The nature of the conductance increase induced by filipin in cholesterol-containing planar lipid bilayers

The interaction of dipole modifiers with polyene-sterol complexes

Recently, we showed that the effect of dipole modifiers (flavonoids and styrylpyridinium dyes) on the conductance of single amphotericin B (AmB) channels in sterol-containing lipid bilayers primarily resulted from changes in the membrane dipole potential. The present study examines the effect of dipole modifiers on the AmB multi-channel activity. The addition of phloretin to cholesterol-containing membranes leads to a significant increase in the steady-state AmB-induced transmembrane current. Quercetin significantly decreases and RH 421 increases the current through ergosterol-containing bilayers. Other tested flavonoids and styrylpyridinium dyes do not affect the channel-forming activity of AmB independently on the sterol composition of the bilayers. The effects obtained in these trials may instead be attributed to the direct interaction of dipole modifiers with AmB/sterol complexes and not to the effect of dipole potential changes. The presence of double bonds in the Δ7 and Δ22 positions of sterol molecules, the number of conjugated double bonds and amino sugar residues in polyene molecules, and the conformation and adsorption plane of dipole modifiers are important factors impacting this interaction.

Functional and morphological studies of protein transcytosis in continuous endothelia

Continuous microvascular endothelium constitutively transfers protein from vessel lumen to interstitial space. Compelling recent biochemical, ultrastructural, and physiological evidence reviewed herein demonstrates that protein transport is not the result of barrier “leakiness” but, rather, is an active process occurring primarily in a transendothelial vesicular pathway. Protein accesses the vesicular pathway by means of caveolae open to the vessel lumen. Vascular tracer proteins appear in free cytoplasmic vesicles within minutes; contents of transport vesicles are rapidly deposited into the subendothelial matrix by exocytosis. Caveolin-1 deficiency eliminates caveolae and abolishes vesicular protein transport; interestingly, exchange vessels develop a compensatory transport mode through the opening of a paracellular permeability pathway. The evidence supports the transcytosis hypothesis and the concept that transcytosis is a fundamental component of transendothelial permeability of macromolecules.

Filipin and its interaction with cholesterol in aqueous media studied using static and dynamic light scattering

Aggregation of filipin in aqueous medium and filipin-induced changes in cholesterol micelles have been studied using intensity and dynamic light scattering. The dependencies of filipin aggregate dimensions on concentration, solvent, and temperature were studied, and revealed that the aggregates do not have a well-defined geometry, i.e., a critical micelle concentration cannot be detected and stable structures are not formed. The aggregates are of size Rg approximately 110 nm and Rh approximately 63 nm, referring to the radius of gyration and hydrodynamic radius, respectively. In the concentration range studied (1 microM < C < 30 microM), a low molecular weight species (monomer/dimer) is always present together with the aggregates. In ethanol/water mixtures, large (Rg approximately 500 nm), narrow distribution aggregates are formed in the water volume fraction range 0.45 < phi H2O < 0.65. Aggregation also occurs on changing the temperature; In the range 7-37 degrees C, smaller aggregates (10-30 nm form and the process is only partially reversible. No pronounced effect of filipin on the structure of the cholesterol micelles was observed (a small increase in Rg and Rh is noted). These results rule out any "specificity" for the filipin interactions with cholesterol, which has been considered a key event in the filipin biochemical mode of action. A reevaluation of this question is suggested and some alternatives are advanced.

Permeabilizing action of filipin III on model membranes through a filipin-phospholipid binding

The binding of the pentaene antibiotic filipin to egg-yolk phosphatidylcholine (EPC) and dimyristoylphosphatidylcholine (DMPC) unilamellar vesicles, has been studied by ultraviolet (UV) absorption and circular dichroism (CD). A stoichiometry of one molecule of filipin for five molecules of phospholipid was demonstrated by CD when phospholipids were in fluid phase. The similarity of the CD spectra with EPC and DMPC established a similar filipin-phospholipid assemblage in both membranes. We therefore postulated that filipin incorporation leads to the formation of gel-like domains in fluid EPC membranes as previously demonstrated for fluid DMPC membranes (Milhaud, J., Mazerski J., Bolard, J. and Dufoure, E.J. (1989) Eur. Biophys. J. 17, 151-158). The release of fluorescent probes (carboxyfluorescein (CF) or calcein (CC)), entrapped in EPC small unilamellar vesicles (SUV), due to the action of filipin, was followed by fluorescence and CD measurements concomitantly. The following observations were made. (1) The percentage of released probe, as a function of the filipin/phospholipid molar ratios, was the same whether or not membranes contained cholesterol. (2) The permeabilization of vesicles proceeded concomitantly with filipin-phospholipid binding while filipin-cholesterol binding leveled off. (3) The release of the content of vesicles occurred by an all-or-none mechanism leaving the depleted vesicles intact. From these observations and from the previous structural findings, a new interpretation of the action of filipin is proposed. Precluding any disruptive effect, inducement of permeability would result from the high intrinsic permeability of the interfacial region at the boundaries of the gel-like domains corresponding to the filipin-phospholipid aggregates. Additionally, we obtained the permeability coefficients for the anionic forms of CC and CF across EPC SUV, 0.6.10(-10) cm s-1 and 2.10(-10) cm s-1, respectively, as compared to 2.5.10(-14) cm s-1 for the counterion Na+ (Hauser, H, Oldani, D. and Phillips, M.C. (1973) Biochemistry 12, 4507-4517).