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.     

Substituted tryptophans at amyloid-β(1-40) residues 19 and 20 experience different environments after fibril formation

Amyloid-β protein (Aβ) is the principal component of the neuritic plaques found in Alzheimer's disease. The predominant Aβ morphology in the plaques is fibrillar which has prompted substantial in vitro work to better understand the molecular organization of Aβ fibrils. In the current study, tryptophan substitutions were made at Aβ(1-40) position 19 (F19W) or 20 (F20W) to ascertain environmental differences between the two residues in the fibril structure. Kinetic studies revealed similar rates of fibril formation between Aβ(1-40) F19W and F20W and both peptides formed typical amyloid fibril structures. Aβ(1-40) F19W fibrils displayed a significant tryptophan fluorescence blue-shift in λ(max) (33nm) compared to monomer while Aβ(1-40) F20W fibrils had a much smaller shift (9nm). Fluorescence quenching experiments with water-soluble acrylamide and KI demonstrated that both W19 and W20 were much less accessible to quenching in fibrils compared to monomer. Lipid-soluble TEMPO quenched the fluorescence of Aβ(1-40) F19W fibrils more effectively than F20W fibrils in agreement with the fluorescence blue-shift results. These findings demonstrate distinct environments between Aβ(1-40) residues 19 and 20 fibrils and indicate that while W20 accessibility is compromised in Aβ fibrils it resides in a much less hydrophobic environment than W19.     

Resolution of localized small molecule-Aβ interactions by deep-ultraviolet resonance Raman spectroscopy

The mechanism by which flavonoids prevent formation of amyloid-β (Aβ) fibrils, as well as how they associate with non-fibrillar Aβ is still unclear. Fresh, un-oxidized myricetin exhibited excitation and emission fluorescence maxima at 481 and 531 nm, respectively. Introduction of either Aβ(1-42) or Aβ(25-40) resulted in a fluorescence decrease, when measured at 481 nm, suggesting formation of a myricetin-Aβ complex. Circular dichroism (CD) and ultraviolet resonance Raman (UVRR) studies indicate that the association of myricetin with the Aβ peptide or its hydrophobic fragment, Aβ(25-40), leads to subtle changes in each peptide's conformation. Aβ(25-40) formed amyloid fibrils at a similar rate, when compared to the full-length peptide, Aβ(1-42), using thioflavin T (ThT) fluorescence. Studies also indicated that myricetin was equally effective at preventing the formation of both Aβ(1-42) and Aβ(25-40) fibrils. Although ThT assays indicated that Aβ(1-16) did not form amyloid fibrils, CD studies of the hydrophilic fragment, Aβ(1-16), suggest possible interactions between myricetin and aromatic side chains. UVRR studies of the full-length peptide and Aβ(1-16) showed increases in the intensity of the aromatic modes upon introduction of myricetin. Our findings suggest that myricetin interacts with soluble Aβ via two mechanisms, association with the hydrophobic C-terminal region and interactions with the aromatic side chains.     

Alzheimer's Aβ(1-40) Amyloid Fibrils Feature Size-Dependent Mechanical Properties

Amyloid fibrils are highly ordered protein aggregates that are associated with several pathological processes, including prion propagation and Alzheimer''s disease. A key issue in amyloid science is the need to understand the mechanical properties of amyloid fibrils and fibers to quantify biomechanical interactions with surrounding tissues, and to identify mechanobiological mechanisms associated with changes of material properties as amyloid fibrils grow from nanoscale to microscale structures. Here we report a series of computational studies in which atomistic simulation, elastic network modeling, and finite element simulation are utilized to elucidate the mechanical properties of Alzheimer''s Aβ(1-40) amyloid fibrils as a function of the length of the protein filament for both twofold and threefold symmetric amyloid fibrils. We calculate the elastic constants associated with torsional, bending, and tensile deformation as a function of the size of the amyloid fibril, covering fibril lengths ranging from nanometers to micrometers. The resulting Young''s moduli are found to be consistent with available experimental measurements obtained from long amyloid fibrils, and predicted to be in the range of 20–31 GPa. Our results show that Aβ(1-40) amyloid fibrils feature a remarkable structural stability and mechanical rigidity for fibrils longer than ≈100 nm. However, local instabilities that emerge at the ends of short fibrils (on the order of tens of nanometers) reduce their stability and contribute to their disassociation under extreme mechanical or chemical conditions, suggesting that longer amyloid fibrils are more stable. Moreover, we find that amyloids with lengths shorter than the periodicity of their helical pitch, typically between 90 and 130 nm, feature significant size effects of their bending stiffness due the anisotropy in the fibril''s cross section. At even smaller lengths (⪅50 nm), shear effects dominate lateral deformation of amyloid fibrils, suggesting that simple Euler-Bernoulli beam models fail to describe the mechanics of amyloid fibrils appropriately. Our studies reveal the importance of size effects in elucidating the mechanical properties of amyloid fibrils. This issue is of great importance for comparing experimental and simulation results, and gaining a general understanding of the biological mechanisms underlying the growth of ectopic amyloid materials.     

The Japanese mutant Aβ (ΔE22-Aβ(1-39)) forms fibrils instantaneously, with low-thioflavin T fluorescence: seeding of wild-type Aβ(1-40) into atypical fibrils by ΔE22-Aβ(1-39)

The ΔE693 (Japanese) mutation of the β-amyloid precursor protein leads to production of ΔE22-Aβ peptides such as ΔE22-Aβ(1-39). Despite reports that these peptides do not form fibrils, here we show that, on the contrary, the peptide forms fibrils essentially instantaneously. The fibrils are typical amyloid fibrils in all respects except that they cause only low levels of thioflavin T (ThT) fluorescence, which, however, develops with no lag phase. The fibrils bind ThT, but with a lower affinity and a smaller number of binding sites than wild-type (WT) Aβ(1-40). Fluorescence depolarization confirms extremely rapid aggregation of ΔE22-Aβ(1-39). Size exclusion chromatography (SEC) indicates very low concentrations of soluble monomer and oligomer, but only in the presence of some organic solvent, e.g., 2% (v/v) DMSO. The critical concentration is approximately 1 order of magnitude lower for ΔE22-Aβ(1-39) than for WT Aβ(1-40). Several lines of evidence point to an altered structure for ΔE22-Aβ(1-39) compared to that of WT Aβ(1-40) fibrils. In addition to differences in ThT binding and fluorescence, PITHIRDS-CT solid-state nuclear magnetic resonance (NMR) measurements of ΔE22-Aβ(1-39) are not compatible with the parallel in-register β-sheet generally observed for WT Aβ(1-40) fibrils. X-ray fibril diffraction showed different D spacings: 4.7 and 10.4 ? for WT Aβ(1-40) and 4.7 and 9.6 ? for ΔE22-Aβ(1-39). Equimolar mixtures of ΔE22-Aβ(1-39) and WT Aβ(1-40) also produced fibrils extremely rapidly, and by the criteria of ThT fluorescence and electron microscopic appearance, they were the same as fibrils made from pure ΔE22-Aβ(1-39). X-ray diffraction of fibrils formed from 1:1 molar mixtures of ΔE22-Aβ(1-39) and WT Aβ(1-40) showed the same D spacings as fibrils of the pure mutant peptide, not the wild-type peptide. These findings are consistent with extremely rapid nucleation by ΔE22-Aβ(1-39), followed by fibril extension by WT Aβ(1-40), and "conversion" of the wild-type peptide to a structure similar to that of the mutant peptide, in a manner reminiscent of the prion conversion phenomenon.     

The Properties of Amyloid-β Fibrils Are Determined by their Path of Formation

Fibril formation of the amyloid-β peptide (Aβ) follows a nucleation-dependent polymerization process and is associated with Alzheimer's disease. Several different lengths of Aβ are observed in vivo, but Aβ1–40 and Aβ1–42 are the dominant forms. The fibril architectures of Aβ1–40 and Aβ1–42 differ and Aβ1–42 assemblies are generally considered more pathogenic. We show here that monomeric Aβ1–42 can be cross-templated and incorporated into the ends of Aβ1–40 fibrils, while incorporation of Aβ1–40 monomers into Aβ1–42 fibrils is very poor. We also show that via cross-templating incorporated Aβ monomers acquire the properties of the parental fibrils. The suppressed ability of Aβ1–40 to incorporate into the ends of Aβ1–42 fibrils and the capacity of Aβ1–42 monomers to adopt the properties of Aβ1–40 fibrils may thus represent two mechanisms reducing the total load of fibrils having the intrinsic, and possibly pathogenic, features of Aβ1–42 fibrils in vivo. We also show that the transfer of fibrillar properties is restricted to fibril-end templating and does not apply to cross-nucleation via the recently described path of surface-catalyzed secondary nucleation, which instead generates similar structures to those acquired via de novo primary nucleation in the absence of catalyzing seeds. Taken together these results uncover an intrinsic barrier that prevents Aβ1–40 from adopting the fibrillar properties of Aβ1–42 and exposes that the transfer of properties between amyloid-β fibrils are determined by their path of formation.     

Trace amounts of pyroglutaminated Aβ-(3–42) enhance aggregation of Aβ-(1–42) on neuronal membranes at physiological concentrations: FCS analysis of cell surface

Minor species of amyloid β-peptide (Aβ), such as Aβ-(1–43) and pyroglutaminated Aβ-(3–42) (Aβ-(3pE–42)), have been suggested to be involved in the initiation of the Aβ aggregation process, which is closely associated with the etiology of Alzheimer's disease. They can play important roles in aggregation not only in the aqueous phase but also on neuroral membranes; however, the latter behaviors remain mostly unexplored. Here, initial aggregation processes of Aβ on living cells were monitored at physiological nanomolar concentrations by fluorescence correlation spectroscopy. Membrane-bound Aβ-(1–42) and Aβ-(1–40) formed oligomers composed of ~4 Aβ molecules during 48-h incubation, whereas the peptides remained monomeric in the culture medium, indicating that the membranes facilitated Aβ aggregation. The presence of 5 mol% Aβ-(3pE–42), but not Aβ-(1–43), significantly enhanced the aggregation of Aβ-(1–42) up to ~10-mers. On the other hand, neither trace amounts of Aβ-(1–42) nor Aβ-(3pE–42) enhanced the aggregation of Aβ-(1–40). The observed small Aβ oligomers are expected to act as pathogenic seeds for amyloid fibrils responsible for neurotoxicity. This article is part of a Special Issue entitled: Protein Aggregation and Misfolding at the Cell Membrane Interface edited by Ayyalusamy Ramamoorthy.     

Structural origin of polymorphism of Alzheimer's amyloid β-fibrils

Formation of senile plaques containing amyloid fibrils of Aβ (amyloid β-peptide) is a pathological hallmark of Alzheimer's disease. Unlike globular proteins, which fold into unique structures, the fibrils of Aβ and other amyloid proteins often contain multiple polymorphs. Polymorphism of amyloid fibrils leads to different toxicity in amyloid diseases and may be the basis for prion strains, but the structural origin for fibril polymorphism is still elusive. In the present study we investigate the structural origin of two major fibril polymorphs of Aβ40: an untwisted polymorph formed under agitated conditions and a twisted polymorph formed under quiescent conditions. Using electron paramagnetic resonance spectroscopy, we studied the inter-strand side-chain interactions at 14 spin-labelled positions in the Aβ40 sequence. The results of the present study show that the agitated fibrils have stronger inter-strand spin-spin interactions at most of the residue positions investigated. The two hydrophobic regions at residues 17-20 and 31-36 have the strongest interactions in agitated fibrils. Distance estimates on the basis of the spin exchange frequencies suggest that inter-strand distances at residues 17, 20, 32, 34 and 36?in agitated fibrils are approximately 0.2?? (1??=0.1?nm) closer than in quiescent fibrils. We propose that the strength of inter-strand side-chain interactions determines the degree of β-sheet twist, which then leads to the different association patterns between different cross β-units and thus distinct fibril morphologies. Therefore the inter-strand side-chain interaction may be a structural origin for fibril polymorphism in Aβ and other amyloid proteins.     

Aβ peptide fibrillar architectures controlled by conformational constraints of the monomer

Anomalous self-assembly of the Aβ peptide into fibrillar amyloid deposits is strongly correlated with the development of Alzheimer's disease. Aβ fibril extension follows a template guided "dock and lock" mechanism where polymerisation is catalysed by the fibrillar ends. Using surface plasmon resonance (SPR) and quenched hydrogen-deuterium exchange NMR (H/D-exchange NMR), we have analysed the fibrillar structure and polymerisation properties of both the highly aggregation prone Aβ1-40 Glu22Gly (Aβ(40Arc)) and wild type Aβ1-40 (Aβ(40WT)). The solvent protection patterns from H/D exchange experiments suggest very similar structures of the fibrillar forms. However, through cross-seeding experiments monitored by SPR, we found that the monomeric form of Aβ(40WT) is significantly impaired to acquire the fibrillar architecture of Aβ(40Arc). A detailed characterisation demonstrated that Aβ(40WT) has a restricted ability to dock and isomerise with high binding affinity onto Aβ(40Arc) fibrils. These results have general implications for the process of fibril assembly, where the rate of polymerisation, and consequently the architecture of the formed fibrils, is restricted by conformational constraints of the monomers. Interestingly, we also found that the kinetic rate of fibril formation rather than the thermodynamically lowest energy state determines the overall fibrillar structure.     

Determination of size of folding nuclei of fibrils formed from recombinant Aβ(1-40) peptide

We have developed a highly efficient method for purification of the recombinant product Aβ(1-40) peptide. The concentration dependence of amyloid formation by recombinant Aβ(1-40) peptide was studied using fluorescence spectroscopy and electron microscopy. We found that the process of amyloid formation is preceded by lag time, which indicates that the process is nucleation-dependent. Further exponential growth of amyloid fibrils is followed by branching scenarios. Based on the experimental data on the concentration dependence, the sizes of the folding nuclei of fibrils were calculated. It turned out that the size of the primary nucleus is one “monomer” and the size of the secondary nucleus is zero. This means that the nucleus for new aggregates can be a surface of the fibrils themselves. Using electron microscopy, we have demonstrated that fibrils of these peptides are formed by the association of rounded ring structures.     

Mechanism of A beta(1-40) fibril-induced fluorescence of (trans,trans)-1-bromo-2,5-bis(4-hydroxystyryl)benzene (K114)

K114, (trans,trans)-1-bromo-2,5-bis(4-hydroxystyryl)benzene, is a fluorescent Congo Red analogue that binds tightly to amyloid fibrils, but not the monomeric proteins, with a concomitant enhancement in fluorescence. The mechanism for the low aqueous fluorescence and the subsequent enhancement by A beta(1-40) fibrils was investigated by fluorescence spectroscopy and binding analysis. K114's unusually low buffer fluorescence is due to self-quenching in sedimentable aggregates or micelles which upon interacting with amyloid fibrils undergo an enhancement in fluorescence intensity and shifts in the excitation and emission spectra. These spectral changes are suggestive of a stabilization of the phenolate anion, perhaps by hydrogen bonding, rather than an increase in the microenvironment dielectric constant or dye immobilization. 1,4-Bis(4-aminophenylethenyl)-2-methoxybenzene, which lacks the phenol moiety, and X-34, which contains a stabilized phenol (pK approximately 13.4), do not display the phenolate anion fluorescence in the presence of fibrils. The apparent affinity of K114 for fibril binding is 20-30 nM with a stoichiometry of 2.2 mol of K114/mol of A beta(1-40) monomer. Competition studies indicate that K114 and Congo Red share a site, but K114 does not bind to sites on A beta(1-40) fibrils for neutral benzothiazole (BTA-1), cationic thioflavin T, or the hydrophobic (S)-naproxen and (R)-ibuprofen molecules. Comparison of benzothiazole binding stoichiometry which has been suggested to reflect disease-relevant amyloid structures to that of Congo Red analogues which reflect total fibril content may be useful in defining biologically pertinent conformational forms of amyloid.     

Expression and purification of 15N- and 13C-isotope labeled 40-residue human Alzheimer's β-amyloid peptide for NMR-based structural analysis

Amyloid fibrils of Alzheimer's β-amyloid peptide (Aβ) are a primary component of amyloid plaques, a hallmark of Alzheimer's disease (AD). Enormous attention has been given to the structural features and functions of Aβ in amyloid fibrils and other type of aggregates in associated with development of AD. This report describes an efficient protocol to express and purify high-quality 40-residue Aβ(1-40), the most abundant Aβ in brains, for structural studies by NMR spectroscopy. Over-expression of Aβ(1-40) with glutathione S-transferase (GST) tag connected by a Factor Xa recognition site (IEGR(?)) in Escherichia coli resulted in the formation of insoluble inclusion bodies even with the soluble GST tag. This problem was resolved by efficient recovery of the GST-Aβ fusion protein from the inclusion bodies using 0.5% (w/v) sodium lauroyl sarcosinate as solubilizing agent and subsequent purification by affinity chromatography using a glutathione agarose column. The removal of the GST tag by Factor Xa enzymatic cleavage and purification by HPLC yielded as much as ～7 mg and ～1.5mg of unlabeled Aβ(1-40) and uniformly (15)N- and/or (13)C-protein Aβ(1-40) from 1L of the cell culture, respectively. Mass spectroscopy of unlabeled and labeled Aβ and (1)H/(15)N HSQC solution NMR spectrum of the obtained (15)N-labeled Aβ in the monomeric form confirmed the expression of native Aβ(1-40). It was also confirmed by electron micrography and solid-state NMR analysis that the purified Aβ(1-40) self-assembles into β-sheet rich amyloid fibrils. To the best of our knowledge, our protocol offers the highest yields among published protocols for production of recombinant Aβ(1-40) samples that are amendable for an NMR-based structural analysis. The protocol may be applied to efficient preparation of other amyloid-forming proteins and peptides that are (13)C- and (15)N-labeled for NMR experiments.     

Amyloid-Like Fibril Formation by Tachykinin Neuropeptides and Its Relevance to Amyloid β-Protein Aggregation and Toxicity

Protein aggregation and amyloid formation are associated with both pathological conditions in humans such as Alzheimer's disease and native functions such as peptide hormone storage in the pituitary secretory granules in mammals. Here, we studied amyloid fibrils formation by three neuropeptides namely physalaemin, kassinin and substance P of tachykinin family using biophysical techniques including circular dichroism, thioflavin T, congo red binding and microscopy. All these neuropeptides under study have significant sequence similarity with Aβ(25-35) that is known to form neurotoxic amyloids. We found that all these peptides formed amyloid-like fibrils in vitro in the presence of heparin, and these amyloids were found to be nontoxic in neuronal cells. However, the extent of amyloid formation, structural transition, and morphology were different depending on the primary sequences of peptide. When Aβ(25-35) and Aβ40 were incubated with each of these neuropeptides in 1:1 ratio, a drastic increase in amyloid growths were observed compared to that of individual peptides suggesting that co-aggregation of Aβ and these neuropeptides. The electron micrographs of these co-aggregates were dissimilar when compared with individual peptide fibrils further supporting the possible incorporation of these neuropeptides in Aβ amyloid fibrils. Further, the fibrils of these neuropeptides can seed the fibrils formation of Aβ40 and reduced the toxicity of preformed Aβ fibrils. The present study of amyloid formation by tachykinin neuropeptides is not only providing an understanding of the mechanism of amyloid fibril formation in general, but also offering plausible explanation that why these neuropeptide might reduce the cytotoxicity associated with Alzheimer's disease related amyloids.     

Impact of sequence on the molecular assembly of short amyloid peptides

The goal of this work is to understand how the sequence of a protein affects the likelihood that it will form an amyloid fibril and the kinetics along the fibrillization pathway. The focus is on very short fragments of amyloid proteins since these play a role in the fibrillization of the parent protein and can form fibrils themselves. Discontinuous molecular dynamics simulations using the PRIME20 force field were performed of the aggregation of 48‐peptide systems containing SNQNNF ( PrP (170–175 )), SSTSAA (RNaseA(15–20)), MVGGVV (Aβ(35–40)), GGVVIA (Aβ(37–42)), and MVGGVVIA (Aβ(35–42)). In our simulations SNQQNF, SSTTSAA, and MVGGVV form large numbers of fibrillar structures spontaneously (as in experiment). GGVVIA forms β‐sheets that do not stack into fibrils (unlike experiment). The combination sequence MVGGVVIA forms less fibrils than MVGGVV, hindered by the presence of the hydrophobic residues at the C‐terminal. Analysis of the simulation kinetics and energetics reveals why MVGGVV forms fibrils and GGVVIA does not, and why adding I and A to MVGGVVIA reduces fibrillization and enhances amorphous aggregation into oligomeric structures. The latter helps explain why Aβ(1–42) assembles into more complex oligomers than Aβ(1–40), a consequence of which is that it is more strongly associated with Alzheimer's disease. Proteins 2014; 82:1469–1483. © 2014 Wiley Periodicals, Inc.     

Structure and texture of fibrous crystals formed by Alzheimer's abeta(11-25) peptide fragment

Amyloid fibril deposition is central to the pathology of Alzheimer's disease. X-ray diffraction from amyloid fibrils formed from full-length Abeta(1-40) and from a shorter fragment, Abeta(11-25), have revealed cross-beta diffraction fingerprints. Magnetic alignment of Abeta(11-25) amyloid fibrils gave a distinctive X-ray diffraction texture, allowing interpretation of the diffraction data and a model of the arrangement of the peptides within the amyloid fiber specimen to be constructed. An intriguing feature of the structure of fibrillar Abeta(11-25) is that the beta sheets, of width 5.2 nm, stack by slipping relative to each other by the length of two amino acid units (0.70 nm) to form beta ribbons 4.42 nm in thickness. Abeta(1-40) amyloid fibrils likely consist of once-folded hairpins, consistent with the size of the fibers obtained using electron microscopy and X-ray diffraction.     

Probing the amyloid-β(1-40) fibril environment with substituted tryptophan residues

A signature feature of Alzheimer’s disease is the accumulation of plaques, composed of fibrillar amyloid-β protein (Aβ), in the brain parenchyma. Structural models of Aβ fibrils reveal an extensive β-sheet network with a hydrophobic core extending throughout the fibril axis. In this study, phenylalanines in the Aβ(1-40) sequence were substituted with tryptophan residues at either position 4 (F4W) or 19 (F19W) to probe the fibril environment. The F4W substitution did not alter self-assembly kinetics, while the F19W change slightly lengthened the lag phase without hindering fibril formation. The tryptophan fluorescence of Aβ(1-40) F19W, but not Aβ(1-40) F4W, underwent a marked blue shift during fibril formation and this shift was temporally correlated with thioflavin T binding. Isolated Aβ(1-40) F19W fibrils exhibited the largest fluorescence blue shifts consistent with W19 insertion into the Aβ(1-40) fibril inner core and direct probing of the substantially hydrophobic environment therein.     

Calcium ions promote formation of amyloid β-peptide (1-40) oligomers causally implicated in neuronal toxicity of Alzheimer's disease

Amyloid β-peptide (Aβ) is directly linked to Alzheimer's disease (AD). In its monomeric form, Aβ aggregates to produce fibrils and a range of oligomers, the latter being the most neurotoxic. Dysregulation of Ca(2+) homeostasis in aging brains and in neurodegenerative disorders plays a crucial role in numerous processes and contributes to cell dysfunction and death. Here we postulated that calcium may enable or accelerate the aggregation of Aβ. We compared the aggregation pattern of Aβ(1-40) and that of Aβ(1-40)E22G, an amyloid peptide carrying the Arctic mutation that causes early onset of the disease. We found that in the presence of Ca(2+), Aβ(1-40) preferentially formed oligomers similar to those formed by Aβ(1-40)E22G with or without added Ca(2+), whereas in the absence of added Ca(2+) the Aβ(1-40) aggregated to form fibrils. Morphological similarities of the oligomers were confirmed by contact mode atomic force microscopy imaging. The distribution of oligomeric and fibrillar species in different samples was detected by gel electrophoresis and Western blot analysis, the results of which were further supported by thioflavin T fluorescence experiments. In the samples without Ca(2+), Fourier transform infrared spectroscopy revealed conversion of oligomers from an anti-parallel β-sheet to the parallel β-sheet conformation characteristic of fibrils. Overall, these results led us to conclude that calcium ions stimulate the formation of oligomers of Aβ(1-40), that have been implicated in the pathogenesis of AD.     

Spectroscopic characterization of diverse amyloid fibrils in vitro by the fluorescent dye Nile red

The fluorescence of Nile red (9-diethylamino-5H-benzophenoxazine-5-one) is quenched in aqueous solutions but shows augmented fluorescence in hydrophobic environments. Nile red fluorescence was blue shifted and strongly augmented in the presence of various amyloid fibrils assayed under acidic as well as neutral pH conditions. Fibrils grown from lysozyme and insulin (at pH 1.6 and 65 °C), transthyretin (TTR) fibrils grown from the acid unfolded monomer (pH 2.0, 21 °C) or from the dissociated tetramer starting from native protein under less acidic conditions (pH 4.4, 37 °C) were detected. Nile red was also successfully employed in detecting Aβ1-42 and human prion protein (PrP90-231) amyloid fibrils grown at neutral pH. Nile red was amyloid fibril specific and did not fluoresce appreciably in the presence of the monomeric precursor proteins. Stoke's shifts of the wavelength maximum of Nile red bound to various fibrils were different (ranging from 615 nm to 638 nm) indicating sensitivity to the tertiary structure in its respective binding sites of different amyloid proteins. A polarity assay using ethanol-water mixtures and pure octanol ranging from dielectric constants between 10 and 70 showed a linear correlation of Nile red Stoke's shift and allowed assignment of amyloid fibril binding site polarity. Fluorescence resonance energy transfer between Thioflavin T (ThT) and Nile red was proven to be efficient and co-staining was employed to discriminate between conformational isoforms of Aβ1-42 amyloid fibrils grown under agitated and quiescent conditions. This paper demonstrates the complementary use of this fluorometric method for conformational typing of amyloid structures.     

Two distinct amyloid beta-protein (Abeta) assembly pathways leading to oligomers and fibrils identified by combined fluorescence correlation spectroscopy, morphology, and toxicity analyses

Nonfibrillar assemblies of amyloid β-protein (Aβ) are considered to play primary roles in Alzheimer disease (AD). Elucidating the assembly pathways of these specific aggregates is essential for understanding disease pathogenesis and developing knowledge-based therapies. However, these assemblies cannot be monitored in vivo, and there has been no reliable in vitro monitoring method at low protein concentration. We have developed a highly sensitive in vitro monitoring method using fluorescence correlation spectroscopy (FCS) combined with transmission electron microscopy (TEM) and toxicity assays. Using Aβ labeled at the N terminus or Lys(16), we uncovered two distinct assembly pathways. One leads to highly toxic 10-15-nm spherical Aβ assemblies, termed amylospheroids (ASPDs). The other leads to fibrils. The first step in ASPD formation is trimerization. ASPDs of ～330 kDa in mass form from these trimers after 5 h of slow rotation. Up to at least 24 h, ASPDs remain the dominant structures in assembly reactions. Neurotoxicity studies reveal that the most toxic ASPDs are ～128 kDa (～32-mers). In contrast, fibrillogenesis begins with dimer formation and then proceeds to formation of 15-40-nm spherical intermediates, from which fibrils originate after 15 h. Unlike ASPD formation, the Lys(16)-labeled peptide disturbed fibril formation because the Aβ(16-20) region is critical for this final step. These differences in the assembly pathways clearly indicated that ASPDs are not fibril precursors. The method we have developed should facilitate identifying Aβ assembly steps at which inhibition may be beneficial.