Fluorescence quenching in lecithin and lecithin/cholesterol liposomes by parmagenetic lipid analogues. Introduction of a new probe approach.

1. Perylene, whether incorporated into lecithin or lecithin/cholesterol (1:1) liposomes, exhibits identical fluorescence spectra, but fluorescence in the presence of cholesterol is enhanced by 30-50%. 2. The fluorescence of perylene in pure dipalmitoyllecithin vesicles increases sharply at the transition temperature (Tt equals 41 degrees C). No such fluorescence jump is observed in lecithin/cholesterol (1:1) micelles. 3. In lecithin liposomes maximal quenching of perylene fluorescence at 25 degrees C is effected by cholestane spin label (80%) followed by androstane spin label (70%), 5-nitroxide stearate (60%) and 16-nitroxide stearate (50%). 4. In liposomes containing 5 mol % cholesterol these differences are reduced; however, the sequence of quenching efficiencies is the same except for the nitroxide stearates, which interchange their positions. 5. 5. Paramagnetic quenching of perylene fluorescence is stable below 35 degrees C and above 45 degrees C, but decreases sharply about the phase-transition temperature of dipalmitoyllecithin. 6. In lecithin/cholesterol (1:1, molar ratio) lipsomes fluorescence quenching diminishes linearly, but only slightly, with increasing temperature. 7. Cholestane spin label and androstane spin label at concentrations of greater than 20 mol % themselves suppress the quenching discontinuity at Tt, indicating a cholesterol-like structural effect. 8. The quenching phenomena observed are attributed to a non-random accommodation of fluorophore and quencher molecules (co-clustering) below the phase transition and a statistical distribution of both impurities above Tt. 9. In the presence of cholesterol the clustering tendencies are reduced or even eliminated; this is compatible with the concept that cholesterol fluidizes the phosphatide acyl chains below the transtion temperature.     

A photophysical study of the polyene antibiotic filipin: Self-aggregation and filipin–ergosterol interaction

Filipin, a macrolide polyene antibiotic, is known to interact selectively with ergosterol, a constituent of fungi membranes. In this work, the fluorescence resonance energy transfer (FRET) between a fluorescent analog of ergosterol, dehydroergosterol (DHE), and filipin was measured in small unilamellar vesicles of dipalmitoylphosphatidylcholine at 25°C. The time-resolved FRET results were rationalized in the framework of the mean concentration model, and were complemented with steady-state fluorescence intensity, anisotropy and absorption measurements. The results point to the formation of both DHE–filipin aggregates (evidence from static quenching of DHE fluorescence by filipin) and filipin–filipin aggregates (evidence from: (i) the FRET acceptor concentration distributions; (ii) spectral changes of filipin absorption in the vesicles, the excitonic interaction suggesting a stack arrangement; (iii) filipin fluorescence self-quenching), even in presence of DHE and low antibiotic mole fractions (<1 mol%). These results point out that apparently contradictory biochemical models for the action of filipin (some based on the presence of sterols, others not) can be equally valid. Moreover, since results (ii) and (iii) are also observed when a sterol is present, both models of action can actually coexist in membranes with a low sterol content.     

Stimulation of ion release from liposomes by the polyene antibiotic, filipin.

The effect of the polyene antibiotic, filipin, upon release of the ions Ca²⁺, Sr²⁺, SO₄^2? and phosphate out of phospholipid and phospholipid-cholesterol liposomal vesicles was studied. The addition of filipin at concentrations stoichiometrically comparable to the cholesterol concentration in the liposomes, resulted in 2–10 × stimulation of the rate of release of all of these ions. The filipin mediated stimulation of release of ions from liposomes was dependent upon the presence of cholesterol. The relative effectiveness of filipin increased when the mole percent of cholesterol incorporated into the liposomes increased from 10 to 50% and when the molar filipin:cholesterol ratio increased from 0.2 to 1.0. It has been previously shown that there is a 1:1 stoichiometry of interaction between filipin and cholesterol [Biochem. Biophys. Acta339, 57 (1974)]. The present studies suggest that this 1:1 stoichiometric interaction may also be responsible for the increased release of entrapped ions.A possible mechanism of action of polyene antibiotics is discussed which suggests that the rearrangement of membrane constituents occurring upon interaction of filipin with cholesterol is the basis for the enhancement of ion release. This would imply that the ion specificity observed upon interaction of polyene antibiotics with membranes would not only be determined by the polyene antibiotic itself, but also by the intrinsic properties of the membrane.     

A photophysical study of the polyene antibiotic filipin. Self-aggregation and filipin--ergosterol interaction

Filipin, a macrolide polyene antibiotic, is known to interact selectively with ergosterol, a constituent of fungi membranes. In this work, the fluorescence resonance energy transfer (FRET) between a fluorescent analog of ergosterol, dehydroergosterol (DHE), and filipin was measured in small unilamellar vesicles of dipalmitoylphosphatidylcholine at 25 degrees C. The time-resolved FRET results were rationalized in the framework of the mean concentration model, and were complemented with steady-state fluorescence intensity, anisotropy and absorption measurements. The results point to the formation of both DHE--filipin aggregates (evidence from static quenching of DHE fluorescence by filipin) and filipin--filipin aggregates (evidence from: (i) the FRET acceptor concentration distributions; (ii) spectral changes of filipin absorption in the vesicles, the excitonic interaction suggesting a stack arrangement; (iii) filipin fluorescence self-quenching), even in presence of DHE and low antibiotic mole fractions (<1 mol%). These results point out that apparently contradictory biochemical models for the action of filipin (some based on the presence of sterols, others not) can be equally valid. Moreover, since results (ii) and (iii) are also observed when a sterol is present, both models of action can actually coexist in membranes with a low sterol content.     

Filipin as a cholesterol probe. I. Morphology of filipin-cholesterol interaction in lipid model systems

We report some novel morphological observations on the interaction of the polyene antibiotic filipin (crude complex) with cholesterol, studied in non-cellular systems with replication, freeze-fracture, and negative stain techniques. Cholesterol crystals, lecithin liposomes containing 0 to 20 mole% of cholesterol, and liposomes containing 10 mole% of cholesterol and 5 to 40 mole% of sphingomyelin were incubated for varying lengths of time with filipin at different cholesterol: filipin molar ratios. The resulting filipin-induced lesions (FIL) were pleomorphic in all systems studied. In replicas of crystals, FIL appeared as ridges which were either straight, or curved into C- and S-shaped figures or closed circles. Negatively stained preparations showed FIL as white lines of the same configurations and in addition revealed a delicate veil attached to individual FIL. FIL, fused by their veils into clusters or large sheets ("holey sheets"), were shed from crystals. Incubation of liposomes for 1 h at cholesterol:filipin molar ratios of 4:1, 2:1, 1:1, and 1:5, demonstrated that cholesterol detection (i.e. formation of FIL) depend upon the ratio of cholesterol to filipin. At a 1:1 molar ratio FIL formed on liposomes containing 10 mole% cholesterol or more, but detectability increased to 5 mole% at the 1:5 ratio. Increasing the molar ratio of cholesterol:filipin to 2:1 and 4:1 decreased cholesterol detectability to between 10 and 20 mole%. Increasing concentrations of sphingomyelin decreased cholesterol detectability at the 1:1 cholesterol:filipin ratio; further, FIL in sphingomyelin-containing liposomes tended towards larger diameters. Filipin induced aggregation of liposomes and linked them together by holey sheets, providing evidence for filipin-induced extraction of cholesterol from liposomes. Taken together our morphological observations on filipin-cholesterol interaction in non-cellular systems raise pertinent questions as to the feasibility of filipin as a cholesterol probe in cellular systems.     

Interaction of polyene antibiotics with sterols in phosphatidylcholine bilayer membranes as studied by spin probes

Interaction of filipin and amphotericin B with sterols in phosphatidylcholine membranes has been studied using various spin probes; epiandrosterone, cholestanone, phosphatidylcholine with 12-nitroxide or 5-nitroxide stearate attached to 2 position and also with tempocholine at the head group. Filipin caused increase in the fluidity of cholesterol-containing phosphatidylcholine membranes near the center, while it rather decreased the fluidity near the polar surface. On the other hand, amphotericin B did not apparently affect the fluidity. In the electron spin resonance spectrum of steroid spin probes in the antibiotic-containing membranes, both bound and free signals were observed and the association constant was calculated from the siganal intensity. In the binding of steroids with filipin, both 3 and 17 positions were involved, while the 17 position was less involved in the binding with amphotericin B. Phase change in the host membrane markedly affected the interaction of filipin with epiandrosterone probe. The bound fraction jumped from 0.4 to 0.8 on going to the crystalline state and increased further with decrease in temperature. The overall splitting of the bound signal also increased on lowering the temperature below phase transition. This change was attributed to aggregate formation of filipin-steroid complexes in the crystalline state. On the other hand, effect of phase transition was much smaller on the interaction of amphotericin B with the steroid probe.     

Fluorescence study of the macrolide pentaene antibiotic filipin in aqueous solution and in a model system of membranes.

The polyene antibiotic filipin (a pentaene) has been studied using photophysical techniques. The polyene self-aggregates in water with a critical micellar concentration of 2 microM. Two approaches were used to evaluate the aggregate dimensions: (a) a lower limit of 10 nm for the aggregate radius was obtained from energy transfer experiments; (b) a formula for rationalizing the turbidity spectrum was derived, and from its application a spherical shape of radius about 50 nm was deduced. The low value for the fluorescence anisotropy of the aggregate (r = 0.02) is compatible with a very loose structure, i.e. the chromophore has very efficient depolarization dynamics that is not controlled by the aggregate size. The Stern-Volmer plot of aggregated filipin fluorescence quenching by iodide is non-linear, presenting a downward curvature. A model was used for the interpretation of these data, along with a study of the quenching in transient state; it was concluded that all the components of the decay are affected by the quencher, i.e. the aggregate has a very open structure with respect to the iodide ion. The partition constants of the polyene, Kp, between a model system of membranes (small unilamellar vesicles of dipalmitoylglycerophosphocholine) and the aqueous phase were determined from anisotropy measurements; the values obtained were Kp (gel phase) = (3.4 +/- 0.8) x 10(3) and Kp (liquid crystal phase) = (7.7 +/- 2.2) x 10(2). The observation that the polyene incorporation is efficient is at variance with the belief that the presence of sterols are essential for the interaction of polyene antibiotics with membranes [for review see Bolard, J. (1986) Biochim. Biophys. Acta 864, 257-304].     

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).     

Micromolar concentrations of Zn2+ potentiates Ca2+-induced phase separation of phosphatidyl serine containing liposomes

Fluorescence quenching of 1-acyl-2-[6[(7 nitro-2,1,3-benzoxadiazol-4yl) amino]caproyl] phosphatidyl choline in small unilamellar vesicles consisting of phosphatidyl serine has been used to monitor the lipid phase separation induced by Zn2+ and Ca2+. Phase separation of vesicle membranes was observed with Zn2+ at concentrations as low as 125 microM. Low concentrations of Zn2+ required long incubation times to reach maximal quenching (120 minutes at 375 microM). When low concentrations of Ca2+ were added to the preparation during the developing phase of Zn2+-induced quenching, an explosive increase in fluorescence quenching was instantenously observed. Phase separation induced by sub-millimolar concentrations of Ca2+ could be increased at least 4 times when vesicles were pre-incubated with 250 microM of Zn2+.     

Effect of ganglioside-GM1 on the order of phosphatidylcholine-cholesterol multilamellar liposomes. A fluorescence polarization study

The effect(s) of bovine brain ganglioside-GM1 on the order of phosphatidylcholine-cholesterol membranes were studied using steady-state fluorescence polarization (FPZ) techniques with 1,6-diphenyl-1,3,5-hexatriene (DPH) as the membrane probe. In the absence of cholesterol, GM1 (30 mol%) increases both membrane order and the phase transition temperature of dipalmitoylphosphatidylcholine (DPPC) and dimyristoylphosphatidylcholine (DMPC) membranes. However, in the presence of cholesterol (0.3 or 0.5, cholesterol/phospholipid molar ratio), GM1 significantly decreases steady-state anisotropy (rs) at temperatures above the Tm for the particular phospholipid. This effect may, in part relate to a dilution of membrane cholesterol and is shared by bovine brain sphingomyelin (SM). GM1 (30 mol%) increases the order of 1-palmityl-2-oleyl-PC (POPC) membranes. However, in the presence of cholesterol (0.3 molar ratio) GM1 neither increases or decreases order. Thus, in cholesterol containing artificial membranes, the effect of GM1 depends on the phosphatidylcholine (PC) fatty acid composition and may not be evident from the effect of GM1 on pure PC membranes.     

Filipin resistance in intermediate junction membranes of guinea pig ependyma: possible relationship to filamentous underlying

Plasma membranes in intermediate junctions of ependymal cells are found to show considerable resistance to the antibiotic filipin, suggesting low cholesterol in these membranes. Further, ependymal cells were treated with cytochalasin B (CB) infused into the cerebral ventricle in vivo, and then incubated with filipin. When treated with CB, intermediate junctions show a decrease in their underlying density, mainly composed of microfilaments, and their membranes are found to be more affected by filipin. This reduction of resistance to the antibiotic is clearly demonstrated by thin-section and freeze-fracture as well as quantitative analysis. Nonjunctional lateral membranes, however, show no significant difference in the degree of filipin effect whether treated with CB or not. Although biochemical data on lipid composition have not been available for the intermediate junction membranes, we bring forward a possibility that resistance to filipin in these membranes may come not from less cholesterol but from morphological membrane stability brought about by the filamentous underlying.     

Effects of Filipin on the Structure and Biological Activity of Enveloped Viruses

The interaction of the polyene antibiotic filipin with membrane-bound cholesterol in vesicular stomatitis (VS), influenza, and Rauscher leukemia virions was studied. Exposure of virions to filipin resulted in a series of depressions and ridges in the envelope of VS virions, with a periodicity of 15 to 20 nm perpendicular to the long axis of the particle; similar morphological alterations were observed in negatively stained preparations, in thin-sectioned virions, and in protease-treated virions that lack surface glycoproteins. This morphological effect was specific for filipin, since the envelopes of VS virions that had been treated with another polyene antibiotic, amphotericin B, exhibited markedly different morphology. Morphological alterations induced by filipin in influenza and Rauscher leukemia virions differed from those seen in VS virions. The infectivity of filipin-treated VS virions was reduced up to 500-fold, whereas influenza virions were resistant to filipin treatment. Incorporation of filipin into the virions was demonstrated, and no release of either lipids or proteins from virions was detected after filipin treatment. A stoichiometry of approximately 1 mol of bound filipin per mol of cholesterol was found in both intact and protease-treated VS virions. The equilibrium dissociation constant for filipin-cholesterol interaction was approximately 74-fold larger in intact than in protease-treated VS virions. The initial rate of association of filipin with cholesterol in intact virions was slower than that in protease-treated particles. The fluidity of lipids in VS viral membranes, as probed by a stearic acid derivative spin label, was markedly reduced when either intact or protease-treated virions were treated with filipin.     

Effects of Filipin and cholesterol on housefly, Musca domestica L., and wax moth, Galleria mellonella L

The effects of filipin on insects are dependent on the molar ratio of cholesterol to filipin. The larvicidal effects of the polyene antibiotic, filipin, can be prevented by excess cholesterol (“excess” herein is defined as a molar ratio of cholesterol to filipin of greater than 2 : 1) in housefly, Musca domestica L., and wax moth, Galleria mellonella L., larvae. Excess cholesterol also prevents the chemosterilant effect of filipin in housefly adults. The filipin-induced inhibition of [¹⁴C]cholesterol uptake by wax moth larvae is prevented by excess cholesterol; cholesterol uptake is increased severalfold. Dietary filipin, in the absence of added cholesterol, caused loss of ³²P from housefly tissues and decreased the incorporation of ³²P- and [¹⁴C]methyl-labeled choline into phospholipids of wax moth tissues. Addition of excess cholesterol to filipin-containing diets enhanced incorporation of ³²P into the different classes of phospholipids, and phospholipid synthesis was nearly doubled.     

Neutron diffraction studies of oral stratum corneum model lipid membranes

In this work we have investigated model lipid mixtures simulating a lipid component of oral stratum corneum (OSC). Neutron diffraction experiments on oriented samples have revealed that SM (bovine brain)/dipalmitoylphosphatidylethanolamine/dipalmitoylphosphatidylcholine (DPPE/DPPC) mixtures at molar ratios of 1/2/1 and 1/1/1 are one-phase membranes. The incorporation of low concentrations of ceramide 6 and cholesterol into SM/DPPC/DPPE bilayers does not result in a phase separation, affecting membrane hydration. The model OSC membrane composed of ceramide 6/cholesterol/fatty acids/cholesterol sulfate/SM (bovine brain)/DPPE/DPPC is characterized by coexistence of several lamellar phases, that behave differently during their hydration in water excess. The phase with lamellar repeat distance of about 45 Å is likely a ceramide-rich phase and shows a restricted swelling in water, while another phase with repeat distance of 50 Å swells very quickly on 15 Å and then disappears. Our results indicate that phospholipid-rich and ceramide-rich domains could possibly coexist in the intercellular space of oral epithelium.     

Filipin as a cholesterol probe. II. Filipin-cholesterol interaction in red blood cell membranes

Filipin, a mixture of polyene antibiotics which form complexes with cholesterol, perturbs membrane lipid organization, and causes hemolysis of erythrocytes, is increasingly used as a cytochemical probe for the distribution of cholesterol in cell membranes. We used light (phase-contrast, dark-field and fluorescence) and electron microscopical techniques (whole-mount shadowing, negative staining, and freeze-fracture) to study the interaction of filipin with unfixed and glutaraldehyde-fixed human red blood cell (RBC) membranes. Lysis time and extent depended upon the cholesterol:filipin (C:F) ratio. Lysis was prevented by osmotic protection with high MW dextran. Filipin treated cells fluoresced, but variation in fluorescence intensity among unfixed as well as among fixed cells was evident both at low and high C:F ratios. Negatively stained preparations of unfixed cells lysed on grids or in suspension revealed ring- or C-shaped filipin-induced lesions (FIL) equipped with a veil-like appendage; single FIL, and FIL fused by their veils into aggregates, were shed from membranes. FIL at the surface proper of shadowed whole-mounts and of freeze-etched preparations of prefixed cells appeared as single, dispersed or aggregated cylinders protruding to variable heights above the membrane's plane; aggregated FIL were shed from cells. The freeze-fracture appearance of FIL differed in membranes fixed before or after filipin treatment. E- and P-faces of post-fixed membranes exhibited cylindrical protrusions and depressions, respectively; in essence, the reverse was found in pre-fixed RBC. Both pre- and post-fixed membranes showed considerable variation in the number of FIL on individual cells whether incubated at high (1:1) or low (1:5) C:F ratios, or for a short (10 min) or a long (80-180 min) time. Aggregation and shedding of FIL was evident in all preparations. Thin layer chromatography of the incubation fluid after sedimentation of cells showed that membrane cholesterol was shed from incubated cells. The presented data question the feasibility of filipin as a probe for the topographical distribution of cholesterol in cell membranes.     

Sterol effects on phospholipid biosynthesis in the yeast strain GL7

Cells of the yeast sterol auxotroph GL7 were grown on either ergosterol or cholesterol to mid-logarithmic phase and total membrane fractions prepared. Activities of phospholipid biosynthetic enzymes in the two cell types were determined. The rates of phosphatidyl-ethanolamine-phosphatidyl-choline-N-methyl transferase and acyl-CoA-alpha-glycerol-3-phosphate transcylase were significantly greater in ergosterol-grown than in cholesterol-grown cells. These reactions were also inhibited by the polyene antibiotic filipin. By contrast the activities of long-chain fatty acyl-CoA synthetase, CTP-phosphatidate-cytidyl transferase, phosphatidylserine decarboxylase and of phosphatidylinositol synthetase were identical in the two (ergosterol and cholesterol) cultures and unaffected by filipin. The ergosterol effect on phosphatidyl-ethanolamine N-methyl transferase was greatest in cells harvested in early log phase, intermediate in the mid-log phase cells, and not significant in stationary phase cells.     

More ordered, convex ganglioside-enriched membrane domains: the effects of GM1 on sphingomyelin bilayers containing a low level of cholesterol

The special physical state of the sphingolipid-enriched membranes with characteristic lipid composition, presently one of the most controversial foci in cell biology, provides the essential environment for the proteins inside to be involved in the related physiological processes. The role of gangliosides, an important component of the membranes, deserves attention. The present investigation using several biophysical techniques indicates that ganglioside GM(1) induces the phase separation in the sphingomyelin membrane with 5 mol% cholesterol and regulates the membrane structure. The results of differential scanning calorimetry show that a higher T(m), GM(1)-rich phase emerges behind the lower T(m), sphingomyelin-rich phase with the incorporation of GM(1) into the sphingomyelin/cholesterol bilayers; and the GM(1)-rich phase dominates the membrane when the proportion of GM(1) reaches about 20 mol%. Fluorescence quenching further shows that the separation of the two domains is independent of temperature, occurring both in the gel phase and in the liquid phase. Laser Raman spectroscopy and fluorescence polarization suggest that the order of hydrocarbon chains increases and membrane fluidity decreases with increase in GM(1) content. Use of the fluorescence probe merocyanine-540 and electron microscopy reveals that the insertion of GM(1) leads to an increase in the spatial density of the lipid headgroups and a decrease in the curvature of the sphingomyelin/cholesterol bilayers. In sums, both the hydrophilic sugar heads and the hydrophobic hydrocarbon chains of GM(1) contribute to the regulation of membrane architecture. We suggest that the convex curvature of ganglioside-enriched membrane could be involved in forming and maintaining the characteristic flask-shaped invagination of caveolae.     

Self-association of model transmembrane alpha-helices is modulated by lipid structure

We have developed a fluorescence quenching method using peptides containing 3,5-dibromotryrosine to measure oligomerization of model transmembrane alpha-helices in lipid bilayers. Peptides of the type Ac-LysLysGlyLeu(m)XLeu(n)LysLysAla-amide where X is tryptophan or 3,5-dibromotyrosine were found to form heterodimers in bilayers of phosphatidylcholine in the liquid-crystalline phase. The free energy of dimer formation changed little with increasing number of Leu residues from 16 to 22 but increased with increasing phospholipid fatty acyl chain length, with a slope of about 0.5 kJ mol(-1) per fatty acyl chain carbon. Peptides were excluded from lipid in the gel phase, resulting in increased levels of oligomerization. Addition of cholesterol to form the liquid-ordered state led to increased dimerization but without phase separation. The presence of phosphatidylethanolamine had little effect on dimerization.