Conformational studies of TOAC-labeled bradykinin analogues in model membranes

Summary Spin-labeled analogues of bradykinin (BK) were synthesized containing the amino acid TOAC (2,2,6,6-tetramethylpiperidine-1-oxyl-4-amino-4-carboxylic acid) either before Arg¹ (TOAC⁰-BK) or replacing Pro³ (TOAC³-BK). Whereas the latter is inactive, the former retains about 70% of BK's activity in isolated rat uterus. A combined electron paramagnetic resonance (EPR)-circular dichroism (CD) approach was used to examine the conformational properties of the peptides in the presence of membrane-mimetic systems (negatively charged sodium dodecyl sulfate, SDS, and zwitterionic N-hexadecyl-N,N-dimethyl-3-ammonio-1-propanesulfonate, HPS). While the peptides bind to both monomeric and micellar SDS, no interaction occurs with HPS, evincing the contribution of electrostatic interactions. TOAC³-BK's EPR spectral lineshapes are broader than those of TOAC⁰-BK, indicating a more restricted degree of motion at position 3. Moreover, the motional freedom of both peptides decreased upon binding to SDS. BK and TOAC⁰-BK solution CD spectra indicate highly flexible conformations (possibly an equilibrium between rapidly interconverting forms), while TOAC³-BK's spectra correspond to a more ordered structure. SDS binding induces drastic changes in BK and TOAC⁰-BK spectra, indicating stabilization of similar folds. The micelle interface promotes a higher degree of secondary structure by favoring intramolecular hydrogen bonds. In contrast. TOAC³-BK spectra remain essentially unchanged. These results are interpreted as due to TOAC's ring imposing a more constrained conformation. This rigidity is very likely responsible for the inability of TOAC³-BK to acquire the correct receptor-bound conformation leading to loss of biological activity, On the other hand, the greater flexibility of TOAC⁰-BK and the similarity between its conformational behavior and that of the native hormone are probably related to their similar biological activity.     

Conformational basis for the biological activity of TOAC-labeled angiotensin II and bradykinin: electron paramagnetic resonance, circular dichroism, and fluorescence studies

N-Terminally and internally labeled analogues of the hormones angiotensin (AII, DRVYIHPF) and bradykinin (BK, RPPGFSPFR) were synthesized containing the paramagnetic amino acid 2,2,6,6-tetramethylpiperidine-1-oxyl-4-amino-4-carboxylic acid (TOAC). TOAC replaced Asp1 (TOAC1-AII) and Val3 (TOAC3-AII) in AII and was inserted prior to Arg1 (TOAC0-BK) and replacing Pro3 (TOAC3-BK) in BK. The peptide conformational properties were examined as a function of trifluoroethanol (TFE) content and pH. Electron paramagnetic resonance spectra were sensitive to both variables and showed that internally labeled analogues yielded rotational correlation times (tauC) considerably larger than N-terminally labeled ones, evincing the greater freedom of motion of the N-terminus. In TFE, tauC increased due to viscosity effects. Calculation of tau(Cpeptide)/tau(CTOAC) ratios indicated that the peptides acquired more folded conformations. Circular dichroism spectra showed that, except for TOAC1-AII in TFE, the N-terminally labeled analogues displayed a conformational behavior similar to that of the parent peptides. In contrast, under all conditions, the TOAC3 derivatives acquired more restricted conformations. Fluorescence spectra of AII and its derivatives were especially sensitive to the ionization of Tyr4. Fluorescence quenching by the nitroxide moiety was much more pronounced for TOAC3-AII. The conformational behavior of the TOAC derivatives bears excellent correlation with their biological activity, since, while the N-terminally labeled peptides were partially active, their internally labeled counterparts were inactive [Nakaie, C. R., et al., Peptides 2002, 23, 65-70]. The data demonstrate that insertion of TOAC in the middle of the peptide chain induces conformational restrictions that lead to loss of backbone flexibility, not allowing the peptides to acquire their receptor-bound conformation.     

Synthesis and preliminary conformational analysis of TOAC spin‐labeled analogues of the medium‐length peptaibiotic tylopeptin B

A set of analogues of the 14‐residue peptaibol tylopeptin B, containing the stable free‐radical 4‐amino‐1‐oxyl‐2,2,6,6,‐tetramethylpiperidine‐4‐carboxylic acid (TOAC) at one or two selected positions, was synthesized by the solid‐phase methodology. A solution conformational analysis performed by FTIR absorption and CD suggests that, in membrane‐mimicking solvents, the labeled tylopeptin B analogues preserve the helical propensity of the parent peptide, with a preference for the α‐helix or the 3₁₀‐helix type depending upon the nature of the solvent. In aqueous environment, the spin‐labeled analogues present a higher content of helical conformation as a consequence of the strong helix promoter effect of the conformationally constrained TOAC residue. We observed a progressive increase of the quenching effect of the nitroxyl radical on the fluorescence of the N‐terminal tryptophan as TOAC replaces the Aib residue at positions 13, 8, and 4, respectively. A membrane permeabilization assay performed on two selected analogues, TOAC⁸‐ and TOAC¹³‐tylopeptin B, showed that the labeled peptides exhibit membrane‐modifying properties comparable with those of the natural peptaibiotic. We conclude that our TOAC paramagnetic analogues of tylopeptin B are good models for a detailed ESR investigation of the mechanism of membrane permeabilization induced by medium‐length peptaibiotics. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Electron paramagnetic resonance backbone dynamics studies on spin-labelled neuropeptide Y analogues.

Neuropeptide Y (NPY) is one of the most abundant peptides in the central nervous system of mammalians. NPY acts by binding to at least five G-protein coupled receptors (GPCRs) which have been named Y1, Y2, Y4, Y5 and Y6. Three spin-labelled NPY analogues containing the nitroxide group of the amino acid TOAC (2.2.6.6-tetramethylpiperidine-1-oxyl-4-amino-4-carboxylic acid) as a paramagnetic probe were synthesized by solid-phase peptide synthesis. Synthetic problems owing to the sensitivity of nitroxide towards acidic and reducing conditions have been overcome by using a cleavage cocktail that contains anisole and cresol scavengers. Concerning the receptor binding preferences, the analogues [TOAC34]-pNPY and [Ala31, TOAC32]-pNPY showed a marked selectivity for the Y5 receptor, while [TOAC2]-pNPY maintained a significant binding also to the Y2 receptor subtype. The modifications of the native peptide structure caused by the introduction of TOAC were examined by circular dichroism. In order to determine the rotational correlation time of the spin probes, electron paramagnetic resonance measurements were performed in solution and in the presence of liposomes. This allowed us to evaluate the backbone dynamics of the different parts of the NPY molecule in the free and membrane bound states. The results of these studies showed that NPY Interacts with liposomes by using the C-terminal alpha-helix while the N-terminal tail retains a flexibility that is comparable to that of the peptide in solution as already shown by NMR studies on DPC micelles. Furthermore, we demonstrated that TOAC-labelllng is a valuable tool to investigate changes in the backbone conformation and dynamics. This may be of major importance for peptides and small proteins when they bind to cell membranes.     

Opioid activity of synthetic deltorphin II analogues and their spin labeled derivatives

Summary Deltorphin II (Tyr-D-Ala-Phe-Glu-Val-Val-Gly, NH₂, Del II), an endogenous linear heptapeptide, is a highly selective agonist of the δ-opioid receptor. To study the effect of the position 4 residue (Glu) on the opioid activity of Del II, we designed and synthesized three analogues of Del II by solid-phase peptide synthesis. They were [Val⁴, Glu⁵]Del II, [Val⁴, Glu⁶]Del II and [Gly⁴, Glu⁷]Del II. To study the effect of spin labeling on peptide bioactivities, all the peptides were labeled using a free radical. The labeling material was a stable nitrogen-oxygen free radical which was linked to the N-terminal via an amide bond. We investigated the opioid bioactivities of these analogues both in vivo and in vitro, and concluded that the differences in opioid activity of Del II and its analogues were due to structural differences. When the Glu residue is at position 5 or 6, the internal hydrogen bonds in Del II are affected and there is a change in three-dimensional structure and opioid activity. The antinociceptive activity of all the peptides decreased after spin labeling. This indicates that the stable nitrogen-oxygen free radical is a dual-function spin-labeling molecule.     

Characterization of specific fluorenylmethyloxycarbonyl-containing calmodulin adducts by spectroscopy and phosphodiesterase stimulation

A reagent (I, N⁴-(9-fluorenylmethyloxycarbonyl-4-amino-1-oxyl-4-succinimidyloxycarbonyl-2,2,6,6-tetramethylpiperidine)) that acylates calmodulin specifically at lysines 75 and 148 was recently described (Jackson and Puett, 1984). Chromatographic procedures are described that permit purification to apparent homogeneity of a 1 : 1 and a 2 : 1 adduct characterized by modification at just Lys 75 or at Lys 75 and Lys 148, respectively. These adducts are suitable for detailed characterization in an effort to provide information on calmodulin structure-function relationships. The adducts were incapable of, or exhibited low potency (e.g., 0.1% that of calmodulin) in, stimulating the activity of an activatable bovine brain cyclic nucleotide phosphodiesterase (3,5-cyclic AMP 5-nucleotidehydrolase, EC 3.1.4.17) preparation. Electron paramagnetic resonance (EPR) spectroscopy of the adducts yielded rotational correlation times of approximately 3–6 nsec, in agreement with the expected value for a hydrated protein of this molecular weight (5–7 nsec). Thus, the nitroxide reporter group appears to monitor closely the motion of the protein, and there is no evidence of a major conformational change in the derivative relative to calmodulin. Interestingly, removal of the fluorenylmethyloxycarbonyl portion from the 1 : 1 adduct to give a deprotected 1 : 1 adduct resulted in apparent greater mobility of the probe, since the rotational correlation coefficient was found to be 1 nsec. Circular dichroic spectra were obtained over the wavelength interval 200–250 nm on the two adducts and on the deprotected 1 : 1 adduct. These derivatives, like calmodulin, exhibited a Ca²⁺-mediated increase in helicity, and the spectra of the adducts in the presence of a chelating agent and in the presence of saturating Ca²⁺ were similar to those obtained for calmodulin. Thus, the adducts have secondary structures similar to the native protein. Proton nuclear magnetic resonance spectra were determined in the aromatic region (6–8 ppm) for the deprotected 1 : 1 adduct before and after reduction of the nitroxide with ascorbate. The nitroxide had little effect on the chemical shifts of the two tyrosines and the single histidine relative to calmodulin, although the histidine C4 resonance was markedly altered by the addition of ascorbate. In order to explore in greater detail the tertiary structure of the 1 : 1 adduct, a reagent similar to I, but not paramagnetic, was synthesized. This compound II, -N-(9-fluorenylmethyloxycarbonyl)alanine N-hydroxysuccinimide ester, like I, forms a 1 : 1 adduct at Lys 75 and a 2 : 1 adduct at Lys 75 and Lys 148. Proton NMR spectra of adducts with II were not complicated by the relaxation effects arising from adducts with I; thus more definitive assignments could be made to the upfield resonances, including the fluorene protons. Again, it was possible to conclude that adduct formation had no major effect on the tertiary structure of the protein as monitored by chemical shifts associated with various residues. We conclude that modification of just Lys 75, a residue in the long connecting helix of calmodulin, does not lead to major changes in protein conformation but does interfere with the ability of calmodulin to stimulate an activatable form of bovine brain cyclic nucleotide phosphodiesterase.     

Conformational studies of chemotactic HCO-Met-Leu-Phe-OMe analogues

Summary In order to investigate the proper peptide backbone conformation able to elicit a biological activity, HCO-Met-Pro-Phe-OMe, HCO-Met-[COO]Leu-Phe-OMe, and HCO-Met-OLeu-Phe-OMe, analogues of the prototypical chemotactic peptide HCO-Met-Leu-Phe-OMe, were studied by CD and IR techniques. The results obtained comparing biological and conformational data evidence the critical presence of (i) the NH group at position 2, (ii) a rather flexible backbone, (iii) the chemical structure of the central residue which can affect the stability of a possible active conformer.     

The spin label amino acid TOAC and its uses in studies of peptides: chemical, physicochemical, spectroscopic, and conformational aspects

We review work on the paramagnetic amino acid 2,2,6,6-tetramethyl-N-oxyl-4-amino-4-carboxylic acid, TOAC, and its applications in studies of peptides and peptide synthesis. TOAC was the first spin label probe incorporated in peptides by means of a peptide bond. In view of the rigid character of this cyclic molecule and its attachment to the peptide backbone via a peptide bond, TOAC incorporation has been very useful to analyze backbone dynamics and peptide secondary structure. Many of these studies were performed making use of EPR spectroscopy, but other physical techniques, such as X-ray crystallography, CD, fluorescence, NMR, and FT-IR, have been employed. The use of double-labeled synthetic peptides has allowed the investigation of their secondary structure. A large number of studies have focused on the interaction of peptides, both synthetic and biologically active, with membranes. In the latter case, work has been reported on ligands and fragments of GPCR, host defense peptides, phospholamban, and β-amyloid. EPR studies of macroscopically aligned samples have provided information on the orientation of peptides in membranes. More recent studies have focused on peptide-protein and peptide-nucleic acid interactions. Moreover, TOAC has been shown to be a valuable probe for paramagnetic relaxation enhancement NMR studies of the interaction of labeled peptides with proteins. The growth of the number of TOAC-related publications suggests that this unnatural amino acid will find increasing applications in the future.     

Conformational and functional studies of gomesin analogues by CD, EPR and fluorescence spectroscopies

The aim of this work was to examine the bioactivity and the conformational behavior of some gomesin (Gm) analogues in different environments that mimic the biological membrane/water interface. Thus, manual peptide synthesis was performed by the solid-phase method, antimicrobial activity was evaluated by a liquid growth inhibition assay, and conformational studies were performed making use of several spectroscopic techniques: CD, fluorescence and EPR. [TOAC¹]-Gm; [TOAC¹, Ser^2,6,11,15]-Gm; [Trp⁷]-Gm; [Ser^2,6,11,15, Trp⁷]-Gm; [Trp⁹]-Gm; and [Ser^2,6,11,15, Trp⁹]-Gm were synthesized and tested. The results indicated that incorporation of TOAC or Trp caused no significant reduction of antimicrobial activity; the cyclic analogues presented a β-hairpin conformation similar to that of Gm. All analogues interacted with negatively charged SDS both above and below the detergent's critical micellar concentration (cmc). In contrast, while Gm and [TOAC¹]-Gm required higher LPC concentrations to bind to micelles of this zwitterionic detergent, the cyclic Trp derivatives and the linear derivatives did not seem to interact with this membrane-mimetic system. These data corroborate previous results that suggest that electrostatic interactions with the lipid bilayer of microorganisms play an important role in the mechanism of action of gomesin. Moreover, the results show that hydrophobic interactions also contribute to membrane binding of this antimicrobial peptide.     

A differential association of Apolipoprotein E isoforms with the amyloid-β oligomer in solution

The molecular pathogenesis of disorders arising from protein misfolding and aggregation is difficult to elucidate, involving a complex ensemble of intermediates, whose toxicity depends upon their state of progression along distinct processing pathways. To address the complex misfolding and aggregation that initiates the toxic cascade resulting in Alzheimer's disease (AD), we have developed a 2,2,6,6-tetramethylpiperidine-1-oxyl-4-amino-4-carboxylic acid spin-labeled amyloid-β (Aβ) peptide to observe its isoform-dependent interaction with the apoE protein. Although most individuals carry the E3 isoform of apoE, ～15% of humans carry the E4 isoform, which is recognized as the most significant genetic determinant for Alzheimer's. ApoE is consistently associated with the amyloid plaque marker for AD. A vital question centers on the influence of the two predominant isoforms, E3 and E4, on Aβ peptide processing and hence Aβ toxicity. We used electron paramagnetic resonance (EPR) spectroscopy of incorporated spin labels to investigate the interaction of apoE with the toxic oligomeric species of Aβ in solution. EPR spectra of the spin-labeled side chain report on side chain and backbone dynamics as well as the spatial proximity of spins in an assembly. Our results indicate oligomer binding involves the C-terminal domain of apoE, with apoE3 reporting a much greater response through this conformational marker. Coupled with SPR binding measurements, apoE3 displays a higher affinity and capacity for the toxic Aβ oligomer. These findings support the hypothesis that apoE polymorphism and Alzheimer's risk can largely be attributed to the reduced ability of apoE4 to function as a clearance vehicle for the toxic form of Aβ.     

Orientation and immersion depth of a helical lipopeptaibol in membranes using TOAC as an ESR probe

Trichogin GA IV is a lipopeptaibol antibiotic characterized by the sequence nOct–Aib¹–Gly–Leu–Aib⁴–Gly–Gly–Leu–Aib⁸–Gly–Ile–Lol (nOct: n‐octanoyl; Aib: α‐aminoisobutyric acid; Lol, leucinol), which exhibits membrane‐modifying properties. We synthesized step‐by‐step by solution methods three trichogin analogues, each with a single Aib → 2,2,6,6‐tetramethylpiperidin‐1‐oxyl‐4‐amino‐4‐carboxylic acid (TOAC) substitution. The similarity in the conformational propensities of the C^α‐tetrasubstituted α‐amino acids Aib and TOAC allowed us to exploit these analogues to investigate the orientation and therefore the mechanism of action of trichogin in the membranes by the electron spin resonance (ESR) technique. A conformational analysis by Fourier transform ir absorption and CD in different organic solvents and in a membrane‐mimetic environment indicated that the conformation of the natural lipopeptaibol remains almost unchanged in the three analogues. Moreover, for all of the analogues permeability measurements revealed membrane‐modifying properties comparable to those of trichogin. Our ESR investigation demonstrated that, in liposomes based on phosphatidylcholine, trichogin lays parallel to the membrane surface with its hydrophobic face oriented toward the membrane interior. These results suggest that trichogin might modify membrane permeability via a carpet‐like mechanism, at least in liposomes and in the absence of a transmembrane potential. © 1999 John Wiley & Sons, Inc. Biopoly 50: 239–253, 1999     

Conformational studies of cyclic enkephalin analogues with L- or D-proline in position 3.

The conformation of a series of cyclic enkephalin analogues of a general formula X(1)-cyclo[Y(2)-Z(3)-Nal(4)-Leu(5)] (Nal: beta-(2-naphthyl)alanine), where X = Tyr, Phe, or Phe(NO(2)), Y = D-Dab or L-Dab (Dab: 2,4-diaminobutyric acid), and Z = D-Pro or L-Pro, was studied by means of NMR spectroscopy and theoretical conformational analysis with the Empirical Conformational Energy Program for Peptides and Proteins force field plus solvation. The NMR measurements were performed in dimethyl sulfoxide solution. The nuclear Overhauser effect intensities and coupling constants were used to compute the statistical weights of the conformations of the ensemble generated in global conformational searches. The purpose of this study was to determine whether introducing the D- or L-proline residue in position 3 can produce peptides with both rigid backbone and significant separation of the pharmacophore groups in position 1 and 4 (as required for high affinity for the mu-type opioid receptors). It was found that the analogues with D-Dab in position 2 and D-Pro in position 3 possess a stable type II' beta-turn at positions 3 and 4, which rigidifies the cyclic backbone; this finding was confirmed by independent measurements of the temperature coefficients of the amide protons, which indicated very significant screening of the Leu(5) amide proton from the solvent. However, these analogues were found to possess a short interchromophore distance. The analogues containing both Dab and Pro in the L-configuration are characterized by a larger interchromophore distance; however, they do not possess a stable beta-turn and have therefore a higher conformational flexibility. The modifications proposed in this work are therefore not likely to lead to enkephalin analogues with a high affinity for the mu-receptors.     

Structural determinants of nitroxide motion in spin-labeled proteins: solvent-exposed sites in helix B of T4 lysozyme

Site-directed spin labeling provides a means for exploring structure and dynamics in proteins. To interpret the complex EPR spectra that often arise, it is necessary to characterize the rotamers of the spin-labeled side chain and the interactions they make with the local environment in proteins of known structure. For this purpose, crystal structures have been determined for T4 lysozyme bearing a nitroxide side chain (R1) at the solvent-exposed helical sites 41 and 44 in the B helix. These sites are of particular interest in that the corresponding EPR spectra reveal two dynamic states of R1, one of which is relatively immobilized suggesting interactions of the nitroxide with the environment. The crystal structures together with the effect of mutagenesis of nearest neighbors on the motion of R1 suggest intrahelical interactions of 41R1 with the i + 4 residue and of 44R1 with the i + 1 residue. Such interactions appear to be specific to particular rotamers of the R1 side chain.     

Conformational studies of human islet amyloid peptide using molecular dynamics and simulated annealing methods

Molecular dynamics simulations and simulated annealing in vacuum, model aqueous solution, and simulated membrane were used to analyze the conformational preferences of a segment spanning 20–29 residues of human islet amyloid polypeptide, [referred to as IAPP^H(20–29)]. Molecular dynamics simulations were conducted at 300 K on IAPP^H(20–29). The minimum energy conformers obtained in model aqueous solution and vacuum exhibited similar structures. Even in the absence of any constraints on peptide bonds, trans conformation was preferred consistently by all the peptide bonds. Analysis of the minimum energy conformers indicated that IAPP^H(20–29) showed a strong preference for turn structures in all the environments. These turn structures were stabilized by the formation of hydrogen bonds between the backbone amide and carbonyl groups. A good agreement was found between the results obtained from the molecular dynamics simulation and solid-state nmr experimental studies. © 1998 John Wiley & Sons, Inc. Biopoly 45: 9–20, 1998     

Cholesterol prevents interaction of the cell‐penetrating peptide transportan with model lipid membranes

Interaction of the cell‐penetrating peptide (CPP) cysteine‐transportan (Cys‐TP) with model lipid membranes was examined by spin‐label electron paramagnetic resonance (EPR). Membranes were labeled with lipophilic spin probes and the influence of Cys‐TP on membrane structure was studied. The influence of Cys‐TP on membrane permeability was monitored by the reduction of a liposome‐trapped water‐soluble spin probe. Cys‐TP caused lipid ordering in membranes prepared from pure dimyristoylphosphatidylcholine (DMPC) and in DMPC membranes with moderate cholesterol concentration. In addition, Cys‐TP caused a large increase in permeation of DMPC membranes. In contrast, with high cholesterol content, at which model lipid membranes are in the so‐called liquid‐ordered phase, no effect of Cys‐TP was observed, either on the membrane structure or on the membrane permeability. The interaction between Cys‐TP and the lipid membrane therefore depends on the lipid phase. This could be of great importance for understanding of the CPP–lipid interaction in laterally heterogeneous membranes, while it implies that the CPP–lipid interaction can be different at different points along the membrane. Copyright © 2008 European Peptide Society and John Wiley & Sons, Ltd.     

Structural determinants of nitroxide motion in spin-labeled proteins: tertiary contact and solvent-inaccessible sites in helix G of T4 lysozyme

A nitroxide side chain (R1) has been substituted at single sites along a helix-turn-helix motif in T4 lysozyme (residues 114-135). Together with previously published data, the new sites reported complete a continuous scan through the motif. Mutants with R1 at sites 115 and 118 were selected for crystallographic analysis to identify the structural origins of the corresponding two-component EPR spectra. At 115, R1 is shown to occupy two rotamers in the room temperature crystal structure, one of which has not been previously reported. The two components in the EPR spectrum apparently arise from differential interactions of the two rotamers with the surrounding structure, the most important of which is a hydrophobic interaction of the nitroxide ring. Interestingly, the crystal structure at 100 K reveals a single rotamer, emphasizing the possibility of rotamer selection in low-temperature crystal structures. Residue 118 is at a solvent-inaccessible site in the protein core, and the structure of 118R1, the first reported for the R1 side chain at a buried site, reveals how the side chain is accommodated in an overpacked core.     

Peptide conformational changes induced by tryptophan-phosphocholine interactions in a micelle

Sodium dodecylsulfate (SDS) and dodecylphosphocholine (DPC) micelles are often used to mimic the membrane- or receptor-bound states of peptides in NMR studies. From the present examination of a 26-residue analog of exendin-4 (TrEX4) by NMR and CD in water, aqueous 30% trifluoroethanol (TFE), and bound to both SDS and DPC micelles, it is clear that these two lipid micelles can yield very different peptide structures. The Trp-cage fold (also observed in 30% TFE) is present when TrEX4 is bound to SDS micelles; however, tertiary structure is absent in the presence of DPC micelles. The loss of tertiary structure is attributed to an energetically favorable interaction (estimated as 2-3 kcal/mol) of the tryptophan side chain with the phosphocholine head groups. These dramatic structural differences suggest that care must be taken when using either SDS or DPC to mimic the membrane- or receptor-bound states.     

Silver‐induced conformational changes of polypeptides: a CD study

The role of silver ions in various pathologies, as well as their effect on peptide conformation and properties are less understood. Consequently, we synthesized several peptides with various residues in their sequence to investigate silver‐induced conformational changes at various pH values by Circular Dichroism spectroscopy. Uniquely, the glycine‐based, histidine‐containing peptide showed a severe change from a random coil and β‐turn conformation to large α‐helices during silver binding. When comparing the effect of silver ions on the conformation of bradykinin a similar tendency was found. Besides, silver ions reduced the amyloid‐β peptide tendency to aggregation. Our results suggest a specific and protective role for silver ions in brain pathologies, which is related to their high affinity toward physiologically and pharmacologically active peptides. Fourier transform infrared spectroscopy studies as well as the mass spectrometric ones support our conclusions. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

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.