Effect of succinylation on the membrane activity and conformation of a short cecropin A-melittin hybrid peptide

Structural framework for the modulation of the activity of the hybrid antibiotic peptide cecropin A-melittin [CA(1-7)M(2-9)] by Nε-lysine trimethylation

The 3D structures of six linear pentadecapeptides derived from the cecropin A-melittin antimicrobial peptide CA(1-7)M(2-9) [KWKLFKKIGAVLKVL-NH(2)] have been studied. These analogues are modified by ε-NH(2) trimethylation of one or more lysine residues and showed variation in both antimicrobial and cytotoxic activities, depending on the number and position of modified lysines. Since it is expected that these peptides will display a strong conformational ordering when in contact with membranes, we have investigated their structure on the basis of the data extracted from NMR experiments performed in membrane-mimetic environments. We show that inclusion of N(ε)-trimethylated lysine residues induces a certain degree of structural flexibility, while preserving to a variable extent a largely α-helical structure. In addition, peptide orientation with respect to SDS micelles has been explored by detection of the intensity changes of peptide NMR signals upon addition of a paramagnetic probe (Mn(2+) ions).

Interaction and lipid-induced conformation of two cecropin-melittin hybrid peptides depend on peptide and membrane composition

The interaction of two hybrid peptides of cecropin A and melittin [CA(1-8)M(1-18) and CA(1-7)M(2-9)] with liposomes was studied by differential scanning calorimetry (DSC), circular dichroism (CD), and quasi-elastic light scattering (QELS). The study was carried out with large unilamellar vesicles (LUVs) of three different lipid compositions: 1,2-dimyristoil-sn-glycero-3-phosphocholine (DMPC), 1,2-dimyristoyl-sn-glycero-3-phospho-rac-(1-glycerol) (DMPG) and a binary mixture of DMPC/DMPG, in a wide range of peptide-to-lipid (P:L) molar ratios (0 to 1:7). DSC results indicate that, for both peptides, the interaction depends on membrane composition, with very different behavior for zwitterionic and anionic membranes. CD data show that, although the two peptides have different secondary structures in buffer (random coil for CA(1-7)M(2-9) and predominantly beta-sheet for CA(1-8)M(1-18)), they both adopt an alpha-helical structure in the presence of the membranes. Overall, results are compatible with a model involving a strong electrostatic surface interaction between the peptides and the negatively charged liposomes, which gives place to aggregation in the gel phase and precipitation after a threshold peptide concentration. In the case of zwitterionic membranes, a progressive surface coverage with peptide molecules destabilizes the membrane, eventually leading to membrane disruption. Moreover, delicate modulations in behavior were observed depending on the peptide.

Alpha,beta-dehydrophenylalanine containing cecropin-melittin hybrid peptides: conformation and activity

Synthesis and conformational studies of a cecropin-melittin hybrid pentadecapeptide CA(1-7)MEL(2-9), and its three alpha, beta-dehydrophenylalanine (DeltaPhe) containing analogs in water-TFE mixtures are described. DeltaPhe is placed at strategic positions in order to preserve the amphipathicity of the molecule. The wild type CAMEL0 and its three analogs, containing one, two and three DeltaPhe residues namely CAMELDeltaPhe1, CAMELDeltaPhe2 and CAMELDeltaPhe3 respectively were synthesized in solid phase and their conformation determined by CD and NMR. CAMELDeltaPhe2 and CAMELDeltaPhe3 peptides exhibit the presence of 3(10)-helix and beta-turns in the former and only turns in the latter. CAMELDeltaPhe1 peptide was found to have a largely extended conformation. Antibacterial and hemolytic activities of the peptides were also evaluated. CAMELDeltaPhe2 peptide is maximally potent against both Staphylococcus aureus ATCC 259230 and Escherichia coli ATCC 11303. CAMELDeltaPhe1 with a single DeltaPhe at the center shows minimal hemolysis.

Animal antimicrobial peptides: an overview

Antibiotic peptides are a key component of the innate immune systems of most multicellular organisms. Despite broad divergences in sequence and taxonomy, most antibiotic peptides share a common mechanism of action, i.e., membrane permeabilization of the pathogen. This review provides a general introduction to the subject, with emphasis on aspects such as structural types, post-translational modifications, mode of action or mechanisms of resistance. Some of these questions are treated in depth in other reviews in this issue. The review also discusses the role of antimicrobial peptides in nature, including several pathological conditions, as well as recent accounts of their application at the preclinical level.

The effect of pH on the structure, binding and model membrane lysis by cecropin B and analogs

Cecropins are a group of anti-bacterial, cationic peptides that have an amphipathic N-terminal segment, and a largely hydrophobic C-terminal segment and normally form a helix-hinge-helix structure. In this study, the ability of cecropin B (CB) and two analogs to lyse phospholipid bilayers, which have two levels of anionic content, has been examined by dye-leakage measurements over the pH range 2. 0-12.0. The two analogs differ from the natural peptide by having either two amphipathic segments (CB1) or two hydrophobic segments (CB3). All these peptides (except CB3 on low anionic content bilayers where it is not active) have maximal lytic activity on both types of bilayers at high pH. However, the pattern of secondary structure formation on these bilayers by the peptides, as measured by circular dichroism (CD), and the pattern of their ability to bind lipid monolayers, as measured using a biosensor, do not directly correlate with the pattern of their lytic ability. CB and CB1 with low anionic content bilayers have secondary structures as measured by CD with a similar pattern to membrane lysis, but binding is maximal near neutral, not high, pH. CB3 has some secondary structures on low anionic content bilayers at low pH and this becomes maximal over the basic range, but CB3 neither binds to nor lyses with these lipid layers. On high anionic content lipid layers, all peptides show high levels of secondary structures over most of the pH range and maximal binding at neutral pH (except for CB3, which does not bind). All three peptides lyse with high anionic content bilayers, but show no activity at neutral pH and reach maximal activity at very high pH. This work shows that pH is a major factor in the capability of antibacterial peptides to lyse with liposomes and that secondary structure and binding ability may not be the main determinants.

The structure, dynamics and orientation of antimicrobial peptides in membranes by multidimensional solid-state NMR spectroscopy

Linear peptide antibiotics have been isolated from amphibians, insects and humans and used as templates to design cheaper and more potent analogues for medical applications. Peptides such as cecropins or magainins are < or = 40 amino acids in length. Many of them have been prepared by solid-phase peptide synthesis with isotopic labels incorporated at selected sites. Structural analysis by solid-state NMR spectroscopy and other biophysical techniques indicates that these peptide antibiotics strongly interact with lipid membranes. In bilayer environments they exhibit amphipathic alpha-helical conformations and alignments of the helix axis parallel to the membrane surface. This contrasts the transmembrane orientations observed for alamethicin or gramicidin A. Models that have been proposed to explain the antibiotic and pore-forming activities of membrane-associated peptides, as well as other experimental results, include transmembrane helical bundles, wormholes, carpets, detergent-like effects or the in-plane diffusion of peptide-induced bilayer instabilities.

NMR structural characterization of cecropin A(1-8) - magainin 2(1-12) and cecropin A (1-8) - melittin (1-12) hybrid peptides

In order to elucidate the structure-antibiotic activity relationships of the peptides, the three-dimensional structures of two hybrid peptides, CA(1-8) - MA(1-12) and CA(1-8) - ME(1-12) in trifluoroethanol-containing aqueous solution were investigated by NMR spectroscopy. Both CA(1-8) - MA(1-12) and CA(1-8) - ME(1-12) have strong antibacterial activity but only CA(1-8) - ME(1-12) has hemolytic activity against human erythrocytes. CA(1-8) - MA(1-12) has a hydrophobic 310-helix of only two turns combined with one short helix in the N-terminus with a flexible hinge section in between. CA(1-8) - MA(1-12) has a severely bent structure in the middle of the peptide. These structural features as well as the low hydrophobicity of CA(1-8) - MA(1-12) seem to be crucial for the selective lysis against the membrane of prokaryotic cells. CA(1-8) - ME(1-12) has an alpha-helical structure of about three turns in the melittin domain and a flexible structure with one turn in the cecropin domain connected with a flexible hinge section in between, and these might be the structural features required for membrane disruption against prokaryotic and eukaryotic cells. The central hinge region (Gly9-Ile10-Gly11) in an amphipathic antibacterial peptide is considered to play an important role in providing the conformational flexibility required for ion channel formation of the C-terminal hydrophobic alpha-helix on cell membrane.

Structure-activity studies of normal and retro pig cecropin-melittin hybrids

Chimeric analogs of cecropin P1 and melittin with normal and retro sequences were synthesized to explore the effect of sequence, amide bond direction (helical dipole), charge, amphipathicity and hydrophobicity on their antibacterial activity and channel-forming ability. When viewed from the opposite end by rotation in the plane 180 degrees retro analogs have the same sequence as the parent with reversed amide bond and helical dipole directions. The expected activities were related to the important structural features and a series of assumptions were made. Retro analogs are expected to be inactive if both sequence and amide bond direction make critical contributions to the activity. CP1(1-10)M(2-9) amide, (SWLSKTAKKLIGAVLKVL), showed a broad antibacterial spectrum with high activity against the two Gram-negative and three Gram-positive bacteria tested. Retro-CP1(1-10)M(2-9) was less active compared to its normal peptide. CP1(1-9)M(1-8) and CP1(1-9)M(2-8) amides were found to be active against Gram-negative Escherichia coli and also Gram-positive Streptococcus pyogenes, but inactive against the other test organisms. The corresponding retro analogs were inactive against all the five bacteria tested. These results suggest that both sequence and amide bond direction (helix dipole) are important structural requirements for the activity of CP1-M hybrids. Acetylation of the N-terminal amine in both normal and retro analogs lowered their activity, indicating the contribution of free amine to the activity. These analogs form ion-conducting channels in lipid bilayers. The action of the peptides may be explained by self-aggregation and formation of ion-conducting pores across bacterial membranes. Conformational analysis obtained from CD measurements showed that all analogs form amphipathic alpha-helices in presence of 12-20% hexafluoro isopropanol. The retro CP1(1-10)M(2-9) amide showed higher helicity and is more potent compared to other retro analogs synthesized. These studies show the effect of small sequence modifications on the biological activity of the peptides and on their alpha-helical conformation in HFIP, the structure-inducing organic solvent.

D-enantiomers of 15-residue cecropin A-melittin hybrids

The all-D enantiomers of six 15-residue hybrids of cecropin A and melittin were synthesized. They contained the seven N-terminal residues of cecropin A, followed by eight residues from the N-terminal region of melittin. They were pure and of the correct composition and structure. The peptides were compared with their all-L enantiomers. The L and D isomer pairs were each exact mirror images by circular dichroism at several concentrations of hexafluoroisopropanol, and at 12 or 20% were highly helical. The L analogs were rapidly hydrolyzed by trypsin but the D analogs were very resistant, making them suitable candidates for orally active drugs. These 15-mers did not form ion channels in normal lipid bilayers made in decane, but those bilayers made in squalene were thinner and the peptides did form ion-conducting channels. The D/L pairs of peptides were very active antibiotics against five representative Gram-negative and Gram-positive bacteria. In each case the D and L isomers were essentially equally active within experimental error. This is interpreted to mean that the peptides do not act by tight interactions with chiral receptors, enzymes or lipids. The action of these peptides against these organisms is best explained by self-aggregation and the formation of ion-conducting pores across bacterial membranes.