Toxicity of nystatin and its methyl ester toward parental and hybrid mammalian cells

Summary Nystatin methyl ester (NME), the methyl ester derivative of the polyene macrolide antibiotic nystatin, is known to be effective against fungi and is now found to be relatively less toxic than the parent antibiotic nystatin (NYS) to animal cells in culture as measured by⁵¹Cr release, cell survival at different posttreatment periods and cell growth. NYS and NME were tested on TK⁻ mouse (B82) and hamster (B1) cells, HGPRT⁻ mouse (RAG) cells, and on lysolecithin-fused cells selected in HAT medium and confirmed as B82-RAG an B1-RAG hybrids by chromosomal analysis plus polyacrylamide gel electrophoresis of lactate dehydrogenase. NME was less toxic and caused less immediate membrane damage than NYS when tested in all five cell systems. However, differences in innate polyene sensitivity were evident between the three parental cell types. B82 and B1 cells were more resistant than RAG cells to NYS and NME. B82-RAG hybrids reflected the higher level resistance of B82 parental cells, and B1-RAG hybrids reflected the higher level resistance of B1 cells. Where one parental cell type is relatively more polyene sensitive, the use of polyenes in the future may be applicable as selective agents in cell hybridization. This investigation was supported by NIH Training Grant No. GM 507 from the National Institute of General Medical Sciences.     

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.     

Selection of mouse X hamster hybrids using HAT medium and a polyene antibiotic.

In the present study we tested the feasibility of utilizing a structurally modified polyene antibiotic, amphotericin B methyl ester (AME), as a half-selection agent for isolating somatic cell hybrids. By using HAT medium supplemented with AME we have isolated interspecific mouse-hamster hybrids from mixed cultures of mouse (TK-C1 ID or HPRT-A9) and hamster (BHK/C 13) cells fused with Sendai virus, lysolecithin or polyethylene glycol. Hybrid cells proliferated and clones were isolated after 2 to 3 weeks growth in three changes of HAT-AME medium and subsequent growth in HAT medium alone. In contrast, genetically deficient parental C1 1D or A9 cells and AME-sensitive BHK/C 13 cells were killed using a similar growth protocol. The described technique is simple, efficient and permits one to use a cell line without a genetic defect in combination with a genetically deficient cell type in hybrid formation.     

Selection of mouse x hamster hybrids using hat medium and a polyene antibiotic

Summary In the present study we tested the feasibility of utilizing a structurally modified polyene antibiotic, amphotericin B methyl ester (AME), as a half-selection agent for isolating somatic cell hybrids. By using HAT medium supplemented with AME we have isolated interspecific mouse-hamster hybrids from mixed cultures of mouse (TK⁻C1ID or HPRT⁻ A9) and hamster (BHK/C 13) cells fused with Sendai virus, lysolecithin or polyethylene glycol. Hybrid cells proliferated and clones were isolated after 2 to 3 weeks growth in three changes of HAT-AME medium and subsequent growth in HAT medium alone. In contrast, genetically deficient parental C1 1D or A9 cells and AME-sensitive BHK/C 13 cells were killed using a similar growth protocol. The described technique is simple, efficient and permits one to use a cell line without a genetic defect in combination with a genetically deficient cell type in hybrid formation. This investigation was supported in part by Contract NIH 69-2161, NIH Grant No. AI-2095 and NIH Training Grant No. GM 507 from the National Institute of General Medical Sciences.     

Polyene macrolide antibiotic cytotoxicity and membrane permeability alterations I. Comparative effects of four classes of polyene macrolides on mammalian cells

The relationship between polyene macrolide-induced early membrane damage and cytotoxicity in B1 (hamster), B82 (mouse), and RAG (mouse) cells has been investigated. Filipin (FIL) induced the greatest immediate damage, as monitored by ⁵¹Cr release, followed by mediocidin (MED), amphotericin B-deoxycholate (Fungizone®) (FZ) and pimaricin (PIM). For long term effect, PIM was the least toxic followed by MED, FZ, and FIL as indicated by 24-hour survival, 72-hour viability, and growth rate of cells. In evaluating polyene macrolide-induced permeability alterations and cytotoxicity two types of interactions with mammalian cells were found: (1) cell toxicity at polyene macrolide levels not eliciting immediate membrane permeability changes; and (2) immediate membrane damage without long range toxicity.     

Cation conductance and efflux induced by polyene antibiotics in the membrane of skeletal muscle fiber.

Cation conductance and efflux induced by polyene antibiotics amphotericin B (AMB), amphotericin B methyl ester (AME), nystatin, mycoheptin, and levorin on frog isolated skeletal muscle fibers and whole sartorius muscles were investigated. Conductance was measured under current-clamp conditions using a double sucrose-gap technique. Cation efflux was studied using flame emission photometry. Some new data were obtained concerning the effects of levorin and mycoheptin on biological membranes. The power dependence of polyene-induced cation transport on antibiotic concentration in muscle membrane was lower than that in bilayers. The decline in the equilibrium conductance caused by polyene removal (except for levorin) was very fast. There was reverse temperature dependence of AMB- and nystatin-induced conductances. Both induced conductance and efflux values demonstrated a correlation with the order of antifungal activities: levorin > AMB, mycoheptin > AME > nystatin, except for AME, which was more potent on yeastlike cells. These effects were interpreted in terms of possible differences in the kinetics of channel formation in biological and model membranes and in light of the role of nonconducting antibiotic forms in biological membranes.     

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.     

Phospholipid enrichment of Saccharomyces cerevisiae and its effect on polyene sensitivity

Sensitivity to polyene antibiotics, e.g., nystatin, amphotericin B, and filipin, was determined in phosphatidylcholine (PC) or phosphatidylethanolamine (PE) or phosphatidylserine (PS) enriched Saccharomyces cerevisiae cells, using glutamic acid, phenylalanine, glycine, and lysine transport as an index of polyene antibiotic action. As compared with normal cells, phospholipid-enriched cells acquired resistance towards different polyenes. However, the sensitivity of glutamic acid transport towards nystatin remained unaffected in PC-, PE-, or PS-enriched cells. In contrast to nystatin, the other two polyenes were more effective in checking the influx of amino acids. Results demonstrated that the specific enrichment of PC, PE, or PS could selectively protect S. cerevisiae cells from polyene antibiotic action.     

The effect of fetal bovine serum on polyene macrolide antibiotic cytotoxicity and antifungal activity

Summary The relationships between fetal bovine serum (FBS) concentration and polyene macrolide antibiotic cytotoxicity to animal cells and to fungi were evaluated. The toxicity of amphotericin B (AB) and its derivative, amphotericin B methyl ester (AME), toward KB cells was found to be directly related to fetal bovine serum concentration. At higher FBS levels, increased concentrations of AB and AME were required to reduce 72-hr KB viable cell numbers to 50% of control values. Similarly, polyene macrolide antibiotic levels required to inhibit the growth ofSaccharomyces cerevisiae to 50% of controls, and for obtaining minimum fungicidal concentrations (MFC), were greater when higher levels of FBS were used. In addition, AME was less toxic than AB toward KB cells grown in media containing 2, 5, 10, 15 or 20% FBS, whereas the antifungal activities of AB and AME were similar. AME was also capable of eliminatingCandida albicans, Saccharomyces cerevisiae, Aspergillus niger orFusarium moniliforme from KB cultures at antibiotic levels which exhibited less cell toxicity than did the concentrations of AB required for a similar response. These findings indicate that AME may be a potentially useful antifungal antibiotic for tissue culture systems. Portions of this paper were presented at the 25th Annual Meeting of the Tissue Culture Association at Miami, Florida, 1974. This investigation was supported in part by contract NIH 69-2161, NIH grant no. AI-02095 and NIH training grant no. GM 507 from the National Institute of General Medical Sciences.     

Selective toxicity of the polyene antibiotics and their methyl ester derivatives.

The methyl ester hydrochlorides of amphotericin B and nystatin are less effective than the parent compounds in causing K⁺ release from human erythrocytes. The parent compounds and the derivatives are of comparable activity toward $\text{Candida albicans}$. The enhanced selective toxicity of polyene methyl ester salts for $\text{C. albicans}$ may mean that these antibiotics will be more effective therapeutic agents for systemic fungal infections.     

Reduced toxicity of amphotericin B methyl ester (AME) vs. amphotericin B and fungizone in tissue culture.

The comparative toxicities of amphotericin B methyl ester (AME), the parent antibiotic amphotericin B (AB), and the deoxycholate solubilized complex of AB, Fungizone (FZ), toward five cell lines has been determined as measured by early membrane damage (51Cr release), 24 hr survival, 72 hr viability, and growth rate. Cells used were of turtle (TH-1), marsupial (PT K2), human MA 160), rabbit (RK-13) and hamster (BHK-21) origin. AME: (a) caused less membrane damage at 1 hr than AB or FZ; (b) was less toxic than AB or FZ as indicated by 24 hr cell survival and 72 hr cell viability; and (c) was required in higher levels than AB or FZ to reduce the growth rate of all five cell lines. Spectrophotometric analysis of residual polyene levels indicated that AME had good stability in tissue culture medium. Previous studies have indicated that AME has the same in vitro antifungal activity as the parent antibiotic AB (1, 2). These findings suggest that AME may prove to be superior to AB and FZ for use as an antifungal agent in tissue culture systems.     

Isolation and characterization of amphotericin B-resistant cell lines in Chinese hamster cells

Amphotericin B is a polyene macrolide antibiotic which interacts specifically with steroids in mammalian cell membranes. Amphotericin B-resistant (AMB^r) lines of stable phenotype have been isolated from cultured Chinese hamster (V79) cells. Three AMB^r clones (AMB^r-1, -2 and -3) isolated independently after treatment with nitrosoguanidine were resistant to ≥150 μg/ml of the antibiotic, while DNA synthesis as well as the colony-forming ability of the parental V79 cells was blocked by >80% of control in the presence of 20–50 μg/ml amphotericin B. The AMB^r cell line also exhibited increased resistance to other polyene macrolide antibiotics such as nystatin and pentamycin. Other agents, however, such as cytosine arabinoside or ricin, blocked DNA synthesis in AMB^r cells to the same extent as in V79 cells. The amphotericin B resistance phenotype was stably retained even after AMB^r cells were cultured in the absence of the drug for over 200 generations. The content of free cholesterol or its esters was significantly decreased in all three resistant clones. Furthermore, cholesterol synthesis from acetate as well as mevalonate was partly defective in AMB^r cells, compared with that in V79 cells.     

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)     

Effect of nystatin,amphotericin B and amphotericin B methyl ester on Saccharomyces cerevisiae with different lipid composition

Saccharomyces cerevisiae was cultured under anaerobiosis in semi-complete medium to which either palmitoleic or oleic acid was added. Cells were grown at 20 °C or 30 °C. The levels of total lipids, total sterols, and phospholipids were higher in cells grown at 20 °C than at 30 °C. The effects of nystatin (NYS), amphotericin B (AMB), and amphotericin B methyl ester (AME) were evaluated by determining cell viability and liberation of intracellular compounds. The loss of cell viability is higher in the first 30 minutes of incubation with the drugs and is the same regardless of the type of cells obtained. Low molecular weight compounds and ions such as K⁺ are liberated a few minutes after incubation with the drugs whereas proteins and substances absorbing at 260 nm are liberated later. Phosphate liberation comes after K⁺ and before compounds of higher molecular weights.     

Supersensitivity to levorin and amphotericin B in several Saccharomyces cerevisiae mutants resistant to nystatin]

104 mutants resistant to nystatin were isolated after UV-treatment of two haploid marked strains of Saccharomyces cerevisiae. The analysis of resistance to three polyene antibiotics allowed to determine 8 phenotype classes of mutants including those resistant to nystatin but in various combinations showing hypersensitivity to levorin and (or) amphotericin B. The analysis of UV absorption spectra of sterolic extracts prepared from cells of different mutants showed that similar quality changes in sterol composition could be associated both with polyresistant an supersensitive phenotype. New type of mutants resistant to nystatin and supersensitive to levorin and (or) amphotericin B seems to be promising for studies on the mechanisms of action of polyene antibiotics, the bases of resistance to them and also in consideration of the possibility to increase the efficiency of antimycotic antibiotic therapy.     

Yeast resistance to polyene antibiotics. VII. The interaction of the mutant alleles of the nystatin resistance genes in Saccharomyces cerevisiae

The data on allele interactions of nystatin resistance genes are presented. It has been shown that the mutant phenotype of heteroallelic hybrids NYS1, NYS4 and, probably, NYS3 is strengthened. The intragenic complementation has been found in NYS2 gene, allowing to imply the multimeric structure of delta 8----delta 7 isomerase which is controlled by this gene.     

Pre-resonance Raman spectra and conformations of nystatin in powder,solution and phospholipid-cholesterol multilayers

A Raman scattering study of the channel-forming polyene antibiotic nystatin, is reported in the solid state, in organic and aqueous solutions as well as in phospholipid and phospholipid-cholesterol multilayers. Measurements of the solid and solution spectra as a function of excitation wavelengths in the 459.7–514.5 nm range, and the phospholipid spectra as a function of temperature in the 10–60°C range, have also been made. The spectral features indicate a pre-resonance-enhanced Raman spectrum in which the CC and CC stretching modes of the polyene segment of nystatin are dominant. However, in contrast to previously published results on the nearly isostructural polyene antibiotic amphotericin B, a line at 1610 cm^?1 assignable to the CO stretching mode is also observed to be strongly resonance enhanced. This is explained by a postulated ground-state conformation model in which a twisting of the molecule is facilitated by the break in the polyene chain. This allows the CO group at one end of the molecule to be aligned along the polyene unit at the other end, and the CC stretching vibration, which is strongly modulated by the polyene π → π1 excited state, to mix with the CO stretching vibration. The peak frequencies and intensities of the CC and CC stretching modes in nystatin, however, remain essentially unchanged compared with amphotericin B, indicating that the polyene units in nystatin remain planar and trans both in the ground and excited states.The intensity of the CO mode with respect to the CC stretching mode was observed to vary appreciably with nystatin environment, indicating a     

Growth characteristics and polyene sensitivity of a fatty acid auxotroph of Candida albicans.

A fatty acid auxotroph of Candida albicans 6406, designated A' 44 and originally isolated as an oleic acid requiring strain, has been shown to be a delta9 desaturase mutant. Although lacking this step in fatty acid biosynthesis, it appears to retain the ability to desaturate monounsaturated fatty acids. The polyene sensitivity of the organism grown on different fatty acid supplements varied between 0-08 +/- 0-02 and 1-20 +/- 0-30 microgram amphotericin B methyl ester ml-1 for exponentially growing cells. In spite of this variation, the sterol composition remained fairly constant, the major differences lying in fatty acid composition. Stationary-phase cells were more resistant to amphotericin B methyl ester, although again this change was not associated with changes in sterol content. The organism was most resistant when grown in the presence of oleic or linoleic acid. Protoplasts derived from resistant organisms grown on these two fatty acids were also resistant, indicating that the structure of the cell wall was less important than that of the plasma membrane in determining polyene sensitivity under these conditions.     

Interaction between nystatin and natural membrane lipids in Langmuir monolayers--the role of a phospholipid in the mechanism of polyenes mode of action

Nystatin (NYS), a polyene antifungal antibiotic, has been investigated in Langmuir monolayers alone and in mixtures with mammalian and fungi membrane sterols (cholesterol and ergosterol, respectively) as well as with a model phospholipid (DPPC). The interactions between film molecules have been examined both in a qualitative and quantitative way with the excess area per molecule (AExc), excess free energy of mixing (DeltaGExc) and the interaction parameter (alpha). The obtained results have been compared with those previously reported for another polyene antimycotic: amphotericin B (AmB) mixed with lipids. Higher affinity of NYS has been observed for ergosterol vs. cholesterol, however, the strongest attractions were found for its mixtures with DPPC. The obtained results have been verified with biological studies reported previously for both antibiotics (NYS and AmB). A thorough analysis of the Langmuir experiment results performed for both polyenes enabled us to conclude that the presence of DPPC can be considered as a key factor affecting their antifungal activity as well as their toxicity towards host cells.     

Reduced toxicity of amphotericin B methyl ester (AME) vs. amphotericin B and fungizone in tissue culture

Summary The comparative toxicities of amphotericin B methyl ester (AME), the parent antibiotic amphotericin B (AB), and the deoxycholate solubilized complex of AB, Fungizone² (FZ), toward five cell lines has been determined as measured by early membrane damage (⁵¹Cr release), 24 hr survival, 72 hr viability, and growth rate. Cells used were of turtle (TH-1), marsupial (PT K2), human MA 160), rabbit (RK-13) and hamster (BHK-21) origin. AME: (a) caused less membrane damage at 1 hr than AB or FZ; (b) was less toxic than AB or FZ as indicated by 24 hr cell survival and 72 hr cell viability; and (c) was required in higher levels than AB or FZ to reduce the growth rate of all five cell lines. Spectrophotometric analysis of residual polyene levels indicated that AME had good stability in tissue culture medium. Previous studies have indicated that AME has the same in vitro antifungal activity as the parent antibiotic AB (1, 2). These findings suggest that AME may prove to be superior to AB and FZ for use as an antifungal agent in tissue culture systems. Fungizone^R. Trade mark. E. R. Squibb and Sons. This investigation was supported in part by Contract NIH 69-2161, NIH Grant No. AI-02095 and NIH Training Grant No. GM 507 from the National Institute of General Medical Sciences.