Sarah E. F. D’Orazio scite author profile

Intestinal Listeria monocytogenes infection is not efficient in mice and this has been attributed to a low affinity interaction between the bacterial surface protein InlA and E-cadherin on murine intestinal epithelial cells. Previous studies using either transgenic mice expressing human E-cadherin or mouse-adapted L. monocytogenes expressing a modified InlA protein (InlAm) with high affinity for murine E-cadherin showed increased efficiency of intragastric infection. However, the large inocula used in these studies disseminated to the spleen and liver rapidly, resulting in a lethal systemic infection that made it difficult to define the natural course of intestinal infection. We describe here a novel mouse model of oral listeriosis that closely mimics all phases of human disease: (1) ingestion of contaminated food, (2) a distinct period of time during which L. monocytogenes colonize only the intestines, (3) varying degrees of systemic spread in susceptible vs. resistant mice, and (4) late stage spread to the brain. Using this natural feeding model, we showed that the type of food, the time of day when feeding occurred, and mouse gender each affected susceptibility to L. monocytogenes infection. Co-infection studies using L. monocytogenes strains that expressed either a high affinity ligand for E-cadherin (InlAm), a low affinity ligand (wild type InlA from Lm EGDe), or no InlA (ΔinlA) showed that InlA was not required to establish intestinal infection in mice. However, expression of InlAm significantly increased bacterial persistence in the underlying lamina propria and greatly enhanced dissemination to the mesenteric lymph nodes. Thus, these studies revealed a previously uncharacterized role for InlA in facilitating systemic spread via the lymphatic system after invasion of the gut mucosa.

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Cyclic di-GMP-dependent Signaling Pathways in the Pathogenic Firmicute Listeria monocytogenes

Köseoğlu

et al. 2014

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We characterized key components and major targets of the c-di-GMP signaling pathways in the foodborne pathogen Listeria monocytogenes, identified a new c-di-GMP-inducible exopolysaccharide responsible for motility inhibition, cell aggregation, and enhanced tolerance to disinfectants and desiccation, and provided first insights into the role of c-di-GMP signaling in listerial virulence. Genome-wide genetic and biochemical analyses of c-di-GMP signaling pathways revealed that L. monocytogenes has three GGDEF domain proteins, DgcA (Lmo1911), DgcB (Lmo1912) and DgcC (Lmo2174), that possess diguanylate cyclase activity, and three EAL domain proteins, PdeB (Lmo0131), PdeC (Lmo1914) and PdeD (Lmo0111), that possess c-di-GMP phosphodiesterase activity. Deletion of all phosphodiesterase genes (ΔpdeB/C/D) or expression of a heterologous diguanylate cyclase stimulated production of a previously unknown exopolysaccharide. The synthesis of this exopolysaccharide was attributed to the pssA-E (lmo0527-0531) gene cluster. The last gene of the cluster encodes the fourth listerial GGDEF domain protein, PssE, that functions as an I-site c-di-GMP receptor essential for exopolysaccharide synthesis. The c-di-GMP-inducible exopolysaccharide causes cell aggregation in minimal medium and impairs bacterial migration in semi-solid agar, however, it does not promote biofilm formation on abiotic surfaces. The exopolysaccharide also greatly enhances bacterial tolerance to commonly used disinfectants as well as desiccation, which may contribute to survival of L. monocytogenes on contaminated food products and in food-processing facilities. The exopolysaccharide and another, as yet unknown c-di-GMP-dependent target, drastically decrease listerial invasiveness in enterocytes in vitro, and lower pathogen load in the liver and gallbladder of mice infected via an oral route, which suggests that elevated c-di-GMP levels play an overall negative role in listerial virulence.

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Bacterial ureases: structure, regulation of expression and role in pathogenesis

Collins

D’Orazio

1993

Molecular Microbiology

206

114

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The nickel metalloenzyme urease catalyses the hydrolysis of urea to ammonia and carbamate, and thus generates the preferred nitrogen source of many organisms. When produced by bacterial pathogens in either the urinary tract or the gastroduodenal region, urease acts as a virulence factor. At both sites of infection urease is known to enhance the survival of the infecting bacteria. Ammonia resulting from the action of urease is believed to increase the pH of the environment to one more favourable for growth, and to injure the surrounding epithelial cells. In addition, in the urinary tract urease activity can result in the formation of urinary calculi. Bacterial urease gene clusters contain from seven to nine genes depending upon the species. These genes encode the urease structural subunits and accessory polypeptides involved in the biosynthesis of the nickel metallocentre. So far, three distinct mechanisms of urease gene expression have been described for ureolytic bacteria. Some species constitutively produce urease; some species produce urease only if urea is present in the growth medium; and some species produce urease only during nitrogen-limiting growth conditions. For either the urea-inducible genes or the nitrogen-regulated genes transcription appears to be positively regulated. In the nitrogen-regulated systems, urease gene expression requires Nac (nitrogen assimilation control), a member of the LysR family of transcriptional activators. Urea dependent expression of urease requires UreR (urease regulator), a member of the AraC family of transcriptional activators. An evolutionary tree for urease genes of eight bacterial species is proposed.

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CD8⁺T cells recognize an inclusion membrane-associated protein from the vacuolar pathogenChlamydia trachomatis

Fling

Sutherland²,

Steele³

et al. 2001

Proc. Natl. Acad. Sci. U.S.A.

120

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During infection with Chlamydia trachomatis, CD8 ؉ T cells are primed, even though the bacteria remain confined to a host cell vacuole throughout their developmental cycle. Because CD8 ؉ T cells recognize antigens processed from cytosolic proteins, the Chlamydia antigens recognized by these CD8 ؉ T cells very likely have access to the host cell cytoplasm during infection. The identity of these C. trachomatis proteins has remained elusive, even though their localization suggests they may play important roles in the biology of the organism. Here we use a retroviral expression system to identify Cap1, a 31-kDa protein from C. trachomatis recognized by protective CD8 ؉ T cells. Cap1 contains no strong homology to any known protein. Immunofluorescence microscopy by using Cap1-specific antibody demonstrates that this protein is localized to the vacuolar membrane. Cap1 is virtually identical among the human C. trachomatis serovars, suggesting that a vaccine incorporating Cap1 might enable the vaccine to protect against all C. trachomatis serovars. The identification of proteins such as Cap1 that associate with the inclusion membrane will be required to fully understand the interaction of C. trachomatis with its host cell.

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Multigenic control of Listeria monocytogenes susceptibility in mice

et al. 2001

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Sarah E. F. D’Orazio

InlA Promotes Dissemination of Listeria monocytogenes to the Mesenteric Lymph Nodes during Food Borne Infection of Mice

Cyclic di-GMP-dependent Signaling Pathways in the Pathogenic Firmicute Listeria monocytogenes

Bacterial ureases: structure, regulation of expression and role in pathogenesis

CD8⁺T cells recognize an inclusion membrane-associated protein from the vacuolar pathogenChlamydia trachomatis

Multigenic control of Listeria monocytogenes susceptibility in mice

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Sarah E. F. D’Orazio

InlA Promotes Dissemination of Listeria monocytogenes to the Mesenteric Lymph Nodes during Food Borne Infection of Mice

Cyclic di-GMP-dependent Signaling Pathways in the Pathogenic Firmicute Listeria monocytogenes

Bacterial ureases: structure, regulation of expression and role in pathogenesis

CD8+T cells recognize an inclusion membrane-associated protein from the vacuolar pathogenChlamydia trachomatis

Multigenic control of Listeria monocytogenes susceptibility in mice

Contact Info

Product

Resources

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CD8⁺T cells recognize an inclusion membrane-associated protein from the vacuolar pathogenChlamydia trachomatis