Lateral diffusion and conductance properties of a fluorescein-labelled alamethicin in planar lipid bilayers.

In order to follow alamethicin diffusion within membranes under conditions of pore-formation, a fluorescein isothiocyanate (FITC) analogue was synthesized. To test the influence of the fluorescent probe addition on the pore-forming activity of the new analogue, macroscopic and single-channel experiments into planar lipid bilayers were performed. Although the apparent mean number of monomers per conducting aggregate was equivalent, the voltage-dependence of the new analogue was slightly reduced and hysteresses were broader, in agreement with the much longer duration of the open single-channels. Thus, the conducting aggregates seem to be stabilized by the introduction of the probe, presumably through the interaction of the conjugated cycles with the lipid headgroups, while the added steric hindrance may account for the slightly higher conductances of the open substates. Lateral diffusion of the labelled peptide associated with the bilayer was then investigated by the fluorescence recovery after photobleaching technique. Under applied voltage, associated with high conductance, D, the lateral diffusion coefficient, was reduced by 50% when compared to peptide at rest. These results provide new independent experimental evidence for a voltage-driven insertion of the highly mobile surface-associated peptide into the bilayer as a prominent step in pore formation.