Lactoferricin inspired peptide AMC-109 augments the effect of ciprofloxacin against Pseudomonas aeruginosa biofilm in chronic murine wounds

OBJECTIVES

The pathophysiology of chronic wounds is characterized by prolonged inflammation, low mitogenic-activity, high protease-/low inhibitor-activity, microbiota changes and biofilm formation, in combination with the etiology of the original insult. One strategy to promote healing is to terminate the parasitism-like-relationship between the biofilm-growing-pathogen and the host response. The antimicrobial peptide AMC-109 is a potential treatment with low resistance-potential and broad-spectrum coverage with rapid bactericidal effect. Our purpose was to investigate if adjunctive AMC-109 could augment the ciprofloxacin effect in a chronic Pseudomonas aeruginosa wound model.

METHODS

Third-degree-burns were inflicted on 33BALB/c mice. P.Aeruginosa embedded in seaweed alginate was injected under the eschar to mimic a biofilm. Mice were randomized to receive AMC-109, combined AMC-109 and ciprofloxacin, ciprofloxacin or placebo for 5 days followed by sample collection.

RESULTS

Lower bacterial load was seen in the double treated group when compared to both monotherapy groups (AMC-109, p=0.008 and ciprofloxacin, p=0.03). To evaluate the innate host response, quantification of cytokines and growth factors were performed. The pro-inflammatory response was dampened in the double-treated mice, compared to the mono-ciprofloxacin-treated group (p=0.0009). A lower mobilization of neutrophils from the bone marrow was indicated by reduced granulocyte-colony-stimulating factor in all treatment groups compared to the placebo group. Improved tissue-remodeling was indicated by the highest level of tissue inhibitor of metalloproteases and low metalloprotease level in the double-treated group.

CONCLUSIONS

AMC-109 revealed adjunctive anti-pseudomonas abilities augmenting the antimicrobial effect of ciprofloxacin in this wound model. The study indicates a potential role for AMC-109 in treating chronic wounds with complicating biofilm infections.

Anti-Colonization Effect of Au Surfaces with Self-Assembled Molecular Monolayers Functionalized with Antimicrobial Peptides on S. epidermidis

Medical devices with an effective anti-colonization surface are important tools for combatting healthcare-associated infections. Here, we investigated the anti-colonization efficacy of antimicrobial peptides covalently attached to a gold model surface. The gold surface was modified by a self-assembled polyethylene glycol monolayer with an acetylene terminus. The peptides were covalently connected to the surface through a copper-catalyzed [3 + 2] azide-acetylene coupling (CuAAC). The anti-colonization efficacy of the surfaces varied as a function of the antimicrobial activity of the peptides, and very effective surfaces could be prepared with a 6 log unit reduction in bacterial colonization.

The Medicinal Chemistry of Short Lactoferricin-Based Antibacterial Peptides

This review discusses antibacterial peptides from the perspective of development into clinically useful chemotherapeutic drugs using short lactoferricin based peptides as examples. The review shows how important features for antibacterial activity can be identified and explored using the molecular properties of a range of natural and non-natural amino acids. The results have been further refined quantitatively using a "soft-modelling" approach where important structural parameters that influence the antibacterial activity of 15-residue model peptides were identified. The review describes how this knowledge is utilised to generate pharmacophores for antibacterial efficacy. These pharmacophores turn out to be surprisingly small and relatively consistent between typical Gram-negative and Gram-positive bacteria leading to the discovery of a novel class of short synthetic cationic antimicrobial peptides. These compounds are found to have high antibacterial activity against several bacterial strains that are resistant to commercial antibiotics, and are promising as future clinical candidates for treatment of infections caused by several clinically relevant pathogens.