@phdthesis{Blaettner2016,
  author    = {Bl{\"a}ttner, Sebastian},
  title     = {The role of the non-ribosomal peptide synthetase AusAB and its product phevalin in intracellular virulence of Staphylococcus aureus},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-146662},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2016},
  abstract  = {Staphylococcus aureus is a prevalent commensal bacterium which represents one of the leading causes in health care-associated bacterial infections worldwide and can cause a variety of different diseases ranging from simple abscesses to severe and life threatening infections including pneumonia, osteomyelitis and sepsis. In recent times multi-resistant strains have emerged, causing severe problems in nosocomial as well as community-acquired (CA) infection settings, especially in the United States (USA). Therefore S. aureus has been termed as a superbug by the WHO, underlining the severe health risk originating from it. Today, infections in the USA are dominated by S. aureus genotypes which are classified as USA300 and USA400, respectively. Strains of genotype USA300 are responsible for about 70\% of the CA infections. The molecular mechanisms which render S. aureus such an effective pathogen are still not understood in its entirety. For decades S. aureus was thought to be a strictly extracellular pathogen relying on pore-forming toxins like α-hemolysin to damage human cells and tissue. Only recently it has been shown that S. aureus can enter non-professional phagocytes, using adhesins like the fibronectin-binding proteins which mediate an endocytotic uptake into the host cells. The bacteria are consequently localized to endosomes, where the degradation of enclosed bacterial cells through phagosome maturation would eventually occur. S. aureus can avoid degradation, and translocate to the cellular cytoplasm, where it can replicate. The ability to cause this so-called phagosomal escape has mainly been attributed to a family of amphiphilic peptides called phenol soluble modulins (PSMs), but as studies have shown, they are not sufficient. In this work I used a transposon mutant library in combination with automated fluorescence microscopy to screen for genes involved in the phagosomal escape process and intracellular survival of S. aureus. I thereby identified a number of genes, including a non-ribosomal peptide synthetase (NRPS). The NRPS, encoded by the genes ausA and ausB, produces two types of small peptides, phevalin and tyrvalin. Mutations in the ausAB genes lead to a drastic decrease in phagosomal escape rates in epithelial cells, which were readily restored by genetic complementation in trans as well as by supplementation of synthetic phevalin. In leukocytes, phevalin interferes with calcium fluxes and activation of neutrophils and promotes cytotoxicity of intracellular bacteria in both, macrophages and neutrophils. Further ausAB is involved in survival and virulence of the bacterium during mouse lung pneumoniae. The here presented data demonstrates the contribution of the bacterial cyclic dipeptide phevalin to S. aureus virulence and suggests, that phevalin directly acts on a host cell target to promote cytotoxicity of intracellular bacteria.},
  subject      = {Staphylococcus aureus},
  language  = {en}
}
@phdthesis{Grosz2015,
  author    = {Grosz, Magdalena Urszula},
  title     = {Identification of phagosomal escape relevant factors in Staphylococcus aureus infection},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-121981},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2015},
  abstract  = {Staphylococcus aureus is a facultative Gram-positive human pathogen which can cause different severe infections. Staphylococci are phagocytosed by professional and non-professional phagocytes; they are strongly cytotoxic against eukaryotic cells and have been proposed to play a role in immune evasion by spreading within migrating phagocytes. This study investigated the post invasive events upon S. aureus infection. Strains which are able to escape the phagosome were identified and the responsible toxins were determined. Thereby innovative insights into host pathogen interaction were obtained. A novel class of small amphipathic peptides with strong surfactant-like properties, the phenol soluble modulins, particularly PSMα as well as the leukocidin LukAB, are involved in phagosomal escape of the clinical S. aureus strains LAC, MW2 and 6850 in non-professional and professional phagocytes. Whereas, PSMβ, δ-toxin, α-toxin, β-toxin or phosphatidyl inositol-dependent phospholipase C did not affect phagosomal escape. By blocking the bacterial DNA-dependent RNA polymerase with rifampicin phagosomal escape is determined to start approximately 2.5 hours post infection. Phagosomal escape further was required for intracellular replication of S. aureus. Strains which are not able to escape cannot replicate in the acidic vacuole, whereas, the host cytoplasm offers a rich milieu for bacterial replication. Additionally, phagosomal escape, with intracellular bacterial replication induces the subsequent host cell death. This could be confirmed by an infection assay including S. aureus knockout mutants in psmα or lukAB which were significantly less cytotoxic, compared with those infected with escape-positive wild type strains. Further, this study showed that phagosomal escape is not only mediated by bacterial toxins. Since, the phagocyte-specific cognate receptors for both escape relevant toxins, FPR2 (PSMα receptor) and CD11b (LukAB receptor) are produced in epithelial and endothelial cells only after infection with S. aureus in a calcium dependent fashion. The knockdown of both receptors using siRNA prevents S. aureus to escape the phagosome. Furthermore, blocking intracellular calcium release with the inositol trisphosphate receptor (IP3R) inhibitor 2-APB prohibits upregulation of fpr2 and cd11b and subsequently phagosomal escape of S. aureus. To conclude, the current study clarifies that phagosomal escape and host cell death are interplay of both, bacterial toxins and host cell factors. Staphylococcus aureus ist ein fakultativ Gram-positives Humanpathogen, dass verschiedene schwerwiegende Infektionen verursachen kann. Staphylokokken werden von professionellen und nicht-professionellen Phagozyten (Fresszellen) zu gleich aufgenommen. Desweitern sind sie stark zytotoxisch f{\"u}r eukaryotische Zellen. Außerdem wird vermutet, dass sie sich mittels migrierender Phagozyten dem angeborenen Immunsystem entziehen k{\"o}nnen. In dieser Studie werden die post-invasiven Ereignisse w{\"a}hrend einer Staphylokokken Infektion untersucht. Im Detail wurden St{\"a}mme identifiziert die aus den Phagosomen entkommen k{\"o}nnen und die daf{\"u}r verantwortlichen Toxine. Im Zuge dessen wurden neue Erkenntnisse der Interaktion zwischen Bakterien und Wirtszellen gewonnen. Eine neue Klasse von kleinen amphiphatischen Peptiden mit starken grenzfl{\"a}chenaktiven Eigenschaften (Surfactant), die sogenannten Phenol soluble modulins (PSMs) im Besonderen PSMα sowie das Leukozidin LukAB, sind am phagosomalen Ausbruch der klinisch relevanten S. aureus St{\"a}mmen LAC, MW2 und 6850 in nicht professionellen und professionellen Phagozyten involviert. Hingegen, sind PSMβ, δ-toxin, α-toxin, β-toxin oder Phosphatidylinositol abh{\"a}ngige Phospholipase C nicht am phagosomalen Ausbruch beteiligt. Durch die Hemmung der bakteriellen DNA-abh{\"a}ngigen RNA Polymerase mit Rifampicin wurde der Zeitpunkt f{\"u}r den Ausbruch auf etwa 2,5 Stunden nach der Infektion eingegrenzt. Der phagosomale Ausbruch ist weiterhin f{\"u}r die intrazellul{\"a}re Replikation von S. aureus notwendig. W{\"a}hrend St{\"a}mme, die nicht ausbrechen k{\"o}nnen in der anges{\"a}uerten Vakuole nicht replizieren k{\"o}nnen, bietet das Zytoplasma ein reichhaltiges Milieu f{\"u}r die Vermehrung. Zudem wird der Pathogen induzierte Zelltod erst nach dem phagosomalen Ausbruch und mit anschließender Vermehrung erm{\"o}glicht. Nachgewiesen wurde dies mittels psmα und lukAB defizienten Mutanten welche signifikant weniger zytotoxisch waren als der Wildtyp Stamm. Diese Studie zeigt dar{\"u}ber hinaus, dass der phagosomale Ausbruch nicht nur durch bakterielle Toxine vermittelt wird. Sondern, dass die Phagozyten-spezifischen Rezeptoren f{\"u}r beide relevanten Toxine, FPR2 (PSMα Rezeptor) und CD11b (LukAB Rezeptor), in Epithel- und Endothelzellen nach Infektion mit S. aureus calciumabh{\"a}ngig produziert werden und f{\"u}r den Ausbruch notwendig sind. Der knockdown beider Rezeptoren mittels siRNA verhindert den Ausbruch. Wird der intrazellul{\"a}re Calciumstrom mittels des Inositoltrisphosphat Rezeptor (IP3R) Inhibitor 2-APB blockiert k{\"o}nnen die Gene fpr2 und cd11b nicht hochreguliert werden und der Ausbruch wird ebenfalls verhindert. Folglich zeigt diese Studie, dass der phagosomale Ausbruch und Pathogen induzierte Zelltod sowohl durch bakterielle Toxine als auch Wirtsfaktoren vermittelt wird.},
  subject      = {Phagosom},
  language  = {en}
}