The designer proline-rich antibacterial peptide A3-APO is effective against systemic Escherichia coli infections in different mouse models

Abstract 

Antimicrobial peptides are considered to be viable alternatives to conventional antibiotics. However, they rarely show systemic efficacy in animal models when added at non-toxic doses. The dimer A3-APO was designed to attack both the bacterial membrane and the Enterobacteriaceae-specific domain of the heat shock protein DnaK in order to reduce toxicity whilst maintaining activity. The peptide exhibited a minimal inhibitory concentration (MIC) range of 2–128mg/L against 28 clinical Escherichia coli, Klebsiella pneumoniae and Salmonella enterica serovar Typhimurium strains, with a median MIC of 30mg/L. At this concentration, A3-APO was bactericidal to E. coli 5770, a fluoroquinolone-resistant extended-spectrum β-lactamase-producing strain. The No Observed Adverse Effect Limit (NOAEL) at repeated intraperitoneal peptide administration was 20mg/kg. When administered at this dose three times starting immediately after E. coli Neumann infection, A3-APO cured 100% of mice in a standard bacteraemia model used by the pharmaceutical industry. In a more stringent assay, when treatment started after E. coli 5770 bacteraemia had already been established, three doses of 10mg/kg A3-APO prolonged early survival at a rate similar to that of imipenem and reduced the bacterial counts to base level. When the second assay was repeated in kidney clearance conditions resembling those in humans, 10mg/kg A3-APO was as efficacious as imipenem in the long-term. The increased in vivo efficacy compared with the in vitro bactericidal figures can potentially be explained by the generally observable immunostimulatory properties of antimicrobial peptides. Peptide A3-APO shows promising features as a member in our antibiotic arsenal against multidrug-resistant bacterial pathogens.

Keywords: Bacterial counts, Extended-spectrum β-lactamase, Inhibition of protein folding, Kidney elimination, Peptide antibiotics, Sepsis model, Survival rate