Novel apidaecin 1b analogs with superior serum stabilities for treatment of infections by gram-negative pathogens.

Proline-rich antimicrobial peptides (PrAMPs) from insects and mammals have recently been evaluated for their pharmaceutical potential in treating systemic bacterial infections. Besides the native peptides, several shortened, modified, or even artificial sequences were highly effective in different murine infection models. Most recently, we showed that the 18-residue-long peptide Api88, an optimized version of apidaecin 1b, was efficient in two different animal infection models using the pathogenic Escherichia coli strains ATCC 25922 and Neumann, with a promising safety margin. Here, we show that Api88 is degraded relatively fast upon incubation with mouse serum, by cleavage of the C-terminal leucine residue. To improve its in vitro characteristics, we aimed to improve its serum stability. Replacing the C-terminal amide by the free acid or substituting Arg-17 with l-ornithine or l-homoarginine increased the serum stabilities by more than 20-fold (half-life, ∼4 to 6 h). These analogs were nontoxic to human embryonic kidney (HEK 293), human hepatoma (HepG2), SH-SY5Y, and HeLa cells and nonhemolytic to human erythrocytes. The binding constants of all three analogs with the chaperone DnaK, which is proposed as the bacterial target of PrAMPs, were very similar to that of Api88. Of all the analogs tested, Api137 (Gu-ONNRPVYIPRPRPPHPRL; Gu is N,N,N',N'-tetramethylguanidino) appeared most promising due to its high antibacterial activity, which was very similar to Api88. Positional alanine and d-amino acid scans of Api137 indicated that substitutions of residues 1 to 13 had only minor effects on the activity against an E. coli strain, whereas substitutions of residues 14 to 18 decreased the activity dramatically. Based on the significantly improved resistance to proteolysis, Api137 appears to be a very promising lead compound that should be even more efficient in vivo than Api88.

Api88 is a novel antibacterial designer peptide to treat systemic infections with multidrug-resistant Gram-negative pathogens.

The emergence of multiple-drug-resistant (MDR) bacterial pathogens in hospitals (nosocomial infections) presents a global threat of growing importance, especially for Gram-negative bacteria with extended spectrum ß-lactamase (ESBL) or the novel New Delhi metallo-ß-lactamase 1 (NDM-1) resistance. Starting from the antibacterial peptide apidaecin 1b, we have optimized the sequence to treat systemic infections with the most threatening human pathogens, such as Escherichia coli, Klebsiella pneumoniae, Pseudomonas aeruginosa, and Acinetobacter baumannii. The lead compound Api88 enters bacteria without lytic effects at the membrane and inhibits chaperone DnaK at the substrate binding domain with a K(D) of 5 µmol/L. The Api88-DnaK crystal structure revealed that Api88 binds with a seven residue long sequence (PVYIPRP), in two different modes. Mice did not show any sign of toxicity when Api88 was injected four times intraperitoneally at a dose of 40 mg/kg body weight (BW) within 24 h, whereas three injections of 1.25 mg/kg BW and 5 mg/kg BW were sufficient to rescue all animals in lethal sepsis models using pathogenic E. coli strains ATCC 25922 and Neumann, respectively. Radioactive labeling showed that Api88 enters all organs investigated including the brain and is cleared through both the liver and kidneys at similar rates. In conclusion, Api88 is a novel, highly promising, 18-residue peptide lead compound with favorable in vitro and in vivo properties including a promising safety margin.

Monitoring the interference of protein-protein interactions in vivo by bimolecular fluorescence complementation: the DnaK case.

Many cellular processes depend on protein-protein interactions. The identification of molecules able to modulate protein contacts is of significant interest for drug discovery and chemical biology. Nevertheless, finding antagonists of protein interactions that work efficiently within the cell is a challenging task. Here, we describe the novel use of bimolecular fluorescence complementation (BIFC) to detect compounds that block the interaction of target proteins in vivo. In the BIFC method, each interaction partner is fused to a complementary fragment of a fluorescent protein and interactions are detected by fluorescence restoration after reporter reassembly. Here, we demonstrate that the inhibition of specific intracellular protein interactions results in a concomitant decrease in fluorescence emission. We also show that integration of BIFC with flow cytometry might provide an effective means to detect interaction modulators by directly reading out changes in the reporter signal. The in vivo application of this approach is illustrated through monitoring the inhibition of the interaction between the Escherichia coli Hsp70 chaperone and a short peptidic substrate by pyrrhocoricin-derived antibacterial peptides.