Action of different types of gramicidin S derivatives on bacterial cells and protoplasts

The work was concerned with studying the effect of gramicidin S derivatives with modified free amino groups of ornithine residues on bacterial cells and protoplasts. The substitution of the amino groups with neutral or carboxyl-containing groups eliminated or sharply decreased the antibacterial activity of gramicidin S, its binding to the cells, and the ability to change the permeability of the cytoplasmic membranes of the intact cells. However, the neutral derivatives and the derivative with acidic properties showed a considerable lytic activity when they were incubated with the protoplasts of Micrococcus lysodeikticus, Bacillus megaterium and Bacillus subtilis. Hence, these compounds preserved a certain membranotropic level. Those gramicidin S derivatives with modified ornithine amino groups which possessed basic properties were similar to gramicidin S in the antibiotic activity, the modified permeability of the membranes, the ability to bind with the cells, and the lytic action on the protoplasts.     

Lysis of bacterial protoplasts and spheroplasts and suppression of their dehydrogenase activity by neotehomycin]

Neotelomycin induced lysis of the protoplasts of Bac. megaterium and inhibited their succinate dehydrogenase activity. Direct correlation between the lytic activity of the antibiotic and its effect on succinate dehydrogenase was found. Neotelomycin had no effect on the dehydrogenase activity of the protoplast lysates. Possibly, suppression of the protoplast succinate dehydrogenase of Bac. megaterium under the effect of neotelomycin was due to significant structural changes caused by the antibiotic in the protoplast membranes and leading to their lysis and not to the direct effect on the enzyme. Neotelomycin had practically no effect on the spheroplast dehydrogenase activity of E. coli resistant to the antibiotic and did not induce their lysis. Resistance of E. coli to neotelomycin must be associated not with the presence of the antibiotic non-permeable cell wall but the peculiar properties of the membrane cytoplasm.     

Characterization of daptomycin oligomerization with perylene excimer fluorescence: stoichiometric binding of phosphatidylglycerol triggers oligomer formation

Daptomycin is a lipopeptide antibiotic that binds to and depolarizes bacterial cell membranes. Its antibacterial activity requires calcium and correlates with the content of phosphatidylglycerol in the target membrane. Daptomycin has been shown to form oligomers on liposome membranes. We here use perylene excimer fluorescence to further characterize the membrane-associated oligomer. To this end, the N-terminal fatty acyl chain was replaced with perylene-butanoic acid. The perylene derivative retains one third of the antibacterial activity of native daptomycin. On liposomes containing phosphatidylcholine and phosphatidylglycerol, as well as on Bacillus subtilis cells, the perylene-labeled daptomycin forms excimers, which shows that the N-terminal acyl chains of neighboring oligomer subunits are in immediate contact with one another. In a lipid bicelle system, oligomer formation can be titrated with stoichiometric amounts of phosphatidylglycerol. Therefore, the interaction of daptomycin with a single molecule of phosphatidylglycerol is sufficient to trigger daptomycin oligomerization.     

Chemical modification of bacitracin A and the biological activity of modified bacitracins

The single side chain amino group of the D-ornithine residue in bacitracin seems to be important for the antibacterial activity of the molecule, since, acetylation, formylation, carbamylation and deamination of the antibiotic caused 90–92% loss of antibacterial activity. In contrast, nearly 80–91% of the antibacterial activity of the parent antibiotic was retained after the esterification, amide formation and acid-chloride formation of the α—and Y -carboxyl groups of D-asparagine and D-glutamic acid residues of the antibiotic, respectively.     

家蝇幼虫抗菌肽MDL-2的电泳制备及其抗菌作用机理

通过体壁损伤和感染大肠杆菌同时诱导家蝇Musca domestica幼虫产生免疫血淋巴,经沸水浴热变性,透析浓缩处理,然后经Tricine-SDS-PAGE得到诱导前后家蝇幼虫血淋巴中蛋白差异表达条带,将该条带电泳回收,复性,抗菌活性检测等步骤,分离纯化得到抗菌肽MDL-2,其分子中富含Pro,Gly和碱性氨基酸,分子量为11 kD,对革兰氏阴性菌Escherichia coli和革兰氏阳性菌Staphylococcus aureus均有较强抗性,因此电泳制备抗菌肽的方法为此类生物微量活性物质的分离纯化提供一种行之有效的途径。通过MDL-2对大肠杆菌和金黄色葡萄球菌通透性和透射电镜超微结构的图谱分析,MDL-2首先与细菌的外膜结合,然后抗菌肽形成柔性的两亲空间构象与细胞内膜作用,扰乱了膜脂分子的排列,改变了细胞膜的通透性,影响细胞膜的结构和功能,细胞膜上形成了许多孔道,同时造成细胞内的原生质扩散,并从孔道向胞外渗漏,影响了细菌的代谢系统,最终引起细胞膜破碎,细胞完全解体,从而起到抑菌杀菌作用。     

Effect of gramicidin S and its derivatives on protoplasts of Bacillus subtilis

The lysis of Bacillus subtilis protoplasts by gramicidin S, a membrane active antibiotic, and its derivatives was studied according to free amino groups of the ornithine residue. The initial antibiotic and guanylgramicidin , a positive charge-preserving derivative, had a high lytic activity. Succinylgramicidin , a gramicidin S derivative with acid properties, and carbomoylgramicidin , a neutral derivative, actively lysed B. subtilis protoplasts suspended in 1/15 M phosphate buffer solution with sucrose . No lytic activity of succinylgramicidin was observed with respect to B. subtilis protoplasts suspended in an aqueous solution of sucrose. Comparative study on the sensitivity of the protoplasts of Micrococcus lysodeikticus, B. megaterium and B. subtilis to the lytic action of gramicidin S and its derivatives showed in the main a similar character of their interaction with the membranes of the protoplasts of the taxonomically close species (B. megaterium and B. subtilis). It is likely that the specificity of the action of the above substances on the protoplasts of M. lysodeikticus, i. e. a complicated character of the dependence of the lytic action of gramicidin S on its concentration, manifestation of the lytic activity of the neutral and acid derivatives in the presence of phosphates or other salts and in sucrose aqueous solution was mainly defined by the properties of the micrococcal membranes.     

Study of the adaptation resistance in bacteria to membrane active polypeptide antibiotics

Variants of Micrococcus lysodeikticus resistant to 100 micrograms/ml of gramicidin S with preserved resistance in subcultures on media without the antibiotic were isolated as a result of prolonged adaptation on a solid medium with increasing concentrations of gramicidin. The sensitive and resistant cells did not differ by their ability to bind gramicidin. Under the antibiotic effect permeability of the cytoplasmic membranes of the intact cells in the sensitive bacteria appeared to be impaired to a greater extent than that of the membranes of the cells in the resistant variant. Comparison of the lytic activity of gramicidin and its derivatives with respect to the protoplasts prepared with the cells of the initial and resistant variants of M. lysodeikticus revealed much higher resistance of the resistant variant protoplasts to the membrane-disorganizing effect of the preparations. Malate dehydrogenase and NADH-oxidase in the membrane preparations of the resistant variant cells differed from analogous enzymes from the membranes of the initial strain by the levels of their activity and sensitivity to gramicidin. It is likely that during adaptation of M. lysodeikticus to gramicidin significant changes in the cell cytoplasmic membranes occurred.     

Gramicidin-S: Structure-activity relationship

The two side chain amino groups of the two L-ornithine residues in gramicidin-S seem to be important for the antibacterial activity of the molecule, since complete acetylation, formylation, carbamylation, deamination, trinitrophenylation, succinylation, maleylation of the antibiotic caused 90–95 % loss of the antibacterial activity of the antibiotic. However this modification leads to only 12–30% loss of the hemolytic activity. Monoacetyl- and monoformyl gramicidin-S with a free amino group retains nearly 50% of the antibacterial activity of the molecule. It seems, therefore, that the two amino groups contribute equally to the antibacterial activity of gramicidin-S Presented at 53rd Annual General Body Meeting of the Society of Biological Chemists (India), New Delhi, October, 1984     

Antibiotic N',N''-dibenzyleremomycin with reduced 1,2-peptide bond

Eremomycin derivatives with benzylated amino groups of both residues of eremosamine and with (R) or (S)-2-amino-4-methylpentyl substituted for N-methyl-D-Leu, the first amino acid residue of its heptapeptide, were synthesized to study the role of the peptide bond between the first and the second amino acid residues of the heptapeptide moiety of the antibiotic in its interaction with the precursors of the bacterial cell wall peptidoglycan and exhibition of its antibacterial activity. Comparison of the antibacterial activities of N',N"-dibenzyleremomycin, de-(N-methyl-D-Leu)-N',N"-dibenzyleremomycin, and its N-(2-amino-4-methylpentyl)-derivative (1,2-deoxo-N',N"-dibenzyleremomycin) demonstrated that cleavage or replacement of the first amino acid residue by the corresponding aminoalkyl residue results in a decrease in its antibacterial activity towards both vancomycin-sensitive and vancomycin-resistant strains of microorganisms. The English version of the paper.     

Effect of multiple aliphatic amino acids substitutions on the structure, function, and mode of action of diastereomeric membrane active peptides

The initial stages leading to the binding and functioning of membrane-active polypeptides including hormones, signal sequences, and lytic peptides are mainly governed by electrostatic attraction and hydrophobic partitioning between water and lipid bilayers. Antimicrobial peptides serve as an important model for studying the details of these initial steps. However, a systematic analysis of the contribution of multiple hydrophobic amino acids to these steps have been hindered by the propensity of many peptides to aggregate and become inactivated in solution. To this end, we synthesized a series of model amphipathic all L-amino acid peptides and their diastereomers with the sequence KX(3)KWX(2)KX(2)K, where X = Gly, Ala, Val, Ile, or Leu. The effect of the aliphatic amino acids on the biological activity, binding, structure, membrane localization, and mode of action of these peptides was investigated. Most of the L-amino acid peptides oligomerized and adopted distinct structures in solution and in a membrane mimetic environment. Among this group only the Leu containing peptide was hemolytic and highly active on most bacteria tested. The Val- and Leu-containing peptides were hemolytic but inactive toward most bacteria tested. In contrast, the diastereomeric peptides were monomeric and unstructured in solution, but they adopted distinct structures upon membrane binding. While hemolytic activity was drastically reduced, the spectrum of antibacterial activity was preserved or increased. Importantly, we found a direct correlation with the diastereomers between hydrophobicity and propensity to form a helical/distorted-helix and activity (induced membrane leakage and antibacterial activity), despite the fact that they contained 30% D-amino acids. Furthermore, efficient increase in membrane permeability can proceed through different mechanisms. Specifically, the Leu-containing diastereomeric peptide micellized vesicles and possibly bacterial membranes while the Ile-containing diastereomeric peptide fused model membranes and irregularly disrupted bacterial membranes.     

Antibacterial activity of peptides derived from the C-terminal region of a hemolytic lectin, CEL-III, from the marine invertebrate Cucumaria echinata

Several synthetic peptides derived from the C-terminal domain sequence of a hemolytic lectin, CEL-III, were examined as to their action on bacteria and artificial lipid membranes. Peptide P332 (KGVIFAKASVSVKVTASLSK-NH(2)), corresponding to the sequence from residue 332, exhibited strong antibacterial activity toward Gram-positive bacteria. Replacement of each Lys in P332 by Ala markedly decreased the activity. However, when all Lys were replaced by Arg, the antibacterial activity increased, indicating the importance of positively charged residues at these positions. Replacement of Val by Leu also led to higher antibacterial activity, especially toward Gram-negative bacteria. The antibacterial activity of these peptides was correlated with their membrane-permeabilizing activity toward the bacterial inner membrane and artificial lipid vesicles, indicating that the antibacterial action is due to perturbation of bacterial cell membranes, leading to enhancement of their permeability. These results also suggest that the hydrophobic region of CEL-III, from which P332 and its analogs were derived, may play some role in the interaction with target cell membranes to trigger hemolysis.     

The characteristic region of arenicin-1 involved with a bacterial membrane targeting mechanism

The antimicrobial peptide arenicin-1 consists of two antiparallel β-sheets linked by a hydrophilic β-turn. To determine the role of a specific region found in a particular β-sheet structure of the peptide for antibacterial activity, two analogs with N-terminal deletions (RW) and substitutions of Arg to Ala in the β-turn region were designed. In the minimum inhibitory concentration (MIC) test, the antibacterial activities of the analogs were reduced for both Gram-positive and Gram-negative bacteria, when compared to arenicin-1. The influence of the decrease in hydrophobicity on the antibacterial activity was confirmed by a hemolytic assay. Through flow cytometric analysis using propidium iodide (PI) and a 1,6-diphenyl-1,3,5-hexatriene (DPH) assay, it was confirmed that the analogs decreased the degree of plasma membrane permeability compared to arenicin-1. In particular, analog 2 showed a lower permeability in Gram-negative bacteria than in Gram-positive bacteria. The results indicate that a reduction in the net charge weakened the electrostatic interactions between the peptides and the negatively charged membranes. In liposomes, which mimic bacterial membranes, due to a reduced binding affinity to the membranes, the analogs could not deeply penetrate into the hydrocarbon region and induce enough fluorescein isothiocyanate-dextran (FD) leakage compared to that of arenicin-1. It is thought that the Arg residue in the hydrophilic β-turn region is more important to antibacterial activity than the Arg residue in the N-terminal region. This study suggests that the Arg and Trp residues in the N-terminal region and the Arg residue in the β-turn region of arenicin-1 play a key role in antibacterial activity.     

Peptide derived from the lipid binding domain of Group IB human pancreatic phospholipase A2 possesses antibacterial activity

Group 1B human pancreatic secretory phospholipase A₂ (hp-sPLA₂), a digestive enzyme synthesized by pancreatic acinar cells and present in pancreatic juice, do not have antibacterial activity towards Escherichia coli. Our earlier results suggest that the N-terminal first ten amino acid residues of hp-sPLA₂ constitute major portion of the membrane binding domain of full-length enzyme and is responsible for the precise orientation of enzyme on the membrane surface by inserting into the lipid bilayers (Pande et al. (2006) Biochemistry, 45,12436–12447). In this study we report the antibacterial properties of a peptide (AVWQFRKMIK-CONH₂; N10 peptide), which corresponds to the N-terminal first ten amino acid residues of hp-sPLA₂, against E. coli. Full-length hp-sPLA₂, which contains this peptide sequence as N-terminal α-helix, did not showed detectable antibacterial activity. Presence of physiological concentration of salt or preincubation of N10 peptide with soluble anionic polymer inhibits the antibacterial activity indicating the importance of electrostatic interaction in binding of peptide to bacterial membrane. Addition of peptide resulted in destabilization of outer as well as inner cytoplasmic membrane of E. coli suggesting bacterial membranes to be the main target of action. N10 peptide exhibits strong synergism with lysozyme and potentiates the antibacterial activity of lysozyme. The peptide was inactive against human erythrocyte. Our result shows for the first time that a peptide fragment of hp-sPLA₂ possesses antibacterial activity towards E. coli and at subinhibitory concentration and can potentiate the antibacterial activity of membrane active enzyme. These observations suggest that N10 peptide may play an important role in the antimicrobial activity of pancreatic juice.     

Halogenated trimethoprim derivatives as multidrug-resistant Staphylococcus aureus therapeutics

Incorporation of halogen atoms to drug molecule has been shown to improve its properties such as enhanced in membrane permeability and increased hydrophobic interactions to its target. To investigate the effect of halogen substitutions on the antibacterial activity of trimethoprim (TMP), we synthesized a series of halogen substituted TMP and tested for their antibacterial activities against global predominant methicillin resistant Staphylococcus aureus (MRSA) strains. Structure-activity relationship analysis suggested a trend in potency that correlated with the ability of the halogen atom to facilitate in hydrophobic interaction to saDHFR. The most potent derivative, iodinated trimethoprim (TMP-I), inhibited pathogenic bacterial growth with MIC as low as 1.25?μg/mL while the clinically used TMP derivative, diaveridine, showed resistance. Similar to TMP, synergistic studies indicated that TMP-I functioned synergistically with sulfamethoxazole. The simplicity in the synthesis from an inexpensive starting material, vanillin, highlighted the potential of TMP-I as antibacterial agent for MRSA infections.     

Methylation of the antifungal lipopeptide iturin A modifies its interaction with lipids

Iturin A, extracted from the culture media of Bacillus subtilis, is an antifungal lipopeptide, the peptide cycle of which includes a D-Tyr residue in position 2. The antibiotic strength of iturin A is related to a change in the permeability of the membrane cells which leads to a leakage of K+ from the intracellular medium. Methylation of the D-Tyr residue dramatically decreases the biological activity of iturin A. Using the intrinsic fluorescence of D-Tyr we have shown that both iturin A and O-methyl-tyrosine iturin A enter the lipid membranes. When dimyristoylphosphatidylcholine vesicles contain iturin A we observe a change in the order degree of the lipid phase and an increase in the transition temperature. The methylated derivative has no effect. Two model membranes have been used to study the permeability changes induced by iturin A and O-methyltyrosine iturin A. Studying ionic permeability we have found that the conductance of a planar lipid membrane increases very much less when the lipopeptide is methylated. On the other hand, the release of carboxyfluorescein trapped in lipid vesicles is less upon addition of O-methyltyrosine-iturin A. We conclude that the Tyr residue of the peptide cycle plays a role in determining the interactions of iturin A with lipid membrane.     

Bacitracin A: Structure-activity relationship

The single imidazole nucleus of L-histidine residue in bacitracin-A seems to be important for the anti-bacterial activity of the molecule, since iodination, carboxymethylation and coupling of diazobenzene sulphonic acid to the histidine residue in the antibiotic caused 90–94% loss of antibacterial activity of the antibiotic. In contrast, the bacitracin sulphone and sulphoxide derivatives are as active as the parent antibiotic.     

Lipopeptide daptomycin: Interactions with bacterial and phospholipid membranes,stability of membrane aggregates and micellation in solution

Daptomycin is a cyclic lipopeptide effective against multidrug Gram-positive bacteria. Despite having a net negative charge, it is selective against negatively charged bacterial membranes. It has been established that daptomycin's antibiotic activity is based on directly targeting the bacterial membranes and that this antibacterial activity depends on calcium ions. Importantly, however, both the precise role of ions and the physical mechanisms responsible for daptomycin's action remain poorly understood. We investigate these issues using three types of molecular dynamics simulations: umbrella sampling free energy calculations for a single daptomycin, unbiased simulations for daptomycin tetramers, and unbiased simulations of micellation of daptomycin both in the absence and presence of calcium ions. The simulations are in the excess of 4 μs. As the most important finding, we establish that binding of the calcium ions on the aspartic acid residues is the key to stabilizing daptomycin tetramers inside the model material membrane. These complexes are vital for daptomycin's antibacterial activity. In the absence of binding, the tetramer is not stable and moves slowly out of the membrane. We also demonstrate that in solution, micellation of daptomycin occurs both in the presence and absence of calcium ions, and discuss the similarities between the behaviors of daptomycin and amyloid peptides in membranes.     

Antibiotic N", N""-Dibenzyleremomycin with a Reduced 1,2-Peptide Bond

Eremomycin derivatives with benzylated amino groups of both residues of eremosamine and with (R) or (S)-2-amino-4-methylpentyl substituted for N-methyl-D-Leu, the first amino acid residue of its heptapeptide, were synthesized in order to study the role of the peptide bond between the first and second amino acid residues of the heptapeptide moiety of the antibiotic in its interaction with the precursors of the bacterial cell wall peptidoglycan and the exhibition of its antibacterial activity. Comparison of the antibacterial activities of N",N"-dibenzyleremomycin, de-(N-methyl-D-Leu)-N",N"-dibenzyleremomycin, and its N-(2-amino-4-methylpentyl)-derivative (1,2-deoxo-N",N"-dibenzyleremomycin) demonstrated that cleavage or replacement of the first amino acid residue by the corresponding aminoalkyl residue results in a decrease in its antibacterial activity towards both vancomycin-sensitive and vancomycin-resistant strains of microorganisms.     

壳聚糖与细菌细胞膜相互作用的分子动力学研究

目的 壳聚糖（chitosan,CS）是一种天然的广谱抗菌活性物质。现有研究表明，壳聚糖与细菌细胞膜的相互作用是其发挥抗菌功能的关键。受限于传统实验技术的表征能力，壳聚糖与细菌细胞膜相互作用的具体机制仍有待研究。本文旨在研究壳聚糖与细菌细胞膜相互作用的分子机制。方法 本研究利用全原子分子动力学模拟技术主要探究了完全脱乙酰化的不同聚合度壳聚糖（八聚糖、十二聚糖和十六聚糖）与革兰氏阴性菌外膜（outer membrane,OM）和革兰氏阳性菌质膜（cytoplasmic membrane,CM）相互作用的动态过程。结果 壳聚糖主要依靠其氨基、碳6位羟基和碳3位羟基与OM和CM的头部极性区发生快速结合。随后壳聚糖末端糖基单元倾向于插入OM内部，深度约1 nm，并与脂质分子脂肪酸链上的羰基形成稳定的氢键相互作用。与之相比，壳聚糖分子难以稳定地插入CM内部。壳聚糖结合对膜结构性质产生影响，主要表现在降低OM和CM的单分子脂质面积，显著减少OM和CM极性区的Ca2+和Na+数目，破坏阳离子介导的脂质间相互作用。结论 本研究证明，壳聚糖带正电的氨基基团是介导其与膜相互作用的关键，并破环脂质间的相互作...     

Membranes of bacteria and mechanism of action of the antibiotic gramicidin S]

The cyclopeptide antibiotic gramicidin S taken at a concentration of 100--200 mkg/mg membrane protein rapidly increases the permeability of M. lysodeikticus protoplast membranes for substrates of respiratory chain and exogenous cytochromes c. Prolonged incubation of gramicidin S with protoplasts results in their lysis which is more fast at low temperatures. In contrast to natural gramicidin, a derivative of gramicidin S with acetylated amino groups does not inhibit either the micrococcus membrane dehydrogenase or the whole of respiratory chain and does not affect the osmotic barrier of protoplasts. Aliphatic diamines (at concentrations up to 0.1 M) and Ca2+ ions (10(-2) M) do not affect the functioning of the respiratory chain in isolated micrococcus membranes. Another derivative of the antibiotic with an increased distance of loaded amino groups from the cyclopeptide framework (diglycyl gramicidin S) affects the membrane in a way similar to that of natural gramicidin. Washing of gramicidin-treated membranes with NaCl enhances the inhibitory effect of the antibiotic on membrane enzymes. The data obtained suggest that in addition to ionic interactions some hydrophobic interactions also occur during gramicidin S binding to the bacterial membrane, probably at the expense of a hydrophobic peptide ring. It is assumed that gramicidin S, similar to Ca2+ and some other membranotropic agents provides for phase separation of negatively charged phospholipids from other groups of phospholipids, manifesting itself in an appearance of "frozen" sites on the membrane which destroys its barrier properties. This is due to the formation of ionic bonds of negatively charged phospholipids. Simultaneously, unlike Ca2+, gramicidin S, when interacting with membrane proteins, prevents their redistribution in more liquid parts of the membrane, which results in a situation when the respiratory enzymes become surrounded by alkyl chains with restricted motion.