'Detergent-like' permeabilization of anionic lipid vesicles by melittin.

Melittin (MLT), the 26-residue toxic peptide from the European honeybee Apis mellifera, is widely used for studying the principles of membrane permeabilization by antimicrobial and other host-defense peptides. A striking property of MLT is that its ability to permeabilize zwitterionic phospholipid vesicles is dramatically reduced upon the addition of anionic lipids. Because the mechanism of permeabilization may be fundamentally different for the two types of lipids, we examined MLT-induced release of entrapped fluorescent dextran markers of two different molecular masses (4 and 50 kDa) from anionic palmitoyloleoylphosphatidylglycerol (POPG) vesicles. Unlike release from palmitoyloleoylphosphatidylcholine (POPC) vesicles, which is highly selective for the 4 kDa marker, implying release through pores of about 25 A diameter [Ladokhin et al., Biophys. J. 72 (1997) 1762], release from POPG vesicles was found to be non-selective, i.e., 'detergent-like'. Oriented circular dichroism measurements of MLT in oriented POPG and POPC multilayers disclosed that alpha-helical MLT can be induced to adopt a transbilayer orientation in POPC multilayers, but not in POPG multilayers. The apparent inhibition of MLT permeabilization by anionic membranes may thus be due to suppression of translocation ability.

Temperature-dependent shift of fluorescence spectra without conformational changes in protein; studies of dipole relaxation in the melittin molecule.

When studying bee venom melittin in an ordered tetrameric form we found a shift of the fluorescence spectrum to a longer wavelength with a rise in temperature above 25 degrees C. The application of the methods of circular dichroism, temperature-perturbation difference spectrophotometry, gel filtration, ionic quenching and polarization of Trp-19 fluorescence argues against the possibility of dissociation and change in conformation with the rise in temperature. The spectral shifts are, probably, caused by dipole-orientational structural relaxation of the tryptophanyl environment in the excited state at nanosecond times. The dependence of the fluorescence spectrum on the excitation wavelength was found to be a function of temperature. This function was applied to determine the dipole-orientational relaxation times.

Amino acid substitutions in the membrane-binding domain of cytochrome b5 alter its membrane-binding properties.

The structure-function relationships of the 43-amino-acid membrane-binding domain of cytochrome b5 have been examined in two mutant forms of the protein. In one mutant, two tryptophans in the membrane-binding domain, at positions 108 and 112, were replaced by leucines, and in the second mutant, in addition, aspartic acid 103 was also replaced by leucine. The fluorescence emission spectra of the three proteins and their degree of quenching by brominated lipids indicate that the mutations are not producing major conformational changes or allowing a deeper degree of penetration of the domain into the bilayer. The hydrophobicities of the three proteins were compared, by determining strengths of self-association and membrane affinities, and it was found that the protein with two additional leucines was much less hydrophobic and the one with three additional leucines was much more hydrophobic than the native cytochrome. It appears that small changes in amino acid composition, which produce no gross changes in the structure of the membrane-binding domain, will nevertheless produce very large changes in the strengths of self- and membrane-association. These differences in self-association had profound effects on the times required for membrane-association to reach equilibrium.

Folding of amphipathic alpha-helices on membranes: energetics of helix formation by melittin.

Membranes have a potent ability to promote secondary structure formation in a wide range of membrane-active peptides, believed to be due to a reduction through hydrogen bonding of the energetic cost of partitioning peptide bonds. This process is of fundamental importance for understanding the mechanism of action of toxins and antimicrobial peptides and the stability of membrane proteins. A classic example of membrane-induced folding is the bee-venom peptide melittin that is largely unstructured when free in solution, but strongly adopts an amphipathic alpha-helical conformation when partitioned into membranes. We have determined the energetics of melittin helix formation through measurements of the partitioning free energies and the helicities of native melittin and of a diastereomeric analog with four d-amino acids (d4,l-melittin). Because D4,l-melittin has little secondary structure in either the free or bound forms, it serves as a model for the experimentally inaccessible unfolded bound form of native melittin. The partitioning of native melittin into large unilamellar phosphocholine vesicles is 5.0(+/-0.7) kcal mol-1 more favorable than the partitioning of d4,l-melittin (1 cal=4.186 J). Differences in the circular dichroism spectra of the two forms of melittin indicate that bound native melittin is more helical than bound d4, l-melittin by about 12 residues. These findings disclose that the free energy reduction per residue accompanying the folding of melittin in membrane interfaces is about 0.4 kcal mol-1, consistent with the hypothesis that hydrogen bonding reduces the high cost of partitioning peptide bonds. A value of 0.6 kcal mol-1 per residue has been observed for beta-sheet formation by a hexapeptide model system. These two values provide a useful rule of thumb for estimating the energetic consequences of membrane-induced secondary structure formation.

Protein chemistry at membrane interfaces: non-additivity of electrostatic and hydrophobic interactions.

Non-specific binding of proteins and peptides to charged membrane interfaces depends upon the combined contributions of hydrophobic (DeltaG(HPhi)) and electrostatic (DeltaG(ES)) free energies. If these are simply additive, then the observed free energy of binding (DeltaG(obs)) will be given by DeltaG(obs)=DeltaG(HPhi)+DeltaG(ES), where DeltaG(HPhi)=-sigma(NP)A(NP) and DeltaG(ES)=zFphi. In these expressions, A(NP) is the non-polar accessible area, sigma(NP) the non-polar solvation parameter, z the formal peptide valence, F the Faraday constant, and phi the membrane surface potential. But several lines of evidence suggest that hydrophobic and electrostatic binding free energies of proteins at membrane interfaces, such as those associated with cell signaling, are not simply additive. In order to explore this issue systematically, we have determined the interfacial partitioning free energies of variants of indolicidin, a cationic proline-rich antimicrobial peptide. The synthesized variants of the 13 residue peptide covered a wide range of hydrophobic free energies, which allowed us to examine the effect of hydrophobicity on electrostatic binding to membranes formed from mixtures of neutral and anionic lipids. Although DeltaG(obs) was always a linear function of DeltaG(HPhi), the slope depended upon anionic lipid content: the slope was 1.0 for pure, zwitterionic phosphocholine bilayers and 0.3 for pure phosphoglycerol membranes. DeltaG(obs) also varied linearly with surface potential, but the slope was smaller than the expected value, zF. As observed by others, this suggests an effective peptide valence z(eff) that is smaller than the formal valence z. Because of our systematic approach, we were able to establish a useful rule-of-thumb: z(eff) is reduced relative to z by about 20 % for each 3 kcal mol(-1) (1 kcal=4.184 kJ) favorable increase in DeltaG(HPhi). For neutral phosphocholine interfaces, we found that DeltaG(obs) could be predicted with remarkable accuracy using the Wimley-White experiment-based interfacial hydrophobicity scale.

Folding of beta-sheet membrane proteins: a hydrophobic hexapeptide model.

Beta-sheets, in the form of the beta-barrel folding motif, are found in several constitutive membrane proteins (porins) and in several microbial toxins that assemble on membranes to form oligomeric transmembrane channels. We report here a first step towards understanding the principles of beta-sheet formation in membranes. In particular, we describe the properties of a simple hydrophobic hexapeptide, acetyl-Trp-Leu5 (AcWL5), that assembles cooperatively into beta-sheet aggregates upon partitioning into lipid bilayer membranes from the aqueous phase where the peptide is strictly monomeric and random coil. The aggregates, containing 10 to 20 monomers, undergo a relatively sharp and reversible thermal unfolding at approximately 60 degreesC. No pores are formed by the aggregates, but they do induce graded leakage of vesicle contents at very high peptide to lipid ratios. Because beta-sheet structure is not observed when the peptide is dissolved in n-octanol, trifluoroethanol or sodium dodecyl sulfate micelles, aggregation into beta-sheets appears to be an exclusive property of the peptide in the bilayer membrane interface. This is an expected consequence of the hypothesis that a reduction in the free energy of partitioning of peptide bonds caused by hydrogen bonding drives secondary structure formation in membrane interfaces. But, other features of interfacial partitioning, such as side-chain interactions and reduction of dimensionality, must also contribute. We estimate from our partitioning data that the free energy reduction per residue for aggregation is about 0.5 kcal mol-1. Although modest, its aggregate effect on the free energy of assembling beta-sheet proteins can be huge. This surprising finding, that a simple hydrophobic hexapeptide readily assembles into oligomeric beta-sheets in membranes, reveals the potent ability of membranes to promote secondary structure in peptides, and shows that the formation of beta-sheets in membranes is more facile than expected. Furthermore, it provides a basis for understanding the observation that membranes promote self-association of beta-amyloid peptides. AcWL5 and related peptides thus provide a good starting point for designing peptide models for exploring the principles of beta-sheet formation in membranes.

Evidence for the formation of an unusual ternary complex of rabbit liver EF-1alpha with GDP and deacylated tRNA.

Eukaryotic translation elongation factor 1alpha is known to interact in GTP-bound form with aminoacyl-tRNA promoting its binding to the ribosome. In this paper another ternary complex [EF-1alpha*GDP*deacylated tRNA], never considered in widely accepted elongation schemes, is reported for the first time. The formation of this unusual complex, postulated earlier (FEBS Lett. (1996) 382, 18-20), has been detected by four independent methods. [EF-1alpha*GDP]-interacting sites are located in the acceptor stem, TpsiC stem and TpsiC loop of tRNA(Phe) and tRNA(Leu) molecules. Both tRNA and EF-1alpha are found to undergo certain conformational changes during their interaction. The ability of EF-1alpha to form a complex with deacylated tRNA indicates that the factor may perform an important role in tRNA and aminoacyl-tRNA channeling in higher eukaryotic cells.

[Structural-dynamic properties of the tryptophan residue environment in melittin]. / Strukturno-dinamicheskie svoistva okruzheniia triptofanovogo ostatka v melittine.

The structural dynamics of the environment of the single tryptophan residue in melittin was studied by site-selective red-edge-excitation fluorescence spectroscopy. The dependence of the spectral shift on transition from excitation in a maximum (at 280 nm) to long-wavelength edge (305 nm) was studied as a function of temperature. It was shown, that for melittin at high ionic strength (tetramer), the three regions of temperature dependence of the red-edge effect are observed: retarded relaxation (up to +30 degrees C), relaxational changes of spectra (from +30 to +50 degrees C) and thermal changes of structure (above +50 degrees C). The dipolar-re-orientational relaxation time and activation energy of orientation motions in the environment of indolic ring in the tetrameric melittin structure were estimated. Extrapolation from relaxational region to room temperature results in relaxation time 40 ns. In monomeric melittin (at low ionic strength) the red-edge shift of spectra is absent. The distinct differences in character of thermal quenching of fluorescence between monomeric and tetrameric forms of melittin are observed. It follows, that the short-wave-length fluorescence shift on monomer-tetramer transition is due to both the reduction of polarity, and the increase in rigidity of tryptophan environment, the absence of relaxation motions at nanosecond times.

Fluorescence quenching study of melittin-membrane interactions.

The bee venom peptide melittin is a popular object for studying lipid-protein interactions. In this paper we show that binding of melittin to the bilayer is a complex process involving several steps. We were able to resolve those steps by utilizing a new approach in the quantitative analysis of depth-dependent fluorescence quenching in membranes. The "distribution analysis" technique (DA) employed here provides not only the most probable depth of the fluorophore but also allows the estimation of its conformational heterogeneity and accessibility to the lipid phase. A model for melittin interaction with the membranes is suggested.

Analysis of protein and peptide penetration into membranes by depth-dependent fluorescence quenching: theoretical considerations.

Depth-dependent fluorescence quenching in membranes is playing an increasingly important role in the determination of the low resolution structure of membrane proteins. This paper presents a graphical way of visualizing membrane quenching caused by lipid-attached bromines or spin labels with the help of a depth-dependent fluorescence quenching profile. Two methods are presently available to extract information on membrane penetration from quenching: the parallax method (PM; ) and distribution analysis (DA; A. S. Biophys. J. 64:290a (Abstr.); A. S. Methods Enzymol. 278:462-473). Analysis of various experimental and simulated data by these two methods is presented. The effects of uncertainty in the local concentration of quenching lipids (due to protein shielding or nonideality in lipid mixing), the existence of multiple conformations of membrane-bound protein, incomplete binding, and uncertainty in the fluorescence in nonquenching lipid are described. Regardless of the analytical form of the quenching profile (Gaussian function for DA or truncated parabola for PM), it has three primary characteristics: position on the depth scale, area, and width. The most important result, not surprisingly, is that one needs three fitting parameters to describe the quenching. This will keep the measures of the quenching profile independent of each other resulting in the reduction of systematic errors in depth determination. This can be achieved by using either DA or a suggested modification of the PM that introduces a third parameter related to quenching efficiency. Because DA utilizes a smooth fitting function, it offers an advantage for the analysis of deeply penetrating probes, where the effects of transleaflet quenching should be considered.

Evaluation of lipid exposure of tryptophan residues in membrane peptides and proteins.

Fluorescence quenching is used to gain information on the exposure of tryptophan residues to lipid in membrane-bound proteins and peptides. A protocol is developed to calculate this exposure, based on a comparison of quenching efficiency and of a fluorescence lifetime (or quantum yield) measured for a protein and for a model tryptophan-containing compound. Various methods of analysis of depth-dependent quenching are compared and three universal measures of quenching profile are derived. One of the measures, related to the area under profile, is used to estimate quenching efficiency. The method is applied to single tryptophan mutants of a membrane-anchoring nonpolar peptide of cytochrome b(5) and of an outer membrane protein A. Analysis of quenching of the cytochrome's nonpolar peptide by a set of four brominated lipids reveals a temperature-controlled reversible conformational change, resulting in increased exposure of tryptophan to lipid and delocalization of its transverse position. Kinetic quenching profiles and fluorescence binding kinetics reported by Kleinschmidt et al. (Biochemistry (1999) 38, 5006-5016) were analyzed to extract information on the relative exposure of tryptophan residues during folding of an outer membrane protein A. Trp-102, which translocates across the bilayer, was found to be noticeably shielded from the lipid environment throughout the folding event compared to Trp-7, which remains on the cis side. The approach described here provides a new tool for studies of low-resolution structure and conformational transitions in membrane proteins and peptides.

Fluorescence of membrane-bound tryptophan octyl ester: a model for studying intrinsic fluorescence of protein-membrane interactions.

The fluorescence of a membrane-bound tryptophan derivative (tryptophan octyl ester, TOE) has been examined as a model for tryptophan fluorescence from proteins in membrane environments. The depth-dependent fluorescence quenching of TOE by brominated lipids was found to proceed via a dynamic mechanism with vertical fluctuations playing a central role in the process. The activation energy for the quenching was estimated to be 1.3 kcal/mole. The data were analyzed using the distribution analysis (DA) method, which extends the conventional parallax method to account more realistically for the transbilayer distributions of both probe and quencher and for possible variations in the probe's accessibility. DA provides a better fit than the parallax method to data collected with TOE in membranes formed of lipids brominated at either the 4,5, the 6,7, the 9,10, or the 11,12 positions of the sn-2 acyl chain. DA yields information on the fluorophore's most probable depth in the membrane, its conformational heterogeneity, and its accessibility to the lipid phase. Previously reported data on cytochrome b5 and melittin were reanalyzed together with data obtained with TOE. This new analysis demonstrates conformational heterogeneity in melittin and provides estimates of the freedom of motion and exposure to the lipid phase of membrane-embedded tryptophans of cytochrome b5.

Evidence for an excited-state reaction contributing to NADH fluorescence.

The fluorescence of reduced ß-nicotinamide adenine dinucleotide (NADH) was monitored as a function of the excitation and emission wavelengths. In aqueous and organic solvents the intensity decay was found to be more heterogeneous than reported earlier. When the ternary complex of NADH with the enzyme (horse liver alcohol dehydrogenase) and substrate analog (iso-butyramide) is formed, three exponents are required to fit the data. The decay-associated spectrum for the shortest lifetime undergoes a sign change from positive at the blue edge of emission to negative at the red edge. This phenomenon is interpreted as an outcome of reversible excited-state reaction leading to the appearance of at least one fluorescent product.

Red-edge-excitation fluorescence spectroscopy of indole and tryptophan.

Studies on the dependence of indole and tryptophan fluorescence emission spectra on excitation wavelength, lambda ex, show that the emission shifts to longer wavelengths for red-edge excitation in different solid and viscous solvents. In solid systems the spectral shifts for excitation in the range from 290 to 310 nm can reach tens of nm, and they are more significant than changes of lambda ex. In a viscous medium the magnitude of this effect is shown to be directly related to the dipole-reorientational relaxation of solvent molecules in the environment of the chromophore, which allows the relaxation times to be estimated. The method involves simple steady-state measurements of fluorescence spectra at the maximum and at the red edge of the absorption band. Since it is not necessary to obtain information on the fluorescence spectra of completely relaxed states, this method for the estimation of relaxation times may have advantages in studies of proteins compared with the conventional relaxation shift method, and may produce complementary information to that obtained by nanosecond time-resolved spectroscopy.

Distribution analysis of membrane penetration of proteins by depth-dependent fluorescence quenching.

A new approach is presented to evaluate the depth-dependent quenching of the fluorescence of membrane-bound probes and integral proteins. By utilizing at least three quenchers of known and distinctly different depths, the following parameters can be recovered: most probable depth of the probe; dispersion of the depth distribution, which will depend on the size of probe and fluctuations in its position; and quenching efficiency, which is related to the exposure of a particular fluorophore to the lipid phase. The exposure of tryptophan residues in integral proteins can be quantitatively determined with respect to the model compound (tryptophan octyl ester). The proposed method was applied to the investigation of membrane complexes of the bee venom melittin and cytochrome b5.

Leakage of membrane vesicle contents: determination of mechanism using fluorescence requenching.

Agents such as antimicrobial peptides and toxins can permeabilize membrane vesicles to cause leakage of entrapped contents in either a graded or an all-or-none fashion. Determination of which mode of leakage is induced is an important step in understanding the molecular mechanism of membrane permeabilization. Wimley et al. (1994, Protein Sci. 3:1362-1378) have developed a fluorescence method for distinguishing the two modes that makes use of the dye/quencher pair 8-aminonapthalene-1,3,6 trisulfonic acid (ANTS)/p-xylene-bis-pyridinium bromide (DPX) without the usual need for the physical separation of vesicles from released contents. Their "requenching" method establishes the mode of release through the fluorescence changes that occur when DPX is added externally to a solution of vesicles that have released some fraction of their contents. However, the requenching method as originally stated ignored the possibility of preferential release of dye or quencher. Here we extend the theory of the method to take into account preferential release and the effects of graded leakage. The ratio of the rates of release of the cationic quencher DPX and anionic dye 8-aminonapthalene-1,3,6 trisulfonic acid can be estimated by means of the theory. For graded leakage, we show that the release of the markers does not coincide with the fluorescence changes observed in the standard leakage assay. This is true for self-quenching dyes as well and means that 1) the amount of released material will be overestimated and 2) the kinetics will be nonexponential and have artificially high apparent rates. We show how the extended requenching analysis allows the results of leakage experiments to be corrected for artifacts that result from graded and preferential leakage. Experimental evidence is presented for the existence of peptide-induced preferential graded leakage of DPX from both neutral and anionic vesicles.

CD spectra of indolicidin antimicrobial peptides suggest turns, not polyproline helix.

Indolicidin is a 13-residue antimicrobial peptide-amide isolated from the cytoplasmic granules of bovine neutrophils that contains five Trp and three Pro residues. Falla et al. [(1996) J. Biol. Chem. 271, 19298] suggested that indolicidin forms a poly-L-proline II helix based upon the circular dichroism (CD) spectra of a closely related peptide (indolicidin methyl ester). In contrast, we found no evidence of poly-L-proline II helix formation in the CD spectra of native indolicidin in various solvents or when bound to micelles and membranes [Ladokhin et al. (1997) Biophys. J. 72, 794]. We interpreted the spectra as arising from unordered and/or beta-turn structures, but noted a sharp negative band at 227 nm arising from the tryptophan residues that would mask spectral features characteristic of poly-L-proline II helix. We have reexamined this issue by means of CD measurements of native indolicidin and several of its analogues. None of the features characteristic of a poly-L-proline helix (or alpha- or 3(10)-helix) were observed for any of the peptides studied. To eliminate artifacts associated with tryptophan, we synthesized indolicidin-L and indolicidin-F in which all five tryptophans were replaced with leucines or phenylalanines, respectively. The changes in CD spectra of these Trp-free peptides upon transfer into membrane-like environments were found to be consistent with the formation of beta-turns. For the native indolicidin in SDS micelles, temperature increases resulted in a coupled diminution of two sharp bands, a negative one at 227 nm and a positive one at 217 nm. This phenomenon, which is absent in indolicidin-L variants with single Leu-->Trp substitutions, is consistent with exciton splitting produced by the stacking of indole rings. Type VI turns in model peptides in aqueous solution are known to be promoted by stacking interactions between cis-proline and neighboring aromatic residues [Yao et al. (1994) J. Mol. Biol. 243, 754]. Molecular modeling of indolicidin with a -Trp(6)-cis-Pro(7)-Trp(8)- type VIa turn demonstrated the feasibility of this turn conformation and revealed the possibility of an accompanying amphipathic structure. We therefore suggest that turn conformations are the principal structural motif of indolicidin and that these turns greatly enhance membrane activity.