Global ETD Search

41	Generation and characterization of an attenuated mutant in a response-regulator gene of Francisella tularensis live vaccine strain (LVS) Sammons, Wendy L. January 2007 (has links) Dissertation (Ph.D.)--University of South Florida, 2007. / Includes vita. Includes bibliographical references. Also available online.
42	Elucidating the virulence control network in Francisella tularensis Levasseur, Kathryn 04 June 2015 (has links) The Gram-negative bacterium Francisella tularensis is the causative agent of tularemia and a model intracellular pathogen. It is also considered a potential bioweapon, as F. tularensis is highly infectious and has the potential to cause fatal disease in humans. Many factors required for F. tularensis virulence have been identified, yet we know relatively little regarding how these factors are regulated at the level of transcription. In order to further understand the regulation of virulence factors in F. tularensis, we have systematically determined the genomic regions associated with all of the transcription factors implicated in virulence using chromatin immunoprecipitation coupled with high-throughput DNA sequencing (ChIP-Seq). Microbiology Molecular biology ChIP-Seq Francisella tularensis gene regulation transcription tularemia virulence
43	Identification of a vaccine candidate in protein extracts from francisella tularensis Sikora, Christopher A., University of Lethbridge. Faculty of Arts and Science January 2003 (has links) Francisella tularensis is one of a small group of bacteria recognized for their virulence and potential for use as biological weapons. In this study we utilize a novel approach to identify an immunologically prominent component of F. tularensis that appears to be a promising vaccine candidate. Francisella is an intracellular pathogen that infects cells of the reticuloendothelial system. Other bacteria, such as Brucella spp. have this part of their life cylce in common. However, while mice injected with Brucella spp. survive and produce antibodies to the bacteria which are immunologically reactive not only with Brucella spp. but, also with Francisella. When we vaccinated mice with a B. abortis O-linked polysaccharide (OPS) and then challenged them with 10 LD50F.tularensis LVS, 60% survived. Sera from Brucella OPS-primed/F.tularensis-challenged mice was used to identify immune reactive proteins from F. tularensis. A novel 52 kDa fraction was identified. While vaccination of mice with this partially purified fraction only provided 20% protection to F.tularensis challenged mice, both whole cell extracts and a partially purified soluble fraction (>30kDa) given to Brucella-vaccinated mice were 100% protective. The 52 kDa enriched fraction elicited a rudimentary cytokine burst of nitric oxide in a cell culture of J774.1 macrophages. The 52 kDa fraction was degraded by proteinase K and appeared to decrease in size to 36 kDa in the presence of DNAase, suggesting a possible protein and nucleic acid composition. The host response to F. tularensiss infection is complex, but given the ability of the 52 kDa component to protect against live vaccine challenge, and its apparent ability to elicit a cytokine burst, this component may have potential use in future vaccine production. / xii, 97 leaves ; 29 cm. Dissertations, Academic Francisella tularensis -- Research Vaccines -- Biotechnology -- Research Tularemia -- Vaccination -- Research
44	Mechanisms of the intracellular survival of Francisella tularensis Tancred, Linda January 2011 (has links) Francisella tularensis is a gram-negative, highly virulent, intracellular bacterium which causes the zoonotic disease tularemia. The subspecies tularensis and holarctica are clinically important, and the former is the more virulent. The intracellular lifestyle of F. tularensis is not completely understood, but after uptake in monocytes, the bacterium escapes from the phagosome within hours and replicates massively in the cytosol. The escape is dependent on factors encoded by the Intracellular Growth Locus (igl) operon, located in the Francisella Pathogenicity Island, FPI. The thesis was aimed to clarify and understand the interaction of F. tularensis strains with the endosomal pathway of monocytic cells in general and the roles of the Igl proteins and the global regulator MglA for this interaction in particular. A focus has also been to elucidate the roles of reactive oxygen and nitrogen species for the intracellular host-parasite interaction. We show that mutants in the IglB, IglC, or IglD proteins or their regulator MglA of the live vaccine strain, LVS (subspecies holarctica), all demonstrated reduced replication rates and lowered cytopathogenicity compared to the wild type in a J774 mouse macrophage cell model. Colocalization with LAMP-1 was significantly increased for the IglC, IglD and MglA mutants compared to LVS. This indicated an impaired ability to escape into the cytoplasm, while at the same time they, like LVS, partly prevented fusion with lysosomes. IFN-γ activation of the J774 host cells prior to infection had a bactericidal effect on LVS and all of the mutants, though the cidal effect was significantly more pronounced for the mutants. Following IFN-γ activation, a majority of the mutant-containing phagosomesfused with lysosomeswhile LVS remained localized in the cytosol without significantly increased interactions with the endosomal pathway. Previous studies have revealed that IFN-γ activation of F. tularensis-infected macrophages leads to control of infection but conclusions about the importance of reactive nitrogen and oxygen species on bacterial killing are inconsistent. We found that the growth inhibition resulting from IFN-γ activation could not be attributed to an increased oxidative burst since PMA-induced superoxide production was still inhibited by LVS to the same extent as in non-activated macrophages. On the other hand, reactive nitrogen species may in part have contributed to the cidal effect. To further assess the role of reactive nitrogen species to the killing of F. tularensis, nitric oxide was administrated exogenously to J774 cells infected with LVS. This led to significant killing of intracellular LVS with a concomitant increased phagosomal localization and downregulation of the virulence gene regulator mglA. These effects were reversed by addition of a peroxynitrite decomposition catalyst. A spontaneous avirulent mutant of subspecies tularensis, strain FSC043, was previously demonstrated to provide protective immunity in mice. Here, microscopic analyses of the strain revealed an unusual intracellular localization with a delayed phagosomal escape. This may account for the low virulence, while at the same time FSC043 remains immunogenic and thereby confers protection. The igl operon is intact in strain FCS043 and we hypothesize that a defect in the FPI gene pdpC contributed to the observed phenotype. Altogether, this thesis work demonstrates the importance of the mglA and igl genes for the virulence of F. tularensis and specifically their important roles for a functional phagosomal escape and inhibition of the host cell oxidative burst. Also, addition of exogenous nitric oxide likely leads to formation of peroxynitrite intracellularly, a reactive molecule which confines the bacterium to the phagosome and confers a significant bactericidal effect on intracellular F. tularensis. Francisella tularensis Igl MglA J774 IFN-γ RNS ROS phagosome Clinical bacteriology Klinisk bakteriologi
45	Cutaneous resistance against Francisella tularensis / Stenmark, Stephan, January 2004 (has links) Diss. (sammanfattning) Umeå : Univ., 2004. / Härtill 4 uppsatser.
46	Interaction between waterborne pathogenic bacteria and Acanthamoeba castellanii / Abd, Hadi, January 2006 (has links) Diss. (sammanfattning) Stockholm : Karol. inst., 2006. / Härtill 4 uppsatser.
47	Generation and characterization of an attenuated mutant in a response-regulator gene of Francisella tularensis live vaccine strain (LVS) Sammons, Wendy L. January 2007 (has links) Dissertation (Ph.D.)--University of South Florida, 2007. / Title from PDF of title page. Document formatted into pages; contains 93 pages. Includes vita. Includes bibliographical references.
48	Environmental factors selecting for predation resistant and potentially pathogenic bacteria in aquatic environments Mathisen, Peter January 2017 (has links) The long history of co-existence of bacteria and their protozoan predators in aquatic environments has led to evolution of protozoa resistant bacteria (PRB). Many of these bacteria are also pathogenic to humans. However, the ecological drivers determining the occurrence of different types of PRB in aquatic environments, and the eco-evolutionary link between bacterial adaptation and the resulting implications for mammalian hosts are poorly known. This thesis examines the impact of nutrients and predation on PRB, as well as the ecological and evolutionary connection between their life in aquatic environments and mammalian hosts. In the first study seven bacterial isolates from the Baltic Sea were investigated for their plasticity of adaptation to predation. The response to predation showed large variation where some bacteria rapidly developed a degree of grazing resistance when exposed to predators. The rapid adaptation observed may result in bacterial communities being resilient or resistant to predation, and thus rapid adaptation may be a structuring force in the food web. With the aim to elucidate the link between occurrence of PRB and environmental conditions, a field study and a laboratory experiment were performed. In both studies three PRB genera were found: Mycobacterium, Pseudomonas and Rickettsia. PRB were found both in oligotrophic and eutrophic waters, indicating that waters of all nutrient states can harbor pathogenic bacteria. However, the ecological strategy of the PRB varied depending on environmental nutrient level and disturbance. Using an advanced bioinformatic analysis, it was shown that ecotypes within the same PRB genus can be linked to specific environmental conditions or the presence of specific protozoa, cyanobacteria or phytoplankton taxa. These environmental conditions or specific plankton taxa could potentially act as indicators for occurrence of PRB. Finally, using four mutants (with specific protein deletions) of the pathogenic and predation resistant Francisella tularensis ssp. holarctica, I found evidence of an eco-evolutionary connection between the bacterium´s life in aquatic and mammalian hosts (aquatic amoeba Acanthamoeba castellanii and a murine macrophage). To a large extent F. t. holarctica use similar mechanisms to persist predation by protozoa and to resist degradation by mammal macrophages. To summarize I found a link between predation resistant bacteria in aquatic environments and bacteria that are pathogenic to mammals. Further, I showed that different environmental conditions rapidly selects for PRB with either intracellular or extracellular lifestyles. This thesis provides insights regarding environmental conditions and biomarkers that can be used for assessment of aquatic environments at risk for spreading pathogenic bacteria. / <p>Medfinansiärer var även: Swedish Ministry of Defence (A4040, A4042, A404215, A404217), Swedish Minestry of Foreign Affairs (A4952), Swedish Civil Contingencies Agency (B4055)</p> Eutrophication productivity predation pressure predation-resistant bacteria pathogens Francisella tularensis adaptation biomarker oligotyping Ecology Ekologi
49	Genomic Instability and Gene Dosage Obscures Clues to Virulence Mechanisms of F. tularensis species Modise, Thero 06 September 2016 (has links) The pathogen Francisella tularensis subsp. tularensis has been classified as a Center for Disease Control (CDC) select agent. However, little is still known of what makes the bacteria cause dis-ease, especially the highly virulent type A1 strains. The work in this dissertation focused on type A1 strains from the Inzana laboratory, including a wildtype virulent strain TI0902, an avirulent chemical mutant strain TIGB03 with a Single Nucleotide Polymorphism in the wbtK gene, and several complemented mutants, [wbtK+]TIGB03, with dramatic differences in virulence and growth rates. One of the complemented clones (Clone12 or avp-[wbtK+]TIGB03-C12) was aviru-lent, but protected mice against challenge of a lethal dose of TI0902 and was considered as a possible vaccine strain. Whole genome sequencing was performed to identify genetic differences between the virulent, avirulent and protective strains using both Roche/454 and Illumina next-generation sequencing technologies. Additionally, RNASeq analysis was performed to identify differentially expressed genes between the different strains. This comprehensive genomic analysis revealed the critical role of transposable elements in inducing genomic instability resulting in large du-plications and deletions in the genomes of the chemical mutant and the complemented clones that in turn affect gene dosage and expression of genes known to regulate virulence. For exam-ple, whole genome sequencing of the avirulent chemical mutant TIGB03 revealed a large 75.5 kb tandem duplication flanked by transposable elements, while the genome of a virulent Clone01 (vir-[wbtK+]TIGB03-C1) lost one copy of the 75.5 kb tandem duplicated region but gained a tandem duplication of another large 80kb region that contains a virulence associated transcription factor SspA. RNAseq data showed that the dosage effect of this extra region in Clone1 suppresses expression of MglA regulated genes. Since MglA regulates genes that are known to be crucial for virulence, including the well-studied Francisella Pathogenicity Island (FPI), these results suggest that gene dosage effects arising from large duplications can trigger unknown virulence mechanisms in F. tularensis subsp. tularensis. These results are important especially when designing live vaccine strains that have repeated insertion elements in their genomes. / Ph. D. Francisella tularensis genome instability vaccine transposase inversion duplica-tion deletion RNAseq DNAseq Assembly Gene Dosage Pathogen
50	The Detection and Molecular Evolution of Francisella tularensis Subspecies Gunnell, Mark K 01 November 2015 (has links) (PDF) Francisella tularensis is the etiological agent of tularemia, a zoonotic disease with worldwide prevalence. F. tularensis is a highly pathogenic organism and has been designated as a potential biothreat agent. Currently there are four recognized subspecies of F. tularensis: tularensis (type A), holarctica (type B), mediasiatica, and novicida. In addition, genomic studies have further subdivided type A tularensis into two subclassifications, type A.I and type A.II. These two subclassifications differ in geographic distribution with type A.I appearing mainly in the Eastern United States and type A.II appearing mainly in the Western United States. Because of differences of virulence among the subspecies, it is important to be able to quickly identify each of the subspecies rapidly and accurately. This work describes the development of a multiplex real-time polymerase chain reaction (PCR) assay which was shown to be ~98% successful at identifying the known subspecies of F. tularensis. Furthermore, F. tularensis is thought be a genome in decay (losing genes) because of the relatively large number of pseudogenes present in its genome. We hypothesized that the observed frequency of gene loss/pseudogenes may be an artifact of evolution in response to a changing environment, and that genes involved in virulence should be under strong positive selection. Eleven arbitrarily chosen virulence genes were screened for positive selection along with 10 arbitrarily chosen housekeeping genes. Analyses of selection yielded one housekeeping gene and 7 virulence genes which showed significant evidence of positive selection. Our results suggest that while the loss of functional genes through disuse could be accelerated by negative selection, the genome decay in Francisella could also be the byproduct of adaptive evolution, as evidenced by several of its virulence genes which are undergoing strong, positive selection. Francisella tularensis real-time PCR detection genome decay genome sequencing natural selection virulence TreeSAAP Microbiology

Search results