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Struktur und Funktion der 20S Proteasomen aus Organen Listeria monocytogenes infizierter MäuseStrehl, Britta Katharina 28 June 2005 (has links)
Das Proteasomensystem der Zelle ist für die Degradation von Proteinen verantwortlich und spielt eine zentrale Rolle bei der Generierung von Epitopen, die auf MHC-Klasse-I Molekülen den cytotoxischen T-Lymphozyten (CTLs) präsentiert werden. Die Stimulation von Zellen mit Interferon-gamma (IFNgamma) führt zu der Bildung von Immunoproteasomen, die im Vergleich zu den konstitutiven Proteasomen eine verbesserte Generierung vieler MHC-Klasse-I Epitope aufweisen. In gesunden Mäusen werden Immunoproteasomen vorwiegend in den lymphatischen Geweben exprimiert, wohingegen nicht-lymphatische Gewebe hauptsächlich konstitutive Proteasomen enthalten. In der vorliegenden Arbeit wurde der Einfluss der Listeria monocytogenes Infektion auf die aus der Leber, der Milz, dem Dünndarm und dem Colon stammenden murinen 20S Proteasomen untersucht. Die Struktur der isolierten 20S Proteasomen wurde mittels zweidimensionaler Gelelektrophorese und Westernblot ermittelt, während die Funktion durch in vitro Prozessierung von drei oligomeren Peptidsubstraten analysiert wurde. Die Prozessierungsprodukte wurden mittels HPLC-ESI-Ionenfalle massenspektrometrisch identifiziert sowie quantifiziert. Die vorliegende Arbeit zeigt zum ersten Mal, dass nach einer Infektion die aus den nicht-lymphatischen Organen und Zellen isolierten 20S Proteasomen eine strukturelle und funktionelle Plastizität aufweisen: Nach der Infektion wurde die Bildung von Immunoproteasomen induziert, was mit der gesteigerten Generierung der immunrelevanten Fragmente korreliert werden konnte. Dies verlief unabhängig von der direkten Präsenz von Listeria monocytogenes in den Organen und wurde ausschließlich durch das Cytokin IFNgamma reguliert. Es konnte außerdem eine Zunahme der posttranslationalen Modifikation von Leberproteasomen mit dem Monosaccharid N-Acetylglucosamin nach der Infektion nachgewiesen werden. Des Weiteren wurde eine detaillierte Analyse der massenspektrometrischen Daten hinsichtlich des Schnittverhaltens der konstitutiven und Immunoproteasomen etabliert. Die Auswertung ergab, dass die Immunoproteasomen nach der Infektion durch schnellere und veränderte Nutzung bestehender Spaltstellen an der verbesserten Epitoppräsentation beteiligt sind. / The proteasome system of the cell is responsible for the degradation of proteins and plays a central role in the generation of epitopes which are presented to cytotoxic T-lymphocytes (CTLs) on MHC-class-I molecules. The stimulation of cells by interferon-gamma (IFNgamma) leads to the formation of immunoproteasomes that show an improved generation of many MHC-class-I epitopes compared to constitutive proteasomes. In healthy mice, immunoproteasomes are mainly expressed in the lymphatic tissues, whereas the non-lymphatic organs predominantly contain constitutive proteasomes. In this project the effect of Listeria monocytogenes infection on murine 20S proteasomes derived from the liver, spleen, small intestine and colon were investigated. The structure of the isolated proteasomes was analyzed by two-dimensional gel electrophoresis and western blots while the function was studied by in vitro processing of three oligomeric peptide substrates. Identification and quantification of the processing products was performed by HPLC-ESI-ion trap mass spectrometry. The project showed for the first time, that after infection 20S proteasomes isolated from non-lymphatic organs as well as from non-lymphatic cells displayed structural and functional plasticity: immunoproteasomes were induced post infection which could be correlated with the enhanced generation of immuno-relevant fragments. This was independent of the direct presence of Listeria monocytogenes in the organs and solely controlled by the cytokine IFNgamma. In addition, an increased posttranslational modification with the monosaccharide N-acetylglucosamine could be detected in liver-derived proteasomes after infection. Furthermore, a detailed analysis of the mass spectrometry data was established according to the cleavage site usage of constitutive and immunoproteasomes. The result was that immunoproteasomes are involved in improved generation of the immuno-relevant fragments by the faster cleavage and the changed usage of existing cleavage sites after infection.
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CELLULAR AND MOLECULAR MECHANISM OF LISTERIA ADHESION PROTEIN-MEDIATED BACTERIAL CROSSING OF THE INTESTINAL BARRIERRishi Drolia (5929649) 14 January 2021 (has links)
<p>The
crossing of host barriers (intestinal, blood-brain, and placental) is a critical
step for systemic infections caused by entero-invasive pathogens. In the
intestine, the epithelial cells are the first line of defense against
enteric pathogens. <i>Listeria monocytogenes</i> is a
facultative-intracellular foodborne pathogen that first crosses the intestinal
barrier to cause a systemic infection. However, the underlying
mechanism is not well understood.</p><p><br></p>
<p>We
demonstrate that <i>Listeria</i> adhesion protein (LAP) promotes
the translocation of <i>L. monocytogenes </i>across the intestinal
barrier in mouse models (A/J and C57BL/6). Relative to the wild-type
(WT; serotype 4b) or the isogenic bacterial invasion protein
Internalin A mutant (Δ<i>inlA</i>) strain, the <i>lap<sup>─</sup></i>
strain showed significant defect in translocation across the intestinal
barrier and colonization of the mesenteric-lymph nodes, liver and
spleen in the early phase of infection (24 h and 48
h). LAP induces intestinal epithelial barrier dysfunction for
increased translocation as evidenced by increased permeability
to 4-kDa FITC-dextran (FD4), a marker of paracellular
permeability, in the serum and urine of WT and Δ<i>inlA</i>- infected
mice and across Caco-2 cell barrier, but not the <i>lap<sup>─</sup></i> mutant
strain. Microscopic examination confirmed localization of the WT
and Δ<i>inlA</i> strains in the tight junction, a crucial
barrier of intestinal paracellular permeability, in the mouse ileal tissue
but the <i>lap<sup>─</sup></i> strain remained confined in the
lumen. LAP also upregulates TNF-α and IL-6 in intestinal epithelia
of mice and in Caco-2 cells for increased permeability. </p><p><br></p>
<p>Investigation
of the underlying molecular mechanisms of LAP-mediated increase in intestinal
permeability by using <i>lap<sup>─</sup></i> mutant strain, purified
LAP and shRNA-mediated Hsp60 suppression, we demonstrate that LAP
interacts with its host receptor, Hsp60, and activates the canonical NF-κB
signaling, which in turn facilitates myosin light-chain
kinase (MLCK)-mediated opening of the epithelial barrier via the cellular
redistribution of major epithelial junctional proteins claudin-1, occludin, and
E-cadherin. Pharmacological inhibition of NF-κB or MLCK in cells or
genetic ablation of MLCK in mice (C57BL/6) prevents mislocalization of
epithelial junctional proteins, intestinal permeability and <i>L.
monocytogenes</i> translocation across the intestinal barrier.</p>
<p><br></p><p>Furthermore,
LAP also promotes <i>L. monocytogenes </i>translocation
across the intestinal barrier and systemic dissemination in a
Mongolian gerbil that are permissive to the bacterial invasion proteins;
InlA-and InlB-mediated pathways; similar to that in humans. We show
a direct LAP-dependent and InlA-independent pathway<i> </i>for <i>L.
monocytogenes</i> paracellular translocation across the intestinal
epithelial cells that do not express luminally accessible
E-cadherin. Additionally, we show a functional InlA/E-cadherin interaction
pathway that aids <i>L. monocytogenes</i> translocation by targeting
cells with luminally accessible E-cadherin such as cells at the site of
epithelial cell extrusion, epithelial folds and mucus-expelling goblet
cells. Thus, <i>L. monocytogenes</i> uses LAP to exploit
epithelial innate defense in the early phase of infection to cross the
intestinal epithelial barrier, independent of other invasion proteins.</p><p><br></p>
<p>This
work fills a critical gap in our understanding of <i>L.
monocytogenes </i>pathogenesis and sheds light to the complex interplay
between host-pathogen interactions for bacterial crossing of the crucial
intestinal barrier.</p>
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