Global ETD Search

71	Surface Directed Monoclonal Antibodies against STEC Aid in the Reduction of Pathogen Detection Times from Food and Water Kumaran, Dilini January 2016 (has links) The diagnostic methods implemented at the Canadian Food Inspection Agency for the detection of Shiga toxin producing E. coli (STEC) are time consuming and tedious, taking up to 5 days before a positive sample can be confirmed. The goal of this project was to streamline the detection procedure for serogroup O157 and 6 important non-O157 serogroups of STEC. Following a short enrichment step (4-6 hrs), two approaches were considered: (1) the filtration of enrichment culture through a gradient of filtration membranes (decreasing pore sizes), followed by capture using specific monoclonal antibody (mAb)-coated Dynabeads, and detection via fluorescence microscopy, (2) the addition of enrichment culture into a flow through system consisting of a column packed with large polystyrene beads (≥ 100 μm) coated with specific mAbs for capture. The results indicate that the filtration approach can only be applied to simpler food matrices. However, at least 100 CFU of the target STEC could be recovered using the filtration system following 4 hrs of enrichment of these matrices spiked with ≤ 15CFU of the target STEC. Similar capture results were obtained in the second approach using specific mAbs immobilized on covalently coupled protein G polystyrene beads and diluted enrichment media. A combination of these strategies together with immunofluorescence microscopy (IMS) and polymerase chain reaction (PCR) could provide diagnostic laboratories with a means to confirm a positive sample within 2 days of testing. Food Filtration FNAB Immunomagnetic separation polystyrene beads Shiga toxin producing E. coli
72	Phase separation of biomimetic membranes: / Influence of glycosphingolipid structure and substrate adhesion Sibold, Jeremias 14 October 2019 (has links) No description available. 540 lipid membrane phase separation pore-spanning membrane shiga toxin globotriaosyl ceramide Chemie (PPN62138352X)
73	Cell stress markers during development of hemolytic uremic syndrome and acute kidney injury Motomochi, Amanda 22 January 2016 (has links) Enterohemorrhagic E. coli (EHEC) infections are a leading cause of foodborne illness in the United States. Shiga-like toxins are produced that can cause hemorrhagic colitis and can lead to dangerous complications, such as acute kidney injury and hemolytic uremic syndrome (HUS). There are currently no specific treatments for HUS, and therefore more research into EHEC and HUS needs to be done. Our study focuses on Shiga-like toxin induction of endoplasmic reticulum (ER) stress in in vitro and in vivo systems, using human monocyte-like THP-1 cells and a non-human primate model of HUS. We used qPCR to determine the levels of ER stress marker expression induced by both Shiga-like toxin 1 (Stx1) and Shiga-like toxin 2 (Stx2) challenges. We also looked at ER stress marker expression in non-human primates that survived a lethal Stx2 challenge after being given a Stx2 binding tetravalent peptide. We expected to see increased ER stress marker expression in THP-1 cells challenged with both Shiga-like toxins and in animals that received lethal doses of the toxins. Although results were inconclusive for THP-1 cell experiments, our preliminary non-human primate data suggest that the timing of ER stress marker production is important, and Shiga-like toxins may suppress the unfolded protein response (UPR) in some baboon tissues. We also show that the therapeutic peptide TVP may reverse this UPR suppression and relieve ER stress leading to animal survival. Our study, along with the current literature, shows that Shiga-like toxin induced ER stress is a promising area for future study. Pathology Enterohemorrhagic Escherichia coli Endoplasmic reticulum stress Hemolytic uremic syndrome Shiga-like toxins
74	Investigating the contributions of leukocyte responses and kidney cell stress on Shiga- toxin pathogenesis Parello, Caitlin Suzanne Leibowitz 12 March 2016 (has links) BACKGROUND: Shiga toxin (Stx)-producing enterohemorrhagic Escherichia coli (EHEC) are emerging food- and water- borne pathogens and a leading cause of acute renal failure in otherwise healthy children. Ribotoxic Shiga toxins are the primary virulence factors and are responsible for the potentially lethal EHEC complication of hemolytic uremic syndrome (HUS). HUS, defined clinically by microangiopathic hemolytic anemia, thrombocytopenia and thrombotic microangiopathy which contribute to acute kidney injury or renal failure, is associated with significant patient morbidity. No pathogen- or toxin- specific therapeutic exists, and antibiotic use is contraindicated. Understanding the molecular mechanisms of Stx toxicity could lead to the development of Stx specific therapies. HYPOTHESIS: Experimental evidence suggests a role for leukocytes in systemic Stx2 trafficking and in Stx2 mediated kidney pathology. Cell stress responses, such as the ER stress response and ribosomal stress response, are hypothesized to induce apoptosis, and ultimately cell death, contributing to kidney injury; however these processes have only been described in vitro. If leukocyte and kidney cell stress responses are playing significant roles in in vivo Stx2 kidney injury, then down-regulation of these processes may provide therapeutic benefit. RESULTS: Mice injected with Stx2 or infected with Stx2-producing bacteria developed lethal kidney injury as judged by biomarkers and histopathology. Experimentally induced leukopenia did not alter kidney injury in either model, but did cause striking increases in the intestinal bacterial colonization which was dependent on the presence of Stx2. No Stx binding capacity was observed for either murine or human leukocytes ex vivo. Transcriptional evidence of kidney ER stress and apoptotic biomarkers were observed in both models of Stx2-mediated kidney injury, but down-regulation of these processes did not yield therapeutic benefit. CONCLUSIONS: Contrary to the current disease paradigm, no major role for leukocytes in systemic Stx2 trafficking or kidney injury was observed in vivo, but a novel role for host immune responses to Stx2 in the control of intestinal colonization by Stx2-producing bacteria was identified. Cell stress and apoptosis is induced by Stx2 in vivo but prevention of these is not sufficient to appreciably alter organ injury or survival in the murine models. Pathology Cell stress Enterohemorrhagic Escherichia coli Kidney injury Shiga toxin Hemolytic uremic syndrome
75	Style, Discourse, and the Completion of the Vernacular Style in Modern Japanese Literature Lee, Jacob Zan Adachi 28 June 2013 (has links) (PDF) Many histories of modern Japanese literature see the "completion" of the modern vernacular style in the writings of Shiga Naoya (1883--1971), Mushakōji Saneatsu (1885--1976) and Takamura Kōtarō (1883--1956). Why and how this critical-historical perception of stylistic normalcy arose and still continues is better understood, I propose, through a close reading of key texts that identifies instances and patterns of creative manipulation of-as opposed to mere determination by or complicity with-certain philosophical, social, and historical discourses.How this creative manipulation plays out varies in prose and poetry and from text to text. In Mushakōji's Omedetaki hito (1911; The Simpleton), temporal and generic transitions establish a doubled discourse of sincerity that normalizes the genbun itchi prose into the background. In Shiga's An’ya kōro (1921--37; A Dark Night's Passing), certain syntactical and lexical innovations construct a new and rigid model of intuitive interiority. Takamura's Dōtei (1914; The Journey) reverses, to its own literary historical advantage, gendered discourses on the Japanese language and Japanese literary history. discourse genbun itchi literary history Mushakō ji Saneatsu Shiga Naoya style Takamura Kōtarō Classics Comparative Literature
76	Shiga toxins and damage-associated molecular patterns leading to endothelial dysfunction Mayer, Chad 12 March 2016 (has links) Enterohemorrhagic E. coli (EHEC) infection is a leading cause of acute kidney failure in otherwise healthy children, and a leading cause of foodborne illness with an outsized economic impact from outbreaks. EHEC secrete two Shiga-like toxins (Stx1 and Stx2) which are AB5 holotoxins that inhibit protein synthesis in cells expressing the toxin receptor Gb3. Infection with EHEC typically begins with a diarrheal prodrome that can progress in 5-15% of cases to hemolytic uremic syndrome (HUS), a clinical diagnosis characterized by thrombocytopenia, hemolytic anemia, and thrombotic microangiopathy. Historically, strains of EHEC expressing Stx2 have been associated with more severe disease. We hypothesized that tissue injury due to the toxins leads to the release of damage-associated molecular patterns (DAMPs), which act through inflammatory receptors to promote the endothelial dysfunction that drives this disease alongside the inciting Shiga toxins. Here we demonstrate that two well-characterized DAMPs, extracellular histones and HMGB1, are produced in two different mouse models when Stx2 is present; one model represents challenge with the toxin alone, and the second model introduces toxin through secretion with a lysogenized bacterium, C. rodentium, mimicking EHEC colonization. We investigate whether Stx1, Stx2, or histones affect the endothelial expression of well-characterized members of the protein C pathway, namely the endothelial protein C receptor (ECPR), protease-activated receptor 1 (PAR1), and thrombomodulin (TM), on human aortic (HAEC) and human renal glomerular endothelial cells (HRGEC). We show that Stx and/or histones reduce endothelial expression of these anti-coagulant molecules and histones dramatically increase expression of pro-thrombotic PAR-1. These changes lead to physiologically important decreases in activated protein C (APC), a critical anti-coagulant and cytoprotective molecule. Finally, we demonstrate that histones exacerbate thrombin's barrier-disruptive effects on the endothelium, and prevent APC's protective effects. These data provide novel mechanistic insight into the endothelial dysfunction that characterizes HUS and also provide a new perspective on systemic consequences of the bacterial Shiga toxins that might drive organ injury in susceptible patients. Medicine DAMPs EHEC Protein C STEC Hemolytic uremic syndrome Shiga toxins
77	CHARACTERIZATION OF NEUTRALIZING RESPONSES TO ANTHRAX TOXINS AND ISOLATION AND CHARACTERIZATION OF THE SHIGA-TOXIN ENCODING PHAGE OF ESCHERICHIA COLI 0157:H7 HANSON, JAMES F. 05 October 2004 (has links) No description available. Biology, Microbiology Anthrax Lethal Toxin Protective Antigen Escherichia coli O157:H7 Shiga-toxin
78	Epidemiological studies on Non-O157 Shiga toxin-producing Escherichia coli Persad, Anil Kenneth 08 November 2016 (has links) No description available. Veterinary Services Public Health Epidemiology Escherichia coli Trinidad Shiga toxin MALDI TOF Salmonella Deer
79	Interaction d'Escherichia coli entérohémorragique (EHEC) avec Acanthamoeba castellanii et rôle du régulon Pho chez les EHEC Chekabab, Samuel Mohammed 03 1900 (has links) Les EHEC de sérotype O157:H7 sont des agents zoonotiques d’origine alimentaire ou hydrique. Ce sont des pathogènes émergeants qui causent chez l’humain des épidémies de gastro-entérite aiguë et parfois un syndrome hémolytique-urémique. Les EHEC réussissent leur transmission à l’humain à partir de leur portage commensal chez l’animal en passant par l’étape de survie dans l’environnement. L’endosymbiose microbienne est une des stratégies utilisées par les bactéries pathogènes pour survivre dans les environnements aquatiques. Les amibes sont des protozoaires vivants dans divers écosystèmes et connus pour abriter plusieurs agents pathogènes. Ainsi, les amibes contribueraient à transmettre les EHEC à l'humain. La première partie de mon projet de thèse est centrée sur l'interaction de l’amibe Acanthamoeba castellanii avec les EHEC. Les résultats montrent que la présence de cette amibe prolonge la persistance des EHEC, et ces dernières survivent à leur phagocytose par les amibes. Ces résultats démontrent le potentiel réel des amibes à héberger les EHEC et à contribuer à leur transmission. Cependant, l’absence de Shiga toxines améliore leur taux de survie intra-amibe. Par ailleurs, les Shiga toxines sont partiellement responsables de l’intoxication des amibes par les EHEC. Cette implication des Shiga toxines dans le taux de survie intracellulaire et dans la mortalité des amibes démontre l’intérêt d’utiliser les amibes comme modèle d'interaction hôte/pathogène pour étudier la pathogénicité des EHEC. Durant leur cycle de transmission, les EHEC rencontrent des carences en phosphate inorganique (Pi) dans l’environnement. En utilisant conjointement le système à deux composantes (TCS) PhoB-R et le système Pst (transport spécifique de Pi), les EHEC détectent et répondent à cette variation en Pi en activant le régulon Pho. La relation entre la virulence des EHEC, le PhoB-R-Pst et/ou le Pi environnemental demeure inconnue. La seconde partie de mon projet explore le rôle du régulon Pho (répondant à un stress nutritif de limitation en Pi) dans la virulence des EHEC. L’analyse transcriptomique montre que les EHEC répondent à la carence de Pi par une réaction complexe impliquant non seulement un remodelage du métabolisme général, qui est critique pour sa survie, mais aussi en coordonnant sa réponse de virulence. Dans ces conditions le régulateur PhoB contrôle directement l’expression des gènes du LEE et de l’opéron stx2AB. Ceci est confirmé par l’augmentation de la sécrétion de l’effecteur EspB et de la production et sécrétion de Stx2 en carence en Pi. Par ailleurs, l’activation du régulon Pho augmente la formation de biofilm et réduit la motilité chez les EHEC. Ceci corrèle avec l’induction des gènes régulant la production de curli et la répression de la voie de production d’indole et de biosynthèse du flagelle et du PGA (Polymère β-1,6-N-acétyle-D-glucosamine). / EHEC O157:H7 are an emerging zoonotic food- and water-borne hazard highly pathogenic to humans and associated with diseases ranging from acute gastroenteritis to hemolytic uremic syndrome. From their commensal carriage by farm animals to human targets, EHEC pass through a crucial step of persistence in the open environment. Microbial endosymbiosis is one strategy used by pathogenic bacteria to survive in aquatic environments. Amoebae species are free-living protozoa found in diverse environmental habitats and known to host several water-borne pathogens. Thus amoebae could contribute to transmission of EHEC to humans. The first part of my PhD project was focused on interaction of the free-living amoebae Acanthamoeba castellanii with EHEC. The results showed that the presence of amoeba extends the persistence of EHEC that survived phagocytosis by amoebae. This demonstrates the real potential of amoebae to harbourd EHEC that may contribute to their transmission. However, absence of shiga toxins enhanced the intra-amoeba survival. Moreover, EHEC had a toxic and lethal effect on amoebae partially due to shiga toxins. The involvement of shiga toxins in the intracellular survival and mortality of amoebae suggests the value of using amoebae as a model of host/pathogen interactions to study the pathogenicity of EHEC. During their transmission cycle, EHEC encounter limitation inorganic phosphate (Pi) in the environment. Using jointly the PhoB-R two-component system (TCS) and the Pst (Pi specific transport) system, EHEC detect and respond to this Pi limitation by activating the Pho regulon. The interplay between the EHEC virulence, the Pho-Pst and/or the environmental Pi remains unknown. The second part of my project explored the role of Pho regulon (responding to Pi-limitation stress) in the virulence of EHEC. Transcriptomic analysis showed that EHEC has evolved a sophisticated response to Pi deficiency involving not only biochemical strategies that are likely critical to its survival, but also coordinating its virulence response. In these conditions, the regulator PhoB regulates directly the expression of LEE and Stx2 genes. This is confirmed by an increase in EspB secretion and Stx2 production and secretion in low Pi conditions. Moreover, the activation of Pho regulon increases biofilm formation and reduces motility in EHEC. This correlated with the induction of genes regulating curli production and repression of indole production pathway and the flagellum and PGA biosynthesis. E. coli entérohémorragiques Phosphate environnemental Régulon Pho Shiga toxine Système de sécrétion type 3 Acanthamoeba castellanii Enterohaemorrhagic E. coli Environmental phosphate Pho regulon Shiga toxin Type 3 secretion system
80	Estudo dinâmico da expressão gênica global durante a interação STEC-enterócito utilizando séries temporais / Dinamic study of global gene expression along STEC-enterocyte interaction using time series Iamashita, Priscila 27 November 2017 (has links) As Escherichia coli produtoras da toxina Shiga (STEC) são importantes patógenos humanos, causando desde diarréias até a síndrome hemolítica urêmica (SHU). Há diversos sorotipos associados a SHU, tais como O157:H7 e O113:H21. No Brasil o sorotipo O113:H21 ainda não aparece associado a SHU, embora seja frequentemente isolado de carcaças e fezes bovinas. Nosso grupo já investigou comparativamente as redes de coexpressão gênica (RCG) de STEC EH41 (associado à SHU) e Ec472/01 (isolado de fezes bovinas). A análise comparativa do perfil transcricional de EH41 e Ec472/01 revelou que somente EH41 expressa um conjunto de genes que inclui o regulador transcricional dicA. A maioria destes genes está situada em um único módulo transcricional e podem estar associados a fatores de virulência. Assim, este trabalho centrou-se numa abordagem de biologia de sistemas, integrando análises genômica e fenotípica da resposta de enterócitos Caco-2 à EH41 e Ec472/01. A análise genômica baseou-se no estudo temporal de RCG para compreender os mecanismos moleculares envolvidos na patogenicidade desses dois isolados. As alterações fenotípicas ocorridas nas células Caco-2 ao longo da exposição a cada um dos isolados de STEC foram visualizadas através de MEV. A análise genômica mostrou que o mecanismo molecular da resposta de Caco-2 durante a interação com EH41 ou Ec472/01 é claramente distinto. Nas redes do grupo Caco-2/EH41 as alterações topológicas incluíram a perda do status scale free e a sua recuperação, com o estabelecimento de uma nova hierarquia de genes na rede. Esses resultados se enquadram no modelo de redes para transição saúde-doença: a nova rede representa a resposta adaptativa da célula ao patógeno, o que não significa um retorno à normalidade. Já no grupo Caco-2/Ec472 as redes, após a perda do status scale free, não recuperam esse status até o final do período estudado, o que sugere um estado de transição mais prolongado para reorganização da hierarquia da rede. Mais ainda, através da caracterização dos módulos transcricionais, foi possível compreender dinamicamente os mecanismos moleculares envolvidos na resposta diferencial de Caco-2 aos dois isolados aqui estudados. STEC EH41 induz rapidamente a resposta inflamatória e apoptótica a partir da primeira hora de interação enterócito-bactéria. Por outro lado, células Caco-2 em contato com Ec472/01 ativam, a partir de uma hora, a fagocitose e, a partir da segunda hora, expressam moduladores da homeostase imune. A análise fenotípica das células Caco-2 mostrou, de forma nítida, uma maior destruição dos microvilos dos enterócitos em contato com EH41 do que com Ec472/01. Integrando os resultados genômicos e fenotípicos pode-se concluir que EH41 induz em Caco-2 - em comparação com Ec472/01 - maiores e mais rápidas alterações na expressão gênica global, além de uma resposta inflamatória e apoptótica excessiva, levando assim a alterações morfológicas mais pronunciadas nas células Caco-2. Em seu conjunto, esses resultados contribuem para uma melhor compreensão dos mecanismos moleculares envolvidos na patogenicidade das STECs associadas à SHU. Assim, as perspectivas de desenvolvimento deste trabalho deverão incluir a investigação de fatores de virulência e vias moleculares envolvidas na indução das respostas imunes que podem conduzir à SHU / Shiga toxin-producing Escherichia coli (STEC) O113:H21 strains are associated with human diarrhea and some of these strains may cause hemolytic uremic syndrome (HUS). In Brazil O113:H21 strains are commonly found in cattle but, so far, were not isolated from HUS patients. Previously, our group conducted comparative gene co-expression network (GCN) analyses of two O113:H21 STEC strains: EH41, isolated from a HUS patient in Australia, and Ec472/01, isolated from bovine feces in Brazil. Differential transcriptome profiles for EH41 and Ec472/01 revealed a gene set exclusively expressed in EH41, which includes the dicA putative virulence factor regulator. GCN analysis showed that this set of genes constitutes an EH41 specific transcriptional module which may be associated to virulence factors. Therefore, in the present work a system biology approach was conducted to investigate the differential Caco-2 response - genomic and phenotypic - to EH41 (Caco-2/EH41) or to Ec472/01 (Caco- 2/Ec472) along enterocyte-bacteria interaction. The genomic analysis was based on temporal GCN data in order to gain a better understanding on the molecular mechanisms underlying the capacity to cause HUS. The phenotypic alterations in Caco-2 during enterocyte-bacteria interaction were assessed by scanning electronic microscopy (SEM). The genomic analysis showed that the molecular mechanism of Caco-2 response to EH41 or to Ec472/01 during enterocyte-bacteria interaction is clearly different. The GCN topological analyses for Caco-2/EH41 group revealed loss of the scale-free status after one hour of interaction, persistence of this condition along the second hour and establishment of a new gene hierarchy thereafter. These events resemble the network mechanism of health-disease transition. The new established network represents an adaptive cell response to the pathogen and not the return to a \"normal\" state. Conversely, the networks for Caco-2/Ec472 group showed a slow and progressive loss of the scale-free status without its restoration at the end of the time interval here studied. Through transcriptional module characterization it was possible to reveal the dynamic of the molecular mechanism involved in the Caco-2 differential responses to the STEC isolates. EH41 induces a rapid inflammatory and apoptotic response just after the first hour of enterocyte-bacteria interaction. Instead, the Caco-2 response to Ec472/01 is characterized by phagocytosis activation at the first hour, followed by the expression of immune response modulators after the second hour. SEM phenotypic analysis of Caco-2 cells along enterocyte-bacteria interaction showed more intense microvilli destruction in cells exposed to EH41, when compared to cells exposed to Ec472/01. The integration of genomic and phenotypic data allowed us to conclude that EH41, comparatively to Ec472/01, induces greater and precocious global gene expression alterations in Caco-2, what is related to excessive inflammatory and apoptotic responses. These responses are associated with the pronounced morphological alterations observed by SEM in Caco-2 cells exposed to EH41. Altogether, these results contribute for a better understanding of the molecular mechanism involved in STEC pathogenicity associated to HUS. Therefore, the future perspectives for the development of the present work should include the investigation of virulence factors and molecular pathways involved in the induction of immune responses leading to HUS Biologia de sistemas Células Caco-2 Escherichia coli Shiga toxigênica Gene regulatory networks Hemolytic-uremic syndrome, Caco-2 cells Host-pathogen interactions Interações hospedeiro-patógeno Redes reguladoras de genes Shiga-toxigenic Escherichia coli Síndrome hemolítico-urêmica Systems biology

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