Characterisation of a novel subtilase Cytotoxin from Shiga Toxigenic Escherichia Coli.

Chong, Damien Christopher Chen Sau

January 2009

Subtilase cytotoxin (SubAB) is the prototype of a novel class of AB₅ cytotoxins produced by Shiga-toxigenic Escherichia coli (STEC). The A subunit (SubA) is a serine protease that cleaves the ER chaperone BiP causing cell death by a previouslyundetermined mechanism. The B subunits of AB₅toxins typically recognise host cell glycan receptors and direct the subcellular transport of the A subunit. Although the function of SubA and its intracellular substrate have been elucidated, the B subunit (SubB) is relatively uncharacterised. The subcellular trafficking pathway of SubAB was initially examined. SubAB conjugated to Oregon Green 488 (SubAB-OG) was internalised by Vero cells by 5 min, and co-localised with its ER target BiP within 30 min. When Vero cells were incubated with SubAB-OG and either Alexa Fluor 594-conjugated Cholera toxin B subunit (CtxBAF594) or Texas Red-conjugated Shiga toxin B subunit (StxB-TR), individual cells exhibited differential toxin uptake. This was shown to be cell cycle-dependent, in which, SubAB-OG was preferentially internalised by cells migrating through G1 and early S phases. In contrast, CtxB-AF594 was taken up by cells in S through M phases and by a majority of cells in G1, while StxB-TR endocytosis occurred in cells traversing G1. Fluorescent SubAB co-localised with the clathrin marker transferrin, but not with Caveolin-1 (a marker for cholesterol-associated caveolae) and was subsequently trafficked via a retrograde pathway to the TGN, Golgi and ER. The clathrin inhibitor phenylarsine oxide prevented SubAB entry and BiP cleavage in SubAB-treated Vero, HeLa and N2A cells, while cholesterol depletion did not, demonstrating that, unlike either Stx or Ctx, SubAB internalisation is exclusively clathrin-dependent. Identification of the SubB receptor was initially approached using toxin overlay assays in which Vero cell glycolipid extracts were separated by thin-layer chromatography and overlaid with SubAB. SubAB exhibited a high affinity for particular acidic species in the ganglioside fraction. However, none co-migrated with commercial glycolipid standards. SubAB-OG also exhibited an affinity for the oligosaccharide structures of chimeric LPS from GM₂ and GM₃ bacterial receptor mimic constructs in an LPS toxin overlay assay. Glycan array analysis revealed that SubB possessed a unique affinity for carbohydrate receptors with a terminal Neu5Gcα(2→3)Galβ disaccharide. Monovalent receptor analogues with distal Neu5Gc or Neu5Gcα(2→3)Galβ and highly-sialylated α₁-AGP did not prevent endocytosis of SubAB-OG, BiP cleavage or cytotoxicity in Vero cells. This indicated that SubAB has a greater affinity for the host cell receptors than the receptor analogues and may engage multiple receptors displayed on a lipid bilayer. In addition to mediating toxin binding and subcellular trafficking, CtxB and StxB can also potentiate the immune response to co-administered antigen. Accordingly, the systemic immunomodulatory properties of SubB administered by the i.p. route were assessed in mice. Using SubAA₂₇₂ as a bystander antigen, SubB significantly increased mouse anti-SubAA₂₇₂ titres to levels that were comparable to those obtained using Alum adjuvant. However, when admixed with structurally-unrelated OVA, SubB did not significantly affect anti-OVA titres whereas Alum and CtxB did. This indicated that SubB may function as a systemic carrier protein (rather than an adjuvant) for particular antigens. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1363363 / Thesis (Ph.D.) - University of Adelaide, School of Molecular and Biomedical Science, 2009

Factors affecting prevalence of Shiga toxin-producing Escherichia coli in cattle /

Bollinger, Laurie M.

January 2008

Thesis (Ph. D.)--University of Nevada, Reno, 2008. / Includes bibliographical references. Online version available on the World Wide Web.

Role of muscoid flies in the ecology of shiga toxin-producing Escherichia coli (STEC) in confined cattle environments

Puri Giri, Rukmini

January 1900

Master of Science / Entomology / Ludek Zurek / House flies (Musca domestica L.) and stable flies (Stomoxys calcitrans L.) are insects of medical and veterinary importance. House flies are recognized as mechanical vectors of human foodborne pathogens and stable files are known for their painful bites resulting in reduction of body weight gain and milk production in cattle. The larval development of both fly species takes place in decaying organic materials (primarily animal manure), resulting in large fly populations in confined cattle environments. Shiga toxin-producing Escherichia coli (STEC) are a major foodborne pathogen. Cattle are the asymptomatic reservoir of STEC with bacteria being released to the environment via their feces. STEC O157 is the main serogroup causing human illness. However, infections with non-O157 STEC are increasing: more than 70% of non-O157 infections are caused by six serogroups of non-O157, referred as "Big six" (O26, O45, O103, O111, O121, and O145). In addition, there was a large 2011 outbreak in Europe caused by STEC O104. The objectives of my thesis were: 1) To assess the prevalence of seven serogroups of non-O157 STEC (O26, O45, O103, O104, O111, O121, and O145) (STEC-7) in house flies and stable flies collected from confined cattle environments; 2) To investigate the vector competence of house flies for non-O157 STEC-7. A total of 463 house flies from feedlots and dairies from six states, and 180 stable flies collected from a feedlot in Nebraska were processed for the isolation and identification of STEC-7 using a culture-based approach followed by PCR for the confirmation of serogroups, and virulence genes. A total of 34.3% of house flies and 1.1% of stable flies tested positive for at least one serogroup of E. coli of interest, and 1.5% of house flies harbored STEC with the Shiga-toxin gene (stx1). No STEC were detected in stable flies. Vector competence bioassays for non-O157 STEC revealed that house flies can carry non-O157 STEC for at least six days with the exception STEC O145. Overall, the findings of this research demonstrate that house flies, but not stable flies, likely play an important role in the ecology and transmission of non-O157 STEC in confined cattle environments.

House fly

Stable fly

Cattle

Shiga-toxigenic Escherichia coli

Manure

Entomology (0353)

The pathophysiology of renal failure in a shiga toxin plus lipopolysaccharide induced murine model of hemolytic uremic syndrome

Psotka, Mitchell Adam.

January 2008

Thesis (Ph. D.)--University of Virginia, 2008. / Title from title page. Includes bibliographical references. Also available online through Digital Dissertations.

The pathophysiology of renal failure in a shiga toxin plus lipopolysaccharide induced murine model of hemolytic uremic syndrome

Psotka, Mitchell Adam.

January 2008

Thesis (Ph. D.)--University of Virginia, 2008. / Title from title page. Includes bibliographical references. Also available online as viewed 8/06/2009 through Digital Dissertations.

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

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

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

Priscila Iamashita

27 November 2017

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

Interações hospedeiro-patógeno

Redes reguladoras de genes

Síndrome hemolítico-urêmica

Gene regulatory networks

Hemolytic-uremic syndrome, Caco-2 cells

Host-pathogen interactions

Shiga-toxigenic Escherichia coli

Systems biology

A New Murine Model For Enterohemorrhagic Escherichia coli Infection Reveals That Actin Pedestal Formation Facilitates Mucosal Colonization and Lethal Disease: A Dissertation

Mallick, Emily M.

28 March 2012

Enterohemorrhagic Escherichia coli (EHEC) colonizes the intestine and produces the phage-encoded Shiga toxin (Stx) which is absorbed systemically and can lead to hemolytic uremic syndrome (HUS) characterized by hemolytic anemia, thrombocytopenia, and renal failure. EHEC, and two related pathogens, Enteropathogenic E. coli (EPEC), and the murine pathogen, Citrobacter rodentium, are attaching and effacing (AE) pathogens that intimately adhere to enterocytes and form actin “pedestals” beneath bound bacteria. The actin pedestal, because it is a unique characteristic of AE pathogens, has been the subject of intense study for over 20 years. Investigations into the mechanism of pedestal formation have revealed that to generate AE lesions, EHEC injects the type III effector, Tir, into mammalian cells, which functions as a receptor for the bacterial adhesin intimin. Tir-intimin binding then triggers a signaling cascade leading to pedestal formation. In spite of these mechanistic insights, the role of intimin and pedestal formation in EHEC disease remains unclear, in part because of the paucity of murine models for EHEC infection. We found that the pathogenic significance of EHEC Stx, Tir, and intimin, as well as the actin assembly triggered by the interaction of the latter two factors, could be productively assessed during murine infection by recombinant C. rodentium expressing EHEC virulence factors. Here we show that EHEC intimin was able to promote colonization of C. rodentium in conventional mice. Additionally, previous in vitro data indicates that intimin may have also function in a Tir-independent manner, and we revealed this function using streptomycin pre-treated mice. Lastly, using a toxigenic C. rodentium strain, we assessed the function of pedestal formation mediated by Tir-intimin interaction and found that Tir-mediated actin polymerization promoted mucosal colonization and a systemic Stx-mediated disease that shares several key features with human HUS.

Enterohemorrhagic Escherichia coli

Escherichia coli Infections

Hemolytic-Uremic Syndrome

Shiga-Toxigenic Escherichia coli

Shiga Toxin

Citrobacter rodentium

Adhesins

Bacterial

Escherichia coli Proteins

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Bacteria

Bacterial Infections and Mycoses

Biological Factors

Enzymes and Coenzymes

Hemic and Lymphatic Diseases

Immunology and Infectious Disease

Male Urogenital Diseases