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Toll-like receptor 5 recognition fo bacterial flagellin /Andersen-Nissen, Erica, January 2006 (has links)
Thesis (Ph. D.)--University of Washington, 2006. / Vita. Includes bibliographical references (leaves 101-125).
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Purification of Soluble Recombinant Salmonella typhimurium Flagellin (FliC) Protein Constructs Expressed in Escherichia coliHooker, Jennifer Ann 17 December 2014 (has links)
A platform for vaccine development has been developed at Georgia State University utilizing recombinant Salmonella typhimurium flagellin (FliC) fused to an antigen that can be overexpressed in Escherichia coli grown in a two-stage fermentation. The flagellin acts as an adjuvant to increase the immunopotency of the fused antigen. Flagellin is the ligand for Toll-like Receptor 5 (TLR5), a part of the innate immune system. Binding of the flagellin:antigen recombinant protein to TLR5 triggers a strong innate and adaptive immune response to the fused antigen leading to a potentially strong protective immunity to the antigen.
Purification of the recombinant FliC fusion protein must meet rigorous criteria in order to be used as a vaccine. One of the major issues in purifying recombinant proteins expressed in a Gram-negative bacterium is the removal of endotoxin. Small amounts of endotoxin present in a vaccine can lead to serious complications, including death. Recombinant proteins are also expressed as either soluble or insoluble protein when over expressed in E. coli. Soluble proteins expressed by the bacterium are properly folded and biologically active, however removal of contaminants such as endotoxin, can be problematic. Insoluble protein is improperly folded and biologically inactive. The insoluble proteins aggregate into inclusion bodies with little or no contaminants associated with the protein, making purification easier. However, in order to restore the biological activity of the insoluble protein, it must first be solubilized and then refolded. This process is often expensive and time consuming, as there is currently no standardized method for protein refolding.
In this study a purification method for the soluble protein of two FliC constructs, full-length FliC and FliC fused to a Marburg virus antigen, was evaluated for effectiveness in purification, removal of endotoxin and maintaining TLR5 activity. The proteins of interest were purified utilizing only the soluble protein containing the properly folded and biologically active recombinant protein. Utilizing methods for purification that take advantage of physical and chemical properties of the protein the recombinant proteins were purified and the level of endotoxin reduced to levels acceptable for use as a vaccine. The TLR5 activity of the soluble recombinant proteins was compared to recombinant protein that had been purified using a denaturing and refolding step. The soluble protein elicited a higher TLR5 response at a lower concentration of protein than the refolded protein. Purification of the soluble fraction also involved fewer step and less time than purification of both the soluble and insoluble protein.
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Immunomodulatory role of flagellin in antigen-presenting cellsVicente-Suarez, Ildefonso. January 2007 (has links)
Dissertation (Ph.D.)--University of South Florida, 2007. / Title from PDF of title page. Document formatted into pages; contains 104 pages. Includes vita. Includes bibliographical references.
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Genetic and Phylogenetic Studies of Toll-Like Receptor 5 (TLR5) in River Buffalo (Bubalus Bubalis)Jones, Brittany 14 March 2013 (has links)
River buffalo are economically important to many countries and only recently has their genome been explored for the purpose of mapping genetic variation in traits of economic and biologic interest. The purpose of this research is to characterize the genetic and evolutionary profile of Toll-like receptor 5 (TLR5), which mediates the mammalian innate immune response to bacterial flagellin.
This study is comprised of three parts: 1) generating a radiation hybrid (RH) map of river buffalo chromosome 5 (BBU5) where the TLR5 gene is located and building a comparative map with homologous cattle chromosomes; 2) conducting a single-nucleotide polymorphism (SNP) survey of the TLR5 gene to reveal variation within river buffalo and other species; and 3) performing an evolutionary study by inferring phylogenetic trees of TLR5 across multiple taxa and determining the possible evolutionary constraints within the TLR5 coding region.
River buffalo chromosome 5 is a bi-armed chromosome with arms corresponding to cattle chromosomes 16 and 29. A BBU5 RH map was developed using the previously published river buffalo RH mapping panel and cattle-derived markers. The RH map developed in this study became an integral part of the first river buffalo whole genome RH map.
Genetic variation of the TLR5 gene was evaluated in a small domestic herd of river buffalo. Sequencing of the TLR5 coding region and partial associated 5'- and 3'-untranslated regions yielded 16 novel SNPs. Six SNPs were identified as non-synonymous with one predicted to potentially code for a functionally altered product.
For the evolutionary study of the TLR5 coding region, phylogenetic trees were inferred based on TLR5 variation across multiple orders and another for artiodactyla. Species that are closely related to river buffalo appear to have undergone negative selection in TLR5 while those that diverged from river buffalo earlier may be retaining alleles that river buffalo are removing from the population.
In conclusion, putative chromosomal rearrangements were identified between river buffalo and cattle, the variation that was uncovered in the TLR5 coding region could potentially lead to differential immunity across species, and there appears be some evolutionary flexibility in the DNA sequence of the TLR5 coding region.
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Caractérisation des propriétés anti-infectieuses de la flagelline, agoniste du Toll-like receptor 5 / Characterization of anti-infectious properties of flagellin, Toll-like receptor 5 agonistPorte, Rémi 18 December 2015 (has links)
De par sa capacité à détecter les microorganismes et à mettre en place une défense anti-infectieuse rapide, l’immunité innée représente la première ligne de défense de l’hôte. La réponse immunitaire innée est déclenchée par des motifs microbiens moléculaires universels et conservés reconnus par des récepteurs innés parmi lesquels les "Toll-like Receptors" (TLR). L’activation de ces récepteurs induit une inflammation locale et une réponse antimicrobienne adaptée au pathogène. Ces propriétés biologiques ont permis de d’envisager l’utilisation des TLR comme cible thérapeutique antiinfectieuse. Dans ce contexte il a été montré que la flagelline, le composant majeur des flagelles bactériens et le seul agoniste de TLR5 décrit à ce jour, possédait des propriétés anti-infectieuses. Des études chez la souris ont montré que la flagelline induisait une forte production, par des cellules lymphoïdes innées, d’IL-22, une cytokine impliquées dans la protection des muqueuses. Par ailleurs, la forte expression de TLR5 par les cellules épithéliales laisse présager un rôle de ces cellules dans les propriétés anti-infectieuses de la flagelline. Toutefois, les mécanismes moléculaires et cellulaires effecteurs responsables des effets antimicrobiens de l’agoniste de TLR5 restent à définir.Au cours de ce travail de thèse, nous avons étudié les capacités anti-infectieuses de la flagelline dans deux modèles infectieux chez la souris. Nous avons tout d’abord montré que l’administration systémique de flagelline, en prophylaxie c’est-à-dire préalablement au challenge infectieux, permettait de protéger d’une infection intestinale par Yersinia pseudotuberculosis. La protection induite par la flagelline est observable lors d’une infection par la voie muqueuse mais est absente lors d’un challenge infectieux par la voie systémique, démontrant ainsi le caractère muqueux de la protection. L’effet protecteur de la flagelline dans notre modèle est dépendant de l’expression de TLR5 et indépendant de l’IL-22. Cette étude suggère donc un mécanisme original de protection médié par la flagelline, indépendant de l’IL-22.Nous avons également analysé la capacité anti-infectieuse de la flagelline dans un modèle murin d’infection respiratoire à Streptococcus pneumoniae. Nous avons notamment montré que la flagelline pouvait être utilisée en thérapeutique lorsqu’elle était associée à un antibiotique. En effet, l’association d’amoxicilline ou de co-trimoxazole avec la flagelline (voie intranasale) a permis de protéger des souris infectées par une dose létale de S. pneumoniae comparativement à l’antibiotique seul. L’efficacité de cette thérapie est dépendante de l’activation de TLR5 et est associée à une infiltration pulmonaire importante de polynucléaires neutrophiles. Ce traitement combinatoire améliore également la protection dans un modèle de surinfection pneumococcique post-grippale. Ces résultats montrent que la combinaison agoniste de TLR5/antibiotique améliore la réponse anti-infectieuse pulmonaire et permettent d’envisager de nouvelles stratégies antibactériennes dans le cas d’infections où les antibiotiques montrent leurs limites (infections nosocomiales, bactéries multirésistantes…). / With its ability to sense micro-organisms and to induce a rapid defense against infections, innate immunity represents the first line of host’s defense. The innate immune response is triggered by universal and conserved microbial molecular patterns recognized by innate receptors including the Toll-like receptors (TLRs). Activation of these receptors induces local inflammation and antimicrobial response against pathogens. These biological properties have allowed considering the use of TLR as anti-infective therapeutic target. In this context it has been shown that flagellin, the major component of bacterial flagella and the agonist of TLR5, had anti-infectious properties. It was shown that flagellin induces a strong production by innate lymphoid cells of IL-22, a cytokine involved in the protection of mucosa. Furthermore, the strong expression of TLR5 by epithelial cells suggests a role for these cells in the anti-infectious properties of flagellin. However, the molecular and cellular mechanisms responsible for the antimicrobial effects of the TLR5 agonist remained to be defined.In this thesis, we studied the anti-infectious properties of flagellin in two infectious murine models. We first showed that systemic administration of flagellin, prior to infectious challenge, protect against an intestinal infection with Yersinia pseudotuberculosis. The protection induced by flagellin is observable upon infection by mucosal route but is absent during a challenge by the systemic route, thus demonstrating the role of the mucosa for the protection. The anti-bacterial effect in this model is dependent on the expression of TLR5 and independent of the innate lymphoid cells’ IL-22 production. This study suggests a novel mechanism of flagellin-mediated protection, independent of the IL-22.We also analyzed the anti-infectious abilities of flagellin in a murine model of respiratory infection by Streptococcus pneumoniae. In particular, we showed that flagellin could be used in therapy when combined to an antibiotic. Indeed, the combination of amoxicillin or co-trimoxazole with flagellin protected mice infected with a lethal dose of S. pneumoniae compared to antibiotic standalone. The effectiveness of this therapy was dependent on the activation of TLR5 and was associated with pulmonary infiltration of neutrophils. This combinatory treatment also improved the protection in a model of post-influenza pneumococcal superinfection. These results show that the combination of TLR5 agonist / antibiotic ameliorates pulmonary anti-infectious response and allow to consider new antibacterial strategies against infections when antibiotics reach their limits (nosocomial infections, multiresistant bacteria ...).
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Inhibition of The NF-κB Signaling Pathway and Its Effects On Apoptosis and CancerLupica, Joseph A. 15 July 2008 (has links)
No description available.
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