Rapid membrane permeabilization and inhibition of vital functions of gram-negative bacteria by bactenecins

The interaction of a recombinant cecropin/melittin hybrid peptide with the outer membrane of Pseudomonas aeruginosa

A cecropin/melittin hybrid peptide (CEME) produced by recombinant DNA procedures was tested for its ability to interact with the outer membrane of Pseudomonas aeruginosa and found to have identical biological properties to that of chemically synthesized CEME. CEME was shown to kill P. aeruginosa and permeabilize its outer membrane to lysozyme and 1-N-phenylnaphthlyamine, in some cases better than other antimicrobial agents and permeabilizers. CEME demonstrated a high-binding affinity to purified P. aeruginosa lipopolysaccharide (LPS) and LPS in whole-cell environments. These data provide information on the molecular mechanism of CEME antimicrobial activity and strongly suggest that it is taken up across the outer membrane by the self-promoted uptake pathway.

Bactericidal action of tachyplesin I against oral streptococci

Tachyplesin I, a polycationic antimicrobial peptide isolated from hemocytes of horseshoe crabs, kills bacteria by disrupting the membrane potential of the cytoplasmic membrane. The present study shows that, among 36 oral streptococcal strains, 12 of 21 Streptococcus sanguis, 3 Streptococcus mutans, 9 Streptococcus salivarius and 3 Streptococcus milleri strains were susceptible to tachyplesin I, whereas 9 S. sanguis strains were resistant. Interestingly, these resistant strains include the clinical isolates from both Kawasaki disease and Behçet patients. According to the time-kill study, tachyplesin I inhibited irreversibly the growth of S. sanguis, S. mutans and S. salivarius strains within 20 min and an S. milleri strain within 80 min. Although it has been suggested that Escherichia coli cultured in rich media were more susceptible to tachyplesin I, the present results show that only 3 S. milleri strains were more sensitized to tachyplesin I in a glucose-supplemented medium, and other tested strains were not. Similarly, only 4 strains were more resistant to tachyplesin I in saline than these were in a rich medium.

Identification and characterization of a primary antibacterial domain in CAP18, a lipopolysaccharide binding protein from rabbit leukocytes

Secondary structure prediction studies on CAP18, a lipopolysaccharide binding protein from rabbit granulocytes, identified a highly cationic, 21-residue sequence with the tendency to adopt an amphipathic alpha-helical conformation, as observed in many antimicrobial peptides. The corresponding peptide was chemically synthesized and shown to exert a potent bactericidal activity against both Gram-negative and Gram-positive bacteria, and a rapid permeabilization of the inner membrane of Escherichia coli. Five analogues were synthesized to elucidate structure/activity relationships. It was found that helix disruption virtually eliminates antibacterial activity, while the degree of amphipathicity and the presence of an aromatic residue greatly affect the kinetics of bacterial inner membrane permeabilization.

Chemical synthesis and biological activity of a novel antibacterial peptide deduced from a pig myeloid cDNA

Several myeloid precursors of antibacterial peptides have recently been shown to share homologous pre- and pro-regions. Taking advantage of this homology, a novel cDNA was cloned from pig bone marrow RNA. This encodes a 166-residue polypeptide with highly conserved pre- (29 residues) and pro- (101 residues) sequences, followed by a unique, 36-residue C-terminal sequence. Structure analyses of this C-terminal region have identified a highly cationic sequence predicted to adopt an amphipathic alpha-helical conformation. A peptide corresponding to this sequence was chemically synthesized and shown to arrest the growth of both Gram-positive and Gram-negative bacteria. At least for Escherichia coli, the activity of this peptide appears to be mediated by its ability to permeabilize the bacterial membranes.

The effects of lactoferrin on gram-negative bacteria

Lactoferrin is an iron-binding protein found in human mucosal secretions as well as the specific granules of polymorphonuclear leukocytes. A variety of functions have been ascribed to the protein, and it appears to contribute to antimicrobial host defense. In particular, it has been shown to have direct effects on pathogenic microorganisms including bacteriostasis and the induction of microbial iron uptake systems. Still its overall physiologic role remains to be defined. It has appeared logical that antimicrobial activity of the protein arises from sequestration of environmental iron thereby causing nutritional deprivation in susceptible organisms. This argument is buttressed by the finding that selected highly virulent pathogens have evolved techniques to subvert this effect and use the protein as an iron source. However, recent observations indicate that the protein has additional properties that contribute to host defense. Work by several groups has shown that the protein synergistically interacts with immunoglobins, complement, and neutrophil cationic proteins against Gram-negative bacteria. Further, both the whole protein and a cationic N-terminus peptide fragment directly damage the outer membrane of Gram-negative bacteria suggesting a mechanism for the supplemental effects. This review will summarize these diverse observations with a consideration of how the in vitro work relates to the physiological role of the protein.

Molecular cloning of a putative homolog of proline/arginine-rich antibacterial peptides from porcine bone marrow

Screening of a porcine bone marrow cDNA library with a PCR-derived probe from rabbit LPS-binding protein CAP18 led to the discovery of two closely related clones. The longer, full-length cDNA clone encodes a 228 amino acid residue protein similar to the family of antibacterial/LPS-binding cationic peptides. In contrast to other hitherto discovered precursors of Pro/Arg-rich peptides from this family, they have a novel, unique structure of the C-terminal region of 100 amino acid residues with a repeating sequence of ten residues (FPPPNXPGPR, where X = V or F). These precursors could represent a part of the antibacterial peptide repertoire of porcine bone marrow.

Mechanisms of action on Escherichia coli of cecropin P1 and PR-39, two antibacterial peptides from pig intestine

Cecropin P1 and PR-39 are two antibacterial peptides isolated from the upper part of the small intestine of the pig. They have been sequenced, and their antibacterial spectra have been investigated (J.-Y. Lee, A. Boman, C. Sun, M. Andersson, H. Jörnvall, V. Mutt, and H. G. Boman, Proc. Natl. Acad. Sci. USA 86:9159-9162, 1989; B. Agerberth, J.-Y. Lee, T. Bergman, M. Carlquist, H. G. Boman, V. Mutt, and H. Jörnvall, Eur. J. Biochem. 202:849-854, 1991). We have now compared these two peptides for their mechanism of action on Escherichia coli K-12 by using three strains with different markers. Our results show that cecropin P1, like other cecropins, kills bacteria by lysis and that this reaction requires more peptide to kill more cells. PR-39 requires a lag period of about 8 min to penetrate the outer membrane of wild-type E. coli; then killing is quite fast. This lag period was absent in the envA1 mutant; in this strain the outer membrane was freely permeable to both peptides. PR-39 killed growing bacteria faster than nongrowing cells; for cecropin P1 there was no such difference. It is suggested from isotope incorporation experiments that PR-39 kills bacteria by a mechanism that stops protein and DNA synthesis and results in degradation of these components.

Antimicrobial activity of two bactenecins against spirochetes

Bac5 and Bac7 are antimicrobial peptides of bovine neutrophils that act on enteric gram-negative bacteria. We report here that these two peptides immobilize and kill Leptospira interrogans and Leptospira biflexa with MBCs of 6 to 25 micrograms/ml. Conversely, although both peptides bind to Borrelia burgdorferi, the organism is resistant to their action.

Synthetic peptides of human lysosomal cathepsin G with potent antipseudomonal activity

Enzymatically active and inactive (diisopropylfluorophosphate-treated) cathepsin G exerted antibacterial action in vitro against Staphylococcus aureus, whereas only enzymatically active cathepsin G displayed bactericidal action against Pseudomonas aeruginosa. In order to further test the requirement for protease activity for the antipseudomonal action of cathepsin G, synthetic peptides spanning the full-length mature protein were prepared and examined for antibacterial action. Surprisingly, three structurally distinct peptides that correspond to residues 61 to 80, 117 to 136, and 198 to 223 within the full-length protein were found to exert potent antipseudomonal action (> 4.5 logs of killing at 500 micrograms/ml) against P. aeruginosa ATCC 27853 and four mucoid clinical isolates. Only the peptide (CG117-136) corresponding to residues 117 to 136 (117-RPGTLCTVAGWGRVSMRRGT-136) within cathepsin G exerted antibacterial action against the gram-positive pathogen S. aureus. The antipseudomonal action of CG117-136 was rapid and could be inhibited either by increasing concentrations of NaCl or by 0.5 mM MgCl2 plus 0.5 mM CaCl2, and these conditions appeared to reduce binding of the peptide to whole bacteria. Variants of peptide CG117-136 lacking either a hydrophobic N-terminal domain or a positively charged C-terminal domain were found to have significantly less antipseudomonal action than CG117-136. The antibacterial capacity of the all-D-enantiomeric form of peptide CG117-136 was found to be identical to that of the all-L-peptide, suggesting that the mechanism of killing does not require the recognition of a target site possessing a chiral center.

Characterization of bovine neutrophil antibacterial polypeptides which bind to Escherichia coli

Bovine neutrophils contain several cationic polypeptides which exert potent microbicidal effects in vitro. To better characterize the repertoire of these polypeptides, we have incubated extracts of bovine neutrophils or neutrophil granules at pH 4 or 7 with either a smooth strain of Escherichia coli or a rough one. Only a few polypeptides interacted with the bacterial surface and were subsequently desorbed with 200 mM MgCl2, as revealed by gel electrophoresis and analysis of Western blots (immunoblots) with appropriate antibodies. Two of the main proteins appearing in Coomassie blue-stained gels have molecular masses of 53 and 15 kDa and correspond to the heavy and light chains of myeloperoxidase. Another prevailing protein band with a molecular mass of 31 kDa was purified and shown to be 87% identical to human azurocidin/CAP37 in its 22-amino-acid N-terminal sequence. Proteins separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and blotted to nitrocellulose did not react with an antiserum to human bactericidal/permeability-increasing protein. Conversely, immunoglobulin G against Bac7 or Bac5, two members of the antimicrobial proline- and arginine-rich polypeptide family, recognized in Western blots both the inactive precursor molecules, proBac7 and proBac5, and the mature polypeptides.

Chemotactic and protease-inhibiting activities of antibiotic peptide precursors

We have recently shown that two antimicrobial peptides (Bac5 and Bac7) and/or their immature forms (proBac5 and proBac7) can be released extracellularly from activated neutrophils. In the present study we have investigated the biological activities of the immature forms, which do not exhibit antimicrobial effects. We show that proBac7 is a monocyte-selective chemoattractant, potentially contributing to the recruitment of these cells to infection sites, whereas proBac5 efficiently inhibits the in vitro activity of cathepsin L, a cysteine proteinase thought to contribute to tissue injury in inflammation.

Antibacterial activity of lactoferrin and a pepsin-derived lactoferrin peptide fragment

Although the antimicrobial activity of lactoferrin has been well described, its mechanism of action has been poorly characterized. Recent work has indicated that in addition to binding iron, human lactoferrin damages the outer membrane of gram-negative bacteria. In this study, we determined whether bovine lactoferrin and a pepsin-derived bovine lactoferrin peptide (lactoferricin) fragment have similar activities. We found that both 20 microM bovine lactoferrin and 20 microM lactoferricin release intrinsically labeled [3H]lipopolysaccharide ([3H]LPS) from three bacterial strains, Escherichia coli CL99 1-2, Salmonella typhimurium SL696, and Salmonella montevideo SL5222. Under most conditions, more LPS is released by the peptide fragment than by whole bovine lactoferrin. In the presence of either lactoferrin or lactoferricin there is increased killing of E. coli CL99 1-2 by lysozyme. Like human lactoferrin, bovine lactoferrin and lactoferricin have the ability to bind to free intrinsically labeled [3H]LPS molecules. In addition to these effects, whereas bovine lactoferrin was at most bacteriostatic, lactoferricin demonstrated consistent bactericidal activity against gram-negative bacteria. This bactericidal effect is modulated by the cations Ca2+, Mg2+, and Fe3+ but is independent of the osmolarity of the medium. Transmission electron microscopy of bacterial cells exposed to lactoferricin show the immediate development of electron-dense "membrane blisters." These experiments offer evidence that bovine lactoferrin and lactoferricin damage the outer membrane of gram-negative bacteria. Moreover, the peptide fragment lactoferricin has direct bactericidal activity. As lactoferrin is exposed to proteolytic factors in vivo which could cleave the lactoferricin fragment, the effects of this peptide are of both mechanistic and physiologic relevance.

Proteolytic cleavage by neutrophil elastase converts inactive storage proforms to antibacterial bactenecins

Bac5 and Bac7, antibiotics of the bactenecin (proline/arginine-rich peptide) family, are stored as proforms in the large granules of bovine neutrophils [Zanetti, M., Litteri, L., Gennaro, R., Horstmann, H. and Romeo, D. (1990) J. Cell Biol. 111, 1363-1371]. These proforms have been purified to homogeneity from granule extracts by immunoaffinity and reverse-phase chromatography. While mature bactenecins efficiently kill Escherichia coli, Klebsiella pneumoniae and Salmonella typhimurium with minimal inhibitory concentrations of 6-12 micrograms/ml, proBac5 and proBac7 do not affect the growth of the same microorganisms, even at 500 micrograms/ml. Previous investigations have suggested that the conversion of probactenecins into mature antimicrobial peptides is catalyzed by a neutral serine protease stored in the azurophil granules. Purified proBac5 and proBac7 were thus treated with elastase, cathepsin G or proteinase 3, which constitute the pool of neutral serine proteases of the azurophils, and the reaction products were identified by Western blot analysis, mass spectrometry, and N-terminal sequence analysis. Of the three proteases, only elastase is able to catalyze the stepwise cleavage of probactenecins into the corresponding mature peptides, which have the same mass, N-terminal sequence and antibiotic activity of authentic Bac5 and Bac7. These results point to the importance of cooperation between azurophils and large granules in mounting a defense reaction.

Agents that increase the permeability of the outer membrane

The outer membrane of gram-negative bacteria provides the cell with an effective permeability barrier against external noxious agents, including antibiotics, but is itself a target for antibacterial agents such as polycations and chelators. Both groups of agents weaken the molecular interactions of the lipopolysaccharide constituent of the outer membrane. Various polycations are able, at least under certain conditions, to bind to the anionic sites of lipopolysaccharide. Many of these disorganize and cross the outer membrane and render it permeable to drugs which permeate the intact membrane very poorly. These polycations include polymyxins and their derivatives, protamine, polymers of basic amino acids, compound 48/80, insect cecropins, reptilian magainins, various cationic leukocyte peptides (defensins, bactenecins, bactericidal/permeability-increasing protein, and others), aminoglycosides, and many more. However, the cationic character is not the sole determinant required for the permeabilizing activity, and therefore some of the agents are much more effective permeabilizers than others. They are useful tools in studies in which the poor permeability of the outer membrane poses problems. Some of them undoubtedly have a role as natural antibiotic substances, and they or their derivatives might have some potential as pharmaceutical agents in antibacterial therapy as well. Also, chelators (such as EDTA, nitrilotriacetic acid, and sodium hexametaphosphate), which disintegrate the outer membrane by removing Mg2+ and Ca2+, are effective and valuable permeabilizers.

Agents that increase the permeability of the outer membrane

The outer membrane of gram-negative bacteria provides the cell with an effective permeability barrier against external noxious agents, including antibiotics, but is itself a target for antibacterial agents such as polycations and chelators. Both groups of agents weaken the molecular interactions of the lipopolysaccharide constituent of the outer membrane. Various polycations are able, at least under certain conditions, to bind to the anionic sites of lipopolysaccharide. Many of these disorganize and cross the outer membrane and render it permeable to drugs which permeate the intact membrane very poorly. These polycations include polymyxins and their derivatives, protamine, polymers of basic amino acids, compound 48/80, insect cecropins, reptilian magainins, various cationic leukocyte peptides (defensins, bactenecins, bactericidal/permeability-increasing protein, and others), aminoglycosides, and many more. However, the cationic character is not the sole determinant required for the permeabilizing activity, and therefore some of the agents are much more effective permeabilizers than others. They are useful tools in studies in which the poor permeability of the outer membrane poses problems. Some of them undoubtedly have a role as natural antibiotic substances, and they or their derivatives might have some potential as pharmaceutical agents in antibacterial therapy as well. Also, chelators (such as EDTA, nitrilotriacetic acid, and sodium hexametaphosphate), which disintegrate the outer membrane by removing Mg2+ and Ca2+, are effective and valuable permeabilizers.