Interaction of 14C-labelled amphotericin B derivatives with human erythrocytes: relationship between binding and induced K+ leak

Interaction of amphotericin B and its low toxic derivative, N-methyl-N-D-fructosyl amphotericin B methyl ester, with fungal, mammalian and bacterial cells measured by the energy transfer method

Amphotericin B (AMB) derivative, N-methyl-N-D-fructosyl amphotericin B methyl ester (MFAME) retains the broad antifungal spectrum and potency of the parent antibiotic, whereas its toxicity towards mammalian cells is reduced by about two orders of magnitude. The purpose of this work was to find out whether the differences observed in the toxicity of MFAME and native AMB are due to the differential drugs affinity to fungal and mammalian cell membranes. Comparative studies on AMB and MFAME biological activity and their affinity to fungal, mammalian and bacterial cells were performed. The interaction of AMB and MFAME with cells have been studied by fluorescence method based on the energy transfer between membrane fluorescent probe (donor) and the polyenic chromophore of the antibiotic (acceptor) simultaneously present in the cell membrane. The amount of the antibiotic bound to cells was indicated by the extent of fluorescence quenching of 1-(4-trimethylammoniumphenyl)-6-phenyl-1,3,5-hexatriene (TMA-DPH) or 1,6-diphenyl-1,3,5-hexatriene (DPH) by polyenic chromophore of the antibiotic. The results obtained indicate that binding extent and characteristics for both antibiotics are comparable in the three types of cells studied. Dramatically lower toxicity of MFAME as compared to AMB towards mammalian cells is not related to the antibiotic-cell affinity, but rather to different consequences of these interactions for cells, reflected in membrane permeabilization. MFAME is definitely less effective than parent AMB in the permeabilizing species formation in mammalian cell membrane.

Cooperative partition model of nystatin interaction with phospholipid vesicles

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 approximately 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.

Novel approaches in the rational design of antifungal agents of low toxicity

This paper presents an overview of studies on novel strategies for the rational design of antifungal agents of low toxicity and overcoming the multidrug resistance (MDR) of fungi. This goal was achieved both due to the introduction of a novel target, glucosamine-6-phosphate synthase, as well as to the recognition of molecular basis of selectivity of action of amphotericin B derivatives.

Characterization of the effects of amphotericin B on ion channels in MDCK cells using the patch-clamp technique

Cultured Madin-Darby Canine Kidney cells were used as a model to study the mechanism of nephrotoxicity of amphotericin B using the patch-clamp technique. At the whole-cell level, amphotericin B altered potassium conductances in two types of these cells categorized on the basis of whole-cell potassium currents. The first cell type, classified as Type I, exhibited no significant whole-cell potassium currents. The second type, Type II, exhibited depolarization-induced outward potassium currents that rundown over time. In both of these subpopulations, exposure to amphotericin B at a concentration of 68 nM for a prolonged period of time (approximately 30-45 min) led to an increased whole-cell potassium conductance. In Type I cells, it increased by a factor of 16 and in Type II cells, by a factor of 3.5. Furthermore, the potassium currents observed in Type I cells following amphotericin B treatment bore no resemblance to currents through pores formed by amphotericin B in artificial membranes. At the single-channel level, incubation with amphotericin B led to a significantly higher potassium channel activity in both inside-out and outside-out patches. Kinetic studies in inside-out patches revealed that the increases in channel activity were associated with a decrease in the mean closed time and an overall increase in the mean open time. In summary, our data suggest that the direct toxicity of amphotericin B is primarily related to its ability to disturb normal ion channel functioning rather than to formation of pores in cell membranes.

Effects of aggregation and solvent on the toxicity of amphotericin B to human erythrocytes

In aqueous suspensions of amphotericin B (AmB), a polyene antibiotic and antifungal agent, three forms of AmB coexist: monomers, water-soluble oligomers, and non-water-soluble aggregates. The toxicity of the water-soluble self-associated form of AmB compared with that of the non-water-soluble self-associated form was tested by measuring induction of K+ leakage from human erythrocytes, using different suspensions containing the antibiotic and phosphate-buffered saline. These suspensions were obtained from various stock solutions of the antibiotic in dimethyl formamide or dimethyl sulfoxide. Their circular dichroism spectra around 340 nm, indicative of the degree of AmB self-association, were strongly dependent on the concentration of organic solvent in the suspensions. The nonsoluble self-associated form was separated from the water-soluble form by centrifugation. The nonsoluble form was favored by a high concentration of AmB of the stock solution. The kinetics of AmB-induced K+ leakage from human erythrocytes also appeared to be strongly dependent on the AmB concentration of the stock solution being much weaker with concentrated stock solutions. It was concluded that the only form of AmB toxic to human erythrocytes is the water-soluble self-associated form (in contrast with fungal cells on which the monomeric form is also active). This result may be important in the design of new less toxic AmB derivatives and in the understanding of the mechanism of action of liposomal AmB.

Kinetic study of interaction between [14C]amphotericin B derivatives and human erythrocytes: relationship between binding and induced K+ leak

The relationship between polyene antibiotic binding to red cells and their membrane permeabilization was studied using two 14C-labelled amphotericin B (AmB) derivatives: N-fructosyl AmB and N-acetyl methyl ester AmB. The binding kinetics of both derivatives were determined on whole red cells and ghosts. The resulting experimental points were well fitted by monoexponential functions, and the characteristic t1/2 for both derivatives were calculated from these functions. At 2 X 10(-5) M, the half time t1/2 for N-acetyl methyl ester AmB (30.2 min) which forms aqueous aggregates was longer than the t1/2 for the more soluble species N-fructosyl AmB (4.5 min). At lower concentrations (10(-7) M), the t1/2 for N-acetyl methyl ester AmB (6.3 min) in a more solubilized form was close to that of N-fructosyl AmB (7.9 min). These results suggest that only solubilized species bound to red cell membranes and that disaggregation of aggregates is the limiting step in the binding process. The permeabilization of red cell membranes by N-fructosyl AmB, measured as intracellular K+ leak, was not instantaneous and at 10 degrees C external K+ was only detected 20 min after antibiotic addition. In contrast, binding occurs without lag time. Consequently, different mecanisms underlie binding and K+ permeability inducement. Absorption spectroscopy data showed that bound antibiotic is located in the hydrophobic membrane interior and that this penetration of the membrane by AmB derivatives occurs without lag time. Consequently, the lag time occurring for K+ permeability inducement would be due to some steps subsequent to binding and probably located in the hydrophobic membrane interior. This statement is further supported by the observation that the lag time is sensitive to changes in membrane fluidity as shown here by the break between 20 and 30 degrees C in the slope of the Arrhenius plot for the lag time, coinciding with the phase transition in red cell membranes.

Artificial red cells. A link between the membrane skeleton and RES detectability?

Factors governing nonspecific reticuloendothelial system (RES)-detectability are largely unknown. Will a liposome that mimics the lipid composition of the outer leaflet of the erythrocyte membrane be invisible to the RES? On both experimental and theoretical grounds we believe the answer is no, in part because 1) sorption of proteins is believed to be important in determining RES uptake, 2) a membrane skeleton is apparently necessary to inhibit protein sorption into erythrocyte membranes and 3) Neohemocytes (a liposome encapsulated hemoglobin product) currently lack a membrane skeleton. Neohemocytes with erythrocyte outer leaflet lipid composition do have extended circulation half-times, but these are at least two orders of magnitude shorter than the circulation half-times of erythrocytes. How might a membrane skeleton modulate RES-detectability? Can avoidance of opsonization result in part from the properties of the membrane skeleton? If so, then how? To explore and quantify such questions we have developed a theoretical, statistical-thermodynamic model of protein binding into membranes. It predicts that the membrane area available for rapid lateral diffusion is critically important in controlling the amount of sorbed protein per unit area, and that a membrane skeleton can reduce a protein's sorption by several orders of magnitude. Based on theoretical results, we offer a speculative model for the detection of non-self lipid bilayers by the RES.

Interaction of amphotericin B and its N-fructosyl derivative with murine thymocytes: a comparative study using fluorescent membrane probes

The polyene antibiotics amphotericin B (AmB) and N-(1-deoxy-D-fructos-1-yl)amphotericin (N-Fru-AmB) have different activity towards murine thymocytes (N-Fru-AmB is less toxic but is a potent immunomodulator). The interactions of the drugs with these cells have been studied by fluorescence methods. Fluorescence energy transfer from 1-[4-(trimethylammonio) phenyl]-6-phenylhexa-1,3,5-triene, p-toluenesulfonate (TMA-DPH) to polyenes was used to follow the binding of the two drugs to the plasma membrane. The results, confirmed by circular dichroism measurements, indicate that at saturation the ratio AmB bound/plasma membrane lipid is low (less than 1 molecule of polyene for 170 lipids). The slightly higher binding of AmB as compared to N-Fru-AmB demonstrates that affinity of the antibiotic for plasma membrane does not account for the activity of the polyenes towards lymphocytes. The effect of the two polyenes on membrane fluidity was studied by steady-state fluorescence anisotropy. The results suggest that AmB strongly perturbs the structure of the membrane whereas only a slight decrease of the anisotropy is observed with N-Fru-AmB in the range of concentration where the biological activity has been demonstrated. Polyene location was further investigated by comparing the energy transfer efficiency obtained with TMA-DPH and with the parental compound 1,6-diphenylhexa-1,3,5-triene, p-toluene sulfonate (DPH). While AmB binds to plasma membrane, as well as to intracellular structures, N-Fru-AmB seems to accumulate into the cell and bind to intracellular membrane structures.

Relationship between ionophoric and haemolytic activities of perimycin A and vacidin A, two polyene macrolide antifungal antibiotics

The ionophoric and hemolytic activities of two antifungal aromatic heptaenes: vacidin A and perimycin A, were studied on human red blood cells. Measurements of hemolysis, K+ influx and efflux, H+ movement and potential difference across the cell membrane, show that the hemolytic activity, being related to the K+ permeability induced by the polyene, is strongly dependent on the ability of this polyene to induce H+ movement. It was shown that: (1) both antibiotics have approximately the same efficiency in inducing K+ permeability, but a 100-fold difference in their hemolytic activity; (2) their hemolytic activity is related to their ability to induce H+ movement; (3) the protonophoric activity requires the existence of a free carboxyl group in the macrolide ring, as in vacidin A. The hemolytic activity is determined by the intrinsic efficiency of a K+/H+ exchange induced by this polyene. With perimycin A, which lacks the free carboxyl group, the hemolytic activity is dependent on the Cl- conductive flux which slows down the K+ flux.

Polyene--sterol interaction and selective toxicity

From permeability experiments carried out with series of amphotericin B derivatives in both biological and model membranes, it was concluded that derivatives, whose carboxyl group at the C18 position is blocked by substitution, are much more efficient at inducing permeability in ergosterol-containing than in cholesterol-containing membranes, whereas derivatives whose carboxyl group is free and ionizable are equally efficient in both membranes types. Binding measurements on erythrocyte membranes showed that all amphotericin B derivatives simply partition between membrane lipids and aqueous medium, according to their lipid solubility. There is no relationship between binding and efficiency in inducing permeability. Permeability studies carried out on lipidic vesicles containing various sterols showed that: 1) derivatives having their carboxyl free induced permeability of the 'channel' type, regardless of the sterol present, and no detectable permeability in sterol-free membranes; 2) derivatives whose carboxyl group is blocked induce channels only in membranes containing ergosterol or sterols having an alkyl side chain identical to that of ergosterol. In the presence of other sterols or in sterol-free membranes, their ionophoric activity is poor and always of the 'mobile-carrier' type. A model of polyene-sterol interaction is proposed, accounting for the data obtained with both biological and model membranes.

Intracellular alkalinization induced by amphotericin B derivatives in HL-60 leukemia cells

The effects on intra- and extracellular pH of two polyenic derivatives of amphotericin B, N-fructosyl amphotericin B and N-fructosyl amphotericin B methyl-ester, were tested on HL-60 promyelocytic leukemia cells. Both derivatives raised the internal pH and reduced the external pH in weakly buffered medium. These results support the idea that both derivatives induce outward proton movement from the cell to the external solution. In this respect, the non-esterified derivative proved to be more powerful that the esterified one. Under the present conditions, there was little or no regulation of pH in HL-60 cells, which exhibited an almost constant pH gradient between the external and internal pH (acid inside relative to outside). This deficiency in pH homeostasis might be due to the immature state of the HL-60 cells.