The effect of cell wall structure on pneumococcal virulence
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Mathematisch-Naturwissenschaftliche Fakultät I
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Abstract
Streptococcus pneumoniae ist ein gram-positives Bakterium und ein Krankheitserreger des Menschen. Ein Charakteristikum des Bakteriums ist, dass es Cholin-Reste in seine dicke Zellwand einbaut. Das Ziel meiner Doktorarbeit war herauszufinden, inwiefern diese Cholin-Reste zur Virulenz des Bakteriums während experimenteller Sepsis und Meningitis beitragen. Dabei konnte ich feststellen, das cholinierte Wildtyp-Bakterien hoch virulent waren, ungestört im Wirt wachsen konnten und letztendlich zu einer massiven Überaktivierung des Wirts-Immunsystems (gemessen anhand der Zytokine IL-1beta, IL-6, IL-12, TNFalpha) sowie zum Tode der Versuchtiere führten. Im Gegensatz dazu waren cholin-freie Bakterien nicht in der Lage eine permanente Infektion im Wirt zu etablieren. So wuchsen sie nur anfangs und wurden vom Wirts-Immunsystem kontrolliert und beseitigt, sodass alle Tiere überlebten. Die Injektion von cholin-freien und cholinierten, hoch aufgereinigten Zellwänden, führte zu der Schlussfolgerung, dass Cholin in der Zellwand ein Immunevasionsmechanismus der Bakterien sein muss. Ausserdem waren cholin-freie Bakterien in der Lage einen protektiven, serotyp-spezifischen Immunschutz im Wirt zu induzieren.
Streptococcus pneumonia is a major human pathogen. Since it is a gram positive bacterium it is characterized by the production of a thick cell wall. Being auxotrophic for choline, the pneumococcus attaches this aminoalcohol to its teichoic acids thus decorating its surface with choline-residues. The aim of this work was to investigate the role that these choline residues play in the virulence of the bacterium. By using an isogenic choline-containing and choline-free pair of S. pneumoniae I was able to demonstrate that surface bound choline is essential for the virulence of the bacterium in animal models of experimental sepsis and meningitis. In either model choline-containing bacteria were able to persistently grow within the host system, continuously stimulate the production of proinflammatory cytokines (IL-1beta, IL-6, IL-12, TNFalpha) and eventually led to the death of all infected animals within 24h. In contrast, choline-free bacteria showed only transient growth within the host and induced only moderate and limited expression of cytokines. Consequently, the bacterium was virtually avirulent and all animals survived. Intracisternal application of highly purified cholinated and choline-free cell wall preparations, induced a comparable activation of the immune system. These findings led to the conclusion that choline residues contribute to an immunevasion strategy that allows the bacteria to grow despite an ongoing immune response. Although being avirulent choline-free bacteria were able to induce serotype specific immunity in the animals.
Streptococcus pneumonia is a major human pathogen. Since it is a gram positive bacterium it is characterized by the production of a thick cell wall. Being auxotrophic for choline, the pneumococcus attaches this aminoalcohol to its teichoic acids thus decorating its surface with choline-residues. The aim of this work was to investigate the role that these choline residues play in the virulence of the bacterium. By using an isogenic choline-containing and choline-free pair of S. pneumoniae I was able to demonstrate that surface bound choline is essential for the virulence of the bacterium in animal models of experimental sepsis and meningitis. In either model choline-containing bacteria were able to persistently grow within the host system, continuously stimulate the production of proinflammatory cytokines (IL-1beta, IL-6, IL-12, TNFalpha) and eventually led to the death of all infected animals within 24h. In contrast, choline-free bacteria showed only transient growth within the host and induced only moderate and limited expression of cytokines. Consequently, the bacterium was virtually avirulent and all animals survived. Intracisternal application of highly purified cholinated and choline-free cell wall preparations, induced a comparable activation of the immune system. These findings led to the conclusion that choline residues contribute to an immunevasion strategy that allows the bacteria to grow despite an ongoing immune response. Although being avirulent choline-free bacteria were able to induce serotype specific immunity in the animals.
Description
Keywords
Streptococcus pneumoniae, Virulenz, Dendritische Zellen, Zytokine, Immunevasion, Immunität, Streptococcus pneumoniae, Virulence, Immune evasion, Cytokine, Dendritic Cells, Immunity
Dewey Decimal Classification
570 Biologie
Citation
Gehre, Florian.(2010). The effect of cell wall structure on pneumococcal virulence. 10.18452/16091