Bacterial membrane disrupting dodecapeptide SC4 improves survival of mice challenged with Pseudomonas aeruginosa.

BACKGROUND: Dodecapeptide SC4 is a broad-spectrum bactericidal agent that functions by disintegrating bacterial membranes and neutralizing endotoxins. For insight into which SC4 amino acids are functionally important, we assessed Gram-negative bactericidal effects in structure-activity relationship experiments. Subsequently, SC4 was tested in a murine bacteremia model to combine and compare the efficacy with Zosyn, a first-line antibiotic against Pseudomonas aeruginosa (P. aeruginosa). METHODS: SC4 alanine-scanning analogs and their activities on were tested on P. aeruginosa. Survival studies in P. aeruginosa challenged mice were executed to monitor overall efficacy of SC4 and Zosyn, as a single modality and also as combination treatment. ELISAs were used to measure blood serum levels of selected inflammatory cytokines during treatment. RESULTS: Cationic residues were found to play a crucial role in terms of bactericidal activity against P. aeruginosa. In vivo, while only 9% (3/34) of control animals survived to day two and beyond, 44% (12/27) to 41% (14/34) of animals treated with SC4 or Zosyn, respectively, survived beyond one week. Combination treatment of SC4 and Zosyn demonstrated improved survival, i.e. 60% (12/20). The TNFα, IL-1, and IL-6 serum levels were attenuated in each treatment group compared to the control group. CONCLUSIONS: These data show that combination treatment of SC4 and Zosyn is most effective at killing P. aeruginosa and attenuating inflammatory cytokine levels in vivo. GENERAL SIGNIFICANCE: Combination treatment of SC4 and Zosyn may be useful in the clinic as a more effective antibiotic therapy against Gram-negative infectious diseases.

Probing structure-activity relationships in bactericidal peptide betapep-25.

Cationic peptides, known to disrupt bacterial membranes, are being developed as promising agents for therapeutic intervention against infectious disease. In the present study, we investigate structure-activity relationships in the bacterial membrane disruptor betapep-25, a peptide 33-mer. For insight into which amino acid residues are functionally important, we synthesized alanine-scanning variants of betapep-25 and assessed their ability to kill bacteria (Escherichia coli, Pseudomonas aeruginosa and Staphylococcus aureus) and to neutralize LPS (lipopolysaccharide). Activity profiles were found to vary with the bacterial strain examined. Specific cationic and smaller hydrophobic alkyl residues were crucial to optimal bactericidal activity against the Gram-negative bacteria, whereas larger hydrophobic and cationic residues mediated optimal activity against Gram-positive Staph. aureus. Lysine-substituted norleucine (n-butyl group) variants demonstrated that both charge and alkyl chain length mediate optimal activity. In terms of LPS neutralization, activity profiles were essentially the same against four species of LPS (E. coli 055 and 0111, Salmonella enterica serotype Typhimurium and Klebsiella pneumoniae), and different for two others (Ps. aeruginosa and Serratia marcescens), with specific hydrophobic, cationic and, surprisingly, anionic residues being functionally important. Furthermore, disulfide-bridged analogues demonstrated that an anti parallel beta-sheet structure is the bioactive conformation of betapep-25 in terms of its bactericidal, but not LPS endotoxin neutralizing, activity. Moreover, betapep-25 variants, like the parent peptide, do not lyse eukaryotic cells. This research contributes to the development and design of novel antibiotics.

Topomimetics of amphipathic beta-sheet and helix-forming bactericidal peptides neutralize lipopolysaccharide endotoxins.

Release of lipopolysaccharide (LPS) endotoxin from Gram negative bacterial membranes triggers macrophages to produce large quantities of cytokines that can lead to septic shock and eventual death. Agents that bind to and neutralize LPS may provide a means to clinically prevent septic shock upon bacterial infection. Previously, we reported the design of antibacterial helix peptide SC4 and beta-sheet-forming betapep peptides that neutralize LPS in vitro. We hypothesized that the ability of these and other such peptides to neutralize LPS rested in the common denominator of positively charged amphipathic structure. Here, we describe the design and synthesis of nonpeptide, calixarene-based helix/sheet topomimetics that mimic the folded conformations of these peptides in their molecular dimensions, amphipathic surface topology, and compositional properties. From a small library of topomimetics, we identified several compounds that neutralize LPS in the 10-8 M range, making them as effective as bactericidal/permeability increasing protein and polymyxin B. In an endotoxemia mouse model, three of the most in vitro effective topomimetics are shown to be at least partially protective against challenges of LPS from different bacterial species. NMR studies provide mechanistic insight by suggesting the site of molecular interaction between topomimetics and the lipid A component of LPS, with binding being mediated by electrostatic and hydrophobic interactions. This research contributes to the development of pharmaceutical agents against endotoxemia and septic shock.

Promotion of peptide antimicrobial activity by fatty acid conjugation.

Three peptides, YGAA[KKAAKAA](2) (AKK), KLFKRHLKWKII (SC4), and YG[AKAKAAKA](2) (KAK), were conjugated with lauric acid and tested for the effect on their structure, antibacterial activity, and eukaryotic cell toxicity. The conjugated AKK and SC4 peptides showed increased antimicrobial activity relative to unconjugated peptides, but the conjugated KAK peptide did not. The circular dichroism spectrum of AKK showed a significantly larger increase in its alpha-helical content in the conjugated form than peptide KAK in a solution containing phosphatidylethanolamine/phosphotidylglycerol vesicles, which mimics bacterial membranes. The KAK and AKK peptides and their corresponding fatty acid conjugates showed little change in their structure in the presence of phosphatidylcholine vesicles, which mimic the cell membrane of eukaryotic cells. The hemolytic activity of the KAK and AKK peptides and conjugates was low. However, the SC4 fatty acid conjugate showed a large increase in hemolytic activity and a corresponding increase in helical content in the presence of phosphatidylcholine vesicles. These results support the model of antimicrobial peptide hemolytic and antimicrobial activity being linked to changes in secondary structure as the peptides interact with lipid membranes. Fatty acid conjugation may improve the usefulness of peptides as antimicrobial agents by enhancing their ability to form secondary structures upon interacting with the bacterial membranes.

Acylation of SC4 dodecapeptide increases bactericidal potency against Gram-positive bacteria, including drug-resistant strains.

We have conjugated dodecyl and octadecyl fatty acids to the N-terminus of SC4, a potently bactericidal, helix-forming peptide 12-mer (KLFKRHLKWKII), and examined the bactericidal activities of the resultant SC4 'peptide-amphiphile' molecules. SC4 peptide-amphiphiles showed up to a 30-fold increase in bactericidal activity against Gram-positive strains (Staphylococcus aureus, Streptococcus pyogenes and Bacillus anthracis), including S. aureus strains resistant to conventional antibiotics, but little or no increase in bactericidal activity against Gram-negative bacteria (Escherichia coli and Pseudomonas aeruginosa). Fatty acid conjugation improved endotoxin (lipopolysaccharide) neutralization by 3- to 6-fold. Although acylation somewhat increased lysis of human erythrocytes, it did not increase lysis of endothelial cells, and the haemolytic effects occurred at concentrations 10- to 100-fold higher than those required for bacterial cell lysis. For insight into the mechanism of action of SC4 peptide-amphiphiles, CD, NMR and fluorescence spectroscopy studies were performed in micelle and liposome models of eukaryotic and bacterial cell membranes. CD indicated that SC4 peptide-amphiphiles had the strongest helical tendencies in liposomes mimicking bacterial membranes, and strong membrane integration of the SC4 peptide-amphiphiles was observed using tryptophan fluorescence spectroscopy under these conditions; results that correlated with the increased bactericidal activities of SC4 peptide-amphiphiles. NMR structural analysis in micelles demonstrated that the two-thirds of the peptide closest to the fatty acid tail exhibited a helical conformation, with the positively-charged side of the amphipathic helix interacting more with the model membrane surface. These results indicate that conjugation of a fatty acid chain to the SC4 peptide enhances membrane interactions, stabilizes helical structure in the membrane-bound state and increases bactericidal potency.