albicans (Makovitzki & Shai, 2005), or phosphatidylcholine/ergost

albicans (Makovitzki & Shai, 2005), or phosphatidylcholine/ergosterol CYC202 (10 : 1, w/w), mimicking human red blood cell plasma membranes, applying

the fungal membranes, were measured. The results showed that papiliocin significantly caused calcein leakage from the LUVs within 2 min and that papiliocin contained relatively lower activity compared with that of melittin, corresponding to the results of antifungal susceptibility testing (Fig. 3a and b). The LUV data also showed that papiliocin activity differs in the two kinds of liposomes that mimic different plasma membranes. Furthermore, the papiliocin-induced dye leakage from the liposomes confirms the membrane-active mechanism of the peptide, which was suggested by the PI influx assay. In summary, the results provided confirmation

regarding the membrane-active mechanism of papiliocin, which was assumed in the PI influx assay. In order to visualize the mechanism(s) of papiliocin, a single GUV, composed of phosphatidylcholine/rhodamine-conjugated Alectinib manufacturer phosphatidylethanolamine/phosphatidylinositol/ergosterol (5 : 4 : 1 : 2, w/w/w/w), mimicking the plasma membrane of C. albicans (Makovitzki & Shai, 2005), was used using the electroformation method (Angelova & Dimitrov, 1986; Angelova et al., 1992). Because of their average diameter ranges from 10 to 100 μm, GUVs enable direct optical microscopic observations. Additionally, the use of confocal microscopy or fluorescence spectroscopy allows the study of both the static structural and the dynamical properties of model membrane systems. Therefore, it is believed

that GUVs are one of the most significant model systems used in membrane studies (Wesołowska et al., 2009). As shown in Fig. 4, the rhodamine intensity of a single GUV gradually decreased after the treatment with not only mellitin but also papiliocin. The circular shape of the melittin-treated single GUV was maintained, whereas the papiliocin-treated GUV was time-dependently dispersed. Moreover, after 3 min, the vesicles had been split into multiple small vesicles and the intensity of rhodamine had diminished over time. Papiliocin appears to generate pores in the membranes, which then leads to Tenoxicam a division of the liposome into several particles. In summary, the antifungal effects and the mechanism of action of papiliocin were analyzed. Several membrane studies indicate that papiliocin exerts its antifungal activity against human fungal pathogens, especially C. albicans, by a membrane-active mechanism. Although the exact mechanism must be further clarified, this study suggests that papiliocin has a potential for application as an antifungal agent and that this peptide can be used to design more potent antifungal peptides.

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