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Die Therapie von bakteriellen Infektionen beruht heutzutage zum Großteil auf dem Einsatz von Antibiotika. Die schnelle Entwicklung und rasche Verbreitung von resistenten Stämmen mancher Erreger gegen diese Antibiotika stellt ein enormes Problem für 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 bisquartärer 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. Zytotoxizitätstests ergaben eine geringe bis nicht nachweisbare Toxizität gegen verschiedene Zelllinien im Bereich von 73 bis mehr als 150 µg/ml. Um die Wirkungsweise von MT02 genauer zu untersuchen wurden zunächst DNA-Microarray-Untersuchungen an S. aureus durchgeführt. Deren Ergebnisse ließen einen Einfluss der Substanz auf viele Gene des DNA-Metabolismus erkennen. Inkorporationsstudien mittels radioaktiver Ganzzellmarkierung bestätigten die Auswirkung von MT02 auf den DNA-Stoffwechsel. Durch kompetitive Inkubation wurde festgestellt, dass MT02 in der Lage ist Ethidiumbromid von DNA zu verdrängen bzw. dessen Bindung zu verhindern. Genauere Untersuchungen mittels Oberflächen-Plasmon-Resonanz ergaben, dass MT02 konzentrationsabhängig, 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 primären Wirkungsmechanismus der DNA-Bindung gaben mehrere Befunde Hinweise auf einen sekundären 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 Phänotyp. Die Natur dieses roten Farbstoffes konnte bislang nicht aufgeklärt werden, jedoch gibt es Hinweise, dass dieser auf Abbauprodukte von MT02 zurückzuführen 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 können durch vergleichende Analysen als Grundlage für die Einordnung des Wirkmechanismus neuer Substanzen dienen.
A major problem regarding public health is the emergence of antibiotic resistant bacterial strains, especially methicillin resistant Staphylococcus aureus (MRSA). This is mainly attributed to the unnecessary overuse of antimicrobial drugs by patients; however, one aspect that is often neglected is their untargeted mechanism of action, affecting not only the infection itself but also commensal bacteria which are often opportunistic pathogens causing many diseases as well. Therefore, our goal was to develop a bioresponsive antibiotic delivery system triggered by virulence factors. The designed system is comprised of a polymer to enhance its pharmacokinetic profile, a peptide cleavable linker, and the antibiotic agent itself. The bacterial protease aureolysin which is expressed by S. aureus during infections would cleave the linker and partially release the antibiotic which would be still attached to a remaining tetrapeptide. These would be cleaved by a group of proteases naturally present in plasma called aminopeptidases, finally releasing the compound.
In the first part of this project, we searched for a suitable sequence to serve as a cleavable linker. It should be sensitive towards the target bacterial protease but not be cleaved by any human enzymes to guarantee the specificity of the system. Therefore, we synthesized three peptide sequences via Solid Phase Peptide Synthesis and incubated them with aureolysin as well as with many human matrix Metalloproteases. The analysis and quantification of enzymatic activity was monitored chromatographically (RP-HPLC). The plasminogen originated sequence was chosen since it was not sensitive towards MMPs, but cleaved by aureolysin.
In the second part, we tried to incorporate the chosen peptide sequences as crosslinkers in hydrogel formulations. The purpose was to physically incorporate the antibiotic within the hydrogel, which would be released by the cleavage of those sequences and the consequent loosening the hydrogel net. For that purpose we used a commercially available hydrogel kit with a PVA matrix modified with maleimide, which allows a conjugation reaction with thiol functionalized crosslinkers. Three fluorophores were chosen to serve as antibiotic models and a diffusion assay was performed. Only the glomerular structured Green Fluorescent Protein (GFP) presented a low diffusion rate, thus the aureolysin release assays were performed only using this prototype. Assays showed that with a low hydrogel polymer concentration, the fluorophore either quickly diffused into the medium or was not released at all. The physical incorporation of the antibiotic within the hydrogel pores was therefore abolished as a suitable release approach. For a second attempt, we covalently bound a fluorophore to the linker, which was conjugated to the hydrogel matrix. The incubation with aureolysin and subsequent RP-HPLC analysis showed a peak with the same retention time correspondent to the fragment product after cleavage of the free linker. This is a proof that the concept of linking the peptide sequence to the antibiotic is a promising strategy for its bioresponsive release.
Within the third part of this study, we analyzed the degradation of the resulted fragment after aureolysin activity and subsequent full release of the antibiotic by human aminopeptidases. We determined the concentration of those enzymes in human plasma and synthesized the fragment by conjugating the tetrapeptide sequence to aminofluorescein via EDC/NHS reaction. By incubating the construct with the lowest aminopeptidase concentration measured in plasma, the fluorophore was completely released within two hours, showing the efficacy of these enzymes as bioresponsive agents.
The last part was the construction of the PEGylated linker-antibiotic. For this purpose we chose the tetracycline like antibiotic chelocardin (CHD) as our prototype. The conjugation of the linker- CHD to the polymer was performed by copper free click chemistry. The cleavage rate of the linker by aureolysin was very similar to the one obtained for the free peptide, indicating that the PEGylation does not interfere on the enzymatic activity. However, by trying to increase the loading ratio of chelocardin onto the polymer, we observed a very low cleavage rate for the system, indicating the formation of aggregates by those constructs.
The designed system has proved to be a smart strategy for the delivery on demand of antibiotics in which the drug is only released by the presence of S. aureus during their virulent state.