Interactions of the lipopeptide antifungal iturin A with lipids in mixed monolayers

The miscibility and the interactions of the antifungal lipopeptide iturin A with lipids, DMPC and cholesterol, are studied in monolayers at the air/water interface and a comparison of the respective behaviour of iturin A and the biologically inactive methylated derivative MeTyr-iturin A is made. Each lipopeptide is miscible with anyone of the lipids. This behaviour is revealed by the dependence of the transition pressure upon composition and by deviations from the additivity rule of the mean molecular area. The thermodynamic properties of the mixed systems are studied by the method of Goodrich. The mixed monolayers are always more stable than the two separate components, subsequently there are interactions between the components. However, the excess free energy of mixing delta Gexm is positive for the iturin A/DMPC system which is an indication that the interactions between lipopeptide and lipid molecules are weaker than the interactions between the pure components themselves. This is compatible with the presence of self-associated lipopeptide molecules. However, delta Gexm is highly negative for the iturin A/cholesterol system giving evidence of the formation of a specific complex between iturin A and cholesterol which is not the case with the methylated derivative. These data are analysed in connection with previous results concerning the pore-forming properties of these lipopeptides and the lack of biological activity of MeTyr-iturin A.     

Aggregational behavior of aqueous dispersions of the antifungal lipopeptide iturin A

Iturin A, a lipopeptide isolated from Bacillus subtilis, possesses a strong antifungal activity, and has been devoted to a great deal of attention. Since iturin is an amphiphilic compound with a great propensity to self-associate in solution as well as inside the membrane, the question arises to whether its aggregational behavior is dependent on the concentration of the lipopeptide. In order to test this, the ability of iturin suspensions to encapsulate water-soluble molecules has been examined. Iturin was dispersed at different concentrations above its critical micellar concentration, in a buffer containing the water-soluble dye 5,6-carboxyfluorescein. For iturin A micelles, a Stokes radius of 1.3 nm and an aggregational number of 7 was obtained. The results shown in this work clearly demonstrate that iturin dispersions in water, at concentrations of 0.7, 1.4 and 3 mM, i.e. far above the critical micellar concentration (40 microM), are capable of encapsulating carboxyfluorescein, probably by adopting a type of aggregate different from the micelle. Negative-staining electron microscopy shows the presence of vesicles with an average size of 150 nm. By using (14)C-iturin, it is shown that, at 3 mM concentration, 40 % of the iturin molecules adopt this vesicular state. It is proposed that iturin molecules form a fully interdigitated bilayer, where each hydrocarbon tail span the entire hydrocarbon width of the bilayer, resulting in multilamellar vesicles capable of encapsulating an aqueous compartment. The possible implications of these results to the membrane destabilizing effect of iturin A, are discussed according to the dynamic cone-shape of the iturin molecule.     

Quantification of the antifungal lipopeptide iturin A by high performance liquid chromatography coupled with aqueous two-phase extraction

Iturin A, a powerful antifungal surfactant, is a kind of bacterial lipopeptide produced by Bacillus strains. This study addresses the use of an aqueous two-phase system (ATPS) using ethanol/ammonium sulfate to extract iturin A from Bacillus amyloliquefaciens NJN-6 fermentation broth and the quantification of iturin A by HPLC. Baseline separation of iturin A homologues was performed using an RP-C(18) column with a mixture of water and acetonitrile. The results showed that the correlation coefficient between integral area and concentration was 0.9961 within the range of 20-140 mg/l. The RSD of the retention time and the peak area were 1.29% and 1.45%, respectively. The effects of some operating parameters in ATPS, e.g., pH, temperature and centrifugation time, were also studied. This method can be successfully used for the rapid quantification of iturin A.     

A biophysical study of the interaction of the lipopeptide antibiotic iturin A with aqueous phospholipid bilayers

Iturin A is a lipopeptide extracted from the culture media of Bacillus subtilis which shows a strong antifungal action. The interaction of iturin A with multilamellar vesicles of dimyristoylphosphatidylcholine (DMPC) induced structures which did not sediment during centrifugation. Electron microscopy after negative staining showed that, at 30 mol%, iturin A/DMPC vesicles were visible but smaller than those formed by pure DMPC. Thermograms of DMPC/iturinA obtained after differential scanning calorimetry, at low concentrations of iturin A, were interpreted as indicating the presence of two laterally separated phases, one formed by pure phospholipid and the other by lipopeptide-phospholipid complexes, these two separated phases being already detected even at low concentrations such as 2 mol%. Fluorescence quenching experiments showed that the D-Tyr residue of the lipopeptide was fully accessible to the aqueous medium, indicating that the polar part of iturin A is located outside of the membrane hydrophobic palisade. It was concluded that the membrane barrier properties are likely to be damaged in the area where the lipid complexes are accumulated, due to structural fluctuations, and this may be one of the bases of its biological activity. Iturin-A was also able to greatly destabilize dielaidoylphosphatidylethanolamine (DEPE) membranes in the fluid form, producing a new structure which had a poor correlation in X-ray diffraction, and in 31P NMR spectroscopy gave rise to a spectrum containing a double isotropic signal. Iturin A was shown to induce DEPE to adopt phases other than H(II) inverted hexagonal, underlining that this lipopeptide is capable of modifying the curvature of the membrane, which may also be important in explaining the tendency of iturin A to create small vesicles and which may be another of the bases of its biological activity.     

The interaction of analogues of the antimicrobial lipopeptide, iturin A2, with alkali metal ions

Electrospray mass spectrometry was employed as a tool in this first study on the molecular interaction between the alkali metal ions and antifungal lipopeptide iturin A, and some analogues. Cationisation by sodium and signal intensity of lipopeptide species depended on sodium concentration, but was independent of sample solvent, carrier solvent polarity and sample pH between 4 and 11. 8-Beta, a linear analogue of iturin A2 (8-Beta; beta-aminotetradecanoyl-NYNQPNS), and its shorter linear lipopeptide analogues, associated either one or two alkali metal cations, while the N-->C cyclic peptides associated with only one cation. The chirality of the beta-NC14 residue had a limited influence on the cationisation. It was observed that 8-Beta contained at least four interaction sites for a cation of which two, the C-terminal carboxylate and the side-chain of tyrosine, can take part in ionic interaction with a cation. It is proposed that the remaining two interaction centres of alkali metal ions are within the two type II beta-turns found in conformation of natural iturin A. This was corroborated by the diminished capacity of the shorter peptides, in which one of the beta-turns was eliminated to bind a second larger cation. All the lipopeptides showed the same order of alkali metal ion selectivity: Na+ > K+ > Rb+. These results indicated a size limitation in the interaction cavity or cavities. The absence of, or observation of only low abundance, di-cationised complexes of cyclic peptides the indicated association of the cation in the interior of the peptide ring. It is thus hypothesised that alkali metal ions can bind in one of the two beta-turns in the natural iturin A molecule.     

Pore-forming properties of iturin A, a lipopeptide antibiotic

The addition of iturin A, a lipopeptide antibiotic extracted from Bacillus subtilis, to a bimolecular lipid membrane (BLM) increases dramatically its electrical conductance. For very low concentration of iturin A, discrete conductance steps are observed which are assigned to the formation of conducting pores. The characteristics of these pores depend on the lipid content of the BLM and they change with time. Cholesterol considerably increases the lifetimes of open states. The pores are slightly anion versus cation selective. These first observations unable us to briefly discuss the pore-forming properties of lipopeptides.     

产表面活性素和伊枯草菌素A菌株的筛选及其脂肽类产物的特性

采用血琼脂平板法, 从菜园土壤中分离到8株代谢表面活性剂的菌株, 比较各菌株的排油性、抑菌性, 根据合成脂肽类物质表面活性素(Surfactin)和伊枯草菌素A (Iturin A)必需的sfp、ituD和lpa-14基因设计引物, 结合PCR的方法筛选到一株具广谱抗菌性且含有sfp、ituD和lpa-14 3个关键基因的细菌XZ-173。经过生理生化试验测定和16S rDNA序列系统发育学分析, 将其鉴定为解淀粉芽孢杆菌(Bacillus amyloliquefaciens)。通过红外光谱(FT-IR)分析该菌株代谢产物, 初步鉴定为脂肽类物质, 并对照高效液相色谱(HPLC)与标准品比对结果, 确定含有Surfactin和Iturin A组分。该菌株产生的脂肽粗品能使纯水的表面张力降低至26.6 mN/m, 临界胶束浓度(CMC)为500 mg/L, 具有很好的乳化性能, 对立枯丝核菌和青枯菌表现出很好的拮抗活性。因此, 产脂肽细菌XZ-173是一株应用前景广阔的功能菌。     

Further aspects on the hemolytic activity of the antibiotic lipopeptide iturin A

The bacterial lipopeptide iturin A is able to cause hemolysis of human erythrocytes in a dose-dependent manner. Hemolysis takes place at iturin concentrations below its critical micellar concentration. Relative kinetics determinations clearly show that K(+) leakage occurs prior to hemoglobin release. Furthermore, hemolysis can be prevented by addition to the outer solution of osmotic protectants of appropriate size. Altogether these results indicate that iturin A-induced hemolysis follows a colloid-osmotic mechanism, with the formation of a membrane pore of average diameter 32 A. Iturin A is capable of inducing leakage of an aqueous fluorescent probe trapped in human erythrocyte ghosts, but not in large unilamellar liposomes made of various lipid compositions. The different permeabilizing effects of iturin A on model and biological membranes are discussed on the light of the presented results.     

Further aspects on the hemolytic activity of the antibiotic lipopeptide iturin A

The bacterial lipopeptide iturin A is able to cause hemolysis of human erythrocytes in a dose-dependent manner. Hemolysis takes place at iturin concentrations below its critical micellar concentration. Relative kinetics determinations clearly show that K⁺ leakage occurs prior to hemoglobin release. Furthermore, hemolysis can be prevented by addition to the outer solution of osmotic protectants of appropriate size. Altogether these results indicate that iturin A-induced hemolysis follows a colloid-osmotic mechanism, with the formation of a membrane pore of average diameter 32 Å. Iturin A is capable of inducing leakage of an aqueous fluorescent probe trapped in human erythrocyte ghosts, but not in large unilamellar liposomes made of various lipid compositions. The different permeabilizing effects of iturin A on model and biological membranes are discussed on the light of the presented results.     

Production of lipopeptide antibiotic iturin A using soybean curd residue cultivated with Bacillus subtilis in solid-state fermentation

Bacillus subtilis RB14-CS, which suppresses the growth of various plant pathogens in vitro by producing the lipopeptide antibiotic iturin A, was cultured using soybean curd residue, okara, a by-product of tofu manufacture in solid-state fermentation. After 4 days incubation, iturin A production reached 3,300 mg/kg wet solid material (14 g/kg dry solid material), which is approximately tenfold higher than that in submerged fermentation. When the okara product cultured with RB14-CS was introduced into soil infested with Rhizoctonia solani, which is a causal agent of damping-off of tomato, the disease occurrence was significantly suppressed. After 14 days, the number of RB14-CS cells remained in soil at the initial level, whereas almost no iturin A was detected in soil. As the okara cultured with RB14-CS exhibited functions of both plant disease suppression and nutritional effect on tomato seedlings, this product is expected to contribute to the recycling of the soybean curd residue.     

Study of the Antifungal Ability of Bacillus subtilis Strain PY-1 in Vitro and Identification of its Antifungal Substance （Iturin A）

A Bacillus strain,denoted as PY-1,was isolated from the vascular bundle of cotton.Biochemical,physiological and 16S rDNA sequence analysis proved that it should belong to Bacillus subtilis.The PY-1strain showed strong ability against many common plant fungal pathogens in vitro.The antibiotics producedby this strain were stable in neutral and basic conditions,and not sensitive to high temperature.From theculture broth of PY-1 strain,five antifungal compounds were isolated by acidic precipitation,methanolextraction,gel filtration and reverse-phase HPLC.Advanced identification was performed by mass spec-trometry and nuclear magnetic resonance spectroscopy.These five antifungal compounds were proved to bethe isomers of iturin A:A2,A3,A4,A6 and A7.In fast atom bombardment mass spectrometry/mass spec-trometry collision-induced dissociation spectra,fragmentation ions from two prior linear acylium ions wereobserved,and the prior ion,Tyr-Asn-Gln-Pro-Asn-Ser-βAA-Asn-CO~ ,was first reported.     

Interaction of iturin A, a lipopeptide antibiotic, with Saccharomyces cerevisiae cells: influence of the sterol membrane composition

The binding of the membrane-active lipopeptide antibiotic iturin A to yeast cells was studied using radioactive iturin A. Saccharomyces cerevisiae had a maximum binding capacity of 5.6 x 10(9) molecules per single cell. The Scatchard plot of binding showed a biphasic profile, with a lower dissociation constant for small concentrations of iturin A. The break of slope at 30 microM iturin A corresponds to the micellization of antibiotic in solution. The binding is also dependent on the nature of the sterol present in the membrane. A mutant yeast strain with a membrane containing cholesterol instead of ergosterol showed the highest affinity for iturin A and the highest sensitivity to this antibiotic, as measured by K+ ion release. In contrast the presence of stigmasterol increased the resistance of the cells to iturin A.     

Bacillomycin D: an iturin with antifungal activity against Aspergillus flavus

AIMS: In a search for an antifungal peptide with a high activity against Aspergillus flavus, Bacillus subtilis AU195 was selected from a collection of isolates with antagonistic activity against A. flavus. METHODS AND RESULTS: To identify the antifungal peptides, a protein purification scheme was developed based on the detection of the antifungal activity in purified fractions against A. flavus. Two lipopeptides were purified with anion exchange and gel filtration chromatography. Their masses were determined to be 1045 and 1059 m/z with mass spectrometry, and their peptide moiety was identical to bacillomycin D. CONCLUSION: AU195 synthesized a mixture of two antifungal bacillomycin D analogues with masses of 1045 and 1059, the 14 mass unit difference representing the difference between a C15 and a C16 lipid chain. SIGNIFICANCE AND IMPACT OF THE STUDY: Both bacillomycin D analogues were active at the same concentration against A. flavus, but the different lipid chain length apparently affected the activity of the lipopeptide against other fungi.     

Effect of the lipopeptide antibiotic, iturin A, on morphology and membrane ultrastructure of yeast cells

Abstract The effects of iturin A, at fungicidal concentrations, on yeast cells were studied by scanning electron microscopy and by transmission electron microscopy. A depression, observed in each iturin A-treated cell, was the consequence of the release of electrolytes and other cytoplasmic components. Iturin A passes through the cell wall and disrupts the plasma membrane with the formation of small vesicles and the aggregation of intramembranous particles. Moreover, iturin A passes through the plasma membrane and interacts with the nuclear membrane and probably with membranes of other cytoplasmic organelles.     

The interaction of the Bax C-terminal domain with negatively charged lipids modifies the secondary structure and changes its way of insertion into membranes

Fourier transform infrared spectroscopy (FTIR) was used to study the secondary structure of peptides which imitate the amino acid sequences of the C-terminal domain of the pro-apoptotic protein Bax (Bax-C) when incorporated into different lipid vesicles with or without negatively charged phospholipids. The infrared spectroscopy results showed that while the beta-sheet components are predominant in the membrane-free Bax-C secondary structure as well as in the presence of phosphatidylcholine vesicles, the peptide changes its secondary structure in the presence of negatively charged membranes, including phospholipids such as phosphatidylglycerol or phosphatidylinositol, depending on both the lipid composition and their molar ratio. The negative charges in the model membrane surface caused a marked change from beta-sheet to alpha-helix structure. Moreover, using attenuated total reflection infrared spectroscopy (ATR-FTIR), we investigated the orientation of Bax-C alpha-helical structures with respect to the normal to the internal reflection element. The orientation of Bax-C in membranes was also affected by negatively charged lipids, the presence of phosphatidylglycerol reduced the angle it forms with the normal to the germanium plate from 45 degrees in phosphatidylcholine to 27 degrees in phosphatidylglycerol vesicles. These results highlight the importance of lipid-protein interaction for the correct folding of membrane proteins and they suggest that the C-terminal domain of Bax will only span membranes with a net negative charge in their surface.     

The hydrophobic surface of PaAMP from pokeweed seeds is essential to its interaction with fungal membrane lipids and the antifungal activity

PaAMP is a small seed-specific antimicrobial protein from pokeweeds. It has a cysteine-knot fold with a positive patch and a hydrophobic surface. Site-specific mutagenesis was performed to study the roles of these two domains in antimicrobial activity and we found that the mutations in the hydrophobic surface had a more profound effect than that in the positive patch. A protein-membrane interaction was observed with the green fluorescence protein-PaAMP (GFP-AMP) fusion protein. The mutations that replace the amino acid residues forming hydrophobic surface with neutral residues abolished the interaction of PaAMP with the membrane and the binding of PaAMP to fungal sphingolipids while ergosterol enhanced the binding, suggesting that the hydrophobic surface was required for the interaction between PaAMP and fungal plasma membrane lipid raft.     

A factor which modifies the interaction of steroids with glucocorticoid receptors

A mechanism which determines the difference in the ability of deoxycorticosterone (DOC) to inhibit the binding of 3H-triamcinolone acetonide (3H-TA) to glucocorticoid receptors of rat heart and liver cytosols was investigated. DOC was found to strongly inhibit the binding of 3H-TA by heart cytosol, but to exert only a slight inhibitory effect towards the live cytosol binding. This difference was not due to the influence of the enzymes sensitive to molybdate ions, the presence of DOC-degrading enzymes or contamination of liver cytosol by blood serum. The liver cytosol devoid of the glucocorticoid receptor activity by heating was found to contain a factor modifying the "in vitro" interaction of DOC with the heart cytosol glucocorticoid receptors (receptor modifying factor, RMF). This factor is coeluted with the high molecular weight fraction during gel filtration, is precipitated at 50-70% ammonium sulphate saturation, can be absorbed by DEAE-Sephacel from cytosol at pH 7.4 under hypotonic conditions and extracted at about 0.06 M KC1. The sensitivity to proteases and the lack of sensitivity to nucleases point to the proteinic nature of the factor. It was assumed that in terms of the interaction of some steroids with glucocorticoid receptors, the tissue specificity can, at least partly, be explained by the differences in RMF concentration.     

Coproduction of surfactin and iturin A, lipopeptides with surfactant and antifungal properties, by Bacillus subtilis

Of the 13 strains of Bacillus subtilis tested for the coproduction of the lipopeptide surfactin and the antifungal lipopeptides of the iturin family, only 1 produced both lipopeptides with a high yield. The cultures were made in a synthetic medium. Several L-amino acids and various carbon sources were good substrates for the lipopeptide production. The maximum yield of surfactin was about 110 mg/liter and that of iturin A about 39 mg/liter/absorbance unit for the best strain, B. subtilis S 499.     

Methylation and acetylation of 15-hydroxyanandamide modulate its interaction with the endocannabinoid system

The biological activity of endocannabinoids like anandamide (AEA) and 2-arachidonoylglycerol (2-AG) is subjected in vivo to a “metabolic control”, exerted mainly by catabolic enzymes. AEA is inactivated by fatty acid amide hydrolase (FAAH), that is inhibited competitively by hydroxyanandamides (HAEAs) generated from AEA by lipoxygenase activity. Among these derivatives, 15-HAEA has been shown to be an effective (K_i ∼0.6 μM) FAAH inhibitor, that blocks also type-1 cannabinoid receptor (CB1R) but not other components of the “endocannabinoid system (ECS)”, like the AEA transporter (AMT) or CB2R. Here, we extended the study of the effect of 15-HAEA on the AEA synthetase (NAPE-PLD) and the AEA-binding vanilloid receptor (TRPV1), showing that 15-HAEA activates the former (up to ∼140% of controls) and inhibits the latter protein (down to ∼70%). We also show that 15-HAEA halves the synthesis of 2-AG and almost doubles the transport of this compound across the membrane. In addition, we synthesized methyl and acetyl derivatives of 15-HAEA (15-MeOAEA and 15-AcOAEA, respectively), in order to check their ability to modulate FAAH and the other ECS elements. In fact, methylation and acetylation are common biochemical reactions in the cellular environment. We show that 15-MeOAEA, unlike 15-AcOAEA, is still a powerful competitive inhibitor of FAAH (K_i ∼0.7 μM), and that both derivatives have negligible interactions with the other proteins of ECS. Therefore, 15-MeOAEA is a FAAH inhibitor more selective than 15-HAEA. Further molecular dynamics analysis gave clues to the molecular requirements for the interaction of 15-HAEA and 15-MeOAEA with FAAH.     

Conformational flexibility of the hormonal peptide bombesin and its interaction with lipids

The conformational flexibility of the tetradecapeptide hormone bombesin has been studied using circular dichroism and fluorescence of its single tryptophan residue. The spectral changes observed indicate that the peptide changed from a random flexible coil in solution to a helical structure in lysolecithin micelles and dimyristoylphosphatidylserine vesicles. The tryptophan residue in the lipid complexes was located in a hydrophobic environment. The interaction with lipids was shown to involve both hydrophobic and electrostatic forces.