Amyloid fibrillation kinetics: insight from atomistic nucleation theory

We consider the nucleation of nanosized amyloid fibrils composed of successively layered β-sheets at the molecular level when this process takes place by direct polymerization of protein segments (β-strands) into β-sheets. Application of the atomistic nucleation theory (ANT) to amyloid nucleation of β(2)-microglobulin and amyloid β(40) allows us to predict the fibril nucleus size and the fibril nucleation rate as functions of the supersaturation of the protein solution. The ANT predictions are compared to recent time-resolved optical experiments where they measure the effect of the protein concentration and mutations on the initial lag time before amyloid fibrils form in the protein solution. The presented analysis reveals the general principles underlying the nucleation kinetics of nanosized amyloid fibrils and indicates that it can be treated in the framework of existing general theories of the nucleation of new phases.     

Effect of agitation on the peptide fibrillization: Alzheimer's amyloid‐β peptide 1‐42 but not amylin and insulin fibrils can grow under quiescent conditions

Many peptides and proteins can form fibrillar aggregates in vitro, but only a limited number of them are forming pathological amyloid structures in vivo. We studied the fibrillization of four peptides – Alzheimer's amyloid‐β (Aβ) 1‐40 and 1‐42, amylin and insulin. In all cases, intensive mechanical agitation of the solution initiated fast fibrillization. However, when the mixing was stopped during the fibril growth phase, the fibrillization of amylin and insulin was practically stopped, and the rate for Aβ₄₀ substantially decreased, whereas the fibrillization of Aβ₄₂ peptide continued to proceed with almost the same rate as in the agitated conditions. The reason for the different sensitivity of the in vitro fibrillization of these peptides towards agitation in the fibril growth phase remains elusive. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

Binding Modes of Phthalocyanines to Amyloid β Peptide and Their Effects on Amyloid Fibril Formation

The inherent tendency of proteins to convert from their native states into amyloid aggregates is associated with a range of human disorders, including Alzheimer’s and Parkinson’s diseases. In that sense, the use of small molecules as probes for the structural and toxic mechanism related to amyloid aggregation has become an active area of research. Compared with other compounds, the structural and molecular basis behind the inhibitory interaction of phthalocyanine tetrasulfonate (PcTS) with proteins such as αS and tau has been well established, contributing to a better understanding of the amyloid aggregation process in these proteins. We present here the structural characterization of the binding of PcTS and its Cu(II) and Zn(II)-loaded forms to the amyloid β-peptide (Aβ) and the impact of these interactions on the peptide amyloid fibril assembly. Elucidation of the PcTS binding modes to Aβ₄₀ revealed the involvement of specific aromatic and hydrophobic interactions in the formation of the Aβ₄₀-PcTS complex, ascribed to a binding mode in which the planarity and hydrophobicity of the aromatic ring system in the phthalocyanine act as main structural determinants for the interaction. Our results demonstrated that formation of the Aβ₄₀-PcTS complex does not interfere with the progression of the peptide toward the formation of amyloid fibrils. On the other hand, conjugation of Zn(II) but not Cu(II) at the center of the PcTS macrocyclic ring modified substantially the binding profile of this phthalocyanine to Aβ₄₀ and became crucial to reverse the effects of metal-free PcTS on the fibril assembly of the peptide. Overall, our results provide a firm basis to understand the structural rules directing phthalocyanine-protein interactions and their implications on the amyloid fibril assembly of the target proteins; in particular, our results contradict the hypothesis that PcTS might have similar mechanisms of action in slowing the formation of a variety of pathological aggregates.     

Experimentally derived structural constraints for amyloid fibrils of wild-type transthyretin

Transthyretin (TTR) is a largely β-sheet serum protein responsible for transporting thyroxine and vitamin A. TTR is found in amyloid deposits of patients with senile systemic amyloidosis. TTR mutants lead to familial amyloidotic polyneuropathy and familial amyloid cardiomyopathy, with an earlier age of onset. Studies of amyloid fibrils of familial amyloidotic polyneuropathy mutant TTR suggest a structure similar to the native state with only a simple opening of a β-strand-loop-strand region exposing the two main β-sheets of the protein for fibril elongation. However, we find that the wild-type TTR sequence forms amyloid fibrils that are considerably different from the previously suggested amyloid structure. Using protease digestion with mass spectrometry, we observe the amyloid core to be primarily composed of the C-terminal region, starting around residue 50. Solid-state NMR measurements prove that TTR differs from other pathological amyloids in not having an in-register parallel β-sheet architecture. We also find that the TTR amyloid is incapable of binding thyroxine as monitored by either isothermal calorimetry or 1,8-anilinonaphthalene sulfonate competition. Taken together, our experiments are consistent with a significantly different configuration of the β-sheets compared to the previously suggested structure.     

Induced β-Barrel Formation of the Alzheimer's Aβ25-35 Oligomers on Carbon Nanotube Surfaces: Implication for Amyloid Fibril Inhibition

Recent experimental studies show that carbon nanotubes impact the aggregation process of proteins associated with neurodegenerative diseases. However, the details of molecular interactions between proteins and carbon nanotubes are still not well understood. In this study, we investigate the initial adsorption features and dynamics of the Alzheimer's amyloid-β peptide spanning residues 25-35 (Aβ25-35) on a single-walled carbon nanotube (SWNT) surface using fully atomic molecular dynamics simulations (MD) in explicit solvent. The initial configurations of the Aβ25-35 peptides consist of two preformed bilayer β-sheets, each with four or five β-strands in parallel or mixed antiparallel-parallel orientations. Our simulations show, for what we believe is the first time, that two disjointed Aβ25-35 β-sheets with mixed antiparallel-parallel strands can assemble into β-barrels wrapping the SWNT. In contrast, both simulations of Aβ25-35 without SWNT, and simulations of SWNT−Aβ25-35 with purely parallel β-strands, lead to disordered aggregates. We find that Aβ25-35 β-barrel formation involves at least two steps: i), curving of the Aβ25-35 β-sheets as a result of strong hydrophobic interactions with carbon nanotube concomitantly with dehydration of the SWNT-peptide interface; and ii), intersheet backbone hydrogen bond formation with fluctuating intrasheet hydrogen bonds. Detailed analysis of the conversion shows that β-barrel formation on SWNT surface results from the interplay of dehydration and peptide-SWNT/peptide-peptide interactions. Implications of our results on amyloid fibril inhibition are discussed.     

Simulations of cross-amyloid aggregation of amyloid-β and islet amyloid polypeptide fragments

Amyloid-β (Aβ) and islet amyloid polypeptide (IAPP) are small peptides, classified as amyloids, that have the potential to self-assemble and form cytotoxic species, such as small soluble oligomers and large insoluble fibrils. The formation of Aβ aggregates facilitates the progression of Alzheimer’s disease (AD), while IAPP aggregates induce pancreatic β-cell apoptosis, leading to exacerbation of type 2 diabetes (T2D). Cross-amyloid interactions between Aβ and IAPP have been described both in vivo and in vitro, implying the role of Aβ or IAPP as modulators of cytotoxic self-aggregation of each species, and suggesting that Aβ-IAPP interactions are a potential molecular link between AD and T2D. Using molecular dynamics (MD) simulations, “hotspot” regions of the two peptides were studied to understand the formation of hexamers in a heterogeneous and homogeneous peptide-containing environment. Systems of only Aβ_(16–22) peptides formed antiparallel, β-barrel-like structures, while systems of only IAPP_(20–29) peptides formed stacked, parallel β-sheets and had relatively unstable aggregation structures after 2 μs of simulation time. Systems containing both Aβ and IAPP (1:1 ratio) hexamers showed antiparallel, β-barrel-like structures, with an interdigitated arrangement of Aβ_(16–22) and IAPP_(20–29). These β-barrel structures have features of cytotoxic amyloid species identified in previous literature. Ultimately, this work seeks to provide atomistic insight into both the mechanism behind cross-amyloid interactions and structural morphologies of these toxic amyloid species.     

Inhibitory Effect of β-Casein on the Amyloid Fibril Formation of Aβ<Subscript>1–40</Subscript> Associated with Alzheimer’s Disease

Alzheimer’s disease is associated with the fibril formation of β-amyloid peptide in extracellular plaque. β-Casein is a milk protein that has shown a remarkable ability to stabilize proteins by inhibiting their protein aggregation and precipitation. The aim of this study was to test in vitro the ability of β-casein to bind the Aβ_1–40, change the structure and inhibit the formation of amyloid fibrils in Aβ_1–40. Results from the ThT binding assay indicated that incubation of Aβ_1–40 with β-casein retarded amyloid fibril formation of Aβ_1–40 in a concentration dependent manner such that at a ratio of 1:1 (w:w) led to a significant reduction in the amount of fluorescent intensity. The results from transmission electron microscopy (TEM) also showed that β-casein significantly reduced the number and size of the Aβ_1–40 fibrils, suggesting that the chaperone bound to the Aβ_1–40 fibrils and/or interacted with the fibrils in some way. ANS results also showed that β-casein significantly decreased the exposed hydrophobic surface in Aβ_1–40. Following an ANS binding assay, CD spectroscopy results also showed that incubation of Aβ_1–40 resulted in a structural transition to a β-sheet. In the presence of β-casein, however, α-helical conformation was observed which indicated stabilization of the protein. These results reveal the highly efficacious chaperone action of β-casein against amyloid fibril formation of Aβ_1–40. These results suggest that in vitro, β-casein binds to the Aβ_1–40 fibrils, alters the Aβ_1–40 structure and prevents amyloid fibril formation. This approach may result in the identification of a chaperone mechanism for the treatment of neurological diseases.     

Alzheimer's Disease Drug Candidates Stabilize A-β Protein Native Structure by Interacting with the Hydrophobic Core

Deposition of amyloid fibrils, consisting primarily of Aβ₄₀ and Aβ₄₂ peptides, in the extracellular space in the brain is a major characteristic of Alzheimer's disease (AD). We recently developed new (to our knowledge) drug candidates for AD that inhibit the fibril formation of Aβ peptides and eliminate their neurotoxicity. We performed all-atom molecular-dynamics simulations on the Aβ₄₂ monomer at its α-helical conformation and a pentamer fibril fragment of Aβ₄₂ peptide with or without LRL and fluorene series compounds to investigate the mechanism of inhibition. The results show that the active drug candidates, LRL22 (EC₅₀ = 0.734 μM) and K162 (EC₅₀ = 0.080 μM), stabilize hydrophobic core I of Aβ₄₂ peptide (residues 17–21) to its α-helical conformation by interacting specifically in this region. The nonactive drug candidates, LRL27 (EC₅₀ > 10 μM) and K182 (EC₅₀ > 5 μM), have little to no similar effect. This explains the different behavior of the drug candidates in experiments. Of more importance, this phenomenon indicates that hydrophobic core I of the Aβ₄₂ peptide plays a major mechanistic role in the formation of amyloid fibrils, and paves the way for the development of new drugs against AD.     

Intrinsic Determinants of Neurotoxic Aggregate Formation by the Amyloid β Peptide

The extent to which proteins aggregate into distinct structures ranging from prefibrillar oligomers to amyloid fibrils is key to the pathogenesis of many age-related degenerative diseases. We describe here for the Alzheimer's disease-related amyloid β peptide (Aβ) an investigation of the sequence-based determinants of the balance between the formation of prefibrillar aggregates and amyloid fibrils. We show that by introducing single-point mutations, it is possible to convert the normally harmless Aβ₄₀ peptide into a pathogenic species by increasing its relative propensity to form prefibrillar but not fibrillar aggregates, and, conversely, to abolish the pathogenicity of the highly neurotoxic E22G Aβ₄₂ peptide by reducing its relative propensity to form prefibrillar species rather than mature fibrillar ones. This observation can be rationalized by the demonstration that whereas regions of the sequence of high aggregation propensity dominate the overall tendency to aggregate, regions with low intrinsic aggregation propensities exert significant control over the balance of the prefibrillar and fibrillar species formed, and therefore play a major role in determining the neurotoxicity of the Aβ peptide.     

Atomic-Scale Simulations Confirm that Soluble β-Sheet-Rich Peptide Self-Assemblies Provide Amyloid Mimics Presenting Similar Conformational Properties

The peptide self-assembly mimic (PSAM) from the outer surface protein A (OspA) can form highly stable but soluble β-rich self-assembly-like structures similar to those formed by native amyloid-forming peptides. However, unlike amyloids that predominantly form insoluble aggregates, PSAMs are highly water-soluble. Here, we characterize the conformations of these soluble β-sheet-rich assemblies. We simulate PSAMs with different-sized β-sheets in the presence and absence of end-capping proteins using all-atom explicit-solvent molecular dynamics, comparing the structural stability, conformational dynamics, and association force. Structural and free-energy comparisons among β-sheets with different numbers of layers and sequences indicate that in similarity to amyloids, the intersheet side chain-side chain interactions and hydrogen bonds combined with intrasheet salt bridges are the major driving forces in stabilizing the overall structural organization. A detailed structural analysis shows that in similarity to amyloid fibrils, all wild-type and mutated PSAM structures display twisted and bent β-sheets to some extent, implying that a twisted and bent β-sheet is a general motif of β-rich assemblies. Thus, our studies indicate that soluble β-sheet-rich peptide self-assemblies can provide good amyloid mimics, and as such confirm on the atomic scale that they are excellent systems for amyloid studies. These results provide further insight into the usefulness of such mimics for nanostructure design.     

Structural plasticity in self-assembling transmembrane β-sheets

Here we test the hypothesis that membrane-spanning β-sheets can exhibit structural plasticity in membranes due to their ability to shift hydrogen-bonding patterns. Transmembrane β-sheet forming peptides of the sequence AcWL_n, where n = 5, 6, or 7, which range from 21 to 27 Å in maximum length, were incorporated into bilayers made of phosphatidylcholine lipids with saturated acyl chains containing 14, 16, or 18 carbons, which are 36–50 Å in thickness. The effect of the peptide β-sheets on fluid- and gel-phase bilayers were studied with differential scanning calorimetry and circular dichroism spectroscopy. We show that AcWL₅ forms a stable, peptide-rich gel phase in all three lipids. The whole family of AcWL_n peptides appears to form similarly stable, nonmembrane-disrupting β-sheets in all bilayer phases and thicknesses. Bilayers containing up to 20 mol % peptide, which is the maximum concentration tested, formed gel phases with melting temperatures that were equal to, or slightly higher than, the pure lipid transitions. Given the range of peptide lengths and bilayer thicknesses tested, these experiments show that the AcWL_n family of membrane-inserted β-sheets exhibit remarkable structural plasticity in membranes.     

Binding of the molecular chaperone αB-crystallin to Aβ amyloid fibrils inhibits fibril elongation

The molecular chaperone αB-crystallin is a small heat-shock protein that is upregulated in response to a multitude of stress stimuli, and is found colocalized with Aβ amyloid fibrils in the extracellular plaques that are characteristic of Alzheimer's disease. We investigated whether this archetypical small heat-shock protein has the ability to interact with Aβ fibrils in vitro. We find that αB-crystallin binds to wild-type Aβ₄₂ fibrils with micromolar affinity, and also binds to fibrils formed from the E22G Arctic mutation of Aβ₄₂. Immunoelectron microscopy confirms that binding occurs along the entire length and ends of the fibrils. Investigations into the effect of αB-crystallin on the seeded growth of Aβ fibrils, both in solution and on the surface of a quartz crystal microbalance biosensor, reveal that the binding of αB-crystallin to seed fibrils strongly inhibits their elongation. Because the lag phase in sigmoidal fibril assembly kinetics is dominated by elongation and fragmentation rates, the chaperone mechanism identified here represents a highly effective means to inhibit fibril proliferation. Together with previous observations of αB-crystallin interaction with α-synuclein and insulin fibrils, the results suggest that this mechanism is a generic means of providing molecular chaperone protection against amyloid fibril formation.     

Carbon nanotube inhibits the formation of β-sheet-rich oligomers of the Alzheimer's amyloid-β(16-22) peptide

Alzheimer's disease is associated with the abnormal self-assembly of the amyloid-β (Aβ) peptide into toxic β-rich aggregates. Experimental studies have shown that hydrophobic nanoparticles retard Aβ fibrillation by slowing down the nucleation process; however, the effects of nanoparticles on Aβ oligomeric structures remain elusive. In this study, we investigate the conformations of Aβ(16-22) octamers in the absence and presence of a single-walled carbon nanotube (SWCNT) by performing extensive all-atom replica exchange molecular-dynamics simulations in explicit solvent. Our simulations starting from eight random chains demonstrate that the addition of SWCNT into Aβ(16-22) solution prevents β-sheet formation. Simulation starting from a prefibrillar β-sheet octamer shows that SWCNT destabilizes the β-sheet structure. A detailed analysis of the Aβ(16-22)/SWCNT/water interactions reveals that both the inhibition of β-sheet formation and the destabilization of prefibrillar β-sheets by SWCNT result from the same physical forces: hydrophobic and π-stacking interactions (with the latter playing a more important role). By analyzing the stacking patterns between the Phe aromatic rings and the SWCNT carbon rings, we find that short ring–centroid distances mostly favor parallel orientation, whereas large distances allow all other orientations to be populated. Overall, our computational study provides evidence that SWCNT is likely to inhibit Aβ(16-22) and full-length Aβ fibrillation.     

Wild‐type,Flemish, and Dutch amyloid‐β exhibit different cytotoxicities depending on Aβ40 to Aβ42 interaction time and concentration ratio

Addition of amyloid β (Aβ) peptide Aβ40 to Aβ42 can delay Aβ42 aggregation, but consequent cytotoxicity has been reported to be enhanced or diminished. In the present study, we found that cytotoxicity was enhanced when human neuroblastoma SH‐SY5Y cells were incubated in a mixture of wt Aβ42 and Aβ40wt at a ratio of 1 : 10–20 (0.1 : 1–2 μM) for 24–36 h, whereas the enhancement was detected in cells incubated for longer times (48–60 h) with the less amyloidogenic Flemish Aβ40 variant or in cells incubated for as short as 12 h with the more amyloidogenic Dutch variant. Reductions in cytotoxicity by Aβ40 were most prominently observed in the Flemish and wt Aβ40/Aβ42 mixture at ratio 1 : 20 incubated for a short time (~12 h). The most cytotoxic Aβ40/Aβ42 mixtures were enriched in Aβ protofibril‐like structures, implying a strong correlation between cytotoxicity and this structure, the formation of which was dependent on amyloidogenic properties and incubation time. The consequences of the interactions were probably because of the different amyloidogenic properties of the Aβ40 variants, rather than to those of Aβ42, because aggregation rates of Aβ40 variants were highly dependent on sequence, whereas those of Aβ42 variants were not. These studies highlight a potential role for Aβ40 in cytotoxicity and provide novel mechanistic insights into the pathogenesis of each familial Alzheimer's disease‐associated Aβ40 variant. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

Assessing the causes and consequences of co-polymerization in amyloid formation

How, and why, different proteins form amyloid fibrils is most often studied in vitro using a single purified protein sequence. However, many amyloid diseases involve co-aggregation of different protein species, including proteins with/without post-translational modifications (e.g., different strains of PrP), proteins of different length (e.g., β₂-microglobulin and ΔN6, Aβ40, and Aβ42), sequence variants (e.g., Aβ and Aβ_ARC), and proteins from different organisms (e.g., bovine PrP and human PrP). The consequences of co-aggregation of different proteins upon the structure, stability, species transmission and toxicity of the resulting amyloid aggregates is discussed here, including the role of co-aggregation in expanding the repertoire of oligomeric and fibrillar structures and how this can affect their biological and biophysical properties.     

Amyloid oligomer formation probed by water proton magnetic resonance spectroscopy

Formation of amyloid oligomers, the most toxic species of amyloids in degenerative diseases, is critically coupled to the interplay with surrounding water. The hydrophobic force driving the oligomerization causes water removal from interfaces, changing the surface-hydration properties. Here, we show that such effects alter the magnetic relaxation response of local water in ways that may enable oligomer detection. By using water proton magnetic resonance spectroscopy, we measured significantly longer transverse magnetic relaxation (T₂) times in mixtures of serum and amyloidogenic Aβ_1-42 peptides versus similar concentration solutions of serum and nonamyloidogenic scrambled Aβ_42-1 peptides. Immunochemistry with oligomer-specific antibodies, electron microscopy and computer simulations demonstrated that the hyperintense magnetic signal correlates with Aβ_1-42 oligomerization. Finding early biophysical markers of the oligomerization process is crucial for guiding the development of new noninvasive imaging techniques, enabling timely diagnosis of amyloid-related diseases and pharmacological intervention.     

Inhibition of amyloid fibril formation and disassembly of pre-formed fibrils by natural polyphenol rottlerin

Natural polyphenols, curcumin, rottlerin and EGCG were selected for initial computational modeling of protein-ligand interaction patterns. The docking calculations demonstrated that these polyphenols can easily adjust their conformational shape to fit well into the binding sites of amyloidogenic proteins. The experimental part of the study focused on the effect of rottlerin on fibrillation of three distinct amyloidogenic proteins, namely insulin, lysozyme and Aβ_1–40 peptide. Different experimental protocols such as fluorescence spectroscopy, circular dichroism and atomic force microscopy, demonstrated that amyloid fibril formation of any of the three proteins is inhibited by low micromolar rottlerin concentrations. Most likely, the inhibition of amyloid formation proceeded via interaction of rottlerin with amyloidogenic regions of the studied proteins. Moreover, rottlerin was also effective in pre-formed fibrils disassembly, suggesting that interactions of rottlerin with fibrils were capable to interrupt the fibril-stabilizing bonds of β-sheets. The apparent IC₅₀ and DC₅₀ values were calculated in the range of 1.3–36.4 μM and 15.6–25.8 μM, respectively. The strongest inhibiting/disassembling effect of rottlerin was observed on Aβ_1–40 peptide. The cytotoxicity assay performed on the Neuro 2a cells indicated time-dependent cell morphology changes but rottlerin affected the cell viability only at concentration above 50 μM. The results of this study suggest that chemical modifications on rottlerin could be tested in the future as a promising strategy for the modulation of amyloidogenic proteins aggregation.     

On the Stability of the Soluble Amyloid Aggregates

Many amyloid proteins form metastable soluble aggregates (or protofibrils, or protein nanoparticles, with characteristic sizes from ∼10 to a few hundred nm). These can coexist with protein monomers and amyloid precipitates. These soluble aggregates are key determinants of the toxicity of these proteins. It is therefore imperative to understand the physical basis underlying their stability. Simple nucleation theory, typically applied to explain the kinetics of amyloid precipitation, fails to predict such intermediate stable states. We examine stable nanoparticles formed by the Alzheimer's amyloid-β peptide (40 and 42 residues), and by the protein barstar. These molecules have different hydrophobicities, and therefore have different short-range attractive interactions between the molecules. We also vary the pH and the ionic strength of the solution to tune the long-range electrostatic repulsion between them. In all the cases, we find that increased long-range repulsion results in smaller stable nanoparticles, whereas increased hydrophobicity produces the opposite result. Our results agree with a charged-colloid type of model for these particles, which asserts that growth-arrested colloid particles can result from a competition between short-range attraction and long-range repulsion. The nanoparticle size varies superlinearly with the ionic strength, possibly indicating a transition from an isotropic to a linear mode of growth. Our results provide a framework for understanding the stability and growth of toxic amyloid nanoparticles, and provide cues for designing effective destabilizing agents.     

Effect of zinc binding on β-amyloid structure and dynamics: implications for Aβ aggregation

Assembly of β-amyloid (Aβ) peptide into toxic oligomers is widely believed to initiate Alzheimer's disease pathogenesis. Under in vitro physiological conditions, zinc (Zn(II)) can bind to Aβ and redirect its assembly from amyloid fibrillar toward less toxic amorphous aggregation. Propensity of Aβ to go toward a specific form of aggregate state is determined by structural and dynamical properties of the initial monomeric as well as the aggregate state. Here we probe the structural and dynamical impact of binding of Zn(II) to monomeric Aβ40 using NMR spectroscopy. To obtain further support for the importance of intrinsic dynamics in the aggregation precursor, ¹⁵N relaxation measurements were also performed for Aβ42, the more fibrillar aggregation-prone variant of Aβ. The combined data suggest that, upon Zn(II)-binding to the N-terminus of Aβ40, a relatively rigid turnlike structure is induced at residues Val²⁴-Lys²⁸ whereas the residues flanking this region become more mobile on the picosecond-to-nanosecond timescale. This is in contrast to the increased rigidity of Aβ42 at the C-terminus, and proposed to be linked to the higher propensity of Zn(II)-bound peptide to form amorphous aggregates with less entropic penalties than their fibrillar counterparts.     

Tuning micelles of a bioactive heptapeptide biosurfactant via extrinsically induced conformational transition of surfactin assembly

We have studied the effects of extrinsic environmental conditions on the conformation of surfactin, a heptapeptide biosurfactant from Bacillus subtilis, in aqueous solutions. It has been made clear that temperature, pH, Ca²⁺ ions and the synthetic nonionic surfactant hepta-ethylene glycol (C₁₂E₇) affect the conformation of surfactin in aqueous solutions. The β-sheet formation reached a maximum at 40°C both in presence and absence of (C₁₂E₇) and the nonionic surfactant enhances the β-sheet formation even at 25°C. Ca²⁺ induced the formation of a-helices and caused this transition at 0.3 mm with surfactin monomers or at 0.5 mm with surfactin micelles, but above these transition concentrations of Ca²⁺ β-sheets were observed. In micellar solution the β-sheet structure was stabilized at pH values below 7 or upon addition of Ca²⁺ in concentrations above 0.5 mm . Our results indicated that the bioactive conformation of surfactin is most likely the β-sheets when the molecules are assembled in micelles. The β-sheet structure in micelles could be retained by tuning the micelles. Surfactin micelles could be tuned in the bioactive conformation by manipulating pH, temperature, Ca²⁺ or (C₁₂E₇) concentrations in surfactin solutions. Our results strongly indicated that Ca²⁺ and other molecules (such as C₁₂E₇) may function as directing templates in the assembly and conformation of surfactin in micelles. Thus, we suggest environmental manipulation and template-aided micellation (TAM) as a new approach for preparing predesigned micelles, microemulsions or micro-spheres for specific application purposes. © 1998 European Peptide Society and John Wiley & Sons, Ltd.