Global ETD Search

21	Intravital Microscopy of Borrelia burgdorferi: Delineation of Dissemination Kinetics and Persistence Within Murine Skin Lavik, John-Paul 21 August 2012 (has links) No description available. Immunology Microbiology host-pathogen interactions Borrelia burgdorferi intravital microscopy
22	Comparative genomic analysis and host-pathogen interactions of porphyromonas gingivalis Igboin, Christina 07 January 2008 (has links) No description available. Porphyromonas gingivalis Adult periodontitis Drosophila melanogaster Host-Pathogen interactions Periodontitis
23	Exploring the drivers and consequences of emerging infectious disease of wildlife Grimaudo, Alexander Thomas 22 April 2024 (has links) Emerging infectious diseases of wildlife have threatened host populations of diverse taxa in recent history, which is largely attributable to anthropogenic global change. In three data chapters, this dissertation examines the drivers of individual- to population-level variation in how host populations respond to novel and emerging pathogens. Each chapter explores these processes in bat populations of North America, predominantly the Northeast and Midwest regions of the United States, impacted by the emerging fungal pathogen that causes white-nose syndrome, Pseudogymnoascus destructans. In Chapter 2, I disentangle the effects of adaptive host traits and environmental influences in driving host population stabilization of the little brown bat (Myotis lucifugus), finding that host-pathogen coexistence in this system is the product of their complex interaction. In Chapter 3, I characterize the range-wide variation in white-nose syndrome impacts on a federally endangered and poorly studied species, the Indiana bat (Myotis sodalis), as well as environmental and demographic determinants of its declines over epidemic time. In Chapter 4, I explore the role of individual variation in roosting microclimate selection of little brown bats in driving their infection severity, yielding important insights into the pathophysiology and environmental dependence of white-nose syndrome. Ultimately, this dissertation characterizes complex drivers of variation in host responses to emerging and invading pathogens, yielding insights essential to the successful mitigation of their impacts. / Doctor of Philosophy / In the same way that Covid-19 swept through our global human population in the year 2020, novel infectious diseases have threatened wildlife populations, sometimes to the point of extinction. Often, however, the processes driving the impacts of novel infectious diseases in wildlife are unknown, despite being important information to protect susceptible populations. In this dissertation, I explore how North American bat populations have been impacted by a recently emerged disease, white-nose syndrome, and what processes cause variation in how individual bats and bat colonies have responded to the disease. In Chapter 2, I explore how the little brown bat (Myotis lucifugus) has evolved to co-exist with its new pathogen and how this coexistence is affected by environmental conditions like temperature and humidity. In Chapter 3, I characterize variation in how populations of the Indiana bat (Myotis sodalis) have responded to white-nose syndrome and how environmental and demographic conditions have affected declines since the disease first emerged. In Chapter 4, I explore how the temperatures used by little brown bats during hibernation affect the severity of their infection, giving us important information on how bats survive with white-nose syndrome and the role of temperature. Altogether, the research in this dissertation describes complex interactions between hosts, pathogens, and their environment in driving the patterns we observe after the emergence of novel infectious diseases. disease ecology emerging infectious disease host-pathogen coevolution
24	Pathosystems Biology: Computational Prediction and Analysis of Host-Pathogen Protein Interaction Networks Dyer, Matthew D. 12 August 2008 (has links) An important aspect of systems biology is the elucidation of the protein-protein interactions (PPIs) that control important biological processes within a cell and between organisms. In particular, at the cellular and molecular level, interactions between a pathogen and its host play a vital role in initiating infection and a successful pathogenesis. Despite recent successes in the advancement of the systems biology of model organisms to understand complex diseases, the analysis of infectious diseases at the systems-level has not received as much attention. Since pathogen related disease is responsible for millions of deaths and billions of dollars in damage to crops and livestock, understanding the mechanisms employed by pathogens to infect their hosts is critical in the development of new and effective therapeutic strategies. The research presented here is one of the first computational approaches to studying host-pathogen PPI networks. This dissertation has two main aims. First, we discuss analytical tools for studying host-pathogen networks to identify common pathways perturbed and manipulated by pathogens. We present the first global comparison of the host-pathogen PPI networks of 190 different pathogens and their interactions with human proteins. We also present the construction and analysis of three highly infectious human-bacterial PPI networks: <i>Bacillus anthracis</i>, <i>Francislla tularensis</i>, and <i>Yersinia pestis</i>. The second aim of the research presented here is the development of predictive models for identifying PPIs between host and pathogen proteins. We present two methods: (i) a domain-based approach that uses frequency of domain-pairs in intra-species PPIs, and (ii) a supervised machine learning method that is trained on known inter-species PPIs. The techniques developed in this dissertation, along with the informative datasets presented, will serve as a foundation for the field of computational pathosystems biology. / Ph. D. Pathosystems Biology Protein Interaction Networks Host-Pathogen Interactions
25	The Role of the Alternaria Secondary Metabolite Alternariol in Inflammation Grover, Shivani 10 January 2016 (has links) Allergic inflammatory disorders of the airway like asthma and atopic asthma are complex, often long-term diseases that generate large public health and socioeconomic footprints especially in developed countries like US, UK and Australia. In 2009, approximately 8.2%, 24.6 million people in United States were affected by asthma. Currently 235 million people are affected by asthma worldwide and about 90% of those have allergic (atopic) asthma. An important factor in patients with allergic respiratory tract diseases is sensitization to fungi. Other risk factors for asthma include inhaled allergens that irritate the airways. Up to 70% of mold allergic patients have skin test reactivity to Alternaria. Alta1, an allergen produced by A. alternata also produces a prolonged and intense IgE mediated reaction in sensitized patients. Therefore A. alternata is not only a risk factor in development of asthma but also can lead to exacerbation of severe and potentially lethal asthma than any other fungus. Despite the well-documented clinical importance of Alternaria in allergic airway diseases, little knowledge exists about the role of individual fungal genes and gene products in theses pathological states besides a small repertoire of allergens and proteolytic enzymes. Moreover, the importance of small, secreted molecules of fungal origin has not been explored whatsoever in regards to immune responses triggered by Alternaria. This study addresses the hypothesis that Alternaria derived small molecule's have immune modulatory properties. A major thrust of this project was to assess the role of Alternaria secondary metabolites that are synthesized by genes called polyketide synthases (PKS) in immune responses of lung epithelial cells. / Master of Science Innate Inflammation Alternaria Alternata Host-Pathogen Interactions Alternariol
26	Etude des interactions hôte-pathogène entre Pseudomonas aeruginosa et Drosophilia melanogaster dans un modèle d'infection intestinale / Study of host-pathogen interactions between Pseudomonas aeruginosa and Drosophila melanogaster in a intestinal infection model Haller, Samantha 18 September 2014 (has links) Au cours de ma thèse je me suis intéressée aux relations hôte-pathogène entre Drosophila melanogaster et Pseudomonas aeruginosa PA14. RhlR, un facteur de transcription bactérien permet à la bactérie d’échapper à la phagocytose. Mon projet de thèse consistait à identifier comment RhlR exerce cette fonction. Mes résultats suggèrent que RhlR exercerait également une fonction indépendante du quorum sensing. Un crible de mutants PA14 nous a permis d’isoler trois gènes importants pour la virulence de la bactérie et possiblement reliés à RhlR: xcpR, vfR et sltB1. L’utilisation de mutants de drosophile tep4, m’a permis de montrer que le rôle d’échappement à la phagocytose se ferait au niveau de la détection de la bactérie. Par ailleurs, mes résultats suggèrent aussi l’intervention d’un composé volatil qui permettrait de synchroniser la virulence de la bactérie. Dans une dernière partie, j’ai étudié les effets d’une co-infection entre un virus entérique et PA14. / During my PhD, I studied the host-pathogen interactions between Drosophila melanogaster and Pseudomonas aeruginosa PA14. We previously identified RhlR as a bacterial transcription factor that allows the bacteria to circumvent phagocytosis. My main PhD project was to study and identify how RhlR exerts this function. My first results suggested that RhlR plays also a role independently its the quorum sensing. A screen of PA14 mutants allowed me to identify three genes involved in PA14 virulence and possibility in RhlR function: xcpR, vfR and sltB1. By using tep4 fly mutants, I have shown that RhlR’s role against phagocytosis is most likely required at the level of PA14 detection. Beside this, my results indicated that possibly a volatile compound is involved to synchronize PA14 virulence. In the last part, I studied the effects of a co-infection between an enteric virus and PA14. Drosophile Pseudomonas aeruginosa Phagocytose Virulence Host-pathogen interactions Drosophila Pseudomonas aeruginosa Phagocytosis Virulence Host-pathogen interactions 572.4 579.3
27	A Novel, Molybdenum-Containing Methionine Sulfoxide Reductase Supports Survival of Haemophilus influenzae in an In vivo Model of Infection Dhouib, Rabeb, Othman, Dk. Seti Maimonah Pg, Lin, Victor, Lai, Xuanjie J., Wijesinghe, Hewa G. S., Essilfie, Ama-Tawiah, Davis, Amanda, Nasreen, Marufa, Bernhardt, Paul V., Hansbro, Philip M., McEwan, Alastair G., Kappler, Ulrike 14 November 2016 (has links) Haemophilus influenzae is a host adapted human mucosal pathogen involved in a variety of acute and chronic respiratory tract infections, including chronic obstructive pulmonary disease and asthma, all of which rely on its ability to efficiently establish continuing interactions with the host. Here we report the characterization of a novel molybdenum enzyme, TorZ/MtsZ that supports interactions of H. influenzae with host cells during growth in oxygen-limited environments. Strains lacking TorZ/MtsZ showed a reduced ability to survive in contact with epithelial cells as shown by immunofluorescence microscopy and adherence/invasion assays. This included a reduction in the ability of the strain to invade human epithelial cells, a trait that could be linked to the persistence of H. influenzae. The observation that in a murine model of H. influenzae infection, strains lacking TorZ/MtsZ were almost undetectable after 72 h of infection, while similar to 3.6 x 10(3) CFU/mL of the wild type strain were measured under the same conditions is consistent with this view. To understand how TorZ/MtsZ mediates this effect we purified and characterized the enzyme, and were able to show that it is an S- and N-oxide reductase with a stereospecificity for S-sulfoxides. The enzyme converts two physiologically relevant sulfoxides, biotin sulfoxide and methionine sulfoxide (MetSO), with the kinetic parameters suggesting that MetSO is the natural substrate of this enzyme. TorZ/MtsZ was unable to repair sulfoxides in oxidized Calmodulin, suggesting that a role in cell metabolism/energy generation and not protein repair is the key function of this enzyme. Phylogenetic analyses showed that H. influenzae TorZ/MtsZ is only distantly related to the Escherichia colt TorZ TMAO reductase, but instead is a representative of a new, previously uncharacterized Glade of molybdenum enzyme that is widely distributed within the Pasteurellaceae family of pathogenic bacteria. It is likely that MtsZ/TorZ has a similar role in supporting host/pathogen interactions in other members of the Pasteurellaceae, which includes both human and animal pathogens. molybdenum enzymes Haemophilus influenzae methionine sulfoxide reductase host-pathogen interaction DMSO reductase enzyme family
28	Rôle des microARNs dans les infections bactériennes chez l’Homme : le modèle Helicobacter pylori / Role of microRNAs in bacterial infections in humans : the Helicobacter pylori model Belair, Cédric 09 December 2010 (has links) Les microARNs, régulateurs post-transcriptionnels de l’expression des gènes eucaryotes, sont impliqués dans la défense contre les pathogènes. Afin de favoriser leur multiplication, les virus et les bactéries ont développé des stratégies pour altérer la voie des miRNAs. Dans ce travail, nous avons montré que Helicobacter pylori, une bactérie responsable chez l’Homme de pathologies gastriques sévères, telles que l’ulcère ou le cancer, réprime un cluster de microARNs spécifique des cellules souches embryonnaires dans une lignée épithéliale gastrique. En utilisant une technique de séquençage à haut débit, nous avons identifié miR-372 comme le miRNA le plus exprimé dans cette lignée gastrique. Avec miR-373, miR-372 permet la prolifération cellulaire réprimant l’expression d’un inhibiteur du cycle cellulaire, the LArge Tumor Suppressor 2 (LATS2). Au cours de l’infection par H. pylori, l’expression de miR-372&373 est réprimée, provoquant une accumulation de LATS2 et un arrêt du cycle cellulaire. De manière importante, la répression de ces miRNAs est dépendante de la translocation de l’effecteur bactérien CagA dans la cellule hôte. Ces données constituent un nouvel exemple d’interaction hôte-pathogène impliquant les miRNAs et ont identifié le couple LATS2/miR-372&373 comme un mécanisme inattendu dans l’arrêt du cycle cellulaire observé au cours de l’infection. Ce mécanisme pourrait refléter l’inhibition de l’auto-renouvellement de l’épithélium gastrique, processus impliqué dans la défense contre les infections bactériennes. / MicroRNAs, post-transcriptionnal regulators of eukaryotic gene expression, are implicated in host defense against pathogens. Viruses and bacteria have evolved strategies to suppress miRNA functions with the aim to establish a sustainable infection. In this work, we report that Helicobacter pylori, a bacterium responsible for severe human gastric inflammatory diseases and cancers, down-regulates an embryonic-specific microRNAs cluster in a gastric epithelial cell line. We reveal by using a deep sequencing approach that hsa-miR-372 is the most abundant miRNA expressed in this gastric cell line where, together with hsa-miR-373, it promotes cell proliferation by silencing the expression of a cell cycle inhibitor, the LArge Tumor Suppressor 2 (LATS2). Upon H. pylori infection, miR-372&373 synthesis is inhibited, leading to the derepression of LATS2 and thus, to a cell cycle arrest at the G1/S transition. Importantly, this down-regulation of a specific cell cycle-regulating microRNA is dependent on the translocation of the bacterial effector CagA into the host cells. These data constitute a novel example of host-pathogen interplay involving microRNAs and unveil the couple LATS2/miR-372&373 as an unexpected mechanism in infection-induced cell cycle arrest in proliferating gastric cells which may be relevant of inhibition of gastric epithelium renewal, a major host defense mechanism against bacterial infections. MicroARNs Helicobacter pylori Cancer gastrique Interactions hôte-pathogène MicroRNAs Helicobacter pylori Gastric cancer Host-pathogen interactions
29	Effecteurs moléculaires de lassociation Crassostrea gigas / Vibrio splendidus. Rôle de la porine OmpU dans les mécanismes de résistance et déchappement à la réponse immunitaire de lhôte. / Molecular effectors of the Crassostrea gigas / Vibrio splendidus interaction. Role of the OmpU porin in resistance and evasion to the immune response. Duperthuy, Marylise 04 November 2010 (has links) Vibrio splendidus LGP32 est une bactérie pathogène associée aux épisodes de mortalités estivales qui affectent la production d'huître Crassostrea gigas depuis des décennies. Nous avons montré ici que la porine OmpU était un effecteur majeur de l'interaction V. splendidus / C. gigas. Nous avons pour cela construit un mutant ΔompU de V. splendidus. Celui-ci nous a permis de mo ntrer l'implication de OmpU (i) dans la résistance de V. splendidus aux antimicrobiens, incluant ceux de l'huître, (ii) dans la « fitness » chez l'huître, et (iii) dans la virulence en infections expérimentales (mortalités de 56 % pour le sauvage versus pour le 11% mutant). En accord avec ces résultats, nous avons montré que la délétion de ompU modifiait la sécrétion de protéines dont l'expression est contrôlée par les voies de régulation de la virulence (ToxR) et de l'intégrité membranaire (SigmaE). Par ailleurs, nous avons montré que OmpU jouait un rôle essentiel dans la reconnaissance par les hémocytes. En effet, (i) in vivo, les gènes hémocytaires répondent différemment à l'infection par le Vibrio sauvage ou ΔompU, et (ii) in vitro, OmpU est nécessaire à l'invasion hémocytaire par V. splendidus. Cette invasion utilise la phagocytose dépendante de l'intégrine b et la SOD extracellulaire du plasma d'huître comme opsonine qui lie OmpU. Ainsi, OmpU est un facteur de virulence majeur qui permet l'infection des hémocytes dans lesquels il est capable de survivre en inhibant la formation de radicaux oxygénés et de vacuoles acides. La résistance du Vibrio aux antimicrobiens hémocytaires de l'huître, elle-même dépendante de OmpU, est probablement un élément supplémentaire favorable à la survie intra-cellulaire. / Vibrio splendidus LGP32 is a bacterial pathogen associated to the summer mortality outbreaks that have affected the production of Crassostrea gigas oysters over the past decades. We showed here that the OmpU porin is a major effector of the V. splendidus / C. gigas interaction. For that, we have constructed a ΔompU mutant of V. splendidus, and shown that the OmpU porin is implicated (i) in the resistance of V. splendidus to antimicrobials, including those of oyster, (ii) in its in vivo fitness, and (iii) in its virulence in oyster experimental infections (mortalities have been reduced from 56 % to 11 % upon mutation). In agreement, we have shown that the ompU deletion modified the expression of secreted proteins controlled by the virulence (ToxR) and the membrane integrity (SigmaE) regulation pathways. Furthermore, we have shown that OmpU has a major role in the recognition of V. splendidus by oyster hemocytes. Indeed, (i) in vivo, hemocyt e genes displayed differential responses to an infection with the wild-type or the ΔompU mutant, and (ii) in vitro, OmpU was necessary for hemocyte invasion by V. splendidus. This invasion process required the hemocyte b-integrin and the oyster plasma extracellular SOD, which was found to act as an opsonin recognizing OmpU. Thus, OmpU is a major virulence factor that allows infection of hemocytes in which V. splendidus is able to survive by inhibiting the production of reactive oxygen species and the formation of acidic vacuoles. Resistance of V. splendidus to hemocyte antimicrobials, which is also OmpU-dependant, is probably an additional determinant of V. splendidus intracellular survival. Interaction hôte / pathogène Échappement immunitaire Immunité innée Host / pathogen interaction Immune evasion Innate immunity
30	Analysis of the CD200R family Akkaya, Munir January 2011 (has links) Paired receptor families, consisting of multiple genetically and structurally similar but functionally opposite activating and inhibitory cell surface receptors, are among the fine tuners of the immune regulation. Recent studies on the evolutionary origin of these receptor families have suggested links to pathogen driven diversification, according to which activating receptors continuously evolve in order to counterbalance pathogens that try to subvert the immune response by stimulating the inhibitory receptor through their virulence factors. This thesis is about the CD200R paired receptor family. This family consists of an inhibitory receptor CD200R which is expressed on various leukocytes and delivers inhibitory signals upon engagement with its ligand CD200. In this study, the possibility that the activating members of the family evolved under pathogen pressure was investigated. Genomic DNA from twenty two different mice strains was screened for the presence of members of CD200R family. The number of activating receptors varied, CD200RLe and CD200RLc were found to be mutually exclusive and three strains possessed previously unknown members of CD200R family. In addition, the possibility that CD200R family members and other paired receptors interacted directly with bacteria was tested with a new assay but only the interaction of PIR-A1 with <em)S. aureus was found as previously reported. The rabbit CD200R family has been characterized and ligand receptor interaction between rabbit CD200 and rabbit CD200R has been demonstrated. However, no interaction between rabbit CD200R and a candidate viral CD200 homologue, the M141R protein of myxoma viruses, could be shown. This finding suggested a CD200R independent role for M141R molecule and possibly other homologues in pox viruses. Finally, two novel antibodies (OX131 and OX132) were characterized together with formerly generated antibodies against mouse CD200R family. The binding specificities and their effects on the CD200-CD200R interaction have been shown. This will help usage of these antibodies in various studies on the functionality and distribution of these receptors. 616.079

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