Conformations of bombolitins I and III in aqueous solutions: circular dichroism, 1H NMR, and computer simulation studies

The heptadecapeptides bombolitin I and bombolitin III are two of a series of peptides postulated to be biologically active within a membrane environment. In the preceding paper [Bairaktari, E., Mierke, D.F., Mammi, S., & Peggion, E. (1990) Biochemistry (preceding paper in this issue)] the conformational preferences of these peptides in the presence of SDS surfactant micelles, a mimetic for biological membranes, were examined. During these studies the conformations of these peptides were investigated in aqueous solutions by circular dichroism and nuclear magnetic resonance. A large difference was observed for the two peptides. Bombolitin I lacks any observable secondary structure in aqueous solution, independent of temperature, pH, and concentration. In striking contrast, bombolitin III adopts a well-defined alpha-helix at concentrations greater than 1.3 mM. This is indeed surprising given the great similarity of the two peptides. The alpha-helix of bombolitin III is pH dependent, with a great decrease in the observed secondary structure at pH values below 3.5. This observation could only be due to the protonation of the Asp residue at the fifth position. These findings suggest that the secondary structure arises from molecular aggregation of bombolitin III through the formation of a salt bridge involving the Asp side chain. The alpha-helix observed at "high" concentration (greater than 2.5 mM) has been characterized by CD and by the NOE's measured throughout a majority of the peptide. The experimentally determined structure has been energy refined with restrained molecular dynamics. The conformational results from this study are then compared with the conformations found in the presence of surfactant micelles.     

Interspecies Bombolitins Exhibit Structural Diversity upon Membrane Binding,Leading to Cell Specificity

Bombolitins, a class of peptides produced by bees of the genus Bombus, target and disrupt cellular membranes, leading to lysis. Antimicrobial peptides exhibit various mechanisms of action resulting from the interplay between peptide structure, lipid composition, and cellular target membrane selectivity. Herein, two bombolitins displaying significant amino-acid-sequence similarity, BII and BL6, were assessed for antimicrobial activity as well as correlated dodecylphosphocholine (DPC) micelle binding and membrane-induced peptide conformational changes. Infrared and circular dichroism spectroscopies were used to assess the structure-function relationship of each bombolitin, and the results indicate that BII forms a rigid and helically ordered secondary structure upon binding to DPC micelles, whereas BL6 largely lacks secondary structural order. Moreover, the binding affinity of each peptide to DPC micelles was determined, revealing that BL6 displayed a difference in binding affinity by over two orders of magnitude. Further investigations into the growth-inhibitory activity of the two bombolitins were performed against Escherichia coli and Saccharomyces cerevisiae. Interestingly, BII specifically targeted S. cerevisiae, whereas BL6 more effectively inhibited E. coli growth. Overall, the antimicrobial selectivity and specificity of BII and BL6 are largely dependent on the primary as well as secondary structural content of the peptides and the membrane composition.     

Bombolitins, a new class of mast cell degranulating peptides from the venom of the bumblebee Megabombus pennsylvanicus

Five structurally related heptadecapeptides rich in hydrophobic amino acids have been discovered in the venom of the bumblebee Megabombus pennsylvanicus. We have named them bombolitin I (Ile-Lys-Ile-Thr-Thr-Met-Leu-Ala-Lys-Leu-Gly-Lys-Val-Leu-Ala-His-Val-NH2 ), bombolitin II (Ser-Lys-Ile-Thr-Asp-Ile-Leu-Ala-Lys-Leu-Gly-Lys-Val-Leu-Ala-His-Val-NH2 ), bombolitin III (Ile-Lys-Ile-Met-Asp-Ile-Leu-Ala-Lys-Leu-Gly-Lys-Val-Leu-Ala-His-Val-NH2 ), bombolitin IV (Ile-Asn-Ile-Lys-Asp-Ile-Leu-Ala-Lys-Leu-Val-Lys-Val-Leu-Gly-His-Val-NH2 ), and bombolitin V (Ile-Asn-Val-Leu-Gly-Ile-Leu-Gly-Leu-Leu-Gly-Lys-Ala-Leu-Ser-His-Leu-NH2 ). Bombolitins are structurally and functionally very similar. They lyse erythrocytes and liposomes, release histamine from rat peritoneal mast cells, and stimulate phospholipase A2 from different sources. The threshold dose is 0.5-2.5 micrograms/ml depending on the peptide and the bioassay. Bombolitin V is as potent as the well-known melittin in lysing guinea pig erythrocytes (ED50 = 0.7 microgram/ml = 4 X 10(-7) M) and is 5 times more potent than mastoparan in causing mast cell degranulation, making it one of the most potent degranulating peptides discovered so far (ED50 = 2 micrograms/ml = 1.2 X 10(-6) M). The bombolitins represent a unique structural class of peptides but they have the same biological properties as melittin (from honeybees), mastoparan (wasps, hornets, and yellow jackets), and crabrolin (European hornets). This unusual circumstance (peptides with different amino acid sequences having the same biological properties) may be a manifestion of their amphiphilic nature, a property these peptides have in common.     

Helicity propensity and interaction of synthetic peptides from heptad-repeat domains of herpes simplex virus 1 glycoprotein H: a circular dichroism study

The secondary structure of two synthetic peptides from heptad-repeat domains of herpes simplex virus 1 glycoprotein H was determined by circular dichroism. In particular, the propensity of these peptides to assume an ordered structure was investigated upon by changing the solvent's polarity and the temperature. A reduction of solvent polarity led to a significant increase in the alpha-helix content in the case of HR1, whereas only a slight change in the secondary structure was observed in the case of HR2. In both cases the conformational change followed a two-state transition model. The interaction of the peptides was monitored by the conformational change in the mixture with respect to the single peptides. However, formation of the complex did not significantly enhance thermal stability. A reliable estimation of the secondary structure was obtained by optimising the experimental conditions to collect CD data down to 180 nm, and by comparing the structure data yielded by different software packages.     

Aggregation and conformational transition in aqueous solution of a bombolitin III analogue containing a photoreactive side-chain group

The peptide toxin bombolitin III [B(III)], originally isolated from bumblebee venom, has been shown to undergo a concentration-dependent conformational change from a random structure to an α-helix induced by aggregation. The aggregation process and the consequent folding results from a delicate balance of electrostatic and hydrophobic interactions. The conformational change is strongly dependent on pH and salt concentration. In order to gain insight on the structure of the aggregates, and in particular, on the aggregation number and relative orientation of helices in the molecular complexes, the following analogue of bombolitin III was designed and synthesized: Ile-Lys-Bpa-Met-Asp-Ile-Leu-Ala-Lys-Leu-Gly-Lys-Val-Leu-Ala-His-Val-NH₂ Bpa³-B(III) where Bpa is benzoylphenylalanine. Bpa³-B(III) aggregates were investigated by CD and nmr techniques. The observed nuclear Overhauser effect pattern accounts for an antiparallel orientation of two distinct helices. The Bpa side chain allows for the photoinduced cross reaction with any aliphatic proton in spatial proximity. After irradiation, the reaction mixture was analyzed by high performance liquid chromatography and electrospray mass spectrometry. The results confirmed the presence of dimeric and trimeric complexes of bombolitin III formed upon interhelix cross-linking. © 1997 John Wiley & Sons, Inc. Biopoly 42: 147–156, 1997     

Membrane-induced peptide structural changes monitored by infrared and circular dichroism spectroscopy

As more peptide secondary structures deduced by infrared spectroscopy (IR) have been reported in the literature, there have been overlaps in assignments of elements of secondary structure to carbonyl vibrational frequencies. We have investigated this phenomenon with regards to the use of IR for monitoring membrane-induced structural changes using conformationally diverse peptides. These IR studies, complemented by circular dichroism (CD) experiments, revealed that peptide–solvent interactions can mask membrane-induced conformational changes monitored by IR. A structural transition from random coil to α-helix upon the binding of mastoparan X to a membrane was clearly observed by CD but obscured in the amide I region of the IR spectrum. In addition, unlike the buried helical peptides gramicidin D and P16 in micelles, the amide II peak for mastoparan X was absent, likely due to H–D exchange. This suggests information on the peptide's membrane-bound solvent accessibility could be obtained from this region of the spectrum.     

New short cationic antibacterial peptides. Synthesis,biological activity and mechanism of action

We report a theoretical and experimental study on a new series of small-sized antibacterial peptides. Synthesis and bioassays for these peptides are reported here. In addition, we evaluated different physicochemical parameters that modulate antimicrobial activity (charge, secondary structure, amphipathicity, hydrophobicity and polarity). We also performed molecular dynamic simulations to assess the interaction between these peptides and their molecular target (the membrane). Biophysical characterization of the peptides was carried out with different techniques, such as circular dichroism (CD), linear dichroism (LD), infrared spectroscopy (IR), dynamic light scattering (DLS), fluorescence spectroscopy and TEM studies using model systems (liposomes) for mammalian and bacterial membranes. The results of this study allow us to draw important conclusions on three different aspects. Theoretical and experimental results indicate that small-sized peptides have a particular mechanism of action that is different to that of large peptides. These results provide additional support for a previously proposed four-step mechanism of action. The possible pharmacophoric requirement for these small-sized peptides is discussed. Furthermore, our results indicate that a net +4 charge is the adequate for 9 amino acid long peptides to produce antibacterial activity. The information reported here is very important for designing new antibacterial peptides with these structural characteristics.     

IR, MS and CD Investigations on Several Conformationally-Different Histidine Peptides

Solid phase synthetic methodology has been used to prepare four peptides which form a system able to monitor metal ion binding to conformationally different peptides. The 19-residues oligopeptides containing histidine residues in various positions of Ala or Gly sequences, namely GGGGHGGGGHGGGGHGGGG, GGGHGGGHGGGHGGGGGGG, AAAAHAAAAHAAAA-HAAAA, and AAAHAAAHAAAHAAAAAAA have been synthesized by Fmoc strategy and characterized by Fourier transform infrared spectroscopy (FT-IR) as well as electrospray ion trap mass spectrometry (ESI-MS) and circular dichroism (CD). The analysis of CD-spectra of the four peptides revealed that the secondary structure depends much on the amino acid sequence. Biological and medical consequences of conformational changes of metal-bound peptides are further discussed.     

Folding propensity and biological activity of peptides: the effect of a single stereochemical isomerization on the conformational properties of bombinins in aqueous solution

Folding propensities of bombinins H2 and H4, two members of amphibian bombinins H, a family of 17-20 residue alpha-helical peptides, have been investigated by means of circular dichroism (CD) measurements and molecular dynamics (MD) simulations. The two peptides, with primary structure IIGPVLGLVGSALGGLLKKI-NH2 and differing only for the configuration of the second aminoacid (an L-isoleucine in H2 and a D-alloisoleucine in H4) behave rather differently in solution. In particular both CD measurements and MD simulations indicate that bombinin H2 shows a markedly higher tendency to fold. From a careful inspection of MD trajectories it emerges that the stereochemical isomerization mutation of residue 2 to D-alloisoleucine in H4 peptide, drastically decreases its ability to form intrapeptide contacts. MD simulations also indicate that the conformational sampling in both systems derives from a subtle combination of energetic and entropic effects both involving the peptide itself and the solvent. The present results have been finally paralleled with preliminary information on bombinins H2 and H4 biological activity, i.e. interaction with membrane, supporting the hypothesis of an "already folded" conformation in water rather than interfacial folding tenet.     

Phosphorylation loops in synthetic peptides of the human neurofilament protein middle-sized subunit

Peptides containing 13 and 39 amino acid residues and serine-side-chain-phosphorylated (P) analogues thereof, corresponding to human neurofilament protein middle-sized subunit (NF-M), have been synthesized in order to localize the phosphorylation site of this protein. The secondary structure of the nonphosphorylated peptides, determined by circular dichroism (CD) measurements, predicted secondary structural calculations and energy conformational calculations, was suggested to be a series of alternating type I (III) -turns and 3₁₀ or -helices. By contrast, the phosphorylated peptides exhibit a unique conformation, probably due to salt bridges between the phosphoserine and the lysine residues. This has provided the first clear evidence that phosphorylation induces conformational changes among these synthetic peptides and presumably, in NF proteins as well. These phosphorylation loops might be the major recognition sites of the neurofilament protein-directed kinases.     

The investigation of the secondary structure propensities and free-energy landscapes of peptide ligands by replica exchange molecular dynamics simulations

The conformational states of two peptide sequences that bind to staphylococcal enterotoxin B are sampled by replica exchange molecular dynamic (REMD) simulations in explicit water. REMD simulations were treated with 52 replicas in the range of 280–501 K for both peptides. The conformational ensembles of both peptides are dominated by random coil, bend and turn structures with a small amount of helical structures for each temperature. In addition, while an insignificant presence of β-bridge structures were observed for both peptides, the β-sheet structure was observed only for peptide 3. The results obtained from simulations at 300 K are consistent with the experimental results obtained from circular dichroism spectroscopy. From the analysis of REMD results, we also calculated hydrophobic and hydrophilic solvent accessible surface areas for both peptides, and it was observed that the hydrophobic segments of the peptides tend to form bend or turn structures. Moreover, the free-energy landscapes of both peptides were obtained by principal component analysis to understand how the secondary structural properties change according to their complex space. From the free-energy analysis, we have found several minima for both peptides at decreased temperature. For these obvious minima of both peptides, it was observed that the random coil, bend and turn structures are still dominant and the helix, β-bridge or β-sheet structures can appear or disappear with respect to minima. On the other hand, when we compare the results of REMD with conventional MD simulations for these peptides, the configurations of peptide 3 might be trapped in energy minima during the conventional MD simulations. Hence, it can be said that the REMD simulations have provided a sufficiently high sampling efficiency.     

Induced conformational states of amphipathic peptides in aqueous/lipid environments.

Specific conformational effects have been reported for amphipathic model peptides upon binding of defined hydrophobic domains to nonpolar stationary phases during reversed-phase high performance liquid chromatography (RP-HPLC). Such induced conformations are found to be especially pronounced for peptides that are amphipathic in an alpha-helical conformation. Such induced amphipathic conformations resulted in substantially later elution than predicted using amino acid-based retention coefficients. In the present study, the induced conformational behavior of model peptides observed during RP-HPLC was correlated with their secondary structure as determined by circular dichroism (CD) spectroscopy in both aqueous solution and C18-mimetic environments. The experimental retention times of the peptides studied were found to correlate with their CD spectra in the presence of lipids, whereas a poor correlation was observed with their CD spectra in the presence of trifluoroethanol. A new approach was developed to evaluate the induction of secondary structure in peptides due to interactions at aqueous/lipid interfaces, which involves the measurement of the CD ellipticities of peptides bound to a set of C18-coated quartz plates. An excellent correlation was found in this environment between the RP-HPLC retention times and CD ellipticities of the bound peptides.     

Chemical glycosylation of peptide T at natural and artificial glycosylation sites stabilizes or rearranges the dominant reverse turn structure.

Peptide T (H-Ala-Ser-Thr-Thr-Thr-Asn-Tyr-Thr-OH), a fragment of HIV gp120, has been reported to inhibit binding of the virus to the CD4 receptor. The peptide assumes a beta-turn secondary structure, and stabilization of the conformation may increase the biological activity. We synthesized the octapeptide and its C-terminal pentapeptide fragment, unmodified and glycosylated, when monosaccharides were walked through the molecules. Incorporation of the sugar into the longer peptide resulted in the stabilization of the type I (III) beta-turn, as indicated by circular dichroism measurements. While N-terminal glycosylation of the shorter peptide also stabilized the type I (III) beta-turn, the circular dichroism spectra revealed slightly different type II beta-turn structures when the carbohydrate moiety was incorporated into mid-chain or C-terminal positions. Modification of biologically active reverse-turn structures by glycosylation offers a viable alternative to the peptide mimetics approach in drug design.     

Conformation and interactions of bombolitin I analogues with SDS micelles and phospholipid vesicles: CD,fluorescence, two-dimensional NMR and computer simulations

Bombolitins are five structurally related heptadecapeptides acting at the membrane level able to lyse erythrocytes and liposomes and to enhance the activity of phospholipase A ₂(PLA₂). In the presence of SDS or phospholipid vesicles bombolitins are able to form amphiphilic α-helical structures and this property seems to be the major determinant of bioactivity. In order to test the model of interaction between bombolitin I and membranes, an analogue was synthesized in which all the lysines were replaced by arginines: ([Arg^2,9,12, Ile¹⁰] bornbolitin I). The design ofthis sequence allowed the synthesis of a second analogue through a specijic postsynthetic dansylation at the ?-amino group qf a lysine residue replacing the original leucine residue at position 7. The, first analogue was, fiilly characterized by CD and two-dimensional nmr in the presence of SDS or phospholipid vesicles. The peptide, folds into an amphiphilic α-helical confbrrnation with the helical segment spanning the central part of the sequencefrom Ile³ to His¹⁶. This behavior is identical to that observed for the native sequence. The replacement of Iysine residues by arginine hus no detectable effect on the conformational prderence of the peptide chain. By CD and fluorescence spectroscopy measurements, the fluorophore-containing analogue [Arg^2,9,12, Lys⁷(?-dansyl)] bombolitin I also folded into the α-helical conformation in the presence of SDS micelles or phospholipid vesicles. In particular, the dansyl fluorophore, which is located approximately in the middle of the apolar surface ojthe amphiphilic helix, is clearly buried in a hydrophobic environment when the peptide is bound to phospholipid vesicles. These findings support the hypothesis that the peptide helices are oriented parallel to the vesicle surface. © 1995 John Wiley & Sons, Inc.     

Conformation of retro-bombolitin I in aqueous solution containing surfactant micelles

Bombolitins are five naturally occurring heptadecapeptides acting at the membrane level and able to increase the activity of phospholipase A₂. As for other peptides with similar function, the biological activity of bombolitins seems to be mainly due to their ability to form amphipathic helical structures. We synthesized and tested the retro sequence of bom-bolitin I (retro-bombolitin I). This peptide showed an activity similar to that of the natural sequence and was able to adopt a helical structure in the presence of an amphipathic environment consisting of SDS micelles. The secondary structure of this peptide was fully characterized by CD and nmr spectroscopy. © 1994 John Wiley & Sons, Inc.     

Conformational changes upon calcium binding and phosphorylation in a synthetic fragment of calmodulin

We have recently investigated by far-UV circular dichroism (CD) the effects of Ca(2+) binding and the phosphorylation of Ser 81 for the synthetic peptide CaM [54-106] encompassing the Ca(2+)-binding loops II and III and the central alpha helix of calmodulin (CaM) (Arrigoni et al., Biochemistry 2004, 43, 12788-12798). Using computational methods, we studied the changes in the secondary structure implied by these spectra with the aim to investigate the effect of Ca(2+) binding and the functional role of the phosphorylation of Ser 81 in the action of the full-length CaM. Ca(2+) binding induces the nucleation of helical structure by inducing side chain stacking of hydrophobic residues. We further investigated the effect of Ca(2+) binding by using near-UV CD spectroscopy. Molecular dynamics simulations of different fragments containing the central alpha-helix of CaM using various experimentally determined structures of CaM with bound Ca(2+) disclose the structural effects provided by the phosphorylation of Ser 81. This post-translational modification is predicted to alter the secondary structure in its surrounding and also to hinder the physiological bending of the central helix of CaM through an alteration of the hydrogen bond network established by the side chain of residue 81. Using quantum mechanical methods to predict the CD spectra for the frames obtained during the MD simulations, we are able to reproduce the relative experimental intensities in the far-UV CD spectra for our peptides. Similar conformational changes that take place in CaM [54-106] upon Ca(2+) binding and phosphorylation may occur in the full-length CaM.     

Conformational behavior of temporin A and temporin L in aqueous solution: a computational/experimental study

Molecular dynamics (MD) simulations and circular dichroism (CD) experiments were carried out on aqueous temporin A and L, two short peptides belonging to an interesting class of natural substances known to be active mainly against Gram-positive/negative bacteria and fungi. Experimental results indicate the higher propensity of temporin L, with respect to temporin A, in forming alpha-helical structures. These results were revisited by long-timescale MD simulations, in which their alpha-helical propensity was investigated in the absence of trifluoroethanol. Results clearly show the higher stability of alpha-helix conformations in temporin L; moreover, an interestingly strong mechanical analogy emerges since both temporins show the same residue interval (from 7 to 10) as the most energetically accessible for alpha-helix formation. Such studies provide some intriguing structural and mechanical evidence that may help in better understanding and rationalizing the conformational behaviour of temporins in water solution and, ultimately, the inner principles of their microbial targets selectivity and mechanism of action at the level of cell membranes.     

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.     

Spectral characteristics of cadmium-containing phytochelatin complexes isolated from Schizosaccharomyces pombe.

Phytochelatins, heavy-metal-containing peptides with structures (gamma EC)nG, where n = 2-8, have been isolated from higher plants and the fission yeast Schizosaccharomyces pombe. The present work describes the isolation and characterization of several naturally occurring mixed complexes of these peptides from S. pombe exposed to 1 mM CdCl2. A lower-molecular-mass fraction from Sephadex G-50 chromatography yielded three distinct species on further fractionation. HPLC chromatography revealed the presence of peptides with n = 1-4 in varying amounts in these three complexes, referred to as complexes I, II and III. Stoichiometries are proposed for these complexes, based on [Cd], [SH], [S2-] and the amino acid content. Ultraviolet absorption and magnetic circular dichroism spectra of complexes II and III are similar, whereas the CD spectra of these two complexes are strikingly different. Compared to both complexes II and III, the CD bands of complex I are relatively weak. Ultraviolet absorption, CD and magnetic circular dichroism spectra provide a basis for the discussion of structural differences in these complexes.     

A conformational switch is associated with receptor affinity in peptides derived from the CD4-binding domain of gp120 from HIV I

A 15-residue region within the CD4-binding domain of gp120 from HIV I was identified with use of folding algorithms as conserving the potential for forming a particular secondary structure throughout 11 sequenced HIV strains. The region chosen has a potential for forming both beta-sheet and alpha-helix; the helical form would be amphipathic with the five hydrophobic residues all totally or functionally conserved. Five peptides were synthesized corresponding to this region in strain LAV and the strain most highly divergent from it in primary structure (Z3) plus three additional peptides with critical substitutions in the LAV sequence. The conformation of these five peptides was examined under various conditions with circular dichroism, and the results were compared with the ability of each peptide to bind to a CD4-expressing strain of HeLa cells (HeLa T4). In solution, the unmodified peptides exhibit a bistable structure, existing as beta-sheet in dilute buffer and converting to alpha-helix under more apolar conditions. The transition is reversible and sharp, occurring at a particular point in the polar/apolar gradient with virtually no intermediate state. The ability to undergo this bistable flip is closely associated with binding ability, amino acid substitutions that eliminate binding ability also eliminating the switch, and vice versa. The transition thus may reflect conformational changes occurring in this region of gp120 as it binds to the CD4 receptor.