Effect of polyene antibiotics and their perhydrovderivatives on intact cells and protoplasts of yeast Candida guilliermondii]

Perhydroderivatives of polyene antibiotics have a much lower activity against eukaryotic cells than the polyene antibiotics itself. Bacterial cells are normally resistant against most polyene antibiotics and their perhydroderivatives. In earlier experiments with wall less L-form cells of Escherichia coli we have shown that the bacterial cell wall may be responsible for the resistance of the intact bacterial cells against polyene antibiotics and their perhydroderivatives by masking internal target sites. In the present paper we studied the effect of polyene antibiotics and their perhydroderivatives on intact cells and protoplasts of Candida guilliermondii. Our experiments have shown that most of the perhydroderivatives studied had a lower activity against intact cells as well as protoplasts than the corresponding polyene antibiotics. This means that in the case of eukaryotic cells the cell wall as a penetration barrier cannot mainly be responsible for the low activity of perhydroderivatives. The results are compared with those obtained previously with intact cells and protoplast type L-form cells of E. coli.     

Biosynthesis and pathway engineering of antifungal polyene macrolides in actinomycetes

Polyene macrolides are a large family of natural products typically produced by soil actinomycetes. Polyene macrolides are usually biosynthesized by modular and large type I polyketide synthases (PKSs), followed by several steps of sequential post-PKS modifications such as region-specific oxidations and glycosylations. Although known as powerful antibiotics containing potent antifungal activities (along with additional activities against parasites, enveloped viruses and prion diseases), their high toxicity toward mammalian cells and poor distribution in tissues have led to the continuous identification and structural modification of polyene macrolides to expand their general uses. Advances in in-depth investigations of the biosynthetic mechanism of polyene macrolides and the genetic manipulations of the polyene biosynthetic pathways provide great opportunities to generate new analogues. Recently, a novel class of polyene antibiotics was discovered (a disaccharide-containing NPP) that displays better pharmacological properties such as improved water-solubility and reduced hemolysis. In this review, we summarize the recent advances in the biosynthesis, pathway engineering, and regulation of polyene antibiotics in actinomycetes.     

Dependence of Ion Channel Properties Formed by Polyene Antibiotics Molecules on the Lactone Ring Structure

The properties of ion channels formed in membranes by polyene antibiotics of various chemical structure of hydrophilic and hydrophobic chains are investigated. Small differences in a hydrophylic chain with a changed number of hydroxyl and carbonyl groups significantly influence the values of conductivity and selectivity of the polyene channel. The greater number of double bonds in a hydrophobic part of polyene molecules leads to the higher biological activity of antibiotics. Measurement of anion–cationic selectivity of the channels formed by polyenes showed that anionic selectivity, as well as conductivity of channels, decreases among antibiotics: amphotericin B, nystatin, candidin, mycoheptin, and levorin. The study of physical and chemical properties of the single and hybrid ion channels on the bilayer lipid membranes in the presence of polyene antibiotics makes possible to create a theoretically reasonable recommendation for the targeted synthesis of new antibiotics with the desired properties.     

Polyene antibiotics in the membrane environment.

The cytotoxic activity of the polyene antibiotics mainly depends on the appearance of the drug species which arises from drug-sterol complexation. The unsaturation and intact macrolide ring of the polyenes are the requirements for the biological activity. All the polyene antibiotics can form the complex with the sterol having 3 beta-OH group, and planar ring and a hydrophobic side chain. Aromatic polyene antibiotics with positively charged head group have been considered as most potential antifungal agents.     

Effects of polyene antibiotics on the membranes of dog kidney isolated nuclei]

The effects of amphotericin B and nistatin on the membranes of dog kidney isolated nuclei after their incubation with the antibiotics in question, have been studied. It is found that the polyene antibiotics, though they are superficially-active compounds, have no solubilizing effect on nuclear membranes and do not change their chemical composition. Electrophoretic study has revealed that nuclear membrane proteins, besides high- and low-molecular protein components, also contain a large amount of histones. The incubation of the nuclei with the polyene antibiotics results in marked changes in the fractional composition of nuclear membrane proteins, the most significant changes being induced by amphotericin B. It is assumed that polyene antibiotics induce proteolytic degradation of nuclear membrane proteins.     

多烯类抗生素合成基因簇中ABC转运蛋白研究进展

ABC转运蛋白家族是一个广泛存在于不同生物细胞中且功能保守的膜蛋白亚家族;它们是一类单向底物转运泵,通常以主动转运方式完成多种分子的跨膜转运。随着抗生素合成基因簇相关研究的开展,越来越多的簇内ABC转运蛋白被鉴定出来,对其生物学功能的研究正逐渐成为热点。多烯类抗生素作为一类重要的抗真菌药物,能够有效避免真菌产生耐药性,具有非常重要的临床价值。本文以多烯类抗生素合成基因簇为对象,综述了在其中所发现的ABC转运蛋白的研究进展,综合分析了其结构特性与功能间的关系,并对研究应用进行了展望。     

Study of the resistance of Candida guilliermondii to polyene antibiotics

250 Candida guilliermondii strains resistant to the polyene antibiotics nystatin, levorin and amphotericin B were obtained using UV irradiation. When the mutant strains became resistant to one of the polyene antibiotics, their resistance to the other ones changed. Phenotypic analysis showed that the resistance of the strains to polyene antibiotics did not make them susceptible to a rise in osmotic pressure and to a change of the temperature of incubation. Some of the polyene-resistant strains were stained in a medium with methylene blue. Analysis of the sterol composition in the mutants by UV spectroscopy showed that the resistance to polyene antibiotics sometimes involved changes in the sterol composition. Two new UV spectrum types were recorded for the sterols of the mutant strains; they differed from the UV spectrum for the sterols of the parent sensitive strain.     

The water and ionic permeability induced by polyene antibiotics across plasma membrane vesicles from Leishmania sp

An osmotic method has been used to study the effect of the polyene antibiotics amphotericin B, nystatin and candicidin on the water permeability of plasma membranes prepared from Leishmania sp. The effect of amphotericin B on the permeability of Leishmania membranes to a salt such as potassium nitrate was also investigated. A non-linear and saturable enhancement of water and salt permeability was measured with increasing polyene concentrations, which could be adjusted to Hill cooperativity equation. The antibiotic concentrations that induce at 30 degrees C half-maximal effects on the water permeability of Leishmania vesicles were 0.021 microM for candicidin, 0.21 microM for amphotericin B and 1.4 microM for nystatin. At 30 degrees C, the concentration of amphotericin B required to induce half of the maximal effect on the permeability of Leishmania vesicles to potassium nitrate was 1.8 microM. The temperature dependence for amphotericin B, nystatin and candicidin enhancement of the water permeability of Leishmania vesicles was determined by using Q10 data at 20 and 30 degrees C. The estimated activation energies at increasing polyene concentrations display the same general pattern for all three polyene antibiotics investigated, that is, a maximal positive value at about the polyene concentrations required for half-maximal effect. The significance of these results for understanding the mechanisms of action of polyene antibiotics on natural membranes is discussed.     

The synthesis and characterisation of polyene complexes with divalent metal ions: Mg(II), Ca(II), Ni(II), Cu(II) and Zn(II)

Metal ion (Mg(II), Ca(II), Zn(II), Cu(II), Ni(II)) complexes of nystatin and amphotericin B (polyene antibiotics) have been prepared as solids. The stoichiometry of the complexes has been established. IR, ESR investigation indicates the metal-ligating sites in the polyene molecules. The existence of such complexes is discussed in the light of polyene mode- of-action theories.     

Determination of mycelial steroids with the aid of polyene antibiotics. II. Quantitative determination of the mycelial steroids of Mucor hiemalis.

UV absorption spectrum of polyene antibiotics was dramatically altered in the presence of steroids. The introduction of a steroid to an aqueous solution of polyene antibiotics resulted in a change in the ratio of absorbance of peak 3 (with shorter wavelength) to peak 1 (with longer wavelength), E3/E1. Interactions between 28 steroids and 4 polyene antibiotics were studied and the results revealed that the structures of steroids essential for the optimal interaction with polyene antibiotics were C-17 side chain, substitution C-3 hydroxyl group, intact steroid nucleus and aromatic A-ring. The ratio of E3/E1 was used for the determination of steroids in mycelium of Mucor hiemalis and the result was in good agreement with that obtained from gas chromatograph. The (-) strain had a greater change in the ratio of absorbance, E3/E1, than that of the (+) strain. The ratio of absorbance, E3/E1, decreased in the following order: the (-) strain, the (-) strain with the addition of the filtrate of (+) strains, the mated strains, the (+) with the addition of the filtrate of (-) strain and the (+) strain.     

Composition and characteristics ofCandida albicans cells differing in resistance to polyene antibiotics

Development of resistance to polyene antibiotics in a highly resistantCandida albicans strain was shown to be accompanied by the complete loss of the ability to synthesize ergosterol and the substitution of other sterol components as well as by higher amounts of free fatty acids. No significant differences in lipid and protein composition have been noted between slightly resistant cultures ofC. albicans and initially susceptible ones. Sterols of resistant cultures (added in the solution and incorporated in the composition of native membranes and liposomes) have the same affinity for polyene antibiotics as do sterols of a sensitive strain. It was found that the resistance of the slightly resistantC. albicans strain did not depend on the cell wall. The ability of some detergents to reduce resistance to polyene antibiotics was shown.     

Inhibition of erythrocyte ghost ATPase by polyene antibiotics

The effect of micromolar concentrations of polyene antibiotics on erythrocyte ghost ATPase activities has been studied. (Mg2+)-ATPase is inhibited by amphotericin B and amphotericin B methyl ester, whereas (Na+ + K+ + Mg2+)-ATPase is inhibited by amphotericin B and lucensomycin. (Ca2+ + Mg2+)-ATPase is only slightly affected by polyene antibiotics.     

The Effect of Polyene Antibiotics on Photosynthetic Electron Transfer

The effect of four polyene antibiotics and digitonin on photosyntheticelectron transfer by maize mesophyll chloroplasts has been investigated.All five compounds, at concentrations between 0.1 mM and 20mM, inhibited photosystem 2 activity as measured by the photo-reductionof ferricyanide and 2,6-dichlorophenolindophenol from water.Etruscomycin, amphotericin B, and digitonin were more inhibitorythan filipin and nystatin. Photosystem 1 activity was inhibitedby 1 mM concentrations of etruscomycin, amphotericin B, anddigitonin but not by filipin and nystatin. In all cases whereinhibition occurred, it was temperature dependent. The inhibition of photosystem 1 activity could be relieved byplastocyanin. Etruscomycin and digitonin, at concentrationsof 0.5 mM and above, caused disintegration of the chloroplasts,and this disintegration was accompanied by a two- to three-foldincrease in photosystem 1 activity in the presence of plastocyanin.It is concluded that the action of polyene antibiotics resultsin the release of plastocyanin from its site in the photosyntheticelectron transfer chain. The results are discussed in termsof the abilities of polyene antibiotics and digitonin to formcomplexes with sterols.     

Absorption and fluorescence spectra of polyene antibiotics in the presence of cholesterol.

The alterations in the absorption and fluorescence spectra observed for the polyene antibiotics filipin and nystatin in the presence of cholesterol are due to an exciton interaction (polyene aggregates) and cannot be attributed to a specific sterol-antibiotic complex. Filipin and nystatin molecules partition into the sterol aggregates, these structures being very efficient to induce exciton interaction; the observed splitting profile indicates that the chromophores are in a stacked arrangement (parallel transition dipoles). For filipin incorporated in lipid bilayers, the sterol is able to induce the same type of aggregate, at variance with nystatin.     

Polyene macrolide antibiotic cytotoxicity and membrane permeability alterations. II. Phenotypic expression in intraspecific and interspecific somatic cell hybrids.

Cytotoxicity and membrane permeability alterations induced by the polyene macrolide antibiotics filipin (FIL) and pimaricin (PIM) have been compared in parental intraspecific and interspecific somatic cell hybrids. B82 (mouse) and B1 (hamster) cells were found to be more resistant than RAG (mouse) parental cells to both polyene macrolides as indicated by 24-hour survival, 72-hour viability, and growth rate. Analysis of both intraspecific and interspecific somatic cell hybrids indicated that polyene macrolide resistance was being expressed even in the presence of the polyene macrolide-sensitive (RAG) genome. Where one of the two parental cell types is relatively polyene macrolide resistant, the use of specific polyene macrolides may prove efficacious as half-selective agents in cell hybridization.     

Influence of net charge on the aggregation and solubility behaviour of amphotericin B and its derivatives in aqueous media

The poor solubility of polyene antibiotics in aqueous media limits their application in the therapy of systemic fungal infections. In the present paper we have demonstrated that the ionic state (net electrical charge) of the antibiotic molecule is an important factor in determining the aggregation and solubility properties of amphotericin B and its derivatives. A multi-step model of polyene self-association in aqueous media has been proposed as an explanation for the fact that some major differences are observed when aggregation is monitored by different techniques. Offprint requests to: J. Mazerski     

Cholesterol as a target for toxins

A mechanism is proposed for the way in which cholesterol facilitates channel formation by polyene antibiotics and bacterial protein toxins. Central elements of the model are: (i) interactions between the ring system of the sterol and rigid elements of the polyene or toxin molecule, and (ii) the specific orientation of cholesterol within the membrane.     

How do the polyene macrolide antibiotics affect the cellular membrane properties?

In the 1970's great strides were made in understanding the mechanism of action of amphotericin B and nystatin: the formation of transmembrane pores was clearly demonstrated in planar lipid monolayers, in multilamellar phospholipid vesicles and in Acholeplasma laidlawii cells and the importance of the presence and of the nature of the membrane sterol was analyzed. For polyene antibiotics with shorter chains, a mechanism of membrane disruption was proposed. However, recently obtained data on unilamellar vesicles have complicated the situation. It has been shown that: membranes in the gel state (which is not common in cells), even if they do not contain sterols may be made permeable by polyene antibiotics, several mechanisms may operate, simultaneously or sequentially, depending on the antibiotic/lipid ratio, the time elapsed after mixing and the mode of addition of the antibiotic, there is a rapid exchange of the antibiotic molecules between the vesicles. Although pore formation is apparently involved in the toxicity of amphotericin B and nystatin, it is not the sole factor which contributes to cell death, since K+ leakage induced by these antibiotics is separate from their lethal action. The peroxidation of membrane lipids, which has been demonstrated for erythrocytes and Candida albicans cells in the presence of amphotericin B, may play a determining role in toxicity concurrently with colloid osmotic effect. On the other hand, it has been shown that the action of polyene antibiotics on cells is not always detrimental: at sub-lethal concentrations these drugs stimulate either the activity of some membrane enzymes or cellular metabolism. In particular, some cells of the immune system are stimulated. Furthermore, polyene antibiotics may act synergistically with other drugs, such as antitumor or antifungal compounds. This may occur either by an increased incorporation of the drug, under the influence of a polyene antibiotic-induced change of membrane potential, for example, or by a direct interaction of both drugs. That fungal membranes contain ergosterol while mammalian cell membranes contain cholesterol, has generally been considered the basis for the selective toxicity of amphotericin B and nystatin for fungi. Actually, in vitro studies have not always borne out this assumption, thereby casting doubt on the use of polyene antibiotics as antifungal agents in mammalian cell culture media.(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparative analysis of in vitro antifungal activity and in vivo acute toxicity of the nystatin analogue S44HP produced via genetic engineering]

New polyene macrolide S44HP was purified from the culture of recombinant Streptomyces noursei strain with engineered nystatin polyketide synthase. S44HP, nystatin (NYS), and amphotericin B (Amph-B) were tested against 19 clinical fungal isolates in agar diffusion assay, which demonstrated clear differences in antifungal activities of these antibiotics. Sodium deoxycholate suspensions of all three antibiotics were subjected to acute toxicity studies in vivo upon intravenous administration in mice. NYS exhibited the lowest acute toxicity in mice in these experiments, while both Amph-B and S44HP were shown to be 4 times more toxic as judged from the LD50 values. While the acute toxicity of S44HP was higher than that of Amph-B, the data analysis revealed a significantly increased LD10 to LD50 dose interval for S44HP compared to Amph-B. The data revealed structural features of polyene macrolides, which might have an impact on both the activity and toxicity profiles of these antibiotics. These results represent the first example of preclinical evaluation of an "engineered" polyene macrolide, and can be valuable for rational design of novel antifungal drugs with improved pharmacological properties.     

Sterol and fatty acid composition of polyene macrolide antibiotic resistant Torulopsis glabrata.

Successive reculturing of Torulopsis glabrata on media containing increasing concentration of the polyene macrolide antibiotics nystalin or lucensomycin resulted in the segregation of cultures resistant to these antibiotics. Isolates resistant to lucensomycin showed good resistance to nystatin, and vice versa. Analysis of the sterols and fatty acids of sensitive and polyene resistant T. glabrata revealed that compositional changes occurred in both classes of lipids upon acquistion of resistance. The sterol composition of nystatin and lucensomycin resistant cultures possessed reduced amounts of, or no ergosterol (the major sterol of the sensitive parent culture), and increased amounts of sterols which were biogenetically more primitive than ergosterol. Resistant cultures in which ergosterol was absent possessed a fatty acid composition that did not differ significantly from the parent sensitive culture grown under identical conditions. Resistant cultures containing significantly reduced amounts of ergosterol were found to possess altered fatty acid compositions. Generally it was observed that these latter cultures possessed fatty acids containing shorter and more saturated chains. These results are considered to indicate that alteration in both lipid and sterol composition is involved in determination of culture resistance to polyene macrolides.