Conversion of a porin-like peptide channel into a gramicidin-like channel by glycine to D-alanine substitutions

The beta-barrel and beta-helix formation, as in porins and gramicidin, respectively, represent two distinct mechanisms for ion channel formation by beta-sheet proteins in membranes. The design of beta-barrel proteins is difficult due to incomplete understanding of the basic principles of folding. The design of gramicidin-like beta-helix relies on an alternating pattern of L- and D-amino acid sequences. Recently we noticed that a short beta-sheet peptide (xSxG)(6), can form porin-like channels via self-association in membranes. Here, we proposed that glycine to D-alanine substitutions of the N-formyl-(xSxG)(6) would transform the porin-like channel into a gramicidin-like beta(12)-helical channel. The requirement of an N-formyl group for channel activity, impermeability to cations with a diameter >4 A, high monovalent cation selectivity, and the absence of either voltage gating or subconductance states upon D-alanine substitution support the idea of a gramicidin-like channel. Moreover, the circular dichroism spectrum in membranes is different, indicating a change in regular beta-sheet backbone structure. The conversion of a complex porin-like channel into a gramicidin-like channel provides a link between two different mechanisms of beta-sheet channel formation in membranes and emphasizes the importance of glycine and D-amino acid residues in protein folding and function and in the engineering of ion channels.     

Aggregation and porin-like channel activity of a beta sheet peptide

Beta sheet peptides (e.g., amyloid beta) are known to form ion channels in lipid bilayers possibly through aggregation, though the channel structure is not clear. We have recently reported that a short beta sheet peptide, (xSxG)(6), forms porin-like voltage-gated channels in lipid bilayers [Thundimadathil et al. (2005) Biochem. Biophys. Res. Commun. 330, 585-590]. To account for the porin-like activity, oligomerization of the peptide into a beta barrel-like structure was proposed. In this work, peptide aggregation in aqueous and membrane environments and a detailed study of channel properties were performed to gain insight into the mechanism of channel formation. The complex nature of the channel was revealed by kinetic analysis and the occurrence of interconverting multiple conductance states. Ion channels were inhibited by Congo red, suggesting that the peptide aggregates are the active channel species. Peptide aggregation and fibril formation in water were confirmed by electron microscopy (EM) and Congo red binding studies. Furthermore, oligomeric structures in association with lipid bilayers were detected. Circular dichroism of peptide-incorporated liposomes and peptide-lipid binding studies using EM suggest a lipid-induced beta sheet aggregation. Gel electrophoresis of peptide-incorporated liposomes showed dimeric and multimeric structures. Taken together, this work indicates insertion of (xSxG)(6) as oligomers into the lipid bilayer, followed by rearrangement into a beta barrel-like pore structure. A large peptide pore comprising several individual beta sheets or smaller beta sheet aggregates is expected to have a complex behavior in membranes. A dyad repeat sequence and the presence of glycine, serine, and hydrophobic residues in a repeated pattern in this peptide may be providing a favorable condition for the formation of a beta barrel-like structure in lipid bilayers.     

Unique membrane-interacting properties of the immunostimulatory cationic peptide KLKL(5)KLK (KLK)

We have monitored the effects of KLKL(5)KLK (KLK), a derivative of a natural cationic antimicrobial peptide (CAP) on isolated membrane vesicles, and investigated the partition of the peptide within these structures. KLK readily interacted with fluorescent dyes entrapped in the vesicles without apparent pore formation. Fractionation of vesicles revealed KLK predominantly in the membrane. Peptide-treated vesicles appeared with generally disorganized bilayers. While KLK showed no effect on osmotic resistance of human erythrocytes, dramatic decrease in core and surface membrane fluidity was observed in peptide-treated erythrocyte ghosts as measured by fluorescence anisotropy. Finally, CD spectroscopy revealed lipid-induced random coil to beta-sheet and beta-sheet to alpha-helix conformational transitions of KLK. Together with the oligonucleotide oligo-d(IC)(13) [ODN1a], KLK functions as a novel adjuvant, termed IC31. Among other immunological effects, KLK appears to facilitate the uptake and delivery of ODN1a into cellular compartments, but the nature of KLK's interaction with the cell surface and other membrane-bordered compartments remains unknown. Our results suggest a profound membrane interacting property of KLK that might contribute to the immunostimulatory activities of IC31.     

Secondary structure of substance P bound to liposomes in organic solvents and in solution from Raman and CD spectroscopy.

The membrane lipid phase may be an important mediator of the peptide-receptor interaction. In order to understand the mechanism of this interaction, it is important to know the peptide structure, not only in the hydrophobic lipid bilayer environment, but also at the bilayer surface and in solution. To investigate this problem we have measured the secondary structure of the 11-residue neuropeptide substance P (SP) and its fragments in aqueous solutions, in membrane mimetic solvents, and associated with lipid bilayers using Raman and CD spectroscopy. Raman and CD spectra of SP bound to liposomes indicate a less than 20% helix content. We interpret these results to indicate that SP contains virtually no helix when bound to negatively charged liposomes. These spectra are similar to spectra of peptides in type I and III beta-turns. SP forms between 10 and 30% (1-3 residues) helical structure in sodium dodecyl sulfate micelles and less than 10% helix in methanol and trifluoroethanol. The binding of SP to negatively charged liposomes significantly changes the structure of the lipid acyl chains, decreasing order in some cases and increasing it in others. Raman spectra of SP in water indicates that SP near 30 mM forms an ensemble of structures in water that is distinct from completely unfolded peptide and from the aggregated beta-sheet form observed in saline solutions. We conclude from our CD results that methods used to quantitate secondary structure from CD spectra of short peptides cannot be used to distinguish between very short helical segments and beta-turns.     

Correct folding of the beta-barrel of the human membrane protein VDAC requires a lipid bilayer

Spontaneous membrane insertion and folding of beta-barrel membrane proteins from an unfolded state into lipid bilayers has been shown previously only for few outer membrane proteins of Gram-negative bacteria. Here we investigated membrane insertion and folding of a human membrane protein, the isoform 1 of the voltage-dependent anion-selective channel (hVDAC1) of mitochondrial outer membranes. Two classes of transmembrane proteins with either alpha-helical or beta-barrel membrane domains are known from the solved high-resolution structures. VDAC forms a transmembrane beta-barrel with an additional N-terminal alpha-helix. We demonstrate that similar to bacterial OmpA, urea-unfolded hVDAC1 spontaneously inserts and folds into lipid bilayers upon denaturant dilution in the absence of folding assistants or energy sources like ATP. Recordings of the voltage-dependence of the single channel conductance confirmed folding of hVDAC1 to its active form. hVDAC1 developed first beta-sheet secondary structure in aqueous solution, while the alpha-helical structure was formed in the presence of lipid or detergent. In stark contrast to bacterial beta-barrel membrane proteins, hVDAC1 formed different structures in detergent micelles and phospholipid bilayers, with higher content of beta-sheet and lower content of alpha-helix when inserted and folded into lipid bilayers. Experiments with mixtures of lipid and detergent indicated that the content of beta-sheet secondary structure in hVDAC1 decreased at increased detergent content. Unlike bacterial beta-barrel membrane proteins, hVDAC1 was not stable even in mild detergents such as LDAO or dodecylmaltoside. Spontaneous folding of outer membrane proteins into lipid bilayers indicates that in cells, the main purpose of membrane-inserted or associated assembly factors may be to select and target beta-barrel membrane proteins towards the outer membrane instead of actively assembling them under consumption of energy as described for the translocons of cytoplasmic membranes.     

Secondary and tertiary structure formation of the beta-barrel membrane protein OmpA is synchronized and depends on membrane thickness

The mechanism of membrane insertion and folding of a beta-barrel membrane protein has been studied using the outer membrane protein A (OmpA) as an example. OmpA forms an eight-stranded beta-barrel that functions as a structural protein and perhaps as an ion channel in the outer membrane of Escherichia coli. OmpA folds spontaneously from a urea-denatured state into lipid bilayers of small unilamellar vesicles. We have used fluorescence spectroscopy, circular dichroism spectroscopy, and gel electrophoresis to investigate basic mechanistic principles of structure formation in OmpA. Folding kinetics followed a second-order rate law and is strongly depended on the hydrophobic thickness of the lipid bilayer. When OmpA was refolded into model membranes of dilaurylphosphatidylcholine, fluorescence kinetics were characterized by a rate constant that was about fivefold higher than the rate constants of formation of secondary and tertiary structure, which were determined by circular dichroism spectroscopy and gel electrophoresis, respectively. The formation of beta-sheet secondary structure and closure of the beta-barrel of OmpA were correlated with the same rate constant and coupled to the insertion of the protein into the lipid bilayer. OmpA, and presumably other beta-barrel membrane proteins therefore do not follow a mechanism according to the two-stage model that has been proposed for the folding of alpha-helical bundle membrane proteins. These different folding mechanisms are likely a consequence of the very different intramolecular hydrogen bonding and hydrophobicity patterns in these two classes of membrane proteins.     

Temperature and pH effects on biophysical and morphological properties of self-assembling peptide RADA16-I.

It has been found that the self-assembling peptide RADA 16-I forms a beta-sheet structure and self-assembles into nanofibers and scaffolds in favor of cell growth, hemostasis and tissue-injury repair. But its biophysical and morphological properties, especially for its beta-sheet and self-assembling properties in heat- and pH-denatured conditions, remain largely unclear. In order to better understand and design nanobiomaterials, we studied the self-assembly behaviors of RADA16-I using CD and atomic force microscopy (AFM) measurements in various pH and heat-denatured conditions. Here, we report that the peptide, when exposed to pH 1.0 and 4.0, was still able to assume a typical beta-sheet structure and self-assemble into long nanofiber, although its beta-sheet content was dramatically decreased by 10% in a pH 1.0 solution. However, the peptide, when exposed to pH 13.0, drastically lost its beta-sheet structure and assembled into different small-sized globular aggregates. Similarly, the peptide, when heat-denatured from 25 to 70 degrees C, was still able to assume a typical beta-sheet structure with 46% content, but self-assembled into small-sized globular aggregates at much higher temperature. Titration experiments showed that the peptide RADA16-I exists in three types of ionic species: acidic (fully protonated peptide), zwitterionic (electrically neutral peptide carrying partial positive and negative charges) and basic (fully deprotonated peptide) species, called 'super ions'. The unordered structure and beta-turn of these 'super ions' via hydrogen or ionic bonds, and heat Brownian motion under the above denatured conditions would directly affect the stability of the beta-sheet and nanofibers. These results help us in the design of future nanobiomaterials, such as biosensors, based on beta-sheets and environmental changes. These results also help understand the pathogenesis of the beta-sheet-mediated neuronal diseases such as Alzheimer's disease and the mechanism of hemostasis.     

Spectroscopic analysis of low pH and lipid-induced structural changes in type A botulinum neurotoxin relevant to membrane channel formation and translocation

Botulinum neurotoxin (BoNT) is an extremely toxic protein to animals and humans. In its mode of action, one of its subunits mediates its translocation by integrating itself into the membrane bilayer. We have examined the membrane channel activity of type A BoNT (BoNT/A) and its heavy (H) chain in planar lipid membrane under various pH conditions to understand the possible role of the channel activity in the translocation of the BoNT/A light (L) chain under physiological conditions. Only BoNT/A H chain, and not the BoNT/A, exhibited membrane channel activity for translocation of ions. The H chain-induced increase in conductance did not require a pH gradient across the lipid membrane, although it was enhanced by a pH gradient. To understand the molecular basis of the membrane channel activity and the translocation of the L chain, the secondary structure of BoNT/A and its H and L chains were analyzed using circular dichroism (CD) and Fourier-transform infrared (FT-IR) spectroscopy at different pH values. BoNT/A showed no structural alternation upon acidifying the buffer pH. However, an increase in beta-sheet content of BoNT/A H chain at low pH was noted when examined by FT-IR. The L chain structure significantly changed with decrease in pH, and the change was mostly reversible. In addition, the neurotoxin and its subunit chains induced a partially reversible aggregation of liposomes at low pH, which indicated their integration into the lipid bilayer. Temperature-induced denaturation studies of BoNT/A H chain indicated major structural reorganization upon its interaction with membrane, especially at low pH.     

Solution structure of ZipA, a crucial component of Escherichia coli cell division

ZipA, an essential component of cell division in Escherichia coli, interacts with the FtsZ protein at the midcell in one of the initial steps of septum formation. The high-resolution solution structure of the 144-residue C-terminal domain of E. coli ZipA (ZipA(185)(-)(328)) has been determined by multidimensional heteronuclear NMR. A total of 30 structures were calculated by means of hybrid distance geometry-simulated annealing using a total of 2758 experimental NMR restraints. The atomic root means square distribution about the mean coordinate positions for residues 6-142 for the 30 structures is 0.37 +/- 0.04 A for the backbone atoms, 0. 78 +/- 0.05 A for all atoms, and 0.45 +/- 0.04 A for all atoms excluding disordered side chains. The NMR solution structure of ZipA(185)(-)(328) is composed of three alpha-helices and a beta-sheet consisting of six antiparallel beta-strands where the alpha-helices and the beta-sheet form surfaces directly opposite each other. A C-terminal peptide from FtsZ has been shown to bind ZipA(185)(-)(328) in a hydrophobic channel formed by the beta-sheet providing insight into the ZipA-FtsZ interaction. An unexpected similarity between the ZipA(185)(-)(328) fold and the split beta-alpha-beta fold observed in many RNA binding proteins may further our understanding of the critical ZipA-FtsZ interaction.     

Amyloid-like fibril formation in an all beta-barrel protein. Partially structured intermediate state(s) is a precursor for fibril formation

Acidic fibroblast growth factor from newt (Notopthalmus viridescens) is a approximately 15-kDa, all beta-sheet protein devoid of disulfide bonds. In the present study, we investigate the effects of 2,2,2-trifluoroethanol (TFE) on the structure of newt acidic fibroblast growth factor (nFGF-1). The protein aggregates maximally in 10% (v/v) TFE. Congo red and thioflavin T binding experiments suggest that the aggregates induced by TFE have properties resembling the amyloid fibrils. Transmission electron microscopy and x-ray fiber diffraction data show that the fibrils (induced by TFE) are straight, unbranched, and have a cross-beta structure with an average diameter of 10-15 A. Preformed fibrils (induced by TFE) of nFGF-1 are observed to seed amyloid-like fibril formation in solutions containing the protein (nFGF-1) in the native beta-barrel conformation. Fluorescence, far-UV CD, anilino-8-napthalene sulfonate binding, multidimensional NMR, and Fourier transformed infrared spectroscopy data reveal that formation of a partially structured intermediate state(s) precedes the onset of the fibrillation process. The native beta-barrel structure of nFGF-1 appears to be disrupted in the partially structured intermediate state(s). The protein in the partially structured intermediate state(s) is found to be "sticky" with a solvent-exposed non-polar surface(s). Amyloid fibril formation appears to occur due to coalescence of the protein in the partially structured intermediate state(s) through solvent-exposed non-polar surfaces and intermolecular beta-sheet formation among the extended, linear beta-strands in the protein.     

Aqueous gel formation of a synthetic peptide derived from the beta-sheet domain of platelet factor-4

We observed gelation of a 23-residue peptide derived from the beta-sheet domain of platelet factor-4 (PF4(24)(-)(46)). The gels were primarily heterogeneous mixtures of 50-200 microm spherical aggregates in a less-dense gel matrix. Infrared and circular dichroism spectroscopies showed gelation involving the conversion of PF4(24)(-)(46) from random coil to beta-sheet. We used aggregation-induced NMR resonance broadening to show that temperature, pH, and ionic strength influenced PF4(24)(-)(46) gelation rates. Under identical solution conditions, gel formation took days at T /= 50 degrees C. Gelation was most rapid at pH values near the pK(a) of the central His35 residue. Increases in solution ionic strength reduced the critical gelation concentration of PF4(24)(-)(46). Our results suggest that PF4(24)(-)(46) gels by a process combining aspects of both heat-set and beta-fibril gelation mechanisms.     

Kinetic partitioning between aggregation and vesicle permeabilization by modified ADan

The neurodegenerative illness Familial Danish Dementia (FDD) is linked to formation and aggregation of the 34-residue ADan peptide, whose cytotoxicity may be mediated by membrane interactions. Here we characterize the derived peptide SerADan, in which the two cysteines found in ADan have been changed to serines to emulate the reduced peptide. SerADan aggregates rapidly at pH 5.0 and 7.5 in a series of conformational transitions to form beta-sheet rich fibril-like structures, which nevertheless do not bind amyloid-specific dyes, probably due to the absence of organized beta-sheet contacts. Aggregation is prevented at neutral/acidic pH and low ionic strength by anionic lipid vesicles. These vesicles are permeabilized by monomeric SerADan assembling on the membrane to form stable beta-sheet structures which are different from the solution aggregates. In contrast, solution ageing of SerADan first reduces and then abolishes permeabilization properties. The competition between lipid binding and aggregation may reflect bifurcating pathways for the ADan peptide in vivo between accumulation of inert aggregates and formation of cytotoxic permeabilizing species. Our work demonstrates that non-fibrillar aggregates can assemble in a series of steps to form a hierarchy of higher-order assemblies, where rapid formation of stable local beta-sheet structure may prevent rearrangement to amyloid proper.     

Conformational polymorphism of the amyloidogenic peptide homologous to residues 113-127 of the prion protein

Conformational transitions are thought to be the prime mechanism of amyloid formation in prion diseases. The prion proteins are known to exhibit polymorphic behavior that explains their ability of "conformation switching" facilitated by structured "seeds" consisting of transformed proteins. Oligopeptides containing prion sequences showing the polymorphism are not known even though amyloid formation is observed in these fragments. In this work, we have observed polymorphism in a 15-residue peptide PrP (113-127) that is known to form amyloid fibrils on aging. To see the polymorphic behavior of this peptide in different solvent environments, circular dichroism (CD) spectroscopic studies on an aqueous solution of PrP (113-127) in different trifluoroethanol (TFE) concentrations were carried out. The results show that PrP (113-127) have sheet preference in lower TFE concentration whereas it has more helical conformation in higher TFE content (>40%). The structural transitions involved in TFE solvent were studied using interval-scan CD and FT-IR studies. It is interesting to note that the alpha-helical structure persists throughout the structural transition process involved in amyloid fibril formation implicating the involvement of both N- and C-terminal sequences. To unravel the role of the N-terminal region in the polymorphism of the PrP (113-127), CD studies on another synthetic peptide, PrP (113-120) were carried out. PrP(113-120) exhibits random coil conformation in 100% water and helical conformation in 100% TFE, indicating the importance of full-length sequence for beta-sheet formation. Besides, the influence of different chemico-physical conditions such as concentration, pH, ionic strength, and membrane like environment on the secondary structure of the peptide PrP (113-127) has been investigated. At higher concentration, PrP (113-127) shows features of sheet conformation even in 100% TFE suggesting aggregation. In the presence of 5% solution of sodium dodecyl sulfate, PrP (113-127) takes high alpha-helical propensity. The environment-dependent conformational polymorphism of PrP (113-127) and its marked tendency to form stable beta-sheet structure at acidic pH could account for its conformation switching behavior from alpha-helix to beta-sheet. This work emphasizes the coordinative involvement of N-terminal and C-terminal sequences in the self-assembly of PrP (113-127).     

Circular dichroism studies of the mitochondrial channel, VDAC, from Neurospora crassa.

The protein that forms the voltage-gated channel VDAC (or mitochondrial porin) has been purified from Neurospora crassa. At room temperature and pH 7, the circular dichoism (CD) spectrum of VDAC suspended in octyl beta-glucoside is similar to those of bacterial porins, consistent with a high beta-sheet content. When VDAC is reconstituted into phospholipid liposomes at pH 7, a similar CD spectrum is obtained and the liposomes are rendered permeable to sucrose. Heating VDAC in octyl beta-glucoside or in liposomes results in thermal denaturation. The CD spectrum irreversibly changes to one consistent with total loss of beta-sheet content, and VDAC-containing liposomes irreversibly lose sucrose permeability. When VDAC is suspended at room temperature in octyl beta-glucoside at pH < 5 or in sodium dodecyl sulfate at pH 7, its CD spectrum is consistent with partial loss of beta-sheet content. The sucrose permeability of VDAC-containing liposomes is decreased at low pH and restored at pH 7. Similarly, the pH-dependent changes in the CD spectrum of VDAC suspended in octyl beta-glucoside also are reversible. These results suggest that VDAC undergoes a reversible conformational change at low pH involving reduced beta-sheet content and loss of pore-forming activity.     

Membrane interactions and the effect of metal ions of the amyloidogenic fragment Abeta(25-35) in comparison to Abeta(1-42)

Abeta(1-42) peptide, found as aggregated species in Alzheimer's disease brain, is linked to the onset of Alzheimer's disease. Many reports have linked metals to inducing Abeta aggregation and amyloid plaque formation. Abeta(25-35), a fragment from the C-terminal end of Abeta(1-42), lacks the metal coordinating sites found in the full-length peptide and is neurotoxic to cortical cortex cell cultures. We report solid-state NMR studies of Abeta(25-35) in model lipid membrane systems of anionic phospholipids and cholesterol, and compare structural changes to those of Abeta(1-42). When added after vesicle formation, Abeta(25-35) was found to interact with the lipid headgroups and slightly perturb the lipid acyl-chain region; when Abeta(25-35) was included during vesicle formation, it inserted deeper into the bilayer. While Abeta(25-35) retained the same beta-sheet structure irrespective of the mode of addition, the longer Abeta(1-42) appeared to have an increase in beta-sheet structure at the C-terminus when added to phospholipid liposomes after vesicle formation. Since the Abeta(25-35) fragment is also neurotoxic, the full-length peptide may have more than one pathway for toxicity.     

Solubilization of V-ATPase transmembrane peptides by amphipol A8-35.

Two transmembrane peptides encompassing the seventh transmembrane section of subunit a from V-ATPase from Saccharomyces cerevisiae were studied as complexes with APols A8-35 by CD and fluorescence spectroscopy, with the goal to use APols to provide a membrane-mimicking environment for the peptides. CD spectroscopy was used to obtain the overall secondary structure of the peptides, whereas fluorescence spectroscopy provided information about the local environment of their tryptophan residues. The fluorescence results indicate that both peptides are trapped by APols and the CD results that they adopt a beta-sheet conformation. This result is in contrast with previous work that showed that the same peptides are alpha-helical in SDS micelles and organic solvents. These observations are discussed in the context of APol physical-chemical properties and transmembrane peptide structural propensity.     

Interaction of cationic antimicrobial peptides with model membranes

A series of natural and synthetic cationic antimicrobial peptides from various structural classes, including alpha-helical, beta-sheet, extended, and cyclic, were examined for their ability to interact with model membranes, assessing penetration of phospholipid monolayers and induction of lipid flip-flop, membrane leakiness, and peptide translocation across the bilayer of large unilamellar liposomes, at a range of peptide/lipid ratios. All peptides were able to penetrate into monolayers made with negatively charged phospholipids, but only two interacted weakly with neutral lipids. Peptide-mediated lipid flip-flop generally occurred at peptide concentrations that were 3- to 5-fold lower than those causing leakage of calcein across the membrane, regardless of peptide structure. With the exception of two alpha-helical peptides V681(n) and V25(p,) the extent of peptide-induced calcein release from large unilamellar liposomes was generally low at peptide/lipid molar ratios below 1:50. Peptide translocation across bilayers was found to be higher for the beta-sheet peptide polyphemusin, intermediate for alpha-helical peptides, and low for extended peptides. Overall, whereas all studied cationic antimicrobial peptides interacted with membranes, they were quite heterogeneous in their impact on these membranes.     

Conformational study of fragments of envelope proteins (gp120: 254-274 and gp41: 519-541) of HIV-1 by NMR and MD simulations.

The envelope proteins, gp 120 and gp41 of HIV-1, play a crucial role in receptor (CD4+ lymphocytes) binding and membrane fusion. The fragment 254-274 of gp120 is conserved in all strains of HIV and, as a part of the full gp120 protein, behaves as 'immunosilent', but as an individual fragment it is 'immunoreactive'. When this fragment binds to its receptor, it activates the fusion domain of gp41 allowing viral entry into the host CD4+ cells. The conformation of fragment 254-274 of the gp120 domain and fragment 519-541 of the gp41 domain was studied by NMR and MD simulations. The studies were carried out in three varied media--water, DMSO-d6 and hexafluoroacetone (HFA). The fusogenic nature of the gp41 domain peptide was investigated by 31P NMR experiments with model bilayers prepared from dimyristoyl-L-alpha-phosphatidylcholine (DMPC). The solvent was seen to exert a major effect on the structure of the two peptides. Fragment (254-274) of gp120 in DMSO-d6 had a type I beta-turn around the tetrad Val9-Ser10-Thr11-Gln12 while in HFA a helical structure spanning the region Ile5 to Gln12 was seen with the remaining part of the peptide in a random coil structure. It is possible that the beta-turn may constitute an initiation site for the formation of the helix. In water at pH 4.5, the peptide adopted a beta-sheet. The NMR results for fragment 519-541 of gp41 are conclusive of a beta-sheet structure in DMSO-d6, a conformation which may help in insertion into the membrane, a notion also put forward by others. The 31P NMR studies of DMPC vesicles with this fragment show its fusogenic nature, promoting fusion of unilamellar vesicles to larger agglomerates like multilamellar ones.     

Spontaneous beta-barrel formation: an all-atom Monte Carlo study of Abeta16-22 oligomerization

Using all-atom Monte Carlo simulations with implicit water, combined with a cluster size analysis, we study the aggregation of Abeta(16) (-22), a peptide capable of forming amyloid fibrils. We consider a system of six initially randomly oriented Abeta(16) (-22) peptides, and investigate the thermodynamics and structural properties of aggregates formed by this system. The system is unaggregated without ordered secondary structure at high temperature, and forms beta-sheet rich aggregates at low temperature. At the crossover between these two regimes, we find that clusters of all sizes occur, whereas the beta-strand content is low. In one of several runs, we observe the spontaneous formation of a beta-barrel with six antiparallel strands. The beta-barrel stands out as the by far most long-lived aggregate seen in our simulations.     

Alzheimer's Disease: NMR Studies of Asialo (GM1) and Trisialo (GT1b) Ganglioside Interactions with Aβ(1-40) Peptide in a Membrane Mimic Environment

Amyloid peptide (Abeta) is the major protein constituent of neuritic plaques in Alzheimer's disease (AD). This peptide is an amphipathic molecule that perturbs membranes and binds to raft-like membranes composed of gangliosides. Ganglioside GM1 binds tightly with Abeta and it is speculated that GM1 inhibits Abeta from undergoing alpha-helix to beta-sheet conformational changes. Although the role of gangliosides in conformational changes of Abeta have been studied, the specific nature of these interactions have not been reported. In the present report multidimensional NMR studies of ganglioside-Abeta interactions were conducted in sodium dodecyl sulphate (SDS) micelles, a membrane-mimicking environment. These studies reveal that asialoGM1 binds specifically with Abeta in a manner which could prevent beta-sheet formation. but that ganglioside GT1b does not bind Abeta. Plausible pathways for the involvement of gangliosides in amyloidogenesis are discussed.