Competitive binding of cholesterol and ergosterol to the polyene antibiotic nystatin. A fluorescence study

Competition studies between cholesterol and ergosterol were carried out to gain insight into the binding interactions between nystatin and these sterols. Lipid vesicles were prepared with mixtures of palmitoyloleoylphosphocholine/ergosterol/cholesterol, and both sterol molar ratio and total content were varied. The inhibitory effect of cholesterol toward the ergosterol ability to induce the formation of long-lived fluorescent antibiotic species was used to detect nystatin-cholesterol interactions. It was found that the key factor controlling nystatin photophysical properties in the ternary lipid mixtures was their ergosterol/cholesterol molar ratio and not their overall sterol content. Moreover, permeabilization studies showed that nystatin was able to form pores in all the mixed vesicles, but the initial rate of pore formation was also dependent on the ergosterol/cholesterol molar ratio. Our data show that ergosterol is displaced by competing cholesterol, indirectly confirming cholesterol's ability to coassemble with nystatin. The distinct spectroscopic properties emphasize the different molecular architecture adopted by nystatin-cholesterol and -ergosterol complexes, and therefore are relevant to understanding the interaction of the antibiotic with membranes.     

Nystatin-induced lipid vesicles permeabilization is strongly dependent on sterol structure

The selectivity of the antibiotic nystatin towards ergosterol compared to cholesterol is believed to be a crucial factor in its specificity for fungi. In order to define the structural features of sterols that control this effect, nystatin interaction with ergosterol-, cholesterol-, brassicasterol- and 7-dehydrocholesterol-containing palmitoyloleoylphosphocholine vesicles was studied by fluorescence spectroscopy. Variations in sterol structure were correlated with their effect on nystatin photophysical and activity properties. Substitution of cholesterol by either 7-dehydrocholesterol or brassicasterol enhance nystatin ability to dissipate a transmembrane K⁺ gradient, showing that the presence of additional double bonds in these sterols-carbon C7 and C22, plus an additional methyl group on C-24, respectively-as compared to cholesterol, is fundamental for nystatin-sterol interaction. However, both modifications of the cholesterol molecule, like in the fungal sterol ergosterol, are critical for the formation of very compact nystatin oligomers in the lipid bilayer that present a long mean fluorescence lifetime and induce a very fast transmembrane dissipation. These observations are relevant to the molecular mechanism underlying the high selectivity presented by nystatin towards fungal cells (with ergosterol) as compared to mammalian cells (with cholesterol).     

Nystatin-induced lipid vesicles permeabilization is strongly dependent on sterol structure

The selectivity of the antibiotic nystatin towards ergosterol compared to cholesterol is believed to be a crucial factor in its specificity for fungi. In order to define the structural features of sterols that control this effect, nystatin interaction with ergosterol-, cholesterol-, brassicasterol- and 7-dehydrocholesterol-containing palmitoyloleoylphosphocholine vesicles was studied by fluorescence spectroscopy. Variations in sterol structure were correlated with their effect on nystatin photophysical and activity properties. Substitution of cholesterol by either 7-dehydrocholesterol or brassicasterol enhance nystatin ability to dissipate a transmembrane K+ gradient, showing that the presence of additional double bonds in these sterols-carbon C7 and C22, plus an additional methyl group on C-24, respectively-as compared to cholesterol, is fundamental for nystatin-sterol interaction. However, both modifications of the cholesterol molecule, like in the fungal sterol ergosterol, are critical for the formation of very compact nystatin oligomers in the lipid bilayer that present a long mean fluorescence lifetime and induce a very fast transmembrane dissipation. These observations are relevant to the molecular mechanism underlying the high selectivity presented by nystatin towards fungal cells (with ergosterol) as compared to mammalian cells (with cholesterol).     

The ergosterol biosynthesis inhibitor zaragozic acid promotes vacuolar degradation of the tryptophan permease Tat2p in yeast

Ergosterol is the yeast functional equivalent of cholesterol in mammalian cells. Deletion of the ERG6 gene, which encodes an enzyme catalyzing a late step of ergosterol biosynthesis, impedes targeting of the tryptophan permease Tat2p to the plasma membrane, but does not promote vacuolar degradation. It is unknown whether similar features appear when other steps of ergosterol biogenesis are inhibited. We show herein that the ergosterol biosynthesis inhibitor zaragozic acid (ZA) evoked massive vacuolar degradation of Tat2p, accompanied by a decrease in tryptophan uptake. ZA inhibits squalene synthetase (SQS, EC 2.5.1.21), which catalyzes the first committed step in the formation of cholesterol/ergosterol. The degradation of Tat2p was dependent on the Rsp5p-mediated ubiquitination of Tat2p and was not suppressed by deletions of VPS1, VPS27, VPS45 or PEP12. We will discuss ZA-mediated Tat2p degradation in the context of lipid rafts.     

Susceptibilities of phospholipid membranes containing cholesterol or ergosterol to gramicidin and its derivative incorporated in lysophospholipid micelles

Complex formation of gramicidin (GA) and desformylgramicidin (des-GA) with sterols was investigated by measuring the intrinsic Trp fluorescence. In organic solvents, the Trp fluorescence of momeric GA was quenched upon binding either cholesterol or ergosterol, but that of monomeric des-GA was not quenched by adding cholesterol. Both dimeric GA and des-GA bound highly to ergosterol, but not to cholesterol, determined by quenching of Trp fluorescence. Furthermore, GA- and des-GA-loaded lysophosphatidylcholine micelles were incubated with phosphatidylcholine vesicles containing cholesterol or ergosterol. The results showed that both monomeric and dimeric peptides hardly bound to cholesterol incorporated into phospholipid vesicles, but markedly bound to ergosterol incorporated into the bilayer membranes. Interestingly, des-GA bound more specifically to the two sterols than GA. In addition, fluorescence resonance energy transfer analysis showed that des-GA bound more specifically to the two sterol than GA.     

Cholesterol, lanosterol, and ergosterol attenuate the membrane association of LL-37(W27F) and temporin L

Sterols impart significant changes to the biophysical properties of lipid bilayers. In this regard the impact of cholesterol on membrane organization and dynamics is particularly well documented and serves for comparison with other sterols. However, the factors underlying the molecular evolution of cholesterol remain enigmatic. To this end, cholesterol attenuates membrane perturbation by the so-called antimicrobial peptides (AMPs), produced ubiquitously by eukaryotic cells to combat bacterial infections by compromising the permeability barrier function of the microbial target membranes. In the present study, we addressed the effects of cholesterol, ergosterol, and lanosterol on the membrane association of two structurally and functionally diverse AMPs viz. LL-37(F27W) and temporin L (TemL) using fluorescence spectroscopy. Interestingly, sterol concentration dependent effects on the membrane association of these peptides were observed. At X(Sterol)=0.5 cholesterol was most effective in reducing the membrane intercalation of both LL-37(F27W) and TemL, the corresponding efficiencies of the three sterols decreasing as cholesterol>lanosterol> or =ergosterol, and cholesterol>lanosterol>ergosterol. It is conceivable that part of the selection pressure for the chemical evolution of cholesterol may have derived from the ability to protect the AMP-secreting host cell from the membrane damaging action of the antimicrobial peptides.     

Influence of cholesterol and ergosterol on membrane dynamics: a fluorescence approach

Sterols are essential membrane components of eukaryotic cells and are important for membrane organization and function. Cholesterol is the most representative sterol present in higher eukaryotes. It is often found distributed non-randomly in domains or pools in biological and model membranes. Cholesterol-rich functional microdomains (lipid rafts) are often implicated in cell signaling and membrane traffic. Interestingly, lipid rafts have also recently been isolated from organisms such as yeast and Drosophila, which have ergosterol as their major sterol component. Although detailed biophysical characterization of the effect of cholesterol on membranes is well documented, the effect of ergosterol on the organization and dynamics of membranes is not very clear. We have monitored the effect of cholesterol and ergosterol on the dynamic properties of both fluid (POPC) and gel (DPPC) phase membranes utilizing the environment-sensitive fluorescent membrane probe DPH. Our results from steady state and time-resolved fluorescence measurements show, for the first time, differential effects of ergosterol and cholesterol toward membrane organization. These novel results are relevant in the context of lipid rafts in ergosterol-containing organisms such as Drosophila which maintain a low level of sterol compared to higher eukaryotes.     

Effect of aggregation of amphotericin B on lysophosphatidylcholine micelles as related to its complex formation with cholesterol or ergosterol

The effect of aggregation of amphotericin B (AmB), as well as the complex formation of AmB with cholesterol or ergosterol, was investigated in micelles and vesicles. AmB in lysophosphatidylcholine (LPC) micelles adopted a more favorable monomeric form than that in other drug formulations. At an LPC/AmB ratio of 200, AmB existed only in monomeric form. Such monomeric behavior is likely dependent upon the fluidity and size of the micelles. In LPC micelles composed of 90% monomeric AmB, AmB-ergosterol complex formation occurred with an increase in the sterol concentration, but the complex formation of AmB-cholesterol was slight. On the other hand, in LPC micelles composed of 40% monomeric AmB, the complex formation of AmB-cholesterol as well as AmB-ergosterol was extensive. These results suggest that the complex formation of AmB with both sterols is highly dependent upon the aggregated state of AmB. In addition, using monolayers, mixtures of AmB/LPC/ergosterol were became more stable with rising temperature, while the stability of mixtures of AmB/LPC/cholesterol remained unchanged, implying that complex formation of AmB with cholesterol is different from that of AmB with ergosterol.     

Location and regulation of early enzymes of sterol biosynthesis in yeast.

Acetoacetyl CoA thiolase and 3-hydroxy-3-methylglutaryl (HMG) CoA synthase were found almost entirely in the cytosol of Saccharomyces cerevisiae, whereas HMG CoA reductase was found almost entirely in mitochondria and further located in the matrix. Formation of all three enzymes was inhibited by cycloheximide, but not by chloramphenicol, indicating that they were synthesized in the cytosol. In anaerobically growing cells the levels of acetoacetyl CoA thiolase and HMG CoA synthase were decreased by ergosterol, whereas HMG CoA reductase levels were affected only slightly, suggesting that in yeast the enzymes responsible for synthesis of HMG CoA were regulated by ergosterol. Aerobically growing cells were essentially impermeable to ergosterol and cholesterol, whereas those growing anaerobically and requiring sterols were readily permeable. Mutants blocked in ergosterol formation were also permeable to sterols under aerobic conditions.     

Influence of cholesterol and ergosterol on membrane dynamics using different fluorescent reporter probes

Ergosterol is an evolutionary precursor of cholesterol and is the major sterol present in lower eukaryotes. Although detailed biophysical characterization of the effect of cholesterol on membranes is well documented, the effect of ergosterol on the organization and dynamics of membranes is still at a very early stage. We have monitored the effect of cholesterol and ergosterol on the dynamic properties of both fluid (POPC) and gel (DPPC) phase membranes utilizing fluorescent reporter probes pyrene and TMA-DPH. These results show, for the first time, the important differences on the effect of cholesterol and ergosterol in short-range ordering (reported by TMA-DPH) and long-range dynamics (reported by pyrene). In addition, pyrene vibronic peak intensity ratio provides information on polarity of the microenvironment experienced by the probe. These novel results are relevant in the context of membrane domains in ergosterol-containing organisms such as Drosophila which maintain a low level of sterol compared to higher eukaryotes.     

The ergosterol biosynthesis inhibitor zaragozic acid promotes vacuolar degradation of the tryptophan permease Tat2p in yeast

Ergosterol is the yeast functional equivalent of cholesterol in mammalian cells. Deletion of the ERG6 gene, which encodes an enzyme catalyzing a late step of ergosterol biosynthesis, impedes targeting of the tryptophan permease Tat2p to the plasma membrane, but does not promote vacuolar degradation. It is unknown whether similar features appear when other steps of ergosterol biogenesis are inhibited. We show herein that the ergosterol biosynthesis inhibitor zaragozic acid (ZA) evoked massive vacuolar degradation of Tat2p, accompanied by a decrease in tryptophan uptake. ZA inhibits squalene synthetase (SQS, EC 2.5.1.21), which catalyzes the first committed step in the formation of cholesterol/ergosterol. The degradation of Tat2p was dependent on the Rsp5p-mediated ubiquitination of Tat2p and was not suppressed by deletions of VPS1, VPS27, VPS45 or PEP12. We will discuss ZA-mediated Tat2p degradation in the context of lipid rafts.     

Sterol effects on phospholipid biosynthesis in the yeast strain GL7

Cells of the yeast sterol auxotroph GL7 were grown on either ergosterol or cholesterol to mid-logarithmic phase and total membrane fractions prepared. Activities of phospholipid biosynthetic enzymes in the two cell types were determined. The rates of phosphatidyl-ethanolamine-phosphatidyl-choline-N-methyl transferase and acyl-CoA-alpha-glycerol-3-phosphate transcylase were significantly greater in ergosterol-grown than in cholesterol-grown cells. These reactions were also inhibited by the polyene antibiotic filipin. By contrast the activities of long-chain fatty acyl-CoA synthetase, CTP-phosphatidate-cytidyl transferase, phosphatidylserine decarboxylase and of phosphatidylinositol synthetase were identical in the two (ergosterol and cholesterol) cultures and unaffected by filipin. The ergosterol effect on phosphatidyl-ethanolamine N-methyl transferase was greatest in cells harvested in early log phase, intermediate in the mid-log phase cells, and not significant in stationary phase cells.     

Effect of altered sterol levels on the transport of amino acids and membrane structure ofMicrosporum gypseum

Ergosterol and cholesterol supplementation resulted in a significant increase (1·5-fold) in the sterol content while phospholipid remained unaffected inMicrosporum gypseum. The levels of phosphatidylethanolamine and phosphatidylcholine increased in ergosterol supplemented cells. However, a decrease in phosphatidylcholine and an increase in phosphatidylethanolamine was observed in cholesterol grown cells. The ratio of unsaturated to saturated fatty acids decreased on ergosterol/cholesterol supplementation. The uptake of amino acids (lysine, glycine and aspartic acid) decreased in sterol supplemented cells. Studies with fluorescent probe l-anilinonaphthalene-8-sulfonate showed structural changes in membrane organisation as evident by increased number of binding sites in such cells.     

Sterol replacement in saccharomyces cerevisiae. Effect on cellular permeability and sensitivity to nystatin

More than 80% of the cellular ergosterol can be replaced by cholesterol in a sterol requiring mutant strain of Saccharomyces cerevisiae. The effect of this replacement, as well as the effect of sterol starvation on the uptake and exit of cytosine and α-aminoisobutyric acid (α-AIBA) was studied in an attempt to elucidate the role of sterols in cellular permeability. Neither the exit of cytosine nor the exit of α-AIBA was affected by changes in the sterol content of the cell. Cells grown on cholesterol or on ergosterol had very similar rates of cytosine uptake, but a lower rate was found for sterol-starved cells. This difference may be a consequence of the cellular growth rate. However, nystatin induces a much slower exit of α-AIBA in cells grown on cholesterol than in cells grown on ergosterol. This strongly suggests that a change in membrane structure has taken place.     

Determination of the orientation and dynamics of ergosterol in model membranes using uniform 13C labeling and dynamically averaged 13C chemical shift anisotropies as experimental restraints

A new strategy was established to determine the average orientation and dynamics of ergosterol in dimyristoylphosphatidylcholine model membranes. It is based on the analysis of chemical shift anisotropies (CSAs) averaged by the molecular dynamics. Static (13)C CSA tensors were computed by quantum chemistry, using the gauge-including atomic-orbital approach within Hartree-Fock theory. Uniformly (13)C-labeled ergosterol was purified from Pichia pastoris cells grown on labeled methanol. After reconstitution into dimyristoylphosphatidylcholine lipids, the complete (1)H and (13)C assignment of ergosterol's resonances was performed using a combination of magic-angle spinning two-dimensional experiments. Dynamically averaged CSAs were determined by standard side-band intensity analysis for isolated (13)C resonances (C(3) and ethylenic carbons) and by off-magic-angle spinning experiments for other carbons. A set of 18 constraints was thus obtained, from which the sterol's molecular order parameter and average orientation could be precisely defined. The validity of using computed CSAs in this strategy was verified on cholesterol model systems. This new method allowed us to quantify ergosterol's dynamics at three molar ratios: 16 mol % (Ld phase), 30 mol % (Lo phase), and 23 mol % (mixed phases). Contrary to cholesterol, ergosterol's molecular diffusion axis makes an important angle (14 degrees) with the inertial axis of the rigid four-ring system.     

Comparative molecular dynamics simulations of amphotericin B-cholesterol/ergosterol membrane channels

Amphotericin B (AmB) is a very effective anti-fungal polyene macrolide antibiotic whose usage is limited by its toxicity. Lack of a complete understanding of AmB's molecular mechanism has impeded attempts to design less toxic AmB derivatives. The antibiotic is known to interact with sterols present in the cell membrane to form ion channels that disrupt membrane function. The slightly higher affinity of AmB toward ergosterol (dominant sterol in fungal cells) than cholesterol (mammalian sterol) is regarded as the most essential factor on which antifungal chemotherapy is based. To study these differences at the molecular level, two realistic model membrane channels containing molecules of AmB, sterol (cholesterol or ergosterol), phospholipid, and water were studied by molecular dynamics (MD) simulations. Comparative analysis of the simulation data revealed that the sterol type has noticeable effect on the properties of AmB membrane channels. In addition to having a larger size, the AmB channel in the ergosterol-containing membrane has a more pronounced pattern of intermolecular hydrogen bonds. The interaction between the antibiotic and ergosterol is more specific than between the antibiotic and cholesterol. These observed differences suggest that the channel in the ergosterol-containing membrane is more stable and, due to its larger size, would have a higher ion conductance. These observations are in agreement with experiments.     

Cholesterol, lanosterol, and ergosterol attenuate the membrane association of LL-37(W27F) and temporin L

Sterols impart significant changes to the biophysical properties of lipid bilayers. In this regard the impact of cholesterol on membrane organization and dynamics is particularly well documented and serves for comparison with other sterols. However, the factors underlying the molecular evolution of cholesterol remain enigmatic. To this end, cholesterol attenuates membrane perturbation by the so-called antimicrobial peptides (AMPs), produced ubiquitously by eukaryotic cells to combat bacterial infections by compromising the permeability barrier function of the microbial target membranes. In the present study, we addressed the effects of cholesterol, ergosterol, and lanosterol on the membrane association of two structurally and functionally diverse AMPs viz. LL-37(F27W) and temporin L (TemL) using fluorescence spectroscopy. Interestingly, sterol concentration dependent effects on the membrane association of these peptides were observed. At X_Sterol = 0.5 cholesterol was most effective in reducing the membrane intercalation of both LL-37(F27W) and TemL, the corresponding efficiencies of the three sterols decreasing as cholesterol > lanosterol ≥ ergosterol, and cholesterol > lanosterol > ergosterol. It is conceivable that part of the selection pressure for the chemical evolution of cholesterol may have derived from the ability to protect the AMP-secreting host cell from the membrane damaging action of the antimicrobial peptides.     

Comparative molecular dynamics study of lipid membranes containing cholesterol and ergosterol

Sterol molecules are essential for maintaining the proper structure and function of eukaryotic cell membranes. The influence of cholesterol (the principal sterol of higher animals) on the lipid bilayer properties was extensively studied by both experimental and simulation methods. In contrast, the effect of ergosterol (the principal fungal sterol) on the membrane structure and dynamics is much less recognized. This work presents the results of comparative molecular dynamics simulation of the hydrated dimyristoylphosphatidylcholine bilayer containing approximately 25 mol % of cholesterol or ergosterol. A detailed analysis of the molecular properties (e.g., bilayer thickness, lipid order, diffusion, intermolecular interactions, etc.) of both sterol-induced liquid-ordered membrane phases is presented. Presence of sterols in the membrane significantly changes its property, especially fluidity and molecular packing. Moreover, in accordance with the experiments, our calculations show that, compared to cholesterol, ergosterol has higher ordering effect on the phospholipid acyl chains. This different influence on the properties of the lipid bilayer stems from differences in conformational freedom of sterol side chains. Additionally, obtained models of lipid membranes containing human and fungal sterols, constituting the result of our work, can be also utilized in other chemotherapeutic studies on interaction of selected ligands (e.g., antifungal compounds) with membranes.     

Comparative conformational analysis of cholesterol and ergosterol by molecular mechanics

A comparative conformational analysis of cholesterol and ergosterol has been carried out using molecular mechanics methods. These studies are aimed at giving a better understanding of the molecular nature of the interaction of these sterols with polyene macrolide antibiotics. Structures of cholesterol and ergosterol determined by X-ray methods have been used as initial geometries of these molecules for force field calculations. The calculation of steric energy has also been made for conformations which do not appear in the crystal. The latter conformers have different conformations of the side chain as well as different conformations of rings A and D. The rotational barriers around bonds C17–C20 and C20–C22 have also been calculated. The results obtained on differences and similarities in the conformations of cholesterol and ergosterol allow us to postulate a mechanism for differential interaction with the antibiotics. The relatively rigid side chain of ergosterol (stretched molecule) in comparison with the flexible side chain of cholesterol (bent molecule), allows better intermolecular contact of the first sterol molecule with a polyene macrolide and in consequence facilitates complex formation involving Van der Waal's forces.