The cyclic depsipeptide, teixobactin, kills a number of Gram-positive bacteria, including methicillin-resistant Staphylococcus aureus (MRSA), and Mycobacterium tuberculosis without detectable resistance. To date, teixobactin is the only molecule in its class that has shown in vivo antibacterial efficacy. In this work, we designed and synthesized 10 new in vivo ready teixobactin analogues. These analogues showed highly potent antibacterial activities against Staphylococcus aureus, MRSA, and vancomycin-resistant enterococci (VRE) in vitro. One analogue, d-Arg-Leu-teixobactin, 2, was found to be noncytotoxic in vitro and in vivo. Moreover, topical instillation of peptide 2 in a mouse model of S. aureus keratitis decreased the bacterial bioburden (>99.0% reduction) and corneal edema significantly as compared to untreated mouse corneas. Collectively, our results have established the high therapeutic potential of a teixobactin analogue in attenuating bacterial infections and associated severities in vivo.
The mammalian and microbial cell selectivity of synthetic and biosynthetic cationic polymers has been investigated. Among the polymers with peptide backbones, polymers containing amino side chains display greater antimicrobial activity than those with guanidine side chains, whereas ethylenimines display superior activity over allylamines. The biosynthetic polymer ε-polylysine (εPL) is noncytotoxic to primary human dermal fibroblasts at concentrations of up to 2,000 μg/ml, suggesting that the presence of an isopeptide backbone has greater cell selectivity than the presence of α-peptide backbones. Both εPL and linear polyethylenimine (LPEI) exhibit bactericidal properties by depolarizing the cytoplasmic membrane and disrupt preformed biofilms. εPL displays broad-spectrum antimicrobial properties against antibiotic-resistant Gram-negative and Gram-positive strains and fungi. εPL elicits rapid bactericidal activity against both Gram-negative and Gram-positive bacteria, and its biocompatibility index is superior to those of cationic antiseptic agents and LPEI. εPL does not interfere with the wound closure of injured rabbit corneas. In a rabbit model of bacterial keratitis, the topical application of εPL (0.3%, wt/vol) decreases the bacterial burden and severity of infections caused by Pseudomonas aeruginosa and Staphylococcus aureus strains. In vivo imaging studies confirm that εPL-treated corneas appeared transparent and nonedematous compared to untreated infected corneas. Taken together, our results highlight the potential of εPL in resolving topical microbial infections.
Protein
flexibility poses a major challenge in binding site identification.
Several computational pocket detection methods that utilize small-molecule
probes in molecular dynamics (MD) simulations have been developed
to address this issue. Although they have proven hugely successful
at reproducing experimental structural data, their ability to predict
new binding sites that are yet to be identified and characterized
has not been demonstrated. Here, we report the use of benzenes as
probe molecules in ligand-mapping MD (LMMD) simulations to predict
the existence of two novel binding sites on the surface of the oncoprotein
MDM2. One of them was serendipitously confirmed by biophysical assays
and X-ray crystallography to be important for the binding of a new
family of hydrocarbon stapled peptides that were specifically designed
to target the other putative site. These results highlight the predictive
power of LMMD and suggest that predictions derived from LMMD simulations
can serve as a reliable basis for the identification of novel ligand
binding sites in structure-based drug design.
Bacterial colonization
of acute and chronic wounds is often associated
with delayed wound healing and prolonged hospitalization. The rise
of multi-drug resistant bacteria and the poor biocompatibility of
topical antimicrobials warrant safe and effective antimicrobials.
Antimicrobial agents that target microbial membranes without interfering
with the mammalian cell proliferation and migration hold great promise
in the treatment of traumatic wounds. This article reports the utility
of superhydrophilic electrospun gelatin nanofiber dressings (NFDs)
containing a broad-spectrum antimicrobial polymer, ε-polylysine
(εPL), crosslinked by polydopamine (pDA) for treating second-degree
burns. In a porcine model of partial thickness burns, NFDs promoted
wound closure and reduced hypertrophic scarring compared to untreated
burns. Analysis of NFDs in contact with the burns indicated that the
dressings trap early colonizers and elicit bactericidal activity,
thus creating a sterile wound bed for fibroblasts migration and re-epithelialization.
In support of these observations, in porcine models of Pseudomonas aeruginosa and Staphylococcus
aureus colonized partial thickness burns, NFDs decreased
bacterial bioburden and promoted wound closure and re-epithelialization.
NFDs displayed superior clinical outcome than standard-of-care silver
dressings. The excellent biocompatibility and antimicrobial efficacy
of the newly developed dressings in pre-clinical models demonstrate
its potential for clinical use to manage infected wounds without compromising
tissue regeneration.
Dissecting the complexities of branched peptide-lipopolysaccharides (LPS) interactions provide rationale for the development of non-cytotoxic antibiotic adjuvants. Using various biophysical methods, we show that the branched peptide, B2088, binds to lipid A and disrupts the supramolecular organization of LPS. The disruption of outer membrane in an intact bacterium was demonstrated by fluorescence spectroscopy and checkerboard assays, the latter confirming strong to moderate synergism between B2088 and various classes of antibiotics. The potency of synergistic combinations of B2088 and antibiotics was further established by time-kill kinetics, mammalian cell culture infections model and in vivo model of bacterial keratitis. Importantly, B2088 did not show any cytotoxicity to corneal epithelial cells for at least 96 h continuous exposure or hemolytic activity even at 20 mg/ml. Peptide congeners containing norvaline, phenylalanine and tyrosine (instead of valine in B2088) displayed better synergism compared to other substitutions. We propose that high affinity and subsequent disruption of the supramolecular assembly of LPS by the branched peptides are vital for the development of non-cytotoxic antibiotic adjuvants that can enhance the accessibility of conventional antibiotics to the intracellular targets, decrease the antibiotic consumption and holds promise in averting antibiotic resistance.
Taking advantage of the cluster effect observed in multivalent peptides, this work describes antifungal activity and possible mechanism of action of tetravalent peptide (B4010) which carries 4 copies of the sequence RGRKVVRR through a branched lysine core. B4010 displayed better antifungal properties than natamycin and amphotericin B. The peptide retained significant activity in the presence of monovalent/divalent cations, trypsin and serum and tear fluid. Moreover, B4010 is non-haemolytic and non-toxic to mice by intraperitoneal (200 mg/kg) or intravenous (100 mg/kg) routes. S. cerevisiae mutant strains with altered membrane sterol structures and composition showed hyper senstivity to B4010. The peptide had no affinity for cell wall polysaccharides and caused rapid dissipation of membrane potential and release of vital ions and ATP when treated with C. albicans. We demonstrate that additives which alter the membrane potential or membrane rigidity protect C. albicans from B4010-induced lethality. Calcein release assay and molecular dynamics simulations showed that the peptide preferentially binds to mixed bilayer containing ergosterol over phophotidylcholine-cholesterol bilayers. The studies further suggested that the first arginine is important for mediating peptide-bilayer interactions. Replacing the first arginine led to a 2–4 fold decrease in antifungal activities and reduced membrane disruption properties. The combined in silico and in vitro approach should facilitate rational design of new tetravalent antifungal peptides.
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