The structure of melittin in lipid bilayer membranes

0.15 M inorganic phosphate dramatically increased the α-helix content of melittin in aqueous solution.When melittin interacted with egg yolk phosphatidylcholine liposomes in the absence of inorganic phosphate, it was converted to an α-helix rich form, as postulated by Dawson et al. (Dawson, C.R., Drake, A.F. Helliwell, J. and Hider, R.C. (1978) Biochim. Biophys. Acta 510, 75–86).     

The membrane-induced structure of melittin is correlated with the fluidity of the lipids

The effect of the bee toxin melittin on DMPC dynamics in fast-tumbling bicelles has been investigated. The (13)C R(1) and (13)C-(1)H NOE relaxation parameters for DMPC were used to monitor the effect of melittin and cholesterol on lipid dynamics. It was found that melittin has the largest effect on the DMPC mobility in DMPC/DHPC bicelles, while less effect was observed in cholesterol-doped bicelles, or in bicelles made with CHAPS, indicating that the rigidity of the membrane affects the melittin-membrane interaction. CD spectra were analysed in terms of cooperativity of the alpha-helix to random coil transition in melittin, and these results also indicated similar differences between the bicelles. The study shows that bicelles can be used to investigate lipid dynamics by spin relaxation, and in particular of peptide-induced changes in membrane fluidity.     

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-.     

Conformation and dynamics of melittin bound to magnetically oriented lipid bilayers by solid-state (31)P and (13)C NMR spectroscopy

The conformation and dynamics of melittin bound to the dimyristoylphosphatidylcholine (DMPC) bilayer and the magnetic orientation in the lipid bilayer systems were investigated by solid-state (31)P and (13)C NMR spectroscopy. Using (31)P NMR, it was found that melittin-lipid bilayers form magnetically oriented elongated vesicles with the long axis parallel to the magnetic field above the liquid crystalline-gel phase transition temperature (T(m) = 24 degrees C). The conformation, orientation, and dynamics of melittin bound to the membrane were further determined by using this magnetically oriented lipid bilayer system. For this purpose, the (13)C NMR spectra of site-specifically (13)C-labeled melittin bound to the membrane in the static, fast magic angle spinning (MAS) and slow MAS conditions were measured. Subsequently, we analyzed the (13)C chemical shift tensors of carbonyl carbons in the peptide backbone under the conditions where they form an alpha-helix and reorient rapidly about the average helical axis. Finally, it was found that melittin adopts a transmembrane alpha-helix whose average axis is parallel to the bilayer normal. The kink angle between the N- and C-terminal helical rods of melittin in the lipid bilayer is approximately 140 degrees or approximately 160 degrees, which is larger than the value of 120 degrees determined by x-ray diffraction studies. Pore formation was clearly observed below the T(m) in the initial stage of lysis by microscope. This is considered to be caused by the association of melittin molecules in the lipid bilayer.     

Kinetics and mechanism of hemolysis induced by melittin and by a synthetic melittin analogue.

The cytotoxic peptide from honeybee venom, melittin, and a synthetic peptide analogue of it lyse human erythrocytes in a biphasic process. The kinetics of the lysis in 0.30 M sucrose, 0.01 M sodium phosphate, pH 7.30 at 4 degrees C were investigated. Our results show that melittin rapidly binds to the outer surface of the erythrocyte membrane, and the surface-bound monomers produce transient openings through which approximately 40 hemoglobin molecules can escape. Concomitantly, the melittin loses its ability to effect the process, presumably by translocation through the bilayer. The half-life for this process is 1.2 min. In a much slower process, dimers of this internalized melittin again produce transient membrane openings in a steady state. On a molar basis, the synthetic peptide analogue produces a fast process comparable to that caused by melittin, but is more efficient in the slow phase. Escape of hemoglobin and of carbonic anhydrase through the openings is diffusion controlled. These results suggest that the functional units necessary for the activity of melittin-like cytotoxic peptides are a 20 amino acid amphiphilic alpha-helix with a hydrophobic:hydrophilic ratio greater than 1 and a short segment with a high concentration of positive charges.     

Conformational studies on a peptide fragment representing the RNA-binding N-terminus of a viral coat protein using circular dichroism and NMR spectroscopy

Conformational studies were performed on a synthetic pentacosapeptide representing the RNA-binding N-terminal region of the coat protein of cowpea chlorotic mottle virus. The effects of ionic strength, addition of (oligo)phosphates and temperature on the conformation of this highly positively charged peptide containing six arginines and three lysines were studied. CD experiments show that the peptide has 15-18% alpha-helical conformation and about 80% random-coil conformation in the absence of inorganic salt at 25 degrees C, and 20-21% alpha-helical conformation under the same conditions at 10 degrees C. Addition of inorganic salts results in an increase of alpha-helix content, up to 42% in the presence of oligophosphate with an average chain length of 18 phosphates, which was used as an RNA analog. NMR experiments show that the alpha-helix formation starts in the region between Thr9 and Gln12, and is extended in the direction of the C terminus. Relaxation measurements show that binding to oligophosphates of increasing length results in reduced internal mobilities of the positively charged side chains of the arginyl and lysyl residues and of the side chain of Thr9 in the alpha-helical region. The alpha-helix formation in the N-terminal part of this viral coat protein upon binding of phosphate groups to the positively charged side chains is suggested to play an essential role in RNA binding.     

Orientation of melittin in phospholipid bilayers. A polarized attenuated total reflection infrared study.

The helical order parameter of the 26-residue amphiphilic bee venom peptide melittin was measured by polarized attenuated total reflection infrared spectroscopy (ATR-IR) in dry phospholipid multibilayers (MBLs) and when bound to single supported planar bilayers (SPBs) under D2O. Melittin adopted an alpha-helical conformation in MBLs of dipalmitoyl-phosphatidylcholine (DPPC), 1-palmitoyl-2-oleoyl-phosphatidylcholine (POPC), a 4:1 mixture of POPC and 1-palmitoyl-2-oleoyl-phosphatidylglycerol (POPG), and when bound to SPBs of POPC:POPG (4:1). The order parameter of the alpha-helix in the bilayers depended mainly on the type of membrane preparation, and only little on the phospholipid composition of the bilayers. On hydrated SPBs, the helical order parameter was negative, indicating that the alpha-helix long axis of melittin was preferentially oriented parallel to the plane of the supported membrane. However, in dry MBLs, the helical order parameter was positive, indicating that the alpha-helix of melittin was preferentially oriented parallel to the phospholipid fatty acyl chains. It is concluded that the orientation of melittin in membranes depends on the degree of hydration of the model membranes rather than on the technique which is used for its determination. ATR-IR spectroscopy of polypeptides in or associated with supported planar membranes in D2O may become a useful tool for the determination of their orientation in and on membranes.     

Characterization of selectively 13C-labeled synthetic melittin and melittin analogues in isotropic solvents by circular dichroism, fluorescence, and NMR spectroscopy

The spectroscopic and functional characterization of 13C-labeled synthetic melittin and three analogues is described. Selectively 13C-enriched tryptophan ( [13C delta 1]-L-Trp) and glycine ( [13C alpha]Gly) were incorporated into melittin and three analogues by de novo peptide synthesis. 13C-Labeled tryptophan was incorporated into melittin at position 19 and into single-tryptophan analogues of melittin at positions 17, 11, and 9, respectively. Each of the synthetic peptides contained 13C-labeled glycine at position 12 only. The peptides were characterized functionally in a cytolytic assay, and spectroscopically by CD, fluorescence, and NMR. The behavior of 13C-labeled synthetic melittin was, in all respects, indistinguishable from that of the naturally occurring peptide. All of the analogues were found to be efficient lytic agents and thus were functionally similar to the native peptide, yet no evidence was found for formation of a melittin-like tetramer by any of the analogues in aqueous media, although there was a propensity for apparently nonspecific peptide aggregation, especially for MLT-W9. Since the analogues did exhibit fractional helicities by CD comparable to or even greater than melittin itself in the presence of methanol, we infer that tetramer assembly requires not only the ability to form alpha-helix but also a very precise packing of amino acid side chains of the constituent monomers. The 13C chemical shift of the Gly-12 C alpha was found to be a sensitive marker for helix formation in all of the peptides. For melittin itself, 13C NMR spectra revealed a downfield shift of approximately 1.8 ppm for the Gly-12 13C alpha resonance of the tetramer relative to that observed for the free monomer in D2O. In mixed samples containing melittin monomer and tetramer, two discrete Gly-12 13C alpha peaks were observed simultaneously, suggestive of slow exchange between the two species. We conclude that melittin's ability to form a soluble tetramer is not a prerequisite for cytolytic activity, nor is cytolytic potential precisely correlated with the ability to form an amphiphilic helix.     

The structure of melittin in membranes.

The conformation of the polypeptide melittin in lipid membranes as determined by Raman spectroscopy is a bent alpha-helix formed by the mainly hydrophobic residues 1-21, and a nonhelical COOH-terminal segment of the hydrophilic residues 22-26. Fluorescence quenching experiments on residue Trp19 reveal that all COOH-termini are located on that side of a vesicular membrane to which melittin was added. By means of fluorescence energy transfer between unmodified and modified Trp19 residues, melittin is shown to aggregate in membranes predominantly in the form of tetramers. These and previous results on the location and orientation of melittin permit the development of a model for the structure of melittin tetramers in membranes. The hydrophilic sides of four bilayer-spanning helices face each other to form a hydrophilic pore through the membrane.     

Interdomain cooperativity of calmodulin bound to melittin preferentially increases calcium affinity of sites I and II

Calmodulin (CaM) is the primary transducer of calcium fluxes in eukaryotic cells. Its two domains allosterically regulate myriad target proteins through calcium-linked association and conformational change. Many of these proteins have a basic amphipathic alpha-helix (BAA) motif that binds one or both CaM domains. Previously, we demonstrated domain-specific binding of melittin, a model BAA peptide, to Paramecium CaM (PCaM): C-domain mutations altered the interaction with melittin, whereas N-domain mutations had no discernable effect. Here, we report on the use of fluorescence and NMR spectroscopy to measure the domain-specific association of melittin with calcium-saturated ((Ca(2+))(4)-PCaM) or calcium-depleted (apo) PCaM, which has enabled us to determine the free energies of calcium binding to the PCaM-melittin complex, and to estimate interdomain cooperativity. Under apo conditions, melittin associated with each PCaM domain fragment (PCaM(1-80) and PCaM(76-148)), as well as with the C-domain of full-length PCaM (PCaM(1-148)). In the presence of calcium, all of these interactions were again observed, in addition to which an association with the N-domain of (Ca(2+))(4)-PCaM(1-148) occurred. This new association was made possible by the fact that melittin changed the calcium-binding preferences for the domains from sequential (C > N) to concomitant, decreasing the median ligand activity of calcium toward the N-domain 10-fold more than that observed for the C-domain. This selectivity may be explained by a free energy of cooperativity of -3 kcal/mol between the N- and C-domains. This study demonstrates multiple domain-selective differences in the interactions between melittin and PCaM. Our findings support a model that may apply more generally to ion channels that associate with the C-domain of CaM under low (resting) calcium conditions, but rearrange when calcium binding triggers an association of the N- domain with the channel.     

Ultrasonic study of melittin effects on phospholipid model membranes.

Low dose effects of melittin on dilute suspensions of dipalmitoylphosphatidylcholine multilamellar vesicles are investigated by studying the acoustic properties of the system. The temperature dependencies of sound velocity and absorption have been measured at 7.2 MHz in the temperature range of 20-55 degrees C, for different peptide/lipid molar ratios, R. The most pronounced effects were observed at R = 5 x 10(-3), in the vicinity of the pretransition, with a simultaneous increase in sound absorption and velocity. This indicates that melittin affects the polar head group region of the bilayer resulting in a decrease in mobility of the polar head groups. A nonmonotonic dependence of the main transition temperature, with an initial decrease followed by an increase as melittin is added, is interpreted as a consequence of a destabilizing action of the interfaces between mellitin-affected clusters and the unaffected phase.     

Attenuated total reflectance Fourier transform infrared studies of the interaction of melittin, two fragments of melittin, and delta-hemolysin with phosphatidylcholines

Attenuated total reflectance Fourier transform infrared spectroscopy (ATR FT-IR) has been used to monitor alterations in phospholipid organization in thin layers of 1,2-dipalmitoylphosphatidylcholine (DPPC) and 1-palmitoyl-2-oleoylphosphatidylcholine (POPC), induced by the membrane lytic peptide melittin, its fragments 1-15 (hydrophobic fragment) and 16-26 (hydrophilic fragment), and delta-hemolysin. In addition, the secondary structures of the peptides and the orientation of helical fragments were determined with respect to the bilayer. The insertion of melittin into POPC caused large perturbations in the order and increased rates of motion of the acyl chains, as monitored by the frequency and half-width of the symmetric CH2 stretching vibration near 2850 cm-1, as well as by the ATR dichroic ratio for this mode. Changes in DPPC organization were less and were consistent with peptide-induced static disordering (gauche rotamer formation) in the acyl chains. Melittin adopted primarily an alpha-helical secondary structure, although varying small proportions of beta and/or aggregated forms were noted. The helical segments were preferentially oriented perpendicular to the bilayer plane. Several modes of melittin/lipid interaction were considered in an attempt to semiquantitatively understand the observed dichroic ratios. By considering the peptide as a bent rigid rod, a plausible model for its lytic properties has been developed. The hydrophilic fragment in DPPC showed a secondary structure with little alpha-helix present. As judged by its effect on phospholipid acyl chain organizational parameters, the fragment did not penetrate the bilayer substantially. The hydrophobic fragment in DPPC gave amide I spectral patterns consistent with a mixture of predominantly beta-antiparallel pleated sheet with a smaller fraction of alpha-helix.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lytic effects of melittin and δ-haemolysin from Staphylococcus aureus on vesicles of dipalmitoylphosphatidylcholine

The effects of the lytic peptides, melittin and δ-haemolysin, are compared in vesicles of gel-phase dipalmitoylphosphatidylcholine (DPPC), using calcein as trapped marker. At low concentration, both toxins cause vesicles to lose contents in 5 mM phosphate buffer near neutral pH, with melittin being the more active. As phosphate concentration is increased, the kinetics of melittin-induced leakage change from a slow, sustained loss to a rapid ‘burst’ of leakage when melittin is present mainly as tetramer in solution, under conditions where it is reported to lose haemolytic activity towards erythrocytes. At low phosphate concentration, the leakage induced by δ-haemolysin is preceded by a lag phase, though fluorescence measurements show that binding of toxin is rapid. At higher phosphate concentration, the toxin binds rapidly to vesicles, but causes no leakage of entrapped calcein. Steady-state fluorescence spectra show no obvious differences in tryptophan emission for δ-haemolysin bound to lipid in high- or low-phosphate buffer. Spin-label fluorescence-quenching studies show that the single tryptophan residue of δ-haemolysin is buried within the lipid bilayer at all phosphate concentrations used. In gel-phase DPPC, δ-haemolysin shows no tendency to cause vesicle aggregation over several hours, as judged by light scattering, though a slow non-linear effect is seen above the lipid phase transition temperature. These effects are contrasted with those of melittin under similar conditions.     

Structural and thermodynamic aspects of the interaction between heparan sulfate and analogues of melittin

Melittin is an amphipathic cationic peptide derived from honeybee venom with well-known cytolytic and antimicrobial properties. When coupled to cationic polymers or lipid molecules, it forms conjugates with high transfection efficiency and low toxicity with promising applications in gene therapy. A first step in the internalization of melittin and its conjugates is their binding to the cell surface, a reaction likely to involve heparan sulfate proteoglycans (HSPG). In the present work, we characterize the binding equilibrium of heparan sulfate (HS) with two melittin analogues, [Cys(1)]melittin (mel-SH) and retro-inverso [Cys(1)]melittin (ri-mel-SH). The terminal cysteine found in these peptides replaces the N-terminal glycine present in native melittin and allows covalent binding to other molecules. Isothermal titration calorimetry (ITC) reveals a high affinity of each melittin analogue to HS. Association constants of 4.7 x 10(4) and 3.5 x 10(5) M(-)(1) are found at physiological ionic strength and 15 degrees C for ri-mel-SH and mel-SH, respectively. The reaction enthalpy measured under these conditions is DeltaH(degrees)pep= 4.2 kcal/mol for ri-mel-SH and DeltaH(degrees)pep= 1.1 kcal/mol for mel-SH. The peptide-to-HS stoichiometry is approximately 20 for ri-mel-SH and approximately 14 for mel-SH under the same conditions. Temperature dependence studies using ri-mel-SH (mel-SH) show that DeltaH(degrees)pep decreases in magnitude upon increase in temperature, which results in a molar heat capacity of DeltaH(degrees)pep= -322 cal mol(-)(1) K(-)(1) (-45 cal mol(-)(1) K(-)(1)). Such a negative heat capacity change is not expected for a purely electrostatic interaction and indicates that hydrophobic and other interactions are also involved in the binding equilibrium. Salt dependence studies of the binding constants confirm that nonelectrostatic forces are an important component of the HS-melittin interaction. Binding to HS induces conformational changes in both peptides, with ri-mel-SH showing a 6-fold increase of the alpha-helix content when incubated with HS under saturation conditions.     

In situ study by polarization modulated Fourier transform infrared spectroscopy of the structure and orientation of lipids and amphipathic peptides at the air-water interface.

Free amphipathic peptides and peptides bound to dimyristoylphosphatidylcholine (DMPC) were studied directly at the air/water interface using polarization modulation infrared reflection absorption spectroscopy (PMIRRAS). Such differential reflectivity measurements proved to be a sensitive and efficient technique to investigate in situ the respective conformations and orientations of lipid and peptide molecules in pure and mixed films. Data obtained for melittin, a natural hemolytic peptide, are compared to those of L15K7, an ideally amphipathic synthetic peptide constituted by only apolar Leu and polar Lys residues. For pure peptidic films, the intensity, shape, and position of the amide I and II bands indicate that the L15K7 peptide adopts a totally alpha-helical structure, whereas the structure of melittin is mainly alpha-helical and presents some unordered domains. The L15K7 alpha-helix axis is oriented essentially parallel to the air-water interface plane; it differs for melittin. When injected into the subphase, L15K7 and melittin insert into preformed expanded DMPC monolayers and can be detected by PMIRRAS, even at low peptide content (> 50 DMPC molecules per peptide). In such conditions, peptides have the same secondary structure and orientation as in pure peptidic films.     

Lytic activity of monomeric and oligomeric melittin

The haemolytic activities of melittin and melittin tetramer as induced by high phosphate counterion concentration, were monitored. Monomeric melittin was found to be fully lytic, whilst tetrameric melittin lacked such activity. Under conditions where melittin was fully tetrameric attempts were made to covalently cross-link the native tetramer using a series of different chain length bifunctional imido esters. The cross-linked oligomers were fully lytic under conditions where melittin was demonstrated to lack such activity. This finding, together with molecular weight determinations and circular dichroism studies, indicated that the cross-linked melittin was quite different to the native tetramer. The haemolytic activity of melittin-containing solutions was related to the concentration of monomeric melittin. The effect of reduced dielectric constant (?) on the aggregation behaviour of melittin and its derivatives was found to favour monomeric melittin.     

High pressure FTIR study of interaction of melittin with dimyristoylphosphatidyl glycerol bilayers.

Infrared spectra of hydrated dimyristoylphosphatidyl glycerol (DMPG) and of aqueous dispersions of melittin and DMPG at peptide:lipid molar ratios of 1:10 and 1:4 were recorded as a function of pressure from atmospheric to 22 kbar. Spectral features corresponding to vibrations of the amide linkages in melittin and to various functional groups in DMPG (carbonyl, methlylene, phosphate) were monitored in order to investigate the structure and dynamics of melittin:DMPG dispersions. Melittin was found to cause conformational and orientational disordering of the acyl chains in DMPG bilayers. The magnitude of these disorders was higher for higher concentration of melittin in DMPG. The higher concentration of melittin was also found to disrupt the DMPG bilayers through interactions with the lipid head groups. Such disruption may be related to some of the biological properties of melittin.     

Conformational analysis of melittin in solution phase: vibrational circular dichroism study

The vibrational absorption and vibrational circular dichroism (VCD) spectra of melittin in D(2)O solutions at different pH values, different salt concentrations, or different 2,2,2-trifluoroethanol (TFE) concentrations are recorded in the amide I' (1850-1600 cm(-1)) region. Two models are used to simulate this peptide in different conditions, and a coupled oscillator program is used to obtain the calculated absorption and VCD spectra. This study indicates that melittin adopts a mixed structure in D(2)O solution at low pH, low salt concentration, or low TFE concentration. With an increase in pH, salt concentration, or TFE concentration, the structure changes to alpha-helix and further increases lead to aggregation. These results demonstrate the versatility of VCD in probing the conformations of peptides under different environmental perturbations.     

New methods of isolating bee venom peptides

The three major peptides of bee venom, melittin, apamin, and peptide 401 (MCD peptide), can be readily separated on columns of Heparin Sepharose CL-6B at pH 6.8 (phosphate buffer) using a linear salt gradient. Contamination by melittin of the other two components can be assessed by fluorescence spectrophotometry.     

Structural integrity of the beta beta alpha-Metal finger motif is required for DNA binding and stable protein-DNA complex formation in R.KpnI

Restriction endonuclease (REase) R.KpnI from Klebsiella pneumoniae is a homodimeric enzyme, which recognizes palindromic sequence GGTAC|C and cleaves generating 4 base 3' end overhangs. R.KpnI belongs to the HNH superfamily of nucleases, which are characterized by the presence of the beta beta alpha-Me finger motif. Structurally, this motif consists of a twisted beta-hairpin followed by an alpha-helix, and serves as a scaffold for side chains of residues involved in co-ordination of a divalent metal ion that is required for catalysis. Homology modeling studies of R.KpnI suggested a crossover structure for the alpha-helix, which could possibly form dimeric interface and/or structural scaffold for the active site. We have evaluated the role of the residues present in this alpha-helix in intersubunit interactions and/or stabilization of the active site. We show here that mutations of residues in the alpha-helix lead to a loss of the enzyme activity, but not dimerization ability. Intrinsic fluorescence and circular dichroism studies revealed that the loss of function phenotype was due to the structural perturbation of the beta beta alpha-Me finger motif. The results of mutational analysis suggest that the alpha-helix of the beta beta alpha-Me finger of R.KpnI plays an important role for the stability of the protein-DNA complex.