Global ETD Search

861	Pseudomonas aeruginosa: a formidable and ever-present adversary. Kerr, Kevin G., Snelling, Anna M. January 2009 (has links) No / Pseudomonas aeruginosa is a versatile pathogen associated with a broad spectrum of infections in humans. In healthcare settings the bacterium is an important cause of infection in vulnerable individuals including those with burns or neutropenia or receiving intensive care. In these groups morbidity and mortality attributable to P. aeruginosa infection can be high. Management of infections is difficult as P. aeruginosa is inherently resistant to many antimicrobials. Furthermore, treatment is being rendered increasingly problematic due to the emergence and spread of resistance to the few agents that remain as therapeutic options. A notable recent development is the acquisition of carbapenemases by some strains of P. aeruginosa. Given these challenges, it would seem reasonable to identify strategies that would prevent acquisition of the bacterium by hospitalised patients. Environmental reservoirs of P. aeruginosa are readily identifiable, and there are numerous reports of outbreaks that have been attributed to an environmental source; however, the role of such sources in sporadic pseudomonal infection is less well understood. Nevertheless there is emerging evidence from prospective studies to suggest that environmental sources, especially water, may have significance in the epidemiology of sporadic P. aeruginosa infections in hospital settings, including intensive care units. A better understanding of the role of environmental reservoirs in pseudomonal infection will permit the development of new strategies and refinement of existing approaches to interrupt transmission from these sources to patients. Review Pseudomonas aeruginosa Hospital acquired infection Opportunistic pathogen Hospital environment Infection control Bacterial resistance
862	Bacterial attachment to polymeric materials correlates with molecular flexibility and hydrophilicity Sanni, O., Chang, Chien-Yi, Anderson, D.G., Langer, R., Davies, M.C., Williams, P.M., Williams, P., Alexander, M.R., Hook, A.L. 09 December 2014 (has links) Yes / A new class of material resistant to bacterial attachment has been discovered that is formed from polyacrylates with hydrocarbon pendant groups. In this study, the relationship between the nature of the hydrocarbon moiety and resistance to bacteria is explored, comparing cyclic, aromatic, and linear chemical groups. A correlation is shown between bacterial attachment and a parameter derived from the partition coefficient and the number of rotatable bonds of the materials' pendant groups. This correlation is applicable to 86% of the hydrocarbon pendant moieties surveyed, quantitatively supporting the previous qualitative observation that bacteria are repelled from poly(meth)acrylates containing a hydrophilic ester group when the pendant group is both rigid and hydrophobic. This insight will help inform and predict the further development of polymers resistant to bacterial attachment. / Wellcome Trust (grant number 085245) and EMRP (IND56) Low-fouling Molecular descriptors Polymer microarrays Pseudomonas aeruginosa Ion mass spectrometry
863	Modulation of host biology by Pseudomonas aeruginosa quorum sensing signal molecules: messengers or traitors Liu, Y., Chan, K., Chang, Chien-Yi 09 November 2015 (has links) Yes / Bacterial cells sense their population density and respond accordingly by producing various signal molecules to the surrounding environments thereby trigger a plethora of gene expression. This regulatory pathway is termed quorum sensing (QS). Plenty of bacterial virulence factors are controlled by QS or QS-mediated regulatory systems and QS signal molecules (QSSMs) play crucial roles in bacterial signaling transduction. Moreover, bacterial QSSMs were shown to interfere with host cell signaling and modulate host immune responses. QSSMs not only regulate the expression of bacterial virulence factors but themselves act in the modulation of host biology that can be potential therapeutic targets. / Open Access Funding from the University of Dundee.Also supported by the University of Malaya High Impact Research Grants (UMC/625/1/HIR/MOHE/CHAN/01,A-000001-50001,and UM C/625/1/HIR/MOHE/CHAN/14/1, H-50001-A000027) Quorum sensing N-acyl homoserine lactones Pseudomonas quinolone signal Pseudomonas aeruginosa Immunomodulation
864	Inhibiting N-acyl-homoserine lactone synthesis and quenching Pseudomonas quinolone quorum sensing to attenuate virulence Chan, K., Liu, Y., Chang, Chien-Yi 19 October 2015 (has links) Yes / Bacteria sense their own population size, tune the expression of responding genes, and behave accordingly to environmental stimuli by secreting signaling molecules. This phenomenon is termed as quorum sensing (QS). By exogenously manipulating the signal transduction bacterial population behaviors could be controlled, which may be done through quorum quenching (QQ). QS related regulatory networks have been proven their involvement in regulating many virulence determinants in pathogenic bacteria in the course of infections. Interfering with QS signaling system could be a novel strategy against bacterial infections and therefore requires more understanding of their fundamental mechanisms. Here we review the development of studies specifically on the inhibition of production of N-acyl-homoserine lactone (AHL), a common proteobacterial QS signal. The opportunistic pathogen, Pseudomonas aeruginosa, equips the alkylquinolone (AQ)-mediated QS which also plays crucial roles in its pathogenicity. The studies in QQ targeting on AQ are also discussed. / University of Malaya High Impact Research Grants (UMC/625/1/HIR/MOHE/CHAN/01, A-000001-50001,and UMC/625/1/HIR/MOHE/CHAN/14/1, H-50001-A000027) Quorum sensing Quorum quenching N-acyl-homoserine lactone Pseudomonas quinolone signal Pseudomonas aeruginosa Alkylquinolone
865	Surface sensing for biofilm formation in Pseudomonas aeruginosa Chang, Chien-Yi 01 September 2018 (has links) Yes / Aggregating and forming biofilms on biotic or abiotic surfaces are ubiquitous bacterial behaviors under various conditions. In clinical settings, persistent presence of biofilms increases the risks of healthcare-associated infections and imposes huge healthcare and economic burdens. Bacteria within biofilms are protected from external damage and attacks from the host immune system and can exchange genomic information including antibiotic-resistance genes. Dispersed bacterial cells from attached biofilms on medical devices or host tissues may also serve as the origin of further infections. Understanding how bacteria develop biofilms is pertinent to tackle biofilm-associated infections and transmission. Biofilms have been suggested as a continuum of growth modes for adapting to different environments, initiating from bacterial cells sensing their attachment to a surface and then switching cellular physiological status for mature biofilm development. It is crucial to understand bacterial gene regulatory networks and decision-making processes for biofilm formation upon initial surface attachment. Pseudomonas aeruginosa is one of the model microorganisms for studying bacterial population behaviors. Several hypotheses and studies have suggested that extracellular macromolecules and appendages play important roles in bacterial responses to the surface attachment. Here, I review recent studies on potential molecular mechanisms and signal transduction pathways for P. aeruginosa surface sensing. / This work is supported by University of Bradford Surface sensing Biofilm Pseudomonas aeruginosa Cyclic-di-GMP Type IV pili
866	Development of a numerical model to simulate the biological inactivation of airborne microorganisms in the presence of ultraviolet light. Noakes, C.J., Fletcher, L.A., Beggs, Clive B., Sleigh, P.A., Kerr, Kevin G. January 2004 (has links) No / The effectiveness of any ultraviolet germicidal irradiation (UVGI) system is governed by the passage of airborne microorganisms through the UV field. This paper describes a new method for evaluating the performance of UVGI devices using computational fluid dynamic (CFD) simulations. A microorganism inactivation equation is combined with a scalar transport equation to describe the concentration of airborne microorganisms in the presence of a UV field. The solution of this equation, in conjunction with the momentum and turbulent energy equations, allows the effect of both the airflow and the UV field on the microorganism distribution to be examined. Solutions are shown for the airflow and microorganism concentration through a bench scale flow apparatus, at five different UV intensities. The results from the CFD model are validated against the experimental data, obtained from the flow apparatus, for aerosolised Pseudomonas aeruginosa microorganisms. Good comparisons are seen, giving confidence in the application of the technique to other situations. Bacteria Pseudomonadales Pseudomonadaceae Infection Bacteriosis Mycobacterial infection Pseudomonas aeruginosa Tuberculosis Microorganism Inactivation
867	Mechanistic Studies of the Roles of the Transcriptional Activator ExsA and Anti-activator Protein ExsD in the Regulation of the Type Three Secretion System in Pseudomonas aeruginosa Shrestha, Manisha 19 June 2018 (has links) Pseudomonas aeruginosa is a ubiquitous opportunistic pathogen that is a substantial threat, particularly in hospital settings, causing severe infections in immunocompromised patients that may lead to death. Pseudomonas aeruginosa harbors a multitude of virulence factors that enable this pathogen to establish both acute and chronic infections in humans. A key determinant of acute infections is a hollow molecular needle structure used for injecting toxins into a host cell, called the type three secretion system (T3SS). The secretion machinery itself is highly complex and, together with the specific secreted factors, requires expression of more than 30 genes. Due to the high energy cost of its synthesis to the organism this system is highly regulated to finely time gene expression to coincide with host contact. ExsA, a member of the AraC-type transcription factor family, is the main transcriptional activator of all the genes necessary for expression of the T3SS. Members of the AraC family are characterized by the presence of two helix-turn-helix (HTH) motifs, which bind to the promoter DNA and activate transcription. ExsA uses its HTH containing C-terminal domain (CTD) to regulate gene expression from 10 different promoters. The N-terminal domain (NTD) of ExsA mediates dimerization and regulation of ExsA-activity. While most AraC-type activators are regulated by a small molecule ligands, ExsA is regulated by another protein, ExsD. As part of a four-protein signaling cascade, ExsD interacts directly with ExsA to prevent transcription of T3SS-associated genes under non-inducing conditions prior to host cell contact. The entire regulatory cascade includes of two additional proteins, ExsC and ExsE. ExsA, ExsC, ExsD, and ExsE follow a partner-switching mechanism to link expression of the secretion system with host cell contact. Our laboratory is working to understand this unique signaling mechanism by determining the molecular basis for the regulation of this important virulence factor. Previous studies in the laboratory have solved the structures of ExsE, ExsC and ExsD, and shed light on how these proteins interact and compete for overlapping binding sites. However, it is still unclear as to how the ExsA and ExsD interact and thus how regulation is mediated at the molecular level. In the presented study, we sought to map the molecular interface between ExsA and ExsD. First, the crystal structure of ExsA-NTD is presented wherein the dimerization interface of the protein was identified. Two of the well-studied AraC-type proteins, AraC and ToxT crystal structures have been solved by others in the presence of their respective ligands. Residues that were involved in ligand binding in AraC and ToxT were aligned with the residues in ExsA and analyzed for interaction with ExsD. However, this canonical binding pocket appeared to be not involved in the interaction between ExsA and ExsD. Structure directed site-specific mutagenesis was carried out to construct many different variants of ExsD and ExsA. Thus constructed variants were purified and analyzed in a functional assay. Using this approach, we were able to identify regions on ExsD and ExsA that are crucial for the interaction and for the regulation of ExsA-dependent transcription. It turns out that backbone interactions between the amino-terminal residues of ExsD and the beta-barrel region of the ExsA-NTD are pivotal. This result explains how ExsA and ExsC compete for ExsD binding, since both target the same regions on ExsD. / PHD / Pseudomonas aeruginosa is an opportunistic pathogen that is notorious for causing severe infections in immunocompromised individuals. Acute Pseudomonas aeruginosa infections are characterized by immediate adverse effects. An initial acute infection may become chronic, leading to long-term morbidity and mortality in affected individuals. During the initial stages of infection P. aeruginosa uses the type three secretion system, a syringe-like structure, to puncture the host cell and inject potent toxins. The activation of the genes required for forming this structure is tightly controlled by an activator protein, ExsA. When P.aeruginosa is not invading a host, ExsA is inhibited by another protein called ExsD, to prevent the needless production of the secretion apparatus. The presented work explores the mechanism of how ExsD achieves this inhibition of ExsA. This information is of potential biomedical interest because a clear understanding of the molecular basis for the interaction could inform the development of a small-molecule mimic of ExsD to be used in therapy. In Chapter 2 we report the structure of the domain of ExsA that is known to bind ExsD. Also, in this chapter and more so in Chapter 3, we performed a detailed analysis of potential interacting regions and ultimately succeeded in identifying key interacting regions in both ExsA and ExsD. transcription activator type three secretion system pseudomonas aeruginosa Crystal structure site-directed mutagenesis
868	Light affects metabolism in Pseudomonas aeruginosa biofilms Eckartt, Kelly January 2024 (has links) Many species of bacteria naturally exist in multicellular structures called biofilms, which are formed when microbes excrete an adherent polymeric matrix. The biofilm lifestyle offers protection from environmental attacks. However, the high density of biomass within these structures also promotes the formation of resource gradients and therefore internal microenvironments with distinct conditions. Unlike the well-mixed liquid cultures routinely used for research, biofilms thus contain differentiated subpopulations that perform different metabolic processes. Such metabolic heterogeneity benefits multicellular systems by allowing for division of labor and cross-feeding of metabolites. Importantly, it also contributes to the robustness of the overall population because metabolic subpopulations commonly differ with respect to their abilities to survive environmental changes or drug treatments. Pseudomonas aeruginosa is a chemotrophic opportunistic pathogen that avidly forms biofilms. It is a leading cause of infections in humans and can occupy a variety of sites, including burn and non-healing skin wounds. One factor that allows the bacterium to thrive in a wide range of environments is its metabolic versatility. P. aeruginosa is able to use oxygen and N-oxides as terminal electron acceptors and produces redox active small molecules called phenazines that support metabolic activity in oxygen-limited biofilm subzones. In many of the environments it inhabits P. aeruginosa is exposed to sunlight, which can act as an environmental cue and can damage light-sensitive enzymes. Light sensing proteins are found in diverse chemotrophic bacteria and have been studied structurally and biochemically for decades. In fact, the bacteriophytochrome BphP, purified from P. aeruginosa, was identified and biochemically characterized in the 1990’s. The physiological role of BphP, and light sensing in general, is still an active field of study. Recently light has been shown to play roles in inhibiting biofilm macrostructure formation, inhibiting aerobic respiration, and providing anticipatory protection from osmotic stress in various pseudomonads. My thesis aims to investigate how light affects metabolism in P. aeruginosa biofilms. Chapter 1 provides the necessary background about bacterial multicellularity, light as an environmental factor, and the relevant aspects of P. aeruginosa metabolism. Chapter 2 explores the phenomenon of the inhibitory effect of light on aerobic respiration. Light/dark and temperature cycling elicits transcriptomically entrenched rings of high and low aerobic respiration which is not restricted to a singular color of light within the visible light spectrum. This chapter also highlights the role of the bacteriophytochrome BphP in red light-dependent respiratory switching. Chapter 3 further explores how the light effect is altered in response to changing the redox state of the biofilm. Light has distinct effects on the use of specific respiratory pathways, on oxygen consumption, and on metabolic activity based on the location in the biofilm and the availability of electron acceptors. Chapter 4 identifies the white light and red light-dependent proteome of P. aeruginosa biofilms and additionally determines the red light-dependent BphP regulon. This chapter also highlights how conversion of BphP between photostates is necessary for red light-dependent respiratory switching in P. aeruginosa biofilms. Understanding how P. aeruginosa metabolism is modulated by light provides information as to how this bacterium thrives in diverse environments, and investigating the phenomenon in a biofilm model expands the relevance of this research. Because they define the relationships between light exposure and physiological responses in an important pathogen, the observations presented in this thesis constitute foundational work with the potential to inform treatment conditions for biofilm based infections. Microbiology Pseudomonas aeruginosa Bacteria--Metabolism Biofilms Light--Physiological effect Phytochrome Spectrum, Solar
869	Greywater treatment for reuse by slow sand filtration : study of pathogenic microorganisms and phage survival / Traitement des eaux grises par filtration lente pour leur réutilisation : étude de la survie micro-organismes pathogènes et des bactériophages Khalaphallah, Rafat 14 September 2012 (has links) Dans les dernières décennies, la plupart des pays du monde ont connu une pénurie d'eau et l’augmentation du taux de consommation. Aujourd'hui, tous les pays dans le monde essayent de trouver des alternatives pour remédier à cette pénurie. Une solution consiste en la réutilisation des eaux grises (GW) pour l'irrigation après traitement. Les GW correspondent aux eaux usées générée dans une maison à l'exception de l'eau des toilettes. Les risques associés à la réutilisation de ces eaux est la présence de microorganismes pathogènes qui peuvent infecter les humains, les animaux et les plantes. Dans cette thèse centrée sur l'étude de la survie des représentants d'agents pathogènes, comme E. coli, P. aeruginosa, et le bactériophage MS2 qui sont trouvés dans les eaux grises. Il a été étudié l’effet de quelques facteurs physico-chimiques tels que; température (6 ± 2,23 ± 2 et 42 ± 2 ° C), la salinité (1,75 and 3.5% de NaCl), de l'oxygène (aérobie et anaérobie), des éléments nutritifs (milieu riche et de milieux pauvres), la lumière avec la photocatalyse (lampes UV et visible) et filtre à sable lent (sable du désert égyptien et le sable piscine). Une combinaison de la température, la lumière du soleil et de haute photocatlysis sont principalement responsables de la baisse rapide des bactéries et du coliphage MS2. Le filtre à sable lent a une influence nettement moindre sur la survie des bactéries dans les eaux grises, mais il est efficace pour diminuer la turbidité et de la DCO. / In recent decades, most countries of the world have experienced a shortage of water and increase its rate of consumption. Today, every country in the world are interested in this problem by trying to find alternatives to address this shortage. One solution is reuse greywater (GW) for irrigation after treatment. GW is all water generated from Household except toilet water. The risks associated with the reuse of these waters are the presence of pathogens that can infect humans, animals and plants. In this thesis focused on studying treatment by slow sand filtration and the survival of representatives of pathogens, such as E. Coli, P. aeruginosa , E. Faecalis and Bacteriophage MS2 which could be found in the greywater. The study factors was a physico-chemicals factors such as; temperature (6±2,23±2,42±2°c), salinity (1.75 and 3.5% Nacl), oxygen (aerobic and anaerobic condition), nutrient ( rich media , 50%: 50% salt and poor media ), light with photocatalysis ( UV and Visible lights) and slow sand filter (Egyptian desert sand and swimming pool sand). A combination of high temperature, sunlight and photocatlysis are mainly responsible for the rapid decline of bacteria and MS2 coliphage. Slow sand filter have clearly less influence on the survival of bacteria in the greywater, but it effective to decline turbidity and COD for short times. Filtration lente Filtre à sable Eaux grises Réutilisation Facteurs abiotiques Photocatalyse UV Slow sand filtration Greywater Reuse Abiotic factors Photocatalyse UV
870	Caractérisation par microscopie à force atomique des arrangements protéine/sucre impliquant la lectine PA-IL de la bactérie pseudomonas aeruginosa / Characterisation by atomic force microscopy of protein/glycocluster arrangement involving lectin PA-IL of pseudomonas aeruginosa bacteria Sicard, Delphine 26 November 2012 (has links) La bactérie Pseudomonas aeruginosa est un pathogène opportuniste responsable de graves infections chez les personnes affaiblies immunitairement. Présentant des souches résistantes aux antibiotiques, une nouvelle approche thérapeutique est en cours de développement avec pour objectif l’inhibition des facteurs de virulence de la bactérie. Lors de son processus d’infection, le pathogène utilise les lectines pour reconnaître et se lier de manière spécifique aux glycoconjugués des cellules-hôtes en formant une interaction lectine/glycoconjugué. Plus particulièrement, la lectine PA-IL, spécifique du galactose, a été étudiée. A l’aide de glycomimétique, il semble possible de bloquer l’action de la lectine en créant une interaction lectine/glycomimétique. Pour développer cette approche, de nombreux glycocluster sont donc été élaborés et leur affinité avec la lectine PA-IL a été évaluée par plusieurs méthodes de caractérisation (SPR, HIA, ELLA, puce à sucre,…).Dans ce projet de thèse, nous avons cherché à visualiser par microscopie à force atomique (AFM) l’arrangement des complexes lectine PA-IL/glycocluster formés pour trois glycoclusters différents. Nous avons ainsi pu montrer l’influence du cœur du glycocluster et des bras-espaceurs sur l’arrangement des complexes. Suivant le glycocluster, l’arrangement prend la forme de filaments 1D,de structures dentelées avec des bras sinueux ou encore de larges structures compactes. Dans le cas des filaments, la résolution de nos images AFM nous a permis d’identifier les lectines à l’intérieur même de la structure filaire. Nous avons aussi démontré, en observant les lectines seules, l’existence d’une interaction lectine/lectine. De plus, des expériences ont été menées pour déterminer les conditions expérimentales appropriées à leur observation à l’air et en milieu liquide. / The bacterium P. aeruginosa is an opportunistic pathogen responsible for serious infections in immunocompromised patients. It also develops some strains resistant to antibiotics. A new approach is developed to inhibit virulence factors of the bacterium. During the process of infection, the pathogen uses lectins to recognize and bind specifically to glycoconjugates of the host cells forming alectin/glycoconjugate complex. Particularly, the lectin PA-IL, specific to galactose, was studied. Using glycomimetics, it seems possible to block the action of the lectin by creating lectin/glycomimetic interaction. To develop this approach, many glycoclusters were designed and their affinity with lectin PA-IL was evaluated by various characterization techniques (SPR, HIA, ELLA, microarrays,…).In this thesis project, we have tried to visualize by Atomic Force Microscopy (AFM) the arrangement of lectin PA-IL/glycocluster complexes with three different glycoclusters. Our results show the influence of the glycocluster core and the linker on the arrangement of complexes. Depending on glycocluster, the arrangement takes the form of 1D filaments, 2D "pinked" structures with sinuous branches or large compact structures. In the case of filaments, the resolution of AFM images allows us to identify lectins along the filament. We also demonstrated the existence of lectin/lectin interactions at high concentration of lectin. In addition, some experiments were performed to determine sample preparation techniques to observe lectins in air and in liquid. Microscopie à force atomique Modulation en amplitude Lectine PA-IL Pseudomonas aeruginosa Glycocluster Complexe lectine-sucre Arrangement moléculaire Intéraction lectine-lectine Atomic force microscopy Amplitude modulation - AFM Lectin PA-IL Pseudomonas aeruginosa Glycocluster Lectin/glycocluster Molecular arrangement Lectin/lectin interaction

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