Effect of disulphide bond position on salt resistance and LPS-neutralizing activity of α-helical homo-dimeric model antimicrobial peptides

To investigate the effects of disulphide bond position on the salt resistance and lipopolysaccharide (LPS)-neutralizing activity of α-helical homo-dimeric antimicrobial peptides (AMPs), we synthesized an α-helical model peptide (K6L4W1) and its homo-dimeric peptides (di-K(6)L(4)W(1)-N, di-K(6)L(4)W(1)-M, and di-K(6)L(4)W(1)-C) with a disulphide bond at the N-terminus, the central position, and the C-terminus of the molecules, respectively. Unlike (6)L(4)W(1) and di-K(6)L(4)W(1)-M, the antimicrobial activity of di-K(6)L(4)W(1)-N and di-K(6)L(4)W(1)-C was unaffected by 150 mM NaCl. Both di-K(6)L(4)W(1)-N and di-K(6)L(4)W(1)-C caused much greater inhibitory effects on nitric oxide (NO) release in LPS-induced mouse macrophage RAW 264.7 cells, compared to di-K(6)L(4)W(1)-M. Taken together, our results indicate that the presence of a disulphide bond at the N- or C-terminus of the molecule, rather than at the central position, is more effective when designing salt-resistant α-helical homo-dimeric AMPs with potent antimicrobial and LPS-neutralizing activities. [BMB reports 2011; 44(11): 747-752].     

The effects of Leu or Val residues on cell selectivity of α-helical peptides

In this study, the peptides were designed to compare the effect of multiple Leu or Val residues as the hydrophobic side of an α-helical model on their structure, function, and interaction with model membranes. The Leu-rich peptides displayed 4- to 16-fold stronger antimicrobial activity than Val-rich peptides, while Val-containing peptides showed no haemolysis and weak cytotoxicity. The peptides LR and VR showed an α-helical-rich structure under a membranemimicking environment. Different cell selectivity for Leu- or Val-containing peptides correlated with the targeted cell membranes. The Leu-rich peptide LR(W) and Val-rich peptide VR(W) interacted preferentially with negatively charged phospholipids over zwitterionic phospholipids. VR(W) displayed no interaction with zwitterionic phospholipids, which was consistent with its lack of haemolytic activity. The ability of LR to depolarize bacterial cells was much greater than that of VR. Val- and Leu-rich peptides appeared to kill bacteria in a membrane-targeted fashion, with different modes of action. Leu-rich peptides appeared to be active via a membrane-disrupting mode, while Val-rich peptides were active via the formation of small channels.     

Flexibility is a mechanical determinant of antimicrobial activity for amphipathic cationic α-helical antimicrobial peptides

Antimicrobial peptides (AMPs) are recognized as the potential substitutions for common antibiotics. Flexibility has been demonstrated to be a dominant on antimicrobial activity of an AMP, similar to the structural parameters such as hydrophobicity and hydrophobic moment as well as positive charge. To better understand the effect of flexibility on antimicrobial activity, we herein examined seventy-eight peptides derived from nine different species. Defined as a weighted average of amino acid flexibility indices over whole residue chain of AMP, flexibility index was used to scale the peptide flexibility and indicated to be a reflection of mechanical properties such as tensile and flexural rigidities. The results demonstrated that flexibility index is relevant to but different from other structural properties, may enhance activity against Escherichia coli for stiff clustered peptides or reduce activity against E. coli for flexible clustered peptides, and its optimum occurs at about − 0.5. This effect of flexibility on antimicrobial activity may be involved to the antimicrobial actions, such as stable peptide-bound leaflet formation and sequent stress concentration in target cell membrane, mechanically. The present results provide a new insight in understanding antimicrobial actions and may be useful in seeking for a new structure–activity relationship for cationic and amphipathic α-helical peptides.     

Role of helicity of α-helical antimicrobial peptides to improve specificity

A major barrier to the use of antimicrobial peptides as antibiotics is the toxicity or ability to lyse eukaryotic cells. In this study, a 26-residue amphipathic α-helical antimicrobial peptide A12L/A20L (Ac-KWKSFLKTFKSLK KTVLHTLLKAISS-amide) was used as the framework to design a series of D- and L-diastereomeric peptides and study the relationships of helicity and biological activities of α-helical antimicrobial peptides. Peptide helicity was measured by circular dichroism spectroscopy and demonstrated to correlate with the hydrophobicity of peptides and the numbers of D-amino acid substitutions. Therapeutic index was used to evaluate the selectivity of peptides against prokaryotic cells. By introducing D-amino acids to replace the original L-amino acids on the non-polar face or the polar face of the helix, the hemolytic activity of peptide analogs have been significantly reduced. Compared to the parent peptide, the therapeutic indices were improved of 44-fold and 22-fold against Gram-negative and Grampositive bacteria, respectively. In addition, D- and L-diastereomeric peptides exhibited lower interaction with zwitterionic eukaryotic membrane and showed the significant membrane damaging effect to bacterial cells. Helicity was proved to play a crucial role on peptide specificity and biological activities. By simply replacing the hydrophobic or the hydrophilic amino acid residues on the non-polar or the polar face of these amphipathic derivatives of the parent peptide with D-amino acids, we demonstrated that this method could have excellent potential for the rational design of antimicrobial peptides with enhanced specificity.     

Simulation of voltage-dependent interactions of α-helical peptides with lipid bilayers

Pore formation in lipid bilayers by channel-forming peptides and toxins is thought to follow voltage-dependent insertion of amphipathic α-helices into lipid bilayers. We have developed an approximate potential for use within the CHARMm molecular mechanics program which enables one to simulate voltage-dependent interaction of such helices with a lipid bilayer. Two classes of helical peptides which interact with lipid bilayers have been studied: (a) δ-toxin, a 26 residue channel-forming peptide from Staphylococcus aureus; and (b) synthetic peptides corresponding to the α5 and α7 helices of the pore-forming domain of Bacillus thuringiensis CryIIIA δ-endotoxin. Analysis of δ-toxin molecular dynamics (MD) simulations suggested that the presence of a transbilayer voltage stabilized the inserted location of δ-toxin helices, but did not cause insertion per se. A series of simulations for the α5 and α7 peptides revealed dynamic switching of the α5 helix between a membrane-associated and a membrane-inserted state in response to a transbilayer voltage. In contrast the α7 helix did not exhibit such switching but instead retained a membrane associated state. These results are in agreement with recent experimental studies of the interactions of synthetic α5 and α7 peptides with lipid bilayers.     

Peptide-membrane interactions and mechanisms of membrane destruction by amphipathic α-helical antimicrobial peptides

Antimicrobial peptides (AMPs) have received considerable interest as a source of new antibiotics with the potential for treatment of multiple-drug resistant infections. An important class of AMPs is composed of linear, cationic peptides that form amphipathic α-helices. Among the most potent of these are the cecropins and synthetic peptides that are hybrids of cecropin and the bee venom peptide, mellitin. Both cecropins and cecropin-mellitin hybrids exist in solution as unstructured monomers, folding into predominantly α-helical structures upon membrane binding with their long helical axis parallel to the bilayer surface. Studies using model membranes have shown that these peptides intercalate into the lipid bilayer just below the level of the phospholipid glycerol backbone in a location that requires expansion of the outer leaflet of the bilayer, and evidence from a variety of experimental approaches indicates that expansion and thinning of the bilayer are common characteristics during the early stages of antimicrobial peptide-membrane interactions. Subsequent disruption of the membrane permeability barrier may occur by a variety of mechanisms, leading ultimately to loss of cytoplasmic membrane integrity and cell death.     

Synthesis of all-hydrocarbon stapled α-helical peptides by ring-closing olefin metathesis

This protocol provides a detailed procedure for the preparation of stapled α-helical peptides, which have proven their potential as useful molecular probes and as next-generation therapeutics. Two crucial features of this protocol are (i) the construction of peptide substrates containing hindered α-methyl, α-alkenyl amino acids and (ii) the ring-closing olefin metathesis (RCM) of the resulting resin-bound peptide substrates. The stapling systems described in this protocol, namely bridging one or two turns of an α-helix, are highly adaptable to most peptide sequences, resulting in favorable RCM kinetics, helix stabilization and promotion of cellular uptake.     

Multiple glycosylation of de novo designed α-helical coiled coil peptides

The aim of this study was to investigate the influence of multiple O-glycosylation in α-helical coiled coil peptides on the folding and stability. For this purpose we systematically incorporated one to six β-galactose residues into the solvent exposed positions of a 26 amino acid long coiled coil helix. Surprisingly, circular dichroism spectroscopy showed no unfolding of the coiled coil structure for all glycopeptides. Thermally induced denaturations reveal a successive but relative low destabilization of the coiled coil structure upon introduction of β-galactose residues. These first results indicate that O-glycosylation of the glycosylated variants is easily tolerated by this structural motif and pave the way for further functional studies.     

Effect of hydrocarbon stapling on the properties of α-helical antimicrobial peptides isolated from the venom of hymenoptera

The impact of inserting hydrocarbon staples into short α-helical antimicrobial peptides lasioglossin III and melectin (antimicrobial peptides of wild bee venom) on their biological and biophysical properties has been examined. The stapling was achieved by ring-closing olefin metathesis, either between two S-2-(4′-pentenyl) alanine residues (S ₅) incorporated at i and i + 4 positions or between R-2-(7′-octenyl) alanine (R ₈) and S ₅ incorporated at the i and i + 7 positions, respectively. We prepared several lasioglossin III and melectin analogs with a single staple inserted into different positions within the peptide chains as well as analogs with double staples. The stapled peptides exhibited a remarkable increase in hemolytic activity, while their antimicrobial activities decreased. Some single stapled peptides showed a higher resistance against proteolytic degradation than native ones, while the double stapled analogs were substantially more resistant. The CD spectra of the singly stapled peptides measured in water showed only a slightly better propensity to form α-helical structure when compared to native peptides, whereas the doubly stapled analogs exhibited dramatically enhanced α-helicity.     

Free energy landscapes of two model peptides: α-helical and β-hairpin peptides explored with Brownian dynamics simulation

We applied an atomistic Brownian dynamics (BD) simulation with multiple time step method for the folding simulation of a 13-mer α-helical peptide and a 12-mer β-hairpin peptide, giving successful folding simulations. In this model, the driving energy contribution towards folding came from both electrostatic and van der Waals interactions for the α-helical peptide and from van der Waals interactions for the β-hairpin peptide. Although, many non-native structures having the same or lower energy than that of native structure were observed, the folded states formed the most populated cluster when the structures obtained by the BD simulations were subjected to the cluster analysis based on distance-based root mean square deviation of side-chains between different structures. This result indicates that we can predict the native structures from conformations sampled by BD simulation.     

Endotoxin-neutralizing activity and mechanism of action of a cationic α-helical antimicrobial octadecapeptide derived from α-amylase of rice

We have previously reported that AmyI-1-18, an octadecapeptide derived from α-amylase (AmyI-1) of rice, is a novel cationic α-helical peptide that exhibited antimicrobial activity against human pathogens, including Porphyromonas gingivalis, Pseudomonas aeruginosa, Propionibacterium acnes, Streptococcus mutans, and Candida albicans. In this study, to further investigate the potential functions of AmyI-1-18, we examined its inhibitory ability against the endotoxic activities of lipopolysaccharides (LPSs, smooth and Rc types) and lipid A from Escherichia coli. AmyI-1-18 inhibited the production of endotoxin-induced nitric oxide (NO), an inflammatory mediator, in mouse macrophages (RAW264) in a concentration-dependent manner. The results of a chromogenic Limulus amebocyte lysate assay illustrated that the ability [50% effective concentration (EC₅₀): 0.17 μM] of AmyI-1-18 to neutralize lipid A was similar to its ability (EC₅₀: 0.26 μM) to neutralize LPS, suggesting that AmyI-1-18 specifically binds to the lipid A moiety of LPS. Surface plasmon resonance analysis of the interaction between AmyI-1-18 and LPS or lipid A also suggested that AmyI-1-18 directly binds to the lipid A moiety of LPS because the dissociation constant (K_D) of AmyI-1-18 with lipid A is 5.6 × 10⁻¹⁰ M, which is similar to that (4.3 × 10⁻¹⁰ M) of AmyI-1-18 with LPS. In addition, AmyI-1-18 could block the binding of LPS-binding protein to LPS, although its ability was less than that of polymyxin B. These results suggest that AmyI-1-18 expressing antimicrobial and endotoxin-neutralizing activities is useful as a safe and potent host defense peptide against pathogenic Gram-negative bacteria in many fields of healthcare.     

Inhibitory effects and mechanisms of physiological conditions on the activity of enantiomeric forms of an α-helical antibacterial peptide against bacteria

Enantiomeric amphipathic α-helical antibacterial peptides were synthesized and their biophysical and biological properties under different physiological conditions were studied. In the absence of physiological factors, the l- and d-peptides exhibited similar antimicrobial activities against a broad spectrum of bacteria, even against clinical isolates with resistance to traditional antibiotics. However, in the presence of NaCl, CaCl₂ or human serum albumin (HSA) at physiological concentrations, the enantiomers revealed bacterium-species dependent attenuations in antibacterial activity. In the presence of salts the electrostatic interaction between the peptides and the biomembrane was inhibited. Salts, especially CaCl_2, weakened the ability of the peptides to permeabilize the outer membrane of Gram-negative bacteria, as determined by a 1-N-phenylnaphthylamine uptake assay. HSA exhibited variable inhibitory effects on the activity of the peptides when incubated with different bacterial strains. The peptides showed different binding association abilities to HSA at different molar ratios, regardless of their chirality, resulting in reduced peptide biological activity. The d-peptide performed better than its l-enantiomer in all conditions tested because of its resistance to proteolysis, and may therefore represent a promising candidate for development as a therapeutic agent.     

Effects of α-eleostearic acid on asolectin liposomes dynamics: Relevance to its antioxidant activity

In this study, the effect of α-eleostearic acid (α-ESA) on the lipid peroxidation of soybean asolectin (ASO) liposomes was investigated. This effect was correlated to changes caused by the fatty acid in the membrane dynamics. The influence of α-ESA on the dynamic properties of liposomes, such as hydration, mobility and order, were followed by horizontal attenuated total reflection Fourier transform infrared spectroscopy (HATR-FTIR), nuclear magnetic resonance (NMR), differential scanning calorimetry (DSC) and UV–vis techniques. The α-ESA showed an in vitro antioxidant activity against the damage induced by hydroxyl radical (OH) in ASO liposomes. The analysis of HATR-FTIR frequency shifts and bandwidths and ¹H NMR spin–lattice relaxation times, related to specific lipid groups, showed that α-ESA causes an ordering effect on the polar and interfacial regions of ASO liposomes, which may restrict the OH diffusion in the membrane. The DSC enthalpy variation analysis suggested that the fatty acid promoted a disordering effect on lipid hydrophobic regions, which may facilitate interactions between the reactive specie and α-ESA. Turbidity results showed that α-ESA induces a global disordering effect on ASO liposomes, which may be attributed to a change in the lipid geometry and shape. Results of this study may allow a more complete view of α-ESA antioxidant mode of action against OH, considering its influence on the membrane dynamics.     

Binding of amphipathic α-helical antimicrobial peptides to lipid membranes: Lessons from temporins B and L

Temporins constitute a family of amphipathic α-helical antimicrobial peptides (AMP) and contain some of the shortest cytotoxic peptides, comprised of only 10-14 residues. General characteristics of temporins parallel those of other AMP, both in terms of structural features and biophysical properties relating to their interactions with membrane lipids, with selective lipid-binding properties believed to underlie the discrimination between target vs host cells. Lipid-binding properties also contribute to the cytotoxicity AMP, causing permeabilization of their target cell membranes. The latter functional property of AMP involves highly interdependent acidic phospholipid-induced conformational changes, aggregation, and formation of toxic oligomers in the membrane. These oligomers are subsequently converted to amyloid-type fibers, as demonstrated for e.g. temporins B and L in our laboratory, and more recently for dermaseptins by Auvynet et al. Amyloid state represents the generic minimum in the folding/aggregation free energy landscape, and for AMP its formation most likely serves to detoxify the peptides, in keeping with the current consensus on mature amyloid being inert and non-toxic. The above scenario is supported by sequence analyses of temporins as well as other amphipathic α-helical AMP belonging to diverse families. Accordingly, sequence comparison identifies ‘conformational switches’, domains with equal probabilities for adopting random coil, α-helical and β-sheet structures. These regions were further predicted also to aggregate and assemble into amyloid β-sheets. Taken together, the lipid-binding properties and structural characterization lend support to the notion that the mechanism of membrane permeabilization by temporins B and L and perhaps of most AMP could be very similar, if not identical, to that of the paradigm amyloid forming cytotoxic peptides, responsible for degenerative cell loss in e.g. prion, Alzheimer's and Parkinson's disease, and type 2 diabetes.     

Effects of Hofmeister ions on the α-helical structure of proteins

The molecular conformation of proteins is sensitive to the nature of the aqueous environment. In particular, the presence of ions can stabilize or destabilize (denature) protein secondary structure. The underlying mechanisms of these actions are still not fully understood. Here, we combine circular dichroism (CD), single-molecule Förster resonance energy transfer, and atomistic computer simulations to elucidate salt-specific effects on the structure of three peptides with large α-helical propensity. CD indicates a complex ion-specific destabilization of the α-helix that can be rationalized by using a single salt-free computer simulation in combination with the recently introduced scheme of ion-partitioning between nonpolar and polar peptide surfaces. Simulations including salt provide a molecular underpinning of this partitioning concept. Furthermore, our single-molecule Förster resonance energy transfer measurements reveal highly compressed peptide conformations in molar concentrations of NaClO₄ in contrast to strong swelling in the presence of GdmCl. The compacted states observed in the presence of NaClO₄ originate from a tight ion-backbone network that leads to a highly heterogeneous secondary structure distribution and an overall lower α-helical content that would be estimated from CD. Thus, NaClO₄ denatures by inducing a molten globule-like structure that seems completely off-pathway between a fully folded helix and a coil state.     

Effect of the aminoacid composition of model α-helical peptides on the physical properties of lipid bilayers and peptide conformation: a molecular dynamics simulation

The interaction of a model Lys flanked α-helical peptides K₂-X₂₄-K₂, (X = A,I,L,L+A,V) with lipid bilayers composed of dimyristoylphosphatidylcholine (DMPC) and dipalmitoylphosphatidylcholine (DPPC) both, in a gel and in a liquid-crystalline state, has been studied by molecular dynamics simulations. It has been shown that these peptides cause disordering of the lipid bilayer in the gel state but only small changes have been monitored in a liquid-crystalline state. The peptides affect ordering of the surrounding lipids depending on the helix stability which is determined by amino acid side chains – their volume, shape, etc. We have shown that the helix does not keep the linear shape in all simulations but often bends or breaks. During some simulations with a very small difference between hydrophobic length of peptide and membrane thickness the peptide exhibits negligible tilt. At the same time changes in peptide conformations during simulations resulted in appearance of superhelix.     

Effect of structural modification on the gastrointestinal stability and hepatic metabolism of α-aminoxy peptides

α-Aminoxy peptide AxyP1 has been reported to form synthetic chloride channel in living cells, thus it may have therapeutic potential for the treatment of diseases associated with chloride channel dysfunction. However, this study revealed significant gastrointestinal (GI) instability and extensive hepatic metabolism of AxyP1. To improve its GI and metabolic stability, structural modifications were conducted by replacing the isobutyl side chains of AxyP1 with methyl group (AxyP2), hydroxymethyl group (AxyP3), 4-aminobutyl group (AxyP4) and 3-carboxyl propyl group (AxyP5). Compared with AxyP1 (41 and 47 % degradation), GI stability of the modified peptides was significantly improved by 8-fold (AxyP2), 9-fold (AxyP3) and 12-fold (AxyP5) with no degradation for AxyP4 in simulated gastric fluid within 1 h, and by 12-fold (AxyP2) and 9-fold (AxyP3) with no degradation for AxyP4 and AxyP5 in simulated intestinal fluid within 3 h, respectively. The hepatic metabolic stability of the four modified peptides within 30 min in rat liver S9 preparation was also improved significantly with no metabolism of AxyP5 and threefold (AxyP2 and AxyP4) and eightfold (AxyP3) less metabolism compared with AxyP1 (39 % metabolism). Unlike hydrolysis as the major metabolism of peptides of natural α-amino acids, oxidation mediated by the cytochrome P450 enzymes, especially CYP3A subfamily, to form the corresponding mono-hydroxyl metabolites was the predominant hepatic metabolism of the five α-aminoxy peptides tested. The present findings demonstrate that structural modification can significantly improve the GI and metabolic stability of α-aminoxy peptides and thus increase their potential for therapeutic use in the treatment of chloride channel related diseases.     

Structure–activity relationships of αs-casein peptides with multifunctional biological activities

Multifunctional bioactive peptides have a wider role in modulating physiological functions and possess multiple biological activities. Peptides from bovine milk with sequences QKALNEINQF [p10] and TKKTKLTEEEKNRL [p14] from α-_S2 casein f (79–88) and α-_S2 casein f (148–161) were identified to be having multifunctional biological activities and were synthesized. These synthesized peptides show various biological activities like angiotensin-converting enzyme inhibition, prolyl endopeptidase inhibition, antioxidant, and antimicrobial activities. The mode of antimicrobial mechanism was studied and p10 shows depolarization of cell membrane, whereas p14 was found to display DNA-binding activity. Structural studies envisaged backbone flexibility, for differences in their mode of action. Peptide structure function studies were correlated to understand their multifunctional biological activity.