达托霉素生物合成研究进展

达托霉素是由玫瑰孢链霉菌(Streptomyces roseosporus)生产的一种环脂肽类抗生素, 具有强大的抗革兰氏阳性致病细菌的作用, 是继“抗生素最后一道防线”万古霉素后的新型抗生素。本文主要对达托霉素的结构、作用机制、合成基因簇及合成机制等当前的研究成果进行综述, 并且总结了利用组合生物学对达托霉素进行结构改造的策略, 以此来研究结构与活性之间的关系, 并寻找更广谱高效的抗生素。最后, 本文总结了提高达托霉素产量的策略, 为工业上降低达托霉素生产成本提供理论参考。     

Cardiolipin Prevents Membrane Translocation and Permeabilization by Daptomycin

Daptomycin is an acidic lipopeptide antibiotic that, in the presence of calcium, forms oligomeric pores on membranes containing phosphatidylglycerol. It is clinically used against various Gram-positive bacteria such as Staphylococcus aureus and Enterococcus species. Genetic studies have indicated that an increased content of cardiolipin in the bacterial membrane may contribute to bacterial resistance against the drug. Here, we used a liposome model to demonstrate that cardiolipin directly inhibits membrane permeabilization by daptomycin. When cardiolipin is added at molar fractions of 10 or 20% to membranes containing phosphatidylglycerol, daptomycin no longer forms pores or translocates to the inner membrane leaflet. Under the same conditions, daptomycin continues to form oligomers; however, these oligomers contain only close to four subunits, which is approximately half as many as observed on membranes without cardiolipin. The collective findings lead us to propose that a daptomycin pore consists of two aligned tetramers in opposite leaflets and that cardiolipin prevents the translocation of tetramers to the inner leaflet, thereby forestalling the formation of complete, octameric pores. Our findings suggest a possible mechanism by which cardiolipin may mediate resistance to daptomycin, and they provide new insights into the action mode of this important antibiotic.     

Purification of daptomycin binding proteins (DBPs) from the membrane of Enterococcus hirae

Daptomycin binding proteins (DBPs) are membrane proteins which act as daptomycin targets. Daptomycin is a cyclic lipopeptide antibiotic which is active against Gram-positive bacteria and was shown to be the first inhibitor of lipoteichoic acid (LTA) synthesis. It was found that the antibiotic did not penetrate the bacterial cytoplasm but bound membranes with a non-covalent bond and in particular some proteins which were called DBPs. DBPs were indicated as enzymes involved in LTA synthesis whose binding and inhibition by daptomycin is responsible for the observed effect on bacterial LTA synthesis. The purification of DBPs will make it possible not only to shed light on the biosynthesis of the cell wall polymer but will also provide innovative targets for selection of new antibacterial compounds. In this study, the purification of DBPs is described. Affinity chromatography was used with daptomycin as the ligand. Final elution of DBPs from daptomycin-coupled resin was performed using either 0.1% SDS or 3 M NaCl. Polyacrylamide gel electrophoresis of the eluted protein fractions consistently showed four protein bands (ranging from 55 to 66 kDa) in denaturating conditions and two protein bands (60 and 66 kDa) in non-denaturating conditions. Isoelectrofocusing analysis of the same sample consistently revealed two bands with pIs around 5. That these purified proteins were really the desired DBPs is demonstrated by the retention of daptomycin-binding capability they displayed.     

NMR structural studies of the antibiotic lipopeptide daptomycin in DHPC micelles

Daptomycin is a cyclic anionic lipopeptide that exerts its rapid bactericidal effect by perturbing the bacterial cell membrane, a mode of action different from most other currently commercially available antibiotics (except e.g. polymyxin and gramicidin). Recent work has shown that daptomycin requires calcium in the form of Ca²⁺ to form a micellar structure in solution and to bind to bacterial model membranes. This evidence sheds light on the initial steps in the mechanism of action of this novel antibiotic. To understand how daptomycin goes on to perturb bacterial membranes, its three-dimensional structure has been determined in the presence of 1,2-dihexanoyl-sn-glycero-3-phosphocholine (DHPC) micelles. NMR spectra of daptomycin in DHPC were obtained under two conditions, namely in the presence of Ca²⁺ as used by Jung et al. [D. Jung, A. Rozek, M. Okon, R.E.W. Hancock, Structural transitions as determinants of the action of the calcium-dependent antibiotic daptomycin, Chem. Biol. 11 (2004) 949-57] to solve the calcium-conjugated structure of daptomycin in solution and in a phosphate buffer as used by Rotondi and Gierasch [K.S. Rotondi, L.M. Gierasch, A well-defined amphipathic conformation for the calcium-free cyclic lipopeptide antibiotic, daptomycin, in aqueous solution, Biopolymers 80 (2005) 374-85] to solve the structure of apo-daptomycin. The structures were calculated using molecular dynamics time-averaged refinement. The different sample conditions used to obtain the NMR spectra are discussed in light of fluorescence data, lipid flip-flop and calcein release assays in PC liposomes, in the presence and absence of Ca²⁺ [D. Jung, A. Rozek, M. Okon, R.E.W. Hancock, Structural transitions as determinants of the action of the calcium-dependent antibiotic daptomycin, Chem. Biol. 11 (2004) 949-57]. The implications of these results for the membrane perturbation mechanism of daptomycin are discussed.     

The effect of replacing the ester bond with an amide bond and of overall stereochemistry on the activity of daptomycin

Daptomycin, a cyclic lipodepsipeptide antibiotic, has been used clinically since 2003 to treat serious infections caused by Gram-positive bacteria. Although 37?years have passed since daptomycin’s discovery, its mechanism of action is still debated. In this report, the effect of replacing the ester bond with an amide bond, and overall stereochemistry, on daptomycin’s biological activity was examined. Two peptides were prepared in which the threonine4 residue in the active daptomycin analog, Dap-K6-E12-W13, was replaced with (2S,3R)-diaminobutyric acid ((2S,3R)-DABA) or its epimer (2S,3S-DABA) converting the ring-closing ester bond to an amide bond. Both of these peptides were found to be considerably less active than Dap-K6-E12-W13. These results, along with our previous studies on other daptomycin analogs, enabled us to conclude that the ester bond is crucial to daptomycin’s activity. ent-Dap-K6-E12-W13 was found to be at least 133-fold less active than Dap-K6-E12-W13, indicating that a chiral interaction with a chiral target is essential to daptomycin’s activity. Studies examining the binding of Dap-K6-E12-W13 and ent-Dap-K6-E12-W13 to model liposomes consisting of phosphatidylglycerol (PG) and phosphatidylcholine suggest that the stereochemistry of PG plays a crucial role in daptomycin-membrane interactions.     

Daptomycin,a Bacterial Lipopeptide Synthesized by a Nonribosomal Machinery

Daptomycin (Cubicin®) is a branched cyclic lipopeptide antibiotic of nonribosomal origin and the prototype of the acidic lipopeptide family. It was approved in 2003 for the nontopical treatment of skin structure infections caused by Gram-positive pathogens, including methicillin-resistant Staphylococcus aureus (MRSA), and in 2006 for the treatment of bacteremia. Understanding the ribosome-independent biosynthesis of daptomycin assembly will provide opportunities for the generation of daptomycin derivatives with an altered pharmaceutical spectrum to address upcoming daptomycin-resistant pathogens. Herein, the structural properties of daptomycin, its biosynthesis, recent efforts for the generation of structural diversity, and its proposed mode of action are discussed.     

Daptomycin-mediated reorganization of membrane architecture causes mislocalization of essential cell division proteins

Daptomycin is a lipopeptide antibiotic used clinically for the treatment of certain types of Gram-positive infections, including those caused by methicillin-resistant Staphylococcus aureus (MRSA). Details of the mechanism of action of daptomycin continue to be elucidated, particularly the question of whether daptomycin acts on the cell membrane, the cell wall, or both. Here, we use fluorescence microscopy to directly visualize the interaction of daptomycin with the model Gram-positive bacterium Bacillus subtilis. We show that the first observable cellular effects are the formation of membrane distortions (patches of membrane) that precede cell death by more than 30 min. Membrane patches are able to recruit the essential cell division protein DivIVA. Recruitment of DivIVA correlates with membrane defects and changes in cell morphology, suggesting a localized alteration in the activity of enzymes involved in cell wall synthesis that could account for previously described effects of daptomycin on cell wall morphology and septation. Membrane defects colocalize with fluorescently labeled daptomycin, DivIVA, and fluorescent reporters of peptidoglycan biogenesis (Bocillin FL and BODIPY FL-vancomycin), suggesting that daptomycin plays a direct role in these events. Our results support a mechanism for daptomycin with a primary effect on cell membranes that in turn redirects the localization of proteins involved in cell division and cell wall synthesis, causing dramatic cell wall and membrane defects, which may ultimately lead to a breach in the cell membrane and cell death. These results help resolve the longstanding questions regarding the mechanism of action of this important class of antibiotics.     

NMR structural studies of the antibiotic lipopeptide daptomycin in DHPC micelles

Daptomycin is a cyclic anionic lipopeptide that exerts its rapid bactericidal effect by perturbing the bacterial cell membrane, a mode of action different from most other currently commercially available antibiotics (except e.g. polymyxin and gramicidin). Recent work has shown that daptomycin requires calcium in the form of Ca2+ to form a micellar structure in solution and to bind to bacterial model membranes. This evidence sheds light on the initial steps in the mechanism of action of this novel antibiotic. To understand how daptomycin goes on to perturb bacterial membranes, its three-dimensional structure has been determined in the presence of 1,2-dihexanoyl-sn-glycero-3-phosphocholine (DHPC) micelles. NMR spectra of daptomycin in DHPC were obtained under two conditions, namely in the presence of Ca2+ as used by Jung et al. [D. Jung, A. Rozek, M. Okon, R.E.W. Hancock, Structural transitions as determinants of the action of the calcium-dependent antibiotic daptomycin, Chem. Biol. 11 (2004) 949-57] to solve the calcium-conjugated structure of daptomycin in solution and in a phosphate buffer as used by Rotondi and Gierasch [K.S. Rotondi, L.M. Gierasch, A well-defined amphipathic conformation for the calcium-free cyclic lipopeptide antibiotic, daptomycin, in aqueous solution, Biopolymers 80 (2005) 374-85] to solve the structure of apo-daptomycin. The structures were calculated using molecular dynamics time-averaged refinement. The different sample conditions used to obtain the NMR spectra are discussed in light of fluorescence data, lipid flip-flop and calcein release assays in PC liposomes, in the presence and absence of Ca2+ [D. Jung, A. Rozek, M. Okon, R.E.W. Hancock, Structural transitions as determinants of the action of the calcium-dependent antibiotic daptomycin, Chem. Biol. 11 (2004) 949-57]. The implications of these results for the membrane perturbation mechanism of daptomycin are discussed.     

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.     

Oligomerization of daptomycin on membranes

Daptomycin is a lipopeptide antibiotic that kills Gram-positive bacteria by membrane depolarization. While it has long been assumed that the mode of action of daptomycin involves the formation of membrane-associated oligomers, this has so far not been experimentally demonstrated. We here use FRET between native daptomycin and an NBD-labeled daptomycin derivative to show that such oligomerization indeed occurs. The oligomers are observed in the presence of calcium ions on membrane vesicles isolated from Bacillus subtilis, as well as on model membranes containing the negatively charged phospholipid phosphatidylglycerol. In contrast, oligomerization does not occur on membranes containing phosphatidylcholine only, nor in solution at micromolar daptomycin concentrations. The requirements for oligomerization of daptomycin resemble those previously reported for antibacterial activity, suggesting that oligomerization is necessary for the activity.     

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.     

Estimation of the subunit stoichiometry of the membrane-associated daptomycin oligomer by FRET

Daptomycin is a lipopeptide antibiotic that kills Gram-positive bacteria by depolarizing their cell membranes. This antibacterial action of daptomycin is correlated with the formation of membrane-associated oligomers. We here examine the number of subunits contained in one oligomer using fluorescence resonance energy transfer (FRET). The results suggest that the oligomer contains approximately 6 to 7 subunits, or possibly twice this number if it spans both membrane monolayers.     

达托霉素耐药分子机制研究进展

环脂肽抗生素达托霉素抗菌活性强,致病菌不容易产生耐药性,已成为治疗革兰氏阳性菌特别是耐药菌感染的一线药物。但由于广泛使用,仍然出现了达托霉素耐药菌。细胞膜磷脂代谢和细胞壁结构动态与致病菌达托霉素耐药密切相关。文中综述了达托霉素作用机制和耐药机制,以期对药物研发和临床用药有所裨益。     

Daptomycin forms cation- and size-selective pores in model membranes

Daptomycin is a lipopeptide antibiotic that is used clinically to treat severe infections caused by Gram-positive bacteria. Its bactericidal action involves the calcium-dependent binding to membranes containing phosphatidylglycerol, followed by the formation of membrane-associated oligomers. Bacterial cells exposed to daptomycin undergo membrane depolarization, suggesting the formation of channels or pores in the target membranes. We here used a liposome model to detect and characterize the permeability properties of the daptomycin pores. The pores are selective for cations, with permeabilities being highest for Na⁺, K⁺, and other alkali metal ions. The permeability is approximately twice lower for Mg⁺⁺, and lower again for the organic cations choline and hexamethonium. Anions are excluded, as is the zwitterion cysteine. These observations account for the observed depolarization of bacterial cells by daptomycin and suggest that under typical in vivo conditions depolarization is mainly due to sodium influx.     

Regulation mechanisms underlying the biosynthesis of daptomycin and related lipopeptides

Daptomycin is a lipopeptide antibiotics used to treat Gram-positive pathogens infections, including drug-resistant strains. In-depth exploration of its biosynthesis and regulation is crucial for metabolic engineering improvement of this ever-increasing important antibiotic. The past years have witnessed the significant progresses in the understanding of the molecular mechanisms underlying the biosynthesis and regulation of daptomycin. This information was updated in our review, with special focus on the regulatory network integrating a wide variety of physiological and environmental inputs. This should provide novel insight into the regulatory mechanism of biosynthesis of daptomycin and nodes for strain improvement to increase the yields of daptomycin.     

Staphylococcus aureus Survives with a Minimal Peptidoglycan Synthesis Machine but Sacrifices Virulence and Antibiotic Resistance

Many important cellular processes are performed by molecular machines, composed of multiple proteins that physically interact to execute biological functions. An example is the bacterial peptidoglycan (PG) synthesis machine, responsible for the synthesis of the main component of the cell wall and the target of many contemporary antibiotics. One approach for the identification of essential components of a cellular machine involves the determination of its minimal protein composition. Staphylococcus aureus is a Gram-positive pathogen, renowned for its resistance to many commonly used antibiotics and prevalence in hospitals. Its genome encodes a low number of proteins with PG synthesis activity (9 proteins), when compared to other model organisms, and is therefore a good model for the study of a minimal PG synthesis machine. We deleted seven of the nine genes encoding PG synthesis enzymes from the S. aureus genome without affecting normal growth or cell morphology, generating a strain capable of PG biosynthesis catalyzed only by two penicillin-binding proteins, PBP1 and the bi-functional PBP2. However, multiple PBPs are important in clinically relevant environments, as bacteria with a minimal PG synthesis machinery became highly susceptible to cell wall-targeting antibiotics, host lytic enzymes and displayed impaired virulence in a Drosophila infection model which is dependent on the presence of specific peptidoglycan receptor proteins, namely PGRP-SA. The fact that S. aureus can grow and divide with only two active PG synthesizing enzymes shows that most of these enzymes are redundant in vitro and identifies the minimal PG synthesis machinery of S. aureus. However a complex molecular machine is important in environments other than in vitro growth as the expendable PG synthesis enzymes play an important role in the pathogenicity and antibiotic resistance of S. aureus.     

Whole genome characterization of the mechanisms of daptomycin resistance in clinical and laboratory derived isolates of Staphylococcus aureus

Background

Daptomycin remains one of our last-line anti-staphylococcal agents. This study aims to characterize the genetic evolution to daptomycin resistance in S. aureus.

Methods

Whole genome sequencing was performed on a unique collection of isogenic, clinical (21 strains) and laboratory (12 strains) derived strains that had been exposed to daptomycin and developed daptomycin-nonsusceptibility. Electron microscopy (EM) and lipid membrane studies were performed on selected isolates.

Results

On average, six coding region mutations were observed across the genome in the clinical daptomycin exposed strains, whereas only two mutations on average were seen in the laboratory exposed pairs. All daptomycin-nonsusceptible strains had a mutation in a phospholipid biosynthesis gene. This included mutations in the previously described mprF gene, but also in other phospholipid biosynthesis genes, including cardiolipin synthase (cls2) and CDP-diacylglycerol-glycerol-3-phosphate 3-phosphatidyltransferase (pgsA). EM and lipid membrane composition analyses on two clinical pairs showed that the daptomycin-nonsusceptible strains had a thicker cell wall and an increase in membrane lysyl-phosphatidylglycerol.

Conclusion

Point mutations in genes coding for membrane phospholipids are associated with the development of reduced susceptibility to daptomycin in S. aureus. Mutations in cls2 and pgsA appear to be new genetic mechanisms affecting daptomycin susceptibility in S. aureus.