Secondary structure conversions of Alzheimer's Abeta(1-40) peptide induced by membrane-mimicking detergents

The amyloid beta peptide (Abeta) with 39-42 residues is the major component of amyloid plaques found in brains of Alzheimer's disease patients, and soluble oligomeric peptide aggregates mediate toxic effects on neurons. The Abeta aggregation involves a conformational change of the peptide structure to beta-sheet. In the present study, we report on the effect of detergents on the structure transitions of Abeta, to mimic the effects that biomembranes may have. In vitro, monomeric Abeta(1-40) in a dilute aqueous solution is weakly structured. By gradually adding small amounts of sodium dodecyl sulfate (SDS) or lithium dodecyl sulfate to a dilute aqueous solution, Abeta(1-40) is converted to beta-sheet, as observed by CD at 3 degrees C and 20 degrees C. The transition is mainly a two-state process, as revealed by approximately isodichroic points in the titrations. Abeta(1-40) loses almost all NMR signals at dodecyl sulfate concentrations giving rise to the optimal beta-sheet content (approximate detergent/peptide ratio = 20). Under these conditions, thioflavin T fluorescence measurements indicate a maximum of aggregated amyloid-like structures. The loss of NMR signals suggests that these are also involved in intermediate chemical exchange. Transverse relaxation optimized spectroscopy NMR spectra indicate that the C-terminal residues are more dynamic than the others. By further addition of SDS or lithium dodecyl sulfate reaching concentrations close to the critical micellar concentration, CD, NMR and FTIR spectra show that the peptide rearranges to form a micelle-bound structure with alpha-helical segments, similar to the secondary structures formed when a high concentration of detergent is added directly to the peptide solution.     

Kinetics of adsorption of beta-amyloid peptide Abeta(1-40) to lipid bilayers

The Alzheimer's disease-related peptide beta-amyloid (Abeta) is toxic to neurons. The toxicity of the peptide appears to require conversion of the monomeric form to an aggregated fibrillar species. The interaction of Abeta with cell membranes has attracted interest as one plausible mechanism by which the peptide exerts its toxic activity. We developed two methods to measure the adsorption of fresh (monomeric) and aged (aggregated) Abeta to lipid bilayers. In one method, the kinetics of Abeta adsorption and desorption to liposomes deposited onto a dextran-coated surface was measured using surface plasmon resonance. In the other method, Abeta was contacted with liposome-coated magnetic beads; adsorbed Abeta was separated from solution-phase peptide by use of a magnetic field. Monomeric Abeta adsorbed quickly but reversibly to lipid bilayers with low affinity, while aggregated Abeta adsorbed slowly but irreversibly. These two methods provide complementary means of quantifying the adsorption of aggregating proteins to membranes. The results correlate strongly with previous observations that fibrillar, but not monomeric, Abeta restricts the motion of acyl tails in phospholipid bilayers. The methods should be useful for further elucidation of the role of membrane adsorption in mediating Abeta toxicity, and in the search for inhibitors of toxicity.     

Time-resolved infrared spectroscopy of pH-induced aggregation of the Alzheimer Abeta(1-28) peptide

Aggregation of the Alzheimer's disease-related Aβ_1-28 peptide was induced by a rapid, sub-millisecond pH jump and monitored by time-resolved infrared spectroscopy on the millisecond to second time-scale. The release of protons was induced by the photolysis of a caged compound, 1-(2-nitrophenyl)ethyl sulfate (NPE-sulfate). The pH jump generated in our experimental setup is used to model the Aβ peptide structural conversions that may occur in the acidic endosomal/lysosomal cell compartment system. The aggregation of the Aβ_1-28 peptide induced by the pH jump from 8.5 to < 6 yields an antiparallel β-sheet structure. The kinetics of the structural transition is biphasic, showing an initial rapid phase with a transition from random coil to an oligomeric β-sheet form with a time constant of 3.6 s. This phase is followed by a second slower transition, which yields larger aggregates during 48.0 s.     

A left-handed 3(1) helical conformation in the Alzheimer Abeta(12-28) peptide

We show for the first time that the secondary structure of the Alzheimer beta-peptide is in a temperature-dependent equilibrium between an extended left-handed 3(1) helix and a flexible random coil conformation. Circular dichroism spectra, recorded at 0.03 mM peptide concentration, show that the equilibrium is shifted towards increasing left-handed 3(1) helix structure towards lower temperatures. High resolution nuclear magnetic resonance (NMR) spectroscopy has been used to study the Alzheimer peptide fragment Abeta(12-28) in aqueous solution at 0 degrees C and higher temperatures. NMR translation diffusion measurements show that the observed peptide is in monomeric form. The chemical shift dispersion of the amide protons increases towards lower temperatures, in agreement with the increased population of a well-ordered secondary structure. The solvent exchange rates of the amide protons at 0 degrees C and pH 4.5 vary within at least two orders of magnitude. The lowest exchange rates (0.03-0.04 min(-1)) imply that the corresponding amide protons may be involved in hydrogen bonding with neighboring side chains.     

Zinc binding to Alzheimer's Abeta(1-16) peptide results in stable soluble complex

Aggregation of the human amyloid beta-peptide (Abeta) into insoluble plaques is a key event in Alzheimer's disease. Zinc sharply accelerates the Abeta aggregation in vitro, and the Abeta region 6-28 was suggested to be the obligatory zinc binding site. However, time-dependent aggregation of the zinc-bound Abeta species investigated so far prevented their structural analysis. By using CD spectroscopy, we have shown here for the first time that (i) the protected synthetic peptide spanning the fragment 1-16 of Abeta binds specifically zinc with 1:1 and 1:2 stoichiometry under physiologically relevant conditions; (ii) the peptide-zinc complex is soluble and stable for several months; (iii) zinc binding causes a conformational change of the peptide towards a more structured state. These findings suggest the region 1-16 to be the minimal autonomous zinc binding domain of Abeta.     

Cu（Ⅱ） Potentiation of Alzheimer Aβ1-40 Cytotoxicity and Transition on its Secondary Structure

Mounting evidence has shown that dyshomeostasis of the redox-active biometals such as Cuand Fe can lead to oxidative stress,which plays a key role in the neuropathology of Alzheimer's disease(AD).Here we demonstrate that with the formation of Cu(Ⅱ)·Aβ1-40 complexes,copper markedly potentiatesthe neurotoxicity exhibited by β-amyloid peptide (Aβ).A greater amount of hydrogen peroxide was releasedwhen Cu(Ⅱ)·Aβ1-40 complexes was added to the xanthine oxidase/xanthine system detected by potassiumiodide spectrophotometry.Copper bound to Aβ1-40 was observed by electron paramagnetic resonance(EPR) spectroscopy.Circular dichroism (CD) studies indicated that copper chelation could cause a structuraltransition of Aβ.The addition of copper to Aβ introduced an increase on β-sheet as well as α-helix,whichmay be responsible for the aggregation of Aβ.We hypothesized that Aβ aggregation induced by copper maybe responsible for local injury in AD.The interaction between Cu~(2 ) and Aβ also provides a possible mechanismfor the enrichment of metal ions in amyloid plaques in the AD brain.     

Mechanism of membrane depolarization caused by the Alzheimer Abeta1-42 peptide

We report a novel observation that the neurotoxic Alzheimer peptide Abeta1-42, when pre-incubated, causes a dramatic and lasting membrane depolarization in differentiated human hNT neuronal cells and in rodent PC12 cells in a concentration-dependent manner. This phenomenon involves activation of the metabotropic glutamate receptor, mGluR(1). Abeta-induced membrane depolarization in PC12 cells is sensitive to mGluR(1) antagonists and to pertussis and cholera toxins, indicating the involvement of particular G-proteins. The effect is different from the known ability of aggregated Abeta1-42 to cause a calcium influx. Since mGluR(1) agonists mimic the Abeta effect, we deduce that in this cell system glutamate can control the membrane potential and thereby the excitability of its target neurons. We propose that Abeta-induced membrane depolarization described here leads in Alzheimer's disease to hyperexcitability of affected neurons and is a crucially important molecular mechanism for beta-amyloid toxicity and cognitive dysfunction in the disease.     

NMR and CD studies on the interaction of Alzheimer beta-amyloid peptide (12-28) with beta-cyclodextrin

Polymerization of the amyloid beta-peptide (Abeta) has been identified as a major feature of the pathogenesis of Alzheimer's disease (AD). Inhibition of the formation of these toxic polymers of Abeta has emerged as an approach for developing therapeutics for AD. NMR and CD spectra were used to investigate the interaction between cyclodextrin and Abeta(12-28) peptide, which was reported to be an important region for forming amyloid fibrils. CD spectral analyses show that of the alpha-, beta- and gamma-cyclodextrins only beta-cyclodextrin inhibits the aggregation of Abeta(12-28) at pH 5.0. Analysis of the one-dimensional proton NMR spectra of Abeta(12-28) and the mixture of Abeta(12-28) with beta-cyclodextrin clearly indicates that there are chemical shift changes in the aromatic ring of Phe19 and the methyl groups of Val18 in the peptide. The NOESY spectra show cross-peaks between H-3 and H-5 of beta-cyclodextrin and the aromatic protons of Phe19 and Phe20. These chemical shift differences and NOEs demonstrate that there is an interaction between Abeta(12-28) and beta-cyclodextrin. Analysis of the cross-peak intensity in the NOESY spectra reveals that the aromatic rings of Phe19 and 20 are generally inserted into beta-cyclodextrin at the broad side and are oriented toward the narrow side of the cavity.     

Amyloid beta-protein (Abeta)1-40 protects neurons from damage induced by Abeta1-42 in culture and in rat brain

Previously, we found that amyloid beta-protein (Abeta)1-42 exhibits neurotoxicity, while Abeta1-40 serves as an antioxidant molecule by quenching metal ions and inhibiting metal-mediated oxygen radical generation. Here, we show another neuroprotective action of nonamyloidogenic Abeta1-40 against Abeta1-42-induced neurotoxicity in culture and in vivo. Neuronal death was induced by Abeta1-42 at concentrations higher than 2 microm, which was prevented by concurrent treatment with Abeta1-40 in a dose-dependent manner. However, metal chelators did not prevent Abeta1-42-induced neuronal death. Circular dichroism spectroscopy showed that Abeta1-40 inhibited the beta-sheet transformation of Abeta1-42. Thioflavin-T assay and electron microscopy analysis revealed that Abeta1-40 inhibited the fibril formation of Abeta1-42. In contrast, Abeta1-16, Abeta25-35, and Abeta40-1 did not inhibit the fibril formation of Abeta1-42 nor prevent Abeta1-42-induced neuronal death. Abeta1-42 injection into the rat entorhinal cortex (EC) caused the hyperphosphorylation of tau on both sides of EC and hippocampus and increased the number of glial fibrillary acidic protein (GFAP)-positive astrocytes in the ipsilateral EC, which were prevented by the concurrent injection of Abeta1-40. These results indicate that Abeta1-40 protects neurons from Abeta1-42-induced neuronal damage in vitro and in vivo, not by sequestrating metals, but by inhibiting the beta-sheet transformation and fibril formation of Abeta1-42. Our data suggest a mechanism by which elevated Abeta1-42/Abeta1-40 ratio accelerates the development of Alzheimer's disease (AD) in familial AD.     

Determining the critical nucleus and mechanism of fibril elongation of the Alzheimer's Abeta(1-40) peptide

We use a coarse-grained protein model to characterize the critical nucleus, structural stability, and fibril elongation propensity of Aβ_1-40 oligomers for the C_2x and C_2z quaternary forms proposed by solid-state NMR. By estimating equilibrium populations of structurally stable and unstable protofibrils, we determine the shift in the dominant population from free monomer to ordered fibril at a critical nucleus of ten chains for the C_2x and C_2z forms. We find that a minimum assembly of 16 monomer chains is necessary to mimic a mature fibril, and show that its structural stability correlates with a plateau in the hydrophobic residue density and a decrease in the likelihood of losing hydrophobic interactions by rotating the fibril subunits. While Aβ_1-40 protofibrils show similar structural stability for both C_2x and C_2z quaternary structures, we find that the fibril elongation propensity is greater for the C_2z form relative to the C_2x form. We attribute the increased propensity for elongation of the C_2z form as being due to a stagger in the interdigitation of the N-terminal and C-terminal β-strands, resulting in structural asymmetry in the presented fibril ends that decreases the amount of incorrect addition to the N terminus on one end. We show that because different combinations of stagger and quaternary structure affect the structural symmetry of the fibril end, we propose that differences in quaternary structures will affect directional growth patterns and possibly different morphologies in the mature fiber.     

Eliminating membrane depolarization caused by the Alzheimer peptide Abeta(1-42, aggr.)

A high-throughput screen found compounds that eliminate the dramatic membrane depolarization caused by the aggregated Alzheimer Abeta1-42 peptide, which activates mGluR1 receptors. The library was composed of known biologically active compounds; the cell-based assay measured the changes of membrane potential with a slow-acting voltage-sensitive dye. We found 10 potentially useful compounds, some of which reduce the Abeta-induced membrane depolarization up to 96%. Interestingly, the active compounds include specific tyrosine kinase inhibitors and inhibitors of certain chloride channels. We deduce that mGluR1 receptors, activated by Abeta1-42 or otherwise, can control the membrane potential via downstream activation of certain tyrosine kinases and certain ion channels. Dopaminergic and serotonergic agonists that emerged from the screen presumably compensate for the Abeta-induced membrane depolarization by themselves causing a hyperpolarization. The hit compounds, whose pharmacokinetics are known, show promise for the restoration of cognitive function in the treatment of early and mid-stage Alzheimer's disease.     

Abeta(25-35) and Abeta(1-40) act on different calcium channels in CA1 hippocampal neurons

The acute effects of beta-amyloid (25-35) and (1-40) on high voltage activated calcium channels were compared in CA1 pyramidal cells of adult mouse hippocampal slices using the whole-cell patch-clamp recording. Bath application of oligomeric beta-amyloid (25-35) reversibly increased the barium current (I(Ba)) to 1.61 (normalized amplitude), while oligomeric beta-amyloid (1-40) reversibly enhanced the I(Ba) to 1.74. Reverse-sequence beta-amyloid [(35-25) and (40-1)] had no effect. The effect of beta-amyloid (25-35) was blocked by nifedipine, a selective antagonist of L-type calcium channels. In contrast, the effect of beta-amyloid (1-40) was not blocked by nifedipine and I(Ba) was enhanced to 4.96. It is concluded that these oligomeric peptides may act through different types of calcium channels and/or receptors. The toxicity of Abeta(25-35) implicates a potentiation of L-type calcium channels while the one of Abeta(1-40) is related to an increase of non-L-type calcium channels, which may involve an increase in transmitter release.     

Formation of toxic Abeta(1-40) fibrils on GM1 ganglioside-containing membranes mimicking lipid rafts: polymorphisms in Abeta(1-40) fibrils

The abnormal aggregation and deposition of amyloid β protein (Aβ) on neuronal cells are critical to the onset of Alzheimer's disease. The entity (oligomers or fibrils) of toxic Aβ species responsible for the pathogenesis of the disease has been controversial. We have reported that the Aβ aggregates on ganglioside-rich domains of neuronal PC12 cells as well as in raft-like model membranes. Here, we identified toxic Aβ(1-40) aggregates formed with GM1-ganglioside-containing membranes. Aβ(1-40) was incubated with raft-like liposomes composed of GM1/cholesterol/sphingomyelin at 1:2:2 and 37 °C. After a lag period, toxic amyloid fibrils with a width of 12 nm were formed and subsequently laterally assembled with slight changes in their secondary structure as confirmed by viability assay, thioflavin-T fluorescence, circular dichroism, and transmission electron microscopy. In striking contrast, Aβ fibrils formed without membranes were thinner (6.7 nm) and much less toxic because of weaker binding to cell membranes and a smaller surface hydrophobicity. This study suggests that toxic Aβ(1-40) species formed on membranes are not soluble oligomers but amyloid fibrils and that Aβ(1-40) fibrils exhibit polymorphisms.     

Characterizations of distinct amyloidogenic conformations of the Abeta (1-40) and (1-42) peptides

Major constituents of the amyloid plaques found in the brain of Alzheimer's patients are the 39-43 residue beta-amyloid (Abeta) peptides. Extensive in vitro as well as in vivo biochemical studies have shown that the 40- and 42-residue Abeta peptides play major roles in the neurodegenerative pathology of Alzheimer's disease. Although the two Abeta peptides share common aggregation properties, the 42-residue peptide is more amyloidogenic and more strongly associated with amyloid pathology. Thus, characterizations of the two Abeta peptides are of critical importance in understanding the molecular mechanism of Abeta amyloid formation. In this report, we present combined CD and NMR studies of the monomeric states of the two peptides under both non-amyloidogenic (<5 degrees C) and amyloid-forming conditions (>5 degrees C) at physiological pH. Our CD studies of the Abeta peptides showed that initially unfolded Abeta peptides at low temperature (<5 degrees C) gradually underwent conformational changes to more beta-sheet-like monomeric intermediate states at stronger amyloidogenic conditions (higher temperatures). Detailed residue-specific information on the structural transition was obtained by using NMR spectroscopy. Residues in the N-terminal (3-12) and 20-22 regions underwent conformational changes to more extended structures at the stronger amyloidogenic conditions. Almost identical structural transitions of those residues were observed in the two Abeta peptides, suggesting a similar amyloidogenic intermediate for the two peptides. The 42-residue Abeta (1-42) peptide was, however, more significantly structured at the C-terminal region (39-42), which may lead to the different aggregation propensity of the two peptides.     

白凤丸对Aβ1-40和C31导致PC12细胞损伤的保护作用

目的:探讨Aβ1-40和C31对体外培养的PC12细胞的作用,同时研究了白凤丸有效成份BFP对其作用的影响.方法:采用四甲基偶氮唑盐(MTT)检测方法,在培养的PC12细胞观察应用Aβ1-40和C31前后对细胞在570 m的吸收值的影响,以及给予BFP和雌二醇共同孵育后吸收值的改变.结果:Aβ1-40和C31可使细胞在570 nm的吸收值显著降低,而应用BFP和雌激素后,能有效地提高细胞在570m的吸收值.结论:Aβ1-40和C31对PC12细胞具有毒性作用,而BFP能显著拮抗这种作用,与雌激素的作用类似,具有一定的神经保护作用.     

Beta-amyloid (Abeta40, Abeta42) binding to modified LDL accelerates macrophage foam cell formation

Apart from its role as a risk factor in arteriosclerosis, plasma cholesterol is increasingly recognized to play a major role in the pathogenesis of Alzheimer's disease (AD). Moreover, alterations of intracellular cholesterol metabolism in neuronal and vascular cells are of considerable importance for the understanding of AD. Cellular cholesterol accumulation enhances the deposition of insoluble beta-amyloid peptides, which is considered a hallmark in the pathogenesis of AD. In order to test the hypothesis, whether exogenous beta-amyloid peptides (Abeta42, Abeta40) might contribute to cellular cholesterol accumulation by opsonization of lipoproteins, we compared the binding and uptake of native LDL, enzymatically modified LDL (E-LDL), copper oxidized LDL (Ox-LDL) and HDL as control, preincubated either in the absence or presence of Abeta42 or Abeta40, by human monocytes or monocyte-derived macrophages. Incubation of monocytes and macrophages with Abeta-lipoprotein-complexes lead to increased cellular free and esterified cholesterol when compared to non-opsonized lipoproteins, except for HDL. Furthermore, the cellular uptake of these complexes regulated Abeta-receptors such as FPRL-1 or LRP/CD91. In summary, our results suggest that Abeta42 and Abeta40 act as potent opsonins for LDL, E-LDL and Ox-LDL and enhance cellular cholesterol accumulation as well as Abeta-deposition in vessel wall macrophages.     

Investigations of the molecular mechanism of metal-induced Abeta (1-40) amyloidogenesis

Transition-metal ions (Cu2+ and Zn2+) play critical roles in the Abeta plaque formation. However, precise roles of the metal ions in the Abeta amyloidogenesis have been controversial. In this study, the molecular mechanism of the metal-induced Abeta oligomerization was investigated with extensive metal ion titration NMR experiments. Upon additions of the metal ions, the N-terminal region (1-16) of the Abeta (1-40) peptide was selectively perturbed. In particular, polar residues 4-8 and 13-15 were more strongly affected by the metal ions, suggesting that those regions may be the major binding sites of the metal ions. The NMR signal changes of the N-terminal region were dependent on the peptide concentrations (higher peptide concentrations resulted in stronger signal changes), suggesting that the metal ions facilitate the intermolecular contact between the Abeta peptides. The Abeta (1-40) peptides (>30 microM) were eventually oligomerized even at low temperature (3 degrees C), where the Abeta peptides are stable as monomeric forms without the metal ions. The real-time oligomerization process was monitored by 1H/15N HSQC NMR experiments, which provided the first residue-specific structural transition information. Hydrophobic residues 12-21 initially underwent conformational changes due to the intermolecular interactions. After the initial structural rearrangements, the C-terminal residues (32-40) readjusted their conformations presumably for effective oligomerization. Similar structural changes of the metal-free Abeta (1-40) peptides were also observed in the presence of the preformed oligomers, suggesting that the conformational transitions may be the general molecular mechanism of the Abeta (1-40) amyloidogenesis.     

The amyloid beta peptide (Abeta(1-40)) is thermodynamically soluble at physiological concentrations

Precipitation of the 39-43-residue amyloid beta peptide (Abeta) is a crucial factor in Alzheimer's disease (AD). In normal as well as in AD-afflicted brain, the Abeta concentration is estimated to be a few nanomolar. Here we show that Abeta(1-40) precipitates in vitro only if the dissolved concentration is >14 microM. Using fluorescence correlation spectroscopy, we further show that the precipitation is complete in 1 day, after which the size distribution of Abeta monomer/oligomers in the solution phase becomes stationary in time and independent of the starting Abeta concentration. Mass spectra confirm that both the solution phase and the coexisting precipitate contain chemically identical Abeta molecules. Incubation at 68 degrees C for 1 h reduces the solubility by <12%. Together, these results show that the thermodynamic saturation concentration (C(sat)) of Abeta(1-40) in phosphate-buffered saline (PBS) at pH 7.4 has a well-defined lower limit of 15.5 +/- 1 microM. Divalent metal ions (believed to play a role in AD) at near-saturation concentrations in PBS reduce C(sat) only marginally (2 mM Mg(2+) by 6%, 2.5 microM Ca(2+) by 7%, and 4 microM Zn(2+) by 11%). Given that no precipitation is possible at concentrations below C(sat), we infer that coprecipitant(s), and not properties of Abeta(1-40) alone, are key factors in the in vivo aggregation of Abeta.     

Plasma beta carotene in Alzheimer's disease. Association with cerebrospinal fluid beta-amyloid 1-40, (Abeta40), beta-amyloid 1-42 (Abeta42) and total Tau

We studied the plasma beta carotene concentrations in 40 Alzheimer's disease patients and the association with cerebrospinal fluid beta-amyloid 1-40, (Abeta40), cerebrospinal fluid beta-amyloid 1-42 (Abeta42) and cerebrospinal fluid total Tau. We found that patients with plasma beta carotene levels below the 25th percentile had 55% reduced ratios of Abeta40/Tau and 51% reduced ratios of Abeta 40/Abeta 42 compared with patients in the highest quartile. Mean Tau concentrations in the lowest quartile of plasma beta-carotene levels were 74% higher compared with the highest quartile of plasma beta-carotene levels. Thus, we could demonstrate an statistically significant association between beta carotene levels in plasma and neurochemical markers in the cerebrospinal fluid of Alzheimer's disease patients.     

Effects of sphingomyelin, cholesterol and zinc ions on the binding, insertion and aggregation of the amyloid Abeta(1-40) peptide in solid-supported lipid bilayers

We utilized plasmon-waveguide resonance (PWR) spectroscopy to follow the effects of sphingomyelin, cholesterol and zinc ions on the binding and aggregation of the amyloid beta peptide(1-40) in lipid bilayers. With a dioleoylphosphatidylcholine (DOPC) bilayer, peptide binding was observed, but no aggregation occurred over a period of 15 h. In contrast, similar binding was found with a brain sphingomyelin (SM) bilayer, but in this case an exponential aggregation process was observed during the same time interval. When the SM bilayer included 35% cholesterol, an increase of approximately 2.5-fold occurred in the amount of peptide bound, with a similar increase in the extent of aggregation, the latter resulting in decreases in the bilayer packing density and displacement of lipid. Peptide association with a bilayer formed from equimolar amounts of DOPC, SM and cholesterol was followed using a high-resolution PWR sensor that allowed microdomains to be observed. Biphasic binding to both domains occurred, but predominantly to the SM-rich domain, initially to the surface and at higher peptide concentrations within the interior of the bilayer. Again, aggregation was observed and occurred within both microdomains, resulting in lipid displacement. We attribute the aggregation in the DOPC-enriched domain to be a consequence of lipid mixing within these microdomains, resulting in the presence of small amounts of SM and cholesterol in the DOPC microdomain. When 1 mM zinc was present, an increase of approximately threefold in the amount of peptide association was observed, as well as large changes in mass and bilayer structure as a consequence of peptide aggregation, occurring without loss of bilayer integrity. A structural interpretation of peptide interaction with the bilayer is presented based on the results of simulation analysis of the PWR spectra.