Identification and characterization of the lysobactin biosynthetic gene cluster reveals mechanistic insights into an unusual termination module architecture

Lysobactin (katanosin B) is a macrocyclic depsipeptide, displaying high antibacterial activity against human pathogens. In this work, we have identified and characterized the entire biosynthetic gene cluster responsible for lysobactin assembly. Sequential analysis of the Lysobacter sp. ATCC 53042 genome revealed the lysobactin gene cluster to encode two multimodular nonribosomal peptide synthetases. As the number of modules found within the synthetases LybA and LybB directly correlates with the primary sequence of lysobactin, a linear logic of lysobactin biosynthesis is proposed. Investigation of adenylation domain specificities in?vitro confirmed the direct association between the synthetases and lysobactin biosynthesis. Furthermore, an unusual tandem thioesterase architecture of the LybB termination module was identified. Biochemical characterization of the individual thioesterases in?vitro provides evidence that solely penultimate thioesterase domain mediates the cyclization and simultaneous release of lysobactin.     

Solid-phase synthesis of lysobactin (katanosin B): insights into structure and function

The solid phase synthesis of the cyclic depsipeptide antibiotic lysobactin is described. The natural product was synthesized via a linear approach using mostly an Fmoc-strategy solid phase peptide synthesis (SPPS) with a single purification. A lysobactin analog has also been synthesized displaying nanomolar membrane disruption activity not seen with the natural product.     

Multivalent drug design. Synthesis and in vitro analysis of an array of vancomycin dimers

The design, synthesis, and in vitro microbiological analysis of an array of forty covalently linked vancomycin dimers are reported. This work was undertaken to systematically probe the impact of linkage orientation and linker length on biological activity against susceptible and drug-resistant Gram-positive pathogens. To prepare the array, monomeric vancomycin synthons were linked through four distinct positions of the glycopeptide (C-terminus (C), N-terminus (N), vancosamine residue (V), and resorcinol ring (R)) in 10 unique pairwise combinations. Amphiphilic, peptide-based linkers of four different lengths (11, 19, 27, and 43 total atoms) were employed. Both linkage orientation and linker length were found to affect in vitro antibacterial potency. The V-V series displayed the greatest potency against vancomycin-susceptible organisms and vancomycin-resistant Enterococcus faecalis (VRE) of VanB phenotype, while the C-C, C-V, and V-R series displayed the most promising broad-spectrum activity that included VRE of VanA phenotype. Dimers bearing the shortest linkers were in all cases preferred for activity against VRE. The effects of linkage orientation and linker length on in vitro potency were not uniform; for example, (1) no single compound displayed activity that was superior against all test organisms to that of vancomycin or the other dimers, (2) linker length effects varied with test organism, and (3) whereas one-half of the dimers were more potent than vancomycin against methicillin-susceptible Staphylococcus aureus (MSSA), only one dimer was more potent against methicillin-resistant S. aureus (MRSA) and glycopeptide-intermediate susceptible S. aureus (GISA). In interpreting the results, we have considered the potential roles of multivalency and of other phenomena.     

Design,synthesis and biological activity of novel demethylvancomycin dimers against vancomycin-resistant enterococcus faecalis

The emergence of resistance to vancomycin and other glycopeptide antibiotics is a serious concern in clinical practice and has prompted intensive efforts to develop analogues that may overcome the resistance. One of major strategies to enhancing anti-vancomycin-resistant enterococci (VRE) activity emerged in recent years was connecting two vancomycin molecules by covalent linkers. Herein, we reported the design and synthesis of three different covalently linked demethylvancomycin dimers 7a-c by applying click chemistry. Interestingly, these dimers restored their activities against VRE. Furthermore, the interactions of molecules with peptidoglycan were also investigated via computer modelling.     

D-Ala-D-lac binding is not required for the high activity of vancomycin dimers against vancomycin resistant enterococci

Covalent dimerization and oligomerization of vancomycin is an important and extensively used strategy to develop analogues active against vancomycin resistant enteroccoci (VRE). Here, we have carried out investigations to probe the role of peptide binding (Lys-d-Ala-d-Lac) in the high anti-VRE activities of covalently linked vancomycin dimers. Covalent dimers of damaged vancomycin (desleucyl) were prepared, and their anti-VRE activities and binding affinities toward various model peptides were measured. Despite the dramatic loss in affinity toward several model peptides in comparison to the corresponding intact vancomycin dimers, these damaged dimers maintained good activity against VRE. These results strongly suggest that the high anti-VRE activities of covalent vancomycin dimers are conferred from mechanisms other than Lys-d-Ala-d-Lac binding.     

Self-assembled multivalent vancomycin on cell surfaces against vancomycin-resistant enterococci (VRE)

A vancomycin (Van) derivative self-assembles in a phosphate buffer as a divalent Van and on cell surfaces as a multivalent Van, which offers potent activity against VRE.     

A redesigned vancomycin engineered for dual D-Ala-D-ala And D-Ala-D-Lac binding exhibits potent antimicrobial activity against vancomycin-resistant bacteria

The emergence of bacteria resistant to vancomycin, often the antibiotic of last resort, poses a major health problem. Vancomycin-resistant bacteria sense a glycopeptide antibiotic challenge and remodel their cell wall precursor peptidoglycan terminus from d-Ala-d-Ala to d-Ala-d-Lac, reducing the binding of vancomycin to its target 1000-fold and accounting for the loss in antimicrobial activity. Here, we report [Ψ[C(═NH)NH]Tpg(4)]vancomycin aglycon designed to exhibit the dual binding to d-Ala-d-Ala and d-Ala-d-Lac needed to reinstate activity against vancomycin-resistant bacteria. Its binding to a model d-Ala-d-Ala ligand was found to be only 2-fold less than vancomycin aglycon and this affinity was maintained with a model d-Ala-d-Lac ligand, representing a 600-fold increase relative to vancomycin aglycon. Accurately reflecting these binding characteristics, it exhibits potent antimicrobial activity against vancomycin-resistant bacteria (MIC = 0.31 μg/mL, VanA VRE). Thus, a complementary single atom exchange in the vancomycin core structure (O → NH) to counter the single atom exchange in the cell wall precursors of resistant bacteria (NH → O) reinstates potent antimicrobial activity and charts a rational path forward for the development of antibiotics for the treatment of vancomycin-resistant bacterial infections.     

Functional analysis of the lipoglycodepsipeptide antibiotic ramoplanin

The peptide antibiotic ramoplanin is highly effective against several drug-resistant gram-positive bacteria, including vancomycin-resistant Enterococcus faecium (VRE) and methicillin-resistant Staphylococcus aureus (MRSA), two important opportunistic human pathogens. Ramoplanin inhibits bacterial peptidoglycan (PG) biosynthesis by binding to Lipid intermediates I and II at a location different than the N-acyl-D-Ala-D-Ala dipeptide site targeted by vancomycin. Lipid I/II capture physically occludes these substrates from proper utilization by the late-stage PG biosynthesis enzymes MurG and the transglycosylases. Key structural features of ramoplanin responsible for antibiotic activity and PG molecular recognition have been discovered by antibiotic semisynthetic modification in conjunction with NMR analyses. These results help define a minimalist ramoplanin pharmacophore and introduce the possibility of generating ramoplanin-derived peptide or peptidomimetic antibiotics for use against VRE, MRSA, and related pathogens.     

Antibacterial effect of butyryl alkannin from Arnebia euchroma against vancomycin-resistant pathogens of Enterococcus faecalis causing urinary tract infections

This study was carried out to investigate the biomedicinal potential of a bioactive marker component, butyryl alkannin, isolated from n-hexane root extract of Arnebia euchroma against various vancomycin-resistant Enterococcus (VRE) isolates of Enterococcus faecalis causing urinary tract infections. As a result, butyryl alkannin showed significant antibacterial activity against multidrug-resistant E. faecalis pathogens of VRE as minimum inhibitory concentration values which were found in the range of 3.13 to 6.26 μg ml^? 1. The findings of this study justify biological and biomedicinal potential of butyryl alkannin compound as confirmed by its higher and significant antibacterial efficacy against VRE isolates of E. faecalis as compared to standard antibiotic vancomycin.     

Exploration of the site-specific nature and generalizability of a trimethylammonium salt modification on vancomycin: A-ring derivatives

Vancomycin analogues bearing an A-ring trimethylammonium salt modification were synthesized and their antimicrobial activity against vancomycin-resistant Enterococci (VRE) was evaluated. The modification increased antimicrobial potency and provided the capability to induce bacteria cell membrane permeabilization, but both properties were weaker than that found with our earlier reported similar C-terminus modification. The results provide further insights on the additive effect and generalizability of the structural and site-specific nature of a peripheral quaternary trimethylammonium salt modification of vancomycin.     

Staphylococcus aureus Penicillin‐Binding Protein 2 Can Use Depsi‐Lipid II Derived from Vancomycin‐Resistant Strains for Cell Wall Synthesis

Vancomycin‐resistant Staphylococcus aureus (S. aureus) (VRSA) uses depsipeptide‐containing modified cell‐wall precursors for the biosynthesis of peptidoglycan. Transglycosylase is responsible for the polymerization of the peptidoglycan, and the penicillin‐binding protein 2 (PBP2) plays a major role in the polymerization among several transglycosylases of wild‐type S. aureus. However, it is unclear whether VRSA processes the depsipeptide‐containing peptidoglycan precursor by using PBP2. Here, we describe the total synthesis of depsi‐lipid I, a cell‐wall precursor of VRSA. By using this chemistry, we prepared a depsi‐lipid II analogue as substrate for a cell‐free transglycosylation system. The reconstituted system revealed that the PBP2 of S. aureus is able to process a depsi‐lipid II intermediate as efficiently as its normal substrate. Moreover, the system was successfully used to demonstrate the difference in the mode of action of the two antibiotics moenomycin and vancomycin.     

Elucidation of the Active Conformation of Vancomycin Dimers with Antibacterial Activity against Vancomycin‐Resistant Bacteria

Covalently linked vancomycin dimers have attracted a great deal of attention among researchers because of their enhanced antibacterial activity against vancomycin‐resistant strains. However, the lack of a clear insight into the mechanisms of action of these dimers hampers rational optimization of their antibacterial potency. Here, we describe the synthesis and antibacterial activity of novel vancomycin dimers with a constrained molecular conformation achieved by two tethers between vancomycin units. Conformational restriction is a useful strategy for studying the relationship between the molecular topology and biological activity of compounds. In this study, two vancomycin units were linked at three distinct positions of the glycopeptide (vancosamine residue (V), C terminus (C), and N terminus (N)) to form two types of novel vancomycin cyclic dimers. Active NC‐VV‐linked dimers with a stable conformation as indicated by molecular mechanics calculations selectively suppressed the peptidoglycan polymerization reaction of vancomycin‐resistant Staphylococcus aureus in vitro. In addition, double‐disk diffusion tests indicated that the antibacterial activity of these dimers against vancomycin‐resistant enterococci might arise from the inhibition of enzymes responsible for peptidoglycan polymerization. These findings provide a new insight into the biological targets of vancomycin dimers and the conformational requirements for efficient antibacterial activity against vancomycin‐resistant strains.     

Design and synthesis of simple macrocycles active against vancomycin-resistant enterococci (VRE)

16-membered meta,para-cyclophanes mimicking the vancomycin binding pocket (D-O-E ring) were designed and synthesized. The structural key features of these biaryl ether containing macrocycles are (1) the presence of beta-amino-alpha-hydroxy acid or alpha,beta-diamino acid as the C-terminal component of the cyclopeptide and (2) the presence of a hydrophobic chain or lipidated aminoglucose at the appropriate position. Cycloetherification by an intramolecular nucleophilic aromatic substitution reaction (S(N)Ar) is used as the key step for the construction of the macrocycle. The atropselectivity of this ring-closure reaction is found to be sensitive to the peptide backbone and chemoselective cyclization (phenol versus primary amine) is achievable. Glycosylation of phenol was realized with freshly prepared 3,4,6-tri-O-acetyl-2-N-lauroyl-2-amino-2-deoxy-alpha-D-glucopyranosyl bromide under phase-transfer conditions. Minimum inhibitory concentrations for all of the derivatives are measured by using a standard microdilution assay, and potent bioactivities against both sensitive and resistant strains are found for some of these compounds (MIC (minimum inhibitory concentration) = 4 microg mL(-1) against VRE). From these preliminary SAR studies, it was anticipated that both the presence of a hydrophobic substituent and an appropriate structure of the macrocycle were required for this series of compounds to be active against VRE.     

Synthesis and Antibacterial Activity of Oxazolidinone Derivatives Containing Nitro Heteroaromatic Moiety

A series of novel oxazolidinone derivatives containing nitro heteroaromatic moiety was synthesized and characterized by means of ¹H NMR and MS spectra. All target compounds were evaluated for their in vitro antibacterial activities against S.au 29213, methicillin-resistant Staphylococcus aureus(MRSA) and vancomycin-resistant Enterococcus(VRE) by minimum inhibitory concentration(MIC) assay. Most of them exhibited antibacterial activity against S. au 29213, MRSA and VRE. Among them, compounds 10e and 10f displayed better activity than the control.     

Halogenated Phenazines that Potently Eradicate Biofilms,MRSA Persister Cells in Non‐Biofilm Cultures,and Mycobacterium tuberculosis

Conventional antibiotics are ineffective against non‐replicating bacteria (for example, bacteria within biofilms). We report a series of halogenated phenazines (HP), inspired by marine antibiotic 1 , that targets persistent bacteria. HP 14 demonstrated the most potent biofilm eradication activities to date against MRSA, MRSE, and VRE biofilms (MBEC=0.2–12.5 μM), as well as the effective killing of MRSA persister cells in non‐biofilm cultures. Frontline MRSA treatments, vancomycin and daptomycin, were unable to eradicate MRSA biofilms or non‐biofilm persisters alongside 14 . HP 13 displayed potent antibacterial activity against slow‐growing M. tuberculosis (MIC=3.13 μM), the leading cause of death by bacterial infection around the world. HP analogues effectively target persistent bacteria through a mechanism that is non‐toxic to mammalian cells and could have a significant impact on treatments for chronic bacterial infections.     

Halogenated Phenazines that Potently Eradicate Biofilms,MRSA Persister Cells in Non‐Biofilm Cultures,and Mycobacterium tuberculosis

Conventional antibiotics are ineffective against non‐replicating bacteria (for example, bacteria within biofilms). We report a series of halogenated phenazines (HP), inspired by marine antibiotic 1 , that targets persistent bacteria. HP 14 demonstrated the most potent biofilm eradication activities to date against MRSA, MRSE, and VRE biofilms (MBEC=0.2–12.5 μM), as well as the effective killing of MRSA persister cells in non‐biofilm cultures. Frontline MRSA treatments, vancomycin and daptomycin, were unable to eradicate MRSA biofilms or non‐biofilm persisters alongside 14 . HP 13 displayed potent antibacterial activity against slow‐growing M. tuberculosis (MIC=3.13 μM), the leading cause of death by bacterial infection around the world. HP analogues effectively target persistent bacteria through a mechanism that is non‐toxic to mammalian cells and could have a significant impact on treatments for chronic bacterial infections.     

Binding of a dimeric derivative of vancomycin to L-Lys-D-Ala-D-lactate in solution and at a surface.

BACKGROUND: The emergence of bacteria that are resistant to vancomycin (V), a glycopeptide antibiotic, results from the replacement of the carboxy-terminal D-Ala-D-Ala of bacterial cell wall precursors by D-Ala-D-lactate. Recently, it has been demonstrated that covalent dimeric variants of V are active against vancomycin-resistant enterococci (VRE). To study the contribution of divalency to the activities of these variants, we modeled the interactions of V and a dimeric V with L-Lys-D-Ala-D-lactate, an analog of the cell-wall precursors of the vancomycin-resistant bacteria. RESULTS: A dimeric derivative of V (V-Rd-V) was found to be much more effective than V in inhibiting the growth of VRE. The interactions of V and V-Rd-V with a monomeric lactate ligand - diacetyl-L-Lys-D-Ala-D-lactate (Ac2KDADLac) - and a dimeric derivative of L-Lys-D-Ala-D-lactate (Lac-R'd-Lac) in solution have been examined using isothermal titration calorimetry and UV spectroscopy titrations; the results reveal that V-Rd-V binds Lac-R'd-Lac approximately 40 times more tightly than V binds Ac2KDADLac. Binding of V and of V-Rd-V to Nalpha-Ac-L-Lys-D-Ala-D-lactate presented on the surface of mixed self-assembled monolayers (SAMs) of alkanethiolates on gold indicates that the apparent off-rate for dissociation of V-Rd-V from the surface is much slower than that of V from the same surface. CONCLUSIONS: The results are compatible with the hypothesis that divalency is responsible for tight binding, which correlates with small values of minimum inhibitory concentrations of V and V-Rd-V.     

Total synthesis of [Ψ[C(═S)NH]Tpg4]vancomycin aglycon, [Ψ[C(═NH)NH]Tpg4]vancomycin aglycon, and related key compounds: reengineering vancomycin for dual D-Ala-D-Ala and D-Ala-D-Lac binding

The total synthesis of [Ψ[C(═S)NH]Tpg(4)]vancomycin aglycon (8) and its unique AgOAc-promoted single-step conversion to [Ψ[C(═NH)NH]Tpg(4)]vancomycin aglycon (7), conducted on a fully deprotected substrate, are disclosed. The synthetic approach not only permits access to 7, but it also allows late-stage access to related residue 4 derivatives, alternative access to [Ψ[CH(2)NH]Tpg(4)]vancomycin aglycon (6) from a common late-stage intermediate, and provides authentic residue 4 thioamide and amidine derivatives of the vancomycin aglycon that will facilitate ongoing efforts on their semisynthetic preparation. In addition to early stage residue 4 thioamide introduction, allowing differentiation of one of seven amide bonds central to the vancomycin core structure, the approach relied on two aromatic nucleophilic substitution reactions for formation of the 16-membered diaryl ethers in the CD/DE ring systems, an effective macrolactamization for closure of the 12-membered biaryl AB ring system, and the defined order of CD, AB, and DE ring closures. This order of ring closures follows their increasing ease of thermal atropisomer equilibration, permitting the recycling of any newly generated unnatural atropisomer under progressively milder thermal conditions where the atropoisomer stereochemistry already set is not impacted. Full details of the evaluation of 7 and 8 along with several related key synthetic compounds containing the core residue 4 amidine and thioamide modifications are reported. The binding affinity of compounds containing the residue 4 amidine with the model D-Ala-D-Ala ligand 2 was found to be only 2-3 times less than the vancomycin aglycon (5), and this binding affinity is maintained with the model d-Ala-d-Lac ligand 4, representing a nearly 600-fold increase in affinity relative to the vancomycin aglycon. Importantly, the amidines display effective dual, balanced binding affinity for both ligands (K(a)2/4 = 0.9-1.05), and they exhibit potent antimicrobial activity against VanA resistant bacteria ( E. faecalis , VanA VRE) at a level accurately reflecting these binding characteristics (MIC = 0.3-0.6 μg/mL), charting a rational approach forward in the development of antibiotics for the treatment of vancomycin-resistant bacterial infections. In sharp contrast, 8 and related residue 4 thioamides failed to bind either 2 or 4 to any appreciable extent, do not exhibit antimicrobial activity, and serve to further underscore the remarkable behavior of the residue 4 amidines.     

Bacterial Autoimmune Drug Metabolism Transforms an Immunomodulator into Structurally and Functionally Divergent Antibiotics

Tapinarof is a stilbene drug that is used to treat psoriasis and atopic dermatitis, and is thought to function through regulation of the AhR and Nrf2 signaling pathways, which have also been linked to inflammatory bowel diseases. It is produced by the gammaproteobacterial Photorhabdus genus, which thus represents a model to probe tapinarof structural and functional transformations. We show that Photorhabdus transforms tapinarof into novel drug metabolism products that kill inflammatory bacteria, and that a cupin enzyme contributes to the conversion of tapinarof and related dietary stilbenes into novel dimers. One dimer has activity against methicillin‐resistant Staphylococcus aureus (MRSA) and vancomycin‐resistant Enterococcus faecalis (VRE), and another undergoes spontaneous cyclizations to a cyclopropane‐bridge‐containing hexacyclic framework that exhibits activity against Mycobacterium. These dimers lack efficacy in a colitis mouse model, whereas the monomer reduces disease symptoms.     

Total Synthesis of Cryptophycins and Their 16-(3-Phenylacryloyl) Derivatives

Cryptophycin A, a cyclic depsipeptide isolated from the blue-green alga (cyanobacterium) Nostocsp.GSV 224, has shown excellent activity against solid tumors implanted in mice. The benzylic epoxide, which was shown to be very important for biological activity, is also fairly unstable under both acidic and alkaline conditions. The high doses needed to observe in vivo activity might be a result of this instability. In order to solve this problem while preserving the electrophilic character of the benzylic position, enones 1 and 2 have been proposed as promising analogs of the natural product, and a convergent total synthesis of these compounds is described. In addition, the same strategy was used to prepare Cryptophycins A, B, C, and D.