Macromolecular crowding at membrane interfaces: adsorption and alignment of membrane peptides

Association of proteins to cellular membranes is involved in various biological processes. Various theoretical models have been developed to describe this adsorption mechanism, commonly implying the concept of an ideal solution. However, due to the two-dimensional character of membrane surfaces intermolecular interactions between the adsorbed molecules become important. Therefore previously adsorbed molecules can influence the adsorption behavior of additional protein molecules and their membrane-associated structure. Using the model peptide LAH₄, which upon membrane-adsorption can adopt a transmembrane as well as an in-planar configuration, we carried out a systematic study of the correlation between the peptide concentration in the membrane and the topology of this membrane-associated polypeptide. We could describe the observed binding behavior by establishing a concept, which includes intermolecular interactions in terms of a scaled particle theory.High surface concentration of the peptide shifts the molecules from an in-planar into a transmembrane conformation, a process driven by the reduction of occupied surface area per molecule. In a cellular context, the crowding-dependent alignment might provide a molecular switch for a cell to sense and control its membrane occupancy. Furthermore, crowding might have pronounced effects on biological events, such as the cooperative behavior of antimicrobial peptides and the membrane triggered aggregation of amyloidogenic peptides.     

Polymorphic phospholipid phase transitions as tools to understand peptide-lipid interactions.

The effect of peptides on bilayer----non-bilayer phase transitions can be used as a tool to investigate the molecular aspects of peptide-lipid interactions. In this contribution the action on membranes of the peptide antibiotic gramicidin A and the bee venom component melittin are compared. Although the known structures and locations of these peptides upon membrane binding are very different, their actions on membranes show striking parallels. A general model is proposed that explains the seemingly complex peptide-lipid interactions by making use of simple concepts.     

Lipid-packing perturbation of model membranes by pH-responsive antimicrobial peptides

The indiscriminate use of conventional antibiotics is leading to an increase in the number of resistant bacterial strains, motivating the search for new compounds to overcome this challenging problem. Antimicrobial peptides, acting only in the lipid phase of membranes without requiring specific membrane receptors as do conventional antibiotics, have shown great potential as possible substituents of these drugs. These peptides are in general rich in basic and hydrophobic residues forming an amphipathic structure when in contact with membranes. The outer leaflet of the prokaryotic cell membrane is rich in anionic lipids, while the surface of the eukaryotic cell is zwitterionic. Due to their positive net charge, many of these peptides are selective to the prokaryotic membrane. Notwithstanding this preference for anionic membranes, some of them can also act on neutral ones, hampering their therapeutic use. In addition to the electrostatic interaction driving peptide adsorption by the membrane, the ability of the peptide to perturb lipid packing is of paramount importance in their capacity to induce cell lysis, which is strongly dependent on electrostatic and hydrophobic interactions. In the present research, we revised the adsorption of antimicrobial peptides by model membranes as well as the perturbation that they induce in lipid packing. In particular, we focused on some peptides that have simultaneously acidic and basic residues. The net charges of these peptides are modulated by pH changes and the lipid composition of model membranes. We discuss the experimental approaches used to explore these aspects of lipid membranes using lipid vesicles and lipid monolayer as model membranes.     

Inhibition of PhoE translocation across Escherichia coli inner-membrane vesicles by synthetic signal peptides suggests an important role of acidic phospholipids in protein translocation

To obtain insight into the mechanism of precursor protein translocation across membranes, the effect of synthetic signal peptides and other relevant (poly)peptides on in vitro PhoE translocation was studied. The PhoE signal peptide, associated with inner membrane vesicles, caused a concentration-dependent inhibition of PhoE translocation, as a result of a specific interaction with the membrane. Using a PhoE signal peptide analog and PhoE signal peptide fragments, it was demonstrated that the hydrophobic part of the peptide caused the inhibitory effect, while the basic amino terminus is most likely important for an optimal interaction with the membrane. A quantitative analysis of our data and the known preferential interaction of synthetic signal peptides with acidic phospholipids in model membranes strongly suggest the involvement of negatively charged phospholipids in the inhibitory interaction of the synthetic PhoE signal peptide with the inner membrane. The important role of acidic phospholipids in protein translocation was further confirmed by the observation that other (poly)peptides, known to have both a high affinity for acidic lipids and hydrophobic interactions with model membranes, also caused strong inhibition of PhoE translocation. The implication of these results with respect to the role of signal peptides in protein translocation is indicated.     

Dimerization of Aβ40 inside dipalmitoylphosphatidylcholine bilayer and its effect on bilayer integrity: Atomistic simulation at three temperatures

Amyloid-beta (Aβ) protein is related to Alzheimer disease (AD), and various experiments have shown that oligomers as small as dimers are cytotoxic. Recent studies have concluded that interactions of Aβ with neuronal cell membranes lead to disruption of membrane integrity and toxicity and they play a key role in the development of AD. Molecular dynamics (MD) simulations have been used to investigate Aβ in aqueous solution and membranes. We have previously studied monomeric Aβ40 embedded in dipalmitoylphosphatidylcholine (DPPC) membrane using MD simulations. Here, we explore interactions of two Aβ40 peptides in DPPC bilayer and its consequences on dimer distribution in a lipid bilayer and on the secondary structure of the peptides. We explored that N-terminals played an important role in dimeric Aβ peptide aggregations and Aβ-bilayer interactions, while C-terminals bound peptides to bilayer like anchors. We did not observe exiting of peptides in our simulations although we observed insertion of peptides into the core of bilayer in some of our simulations. So it seems that the presence of Aβ on membrane surface increases its aggregation rate, and as diffusion occurs in two dimensions, it can increase the probability of interpeptide interactions. We found that dimeric Aβ, like monomeric one, had the ability to cause structural destabilization of DPPC membrane, which in turn might ultimately lead to cell death in an in vivo system. This information could have important implications for understanding the affinity of Aβ oligomers (here dimer) for membranes and the mechanism of Aβ oligomer toxicity in AD.     

Progressive structuring of a branched antimicrobial Peptide on the path to the inner membrane target

In recent years, interest has grown in the antimicrobial properties of certain natural and non-natural peptides. The strategy of inserting a covalent branch point in a peptide can improve its antimicrobial properties while retaining host biocompatibility. However, little is known regarding possible structural transitions as the peptide moves on the access path to the presumed target, the inner membrane. Establishing the nature of the interactions with the complex bacterial outer and inner membranes is important for effective peptide design. Structure-activity relationships of an amphiphilic, branched antimicrobial peptide (B2088) are examined using environment-sensitive fluorescent probes, electron microscopy, molecular dynamics simulations, and high resolution NMR in solution and in condensed states. The peptide is reconstituted in bacterial outer membrane lipopolysaccharide extract as well as in a variety of lipid media mimicking the inner membrane of Gram-negative pathogens. Progressive structure accretion is observed for the peptide in water, LPS, and lipid environments. Despite inducing rapid aggregation of bacteria-derived lipopolysaccharides, the peptide remains highly mobile in the aggregated lattice. At the inner membranes, the peptide undergoes further structural compaction mediated by interactions with negatively charged lipids, probably causing redistribution of membrane lipids, which in turn results in increased membrane permeability and bacterial lysis. These findings suggest that peptides possessing both enhanced mobility in the bacterial outer membrane and spatial structure facilitating its interactions with the membrane-water interface may provide excellent structural motifs to develop new antimicrobials that can overcome antibiotic-resistant Gram-negative pathogens.     

Membrane association, electrostatic sequestration, and cytotoxicity of Gly-Leu-rich peptide orthologs with differing functions

The skins of closely related frog species produce Gly-Leu-rich peptide orthologs that have very similar sequences, hydrophobicities, and amphipathicities but differ markedly in their net charge and membrane-damaging properties. Cationic Gly-Leu-rich peptides are hemolytic and very potent against microorganisms. Peptides with no net charge have only hemolytic activity. We have used ancestral protein reconstruction and peptide analogue design to examine the roles of electrostatic and hydrophobic interactions in the biological activity and mode of action of functionally divergent Gly-Leu-rich peptides. The structure and interaction of the peptides with anionic and zwitterionic model membranes were investigated by circular dichroism with 2-dimyristoyl-sn-glycero-3-phosphatidylcholine or 1,2-dimyristoyl-sn-glycero-3-phosphatidylglycerol vesicles and surface plasmon resonance with immobilized bilayers. The results, combined with antimicrobial assays, the kinetics of bacterial killing, and membrane permeabilization assays, reveal that Gly, Val, Thr, and Ile can all be accommodated in an amphipathic alpha helix when the helix is in a membrane environment. Binding to anionic and zwitterionic membranes fitted to a 2-stage interaction model (adsorption to the membrane followed by membrane insertion). The first step is governed by hydrophobic interactions between the nonpolar surface of the peptide helix and the membranes. The strong binding of Gly-Leu-rich cationic peptides to anionic membranes is due to the second binding step and involves short-range Coulombic interactions that prolong the residence time of the membrane-inserted peptide. The data demonstrate that evolution has positively selected charge-altering nucleotide substitutions to generate an orthologous cationic variant of neutral hemolytic peptides that bind to and permeate bacterial cell membranes.     

The effects of the C-terminal amidation of mastoparans on their biological actions and interactions with membrane-mimetic systems

Polycationic peptides may present their C-termini in either amidated or acidic form; however, the effects of these conformations on the mechanisms of interaction with the membranes in general were not properly investigated up to now. Protonectarina-MP mastoparan with an either amidated or acidic C-terminus was utilized to study their interactions with anionic and zwitterionic vesicles, using measurements of dye leakage and a combination of H/D exchange and mass spectrometry to monitor peptide–membrane interactions. Mast cell degranulation, hemolysis and antibiosis assays were also performed using these peptides, and the results were correlated with the structural properties of the peptides. The C-terminal amidation promotes the stabilization of the secondary structure of the peptide, with a relatively high content of helical conformations, permitting a deeper interaction with the phospholipid constituents of animal and bacterial cell membranes. The results suggested that at low concentrations Protonectarina-MP interacts with the membranes in a way that both terminal regions remain positioned outside the external surface of the membrane, while the α-carbon backbone becomes partially embedded in the membrane core and changing constantly the conformation, and causing membrane destabilization. The amidation of the C-terminal residue appears to be responsible for the stabilization of the peptide conformation in a secondary structure that is richer in α-helix content than its acidic congener. The helical, amphipathic conformation, in turn, allows a deeper peptide–membrane interaction, favoring both biological activities that depend on peptide structure recognition by the GPCRs (such as exocytosis) and those activities dependent on membrane perturbation (such as hemolysis and antibiosis).     

The use of fluoresceinphosphatidylethanolamine (FPE) as a real-time probe for peptide-membrane interactions

The characterization of fluorescelnphosphatidylethanolamlne (FPE) as a real-time Indicator of the electrostatic nature of a membrane surface is described. The conditions appropriate for the labelling of membranes and the implementation of FPE as a tool to monitor the interactions of various peptides with model membranes are outlined. It is shown that of the membrane-active peptides studied, Naja naja kaouthla cardiotoxin and pyrularia thionin bind to certain model membranes without insertion. Whereas the leader sequence of the nuclear encoded subunit IV of mammalian cytochrome c oxidase (E.C. 1.9.3.1), known as p-25, and melittin appear to bind and then partially insert into the membrane. It seems evident also that melittin does not adopt a fully transmembrane configuration. Melittin is known to promote membrane lysis and by employing a rapid-kinetic technique it is shown that the time-course of such lysis does not appear to correlate with peptide binding, but following binding a significant proportion of melittin must become inserted into the membrane before lysis appears to commence.     

Cationic peptide-induced remodelling of model membranes: direct visualization by in situ atomic force microscopy

Our understanding of how antimicrobial and cell-penetrating peptides exert their action at cell membranes would benefit greatly from direct visualization of their modes of action and possible targets within the cell membrane. We previously described how the cationic antimicrobial peptide, indolicidin, interacted with mixed zwitterionic planar lipid bilayers as a function of both peptide concentration and lipid composition [Shaw, J.E. et al., 2006. J. Struct. Biol. 154 (1), 42-58]. In the present report, in situ atomic force microscopy was used to characterize the interactions between three families of cationic peptides: (1) tryptophan-rich antimicrobial peptides--indolicidin and two of its analogues, (2) an amphiphilic alpha-helical membranolytic peptide--melittin, and (3) an arginine-rich cell-penetrating peptide--Tat with phase-separated planar bilayers containing 1,2-dioleoyl-sn-glycerol-3-phosphocholine (DOPC)/1,2-distearoyl-sn-glycerol-3-phosphocholine (DSPC) or DOPC/N-stearoyl-D-erythro-sphingosylphosphorylcholine (SM)/cholesterol. We found that these cationic peptides all induced remodelling of the model membranes in a concentration, and family-dependent manner. At low peptide concentration, these cationic peptides, despite their different biological roles, all appeared to reduce the interfacial line tension at the domain boundary between the liquid-ordered and liquid-disordered domains. Only at high peptide concentration was the membrane remodelling induced by these peptides morphologically distinct among the three families. While the transformation caused by indolicidin and its analogues were structurally similar, the concentration required to initiate the transformation was strongly dependent on the hydrophobicity of the peptide. Our use of lipid compositions with no net charge minimized the electrostatic interactions between the cationic peptides and the model supported bilayers. These results suggest that peptides within the same functional family have a common mechanism of action, and that membrane insertion of short cationic peptides at low peptide concentration may also alter membrane structure through a common mechanism regardless of the peptide's origin.     

Solution NMR studies of peptide-lipid interactions in model membranes

Abstract

Many important processes in life take place in or around the cell membranes. Lipids have different properties regarding their membrane-forming capacities, their mobility, shape, size and surface charge, and all of these factors influence the way that proteins and peptides interact with the membrane. In order for us to correctly understand these interactions, we need to be able to study all aspects of the interplay between lipids and peptides and proteins. Solution-state NMR offers a somewhat unique possibility to investigate structure, dynamics and location of proteins and peptides in bilayers. This review focuses on solution NMR as a tool for investigating peptide-lipid interaction, and special attention is given to the various membrane mimetics that are used to model the membrane. Examples from the field of cell-penetrating peptides and their lipid interactions will be given. The importance of studying lipid and peptide dynamics, which reflect on the effect that peptides have on bilayers, is highlighted, and in this respect, also the need for realistic membrane models.     

Solution NMR studies of peptide-lipid interactions in model membranes

Many important processes in life take place in or around the cell membranes. Lipids have different properties regarding their membrane-forming capacities, their mobility, shape, size and surface charge, and all of these factors influence the way that proteins and peptides interact with the membrane. In order for us to correctly understand these interactions, we need to be able to study all aspects of the interplay between lipids and peptides and proteins. Solution-state NMR offers a somewhat unique possibility to investigate structure, dynamics and location of proteins and peptides in bilayers. This review focuses on solution NMR as a tool for investigating peptide-lipid interaction, and special attention is given to the various membrane mimetics that are used to model the membrane. Examples from the field of cell-penetrating peptides and their lipid interactions will be given. The importance of studying lipid and peptide dynamics, which reflect on the effect that peptides have on bilayers, is highlighted, and in this respect, also the need for realistic membrane models.     

Interaction of enkephalin peptides with anionic model membranes.

According to the model for passive transport across the membranes, the total flow of permeant molecules is related to the product of the water-membrane partition coefficient and the diffusion coefficient, and to the water-membrane interfacial barrier. The effect of membrane surface charge on the permeability and interaction of analgesic peptide ligands with model membranes was investigated. A mixture of zwitterionic phospholipids with cholesterol was used as a model membrane. The lipid membrane charge density was controlled by the addition of anionic 1-palmitoyl-2-oleoylphosphatidylserine. Two classes of highly potent analgesic peptides were studied, c[D-Pen(2),D-Pen(5)]enkephalin (DPDPE) and biphalin, a dimeric analog of enkephalin. The effect of increased surface charge on the permeability of the zwitterionic DPDPE is a relatively modest decrease, that appears to be due to a diminished partition coefficient. On the other hand the binding of the dicationic biphalin ligands to membranes increases proportionally with increased negative surface charge. This effect translates into a significant reduction of biphalin permeability by reducing the diffusion of the peptide across the bilayer. These experiments show the importance of electrostatic effects on the peptide-membrane interactions and suggest that the negative charge naturally present in cell membranes may hamper the membrane transport of some peptide drugs, especially cationic ones, unless there are cationic transporters present.     

Lipid-induced conformation and lipid-binding properties of cytolytic and antimicrobial peptides: determination and biological specificity

While antimicrobial and cytolytic peptides exert their effects on cells largely by interacting with the lipid bilayers of their membranes, the influence of the cell membrane lipid composition on the specificity of these peptides towards a given organism is not yet understood. The lack of experimental model systems that mimic the complexity of natural cell membranes has hampered efforts to establish a direct correlation between the induced conformation of these peptides upon binding to cell membranes and their biological specificities. Nevertheless, studies using model membranes reconstituted from lipids and a few membrane-associated proteins, combined with spectroscopic techniques (i.e. circular dichroism, fluorescence spectroscopy, Fourier transform infra red spectroscopy, etc.), have provided information on specific structure-function relationships of peptide-membrane interactions at the molecular level. Reversed phase-high performance chromatography (RP-HPLC) and surface plasmon resonance (SPR) are emerging techniques for the study of the dynamics of the interactions between cytolytic and antimicrobial peptides and lipid surfaces. Thus, the immobilization of lipid moieties onto RP-HPLC sorbent now allows the investigation of peptide conformational transition upon interaction with membrane surfaces, while SPR allows the observation of the time course of peptide binding to membrane surfaces. Such studies have clearly demonstrated the complexity of peptide-membrane interactions in terms of the mutual changes in peptide binding, conformation, orientation, and lipid organization, and have, to a certain extent, allowed correlations to be drawn between peptide conformational properties and lytic activity.     

Interaction of enkephalin peptides with anionic model membranes

According to the model for passive transport across the membranes, the total flow of permeant molecules is related to the product of the water-membrane partition coefficient and the diffusion coefficient, and to the water-membrane interfacial barrier. The effect of membrane surface charge on the permeability and interaction of analgesic peptide ligands with model membranes was investigated. A mixture of zwitterionic phospholipids with cholesterol was used as a model membrane. The lipid membrane charge density was controlled by the addition of anionic 1-palmitoyl-2-oleoylphosphatidylserine. Two classes of highly potent analgesic peptides were studied, c[D-Pen²,D-Pen⁵]enkephalin (DPDPE) and biphalin, a dimeric analog of enkephalin. The effect of increased surface charge on the permeability of the zwitterionic DPDPE is a relatively modest decrease, that appears to be due to a diminished partition coefficient. On the other hand the binding of the dicationic biphalin ligands to membranes increases proportionally with increased negative surface charge. This effect translates into a significant reduction of biphalin permeability by reducing the diffusion of the peptide across the bilayer. These experiments show the importance of electrostatic effects on the peptide-membrane interactions and suggest that the negative charge naturally present in cell membranes may hamper the membrane transport of some peptide drugs, especially cationic ones, unless there are cationic transporters present.     

Membrane-induced folding of cecropin A

Lipid membranes manifest a diverse array of surface forces that can fold and orient an approaching protein. To better understand these forces and their ability to influence protein function, we have used infrared spectroscopy with isotopic editing to characterize the 37-residue membrane-active antimicrobial polypeptide cecropin A as it approached, adsorbed onto, and finally penetrated various lipid membranes. Intermediate stages in this process were isolated for study by the use of internal reflection and Langmuir trough techniques. Results indicate that this peptide adopts well-ordered secondary structure while superficially adsorbed to a membrane surface. Its conformation is predominantly alpha-helical, although some beta structure is likely to be present. The longitudinal axis of the helical structure, and the transverse axes of any beta structure, are preferentially oriented parallel to the membrane surface. The peptide expands the membrane against pressure when it penetrates the membrane surface, but its structure and orientation do not change. These observations indicate that interactions between the peptide and deeper hydrophobic regions of the membrane provide energy to perform thermodynamic work, but separate and distinct interactions between the peptide and superficial components of the membrane are responsible for peptide folding. These results have broad implications for our understanding of the mechanism of action and the specificity of these antimicrobial peptides.     

Lipid-controlled peptide topology and interactions in bilayers: structural insights into the synergistic enhancement of the antimicrobial activities of PGLa and magainin 2

To gain further insight into the antimicrobial activities of cationic linear peptides, we investigated the topology of each of two peptides, PGLa and magainin 2, in oriented phospholipid bilayers in the presence and absence of the other peptide and as a function of the membrane lipid composition. Whereas proton-decoupled ¹⁵N solid-state NMR spectroscopy indicates that magainin 2 exhibits stable in-plane alignments under all conditions investigated, PGLa adopts a number of different membrane topologies with considerable variations in tilt angle. Hydrophobic thickness is an important parameter that modulates the alignment of PGLa. In equimolar mixtures of PGLa and magainin 2, the former adopts transmembrane orientations in dimyristoyl-, but not 1-palmitoyl-2-oleoyl-, phospholipid bilayers, whereas magainin 2 remains associated with the surface in all cases. These results have important consequences for the mechanistic models explaining synergistic activities of the peptide mixtures and will be discussed. The ensemble of data suggests that the thinning of the dimyristoyl membranes caused by magainin 2 tips the topological equilibrium of PGLa toward a membrane-inserted configuration. Therefore, lipid-mediated interactions play a fundamental role in determining the topology of membrane peptides and proteins and thereby, possibly, in regulating their activities as well.     

Simulation study of interaction mechanism between peptide and asymmetric membrane

Cell-penetrating peptides (CPPs) are widely used as drug carriers, owing to their superior ability to cross cell membrane both alone and with cargos, such as genes and other particles. Understanding the translocation mechanism of CPP is significant for many therapeutic purposes, including targeting drug and gene delivery. In this study, we performed a coarse-grained molecular dynamics simulation to investigate the interaction mechanism between polyarginine peptides and asymmetric membranes. Results showed that peptides can penetrate through the lipid bilayer by inducing a hydrophilic hole formation in the asymmetric membrane. Furthermore, the lengthy peptide chain length (R4–R16 peptides) and high membrane asymmetry positively affect peptide penetration. Our study provides insights into the molecular-level interactions between peptides and asymmetric membranes, as well as suggestions for targeted gene and drug delivery.     

Effects of topology, length, and charge on the activity of a kininogen-derived peptide on lipid membranes and bacteria

Effects of topology, length, and charge on peptide interactions with lipid bilayers was investigated for variants of the human kininogen-derived peptide HKH20 (HKHGHGHGKHKNKGKKNGKH) by ellipsometry, CD, fluorescence spectroscopy, and z-potential measurements. The peptides display primarily random coil conformation in buffer and at lipid bilayers, and their lipid interaction is dominated by electrostatics, the latter evidenced by higher peptide adsorption and resulting membrane rupture for an anionic than for a zwitterionic membrane, as well as by strongly reduced adsorption and membrane rupture at high ionic strength. At sufficiently high peptide charge density, however, electrostatic interactions contribute to reducing the peptide adsorption and membrane defect formation. Truncating HKH20 into overlapping 10 amino acid peptides resulted in essentially eliminated membrane rupture and in a reduced amount peptide charges pinned at the lipid bilayer. Finally, cyclic HKH20 was found to be less efficient than the linear peptide in causing liposome rupture, partly due to a lower adsorption. Analogous results were found regarding bactericidal effects.