Potential-dependent formation of single conducting ion channels in lipid bilayers induced by the polyene antibiotic levorin A2

The aromatic polyene antibiotic levorin A₂ forms ion channels permeable to monovalent cations, in lipid membranes containing cholesterol or ergosterol. Channel conductivity is in the range 0.3–0.5 pS. The channel has two main states: conducting (open) and nonconducting (closed). The potential-dependent formation of levorin A₂ channels is observed in lipid membranes. The system responsible for the ion-channel selectivity is localized on the hydrophilic side of the lactone ring of the polyene molecule.     

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.     

An aromatic heptaene antibiotic levorin and its derivatives in muscle activity]

The review is concerned with the outlooks for the use of levorin, a membrane active and channel forming polyene antibiotic, and its alkyl derivatives in muscle activity. In complex with cholesterol and ergosterol, the aromatic heptaene antibiotic levorin forms structural ionic channels of the molecular size in the lipid and cell membranes. Levorin increases the membrane permeability for monosucrose and other neutral molecules as follows: H2O > urea > acetamide > glycerine > ribose > arabinose > glucose > saccharose. As a channel forming compound, levorin is able to induce in the cell membranes of the muscle fibres formation of additional channels permeable for the cations and to increase the flow of the energy dependent substrates to the cells and the outburst of the metabolites from them during intensive muscle activity. Levorin several times decreases the surface tension of aqueous solutions. In some models of experimental animals levorin promoted an increase of the blood fluidity and accelerated the blood stream in the blood vessels both in rest and in muscle activity. Physical load in a high power zone increases the intensity of lipid peroxidation that results in fatigue and lower physical efficiency. Possible prevention of an increase of the rate of free radical reactions by levorin and its alkyl derivatives providing higher antioxidant protection is discussed.     

The Properties of Ion Channels in Lipid Membranes Modified by the Aromatic Antibiotic Levorin А2

It has been shown that the main components of levorin A, that is, A₀, A₁, A₂, or A₃, that contain an aromatic group increase the permeability of membranes in the series A₃ > A₂ > A₁ > A₀ when they are on the same side of the membrane. All levorin components have cationic selectivity. The most studied levorin, А₂, promotes the almost ideal permeability of membranes to potassium ions. The membrane potential for a ten-fold change in the KCl concentration gradient is 56 ± 2 mV. It has been shown that the injection of the same concentration of levorin А₂ into one side of the membrane and then, after achieving the typical membrane permeability, into the other side of the membrane generates a two-fold increase in the total membrane permeability. This means that independent levorin-induced conductive semi-pores are formed on each side of the membrane. It has been found that the injection of levorin А₂ only into one side of the membrane enhances the membrane permeability to monosaccharides and other neutral molecules. The presence of levorin А₂ in cholesterol-, ergosterol-, and stigmasterol-containing phospholipid membranes has been shown to lead to the single-channel conductivity of typical ion channels of 0.2–0.5 pS. The properties of these channels have been studied. The levorin channels exist in two states, open and closed. Most of the time, the channel remains in the open state in the KBr solution. In solutions of different salts of the same concentration, the conductivity value of the levorin channels is approximately the same (0.4–0.5 pS). An increase in the dimethyl sulfoxide concentration in aqueous solutions facilitates the transition of polyene antibiotic molecules from dispersed to monomolecular form. The molecules of polyene antibiotics in the associated form exhibit high membrane activity.

     

Composition of membranes and mycelia ofStreptomyces levoris at different stages of growth

The composition of cell membranes and mycelia ofStreptomyces levoris, producer of the polyene antibiotic levorin, was studied. The membrane protein/lipid ratio was shown to be constant during growth of the microorganism. The membrane protein was found to be heterogeneous and to have a low molecular weight. The lipid component of the membranes consisted mainly of polar lipids—phosphatidyl ethanolamine, diphosphatidyl glycerol, and phosphatidyl inositol mannoside being predominant. During growth, the phospholipid content of the polar lipid fraction decreased, apparently due to replacement of phospholipids by phosphorus-free analogs.     

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.     

Electrophoretic mobility of bimolecular lipid membranes

The floating membrane vesicle is fixed by the counter solution flow in different points along the radius of a cylinder electrophoretic chamber, which permits to measure the vesicle electrophoretic mobility (EM). Close state condition of the chamber is provided for by the capillary system successively connected with the chamber. Relationship between EM of bimolecular lipid membranes (BLM) and pH and ionic concentration of aqueous solution qualitatively coincides with similar relationship for liposomes. The EM value of BLM essentially decreases in solution containing polyene antibiotics nystatine and levorin when derivative of cholesterol having 3betaOH-groups is present in the membrane.     

Antibodies affect the ionic conductance of channels formed by amphotericin B in a lipid bilayer

For the first time poly- and monoclonal antibodies (class IgM) against the polyene antibiotic amphotericin B were obtained affecting the properties of a channel formed by the antibiotic and cholesterol in a lipid bilayer when amphotericin B was added to the solution at one (cis) side of the membrane. In the case of the symmetric distribution of cholesterol in the lipid bilayer, three molecules of monoclonal antibodies bind firmly to the channel at the trans-side of the membrane, thus strongly increasing the mean lifetime of the channel in the open state, and not changing practically the ion conductance of its open state. The antibodies did not alter the properties of these channels when added at the cis-side of the membrane as well as of the channels formed in the lipid bilayer when amphotericin B was added at both membrane sides. The antibodies obtained did not affect the conductance of channels in which amphotericin B and cholesterol were replaced with their analogs levorin and 5 alpha-androstan-3 beta-one, which points to a high specificity of the immunoglobulins isolated. When cholesterol was present only in the cis-monolayer of the lipid bilayer and was absent in the trans-monolayer, the same monoclonal antibodies when added at the trans-side of the membrane blocked the conductance of the channel formed by adding the antibiotic to the solution at the cis-side of the bilayer. The obtained evidence is of interest in elucidating the general features of interaction of antibodies with the ionic channels of cellular and model membranes.     

Characteristics of diffusion of polyene antibiotic levorin

Studies were performed which provided estimation of the impact of some physico-chemical properties of levorin, a polyene antibiotic, and in particular its multicomponent nature and capacity for isomerization on formation of inhibition zones in assay of the antibiotic activity by the agar diffusion method. It was shown that the levorin complex components markedly differed in the biological activity and diffusion capacity. The diffusive properties of the highly active components A2 and A3 were better. The diffusion rate of isomerized levorin was much lower than that of the initial levorin. To provide better diffusion of the levorin components with low diffusion capacity it was recommended to use a new solution composed of ethanol, glycerol and water at a ratio of 15:25:60.     

Biochemical analysis of the microvillose membranes of the small intestine mucosa of dogs after levorin administration

The effect of oral levorin used for a prolonged period of time on the lipid composition and activity of alkaline phosphatase and invertase of the microvilli membranes of the small intestinal enterocytes of old dogs was studied. Higher ratios of cholesterol/phospholipids in the membranes and inactivation of alkaline phosphatase and invertase were noted in the old dogs as compared to the young ones. Exposure of the old dogs to levorin had a significant effect on the microvilli membranes of the intestinal epithelial cells. It was evident from a lower ratio of cholesterol/phospholipids in the membranes and stimulation of the alkaline phosphatase activity. It is supposed that the changes in the state of the microvilli membranes of the small intestinal mucosa due to levorin play a definite role in the mechanism of its hypercholesterolemic action.     

Interrelationship of polyphosphate metabolism and levorin biosynthesis in Streptomyces levoris

The effect of inorganic phosphate on biosynthesis of the polyene antibiotic levorin by Streptomyces levoris was studied. At phosphate concentration of 4.0 mM levorin biosynthesis is repressed by 90%, resulting in an increase of ATP and a condensed inorganic polyphosphates content in the producer cells. At phosphate concentration optimal for levorin production (0.04 mM) the level of intracellular ATP sharply falls by the beginning of the steady-state phase of the producer growth and that of polyphosphates decreases 3-6-fold. The inorganic phosphate exerts different effects on polyphosphate metabolism enzymes, such as polyphosphate: D-glucose-6-phosphotransferase, polyphosphate phosphohydrolase, tripolyphosphate phosphohydrolase, pyrophosphate phosphohydrolase, alkaline and acid phosphatase. The strongest effect of phosphate excess is observed in the case of polyphosphate: D-glucose-6-phosphotransferase, whose activity decreases 2-5-fold. The activity of this enzyme was shown to be correlated with the antibiotic accumulation. The data obtained are indicative of interrelationship between the polyphosphate metabolism and levorin biosynthesis.     

Structure of planar membrane formed from liposomes

Lipid vesicles with incorporated ion channels from polyene antibiotic amphotericin B were used to investigate structures of planar membranes formed by Shindler's techniques. A planar membrane assembled on the aperture in a lavsan film from two layers generated at the air-aqueous liposome suspension interface is not a simple bilayer but a bimolecular membrane containing numerous partly fused liposomes. A complete fusion of liposomal membranes with the planar bilayer is an unlikely event during membrane formation. A planar bimolecular lipid membrane without incorporated liposomes can be made by a method consisting of three stages: formation of a lipid layer on the air-water interface of a suspension containing liposomes, transfer of this layer along the surface of the solution into a chamber containing a solution without liposomes where a lipid monomolecular layer forms gradually (within about 20 min) at the air-water interface, assembling of the planar bilayer membrane from this monolayer. The knowledge of the planar membrane structure may be useful in experiments on incorporation of membrane proteins into a planar lipid bilayer.     

Effect of Membrane Structure on the Action of Polyenes II: Nystatin Activity along the Phase Diagram of Ergosterol- and Cholesterol-Containing POPC Membranes

Pores formed by the polyene antibiotic nystatin were studied in solvent-free lipid membranes. The membranes were formed by the tip-dip technique using 1-palmitoyl-2-oleoyl-sn-glycero-3-phosphocholine (POPC) with different mol fractions (0–50%) of cholesterol or ergosterol. The effects of the mol fraction of sterol and of temperature variation (15–35°C) on the activity of the pores, their unitary conductances, lifetimes and time average conductances were studied. The results were used to analyze the behavior of nystatin channels along the phase diagrams previously reported for these lipid mixtures and to propose that membrane structure is the determinant factor for the known ergosterol/cholesterol selectivity.     

Interaction of local anesthetics with bilayer phospholipid membranes

Local anesthetics--cocaine, lidocaine, novocaine were tested for conductivity of bilayer lipid membranes containing anion-selective channels formed by polyene antibiotic amphotericin B. It has been shown that 5 X 10(-4) M cocaine doubles the membrane conductance. The line of efficiency of the tested anesthetics is: cocaine greater than lidocaine greater than novocaine. Possible molecular mechanism of the discovered effect is discussed.     

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.     

The nature of the conductance increase induced by filipin in cholesterol-containing planar lipid bilayers

The effects of the polyene antibiotic filipin on the conductance and permeability of planar lipid bilayers were investigated under voltage-clamp conditions. The membrane conductance of lipid bilayers containing no cholesterol was not affected by filipin. In the presence of cholesterol containing lipid bilayers, filipin induced a 10(4)-10(5)-fold increase in transmembrane conductance. This conductance increase was dependent on the ionic species present in solution, decreasing in the following order: GCsCl greater than GNaAc greater than GKCl greater than GNaCl greater than CaCl2 greater than GNa2SO4 greater than GBaCl2 greater than GMgCl2. Reversal potential measurements in simple biionic conditions revealed the following relative permeability sequence: PK greater than PCl greater than PNa approximately Pac approximately PBa greater than PCs greater than PMg approximately PCa greater than Psulphate. The filipin-sterol mediated increase in membrane conductance was independent of the membrane potential. The increase in membrane current following a step alteration in membrane potential occurred instantaneously and had no dependence on the previous value of the holding membrane potential. We propose that the filipin-sterol complex forms ion channels in lipid membranes. These channels are found in a single configuration (open state) and select preferentially monovalent cations or anions over divalent ions. Our experimental results are discussed in relation to the effects of other polyene antibiotics on the membrane permeability, and also in relation to experimental problems previously reported with the use of filipin in planar lipid bilayers.     

Mechanism of the effect of levorin on transport of amino acids inCandida albicans

By use of incubation media of various ionic compositions and pH's, it was possible to reveal that inhibition of the transport of neutral amino acids having long hydrophobic chains (leucine, phenylalanine) inCandida albicans by the polyene antibiotic levorin was mainly due to redistribution—caused by the antibiotic—of monovalent cations in the cells and protoplasts of the yeast. In an acidic medium, levorin was also found to induce a decrease of proton release from the cells, accompanied by some inhibition of leucine transport. Transport of neutral amino acids having short hydrophobic chains (alanine, glycine, proline) was inhibited by this polyene antibiotic, irrespective of the ionic composition or pH of the medium.     

Radioprotective and antineoplastic activity of polyene antibiotics combined with dimethyl sulfoxide]

Radioprotective and antineoplastic activity of polyene, its derivatives and combinations with dimethyl sulfoxide (DMSO) was studied. The most potent radioprotective effect was demonstrated by methylated levorin, original levorin and by its isomer--isolevorin. Survival rate of the animals on 12th day after X-ray exposure was 100, 60, 60 per cent, at the control group 33.6, 20 and 0 per cent consequently. Levorin and alkyl derivatives of amphotericin B--methamphocin and buthamphocin inhibited growth of ascites and solid tumors to 46.3-79.0 per cent when compared to control group. Polyen antibiotics combined with DMSO also demonstrated antineoplastic activity at the animals treated with carcinogenic agent--diethyl nitrosoamine (DENA). 5-month survival of the animals was 76 per cent at nystatin and levorin group and 35.7 per cent at the control group (animals treated with DENA only).     

Mechanism of blockage of amphotericin B channels in a lipid bilayer.

A number of organic compounds (non-electrolytes, tetraalkylammonia, etc.) with a molecular size of 6--8 angstrom decrease the conductance of ionic channels formed in the lipid bilayer by a polyene antibiotic amphotericin B. It is suggested that these compounds, upon entering the channel, block the passage of inorganic ions. The extent of conductance blockage by organic ions depends on the membrane potential and electrolyte concentration. In the presence of ionic blockers, for instance tetraethylammonium, amphotericin B-containing membranes assume some properties characteristic of excitable membranes, i.e. the current-voltage characteristic acquires the negative resistance region, and in response to a potential step activation followed by inactivation of conductance is observed. It is shown that the potential dependence of the blockage is due to interaction inside the channel of the blocker ion with penetrating ions, by a mechanism similar to that described by Armstrong ((1979) Q. Rev. Biophys. 7, 179--210) for blockage of squid axon potassium channels by ammonium derivatives.     

Action of polyene antibiotics on ribosome binding with Candida albicans membranes]

The effect of treatment of the protoplasts and cell membranes of C. albicans with polyenic entibiotics on formation of the ribosomal-membrane complex was studied in vitro. It was shown that amphotericin B and nystatin had no effect on this process. Significant suppression of the ribosome binding with the membranes was observed only in vivo in the presence of levorin. The role of the structural changes occurring in the membranes on formation of the polyen-sterol complex, as well as the role of the lipid components of the membrane in binding of the ribosomes is discussed.