A kinetic study of the oxidation effects of amphotericin B on human low-density lipoproteins.

The UV-visible results of this kinetic study show that amphothericin B as Fungizone is a much stronger oxidant than CuSO(4), itself a powerful oxidant of low-density lipoprotein (LDL). Amphotericin B as AmBisome alone has no oxidizing effect on LDL while a mixture of both AmBisome and CuSO(4) induces an important potentialization of the LDL oxidation. These results allow us to believe that the high toxicity of amphotericin B is related to its capacity to modify and to weaken the structure of LDL. In addition, differential scanning calorimetry experiments show that the oxidative modifications of LDL by CuSO(4) or by amphotericin B proceed through different mechanisms.

Amphotericin B toxicity as related to the formation of oxidatively modified low-density lipoproteins.

The effect of amphotericin B on the oxidation and degradation of low- and high-density lipoproteins was investigated by UV-vis spectroscopy, electron microscopy, electrophoresis, and size-exclusion chromatography. Two formulations of the drug were used: the commercial Fungizone and a new, less toxic, liposomal formulation, AmBisome. It was shown that Fungizone strongly enhanced the oxidative deformation of low-density lipoprotein structure while AmBisome did not bind to this lipoprotein fraction and did not affect its oxidation. It was shown that amphotericin B contained in Fungizone extracted cholesterol from low-density lipoproteins which sensitized them to oxidation. Both formulations of amphotericin B studied here did not bind to high-density lipoprotein and did not affect the process of its oxidation.

Modulation of amphotericin B activity by association with mannose ester.

The biological and molecular properties of a new formulation of Amphotericin B complexed with the surfactant palmitoyl mannose were studied in in vitro as well as in in vivo situations. The properties analyzed include toxicity towards two types of mammalian cells and four fungi strains, effect on macrophage activity, inflammatory properties, acute toxicity in mice and spectral behavior in presence of foetal calf serum or 6% propanol. The results demonstrate that, in presence of palmitoyl mannose, the cytotoxicity of AmB is decreased towards both, fungal and mammalian cells while its fungistatic potential is increased, its inflammatory properties are conserved and its acute toxicity is significantly diminished. These effects can be potentially explained by the formation of a complex between AmB and the sugar ester that impedes the interaction of the drug with either serum components or cell membrane constituents. The overall properties of AmB in the complex would be expected to favor an increase in the immunoadjuvant properties of the drug, a more localized inflammation during fungal infection and consequently a better therapeutic efficiency.

Effects of the aggregation state of amphotericin B on its toxicity to mice.

Amphotericin B (AmB) is a very effective antifungal agent for most systemic fungal infections. However, the relatively high toxicity of this drug imposes limits on its clinical usefulness. Most of the current work in this field is devoted to the search for less-toxic formulations of the drug. Here we describe the effects of three surfactants, one anionic and the other two nonionic, on the aggregation state of AmB in solutions which were injected intravenously into mice. The degree of aggregation of AmB was monitored spectroscopically and by light scattering. The toxicity was expressed as percentage of survivors. These results were compared with those obtained with doses of AmB the same as those present in a commercial formulation of AmB, Fungizone. Two surfactants, lauryl sucrose and sodium deoxycholate, used at concentrations which induced monomerization of AmB, substantially decreased the acute toxicity of AmB to mice. Conversely, the third surfactant, Tween 80, showed a synergistic potentiation of the toxicity of the antibiotic. A good correlation was found between the in vivo toxicity and the aggregation state of AmB in injected solutions. Solutions in which AmB was almost entirely monomeric were half as toxic after 24 h and about six times less toxic after 1 week than the corresponding solutions of Fungizone.

Inhibition of the interaction between lipoproteins and amphotericin B by some delivery systems.

Amphotericin B (AmB) is a potent antifungal agent used to treat patients with systemic mycoses. The clinical usefulness of the drug is limited by its high toxicity and several new less toxic formulations of AmB have been recently developed. In order to understand the mechanism of the decreases of toxicity caused by various new delivery systems, we have investigated by uv-visible spectroscopy the interaction of two of these formulations with human blood lipoproteins. The results were compared with those obtained with the commonly used pharmaceutical form of AmB (Fungizone). This study shows that AmB-lipoprotein interaction is hindered when the drug is in a monomeric form and/or when it is included in phospholipid-surfactant micelles. In an in vivo study on mice it is shown here that AmB monomerized by surfactant is less toxic to animals than the same concentration of Fungizone, where the polyene is strongly aggregated. It may be concluded from the present study that the AmB species which is responsible for the in vivo toxicity is a complex of the antibiotic with the low density and the very low density blood lipoproteins and that hindering of this complex formation results in a decrease of AmB toxicity.

Structure-activity study of inhibition of amphotericin B (Fungizone) binding to sterols, toxicity to cells, and lethality to mice by esters of sucrose.

The effects of four monoesters of sucrose with different acyl chain lengths (palmitate, C16; myristate, C14; laurate, C12; and caprate, C10) on the aggregation state of amphotericin B (AmB), its binding to cholesterol and ergosterol, its toxicity to cells, and its lethality to mice were determined. In solution, all four of these esters inhibited AmB binding to cholesterol more than to ergosterol; this effect correlated with the ester-induced shift from the mainly aggregated form of AmB to the mainly monomeric form. In experiments with cells, the esters inhibited the toxicity of AmB to mouse erythrocytes and cultured mouse fibroblast L-929 cells more than its toxicity to Candida albicans cells. When injected intravenously with AmB, these esters decreased AmB lethality to mice. In all of these assays, the ester with the shortest chain length (caprate) was much less potent than the other three esters. Our results indicate a correlation between in vitro and in vivo assays and suggest that the in vitro and in vivo selectivity of AmB may be enhanced by surface-active agents which modulate the aggregation state of AmB.

The effect of surfactants on the aggregation state of amphotericin B.

We have studied the effect of two surfactants, one non-ionic, lauryl sucrose (LS) and the other ionic, sodium deoxycholate (DOC), on the aggregation state of amphotericin B (AmB) and its selectivity towards ergosterol and cholesterol. It is shown that the addition of these surfactants has very similar effects on the AmB micelles. Below the critical micellar concentration of the surfactants, mixed micelles with AmB are first formed as a result of the penetration of the surfactant molecules into the AmB micelles. At higher concentrations of the surfactant molecules, the micellar structure is completely destroyed and AmB is found as monomers in solution. When the concentration of the surfactant is further increased, micelles of the surfactant molecules are built up, AmB remaining in monomeric form. However, the critical micellar concentration of LS is modified by the presence of AmB in solution, while that of DOC is not affected, thereby indicating that the interactions of AmB with LS are stronger than those of DOC with AmB. We also show that both surfactants enhance the selectivity of the AmB binding to sterols at exactly the concentrations of the surfactants which induce the monomerization of the antibiotic. It is observed that the maximal selectivity is found at a concentration of the surfactants corresponding to their particular CMC in presence of the antibiotic.

The effect of molecular structure in a series of merocyanines on the in vitro cytotoxicity for adenocarcinoma cells.

Preliminary results have shown that merocyanines were cytotoxic for human adenocarcinoma cells in vitro. We report the synthesis of a series of new merocyanines and the structure-effect relationship as cytotoxic agents on human adenocarcinoma cells in vitro. Some of these new derivatives were found very cytotoxic for tumor cells in vitro, whereas their systemic toxicity in vivo was very low.

Concentration dependent dual effect of the monolauryl ester of sucrose on the antifungal activity and absorption spectra of amphotericin B (Fungizone).

A mild detergent, the monolauryl ester of sucrose (LS), at concentrations which ranged from 0.008 to 0.03%, enhanced amphotericin B (AmB) toxicity against Saccharomyces cerevisiae and Cryptococcus neoformans cells. At higher concentrations, 0.06 to 2.5%, LS inhibited AmB effects on these two fungi. We analyzed changes in the absorption spectrum of AmB induced by LS at these two concentration ranges by comparing ratios (R values) of AmB absorbance at 409 nm, the wavelength characteristic of non-aggregated (monomeric) AmB, to absorbance at 328 nm, the wavelength characteristic of aggregated AmB. Low concentrations of LS caused a decrease in R, whereas the higher LS concentrations increased R. Therefore, LS had concentration-dependent dual effects on the antifungal activity of AmB which correlated with shifts in the physical states of AmB. The concentration range of LS required to inhibit the antifungal effects of AmB was about 1000-fold greater than the previously reported concentrations required to inhibit AmB toxicity to mammalian cells (Gruda, I., Gauthier, E., Elberg, S., Brajtburg, J. and Medoff, G. (1988) Biochem. Biophys. Res. Commun. 154, 954-958). This suggests that LS may be a useful agent to decrease AmB toxicity to host cells without affecting the antifungal effects. Moreover, increase in AmB toxicity induced by low concentrations of LS suggests the possibility that synergistic interaction between fatty acid esters and polyene antibiotics may have therapeutic value.

Stimulation of lymphoproliferation by sucrose esters.

Lauryl sucrose has recently been shown to decrease the toxicity of amphotericin B (AmB), a widely used antifungal agent, probably through a modulation of its physical state. In this paper, we demonstrate using a lymphoproliferative assay, that lauryl sucrose and monosubstituted analogs in addition to their effects on AmB also possess significant immune enhancer properties. An anti-bell shape relationship was observed between stimulation of lymphoproliferation and chain length of ester's fatty acid, lauryl sucrose being the less active of the tested derivatives. These properties of sucrose esters are discussed in the specific context of antifungal therapy.

Effects of the detergent sucrose monolaurate on binding of amphotericin B to sterols and its toxicity for cells.

Amphotericin B (AmB) is a potent antifungal agent used to treat patients with systemic mycoses. The cytotoxicity of AmB is related to its binding to membrane sterols and its clinical usefulness is based on its greater affinity to ergosterol, the fungal sterol, compared to the mammalian cell sterol, cholesterol (1-3). Here we report that sucrose monolaurate (L.S.) decreased the binding of AmB to cholesterol without interfering with its binding to ergosterol. Furthermore, the toxicity of AmB for mouse erythrocytes (RBC) and cultured mouse fibroblasts, L-929, cells was significantly decreased by low concentrations of L.S., whereas under the same conditions, its toxicity for Candida albicans was unaffected. We observed a very good correlation between the spectroscopic and cell studies. The results reported here on the effects of L.S. on the selectivity of AmB toxicity for fungal cells compared to animal cells and the relative nontoxic nature of sugar esters suggest a potential for compounds of this type to enhance the therapeutic index of AmB.

Effect of the aggregation state of amphotericin B on its interaction with ergosterol.

The interaction of amphotericin B with ergosterol was studied in aqueous solutions of propanol. The mode of the interaction was found to be related to the aggregation state of amphotericin B. Ergosterol does not react (or reacts extremely slowly) with monomeric amphotericin B. Traces of a small aggregate, probably a dimer, enable a cooperative reaction. At high concentrations of the dimer, the reaction is immediate and the concentration of amphotericin B complexed with ergosterol is twice as high as the amount of added sterol. The interaction with ergosterol is hindered when the antibiotic is in micellar form. The pharmaceutical form, Fungizone, behaves similarly to the pure amphotericin B. Fungizone's greater solubility in water does not modify either the extent or the mode of interaction with ergosterol.

Merocyanines: potential new anticancer agents.

We report the synthesis of a series of merocyanines and the structure-effect relationship as cytotoxic agents for human adenocarcinoma cells in vitro. The cytotoxicity of these compounds in vitro makes them potential anticancer agents. One of these compounds was found active on human and mouse tumor models.

Analysis of amphoteric surfactants of the alkylaminopropylglycine type by gas chromatography.

A procedure was developed for gas chromatographic analysis of glycine-type amphoteric surfactants. The commercial samples contained N-alkylaminopropylglycines, N-alkylamines and N-alkylaminopropylamines. Some di- and triacids were also detected. The method proposed allows a good separation according to both the carbon number and the chemical function.

On the existence of an amphotericin B--sterol complex in lipid vesicles and in propanol-water systems.

The amphotericin B (AmB) - ergosterol complex, formed by interaction of the antibiotic with ergosterol-containing phospholipid vesicles, is associated with the lipid bilayer. It has been shown by circular dichroism studies that the AmB-ergosterol complex formed in water-propanol binary mixtures has a similar structure to that observed in phospholipid vesicles. A positive cooperativity is found for the interaction of AmB with ergosterol. The similar AmB-cholesterol complex is much less stable and rearranges rapidly to a different conformation.

Relative avidity of etruscomycin to cholesterol and ergosterol.

Two methods, biological and spectroscopic, were used to determine the avidity of the polyene antibiotic Etruscomycin for cholesterol and ergosterol. The biological method consisted of measuring the inhibitory potency of both sterols on the Etruscomycin-induced damage to erythrocytes and fungi. The spectroscopic method consisted of recording of series of differential spectra in a number of solvents of different composition. The results obtained showed that cholesterol protected erythrocytes and candida albicans against the damaging action of Etruscomycin more efficiently than ergosterol did and that Etruscomycin-cholesterol complexes were more resistant to interruption by organic solvents than Etruscomycin-ergosterol complexes. These results and their comparison with the results obtained with other polyene antibiotics indicate that Etruscomycin resembles filipin in that it binds more avidly to cholesterol than to ergosterol. This implies that the length of the hydrophobic chain rather than the presence of the amino sugar determines sterol preference. The spectral method that we used can have general application for the quantitative measurement of complex formation between polyenes and sterols.

Application of differential spectra in the ultraviolet-visible region to study the formation of amphotericin B-sterol complexes.

The extent of complex formation between the polyene antibiotic, amphotericin B, and cholesterol or ergosterol was investigated and a method for a quantitative measurement of the complex formation was developed. The effect of experimental conditions on the magnitude of the amphotericin B-sterol interaction and on the selectivity of this interaction showed that there was only a narrow range of solvent composition in which the differential selectivity of amphotericin B towards these two sterols could be observed.