The dipole-modifying effect of styrylpyridinium dyes and flavonoids on model membranes of different lipid compositions

Changes in dipole potential of lipid bilayers ?d mimicking cell membranes induced by the adsorption of low-molecular-weight amphiphiles, flavonoids (phloretin and quercetin), and styrylpyridinium dyes (RH 421 and RH 237) were measured. A method based on the determination of ionophore-induced transmembrane current was used to evaluate changes in ?d after modifier addition. The characteristic parameters of the Langmuir adsorption isotherm and the greatest changes in ?d at an infinitely large concentration of flavonoid and its desorption constant, which reflects the affinity of the flavonoid to the lipid phase, were determined. The slopes of linear dependences of ?d increasing on the concentration of the styrylpiridinium dyes in membrane-bathing solution were defined. It was found that the dipole-modifying effect of phloretin depends on the charge of the lipids forming the membranes, while the ability of quercetin to reduce ?d is determined by the initial hydration of the bilayer. The results indicate that there are different mechanisms of the decrease in ?d upon the adsorption of the tested flavonoids. It was shown that the changes in ?d at the incorporation of styrylpyridinium dyes into bilayers are determined by the interaction of modifiers with membrane components.     

Probing amphotericin B single channel activity by membrane dipole modifiers

The effects of dipole modifiers and their structural analogs on the single channel activity of amphotericin B in sterol-containing planar phosphocholine membranes are studied. It is shown that the addition of phloretin in solutions bathing membranes containing cholesterol or ergosterol decreases the conductance of single amphotericin B channels. Quercetin decreases the channel conductance in cholesterol-containing bilayers while it does not affect the channel conductance in ergosterol-containing membranes. It is demonstrated that the insertion of styryl dyes, such as RH 421, RH 237 or RH 160, in bilayers with either cholesterol or ergosterol leads to the increase of the current amplitude of amphotericin B pores. Introduction of 5α-androstan-3β-ol into a membrane-forming solution increases the amphotericin B channel conductance in a concentration-dependent manner. All the effects are likely to be attributed to the influence of the membrane dipole potential on the conductance of single amphotericin B channels. However, specific interactions of some dipole modifiers with polyene-sterol complexes might also contribute to the activity of single amphotericin B pores. It has been shown that the channel dwell time increases with increasing sterol concentration, and it is higher for cholesterol-containing membranes than for bilayers including ergosterol, 6-ketocholestanol, 7-ketocholestanol or 5α-androstan-3β-ol. These findings suggest that the processes of association/dissociation of channel forming molecules depend on the membrane fluidity.     

The interaction of dipole modifiers with amphotericin-ergosterol complexes. Effects of phospholipid and sphingolipid membrane composition

The influence of agents, known to affect the membrane dipole potential, phloretin and RH 421, on the multi channel activity of amphotericin B in lipid bilayers of various compositions, was studied. It was shown that the effects were dependent on the membrane’s phospholipid and sphingolipid type. Phloretin enhanced amphotericin B induced steady-state transmembrane current through bilayers made from binary mixtures of POPC (DOPC) and ergosterol and ternary mixture of DPhPC, ergosterol and stearoylphytosphingosine. RH 421 increased steady-state polyene induced transmembrane current through membranes made from binary mixtures of DPhPC (DPhPS) and ergosterol and ternary mixture of DPhPS, ergosterol and stearoylphytosphingosine. It was proposed that the observed effects reflect the fine balance of the interactions between the various components present: amphotericin B, ergosterol, phospholipid, sphingolipid and dipole modifier. The shape of lipid molecules seems to be an important factor impacting the responses of amphotericin B modified bilayers to dipole modifiers. The influence of different phospholipids and sphingolipids on the physical and structural properties of ordered lipid microdomains, enriched in AmB, was also discussed. It was also shown that RH 421 enhanced the antifungal activity of amphotericin B in vitro.     

The effects of amphotericin B on pure and ergosterol- or cholesterol-containing dipalmitoylphosphatidylcholine bilayers as viewed by 2H NMR

Amphotericin B (AmB) is a widely used polyene antibiotic to treat systemic fungal infections. This drug is known to be lethal to fungal cells but it has also side effect toxicity on mammalian cells. The mechanism of action of AmB is thought to be related to the difference of the main sterol present in the mammalian and the fungal cells, namely cholesterol and ergosterol, respectively. The effect of AmB has been investigated on pure dipalmitoylphosphatidylcholine (DPPC) and on cholesterol- and ergosterol-containing DPPC bilayers by 2H NMR spectroscopy. The 2H NMR results first confirm that AmB forms a complex with sterol-free DPPC bilayers, the interaction causing the structurization of the lipids and the increase of the gel-to-lamellar fluid DPPC phase transition temperature with increasing concentration of the antibiotic. The results also show that the effects of AmB on cholesterol- and ergosterol-containing DPPC bilayers are remarkably different. On one hand, the drug causes an increase of the orientational order of the lipid acyl chains in cholesterol-containing membranes, mostly in high cholesterol content membranes. On the other hand, the addition of AmB disorders the DPPC acyl chains when ergosterol is present. This is thought to be due to the direct complexation of the ergosterol by AmB, causing the sterol ordering effect to be weaker on the lipids.     

Comparative molecular dynamics simulations of amphotericin B-cholesterol/ergosterol membrane channels

Amphotericin B (AmB) is a very effective anti-fungal polyene macrolide antibiotic whose usage is limited by its toxicity. Lack of a complete understanding of AmB's molecular mechanism has impeded attempts to design less toxic AmB derivatives. The antibiotic is known to interact with sterols present in the cell membrane to form ion channels that disrupt membrane function. The slightly higher affinity of AmB toward ergosterol (dominant sterol in fungal cells) than cholesterol (mammalian sterol) is regarded as the most essential factor on which antifungal chemotherapy is based. To study these differences at the molecular level, two realistic model membrane channels containing molecules of AmB, sterol (cholesterol or ergosterol), phospholipid, and water were studied by molecular dynamics (MD) simulations. Comparative analysis of the simulation data revealed that the sterol type has noticeable effect on the properties of AmB membrane channels. In addition to having a larger size, the AmB channel in the ergosterol-containing membrane has a more pronounced pattern of intermolecular hydrogen bonds. The interaction between the antibiotic and ergosterol is more specific than between the antibiotic and cholesterol. These observed differences suggest that the channel in the ergosterol-containing membrane is more stable and, due to its larger size, would have a higher ion conductance. These observations are in agreement with experiments.     

Cholesterol markedly reduces ion permeability induced by membrane-bound amphotericin B

It is widely accepted that amphotericin B (AmB) together with sterol makes a mixed molecular assemblage in phospholipid membrane. By adding AmB to lipids prior to preparation of large unilamellar vesicles (LUV), we directly measured the effect of cholesterol on assemblage formation by AmB without a step of drug's binding to phospholipid bilayers. Potassium ion flux assays based on ³¹P-nuclear magnetic resonance (NMR) clearly demonstrated that cholesterol markedly inhibits ion permeability induced by membrane-bound AmB. This could be accounted for by a membrane-thickening effect of cholesterol since AmB actions are known to be markedly affected by the thickness of membrane. Upon addition of AmB to an LUV suspension, the ion flux gradually increased with increasing molar ratios of cholesterol up to 20 mol%. These biphasic effects of cholesterol could be accounted for, at least in part, by the ordering effect of cholesterol.     

Long Open Amphotericin Channels Revealed in Cholesterol-Containing Phospholipid Membranes Are Blocked by Thiazole Derivative

The action of antifungal drug, amphotericin B (AmB), on solvent-containing planar lipid bilayers made of sterols (cholesterol, ergosterol) and synthetic C14–C18 tail phospholipids (PCs) or egg PC has been investigated in a voltage-clamp mode. Within the range of PCs tested, a similar increase was achieved in the lifetime of one-sided AmB channels in cholesterol- and ergosterol-containing membranes with the C16 tail PC, DPhPC at sterol/DPhPC molar ratio ≤1. The AmB channel lifetimes decreased only at sterol/DPhPC molar ratio >1 that occurred with sterol/PC molar ratio of target cell membranes at a pathological state. These data obtained on bilayer membranes two times thicker than one-sided AmB channel length are consistent with the accepted AmB pore-forming mechanism, which is associated with membrane thinning around AmB–sterol complex in the lipid rafts. Our results show that AmB can create cytotoxic (long open) channels in cholesterol membrane with C14–C16 tail PCs and nontoxic (short open) channels with C17–C18 tail PCs as the lifetime of one-sided AmB channel depends on ~2–5 Å difference in the thickness of sterol-containing C16 and C18 tail PC membranes. The reduction in toxic AmB channels efficacy can be required at the drug administration because C16 tails in native membrane PCs occur almost as often as C18 tails. The comparative analysis of AmB channel blocking by tetraethylammonium chloride, tetramethylammonium chloride and thiazole derivative of vitamin B₁, 3-decyloxycarbonylmethyl-4-methyl-5-(2-hydroxyethyl) thiazole chloride (DMHT), has proved that DMHT is a comparable substitute for both tetraalkylammonia that exhibits a much higher affinity.     

Cholesterol markedly reduces ion permeability induced by membrane-bound amphotericin B

It is widely accepted that amphotericin B (AmB) together with sterol makes a mixed molecular assemblage in phospholipid membrane. By adding AmB to lipids prior to preparation of large unilamellar vesicles (LUV), we directly measured the effect of cholesterol on assemblage formation by AmB without a step of drug's binding to phospholipid bilayers. Potassium ion flux assays based on 31P-nuclear magnetic resonance (NMR) clearly demonstrated that cholesterol markedly inhibits ion permeability induced by membrane-bound AmB. This could be accounted for by a membrane-thickening effect of cholesterol since AmB actions are known to be markedly affected by the thickness of membrane. Upon addition of AmB to an LUV suspension, the ion flux gradually increased with increasing molar ratios of cholesterol up to 20 mol%. These biphasic effects of cholesterol could be accounted for, at least in part, by the ordering effect of cholesterol.     

Interactions of amphotericin B derivatives with lipid membranes--a molecular dynamics study

Amphotericin B (AmB) is a well-known polyene macrolide antibiotic used to treat systemic fungal infections. AmB targets more efficiently fungal than animal membranes. However, there are only minor differences in the mode of action of AmB against both types of membranes, which is a source of AmB toxicity. In this work, we analyzed interactions of two low toxic derivatives of AmB (SAmE and PAmE), synthesized in our laboratory, with lipid membranes. Molecular dynamics simulations of the lipid bilayers containing ergosterol (fungal cells) or cholesterol (animal cells) and the studied antibiotic molecules were performed to compare the structural and dynamic properties of AmB derivatives and the parent drug inside the membrane. A number of differences was found for AmB and its derivatives' behavior in cholesterol- and ergosterol-containing membranes. We found that PAmE and SAmE can penetrate deeper into the hydrophobic region of the membrane compared to AmB. Modification of the amino and carboxyl group of AmB also resulted in the conformational transition within the antibiotic's polar head. Wobbling dynamics differentiation, depending on the sterol present, was discovered for the AmB derivatives. These differences may be interpreted as molecular factors responsible for the improved selectivity observed macroscopically for the studied AmB derivatives.     

Interactions of amphotericin B derivatives with lipid membranes—A molecular dynamics study

Amphotericin B (AmB) is a well-known polyene macrolide antibiotic used to treat systemic fungal infections. AmB targets more efficiently fungal than animal membranes. However, there are only minor differences in the mode of action of AmB against both types of membranes, which is a source of AmB toxicity. In this work, we analyzed interactions of two low toxic derivatives of AmB (SAmE and PAmE), synthesized in our laboratory, with lipid membranes. Molecular dynamics simulations of the lipid bilayers containing ergosterol (fungal cells) or cholesterol (animal cells) and the studied antibiotic molecules were performed to compare the structural and dynamic properties of AmB derivatives and the parent drug inside the membrane. A number of differences was found for AmB and its derivatives' behavior in cholesterol- and ergosterol-containing membranes. We found that PAmE and SAmE can penetrate deeper into the hydrophobic region of the membrane compared to AmB. Modification of the amino and carboxyl group of AmB also resulted in the conformational transition within the antibiotic's polar head. Wobbling dynamics differentiation, depending on the sterol present, was discovered for the AmB derivatives. These differences may be interpreted as molecular factors responsible for the improved selectivity observed macroscopically for the studied AmB derivatives.     

Changes of dipole potential of phospholipid membranes resulted from flavonoid adsorption

The effects of flavonoids, phloridzin, quercetin, myricetin and biochanin A on the dipole potential of planar lipid bilayers formed from dioleylphosphoethanolamine, dioleylphosphoserine, dioleoylphosphocholine, and diphytanoylphosphocholine are investigated. The characteristic parameters of the Langmuir adsorption isotherm, the maximum changes in the membrane dipole potential at an infinitely large concentration of flavonoid and its dissociation constant, which reflects the affinity of flavonoid to the membrane lipids, are determined. Modifying effects of chalcones, flavonols and isoflavones are compared. The influence of the surface charge of the lipid bilayer and the spontaneous curvature of the membrane-forming phospholipids on the adsorption of flavonoids on the model membranes is discussed.     

Mechanism of response of potential-sensitive dyes studied by time-resolved fluorescence

The mechanism of response of two potential-sensitive dyes, diOC₂(5) (3,3′-diethyloxadicarbocyanine iodide) and oxonol V (bis-[3-phenyl-5-oxoisoxazol-4-yl]pentamethine oxonol), were studied by using steady-state and time-resolved fluorescence techniques. The lipid concentration dependence of the Δψ (membrane potential)-induced change in total fluorescence intensity was quite different for these two dyes. Time-resolved fluorescence measurements showed that the fluorescence decay of these dyes in membranes could be resolved into at least three exponentials. Δψ-induced changes in the levels of these three populations were also measured under a variety of conditions. In the case of diOC₂(5) an inside negative Δψ increased the levels of the bound forms. This shows that diOC₂(5) responds to Δψ mainly by an “on-off” mechanism whereby Δψ perturbs the membrane-water partition coefficient of the dye. The Δψ-induced changes approached zero when the dye was totally membrane bound. In contrast, the Δψ-induced response of oxonol V increased with increased membrane binding. An inside negative Δψ decreased the level of the bound form with a longer lifetime. This shows that the mechanism of response of oxonol V is a Δψ-induced shift in the equilibrium between bound forms of the dye.     

Phloretin-Induced Reduction in Dipole Potential of Sterol-Containing Bilayers

The phloretin-induced reduction in the dipole potential of planar lipid bilayers containing cholesterol, ergosterol, stigmasterol, 7-dehydrocholesterol and 5α-androstan-3β-ol was investigated. It is shown that effects depend on the type and concentration of membrane sterol. It is supposed that the effectiveness of phloretin in reducing the dipole potential of the bilayers that contain cholesterol, ergosterol and 7-dehydrocholesterol correlates with the ordering and condensing effects. The role of the concentration-dependent ability of different sterols to promote lateral heterogeneity in membranes is also discussed.     

Thermodynamic equilibria of cholesterol-detergent-water.

Cholesterol monomer is incorporated into alkyl sulfate micelles with a unitary free energy of -10.3 kcal/mol. This experimental free energy is in good agreement with that predicted by our previous determination of the hydrophobicity of the sterol suggesting that the partitioning is primarily hydrophobic with little or no contribution to the free energy from head group interactions in this system. The intrinsic hydrophobicity of cholesterol is shown to be insufficient for effective partitioning of the sterol between micelles (or bilayers) and its own self-associated form. This finding strongly supports a model of phospholipid-cholesterol interaction involving significant free energy contributions from head group effects such as alterations in hydrogen bonds or hydration. Since these head group contributions are not observed in the cholesterol-alkyl sulfate system, one concludes that there is a high degree of specificity of interaction between the sterol OH and polar moieties of other amphiphilic molecules.     

Influence of anions and cations on the dipole potential of phosphatidylcholine vesicles: a basis for the Hofmeister effect

Anions and cations have long been recognized to be capable of modifying the functioning of various membrane-related physiological processes. Here, a fluorescent ratio method using the styrylpyridinium dyes, RH421 and di-8-ANEPPS, was applied to determine the effect of a range of anions and cations on the intramembrane dipole potential of dimyristoylphosphatidylcholine vesicles. It was found that certain anions cause a decrease in the dipole potential. This could be explained by binding within the membrane, in support of a hypothesis originally put forward by A. L. Hodgkin and P. Horowicz [1960, J. Physiol. (Lond.) 153:404-412.] The effectiveness of the anions in reducing the dipole potential was found to be ClO4- > SCN- > I- > NO3- > Br- > Cl- > F- > SO42-. This order could be modeled by a partitioning of ions between the membrane and the aqueous phase, which is controlled predominantly by the Gibbs free energy of hydration. Cations were also found to be capable of reducing the dipole potential, although much less efficiently than can anions. The effects of the cations was found to be trivalent > divalent > monovalent. The cation effects were attributed to binding to a specific polar site on the surface of the membrane. The results presented provide a molecular basis for the interpretation of the Hofmeister effect of lyotropic anions on ion transport proteins.     

Influence of vitamin C on alcohol binding to phospholipid monolayers

The simple model of the biological membrane is provided by well-controlled lipid monolayers at the air-water interface. The Maxwell displacement current technique (MDC) provides novel approach to conformation study of the membrane models. The effect of alcohols is interaction with membrane molecules, mainly with the lipid head group and consequent changes in physical-chemical properties of the membrane. The aim of study is to detect changes in structural, electrical and mechanical properties of dipalmitoyl-phosphatidylcholine (DPPC) monolayer on the subphase of methanol-water and ethanol-water mixtures before and after addition of antioxidant agent, vitamin C. Monolayers properties are investigated by a surface pressure analysis (including mechanical properties evaluation) and the Maxwell displacement current measurement, the dipole moment projection calculation. Surface pressure-area isotherms show similar behaviour of the DPPC monolayer on alcohol-water mixtures independently on presence of vitamin C. Binding/adsorption process induces change of electron density distribution across monolayer and thus the molecular dipole moment. We observe small or negligible binding of methanol molecules on oxygen bonds of DPPC. Thus the antioxidant, vitamin C, has no significant effect. For ethanol-water mixtures is observed recovery of electrical properties in presence of antioxidant agent. We suppose that vitamin C regulates DPPC-ethanol molecules interaction.     

Two-step impact of Amphotericin B (AmB) on lipid membranes: ESR experiment and computer simulations

Abstract

In this study, the electron spin resonance (ESR) method was used to examine the effect of Amphotericin B (AmB) molecules on the fluidity of model membranes made of dipalmitoylphosphatidylcholine (DPPC). The changes occurring under increased AmB concentrations in the spectroscopic parameters of spin probes placed in liposomes were determined. Three probes were used, penetrating the membrane at different depths which allowed the changes in its fluidity to be found in the transverse section. A computer model of the surface layer of membrane, with AmB admixture, was developed and subjected to computer simulation. The effect of changing concentration of the admixture on the binding energy in the system of dipoles representing the surface of the membrane was examined. The ESR studies showed that the process of accumulation of AmB molecules in the membrane has two stages, marked by local maxima in the ESR spectra. The first appears for concentrations of ca. 0.25–0.5% and the second appears for ca. 2.5–3% AmB of its molar ratio to DPPC. The computer simulations permitted reconstructing the two-stage mechanism of interaction between the molecules and the membrane. They demonstrated that, at low concentrations, the AmB molecules position themselves flat on the membrane surface. After the threshold concentration is exceeded, they re-orientate to a vertical position. This process leads to the perforation of the membrane.     

Interaction of phloretin with membranes: on the mode of action of phloretin at the water-lipid interface

 The interaction of phloretin with single lipid bilayers on a spherical support and with multilamellar vesicles was studied by differential scanning calorimetry (DSC) and nuclear magnetic resonance (NMR). The results indicated that phloretin interacts with the lipid layer and changes its structural parameters. In DSC experiments, phloretin in its neutral form strongly decreased the lipid phase transition temperature and slightly reduced the cooperativity of the phase transition within the lipid layer. In NMR measurements, phloretin led to an increase of the transverse relaxation time constant but had no effect on the spin-lattice relaxation time constant. The overall dipole moment of phloretin was experimentally determined and was found to be roughly 40% lower than has been published previously. This result suggested that the size of the dipole moment of phloretin does not provide such a high contribution to the effect of phloretin on the dipole potential of monolayers and bilayers as has been published previously. To understand the discrepancy between phloretin adsorption and dipole potential change, we performed computational conformational analysis of phloretin in the gas phase. The results showed that a wide distribution of the dipole moments of phloretin conformers exists, which mainly depends on the orientation of the OH moieties. The adsorption of phloretin as determined from its binding to solid supported bilayers differed from the one determined from dipole potential measurements on black lipid membranes. The difference between the phloretin dissociation constants of both types of experiments suggested a change of its dipole moment normal to the membrane surface in a concentration-dependent manner, which was in agreement with the results of the computational conformational analysis. Received: 21 June 1999 / Revised version: 7 January 2000 / Accepted: 31 March 2000     

Molecular dynamics simulation of dipalmitoylphosphatidylcholine membrane with cholesterol sulfate

Using the molecular dynamics simulation technique, we studied the changes occurring in a dipalmitoylphosphatidylcholine (DPPC):cholesterol (CH) membrane at 50 mol% sterol when cholesterol is replaced with cholesterol sulfate (CS). Our simulations were performed at constant pressure and temperature on a nanosecond time scale. We found that 1) the area per DPPC:CS heterodimer is greater than the area of the DPPC:CH heterodimer; 2) CS increases ordering of DPPC acyl chains, but to a lesser extent than CH; 3) the number of hydrogen bonds between DPPC and water is decreased in a CS-containing membrane, but CS forms more water hydrogen bonds than CH; and 4) the membrane dipole potential reverses its sign for a DPPC-CS membrane compared to a DPPC-CH bilayer. We also studied the changes occurring in lipid headgroup conformations and determined the location of CS molecules in the membrane. Our results are in good agreement with the data available from experiments.