@phdthesis{Wermser2019,
  author    = {Wermser, Charlotte},
  title     = {Morphology, regulation and interstrain interactions in a new macrocolony biofilm model of the human pathogen \(Staphylococcus\) \(aureus\)},
  doi       = {10.25972/OPUS-16593},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-165931},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2019},
  abstract  = {The role of multicellularity as the predominant microbial lifestyle has been affirmed by studies on the genetic regulation of biofilms and the conditions driving their formation. Biofilms are of prime importance for the pathology of chronic infections of the opportunistic human pathogen Staphylococcus aureus. The recent development of a macrocolony biofilm model in S. aureus opened new opportunities to study evolution and physiological specialization in biofilm communities in this organism. In the macrocolony biofilm model, bacteria form complex aggregates with a sophisticated spatial organization on the micro- and macroscale. The central positive and negative regulators of this organization in S. aureus are the alternative sigma factor σB and the quorum sensing system Agr, respectively. Nevertheless, nothing is known on additional factors controlling the macrocolony morphogenesis. In this work, the genome of S. aureus was screened for novel factors that are required for the development of the macrocolony architecture. A central role for basic metabolic pathways was demonstrated in this context as the macrocolony architecture was strongly altered by the disruption of nucleotide and carbohydrate synthesis. Environmental signals further modulate macrocolony morphogenesis as illustrated by the role of an oxygen-sensitive gene regulator, which is required for the formation of complex surface structures. A further application of the macrocolony biofilm model was demonstrated in the study of interstrain interactions. The integrity of macrocolony communities was macroscopically visibly disturbed by competitive interactions between clinical isolates of S. aureus. The results of this work contribute to the characterization of the macrocolony biofilm model and improve our understanding of developmental processes relevant in staphylococcal infections. The identification of anti-biofilm effects exercised through competitive interactions could lead to the design of novel antimicrobial strategies targeting multicellular bacterial communities.},
  subject      = {Staphylococcus aureus},
  language  = {en}
}
@phdthesis{Menzel2011,
  author    = {Menzel, Thomas Michael},
  title     = {Studien zum Wirkungsmechanismus neuer antiinfektiver Bisnaphthalimide gegen Staphylococcus aureus und Transkriptomanalysen zur Auswirkung von Antibiotika auf S. epidermidis},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-56362},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2011},
  abstract  = {Die Therapie von bakteriellen Infektionen beruht heutzutage zum Großteil auf dem Einsatz von Antibiotika. Die schnelle Entwicklung und rasche Verbreitung von resistenten St{\"a}mmen mancher Erreger gegen diese Antibiotika stellt ein enormes Problem f{\"u}r das Gesundheitswesen dar. Da momentan zur Antibiotikatherapie keine Alternativen bestehen, kommt der Erforschung neuer potenzieller Wirkstoffe eine sehr große Bedeutung zu. In einem Screening-Verfahren lagen die minimalen Hemmkonzentrationen einiger bisquart{\"a}rer Bisnaphthalimide gegen Staphylococcus aureus und S. epidermidis im Bereich von 0,6 bis 2,5 µg/ml. Die Substanz mit den geringsten minimalen Hemmkonzentrationen war MT02. Daraufhin wurde das Wirkungsspektrum von MT02 gegen Bakterien detaillierter untersucht und gefunden, dass die Substanz vorwiegend gegen Gram-positive Erreger und nicht gegen Gram-negative Bakterien wirksam ist. Zytotoxizit{\"a}tstests ergaben eine geringe bis nicht nachweisbare Toxizit{\"a}t gegen verschiedene Zelllinien im Bereich von 73 bis mehr als 150 µg/ml. Um die Wirkungsweise von MT02 genauer zu untersuchen wurden zun{\"a}chst DNA-Microarray-Untersuchungen an S. aureus durchgef{\"u}hrt. Deren Ergebnisse ließen einen Einfluss der Substanz auf viele Gene des DNA-Metabolismus erkennen. Inkorporationsstudien mittels radioaktiver Ganzzellmarkierung best{\"a}tigten die Auswirkung von MT02 auf den DNA-Stoffwechsel. Durch kompetitive Inkubation wurde festgestellt, dass MT02 in der Lage ist Ethidiumbromid von DNA zu verdr{\"a}ngen bzw. dessen Bindung zu verhindern. Genauere Untersuchungen mittels Oberfl{\"a}chen-Plasmon-Resonanz ergaben, dass MT02 konzentrationsabh{\"a}ngig, reversibel und sequenzunspezifisch an DNA bindet. Die thermodynamischen Dissoziationskonstanten lagen im Mittel bei ca. 4 x 10-8 mol/l und beschrieben somit eine relativ starke Bindung von MT02 an DNA. Neben diesem prim{\"a}ren Wirkungsmechanismus der DNA-Bindung gaben mehrere Befunde Hinweise auf einen sekund{\"a}ren Wirkmechanismus, der die Zellwand-Struktur bzw. Zellwand-Biosynthese beinhaltet. Eine MT02-resistente Mutante von S. aureus HG001 konnte durch vielfaches Passagieren in MT02-haltigem Medium generiert werden. Diese erzeugte bei Wachstum mit hohen Konzentrationen an MT02 einen roten Ph{\"a}notyp. Die Natur dieses roten Farbstoffes konnte bislang nicht aufgekl{\"a}rt werden, jedoch gibt es Hinweise, dass dieser auf Abbauprodukte von MT02 zur{\"u}ckzuf{\"u}hren ist. In einem weiteren Projekt wurde mittels Transkriptionsstudien die Auswirkung von verschiedenen bekannten Antibiotika sowie von neuen Wirkstoffen auf das Transkriptom von S. epidermidis untersucht. Die Ergebnisse dieser Studien k{\"o}nnen durch vergleichende Analysen als Grundlage f{\"u}r die Einordnung des Wirkmechanismus neuer Substanzen dienen.},
  subject      = {MRSA},
  language  = {de}
}
@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}
}