Organized assembly or aggregation of sphingolipid-binding ligands, such as certain toxins and pathogens, has been suggested to increase binding affinity of the ligand to the cell membrane and cause membrane reorganization or distortion. Here we show that the diffusion behavior of the fluorescently tagged sphingolipid-interacting peptide probe SBD (Sphingolipid Binding Domain) is altered by modifications in the construction of the peptide sequence that both result in a reduction in binding to ganglioside-containing supported lipid membranes, and at the same time increase aggregation on the cell plasma membrane, but that do not change relative amounts of secondary structural features. We tested the effects of modifying the overall charge and construction of the SBD probe on its binding and diffusion behavior, by Surface Plasmon Resonance (SPR; Biacore) analysis on lipid surfaces, and by Fluorescence Correlation Spectroscopy (FCS) on live cells, respectively. SBD binds preferentially to membranes containing the highly sialylated gangliosides GT1b and GD1a. However, simple charge interactions of the peptide with the negative ganglioside do not appear to be a critical determinant of binding. Rather, an aggregation-suppressing amino acid composition and linker between the fluorophore and the peptide are required for optimum binding of the SBD to ganglioside-containing supported lipid bilayer surfaces, as well as for interaction with the membrane. Interestingly, the strength of interactions with ganglioside-containing artificial membranes is mirrored in the diffusion behavior by FCS on cell membranes, with stronger binders displaying similar characteristic diffusion profiles. Our findings indicate that for aggregation-prone peptides, aggregation occurs upon contact with the cell membrane, and rather than giving a stronger interaction with the membrane, aggregation is accompanied by weaker binding and complex diffusion profiles indicative of heterogeneous diffusion behavior in the probe population.
Aufgrund verschiedenster Reaktorformen im Bereich der Biotechnologie liefern gewöhnliche Stabsonden unzureichend repräsentative Messergebnisse. In dieser Publikation werden neuartige mobile kugelförmige Sensoreinheiten mit einem Gesamtdurchmesser von 7,9 mm vorgestellt. Basierend auf Simulationen wurden diese in ihrer Dichte für die beste Verteilung im wässrigen Medium optimiert. Darüber hinaus wurde ermittelt, welche Auswirkungen unterschiedliche Rührgeschwindigkeiten in typischen Bioreaktoren auf die Verteilung der Sonden haben. Anhand dreier Bioreaktortypen wird die Anwendbarkeit der hier vorgestellten Messsonden gezeigt.
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