Interaction of amphotericin B and nystatin with phospholipid bilayer membranes:effect of cholesterol.

Sodium-22 efflux was measured in multilamellar liposomes, exposed to one of the two polyene antibiotics amphotericin B or nystatin. Polyene mediated 22Na transport progressively rises with membrane sterol concentrations up to about 20 mol %, but falls with higher cholesterol concentrations. The polyene induced 22Na movement in cholesterol rich liposomes could be 'restored' by the addition of either dibucaine or propranolol (two local anesthetics) to the aqueous solution. These observations are interpreted in terms of the model of De Kruijff and Demel (Biochim. Biophys. Acta, 339, 57-70, 1974). In this model, nystatin and amphotericin B first complex with cholesterol and then these complexes aggregate to form transmembrane channels. It is here proposed that the aggregation of these complexes is inhibited by a high cholesterol content (decreased membrane fluidity) but that the two local anesthetics, by disrupting phospholipid-sterol interactions (increased membrane fluidity), can 'restore' this process of aggregation.     

Interaction of amphotericin B with monolayers of egg lecithin and cholesterol: polorized absorption spectra

Polarized absorption spectra have been obtained of the antibiotic polyene, amphotericin B, interacting with monolayers of egg lecithin, cholesterol and equimolar egg lecithin-cholesterol at low and high surface pressures. An expression is derived which enables the determination from the polarization data of the orientations of the transition moments of the polyene absorption bands at 4077 and 3645 Å. For some of the systems the 3645-Å band is replaced by a previously unreported band appearing between 3610 and 3632 Å. The orientation of the 4077-Å transition moment (parallel to the long molecular axis) is found to vary from an angle of 64 ° with the surface for the low-pressure monolayers of cholesterol to 21 ° for the high-pressure films of egg lecithin-cholesterol. For the band between 3610 Å and 3645 Å, the angle varies from 90 ° for cholesterol to 18 ° for the high-pressure mixed-lipid film. It is found that a large increase in surface pressure of the cholesterol and egg lecithin-cholesterol monolayers causes a decrease in the angle of the 4077-Å moment for both films and that of the higher energy moment for the mixed film. Increasing the content of cholesterol in these monolayers rotates the orientation of the transition moments for both bands toward the surface normal, the change being greatest for the low-pressure films. The effectiveness of amphotericin B in lowering the surface tension of these lipid monolayers is related to its binding, orientation and extent of penetration. For low-pressure cholesterol films where the surface interaction with the polyene is greatest, the binding and penetration are large and the polyene molecule is oriented with its long dimension nearly perpendicular to the surface.     

Stoichiometry of hemolysis by the polyene antibiotic lucensomycin

The stoichiometry of hemolysis by the polyene antibiotic lucensomycin was investigated. It appears that hemolysis occurs only when a relatively high fraction (probably between 15 and 40%) of the cholesterol sites in the erythrocyte membrane have combined with the polyene. Also in phospholipid-cholesterol vesicles the increase of permeability requires occupancy of 40–50% of the existing cholesterol sites.As for the possible cooperative effect in the hemolytic process, it is probable that several (at least 9–10) lucensomycin-cholesterol adducts must interact on each side of the membrane to form an aqueous channel; the distribution of these adducts in the erythrocyte membrane occurs, however, apparently at random.     

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.     

Potential-dependent formation of single conducting ion channels in lipid bilayers induced by the polyene antibiotic levorin A

The aromatic polyene antibiotic levorin A2 forms ion channels permeable to monovalent cations, in lipid membranes containing cholesterol or ergosterol. Channel conductivity is in the range 0.3-0.5 pS. The channel has two main states: conducting (open) and nonconducting (closed). The potential-dependent formation of levorin A2 channels is observed in lipid membranes. The system responsible for the ion-channel selectively is localized on the hydrophilic side of the lactone ring of the polyene molecule.     

PMR studies of phosphatidylcholine-cholesterol vesicles interacting with lucensomycin.

Spin-lattice relaxation times (T1) were measured above the phase transition temperature on sonicated vesicles of egg- or dipalmitoyl-phosphatidylcholine containing cholesterol and/or the polyenic antibiotic, lucensomycin. T1 values of only the terminal methyl groups of the fatty acyl chains were significantly reduced by cholesterol. Lucensomycin caused, more markedly in cholesterol-containing vesicles, a selective reduction of the T1 values of the N-methyl groups. An even more conspicuous decrease, occurring only in cholesterol-containing vesicles, was observed for the transverse relaxation times (T2) of the N-methyl signals upon addition of lucensomycin. The polyene failed to remove the well-known broadening effect of cholesterol on phosphatidylcholine methylene signals. These results indicate that as lucensomycin binds to cholesterol-containing membranes, there is a detectable perturbation of the dynamic structure of the N-methyl groups with an increase in the degree of motional anisotropy. But the non-polar region of the bilayer seems not significantly perturbed by the polyene.     

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.     

Potential-dependent formation of single conducting ion channels in lipid bilayers induced by the polyene antibiotic levorin A2

The aromatic polyene antibiotic levorin A₂ forms ion channels permeable to monovalent cations, in lipid membranes containing cholesterol or ergosterol. Channel conductivity is in the range 0.3–0.5 pS. The channel has two main states: conducting (open) and nonconducting (closed). The potential-dependent formation of levorin A₂ channels is observed in lipid membranes. The system responsible for the ion-channel selectivity is localized on the hydrophilic side of the lactone ring of the polyene molecule.     

Comparative conformational analysis of cholesterol and ergosterol by molecular mechanics

A comparative conformational analysis of cholesterol and ergosterol has been carried out using molecular mechanics methods. These studies are aimed at giving a better understanding of the molecular nature of the interaction of these sterols with polyene macrolide antibiotics. Structures of cholesterol and ergosterol determined by X-ray methods have been used as initial geometries of these molecules for force field calculations. The calculation of steric energy has also been made for conformations which do not appear in the crystal. The latter conformers have different conformations of the side chain as well as different conformations of rings A and D. The rotational barriers around bonds C17–C20 and C20–C22 have also been calculated. The results obtained on differences and similarities in the conformations of cholesterol and ergosterol allow us to postulate a mechanism for differential interaction with the antibiotics. The relatively rigid side chain of ergosterol (stretched molecule) in comparison with the flexible side chain of cholesterol (bent molecule), allows better intermolecular contact of the first sterol molecule with a polyene macrolide and in consequence facilitates complex formation involving Van der Waal's forces.     

Interaction between nystatin and natural membrane lipids in Langmuir monolayers--the role of a phospholipid in the mechanism of polyenes mode of action

Nystatin (NYS), a polyene antifungal antibiotic, has been investigated in Langmuir monolayers alone and in mixtures with mammalian and fungi membrane sterols (cholesterol and ergosterol, respectively) as well as with a model phospholipid (DPPC). The interactions between film molecules have been examined both in a qualitative and quantitative way with the excess area per molecule (AExc), excess free energy of mixing (DeltaGExc) and the interaction parameter (alpha). The obtained results have been compared with those previously reported for another polyene antimycotic: amphotericin B (AmB) mixed with lipids. Higher affinity of NYS has been observed for ergosterol vs. cholesterol, however, the strongest attractions were found for its mixtures with DPPC. The obtained results have been verified with biological studies reported previously for both antibiotics (NYS and AmB). A thorough analysis of the Langmuir experiment results performed for both polyenes enabled us to conclude that the presence of DPPC can be considered as a key factor affecting their antifungal activity as well as their toxicity towards host cells.     

The interaction of the polyene antibiotic lucensomycin with cholesterol in erythrocyte membranes and in model systems. III. Characterization of spectral parameters.

The variations of optical density and fluorescence of lucensomycin are good indices of the binding of this polyenic antibiotic to membranes. The former parameter reflects more generally the binding to any site present in the membrane, while the latter is more specific for binding to cholesterol. The chromophore of the lucensomycin-cholesterol complex has a relatively long lifetime, is almost immobile in the membrane, and is not accessible to water-soluble fluorescence-quenching agents. The stoichiometry, evaluated fluorometrically, corresponds to about two cholesterol molecules per polyene. In colloidal cholesterol suspensions, the extent of binding as a function of free polyene concentration is described by rectangular hyperbolae, the dissociation constant being, however, dependent on the sterol concentration. In erythrocyte membranes, on the other hand, and even more markedly in model systems containing appropriate solvents, the combination between lucensomycin and the sterol sites is described by sigmoid titration curves, indicative of cooperative effects, and probably due to solvation of cholesterol.     

Investigation of polyene macrolide antibiotic-induced permeability changes in vesicles by 31P nuclear magnetic resonance

The permeability of egg yolk lecithin (EYL) vesicles to Pr3+ has been measured by 31P nuclear magnetic resonance (nmr) spectroscopy. Measurable Pr3+ leakage into the internal aqueous compartment of EYL vesicles at ambient (21 degrees C) temperature required the presence of small (7--10 mol%) amounts of dicetyl phosphate (DCP). The permeability of DCP-containing vesicles is decreased by incorporation of sterol (cholesterol greater than ergosterol approximately 5.6-dihydroergosterol greater than zymosterol) into the lipid bilayer. Addition of the polyene macrolide antibiotic, nystatin, to DCP-containing EYL vesicles with and without sterol resulted in increased Pr3+ permeability at the three temperatures studied (21--37.5 degrees C). Permeability changes observed upon addition of nystatin to sterol-impregnated, DCP-containing vesicles varied with sterol structure: ergosterol approximately 5,6-dihydroergosterol greater than cholesterol approximately zymosterol. These results are compared with other polyene macrolide induced permeability changes on model and natural membrane systems. Permeability changes induced by nystatin in sterol-free EYL vesicles were generally greater than for comparable sterol-containing vesicles. This is attributed to a nonspecific interaction of the antibiotic with the latter vesicles.     

Compactin (ML-236B) reduces the content of filipin-cholesterol complexes in the plasma membrane of chronic lymphocytic leukemia cells

The polyene antibiotic filipin was used to visualize the presence and distribution of cholesterol in the plasma membrane of glutaraldehyde-fixed human chronic lymphocytic leukemia (CLL) cells. Both compactin (ML-236B), a competitive inhibitor of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase, and 25-hydroxycholesterol reduced the content of filipin-cholesterol complexes in the plasma membrane of CLL cells grown in media supplemented with either 15% delipidized horse serum or 15% normal (whole) horse serum. The reduction due to compactin was reversed by the concomitant addition of mevalonolactone. The ability of compactin to reduce the relative cholesterol content (as judged by filipin labeling) in CLL cells grown in lipoprotein-containing (normal) serum suggest that either CLL cells are different from other cells in that they predominantly utilize endogenously synthesized cholesterol for incorporation into the plasma membrane, or that a separate pool of endogenously synthesized cholesterol provides cholesterol for the plasma membrane.     

Specificity of the effect of polyene phosphatidylcholine depending on the mode of administration and animal species]

The effects of polyene phosphatidylcholine (PPC) treatment at oral and intravenous administration to rats and rabbits in hypercholesterolemic diet were studied. No aorta damage was observed in either of rat groups. But fatty liver appeared, and it was the greatest in rats, who received cholesterol and PPC. The result may be attributed to adaptive protection of peripheral tissues due to high experiment duration (18 months) in the state of active reverse cholesterol transport (RChT). No antiatherogenic effect was noted in rabbits at PPC administration (170 mg/kg), while its intravenous injection (50 mg/kg) resulted in marked reduction of plasma cholesterol level, elevation of HDL cholesterol and decrease of the extent of aorta damage. The conclusion is drawn on the ppc high antiatherogenic effect predominantly at intravenous administration, and on advisability of its use in cases of RChT deficiencies, as its activator.     

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.     

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.     

Interaction of lucensomycin with membranes: the role of non-steroidal components

The binding of lucensomycin to unilamellar phospholipid/cholesterol vesicles and to colloidal emulsions of cholesterol in aqueous solutions was studied by monitoring the changes in the electronic absorption spectra of the polyene antibiotic. The total extent of the absorption variations was a direct function of cholesterol concentration and quite independent of the nature of the emulsion. The rate of binding, relatively slow in the colloidal systems, was greatly enhanced when cholesterol was included in phospholipid-containing membranes. The rate of lucensomycin binding to colloidal cholesterol increased with increasing cholesterol concentrations and/or stirring the heterogeneous suspension. The time course of lucensomycin binding to vesicles appeared to be independent of the concentrations of phospholipids and cholesterol.     

Effect of cholesterol on the functional activity of proteins responsible for the resistance of human lymphocytes to xenobiotics

The influence of agents modifying cholesterol in plasma membranes on the functional activity of transporter proteins (P-glycoprotein (P-gp) and multidrug resistance protein 1 (MRP1)) in human lymphocytes has been studied. It was shown that changes in the lateral distribution of cholesterol using the polyene antibiotic filipin, which disturbs the structure and function of glycolipid microdomains in plasma membranes of lymphocytes lead to a decrease in the transport activity of both P-gp and MRP1. It was found that the treatment of human lymphocytes with the cyclic oligosaccharide methyl-β-cyclodextrin, which leads to cholesterol depletion and reduction of lipid bilayer microviscosity in membranes of these cells, also decreases the functional activity of these proteins. It was concluded that the transport activity of P-gp and MRP1 depends on the modification of cholesterol in the membranes of human lymphocytes, i.e., is closely associated with the level of cholesterol and its lateral distribution.     

The mechanism of the action of prymnesium toxin on membranes

The mechanism of the lytic action of prymnesin, a toxin produced by the alga, Prymnesium parvum, was studied using liposomes as a model membrane system. Prymnesin showed severe damage to liposomes containing cholesterol but did not affect those without cholesterol. The requirement of cholesterol for the susceptibility to prymnesin was much more strict than the reported requirement for the susceptibility to polyene antibiotics. The net charge on the membranes was shown not to be important for the reaction.     

Microbial cholesterol oxidases: bioconversion enzymes or signal proteins?

Cholesterol oxidases (3beta-hydroxysterol oxidases; EC 1.1.3.6), serve as catalysts for the initial step in the degradation of cholesterol, and probably other natural sterols, that are used as carbon sources for growth of different bacteria. Because of their suitability for attacking cholesterol they have been widely used for the quantification of cholesterol in clinical and food specimens. Cholesterol oxidase has also found application as a probe for membrane structure, as an insecticide, and has been implicated in bacterial pathogenesis. Recently, we have found that a Streptomyces cholesterol oxidase is required for the biosynthesis of the antifungal polyene pimaricin, apparently acting as an antifungal sensor. Here we describe our current understanding of these fascinating enzymes.