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Staphylococcus aureus virulence factors dictate host signaling pathways and immune responsesOrtiz Marty, Rebecca Josefina 19 January 2012 (has links)
Staphylococcus aureus causes nosocomial- and community- acquired infections. This versatile pathogen expresses virulence factors (VF) that enhance establishment of infection and immune evasion. Our research focused on defining the roles of S. aureus VF on host immune responses during intracellular or extracellular infections. Accessory gene regulator (agr) controls VF expression and intracellular survival. Our goal was to determine mammary epithelial cells (MEC) responses to intracellular infection and subsequent polymorphonuclear leukocyte (PMN) responses. Intracellular S. aureus increased thrombomodulin expression by MEC and activated protein C (APC) production. APC inhibited PMN chemotaxis. Findings depicted an indirect role for VF on PMN responses, so next we determined signaling pathways and cytokine responses of PMN to S. aureus toxins. Live S. aureus infections increased activation of stress signaling pathways and highlighted a role for agr-regulated genes in MAPK p38 phosphorylation and α-hemolysin in ERK phosphorylation and IL-8 expression in PMN. Continuing our studies of VF, chemotaxis inhibitory protein of S. aureus (CHIPS) inhibits monocyte chemotaxis. We hypothesized that CHIPS inhibited C5a receptor (C5aR) signaling. Monocytes pretreated with CHIPS did not inhibit C5aR signaling. Nevertheless, signaling pathways can reduce PMN function in models such as glucocorticoid treatment. Immunosuppressive effects of glucocorticoids on PMN are restored with OmniGen-AF® supplementation. Glucocorticoid receptor and Toll-like receptor signaling potentially crosstalk to restore PMN function. OmniGen-AF® supplementation restored dexamethasone-induced immunosuppression in a MyD88-dependent manner. Overall, this research focused on characterizing immune responses to S. aureus infections and PMN signaling pathways and how it is key to understanding pathogenesis. / Ph. D.
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Phagocytosis of Bacteroides in Suspension and on a Glass Surface Determined by a Modified Fluorochrome AssayVeringa, E. M., Ferguson, D. A., Lambe, D. W., Verhoef, J. 01 January 1989 (has links)
Phagocytosis of Bacteroides fragilis and Bacteroides thetaiotaomicron by human polymorphonuclear leukocytes (PMNL) was studied using a modified fluorochrome assay. Bacteria were grown overnight, washed and opsonized in normal, human, pooled serum. Preopsonized bacteria, either in suspension or preadhered onto a glass cover slip, were then incubated with PMNL. Afer appropriate incubation, the mixtures were centrifuged onto the cover glasses. The cover glasses were stained with acridine orange, while duplicate cover glasses were also stained with Giemsa solution. The total number and distribution of bacteria and PMNL, as well as morphological changes in PMNL, were observed with the Giemsa stain. The acridine orange stained only ingested bacteria which provided an accurate indication of phagocytosis. Bacteroides cells adhered to a glass surface were phagocytized significantly more efficiently than Bacteroides in suspension.
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Survival Of Mycobacterium Avium Subspecies Paratuberculosis In The PolRumsey, John 01 January 2004 (has links)
Mycobacterium avium subspecies paratuberculosis (map) is an intracellular pathogen that is known to parasitize macrophages and monocytes. Map infiltrates gastrointestinal tract host tissue where it is the known etiological agent of johne's disease in ruminants and implicated in the etiology of crohn's disease in humans. Map's ability to survive within macrophages enables it to disseminate throughout the rest of the host, possibly infecting other circulating blood leukocytes. In this study, the survival and fate of map strain atcc 43015 (human isolate) following phagocytosis was determined using in vitro murine macrophage cell line j774a.1 and polymorphonuclear cells (pmnc's) from five crohn's disease patients. Pmnc's from three healthy individuals and two ulcerative colitis patients, as well as escherichia coli (atcc 11303) and mycobacterium tuberculosis strain h37ra (atcc 25177), were included as controls (moi 10:1). Maturation of the phagosome was determined by evaluating the presence of stage specific markers on the surface of the phagosomal membrane. The endosomal protein, transferrin receptor, and the lysosomal marker, lamp-1, were then immunostained with cy-5 conjugated secondary antibodies, and colocalization of bacteria with each marker was evaluated separately using confocal scanning laser microscopy (cslm). In both tissue models, colocalization of viable map and m. Tuberculosis with the early endosomal marker, transferrin receptor occurred with an estimated five fold higher frequency than did association with the late lysosomal marker, lamp-1, as compared to live e. Coli, and all dead bacterial species. Using differential live/dead staining and fluorescent microscopy, survival of m. Tuberculosis and map was estimated at 85% and 79%, respectively compared to only 14% for e. Coli. The outcome was similar for both tissue culture and pmncs from all patients tested, suggesting that map and m. Tuberculosis can survive readily in both cell types, and regardless of the disease state of the host or the killing power of the cell. Map's survival appears to mimic m. Tuberculosis', suggesting the ability to resist phagolysosome fusion, by maintaining association with the early endosomes. Overall, the data confirms map virulence in host human blood leukocytes.
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Towards a Refined Model of Neutrophil MotilityLoitto, Vesa-Matti January 2001 (has links)
The ability of human polymorphonuclear leukocytes (PMNL; neutrophils), to sense and move to sites of infection is essential for our defense against pathogens. Cell motility is critically dependent on a dynamic remodeling of morphology. The morphological polarization toward chemoattractants, such as N-formyl-Met-Leu-Phe (fMLF), is associated with temporary extension and stabilization of lamellipodia in the direction of movement. The underlying mechanisms of cell motility are, however, still not entirely elucidated. It is therefore an urgent task to extend the present experimental evidence to give solid basis for a comprehensive model. Here it is shown that nitric oxide (NO) stimulates the morphological response of neutrophils, most likely due to transient increases in [Ca2+]i, following addition of NO-donors. This will, hypothetically, activate gelsolin and other actin filament severing proteins, leading to a subsequent decrease in filamentous actin. The incapability to efficiently turnover the actin filament network then blocks all motile activity. It is also shown that N-formyl peptide receptors on polarized neutrophils accumulate non-uniformly towards regions involved in motility. It is suggested that neutrophils use the asymmetric receptor distribution for directional sensing and sustained migration. A model for lamellipodium extension, where water fluxes play a pivotal role is presented. It is suggested that water fluxes through water-selective aquaporin (AQP) channels, contribute to the propulsive force for formation of various membrane protrusions and, thus, cell motility. It is well known that small G proteins of the Rho family GTPases play important roles in the intracellular signaling underlying cell motility. In morphologically polarized neutrophils it is shown that Cdc42, Rac2 and RhoA display spatially distinct distributions, which allows for sequential chemoattractant stimulation of neutrophil motility. The specific localizations of Rac2, Cdc42 and RhoA relative to each other and filamentous actin and fMLF receptors support the hypothesized order of activation and regulation of neutrophil cell motility. In conclusion, the detailed analysis of motility-related issues presented here provide new data allowing further refinement of previous models of neutrophil motility.
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Analysis Of The Polymorphonuclear Leukocyte Formylpeptide Receptor in Aggressive PeriodontitisManey, Pooja 27 August 2009 (has links)
No description available.
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The Interactions of Clostridium Perfringens With Phagocytic CellsO'Brien, David Kenneth 24 April 2003 (has links)
Clostridium perfringens is the most common cause of gas gangrene (clostridial myonecrosis), a disease that begins when ischemic tissues become contaminated with C. perfringens. C. perfringens quickly multiplies in ischemic tissues and spreads to healthy areas, leading to high levels of morbidity and mortality. As a species, the bacterium can synthesize thirteen different toxins. The alpha toxin (PLC) and perfringolysin O (PFO) are thought to be important virulence factors in gangrene. We wished to understand how C. perfringens is capable of avoiding killing by the host immune system, and determine if PLC and PFO play a role in this avoidance. We found C. perfringens was not killed by J774-33 cells or mouse peritoneal macrophages under aerobic or anaerobic conditions. Using electron microscopy, we showed that C. perfringens could escape the phagosome of J774-33 and mouse peritoneal macrophages. We believe the ability of C. perfringens to survive in the presence of macrophages is due to its ability to escape the phagosome. Using a variety of inhibitors of specific receptors, we identified those used by J774-33 cells to phagocytose C. perfringens. The scavenger receptor, mannose receptor(s), and complement receptor (CR3) were involved in the phagocytosis of C. perfringens. To determine if PFO or PLC were involved in the ability of C. perfringens to survive in the presence of macrophages, we constructed C. perfringens strains lacking these toxins. The ability of C. perfringens to survive in the presence of J774-33 cells is dependent on PFO, while survival in mouse peritoneal macrophages is dependent on PFO and PLC. The ability of C. perfringens to escape the phagosome of J774-33 cells and mouse peritoneal macrophages is mediated by either PFO or PLC. Using a mouse model, we found that PFO and PLC were necessary for C. perfringens to survive in vivo using infectious doses 1000 times lower than those required to initiate a gangrene infection. We propose that PFO and PLC play a critical role in the survival of C. perfringens during the early stages of gangrene infections, when phagocytic cells are present and bacterial numbers are low. / Ph. D.
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