An inducible, nondegradative phytoalexin resistance mechanism in Dictyostelium discoideum is suppressed by mutations that alter membrane sterol composition.

Pretreatment of Dictyostelium discoideum amoebae with a sublethal concentration of the pea phytoalexin pisatin was shown to induce nondegradative resistance to subsequent challenges with inhibitory concentrations. An alteration of membrane sterol composition either with the azasterol A25822B or by mutations in nysC that confer resistance to the polyene antibiotic nystatin suppressed the induction of pisatin resistance. Wild-type cells grown on pisatin medium acquired resistance to nystatin; however, after transfer to nystatin medium, they lost their pisatin resistance phenotype but remained nystatin resistant. To account for this asymmetry in the induction and maintenance of cross-resistance after growth on pisatin and nystatin media, we propose a model in which the two resistance phenotypes are governed by distinct mechanisms. This model presumes that growth on pisatin induces membrane alterations that predispose cells to acquire nystatin resistance but that the pisatin-induced membrane alterations are not maintained in the absence of pisatin.     

Effects of pisatin on Dictyostelium discoideum: its relationship to inducible resistance to nystatin and extension to other isoflavonoid phytoalexins

Dictyostelium discoideum amoebae can acquire resistance to otherwise inhibitory concentrations of pisatin, an isoflavonoid phytoalexin of pea, and nystatin, a polyene antibiotic, following pretreatment with sublethal concentrations of these compounds. Additionally, growth on medium containing pisatin can induce nystatin resistance. We show here that distinct mechanisms mediate the inducible resistance to these two compounds because it is possible to isolate mutations that specifically block the induction of nystatin resistance but do not affect the induction of pisatin resistance. Pisatin did not affect wild-type sterol biosynthesis; therefore, the induction of nystatin resistance by pisatin is probably not via an alteration of membrane sterols. The inducible pisatin resistance phenotype was shown to extend to the isoflavonoid phytoalexins maackiain and biochanin A, and all three compounds inhibited the aggregation of amoebae that is normally triggered by starvation. Received: 23 February 1998 / Accepted: 26 June 1998     

Expression of pisatin demethylating ability in Nectria haematococca

A mycelial suspension of Nectria haematococca completely demethylated 0.1 mM pisatin in 2 h in a medium free of other carbon sources while no demethylation of pisatin by the fungus occurred in 6 h when 2% glucose was in the medium. Prior exposure of the fungal cells to pisatin in glucosefree medium markedly enhanced the rate of pisatin demethylation, with maximum stimulation occurring 5–9h after the initial exposure. The stimulation of pisatin demethylating ability was relatively specific for pisatin as the inducer. Out of a large variety of isoflavonoids tested the only compounds other than pisatin that stimulated the activity significantly were pterocarpan or isoflavan derivatives. Protoplasts with pisatin demethylating ability were isolated from pisatin-treated mycelium. Attempts to obtain a cell-free system with pisatin demethylating ability from these protoplasts were unsuccessful.     

Effect of nystatin on the release of glycerol from salt-stressed cells of the salt-tolerant yeast Zygosaccharomyces rouxii

The polyene antibiotic nystatin, which affects fungal membrane permeability, inhibited the growth of Zygosaccharomyces rouxii grown in medium containing 15% (w/v) NaCl, whereas yeast grown in medium without NaCl were only slightly inhibited. Nystatin caused salt-stressed cells to release large amounts of glycerol and inhibited their growth, but amino acids and materials with an absorbance at 260 nm were not released from the cells. The leakage was increased by the addition of glucose, and more than 90% of the intracellular glycerol was released into the medium during a 2-h incubation with 0.11 microM nystatin and 2% (w/v) glucose. Glycerol was indispensable for the growth of Z. rouxii grown in culture medium containing 15% NaCl.     

The effect of nystatin on electrical characteristics of the algaHydrodictyon reticulatum

The effect of nystatin on the fresh-water algaHydrodictyon reticulatum was studied by estimating the electrical resistance of both the membranes and the intracellular fluid. The outflow of potassium ions into the external medium, occurring after addition of nystatin, was determined by flame photometry. Values of ohmic resistance of membranes treated with nystatin ranged from 0.33 to 1.51 kΩcm², the control values being 8.03–16.73 kΩcm². Values of the resistance of intracellular fluid in nystatin-treated cells lay in the range of 3.21–7.13 kΩcm, those of control cells being 1.10 to 1.91 kΩcm. The concentration of potassium ions in the external medium increased from 1.35 mM to 4.3 mM after addition of nystatin.     

Energy metabolism in wheat root cells under modification of plasma membrane permeability by antibiotic nystatin

This paper reports changes in ion transport and energy metabolism of plant cells during short- and long-term expositions, resp., to antibiotic nystatin, which is known to specifically bind with plasma membrane sterols to form channels. The excised roots of 5 days old wheat seedlings were used as a model system in this research. It has been shown that treatment of excised roots with nystatin leads to activation of energy metabolism expressed as an increase of respiration and heat production by root cells. Furthermore, in the presence of nystatin increased pH of incubation medium, plasma membrane depolarization and a significant loss of potassium ions were observed. Nystatin-induced stimulation of respiration was prevented by malonate, an inhibitor of succinate dehydrogenase, electron acceptor dichlorophenolindophenol, and AgNO3, an inhibitor of H(+)-ATPase. Based on the data obtained it can be suggested that nystatin-induced stimulation of respiration is related to electron transport activation via mitochondrial respiratory chain, and is connected with activation of plasmalemma proton pump. Moreover, nystatin-induced increase of oxygen consumption was prevented by cerulenin, an inhibitor of fatty acid and sterol synthesis. This indicates that additional sterols and phospholipids may be synthesized in root cells to "heal" nystatin-caused damage of plasma membrane. A supposed chain of events of cell response to nystatin action may by as following: formation of nystatin channels-influx of protons--depolarization of plasmalemma-efflux of potassium ions-disturbance of ion homeostasis--activation of H(+)-ATPase work-increase in energy "requests" for H(+)-ATPase function--increase in the rate of oxygen consumption and heat production. The increased energy production under the action of nystatin, may provide the work of proton pump and synthesis of sterols and phospholipids, which are necessary for membrane regeneration.     

Biochemical and Genetic Aspects of Nystatin Resistance in Saccharomyces cerevisiae

Two phenotypically distinct sets of nystatin-resistant mutants were investigated. One set is resistant, respiratory competent, and requires no lipid for growth. The other set is more resistant, respiratory deficient, and lipid requiring (unsaturated fatty acid or sterol). Both sets show altered sterol composition as demonstrated by the Liebermann-Burchard colorimetric reaction, ultraviolet spectrophotometry, and gas-liquid chromatography. Genetic analysis indicates that all nystatin-resistant mutants can be placed into one of six distinct genetic groups. The phenotype's nystatin resistance, lipid requirement, and respiratory deficiency are recessive. There was one case of allelism for mutants from different sets. Revertants of mutants which have the tripartite phenotype retain a residual level of nystatin resistance, but they are no longer lipid requiring or respiratory deficient. Growth studies in mutants which have the tripartite phenotype reveal that the addition of ergosterol to the growth medium results in decreased resistance to nystatin.     

Binding of sterols affects membrane functioning and sphingolipid composition in wheat roots

The present work was devoted to the exploration of the role of sterols in the functioning of membranes in root cells. Membrane characteristics and composition of the membrane lipids in the roots of wheat (Triticum aestivum L.) seedlings treated with exogenous cholesterol and antibiotic nystatin, which specifically binds with endogenous sterols, were analyzed. Cholesterol caused a fall of membrane potential, acidification of the incubation medium, decrease in potassium leakage of roots, and increase in the level of exogenous superoxide radical. Similarly to cholesterol, the application of nystatin also induced the depolarization of the plasma membrane, but in contrast with cholesterol it was accompanied by alkalinization of the incubation medium and decrease in the level of exogenous superoxide radical. Analysis of membrane lipids showed that following nystatin treatment the total sterol content in roots did not change, while the level of complex sphingolipids represented mainly by glycoceramides became higher. Using mass spectrometry with electrospray ionization (+ESI-MS) for the analysis of the glycoceramide composition, we showed that nystatin induced changes in the ratios of molecular species of glycoceramides. It was suggested that the modification of the sterol component of plasma membrane could influence membrane functioning by changing the sphingolipid composition of lipid rafts.     

Nystatin and killer toxin sensitivity of free and immobilizedSaccharomyces cerevisiae

The inhibitory effect of nystatin and killer toxin on the growth of free and covalently-immobilizedSaccharomyces cerevisiae cells was studied. The resistance of immobilized cells to both agents was accompanied by increased amounts of phospholipids and sterols. The possible relationship between these changes in the membrane composition and the transduction of a signal across the cytoplasmic membrane is discussed.     

Nystatin as a probe for investigating the electrical properties of a tight epithelium

We show how the antibiotic nystatin may be used in conjunction with microelectrodes to resolve transepithelial conductance Gt into its components: Ga, apical membrane conductance; Gbl, basolateral membrane conductance; and Gj, junctional conductance. Mucosal addition of nystatin to rabbit urinary bladder in Na+-containing solutions caused Gt to increase severalfold to ca. 460 micrometerho/muF, and caused the transepithelial voltage Vt to approach +50 mV regardless of its initial value. From measurements of Gt and the voltage-divider ratio as a function of time after addition or removal of nystatin, values for Ga, Gbl, and Gj of untreated bladder could be obtained. Nystatin proved to have no direct effect on Gbl or Gj but to increase Ga by about two orders of magnitude, so that the basolateral membrane then provided almost all of the electrical resistance in the transcellular pathway. The nystatin channel in the apical membrane was more permeable to cations than to anions. The dose-response curve for nystatin had a slope of 4.6. Use of nystatin permitted assessment of whether microelectrode impalement introduced a significant shunt conductance into the untreated apical membrane, with the conclusion that such a shunt was negligible in the present experiments. Nystatin caused a hyperpolarization of the basolateral membrane potential in Na+- containing solutions. This may indicate that the Na+ pump in this membrane is electrogenic.     

Effects of sterol-binding agent nystatin on wheat roots: the changes in membrane permeability, sterols and glycoceramides

Plant sterols are important multifunctional lipids, which are involved in determining membrane properties. Biophysical characteristics of model lipid and isolated animal membranes with altered sterol component have been intensively studied. In plants however, the precise mechanisms of involvement of sterols in membrane functioning remain unclear. In present work the possible interactions between sterols and other membrane lipids in plant cells were studied. A useful experimental approach for elucidating the roles of sterols in membrane activity is to use agents that specifically bind with endogenous sterols, for example the antibiotic nystatin. Membrane characteristics and the composition of membrane lipids in the roots of wheat (Triticum aestivum L.) seedlings treated with nystatin were analyzed. The application of nystatin greatly increased the permeability of the plasma membrane for ions and SH-containing molecules and decreased the total sterol level mainly as a consequence of a reduction in the amount of β-sitosterol and campesterol. Dynamic light-scattering was used to confirm the in vitro formation of stable complexes between nystatin and β-sitosterol or cholesterol. Sterol depletion was accompanied by a significant rise in total glycoceramide (GlCer) content after 2h treatment with nystatin. Analysis of the GlCer composition using mass spectrometry with electrospray ionization demonstrated that nystatin induced changes in the ratio of molecular species of GlCer. Our results suggest that changes in the sphingolipid composition can contribute to the changes in plasma membrane functioning induced by sterol depletion.     

Model suicide vector for containment of genetically engineered microorganisms

A model suicide vector (pBAP19h), designed for the potential containment of genetically engineered microorganisms, was made by constructing a plasmid with the hok gene, which codes for a lethal polypeptide, under the control of the lac promoter. The vector plasmid also codes for carbenicillin resistance. In the absence of carbenicillin, induction of the hok gene in vitro caused elimination of all detectable cells containing the suicide vector; pBAP19h-free cells of the culture survived and grew exponentially. In the presence of carbenicillin, however, the number of cells containing pBAP19h initially declined after induction of hok but then multiplied exponentially. The surviving cells still had a fully functional hok gene and had apparently developed resistance to the action of the Hok polypeptide. Thus, high selective pressure against the loss of the suicide vector led to a failure of the system. Soil microcosm experiments confirmed the ability of a suicide vector to restrict the growth of a genetically engineered microorganism in the absence of selective pressure against the loss of the plasmid, with 90 to 99% elimination of hok-bearing cells within 24 h of hok induction. However, some pBAP19h-bearing cells survived in the soil microcosms after hok induction. The surviving cells contained an active hok gene but were not capable of normal growth even after elimination of the hok gene; it appears that a mutation that made them Hok resistant also reduced their capacity for membrane functions needed for energy generation and exponential cell growth. Thus, the model suicide vector was shown to be functional in soil as well as in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of Nystatin on the Metabolism of Xylitol and Xylose by Pachysolen tannophilus

Ethanol production from xylitol by resting cells of Pachysolen tannophilus was increased 40-fold in the presence of nystatin, amphotericin B, and filipin, a group of antifungal agents that alter the permeability of the plasma membrane. Furthermore, these agents had little or no effect on ethanol formation from xylitol or xylose by the cell extract. During xylose metabolism, nystatin caused the intracellular xylitol to leak out into the medium at a 23-fold-faster rate but did not affect overall xylose utilization and CO₂ evolution. These observations explain the rate of xylitol utilization by cell extract being higher than that by whole cells (J. Xu and K. B. Taylor, Appl. Environ. Microbiol. 59:231-235, 1993) as well as the relative inability of P. tannophilus to utilize xylitol to support significant ethanol production and cell growth.     

Model suicide vector for containment of genetically engineered microorganisms.

A model suicide vector (pBAP19h), designed for the potential containment of genetically engineered microorganisms, was made by constructing a plasmid with the hok gene, which codes for a lethal polypeptide, under the control of the lac promoter. The vector plasmid also codes for carbenicillin resistance. In the absence of carbenicillin, induction of the hok gene in vitro caused elimination of all detectable cells containing the suicide vector; pBAP19h-free cells of the culture survived and grew exponentially. In the presence of carbenicillin, however, the number of cells containing pBAP19h initially declined after induction of hok but then multiplied exponentially. The surviving cells still had a fully functional hok gene and had apparently developed resistance to the action of the Hok polypeptide. Thus, high selective pressure against the loss of the suicide vector led to a failure of the system. Soil microcosm experiments confirmed the ability of a suicide vector to restrict the growth of a genetically engineered microorganism in the absence of selective pressure against the loss of the plasmid, with 90 to 99% elimination of hok-bearing cells within 24 h of hok induction. However, some pBAP19h-bearing cells survived in the soil microcosms after hok induction. The surviving cells contained an active hok gene but were not capable of normal growth even after elimination of the hok gene; it appears that a mutation that made them Hok resistant also reduced their capacity for membrane functions needed for energy generation and exponential cell growth. Thus, the model suicide vector was shown to be functional in soil as well as in vitro.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pisatin metabolism in pea (Pisum sativum L.) cell suspension cultures

Cell suspension cultures were established from germinating pea (Pisum sativum L.) seeds. This cell culture, which accumulated pisatin, consisted mostly of single cells containing a few cell aggregates. The cells responded to treatment with a yeast glucan preparation with transient accumulation of pisatin in both cells and culture media. Addition of pisatin to cell cultures resulted in increased synthesis of pisatin. Phenylalanine ammonia-lyase, chalcone synthase and isoflavone reductase activities were present in untreated cells. Upon treatment with an elicitor preparation the activities of the first two enzymes showed a rapid, transient increase up to 20 hours after treatment. Isoflavone reductase showed a major and minor peak at 16 and 36 h, respectively, after elicitor treatment. The time course of the enzyme activity and pisatin accumulation is consistent with an elicitor-mediated response.Abbreviations CHS chalcone synthase - 2,4-D 2,4-dichlorophenoxyacetic acid - IBA indole-3-butyric acid - IFR isoflavone reductase - 2iP 6-(dimethylallylamino)-purine - MS Murashige & Skoog basal salt medium - PAL phenylalanine ammonia-lyase - PMSF phenylmethylsulfonyl fluoride - POPOP 1,4-bis-2-(4-methyl-5-phenyloxazolyl)-benzene - PPO 2,5-diphenyloxazole     

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

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 by 51Cr 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 and 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.     

(−)-Pisatin,an induced pterocarpan metabolite of abnormal configuration from Pisum sativum

Pea (Pisum sativum) tissues, on treatment with aqueous CuCl₂ synthesize the 6a-hydroxypterocarpan phytoalexin (+) - (6aR, 11aR) - pisatin. By supplying (?) - (6aR, 11aR) - maackiain during this induction process, sigruficant quantities of ( ? ) - (6aS, 11aS) - pisatin are produced, immature pods being most effective. Pisatin levels are considerably reduced when compared with the normal induction process, but may contain as much as 92% (?)-pisatin. This confirms that the 6a-hydroxylation of maackiain during the biosynthesis of pisatin must proceed with retention of configuration at C-6a.     

Natamycin blocks fungal growth by binding specifically to ergosterol without permeabilizing the membrane

Natamycin is a polyene antibiotic that is commonly used as an antifungal agent because of its broad spectrum of activity and the lack of development of resistance. Other polyene antibiotics, like nystatin and filipin are known to interact with sterols, with some specificity for ergosterol thereby causing leakage of essential components and cell death. The mode of action of natamycin is unknown and is investigated in this study using different in vitro and in vivo approaches. Isothermal titration calorimetry and direct binding studies revealed that natamycin binds specifically to ergosterol present in model membranes. Yeast sterol biosynthetic mutants revealed the importance of the double bonds in the B-ring of ergosterol for the natamycin-ergosterol interaction and the consecutive block of fungal growth. Surprisingly, in strong contrast to nystatin and filipin, natamycin did not change the permeability of the yeast plasma membrane under conditions that growth was blocked. Also, in ergosterol containing model membranes, natamycin did not cause a change in bilayer permeability. This demonstrates that natamycin acts via a novel mode of action and blocks fungal growth by binding specifically to ergosterol.     

Plant Lectins Induce the Production of a Phytoalexin in Pisum sativum

The effects of several plant lectins on the production of apea phytoalexin, pisatin, were examined. Con A, PHA, PNA andPSA each induced the production of pisatin in pea epicotyl tissues,demonstrating that plant lectins can act as elicitors. The productionof pisatin in response to PHA, PNA or PSA was not affected bythe simultaneous presence of the respective hapten sugars, whereashaptens specific for Con A, such as -D-mannose and methyl--D-mannoside,abolished the induction of pisatin by Con A. These results indicatethat the elicitor effect of Con A is attributable to its abilityto bind to specific carbohydrates in pea cells. Induction ofthe production of pisatin by Con A was markedly inhibited bythe suppressor derived from a pea pathogen, Mycosphaerella pinodes,and by several inhibitors related to signal-transduction pathways.It is suggested, therefore, that the Con A-induced productionof pisatin in pea tissues might be associated with activationof a signal-transduction pathway. An additive effect on theaccumulation of pisatin was observed when Con A was presentwith a polysaccharide elicitor from M. pinodes, suggesting thatexogenous Con A does not compete with the recognition site(s)for the fungal elicitor in pea cells. The present data alsoindicate that Con A may be useful for characterization of thesignal-transduction system that leads to the synthesis of phytoalexinin pea epicotyl tissues. (Received November 16, 1994; Accepted April 20, 1995)     

Study of the action of nystatin on the plasmatic membranes of the liver of rabbits]

The effect of mystatin on the plasmic membranes of the rabbit liver after intravenous administration of the antibiotic to the animals in a dose of 5 mg/kg was studied. It was found that intravenous administration of nystatin had no effect on the quantitative content of protein, lipids and nucleic acids in the plasmic membranes of the liver. The method of electrophoresis in polyacrylamide gel revealed significant changes in the composition of the liver membrane protein due to the treatment with nystatin. The effect of nystatin on the composition of lipids and fatty acids contained in the membrane lipids was also investigated. The data of the thin layer chromatography showed that nystatin did not affect the qualitative composition and the content of separate lipid fractions in the lipids of the liver plasmic membranes. However, the fatty acid analysis of the membrane lipids after intravenous administration of nystatin revealed a number of qualitative and quantitative differences in the composition of the lipid fatty acids of the membranes tested. The results showed that nystatin affected the membrane structures of the rabbit liver cells.