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Cooperative Partition Model of Nystatin Interaction with Phospholipid Vesicles

Ana Coutinho ^*  and Manuel Prieto ^*

^* Centro de Química-Física Molecular, Instituto Superior Técnico, P-1049-001 Lisbon, Portugal; and Departamento de Química e Bioquímica, F.C.U.L., P-1749-016 Lisbon, Portugal

Correspondence: Address reprint requests to Dr. Manuel Prieto, Centro de Química-Física Molecular, Instituto Superior Técnico, Av. Rovisco Pais, P-1049-001 Lisbon, Portugal. Tel.: 3-51-21-841-9219; Fax: 3-51-21-846-4455; E-mail: prieto{at}alfa.ist.utl.pt.

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS ACKNOWLEDGEMENTS REFERENCES

 
Nystatin is a membrane-active polyene antibiotic that is thought to kill fungal cells by forming ion-permeable channels. In this report we have investigated nystatin interaction with phosphatidylcholine liposomes of different sizes (large and small unilamellar vesicles) by time-resolved fluorescence measurements. Our data show that the fluorescence emission decay kinetics of the antibiotic interacting with gel-phase 1,2-dipalmitoyl-sn-glycero-3-phosphocholine vesicles is controlled by the mean number of membrane-bound antibiotic molecules per liposome, A. The transition from a monomeric to an oligomeric state of the antibiotic, which is associated with a sharp increase in nystatin mean fluorescence lifetime from 7–10 to 35 ns, begins to occur at a critical concentration of 10 nystatin molecules per lipid vesicle. To gain further information about the transverse location (degree of penetration) of the membrane-bound antibiotic molecules, the spin-labeled fatty acids (5- and 16-doxyl stearic acids) were used in depth-dependent fluorescence quenching experiments. The results obtained show that monomeric nystatin is anchored at the phospholipid/water interface and suggest that nystatin oligomerization is accompanied by its insertion into the membrane. Globally, the experimental data was quantitatively described by a cooperative partition model which assumes that monomeric nystatin molecules partition into the lipid bilayer surface and reversibly assemble into aggregates of 6 ± 2 antibiotic molecules.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS ACKNOWLEDGEMENTS REFERENCES

 
Amphotericin B (AmB) and nystatin are two structurally similar polyene macrolide antibiotics characterized by a very low antibacterial activity and a potent broad-spectrum antifungal action (Bolard, 1986). After more than 40 years after its discovery, AmB still is the most common antifungal agent used to treat systemic fungal infections (Hartsel and Bolard, 1996). However, several side effects, especially nephrotoxicity, have restricted its use and promoted the development of various liposomal formulations to minimize these problems (Schaffner, 1984). Nystatin, on the other hand, is only used topically, as it is ineffective orally and severely toxic when administered intravenously (Schaffner, 1984). To be able to develop rationale strategies to circumvent the severe secondary effects caused by these antibiotics, it is essential to obtain a detailed picture of their mode of action at the molecular level.

The most widely accepted model for the mechanism of action of these antibiotic molecules considers that their cellular target is the plasma membrane of the antibiotic-sensitive organisms where they act by forming aqueous pores (Bolard, 1986; Hartsel et al., 1993). Several electrophysiological studies have shown that bilayer-spanning potassium-selective channels are formed upon one-sided addition of nystatin or AmB to different lipid membranes (Akaike and Harata, 1994). These pores have size-discriminating properties, being permeable only to solutes not larger than glucose or sucrose for nystatin and AmB, respectively (Andreoli et al., 1969; Holz and Finkelstein, 1970). The disturbance of the cellular electrochemical gradients caused by the increase of cell permeability to ions and small molecules ultimately leads to cell lysis and death (Bolard, 1986). Despite the general consensus about the antibiotic mode of action, there is still some controversy regarding the molecular architecture of the ion-permeable channels formed by these membrane-active compounds. In particular, the role and even the indispensability of sterols in the antibiotic self-assembly process that occurs within the lipid bilayers are still matters of debate (Hartsel et al., 1993). Some authors explain the sterol requirement frequently found in nystatin and AmB activity measurements by invoking the formation of transmembrane pores constituted by antibiotic-sterol complexes composed of alternated antibiotic and sterol molecules (Andreoli, 1974; de Kruijff and Demel, 1974; van Hoogevest and de Kruijff, 1978). The distinct antibiotic sensitivities presented by cholesterol-containing mammalian cells relative to ergosterol-rich fungal cells are therefore justified by the different affinities of the polyene antibiotics toward the sterol present in the plasma membranes of the antibiotic-sensitive organism (Bolard, 1986). On the other hand, other studies suggested that the key factor controlling the ability of large polyene antibiotic molecules to pack together is the overall membrane organization. In this way, the formation of active antibiotic species may be facilitated by the presence of an ordered state in the lipid bilayer. This can be achieved either by the progressive incorporation of a sterol in the membrane (Marty and Finkelstein, 1975) or by keeping the lipid bilayers in a gel phase (Hsu-Chen and Feingold, 1973).

The presence of a conjugated double-bond system in the chemical structure of the polyene antibiotics has enabled the application of several optical spectroscopic techniques to the study of the molecular structure of the channels formed by these molecules in the lipid bilayers. The main spectroscopies applied so far to AmB (with a heptanes group) were ultraviolet-visible absorption and circular dichroism (CD) (Bolard, 1986; Hartsel et al., 1993). The great potentialities of these techniques derive from their ability to detect the formation of several different antibiotic species in the membranes, which are identified by a characteristic signature spectrum. In addition, it is possible to evaluate the influence that several parameters have on their occurrence, e.g., the membrane-lipid composition (type of sterol and mole fraction) and antibiotic-to-lipid ratios used (Bolard et al., 1980; Vertut-Croquin et al., 1983). However, until recently a quantitative analysis of the data obtained in most of these studies was impaired by the complex equilibria present in the samples that involved antibiotic aggregation in the aqueous solution (Mazerski et al., 1982, 1990), partition into the lipid bilayers (Szponarski et al., 1988) and self-association in the lipid environment (Balakrishnan and Easwaran, 1993). Fujii et al. (1997) were the first to overcome this problem by guaranteeing a complete association of AmB with the liposomes used in all experimental conditions tested. From a combination of functional assays with spectroscopic measurements, these authors were able to show unequivocally that a transition from the ion-impermeable to the ion-permeable state occurred concomitantly with significant spectroscopic changes, indicating that two distinct forms of AmB were present in the membranes, namely a monomeric and an aggregated form (Fujii et al., 1997).

Regarding the application of optical techniques to the study of polyene antibiotics mode of action, much less attention has been paid to fluorescence so far. However, from the anticipated sensitivity of several fluorescence parameters to the properties of the fluorophore microenvironment, this technique is also expected to be able to report changes of antibiotic location/aggregation state in the lipid bilayer that are associated with the formation of active species (Strom et al., 1976; Castanho and Prieto, 1992, Coutinho and Prieto, 1995). In a previous work, we began to exploit the intrinsic fluorescence properties of the tetrane-containing antibiotic nystatin (Coutinho and Prieto, 1995). We carried out a general characterization of the photophysical behavior of nystatin both in homogeneous media and in interaction with phospholipid vesicles and established a comparison with the photophysical properties of the well-studied tetrane fluorescent fatty-acid trans-parinaric acid. Before addressing more complex, and yet more biologically relevant lipid mixtures—namely ergosterol- and cholesterol-containing lipid bilayers—we have decided to extend the previous investigation of nystatin interaction with single component liposomes to studies with small unilamellar vesicle (SUV) and large unilamellar vesicle (LUV) prepared with DPPC and 1-palmitoyl-2-oleyl-sn-glycero-3-phosphocholine (POPC). To evaluate the influence exerted by the lateral packing of phospholipids on nystatin interaction with the lipid vesicles, several experiments were carried out with the lipid vesicles kept in a gel phase. The creation of a lipid-ordered state by adding sterol to a phospholipid at temperatures above the phase transition would be a better in vitro model of a biomembrane in a liquid-ordered phase. However, we envisaged that the use of a gel phase would eventually allow us to distinguish a general influence (the presence of lipid ordered phase-gel phase, in this case) from a possible specific effect (formation of specific antibiotic-cholesterol complexes) on nystatin interaction with the lipid vesicles.

By measuring the fluorescence decay curves of the lipid-bound antibiotic molecules, nystatin was shown to form strongly fluorescent antibiotic aggregates in gel-phase membranes that were dependent upon the antibiotic and lipid concentrations used. These results were ascribed to a self-association process undergone by the monomeric antibiotic molecules within the lipid bilayer. Since it is believed that the assembly of the large polyene antibiotics into conducting pores plays a key role in their biological activity (Bolard, 1986), we decided to further characterize the factors controlling nystatin oligomerization in the lipid vesicles. By carrying out experiments with DPPC liposomes with different outer diameters (SUV and LUV), we were able to show that the emission decay kinetics of the antibiotic was governed by the mean number of membrane-bound nystatin molecules per lipid vesicle and not strictly by its surface density.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS ACKNOWLEDGEMENTS REFERENCES

 
Reagents
Nystatin (pharmaceutical grade) was a gift from Squibb Farmacêutica Portuguesa and was used without further purification. DPPC and POPC were purchased from Avanti Polar Lipids (Alabaster, AL). The spin labels 5- and 16-doxyl-stearic acids (5-DS and 16-DS, respectively) were obtained from Molecular Probes (Eugene, OR). All other chemicals were of analytical or spectroscopic reagent grade.

The antibiotic was stored in the dark at -20°C. A stock solution of nystatin in methanol (spectroscopic grade) (1 mM) was also stored at -20°C in the dark before being used. Its concentration was determined by UV spectroscopy using an absorption coefficient of 7.4 x 10⁴ M^-1 cm^-1 at 304 nm (Coutinho and Prieto, 1995). The stock solutions of n-DS were also prepared in methanol (8 and 6 mM for 5-DS and 16-DS, respectively) and kept at -20°C.

Vesicle preparation
SUV were prepared by ultrasonic irradiation using a Branson 250 sonicator with a standard flat tip as described elsewhere (Coutinho and Prieto, 1995). The standard buffer used was HEPES buffer (20 mM HEPES-NaOH (pH 7.4), 150 mM NaCl, 1 mM EDTA) but some lipid suspensions were also prepared using a Tris buffer (50 mM Tris-HCl (pH 7.4), 10 mM NaCl, 0.2 mM EDTA). By means of the extrusion technique (Mayer et al., 1986) we prepared LUV with a mean diameter of 100 nm. Briefly, the lipid was dissolved in chloroform in a round-bottom flask and the solvent was first dried under a stream of N₂ and then further evaporated overnight under an oil pump vacuum. The dried lipid was dispersed to the desired concentration by adding the appropriate volume of the standard buffer and by repeated vortexing at 50°C, well above the gel-to-liquid crystalline phase transition temperature (T_m) of the lipids used, until all lipid was removed from the flask wall. Then a freeze-thaw cycle was repeated eight times. Subsequently, the lipid suspension was extruded four and 10 times through polycarbonate membranes of 400- and 100-nm pore size (Nucleopore, Pleasanton, CA), respectively. The resulting stock solution was stored at 4°C. The final lipid concentration was determined by phosphate analysis (McClare, 1971).

Nystatin partitioning experiments
The partitioning of nystatin into the lipid bilayer was determined through the fluorescence intensity increase of the antibiotic's tetrane group with the lipid concentration measured in 0.5-cm cuvettes at 21 or 45°C. Due to the high susceptibility of nystatin to photochemical degradation, several dilutions of a stock solution of SUV or LUV (5 mM) were prepared with buffer. Then, a constant volume from nystatin stock solution was injected to each of these samples. The final volume of methanol in solution never exceeded 1.5% of the total volume of each sample. After an incubation time of 1 h in the dark and at room temperature, the fluorescence signal of each sample was monitored as a function of the lipid concentration used. The contribution of the liposomes alone was subtracted from this intensity.

The partitioning experiments were analyzed according to Eq. 1 (White et al., 1998):

(1)

In this equation, stands for the difference between the steady-state fluorescence intensity of the antibiotic measured in the presence (I) and in the absence of phospholipid vesicles (I₀); is the maximum value of this difference, since I is the limiting value of I measured upon increasing the lipid concentration, [L], of the solution; K_p is the mole-fraction partition coefficient of the antibiotic between the aqueous and lipid phases and [W] is the molar concentration of water. It was assumed that only 60% and 50% of the overall lipid used was available, [L]_av, for the initial partition of the antibiotic in the experiments carried out with SUV and LUV, respectively.

Quenching studies
The experiments were carried out with 3 mM DPPC SUV incubated with either 3.0 or 12.5 µM nystatin for 1 h at room temperature. The antibiotic-labeled lipid suspensions were divided into several samples and variable aliquots from a methanolic stock solution of either spin probe (5- or 16-DS, respectively) were then added to obtain different final quencher concentrations for each sample. After another incubation time of 1 h at room temperature, the steady-state fluorescence intensity of nystatin in each sample was measured at 21°C. The volume of organic solvent did not surpass 3.0% of each sample total volume. On the other hand, the highest mole fraction of spin-labeled fatty acids used never exceeded 4–6% of the phospholipid present in the outer monolayer of the liposomes.

Quenching data were analyzed by the Stern-Volmer plot of I₀/I versus [Q]_l, where I₀ and I stand for the fluorescence intensities in the absence and in the presence of the quencher, respectively, and [Q]_l is the quencher (spin label) concentration in the phospholipid phase,

(2)

where is the Nernst partition coefficient of the quencher between the phospholipid phase and the aqueous phase, [Q] is the bulk molar concentration of the quencher (relative to the total sample volume, V_t (V_t = V_l + V_w)) and V_l and V_w are the volumes of the lipid and aqueous phases, respectively. For 5-DS and 16-DS, is 12,570 and 3340, respectively, for the lipid vesicles in the gel phase (Wardlaw et al., 1987) and a phospholipid molar volume, , of 0.688 dm³ mol^-1 was used for DPPC (Marsh, 1990).

Absorption and steady-state fluorescence measurements
Absorption spectra were measured at room temperature using a Jasco V-560 spectrophotometer. Fluorescence measurements were made on a Spex F112A Fluorolog photon-counting instrument (Edison, NJ) under the control of a IBM PC equipped with the software DM3000, using a 150-W Xenon light source, as previously described (Coutinho and Prieto, 1995). The spectrofluorometer was equipped with a thermostated cuvette holder (±1°C) and 0.5 cm pathlength quartz cuvettes were used. The conditions used in most measurements were _exc = 315 nm (bandwidth 0.9 nm) and _em = 415 nm (bandwidth 9 nm). Stray light was reduced using an ultraviolet band-pass filter SB-300 (Corion) in the exciting beam and a WG-360 (Corion) cutoff filter in the emission beam. Moreover, background intensities in nystatin-free samples due to the lipid vesicles were subtracted from each recording of fluorescence intensity. All the fluorescence measurements were carried out with a right-angle geometry, and the geometry effect was taken into account when necessary (Coutinho and Prieto, 1995).

Nystatin aggregation in Tris and HEPES buffers and the detection of vesicle aggregation or fusion induced by the antibiotic were studied by measuring the light-scattered intensity by the antibiotic solutions or vesicle suspensions, respectively, at _exc = _em = 450 nm (detected at 90°).

Time-resolved fluorescence measurements
Fluorescence lifetimes were determined by the single-photon timing technique using a nitrogen-filled flashlamp (Edinburgh Instruments, 119F) as described previously (Coutinho and Prieto, 1995). The measurements were done using _exc = 316 nm and _em = 415 nm with bandwidths of 4 and 8 nm, respectively. Fluorescence intensity decay curves were analyzed by nonlinear least-squares regression, fitting to the data a sum of exponentials,

(3)

where _i and _i are the normalized amplitude () and lifetime of the ith decay component, respectively. The reduced chi-squared value (²) and weighted residuals with their autocorrelation were used as best fit criteria. The range of chi-squared values obtained was 1.0–1.3.

The intensity-weighted mean fluorescence lifetime, , is given by Eq. 4:

(4)

where f_i, the fractional intensity of the ith decay component, is:

(5)

On the other hand, is the amplitude-weighted mean fluorescence lifetime,

(6)

or the lifetime-weighted quantum yield, since it is directly proportional to the area under the decay curve (Lakowicz, 1999).

Parameters that describe the occupation of lipid vesicles with nystatin
To identify the controlling parameter of nystatin self-association in the lipid vesicles, two different quantities were calculated for each sample studied. The first one was the phospholipid-to-antibiotic surface molar ratio, R_S,

(7)

where , the concentration of monomeric membrane-bound nystatin, is given by

(8)

[N] is the bulk molar concentration of antibiotic and x_l is the membrane-bound mole fraction of monomeric antibiotic molecules:

(9)

It should be noted that in these calculations it is implicitly assumed that 1), only monomeric antibiotic molecules partition between the aqueous phase and the external lipid monolayer of the lipid vesicles; and 2), the mole fraction of antibiotic molecules involved in oligomer formation is so small that it can be ignored.

When liposomes with variable diameters are used, it is also useful to compute A, the mean number of antibiotic molecules associated with a lipid vesicle. A is readily derived from R_S and µ, the average number of lipid molecules per vesicle:

(10)

x_av is the fraction of lipid molecules in the outer half of a lipid vesicle. For SUV and LUV we estimated µ = 6 018 and µ = 82 045, respectively (Table 1).

(11)

where K_p is the mole-fraction partition coefficient of the antibiotic, and are the bulk molar concentrations of monomeric antibiotic in the lipid (i = l) and aqueous (i = w) phases, respectively, and [L] and [W] are the molar concentrations of lipid and water, respectively (White et al., 1998).

After partitioning into the lipid vesicles, the membrane-bound antibiotic molecules may reversibly assemble into aggregates. The association constant for the conversion of monomers into an aggregated form, a z-mer, is given by

(12)

where and represent the two different kinds of fluorescent antibiotic species that may be present in the liposomes, namely monomeric and oligomeric nystatin. Each aggregate is formed by z antibiotic molecules. The concentration unit chosen to describe this equilibrium was the mean number of membrane bound antibiotic molecules per liposome.

The mass conservation law for the antibiotic is

(13)

where represents the total amount (i.e., number of moles) of antibiotic, are the amount of monomeric nystatin molecules present in each phase (i = w, aqueous phase; i = l, lipid phase, respectively), and is the amount of aggregates formed by nystatin molecules in the lipid vesicles.

For any lipid or antibiotic concentration used, both the partition (Eq. 11) and nystatin association equilibria (Eq. 12) must be simultaneously obeyed. Combination of Eqs. 11 and 12 with the mass balance equation (Eq. 13) results in:

(14)

where

(15)

with N_A, [L]_av, n_l, and µ being the Avogadro's number, the lipid concentration available to the antibiotic binding, the amount of lipid molecules in a sample and the number of lipids forming a single liposome, respectively. Generally, this polynomial of zth-order (Eq. 14) has no analytical resolution and therefore the simulation of nystatin binding to the lipid vesicles had to be performed by an iterative numerical technique. For the initial simulations, the antibiotic was assumed to undergo a cooperative aggregation to an hexamer (z = 6) and the partition coefficient of nystatin was set equal to its experimental value. After assigning a numerical value to K_ag, the mass balance equation was solved using the routine Solve for from Quattro Pro Version 5.0 to calculate the mole fractions of each antibiotic population present in the system

(16)

(17)

and

(18)

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS ACKNOWLEDGEMENTS REFERENCES

 
Nystatin interaction with DPPC and POPC LUV
In a previous study of nystatin interaction with gel phase DPPC SUV anomalous binding curves were obtained for this antibiotic when high antibiotic concentrations (6.5, 7.8, and 13.5 µM) were used in some experiments (Coutinho and Prieto, 1995). It was then shown that the steady-state fluorescence intensity of the antibiotic leveled off toward a plateau, or even decreased sharply upon increasing the lipid concentration, while nystatin overall concentration was kept constant. The deviations presented by these experimental binding curves from the expected hyperbolic behavior (Eq. 1) were then tentatively ascribed to the fusion/aggregation of these lipid vesicles induced by the antibiotic molecules (Coutinho and Prieto, 1995). Therefore, in this work DPPC and POPC LUV were used in nystatin binding studies to avoid these problems. In fact, it is well known that an important characteristic of the model membrane system used is its diameter since the curvature radius of the lipid vesicles modulates its phospholipid packing, thereby conditioning its interfacial properties and stability (Chrzeszczyck et al., 1977; Brouillette et al., 1982). Considering that LUV prepared by the extrusion procedure through filters with pores of 100 nm have an outer diameter that is almost 3–4 times larger than SUV prepared by sonication, we expected these vesicles to be more stable and not so prone to undergo morphological changes.

The relative increase in the steady-state fluorescence intensity of nystatin in the presence of DPPC LUV was used to quantify its phospholipid/water partition coefficient (Fig. 1). It was considered that only the external monolayer of the lipid vesicles was accessible to the antibiotic incorporation because Finkelstein and co-workers (Marty and Finkelstein, 1975; Kleinberg and Finkelstein, 1984) have shown that the pores formed from one-sided and two-sided addition of nystatin to black lipid membranes had different properties. If an equilibrium distribution of antibiotic molecules among the two halves of the lipid bilayer was rapidly reached due to a fast flip-flop rate, the method used in antibiotic delivery should not influence the final results, contrary to what was observed experimentally. From a two-parameter fitting procedure (I_max and K_p, Eq. 1), a K_p = (1.1 ± 0.3) x 10⁴ was obtained for nystatin interacting with these lipid vesicles in the gel phase (Table 2). This partition coefficient was independent of the antibiotic concentration used (Fig. 1) at variance with what was previously reported for the experiments carried out with DPPC SUV (Coutinho and Prieto, 1995). In addition, light-scattering measurements provided no evidence for vesicle fusion/aggregation induced by the antibiotic binding (results not shown). Similar partition coefficients for fluid lipid vesicles, either DPPC LUV at 45°C (K_p = (0.9 ± 0.1) x 10⁴) or POPC LUV at 21°C (K_p = (1.4 ± 0.2) x 10⁴, were also determined for nystatin (Table 2).

View larger version (13K): [in this window] [in a new window]   FIGURE 1  Determination of the partition coefficient of nystatin from its fluorescence intensity increase upon incorporation into LUV of DPPC at 21°C. The nystatin concentrations used were () 3.2 and (•) 7.9 µM. The solid line is the best fit of Eq. 1 to the experimental data with Kp = (1.1 ± 0.3) x 104.

View larger version (17K): [in this window] [in a new window]   FIGURE 2  Variation of (A) the steady-state fluorescence intensity, If (exc = 304 nm; em = 410 nm) and (B) light scattering intensity, Id (exc = em = 450 nm), with nystatin concentration in (•) Tris and () HEPES buffers.

View larger version (18K): [in this window] [in a new window]   FIGURE 3  Relationship between the mean fluorescence lifetime of nystatin, , and the phospholipid-to-antibiotic surface molar ratio, RS, obtained with SUV of DPPC at 21°C. (A) The phospholipid concentration was kept constant () 1.1 mM, (•) 1.6 mM, () 2.3 mM, () 2.4 mM, and () 3.5 mM DPPC) while the antibiotic concentration was varied. (B) The nystatin concentration was kept constant () 7.9 µM, () 9.4 µM, and () 11.0 µM antibiotic) while the phospholipid concentration was varied in each experiment. The dashed vertical lines define the range of RS values (150 < RS < 280) correspondent to the transition region between a long and short mean fluorescent lifetimes of nystatin.

View larger version (22K): [in this window] [in a new window]   FIGURE 4  Mean fluorescence lifetime of nystatin, , at different (A) surface molar ratios of phospholipid-to-antibiotic, RS, and (B) mean number of membrane bound antibiotic molecules per liposome, A. The model membrane systems used were DPPC SUV () or LUV (•) at 21°C. In some experiments the phospholipid concentration was kept constant and the antibiotic concentration was varied and vice versa (see Fig. 3, legend). The solid line is the best fit of the cooperative partition model of the antibiotic to the experimental data (see the text and Fig. 8, legend, for details). (C, inset) Plot showing the relationship between the lowest value of the root-mean-square deviations (RMSD), and the aggregation number of nystatin, z. K'ag was allowed to vary in each fitting while z was kept constant at different integer numbers (see Table 5).

View larger version (15K): [in this window] [in a new window]   FIGURE 8  Simulation of the effect of nystatin self-association upon the antibiotic binding to the lipid vesicles and its fluorescence emission decay kinetics. (A) Antibiotic mole fractions as a function of the bulk molar nystatin concentration added to the SUV suspension: () , (•) , and () (calculated according to Eqs. 16–18). and are coincident. (B) Relationship between the partition coefficient of the antibiotic and its total concentration in solution. The dashed line depicts the value used for nystatin partition coefficient in this simulation ( = 9.2 x 104), whereas (•) represent (calculated according to Eq. 20). (C) Mean fluorescence lifetime computed for nystatin, calc, at different mean number of membrane bound antibiotic molecules per liposome, A. This last parameter was calculated according to Eq. 10 using either () or (•) in Eq. 9. The simulation of the cooperative partition model of nystatin was done considering that i), only monomeric antibiotic molecules partition into the liposomes ([L]t = 1 mM; µ = 6,018; T = 21°C); and that ii), nystatin self-associates into hexamers (z = 6) with an association constant Kag = 3.7 x 10111. calc was computed according to Eq. 27 considering for monomeric nystatin M1 = 0.63; M2 = 0.36; M3 = 0.01; M1 = 2.6 ns; M2 = 8.1 ns e M3 = 28 ns, and for the antibiotic molecules involved in aggregate formation Ag1 = 0.40; Ag2 = 0.10; Ag3 = 0.50; Ag1 = 2.4 ns; Ag2 = 14.0 ns e Ag3 = 42 ns.

Fluorescence quenching studies of nystatin by 5- and 16-DS
To estimate the antibiotic location in the lipid vesicles, a fluorescence quenching study of nystatin by two lipophilic probes, 5- and 16-DS, was carried out. These two spin-labeled fatty acids are known to insert predominantly vertical to the bilayer surface of the lipid vesicles (Ellena et al., 1988). Therefore their doxyl groups are located at different depths in the lipid bilayer (Fig. 5; see also Ellena et al., 1988; Feix et al., 1984), allowing information about the transversal position of the antibiotic fluorophore in the lipid vesicles to be obtained. The fluorescence quenching study of nystatin was carried out with DPPC SUV at 21°C using two different antibiotic concentrations, 3.0 and 12.5 µM. As these antibiotic samples have very different mean fluorescence lifetimes (10 and 28 ns, respectively), it was anticipated that they might provide information regarding the influence that the antibiotic aggregation state—monomer or oligomer—had on its transversal position in the lipid bilayer.

View larger version (17K): [in this window] [in a new window]   FIGURE 5  Schematic representation of the expected transversal positions for the lipophilic probes 5- and 16-DS in a lipidic membrane. The dashed line represents the boundary between the polar and apolar regions of the membrane. Nystatin is represented perpendicular to the membrane surface just to illustrate that, upon internalization, its fluorophore group should get closer to both spin probes.

View larger version (18K): [in this window] [in a new window]   FIGURE 6  Stern-Volmer plots for the steady-state fluorescence quenching study of nystatin by 5- and 16-DS in 3 mM SUV of DPPC at 21°C. The nystatin concentrations used were (A) 3.0 and (B) 12.5 µM. Liposomes were prepared in Tris buffer. Lines are drawn just to guide the eye.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION CONCLUSIONS ACKNOWLEDGEMENTS REFERENCES

In the first part of this work, the intrinsic fluorescence emission properties of the polyene antibiotic nystatin were explored to characterize its binding to DPPC and POPC vesicles. Two main differences were found between nystatin interaction with DPPC SUV and LUV in the gel phase: 1), nystatin was only able to induce the fusion/aggregation of the smaller lipid vesicles (Coutinho and Prieto, 1995); and 2), the partition coefficient of this antibiotic was 5–7 times larger for SUV than for LUV in the gel phase (Table 2). The most probable explanation for these results lies in the nonequilibrium structure of SUV due to its small curvature radius. In fact, it is well known that the size of a liposome has a lower limit below which the curvature radius of its internal monolayer is so small that packing constraints between the phospholipid headgroups arise, preventing the formation of smaller lipid vesicles and making the outer monolayer of a SUV more expanded than the one obtained with a planar lipid bilayer (Chrzeszczyck et al., 1977; Brouillette et al., 1982). These structural characteristics of the SUV make them thermodynamically unstable (Suurkuusk et al., 1976) and more prone to undergo fusion/aggregation induced by an active molecule (van Dijck et al., 1978). The interfacial packing defects, which are more important in gel phase SUV, also justify the larger partition coefficient found for nystatin toward DPPC SUV compared to DPPC LUV (Table 2) because they are expected to be preferential partitioning sites for the antibiotic. In contrast, when the lipid vesicles were in a fluid phase an antibiotic partition coefficient K_p (1.3 ± 0.3) x 10⁴ was always obtained (Table 2), which was essentially independent of the type of phospholipid (DPPC or POPC) or liposome (SUV or LUV) employed.

Bolard and co-workers had previously obtained similar results with vacidin A (Bolard et al., 1984), an aromatic polyene antibiotic, and with AmB (Milhaud et al., 1989). These authors found that these polyene antibiotics had a higher affinity for gel phase relative to fluid phase lipid membranes only when the model lipid bilayer system used were SUV. Furthermore, Bolard and Cheron (1982) showed by gel filtration and ultracentrifugation techniques that AmB was only able to induce the fusion or aggregation of small vesicles in the gel phase. When the lipid vesicles were in the liquid-crystalline phase or when larger lipid vesicles were used (although in the gel state), these processes did not occur.

Fluorescence decay kinetics reports on nystatin self-association in gel-phase lipid vesicles
Considering that the main factor governing nystatin photophysics is the aggregation state of the antibiotic in the lipid vesicles (Coutinho and Prieto, 1995), one would expect its mean fluorescence lifetime to be controlled by the surface density of membrane-bound antibiotic molecules in the phospholipid vesicles. Although the first experiments performed to test this hypothesis seemed to confirm this prediction (Fig. 3), they were unable to explain why the mean fluorescence lifetime of the antibiotic interacting with DPPC LUV was essentially independent of the phospholipid-to-antibiotic surface molar ratio used, always presenting a large value characteristic of the long-lived/aggregated antibiotic species, even when very diluted samples were prepared (Fig. 4 A). Further analysis of these results (Fig. 4 B) gave support to a different hypothesis, namely that the formation of highly fluorescent oligomers by nystatin was controlled by the mean occupation number of a lipid vesicle, A, and not strictly by its phospholipid-to-antibiotic surface molar ratio. For this to be possible, the rate of aggregate formation must be fast compared to the incubation time (1 h) that preceded the time-resolved fluorescence measurement of each sample. Tachyia (1987) deduced a relationship between the mean reaction time, _m, of a pair of randomly distributed molecules in the surface of a sphere (e.g., a micelle or a lipid vesicle) and the sum of the radii of the sphere and the reactant, r, and the sum of the diffusion coefficients of both reactants, D:

(19)

with d being the sum of the radii of the reactants. If one considers the worst situation of our studies, i.e., a lipid vesicle with a radius of 50 nm (LUV) and D 10^-14 m² s^-1 (lipids in the gel phase; Sackmann, 1983), we get _m 1 s. Therefore, it is safe to conclude that even if the aggregates formed are larger than a dimer, the incubation time used for each lipid and antibiotic mixture must have been sufficiently long for nystatin oligomerization reaction to attain its final equilibrium value even when the larger lipid vesicles were used.

The time-resolved fluorescence data also show that the minimal number of monomeric-bound antibiotic molecules required to be present in a lipid vesicle for the long-lived fluorescent antibiotic species to be formed is A^* 10 (Fig. 4 B). It is important to note, however, that this parameter corresponds to the antibiotic aggregation number in the liposomes only if nystatin self-association in the lipid vesicles is an irreversible process, which is not the case (Coutinho and Prieto, 1995). According to St. Pierre-Chazalet and co-workers (St. Pierre-Chazalet et al., 1988) and Seoane et al. (1997) the superficial area occupied by AmB in an antibiotic monolayer at the air/water interface is 1.8–1.9 nm²/molecule when the molecules are horizontal, i.e., when their polar faces are anchored in the water and their hydrophobic polyene chains are in contact with the air. On the other hand, upon switching to an orientation perpendicular to the interface (vertical form), the AmB molecules occupy 0.55 nm²/molecule. Considering that the surface area of a DPPC molecule is 0.5 nm² (gel phase; see Marsh, 1990), the performance of a simple calculation shows that for this critical occupation number (A^* = 10), less than 1% of the external surface area of a small unilamellar vesicle is occupied by horizontally adsorbed nystatin molecules.

This hypothesis also provides an explanation for the anomalous binding curves obtained for this antibiotic when small unilamellar gel-phase DPPC vesicles with high antibiotic concentrations were used (see Coutinho and Prieto, 1995; see also Results section, this article). In fact, the formation of long-lived and highly fluorescent antibiotic oligomers in the liposomes at low liposome concentrations (A >> 10) must be the cause for this puzzling behavior. Upon increasing the lipid concentration in each sample, there must have been a rapid exchange of antibiotic molecules between the lipid vesicles causing the dissociation of these aggregates (A << 10). Since the monomeric membrane-bound antibiotic molecules have a lower quantum yield than the oligomers, the steady-state fluorescence intensity of the antibiotic samples stabilized, or even decreased, upon increasing the lipid concentration in solution, contrary to the theoretical expectation. These deviations were not noticed with the lowest antibiotic concentration used in the partitioning experiments (4.2 µM nystatin; Coutinho and Prieto, 1995) because in this case the alterations in the fluorescence emission decay kinetics of the antibiotic occurred at a very low phospholipid concentration ( 0.5 mM). This interpretation of the experimental data is further supported by other studies that show the polyene antibiotics ability's to undergo a rapid distribution between the aqueous phase and the lipid bilayers, either black lipid membranes (Cass et al., 1970) or liposomes (Witzke and Bittman, 1984). The spectroscopic CD studies carried out by Bolard et al. (1981) have also shown the capacity of AmB to rapidly exchange between DPPC SUV in the gel phase. Vertut-Croquin et al. (1984) even took advantage of this property to change the incorporation procedure of AmB into the lipid vesicles from an injection of an antibiotic stock solution prepared with an organic solvent to the utilization of liposomes preloaded with AmB.

However, two major criticisms may be raised against the hypothesis discussed above. First, a rigorous demonstration of its validity would require testing if a slow-decaying antibiotic species is obtained when nystatin samples are prepared with DPPC LUV containing a mean antibiotic occupation number below the determined critical value, i.e., A <10. Unfortunately, these measurements were extremely difficult to perform with our experimental setup because they would either require the use of a very low antibiotic concentration (implying a large acquisition time for the time-resolved fluorescence measurement) or of a very concentrated lipid suspension (that would originate an important scattering contribution to the experimental data). Therefore, it cannot be ruled out that the curvature radius of the lipid vesicles used may play some role in nystatin oligomerization. In fact, since this parameter determines the lipid packing of the external monolayer of LUV and SUV, it may also influence the penetration of the membrane surface by nystatin molecules and, consequently, their ability to form aggregates.

Secondly, it should be noted that the calculation of the mean occupation number of the liposomes by the antibiotic molecules was carried out using two major approximations: 1), it was admitted that both liposome suspensions, SUV and LUV, consisted of an homogeneous population of lipid vesicles; and 2), nystatin ability to induce the aggregation/fusion of SUV was ignored. Both these factors must be responsible, at least to some extent, for the scattering of values displayed in Figs. 3 and 4, particularly the one presented by the samples prepared with the highest concentrations of antibiotic. However, their relative importance on the final result must not have been too severe, otherwise it would not have been possible to normalize all the experimental data by computing A for each sample, as it is shown in Fig. 4 B.

Nystatin location in the lipid vesicles
Depth-dependent fluorescence quenching studies of nystatin with two lipophilic probes, 5- and 16-DS, were carried out using two different antibiotic concentrations, namely 3.0 and 12.5 µM. These samples displayed distinct mean fluorescence lifetimes (10 and 28 ns, respectively) and therefore they represented two different experimental situations: in the first case (3.0 µM nystatin; A = 4.1), the bound antibiotic molecules were predominantly monomeric in the lipid bilayer, whereas in the second case (12.5 µM nystatin; A = 17.0) a significant fraction of the bound antibiotic molecules was already engaged in the formation of oligomers with a long-lived fluorescence lifetime. Hence, it was anticipated that these fluorescence quenching studies could eventually provide some information about nystatin assembly being accompanied by an internalization of the antibiotic molecules from the bilayer surface toward its hydrophobic interior.

In the first situation studied (A = 4.1), it was concluded that the monomeric antibiotic molecules reside near the phospholipid/water interface since the Stern-Volmer plot showed that the shallower spin-labeled fatty acid 5-DS was a more effective quencher of the tetrane fluorophore than the16-DS probe (Fig. 6 A). This location is compatible with the fast fluorescence decay kinetics presented by this antibiotic species ( 10 ns) because the surface-adsorbed antibiotic molecules must not experience a very rigid environment upon membrane binding.

Since the same experimental methodology was also used to determine the transverse location of filipin (Castanho and Prieto, 1995), another polyene antibiotic, it is interesting to compare both studies. Contrary to the present data, it was reported that the spin-labeled fatty acid 16-DS was a more efficient quencher of the fluorescence from the filipin pentane group than the 5-DS probe. Therefore, it was concluded that filipin location was in the inner region of the membrane, near the phospholipid bilayer center. The difference between the preferred locations found for these two polyene antibiotics must be related to their distinct chemical structures; whereas nystatin has a mycosamine residue attached to its macrolide ring, the small polyene macrolide antibiotic filipin does not. Hence, this sugar must be essential in anchoring nystatin at the membrane surface due to its polar character.

The analysis of the quenching data obtained in the second situation studied (A = 17.0) is necessarily more complex, because two different antibiotic populations—monomers and oligomers—co-exist in equilibrium in the lipid vesicles. In addition to different fluorescence quantum yields, these two antibiotic populations most probably also have distinct transverse locations in the lipid membrane as well as a variable exposure of their tetrane groups to the quenchers used. Ladokhin (1997) and Asuncion-Punzalan et al. (1998) have already addressed some of these problems by considering the effect of two populations of fluorophores at different depths in the lipid bilayer in the analysis of the quenching results. The authors concluded that the information obtained about the center of the transverse distributions of the molecules in the liposomes reflected their average depth in the lipid bilayer weighted by their respective fluorescence quantum yields. Considering that the oligomers formed by nystatin exhibit a lifetime-weighted quantum yield 5x higher than the membrane-bound monomeric molecules (see next section), the fluorescence emitted by the 12.5 µM nystatin sample must be dominated to a large extent by the long-lived aggregates formed by nystatin. Therefore, it seems reasonable to assume that the quenching results must reflect predominantly the average location of the tetrane fluorophore in these antibiotic assemblies. Since both spin-labeled fatty acids quenched 12.5 µM nystatin fluorescence nearly to the same extent (Fig. 6 B), it seems that nystatin oligomerization in the liposomes is accompanied by a coordinate translocation of the antibiotic molecules from the bilayer surface toward its center (Fig. 7). On the other hand, it is expected that the self-association undergone by nystatin in the liposomes must have shielded to some extent the antibiotic fluorophores from the spin-labeled fatty acids used. However, this alteration in the fluorophores accessibility to the quenchers does not influence the interpretation of the quenching data because the masking of the quenching efficiencies is expected to be the same for both spin-labeled fatty acids.

View larger version (23K): [in this window] [in a new window]   FIGURE 7  Schematic representation of the main stages of nystatin interaction with gel-phase lipid vesicles. (i) After nystatin addition to a liposome suspension, the monomeric antibiotic molecules partition into the membrane-water interface of the lipid vesicles. (ii) When the mean number of antibiotic molecules per liposome reaches a critical value (10 for gel-phase lipid vesicles), nystatin starts to self-associate. This process is accompanied by an increase in nystatin mean fluorescence lifetime from 7–10 ns to 35 ns. Concurrently, nystatin molecules translocate from the surface toward the interior of the lipid vesicles. The nystatin molecules that form an oligomer must shield their polar groups from contact with the acyl chains of the phospholipids.

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When nystatin is added to the aqueous solution at a sufficient low concentration, monomeric antibiotic molecules adsorb predominantly at the phospholipid/water interface. This surface location of the antibiotic does not impose severe restrictions to the vibrational movements of the macrolide ring of the antibiotic molecules, and therefore their fluorescence emission decay kinetics is relatively rapid, i.e., the antibiotic presents a short mean fluorescence lifetime ( 7–10 ns).

Upon increasing the antibiotic concentration added to each sample, the membrane-bound antibiotic molecules start to oligomerize. Since the antibiotic molecules are putatively more rigidified in the antibiotic assemblies formed in the lipid bilayer than in its monomeric form, its nonradiative deactivation pathways decrease and its fluorescence emission decay kinetics becomes slower. Therefore, the mean fluorescence lifetime of nystatin progressively increases from 7–10 ns to 35 ns.

The quenching experiments support the hypothesis that nystatin aggregation in the lipid vesicles is accompanied by an internalization of the antibiotic molecules from the lipid bilayer surface toward its center (Fig. 7). This re-orientation of nystatin in the membrane must increase the local perturbation exerted by the antibiotic molecules upon the lipid bilayer structure. When SUV are used, this effect is translated into an increased liposome aggregation/fusion induced by the antibiotic molecules.

The above model raises two important questions, both of which deserve further consideration. The first question is, what is the effect of the interdependence between both equilibria—nystatin partition and oligomerization—on nystatin partitioning into the lipid vesicles? In fact, if both equilibria must be obeyed simultaneously, they may influence each other significantly depending on the experimental conditions employed (i.e., antibiotic and phospholipid concentrations used). The second issue that must be considered is whether this model has the ability to reproduce the general