Membrane-permeabilizing activities of amphidinol 3, polyene-polyhydroxy antifungal from a marine dinoflagellate

Amphidinols, which are polyene-polyhydroxy metabolites produced by the marine dinoflagellate Amphidinium klebsii, possess potent antifungal and hemolytic activities. The membrane permeabilizing actions of amphidinol 3, the most potent homologue, were compared with those of polyene antibiotics, amphotericin B (AmB) and filipin, in hemolytic tests, ²³Na nuclear magnetic resonance (NMR)-based membrane permeabilizing assays, and UV spectroscopy for liposome-bound forms. In Na⁺ flux experiments using large unilamellar vesicles (LUVs), ion efflux by amphidinol 3 was inhibited by cholesterol or ergosterol, which was opposed to previous results [J. Mar. Biotechnol., 5 (1997) 124]. When the effect of the agents on the size of vesicles was examined by light scattering experiments, amphidinol 3 did not significantly alter their size while filipin and synthetic detergent Triton X-100 did. The observations implied that the activity of amphidinol 3 was mainly due to formation of large pores/lesions in liposomes rather than detergent-like disruption of membrane. The pore/lesion size was estimated to be 2.0-2.9 nm in diameter on the basis of osmotic protection experiments using blood cells. The UV spectra in liposomes, which revealed the close interaction of polyene moieties in a lipid bilayer, further implied that the membrane activity of amphidinol 3 is caused by the molecular assemblage formed in biomembrane. These results disclose that amphidinol 3 is one of few non-ionic compounds that possess potent membrane permeabilizing activity with non-detergent mechanism.     

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.     

Effect of filipin on liposomes prepared with different types of steroids

The action of the polyene antibiotic filipin on the permeability of liposomes prepared with lecithin and several plant and other steroids was studied. The effect of filipin was found to be dependent upon the type of steroid incorporated into the membrane. The interaction of filipin with steroids was found to be related both to the functional group at the 3-position and the aliphatic chain of the steroid. Complex formation of the steroid with filipin in aqueous solutions, as detected by ultraviolet spectrophotometry, correlated with the ability of filipin to increase the permeability of the liposomes.     

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.     

Interaction of the polyene antibiotics with lipid bilayer vesicles containing cholesterol

The interaction of the polyene antibiotics, amphotericin B, nystatin and filipin with cholesterol-containing single bilayer lipid vesicles has been characterized using gel permeation chromatography and proton magnetic resonance. All three antibiotics bind to vesicles at low concentrations without causing a large amount of vesicle destruction. The strength of binding as determined by gel permeation studies is greater for filipin and amphotericin than for nystatin. Nystatin and amphotericin B at these low concentrations induce a rapid loss of internal vesicle contents consistent with pore formation. Filipin induces no leakage beyond that expected from partial vesicle destruction or general detergent action.At antibiotic levels above 1 : 1 antibiotic : cholesterol ratios the NMR results show all three antibiotics to cause extensive vesicle destruction. The onset of this behavior, which appears to be independent of the total antibiotic concentration, indicates a well defined antibiotic : cholesterol interaction stoichiometry. Despite the fact that cholesterol is required for antibiotic activity, the NMR spectra prior to vesicle destruction show no changes indicative of an antibiotic-induced reversal of cholesterol restriction of phosphatidylcholine mobility. The contrast with polyene antibiotic behavior in more extended bilayers is discussed.     

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

The effects of the polyene antibiotic filipin on the conductance and permeability of planar lipid bilayers were investigated under voltage-clamp conditions. The membrane conductance of lipid bilayers containing no cholesterol was not affected by filipin. In the presence of cholesterol containing lipid bilayers, filipin induced a 10(4)-10(5)-fold increase in transmembrane conductance. This conductance increase was dependent on the ionic species present in solution, decreasing in the following order: GCsCl greater than GNaAc greater than GKCl greater than GNaCl greater than CaCl2 greater than GNa2SO4 greater than GBaCl2 greater than GMgCl2. Reversal potential measurements in simple biionic conditions revealed the following relative permeability sequence: PK greater than PCl greater than PNa approximately Pac approximately PBa greater than PCs greater than PMg approximately PCa greater than Psulphate. The filipin-sterol mediated increase in membrane conductance was independent of the membrane potential. The increase in membrane current following a step alteration in membrane potential occurred instantaneously and had no dependence on the previous value of the holding membrane potential. We propose that the filipin-sterol complex forms ion channels in lipid membranes. These channels are found in a single configuration (open state) and select preferentially monovalent cations or anions over divalent ions. Our experimental results are discussed in relation to the effects of other polyene antibiotics on the membrane permeability, and also in relation to experimental problems previously reported with the use of filipin in planar lipid bilayers.     

Interaction of the polyene antibiotics with lipid bilayer vesicles containing cholesterol.

The interaction of the polyene antibiotics, amphotericin B, nystatin and filipin with cholesterol-containing single bilayer lipid vesicles has been characterized using gel permeation chromatography and proton magnetic resonance. All three antibiotics bind to vesicles at low concentrations without causing a large amount of vesicle destruction. The strength of binding as determined by gel permeation studies is greater for filipin and amphotericin than for nystatin. Nystatin and amphotericin B at these low concentrations induce a rapid loss of internal vesicle contents consistents consistent with pore formation. Filipin induces no leakage beyond that expected from partial vesicle destruction or general detergent action. At antibiotic levels above 1:1 antibiotic: cholesterol ratios the NMR results show all three antibiotics to cause extensive vesicle destruction. The onset of this behavior, which appears to be independent of the total antibiotic concentraion, indicates a well defined antibiotic : cholesterol interaction stoichiometry. Despite the fact that cholesterol is required for antibiotic activity, the NMR spectra prior to vesicle destruction show no changes indicative of an antibiotic-induced reversal of cholesterol restriction of phosphatidylcholine mobility. The contrast with polyene antibiotic behavior in more extended bilayers is discussed.     

Effects of Filipin and Cholesterol on K Movement in Etiolated Stem Cells of Pisum sativum L

Filipin, a polyene antibiotic known to induce leakage of materials from various cells, depresses K⁺ and NO₃⁻ uptake in etiolated pea epicotyl segments. Filipin concentrations which strongly reduce K⁺ influx have little effect on efflux; however, high concentrations enhance K⁺ efflux. Filipin has no effect on respiration rates or cell electropotentials; its action is presumed to be on the cell membranes. Cholesterol, but not a thiol-protecting agent (dithiothreitol), enhances K⁺ influx and counteracts the inhibition by filipin. Although this effect of cholesterol may be due to an interaction with filipin in the outer solution, there is reason to believe that its major effect is to impart stability to the membrane; filipin is believed to act by interfering with sterol stabilization of phospholipid layers. The predominant native sterols of etiolated pea stem (Pisum sativum L. var. Alaska), which cholesterol probably mimics, are β-sitosterol, campesterol, and stigmasterol.     

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.     

Membrane-permeabilizing activities of amphidinol 3, polyene-polyhydroxy antifungal from a marine dinoflagellate

Amphidinols, which are polyene-polyhydroxy metabolites produced by the marine dinoflagellate Amphidinium klebsii, possess potent antifungal and hemolytic activities. The membrane permeabilizing actions of amphidinol 3, the most potent homologue, were compared with those of polyene antibiotics, amphotericin B (AmB) and filipin, in hemolytic tests, 23Na nuclear magnetic resonance (NMR)-based membrane permeabilizing assays, and UV spectroscopy for liposome-bound forms. In Na+ flux experiments using large unilamellar vesicles (LUVs), ion efflux by amphidinol 3 was inhibited by cholesterol or ergosterol, which was opposed to previous results [J. Mar. Biotechnol., 5 (1997) 124]. When the effect of the agents on the size of vesicles was examined by light scattering experiments, amphidinol 3 did not significantly alter their size while filipin and synthetic detergent Triton X-100 did. The observations implied that the activity of amphidinol 3 was mainly due to formation of large pores/lesions in liposomes rather than detergent-like disruption of membrane. The pore/lesion size was estimated to be 2.0-2.9 nm in diameter on the basis of osmotic protection experiments using blood cells. The UV spectra in liposomes, which revealed the close interaction of polyene moieties in a lipid bilayer, further implied that the membrane activity of amphidinol 3 is caused by the molecular assemblage formed in biomembrane. These results disclose that amphidinol 3 is one of few non-ionic compounds that possess potent membrane permeabilizing activity with non-detergent mechanism.     

Phosphatidylcholine liposomes containing cholesterol analogues with side chains of various lengths

The effect of the length of the side chain of sterols on their interaction with phosphatidylcholine was studied by measuring the permeability properties of liposomes constituted with sterol analogues with side chains of various lengths. The sensitivities of liposomes constituted with these sterol analogues toward digitonin and polyene antibiotics were also examined.The effects of sterols on phase transition of phosphatidylcholine were examined by measuring their effects on permeability increase due to perturbation of phase equilibrium and by differential scanning calorimetry. An analogue with a short side chain, isopropyl (C-22), had a very similar effect to cholesterol in suppressing the permeability increase, suggesting that the full length of the side chain is not necessary for this effect.The permeability of egg yolk phosphatidylcholine at 42°C was suppressed as much by the analogue C-22 as by cholesterol. Androstene-3-β-ol, an analogue without a side chain, however, had little suppressive effect. Thus it is concluded that the condensing effect of sterol requires a side chain, but not the full length of side chain.Liposomes constituted with analogues having a side chain with more than 5 carbon atoms showed maximum reactivity with a polyene antibiotic, amphotericin B, whereas those constituted with analogues having a side chain with less than 4 carbon atoms showed weaker reactivity. These findings indicate that a side chain with more than 5 carbon atoms is essential for the maximum interaction of liposomes with amphotericin B. Unlike amphotericin B, filipin reacted almost equally well with liposomes containing C-22 and with those containing cholesterol. Thus the chain length of the side chain of sterol is less important for interaction of liposomes with filipin than for their interaction with amphotericin B.Liposomes containing analogues having a side chain with more than 6 carbon atoms showed maximum reactivity with digitonin. Thus for the maximum interaction of liposomes with digitonin, the side chain of sterol should be longer than 6 carbon atoms.     

2H NMR evidence for antibiotic-induced cholesterol immobilization in biological model membranes

The interaction of the polyene antibiotic filipin with membrane sterols has been studied by deuterium nuclear magnetic resonance of the molecular probes [2,2,3,4,4,6-2H6]cholesterol and 1-myristoyl-2-[4',4',14',14',14'-2H5]myristoyl-sn-glycero-3-phospho- choline. At physiological temperatures, there is evidence of filipin-induced cholesterol immobilization in the membrane. The 2H NMR spectra of cholesterol show two domains in which ordering and dynamics are very different. In one of these, cholesterol is static on the 2H NMR time scale, whereas in the other it undergoes rapid axially symmetric motions similar to those it exhibits in the drug-free membrane; this indicates that the jumping frequency of cholesterol between the labile and immobilized domains is less than 10(5) s-1. The distribution of cholesterol between these two sites is temperature dependent; at 0 degrees C all sterol molecules are immobilized, whereas at 60 degrees C they are almost totally in the labile site. In contrast to cholesterol, the phospholipids sense only one type of environment, at both the top and center of the bilayer, indicating that cholesterol acts as a screen, preventing the lipids from direct interaction with the antibiotic. At low temperature, the ordering of the lipid in the presence of cholesterol does not change upon filipin addition, whereas at elevated temperatures the local ordering of both the lipid and the labile cholesterol is significantly lower than that in the absence of the drug. Moreover, there is a very important difference between the degree of local ordering as measured by the lipids and by cholesterol at high temperatures.(ABSTRACT TRUNCATED AT 250 WORDS)     

Activation of particulate guanylate cyclase by nitroprusside and MNNG after filipin treatment.

Particulate guanylate cyclase from rat lung was stimulated less than 2-fold by agents capable of activating the soluble guanylate cyclase, including sodium nitroprusside, MNNG, azide and hydroxylamine. The action of the first two agents was potentiated by 10 mM 2-mercaptoethanol, and that of the last two by catalase. Pretreatment of the particulate enzyme with the polyene antibiotic, filipin, potentiated the stimulatory effects of the activators, activity with 1 mM nitroprusside in the presence of 2-mercaptoethanol being increased 10.4-fold over basal. The enzyme treated with filipin and nitroprusside showed less specificity for Mn2+, as it was able to use Mg2+ as sole cation more efficiently than the untreated enzyme. Since filipin is known to alter membrane fluidity by interacting with membrane cholesterol, it is proposed that the activity of membrane bound guanylate cylase may be regulated in part by the fluid state of the phospholipid matrix.     

Formation of Two Different Types of Ion Channels by Amphotericin B in Human Erythrocyte Membranes

The polyene antibiotic amphotericin B (AmB) is known to form aqueous pores in lipid membranes and biological membranes. Here, membrane potential and ion permeability measurements were used to demonstrate that AmB can form two types of selective ion channels in human erythrocytes, differing in their interaction with cholesterol. We show that AmB induced a cation efflux (negative membrane polarization) across cholesterol-containing liposomes and erythrocytes at low concentrations (≤1.0 × 10⁻⁶ M), but a sharp reversal of such polarization was observed at concentrations greater than 1.0 × 10⁻⁶ M AmB, an indication that aqueous pores are formed. Cation-selective AmB channels are also formed across sterol-free liposomes, but aqueous pores are only formed at AmB concentrations 10 times greater. The effect of temperature on the AmB-mediated K⁺ efflux across erythrocytes revealed that the energies of activation for channel formation are negative and positive at AmB concentrations that lead predominantly to the formation of cation-selective channels and aqueous pores, respectively. These findings support the conclusion that the two types of AmB channels formed in human erythrocytes differ in their interactions with cholesterol and other membrane components. In effect, a membrane lipid reorganization, as induced by incubation of erythrocytes with tetrathionate, a cross-linking agent of the lipid raft–associated protein spectrin, led to differential changes in the activation parameters for the formation of both types of channels, reflecting the different lipid environments in which such structures are formed.     

Absorption and fluorescence spectra of polyene antibiotics in the presence of cholesterol.

The alterations in the absorption and fluorescence spectra observed for the polyene antibiotics filipin and nystatin in the presence of cholesterol are due to an exciton interaction (polyene aggregates) and cannot be attributed to a specific sterol-antibiotic complex. Filipin and nystatin molecules partition into the sterol aggregates, these structures being very efficient to induce exciton interaction; the observed splitting profile indicates that the chromophores are in a stacked arrangement (parallel transition dipoles). For filipin incorporated in lipid bilayers, the sterol is able to induce the same type of aggregate, at variance with nystatin.     

Influence of the membrane undercoat on filipin perturbation of the red blood cell membrane

Filipin, a polyene antibiotic, interacts with beta-hydroxy sterols such as cholesterol in most cell membranes, forming bumps and pits that are visible by electron microscopy of freeze-fracture replicas. The markedly reduced perturbability of the red blood cell (RBC) membrane, compared to other cells, has been attributed to the constraining influence of the red cell membrane skeleton, the undercoat composed of spectrin, actin, and protein 4.1. To test the influence of the membrane skeleton on filipin-induced perturbation of the RBC membrane, we studied the interaction of filipin with red cells that were inherently devoid of spectrin and RBC in which spectrin had been crosslinked or denatured. These spectrin-deficient, crosslinked, and denatured cells have a fivefold increase in the number of filipin-induced perturbations as compared to control cells, despite equivalent membrane cholesterol content. These findings confirm that the spectrin-based membrane skeleton strongly influences the organization of the membrane so as to limit perturbation by filipin:cholesterol interaction and that for membranes in which the cholesterol content is known, filipin is a useful probe for testing the avidity of spectrin-based cytoskeletal attachment.