Conformational studies of anionic melittin analogues: effect of peptide concentration, pH, ionic strength, and temperature--models for protein folding and halophilic proteins.

Melittin (MLT), a 26-residue cationic (net charge +5 at pH 7.2) peptide from bee venom, is well known to be a monomeric, approximately random coil; but when its charges are reduced by titration, by acetylation (net charge +2) or succinylation (net charge -2), or by screening by salt, it goes over to tetrameric alpha-helix. The conversion is promoted by raising the peptide concentration. The tetramer is held together by hydrophobic forces. We have changed the net charge to -6 by acylation with acetylcitric anhydride (a new acylating agent); this anionic derivative forms tetrameric helix at neutral pH, without salt, and at relatively low concentration, conditions under which the cationic MLT does not become helical. Thus, a high net charge is not sufficient to prevent association and helix formation. We have synthesized an anionic melittin analogue of MLT (E-MLT; net charge -4) in which all five lysine and arginine residues are replaced with glutamate, and acetyl and succinyl derivatives of E-MLT (net charges -5 and -6). All three of these are resistant to helix formation. They require much higher NaCl or NaClO4 concentration for helix formation than does MLT. Even CaCl2, MgCl2, and spermine.4HCl are less effective in helicizing E-MLT than MLT. MLT, at pH 7.2, shows increasing helix as the peptide concentration increases (8-120 microM), but E-MLT and its acyl derivatives do not. MLT and acylated MLTs in the helical tetramer show both cold- and heat-induced unfolding, with maximum stability near room temperature. At high temperature, a significant amount of residual structure remains. Heating (to 100 degrees C) monomeric MLT (i.e., MLT at low concentration) or E-MLT results in a monotonic increase in negative ellipticity. In 1.0 M NaCl, E-MLT (at sufficiently high concentration) also shows cold and hot unfolding. The results are discussed in respect to charge-charge and charge-dipole interactions, and hydrophobic effects. E-MLT is also discussed in relation to proteins of halophilic bacteria, which have higher proportions of anionic residues than do corresponding proteins of nonhalophiles.     

The effect of counterions on melittin aggregation.

Melittin, a surface-active polypeptide from bee venom, has an overall hydrophobic N-terminus, with basic residues clustered at the C-terminus. In aqueous solution melittin exists as a mixture of monomer and tetramer, the monomer adopting a predominantly random-coil configuration, whereas the tetramer is rich in alpha-helix. The tendency of melittin to aggregate is dependent on the counter-anions present in solution, the effect being most marked with phosphate, decreasing in the order HPO4(2-) greater than SO4(2-) greater than ClO4- greater than Cl-.     

Charge repulsion in the conformational stability of melittin.

Electrostatic repulsion between positively charged groups has been suggested to be critical in determining the conformation of melittin. To clarify the role of repulsive forces, we prepared a series of succinylated melittins, an acetylated melittin, and a synthetic melittin mutant, with various degrees of charge repulsion. The conformation of the melittin derivatives was examined by far-UV circular dichroism under various conditions of pH and salt at 20 degrees C. The stability of the tetrameric helical state was found to be dependent on the net charge of the peptides. The charge repulsive forces destabilized the helical state of intact melittin by 600 cal/(charge.mol of tetramer). This value was close to the corresponding one (450 cal/(charge.mol)) obtained for the acidic molten globule of horse cytochrome c [Goto, Y., & Nishikiori, S. (1991) J. Mol. Biol. 222, 679-686], which has a molecular weight and a net charge comparable to those of the tetrameric melittin. Small-angle X-ray scattering of the tetrameric melittin and the molten globule of cytochrome c showed that the two states are also comparable to each other in the radius of gyration. These results suggest that the contribution of electrostatic repulsion to the conformational stability of melittin is similar to that of the molten globule.     

Influence of the arrangement and secondary structure of melittin peptides on the formation and stability of toroidal pores

Melittin interactions with lipid bilayers and melittin formed pores are extensively studied to understand the mechanism of the toroidal pore formation. Early experimental studies suggested that melittin peptide molecules are anchored by their positively charged residues located next to the C-terminus to only one leaflet of the lipid bilayer (asymmetric arrangement). However, the recent non-linear spectroscopic experiment suggests a symmetric arrangement of the peptides with the C-terminus of the peptides anchored to both bilayers. Therefore, we present here a computational study that compares the effect of symmetric and asymmetric arrangements of melittin peptides in the toroidal pore formation. We also investigate the role of the peptide secondary structure during the pore formation. Two sets of the symmetric and asymmetric pores are prepared, one with a helical peptide from the crystal structure and the other set with a less helical peptide. We observe a stable toroidal pore being formed only in the system with a symmetric arrangement of the less helical peptides. Based on the simulation results we propose that the symmetric arrangement of the peptides might be more favorable than the asymmetric arrangement, and that the helical secondary structure is not a prerequisite for the formation of the toroidal pore.     

Antimicrobial peptide-lipid binding interactions and binding selectivity

Surface pressure measurements, external reflection-Fourier transform infrared spectroscopy, and neutron reflectivity have been used to investigate the lipid-binding behavior of three antimicrobial peptides: melittin, magainin II, and cecropin P1. As expected, all three cationic peptides were shown to interact more strongly with the anionic lipid, 1,2 dihexadecanoyl-sn-glycerol-3-(phosphor-rac-(1-glycerol)) (DPPG), compared to the zwitterionic lipid, 1,2 dihexadecanoyl-sn-glycerol-3-phosphocholine (DPPC). All three peptides have been shown to penetrate DPPC lipid layers by surface pressure, and this was confirmed for the melittin-DPPC interaction by neutron reflectivity measurements. Adsorption of peptide was, however, minimal, with a maximum of 0.4 mg m(-2) seen for melittin adsorption compared to 2.1 mg m(-2) for adsorption to DPPG (from 0.7 microM solution). The mode of binding to DPPG was shown to depend on the distribution of basic residues within the peptide alpha-helix, although in all cases adsorption below the lipid layer was shown to dominate over insertion within the layer. Melittin adsorption to DPPG altered the lipid layer structure observed through changes in the external reflection-Fourier transform infrared lipid spectra and neutron reflectivity. This lipid disruption was not observed for magainin or cecropin. In addition, melittin binding to both lipids was shown to be 50% greater than for either magainin or cecropin. Adsorption to the bare air-water interface was also investigated and surface activity followed the trend melittin>magainin>cecropin. External reflection-Fourier transform infrared amide spectra revealed that melittin adopted a helical structure only in the presence of lipid, whereas magainin and cecropin adopted helical structure also at an air-water interface. This behavior has been related to the different charge distributions on the peptide amino acid sequences.     

Melittin: a Membrane-active Peptide with Diverse Functions

Melittin is the principal toxic component in the venom of the European honey bee Apis mellifera and is a cationic, hemolytic peptide. It is a small linear peptide composed of 26 amino acid residues in which the amino-terminal region is predominantly hydrophobic whereas the carboxy-terminal region is hydrophilic due to the presence of a stretch of positively charged amino acids. This amphiphilic property of melittin has resulted in melittin being used as a suitable model peptide for monitoring lipid–protein interactions in membranes. In this review, the solution and membrane properties of melittin are highlighted, with an emphasis on melittin–membrane interaction using biophysical approaches. The recent applications of melittin in various cellular processes are discussed.     

NMR studies on the monomer–tetramer transition of melittin in an aqueous solution at high and low temperatures

Melittin, a peptide of 26 amino acid residues, has been used as a model peptide for protein folding and unfolding, and extensive research has been done into its structure and conformational stability. Circular dichroism (CD) studies have demonstrated that melittin in an aqueous solution undergoes a transition from a helical tetramer to a random coil monomer not only by heating but also by cooling from room temperature (i.e., heat- and cold-denaturation, respectively). The heat-denaturation has been also examined by nuclear magnetic resonance (NMR) experiments, however, no NMR data have been presented on the cold-denaturation. In this paper, using proton ((1)H) NMR spectroscopy, we show that melittin undergoes conformational transitions from the monomer to the tetramer to the monomer by elevating temperature from 2 to 70 °C. Only melittin including a trans proline peptide bond participates in the transitions, whereas melittin including a cis proline one does not. The tetramer has maximum conformation stability at around 20 °C, and cooperativity of the heat-denaturation is extremely low.     

Effects of fluidity on the ensemble structure of a membrane embedded α‐helical peptide

Melittin, the main hemolytic component of honeybee venom, is unfolded in an aqueous environment and folds into an α‐helical conformation in a lipid environment. Membrane fluidity is known to affect the activity and structure of melittin. By combining two structurally sensitive optical methods, circular dichroism (CD) and deep‐ultraviolet resonance Raman spectroscopy (dUVRR), we have identified distinct structural fluctuations in melittin correlated with increased and decreased 1,2‐dimyristoyl‐sn‐glycero‐3‐phosphocholine bilayer fluidities. CD spectra have reduced intensity at temperatures above 22°C and high concentrations of the cholesterol analog 5α‐cholestan‐3β‐ol indicating distortions in the α‐helical structure under these conditions. No increase in the amide S is observed in the temperature‐dependent dUVRR spectra, suggesting an increase in 3₁₀‐helical structure with increasing temperatures above 22°C. However, incorporation of 25 mol% 5α‐cholestan‐3β‐ol resulted in a small increase in the amide S intensity indicating partial unfolding of melittin. © 2014 Wiley Periodicals, Inc. Biopolymers 101: 895–902, 2014.     

Phospholipases: melittin facilitation of bee venom phospholipase A2-catalyzed hydrolysis of unsonicated lecithin liposomes.

Melittin isolated from the venom of the common honey bee is a potent activator for bee venom phospholipase A₂-catalyzed hydrolysis of unsonicated liposomes of egg phosphatidyl choline. At 37 °C and pH 8, the rate of this enzymatic reaction is increased approximately 300-fold by the addition of 8 × 10^?5m melittin. The magnitude of facilitation of the phospholipase A₂ reaction is much greater than that previously reported by other workers for systems involving sonicated egg phosphatidyl choline liposomes or Escherichia coli membrane fragments as substrates. Melittin having lysines quantitatively modified through reaction with methyl acetimidate is as effective a potentiator of phospholipase A₂ activity as the unmodified material. The same result was obtained for melittin in which the single tryptophan residue was modified. Melittin modified by succinylation retained approximately 50% of its capacity to facilitate phospholipase A₂ activity. In contrast, a modified melittin in which the C-terminal four amino residues were removed, acetimidated des(23–26)melittin, is a very poor activator, as is a mixture of this peptide with the C-terminal tetrapeptide. In contrast to the results with egg lecithin liposomes, melittin has little influence on the susceptibility of monomolecular aqueous solutions of dihexanoylphosphatidyl choline to phospholipase A₂ attack.     

Melittin inhibition and uncoupling of spinach thylakoids

Melittin has been found to inhibit a photosystem I reaction (diaminodurene to methylviologen) in much the same way that it inhibits sequential electron transport through both photosystems (water to methylviologen). At much lower concentrations melittin uncouples ATP synthesis. Melittin inhibition and uncoupling are found to be irreversible indicating very tight association between melittin and the membrane. Melittin inhibits the light-induced proton pump and the light-induced thylakoid Mg⁺²-ATPase activity as well as the Ca⁺²-ATPase activity of isolated coupling factor. The results are consistent with both a conventional model where the uncoupling by melittin is related to its lytic properties and a model wherein melittin interacts directly with coupling factor causing an uncoupling condition.     

Primary structure of peptides and ion channels. Role of amino acid side chains in voltage gating of melittin channels.

Melittin produces a voltage-dependent increase in the conductance of planar lipid bilayers. The conductance increases when the side of the membrane to which melittin has been added (cis-side) is made positive. This paper reports observations on the effect of modifying two positively charged amino acid residues within the NH2-terminal region of the molecule: lysine at position 7 (K7), and the NH2-terminal glycine (G1). We have synthesized melittin analogues in which K7 is replaced by asparagine (K7-N), G1 is blocked by a formyl group (G1-f), and in which both modifications of the parent compound were introduced (G1-f, K7-N). The time required to reach peak conductance during a constant voltage pulse was shorter in membranes exposed to the analogues than in membranes modified by melittin. The apparent number of monomers producing a conducting unit for [K7-N]-melittin and [G1-f]-melittin, eight, was found to be greater than the one for [G1-f], K7-N]-melittin and for melittin itself, four. The apparent gating charge per monomer was less for the analogues, 0.5-0.3 than for melittin, one. Essentially similar results were obtained with melittin analogues in which the charge on K7 or G1 or both was blocked by an uncharged N-linked spin label. These results show that the positive charges in the NH2-terminal region of melittin play a major but not exclusive role in the voltage gating of melittin channels in bilayers.     

Conformational changes in melittin upon complexation with an anionic melittin analog.

Melittin and its Glu-(7,21,22,23,24) analog upon mixing in equimolar concentrations form a hybrid oligomer with significant helical structure, in conditions in which each peptide separately adopts a largely disordered structure. The hybrid exhibits both cold- and heat-induced denaturations similar to the phenomena exhibited by proteins. The hybrid also retains significant residual structure at higher temperature, similar to the 'molten globular state' that has been suggested for protein. Melittin, at concentrations in which it forms helical tetramers, also exhibits these phenomena and may be used as a model for protein-denaturation studies.     

Effect of acetylation and permethylation on the conformation and candidacidal activity of salivary histatin-5

Summary Salivary histatins provide the non-immune defense against oral pathogens such as Candida albicans. The structural requirements of histatin-5 for anticandida activity were examined with respect to its ability to adopt helical structures, its electrostatic interactions and the hydrogen-bonding potency of its basic residues. For this purpose, the lysine and/or histidine residues of histatin-5 were chemically modified by acetylation and permethylation. Acetylated histatin-5 retained its ability to adopt helical structures in 2,2,2-trifluoroethanol, but completely lost its ability to kill yeast cells. In contrast, permethylated histatin-5 shows very little tendency to adopt a helical structure, but retained significant anticandida activity. The results suggest that the candidacidal activity can arise even when the histatin does not have the ability to adopt helical structures. The candidacidal activity of the derivatives is discussed in terms of electrostatic interactions and hydrogen-bonding potency.     

Conformational studies of parathyroid hormone (PTH)/PTH‐related protein (PTHrP) point‐mutated hybrids

The N‐terminal 1–34 segments of both parathyroid hormone (PTH) and parathyroid hormone‐related protein (PTHrP) bind and activate the same membrane receptor in spite of major differences between the two hormones in their amino acid sequence. Recently, it was shown that in (1–34)PTH/PTHrP segmental hybrid peptides, the N‐terminal 1–14 segment of PTHrP is incompatible with the C‐terminal 15–34 region of PTH leading to substantial reduction in potency. The sites of incompatibility were identified as positions 5 in PTH and 19 in PTHrP. In the present paper we describe the synthesis, biological evaluation, and conformational characterization of two point‐mutated PTH/PTHrP 1–34 hybrids in which the arginine residues at positions 19 and 21 of the native sequence of PTHrP have been replaced by valine (hybrid V²¹) and glutamic acid (hybrid E¹⁹), respectively, taken from the PTH sequence. Hybrid V²¹ exhibits both high receptor affinity and biological potency, while hybrid E¹⁹ binds weakly and is poorly active. The conformational properties of the two hybrids were studied in aqueous solution containing dodecylphosphocholine (DPC) micelles and in water/2,2,2‐trifluoroethanol (TFE) mixtures. Upon addition of TFE or DPC micelles to the aqueous solution, both hybrids undergo a coil‐helix transition. The maximum helix content in 1 : 1 water/TFE, obtained by CD data for both hybrids, is ∼ 80%. In the presence of DPC micelles, the maximum helix content is ∼ 40%. The conformational properties of the two hybrids in the micellar system were further investigated by combined 2D‐nmr, distance geometry (DG), and molecular dynamics (MD) calculations. The common structural motif, consisting of two helical segments located at N‐ and C‐termini, was observed in both hybrids. However, the biologically potent hybrid V²¹ exhibits two flexible sites, centered at residues 12 and 19 and connecting helical segments, while the flexibility sites in the weakly active hybrid E¹⁹ are located at position 11 and in the sequence 20–26. Our findings support the hypothesis that the presence and location of flexibility points between helical segments are essential for enabling the active analogs to fold into the bioactive conformation upon interaction with the receptor. © 1999 John Wiley & Sons, Inc. Biopoly 50: 525–535, 1999     

Melittin and the 8-26 fragment. Differences in ionophoric properties as measured by monolayer method

Melittin is a major (approximately 50%) protein component of bee venom. This peptide is an amphiphilic protein, because, while the amino acid residues 1-20 are predominantly hydrophobic (with the exception of Lys-7), residues 21-26 are hydrophilic. The binding properties to vesicles and lipid bilayers of melittin have provided much useful information regarding biological (hemolytic) activity (Habermann, E., 1972, Science [Wash. DC], 177:314-322). Recent studies have convincingly established that the melittin monolayer (at air-water interface) model membrane system allows one to analyze the various forces present in such structures. We present comparative monolayer studies of melittin and the peptide fragment 8-26 regarding the channel formation for the selective anion (Cl-) penetration in monolayers, analogous to melittin (tetramer) channel function in lipid bilayer. The differences in surface pressure and surface potential of monolayers between native melittin and the 8-26 fragment suggest that these may be ascribed to Lys-7.     

Structural and thermodynamic analyses of the interaction between melittin and lipopolysaccharide

Lipopolysaccharide (LPS), the major constituent of the outer membrane of Gram-negative bacteria, is the very first site of interactions with the antimicrobial peptides. In this work, we have determined a solution conformation of melittin, a well-known membrane active amphiphilic peptide from honey bee venom, by transferred nuclear Overhauser effect (Tr-NOE) spectroscopy in its bound state with lipopolysaccharide. The LPS bound conformation of melittin is characterized by a helical structure restricted only to the C-terminus region (residues A15-R24) of the molecule. Saturation transfer difference (STD) NMR studies reveal that several C-terminal residues of melittin including Trp19 are in close proximity with LPS. Isothermal titration calorimetry (ITC) data demonstrates that melittin binding to LPS or lipid A is an endothermic process. The interaction between melittin and lipid A is further characterized by an equilibrium association constant (Ka) of 2.85 x 10(6) M(-1) and a stoichiometry of 0.80, melittin/lipid A. The estimated free energy of binding (delta G0), -8.8 kcal mol(-1), obtained from ITC experiments correlates well with a partial helical structure of melittin in complex with LPS. Moreover, a synthetic peptide fragment, residues L13-Q26 or mel-C, derived from the C-terminus of melittin has been found to contain comparable outer membrane permeabilizing activity against Escherichia coli cells. Intrinsic tryptophan fluorescence experiments of melittin and mel-C demonstrate very similar emission maxima and quenching in presence of LPS micelles. The Red Edge Excitation Shift (REES) studies of tryptophan residue indicate that both peptides are located in very similar environment in complex with LPS. Collectively, these results suggest that a helical conformation of melittin, at its C-terminus, could be an important element in recognition of LPS in the outer membrane.     

Conformational aspects of polypeptides. XXV. Solvent and temperature effects on the conformations of copolymers of benzyl and methyl L-aspartate with nitrobenzyl L-aspartate

A series of copolymers of β-p-nitrobenzyl L -aspartate with β-benzyl L -aspartate and with β-mcthyl L -aspartatc in helix-supporting and helix-breaking conditions have been reexamined by using ultraviolet isotropic, absorption, optical rotatory dispersion, and circular dichroism techniques. Many different conformations are apparent, depending on solvent and temperature. Chloroform, trifluoroethanol, and methylene dichloride support the left-handed helical conformation of the copolymers containing less than about 20 mole-% nitroaromatic residues and the right-handed helical conformation of the copolymers containing more than approximately 30 mole-% nitroaromatic residues. In trifluoroacetic acid all the copolymers are in a random-coil conformation. In hexa-fluoroacetone trihydrate and in trimethyl phosphate, the copolypeptides with low nitroaromatic residues content are predominantly in a disordered conformation, while those with high nitroaromatic residues content show a right-handed helical array. Reversible helix-ramlom-coil transitions are observed with increasing temperature in trimethyl phosphate. An example of right-handed-left-handed helix reversible transition with temperature is reported in a chloroform-trimethyl phosphate (2:1) mixture. Nitrobenzyl-nilrobenzyl side-chain interactions in chloroform, but not in trifluoroacetic acid or in trimethyl phosphate, have been confirmed. For the first time we report the circular dichroism spectra in which the n-π* peptide band of a left-handed helical conformation is almost completely evident.     

The Structure of a Melittin-Stabilized Pore

Melittin has been reported to form toroidal pores under certain conditions, but the atomic-resolution structure of these pores is unknown. A 9-μs all-atom molecular-dynamics simulation starting from a closely packed transmembrane melittin tetramer in DMPC shows formation of a toroidal pore after 1 μs. The pore remains stable with a roughly constant radius for the rest of the simulation. Surprisingly, one or two melittin monomers frequently transition between transmembrane and surface states. All four peptides are largely helical. A simulation in a DMPC/DMPG membrane did not lead to a stable pore, consistent with the experimentally observed lower activity of melittin on anionic membranes. The picture that emerges from this work is rather close to the classical toroidal pore, but more dynamic with respect to the configuration of the peptides.     

Interactions of melittin, a preprotein model, with detergents.

Bee venom melittin is a water-soluble tetramer of identical polypeptide chains. Each chain has 26 residues. The 20 N-terminal residues are hydrophobic and the 6 C-terminal residues are basic. Melittin has been shown to integrate into natural and synthetic membranes and to lyse a wide variety of cells. To understand how a water-soluble protein can spontaneously partition into a membrane, we have studied the interaction of melittin with micelles of deoxycholate (DOC), Brij 58, and sodium dodecyl sulfate (NaDodSO4). Circular dichroism spectra showed that NaDodSO4, an ionic detergent, and Brij 58, a nonionic detergent, caused similar major changes in the protein's conformation. Gel filtration studies revealed that melittin forms mixed micelles with either Brij or DOC. The melittin-DOC mixed micelles have 2 mol of DOC per mol of melittin. Cross-linking studies with dimethyl suberimidate confirmed that the protein is a tetramer and showed that it becomes monomeric either in mixed micelles with Brij or DOC or in butanol. Despite this major structural change of melittin in the presence of an amphiphile, the covalently cross-linked form is as active in human erythrocyte lysis as the native protein.