophage (AM) pools were observed starting from 3 days post-exposure, which was associated with monocyte recruitment, and this was followed by a series of phenotypic shifts in AMs. The altered AM phenotype profile persisted for up to 8 weeks post-exposure. Importantly, β-glucan-trained AMs demonstrated heightened MHC II expression, enhanced responses to secondary stimulation and improved capacity to perform bacterial phagocytosis. Furthermore, mice with, β-glucan-trained AMs displayed higher rates of survival and improved bacterial control, in the lung and periphery, following a lethal S. pneumoniae infection. Our findings together indicate that a single intranasal delivery of β-glucan is able to train AMs. Further work into epigenetics, metabolism, and the contribution of AMs in protection is needed. / Thesis / Master of Health Sciences (MSc) / The immune system has been classically divided into two major compartments known as the innate and adaptive immune system. For decades, the predominant consensus amongst the field was that only the adaptive immune system can form memory against any pathogens encountered. It has been well established that plants and invertebrates only possess an innate immune system and still show boosted responses and enhanced protection against previously encountered as well as new pathogens. Recently, such capacity for innate immune memory has also been demonstrated in humans and pre-clinical animal models. Innate immune memory provides non-specific, broad- spectrum protection whereas adaptive memory is specific to a singular pathogen. Inducing broad-spectrum protection can be crucial for the future of human medicine. Activation of both adaptive and innate immune arms could prove to be extremely beneficial in vaccination strategies. Through the use of a pre-clinical model, we have found that administering β-glucan, a component of fungal cell wall, directly into the lung significantly alters the phenotype and functionality of lung immune cells, and also provides enhanced protection against a heterologous infection.
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Résistance des planaires à l'infection bactérienne : caractérisation de la mémoire immunitaire innée / Planarian resistance to the bacterial infection : caracterization of the innate immune memoryTorre, Cédric 23 November 2017 (has links)
Mon travail de Thèse a porté sur la description de l’immunité antibactérienne de la planaire, et plus particulièrement la mémoire immunitaire innée.La mémoire immunitaire innée constitue une ligne de défense de l’hôte à la réinfection qui ne fait intervenir que des composants de l’immunité innée. Présente chez les vertébrés et les invertébrés, ces derniers constituent un modèle de choix car dépourvus d’immunité acquise. La planaire dispose d’une mémoire immunitaire innée envers S. aureus, qui, suite à une réinfection, se traduit par une élimination exacerbée. La déplétion des planaires en cellules souches et la greffe tissulaire ont permis de mettre en avant les cellules souches comme acteurs principaux de cette réponse immunitaire. Un criblage RNAi associé à un profilage transcriptomique ont fait ressortir des gènes en les hiérarchisant au sein d’une voie de signalisation impliquant un récepteur au peptidoglycane (pgrp-2), une histone méthyltransférase (setd8.1), et un mécanisme effecteur dans l’élimination bactérienne (p38 et morn2). Setd8.1, histone méthyltransférase, se placerait au cœur du processus en déposant des marques épi-génétiques sur des loci de l’ADN, garantissant l’expression accrue des gènes effecteurs suite à la réinfection. Ce mécanisme, décrit chez l’Homme, n’avait jusqu’alors jamais impliqué des cellules souches, ni ce type d’histone méthyltransférase comme acteurs dans la mémoire immunitaire innée.Collectivement, l’investigation du système immunitaire de la planaire a permis la découverte de mécanismes de défense antibactérienne inédits, dont le transfert à l’Homme pourrait compléter l’approche actuelle du traitement des maladies infectieuses. / My Thesis work has focused on the description of the planarian antibacterial immunity, and more precisely the innate immune memory.The innate immune memory forms a host defense line to the reinfection which only involves components from innate immunity. Present in vertebrates and invertebrates, invertebrates are a model of choice because devoid of acquired immunity. The planarian has an innate immune memory against S. aureus, which, after a reinfection, displays an exacerbated elimination. The depletion of stem cells from planarians and tissue graft highlighted stem cells as the main actors of this immune response. An RNAi screening combined with a transcriptomic profiling brought out genes and classified them within a signaling pathway involving a peptido-glycan receptor (pgrp-2), a histone methyltransferase (setd8.1), and an effector mechanism of the bacterial elimination (p38 and morn2). Setd8.1, histone methyltransferase, would be the core of the process putting epigenetic marks on DNA loci, ensuring the increased expression of effector genes after reinfection. This mechanism, described in humans, has neither involved stem cells, nor this type of histone methyltransferase as actors in the innate immune memory.Collectively, the investigation of the planarian immune system allowed the discovery of new antibacterial defense mechanisms, and transferring it to humans could complete the actual approach of the infectious disease treatment.
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The role of neutrophils in trained immunityKalafati, Lydia, Hatzioannou, Aikaterini, Hajishengallis, George, Chavakis, Triantafyllos 26 February 2024 (has links)
The principle of trained immunity represents innate immune memory due to sustained, mainly epigenetic, changes triggered by endogenous or exogenous stimuli in bone marrow (BM) progenitors (central trained immunity) and their innate immune cell progeny, thereby triggering elevated responsiveness against secondary stimuli. BM progenitors can respond to microbial and sterile signals, thereby possibly acquiring trained immunity-mediated long-lasting alterations that may shape the fate and function of their progeny, for example, neutrophils. Neutrophils, the most abundant innate immune cell population, are produced in the BM from committed progenitor cells in a process designated granulopoiesis. Neutrophils are the first responders against infectious or inflammatory challenges and have versatile functions in immunity. Together with other innate immune cells, neutrophils are effectors of peripheral trained immunity. However, given the short lifetime of neutrophils, their ability to acquire immunological memory may lie in the central training of their BM progenitors resulting in generation of reprogrammed, that is, “trained”, neutrophils. Although trained immunity may have beneficial effects in infection or cancer, it may also mediate detrimental outcomes in chronic inflammation. Here, we review the emerging research area of trained immunity with a particular emphasis on the role of neutrophils and granulopoiesis.
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