Structural and dynamic features of Alzheimer's Abeta peptide in amyloid fibrils studied by site-directed spin labeling

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

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

A strategy for designing a peptide probe for detection of β-amyloid oligomers

Aggregation of β-amyloid (Aβ) is implicated in the pathology of Alzheimer's disease. Development of a robust strategy to detect Aβ oligomeric intermediates, which have been identified as significant toxic agents, would be highly beneficial in the screening of drug candidates as well as enhancing our understanding of Aβ oligomerization. Rapid, specific and quantitative detection, currently unavailable, would be highly preferred for accurate and reliable probing of transient Aβ oligomers. Here, we report the development of a novel peptide probe, PG46, based on the nature of Aβ self-assembly and the conformation-sensitive fluorescence of the biarsenical dye, FlAsH. PG46 was found to bind to Aβ oligomers and displayed an increase in FlAsH fluorescence upon binding. No such event was observed when PG46 was co-incubated with Aβ low-molecular-weight species or Aβ fibrils. Aβ oligomer detection was fast, and occurred within one hour without any additional sample incubation or preparation. We anticipate that the development of a strategy for detection of amyloid oligomers described in this study will be directly relevant to a host of other amyloidogenic proteins.

Structural evolution of Iowa mutant β-amyloid fibrils from polymorphic to homogeneous states under repeated seeded growth

Structural variations in β-amyloid fibrils are potentially important to the toxicity of these fibrils in Alzheimer's disease (AD). We describe a repeated seeding protocol that selects a homogeneous fibril structure from a polymorphic initial state in the case of 40-residue β-amyloid fibrils with the Asp23-to-Asn, or Iowa, mutation (D23N-Aβ(1-40)). We use thioflavin T (ThT) fluorescence, transmission electron microscopy (TEM), and solid-state nuclear magnetic resonance (NMR) to track the evolution of fibril structure through multiple generations under this protocol. The data show that (i) repeated seeding selectively amplifies a single D23N-Aβ(1-40) fibril structure that can be a minor component of the initial polymorphic state; (ii) the final structure is highly sensitive to growth conditions, including pH, temperature, and agitation; (iii) although the initial state can include fibrils that contain both antiparallel and parallel β-sheets, the final structures contain only parallel β-sheets, suggesting that antiparallel β-sheet structures are thermodynamically and kinetically metastable. Additionally, our data demonstrate that ThT fluorescence enhancements, which are commonly used to monitor amyloid fibril formation, vary strongly with structural variations, even among fibrils comprised of the same polypeptide. Finally, we present a simple mathematical model that describes the structural evolution of fibril samples under repeated seeding.

Recent progress in understanding Alzheimer's β-amyloid structures

The formation of amyloid fibrils, protofibrils and oligomers from the β-amyloid (Aβ) peptide represents a hallmark of Alzheimer's disease. Aβ-peptide-derived assemblies might be crucial for disease onset, but determining their atomic structures has proven to be a major challenge. Progress over the past 5 years has yielded substantial new data obtained with improved methodologies including electron cryo-microscopy and NMR. It is now possible to resolve the global fibril topology and the cross-β sheet organization within protofilaments, and to identify residues that are crucial for stabilizing secondary structural elements and peptide conformations within specific assemblies. These data have significantly enhanced our understanding of the mechanism of Aβ aggregation and have illuminated the possible relevance of specific conformers for neurodegenerative pathologies.

Synthesis and study of 2-amino-7-bromofluorenes modified with nitroxides and their precursors as dual anti-amyloid and antioxidant active compounds

A series of 2-aminofluorenes N-alkylated with nitroxides or their precursors were synthesized. The new compounds were tested on hydroxyl radical and peroxyl radical scavenging ability and inflammatory assay on the endothelial brain cells. In agreement with ROS scavenging ability the same compound 7-bromo-N -[(1-Oxyl-2,2,6,6-tetramethyl-1,2,3,6-tetrahydropyridine-4yl)methyl]-9H-fluoren-2-amine (3b) and its hydroxylamine salt (3b/OH/HCl) showed the anti-inflammatory property on the endothelial brain cells.

A kinetic aggregation assay allowing selective and sensitive amyloid-β quantification in cells and tissues

The process of amyloid-β (Aβ) fibril formation is genetically and pathologically linked to Alzheimer's disease (AD). Thus, a selective and sensitive method for quantifying Aβ fibrils in complex biological samples allows a variety of hypotheses to be tested. Herein, we report the basis for a quantitative in vitro kinetic aggregation assay that detects seeding-competent Aβ aggregates in mammalian cell culture media, in Caenorhabditis elegans lysate, and in mouse brain homogenate. Sonicated, proteinase K-treated Aβ fibril-containing tissue homogenates or cell culture media were added to an initially monomeric Aβ(1-40) reporter peptide to seed an in vitro nucleated aggregation reaction. The reduction in the half-time (t(50)) of the amyloid growth phase is proportional to the quantity of seeding-competent Aβ aggregates present in the biological sample. An ion-exchange resin amyloid isolation strategy from complex biological samples is demonstrated as an alternative for improving the sensitivity and linearity of the kinetic aggregation assay.

Point mutations in Aβ result in the formation of distinct polymorphic aggregates in the presence of lipid bilayers

A hallmark of Alzheimer's disease (AD) is the rearrangement of the β-amyloid (Aβ) peptide to a non-native conformation that promotes the formation of toxic, nanoscale aggregates. Recent studies have pointed to the role of sample preparation in creating polymorphic fibrillar species. One of many potential pathways for Aβ toxicity may be modulation of lipid membrane function on cellular surfaces. There are several mutations clustered around the central hydrophobic core of Aβ near the α-secretase cleavage site (E22G Arctic mutation, E22K Italian mutation, D23N Iowa mutation, and A21G Flemish mutation). These point mutations are associated with hereditary diseases ranging from almost pure cerebral amyloid angiopathy (CAA) to typical Alzheimer's disease pathology with plaques and tangles. We investigated how these point mutations alter Aβ aggregation in the presence of supported lipid membranes comprised of total brain lipid extract. Brain lipid extract bilayers were used as a physiologically relevant model of a neuronal cell surface. Intact lipid bilayers were exposed to predominantly monomeric preparations of Wild Type or different mutant forms of Aβ, and atomic force microscopy was used to monitor aggregate formation and morphology as well as bilayer integrity over a 12 hour period. The goal of this study was to determine how point mutations in Aβ, which alter peptide charge and hydrophobic character, influence interactions between Aβ and the lipid surface. While fibril morphology did not appear to be significantly altered when mutants were prepped similarly and incubated under free solution conditions, aggregation in the lipid membranes resulted in a variety of polymorphic aggregates in a mutation dependent manner. The mutant peptides also had a variable ability to disrupt bilayer integrity.

Folding stability of amyloid-beta 40 monomer is an important determinant of the nucleation kinetics in fibrillization

Amyloid formation is initiated by protein misfolding, followed by self-association to ultimately form amyloid fibrils. The discovery of toxic prefibrillar oligomers in many amyloidosis underscores the importance of understanding the folding mechanism prior to such aggregation. Here, we investigated the folding properties of the natively unfolded amyloid-β (Aβ) peptide and the familial variants (A21G, E22Q, E22G, E22K, and D23N) in Alzheimer's disease (AD). In combinations of native electrophoresis, analytical ultracentrifugation, fluorescence emission, and far-UV circular dichroism, we showed that all Aβ40 variants are predominantly monomeric with similar residual secondary structures, but distinct hydrophobic-exposed protein surfaces. Guanidine hydrochloride (GdnHCl) denaturation in the absence and presence of trifluoroethanol (TFE) showed that Aβ variants adopt an apparent 2-state equilibrium model with different stabilities, in which wild type is less stable than A21G but more stable than D23N and E22 mutants. By correlating the folding stability with the nucleation phase in fibrillization, we found the more stable the variant, the slower the nucleation, except for D23N. Besides, the unfolding of Aβ conformation leads to reduced formation of mature fibrils, but an increase in nonfibrillar, amorphous type of aggregates. Overall, we demonstrated that folding stability of Aβ is an important determinant of the nucleation kinetics.

Controlling amyloid-beta peptide(1-42) oligomerization and toxicity by fluorinated nanoparticles

The amyloid-beta peptide (Abeta) is a major fibrillar component of neuritic plaques in Alzheimer's disease brains and is related to the pathogenesis of the disease. Soluble oligomers that precede fibril formation have been proposed as the main neurotoxic species that contributes to neurodegeneration and dementia. We hypothesize that oligomerization and cytotoxicity can be repressed by nanoparticles (NPs) that induce conformational changes in Abeta42. We show here that fluorinated and hydrogenated NPs with different abilities to change Abeta42 conformation influence oligomerization as assessed by atomic force microscopy, immunoblot and SDS-PAGE. Fluorinated NPs, which promote an increase in alpha-helical content, exert an antioligomeric effect, whereas hydrogenated analogues do not and lead to aggregation. Cytotoxicity assays confirmed our hypothesis by indicating that the conformational conversion of Abeta42 into an alpha-helical-enriched secondary structure also has antiapoptotic activity, thereby increasing the viability of cells treated with oligomeric species.

EPR in protein science : intrinsically disordered proteins

Intrinsically disordered proteins (IDPs) form a unique protein category characterized by the absence of a well-defined structure and by remarkable conformational flexibility. Electron Paramagnetic Resonance (EPR) spectroscopy combined with site-directed spin labeling (SDSL) is amongst the most suitable methods to unravel their structure and dynamics. This review summarizes the tremendous methodological developments in the area of SDSL EPR and its applications in protein research. Recent results on the intrinsically disordered Parkinson's disease protein α-synuclein illustrate that the method has gained increasing attention in IDP research. SDSL EPR has now reached a level where broad application in this rapidly advancing field is feasible.

Conformation dependent monoclonal antibodies distinguish different replicating strains or conformers of prefibrillar Aβ oligomers

Background

Age-related neurodegenerative diseases share a number of important pathological features, such as accumulation of misfolded proteins as amyloid oligomers and fibrils. Recent evidence suggests that soluble amyloid oligomers and not the insoluble amyloid fibrils may represent the primary pathological species of protein aggregates.

Results

We have produced several monoclonal antibodies that specifically recognize prefibrillar oligomers and do not recognize amyloid fibrils, monomer or natively folded proteins. Like the polyclonal antisera, the individual monoclonals recognize generic epitopes that do not depend on a specific linear amino acid sequence, but they display distinct preferences for different subsets of prefibrillar oligomers. Immunological analysis of a number of different prefibrillar Aβ oligomer preparations show that structural polymorphisms exist in Aβ prefibrillar oligomers that can be distinguished on the basis of their reactivity with monoclonal antibodies. Western blot analysis demonstrates that the conformers defined by the monoclonal antibodies have distinct size distributions, indicating that oligomer structure varies with size. The different conformational types of Aβ prefibrillar oligomers can serve as they serve as templates for monomer addition, indicating that they seed the conversion of Aβ monomer into more prefibrillar oligomers of the same type.

Conclusions

These results indicate that distinct structural variants or conformers of prefibrillar Aβ oligomers exist that are capable of seeding their own replication. These conformers may be analogous to different strains of prions.

A structural model for apolipoprotein C-II amyloid fibrils: experimental characterization and molecular dynamics simulations

The self-assembly of specific proteins to form insoluble amyloid fibrils is a characteristic feature of a number of age-related and debilitating diseases. Lipid-free human apolipoprotein C-II (apoC-II) forms characteristic amyloid fibrils and is one of several apolipoproteins that accumulate in amyloid deposits located within atherosclerotic plaques. X-ray diffraction analysis of aligned apoC-II fibrils indicated a simple cross-β-structure composed of two parallel β-sheets. Examination of apoC-II fibrils using transmission electron microscopy, scanning transmission electron microscopy, and atomic force microscopy indicated that the fibrils are flat ribbons composed of one apoC-II molecule per 4.7-Å rise of the cross-β-structure. Cross-linking results using single-cysteine substitution mutants are consistent with a parallel in-register structural model for apoC-II fibrils. Fluorescence resonance energy transfer analysis of apoC-II fibrils labeled with specific fluorophores provided distance constraints for selected donor-acceptor pairs located within the fibrils. These findings were used to develop a simple 'letter-G-like' β-strand-loop-β-strand model for apoC-II fibrils. Fully solvated all-atom molecular dynamics (MD) simulations showed that the model contained a stable cross-β-core with a flexible connecting loop devoid of persistent secondary structure. The time course of the MD simulations revealed that charge clusters in the fibril rearrange to minimize the effects of same-charge interactions inherent in parallel in-register models. Our structural model for apoC-II fibrils suggests that apoC-II monomers fold and self-assemble to form a stable cross-β-scaffold containing relatively unstructured connecting loops.

Translational, rotational and internal dynamics of amyloid beta-peptides (Abeta40 and Abeta42) from molecular dynamics simulations

In this study, diffusion constants [translational (D(T)) and rotational (D(R))], correlation times [rotational (tau(rot)) and internal (tau(int))], and the intramolecular order parameters (S(2)) of the Alzheimer amyloid-beta peptides Abeta40 and Abeta42 have been calculated from 150 ns molecular dynamics simulations in aqueous solution. The computed parameters have been compared with the experimentally measured values. The calculated D(T) of 1.61 x 10(-6) cm(2)/s and 1.43 x 10(-6) cm(2)/s for Abeta40 and Abeta42, respectively, at 300 K was found to follow the correct trend defined by the Debye-Stokes-Einstein relation that its value should decrease with the increase in the molecular weight. The estimated D(R) for Abeta40 and Abeta42 at 300 K are 0.085 and 0.071 ns(-1), respectively. The rotational (C(rot)(t)) and internal (C(int)(t)) correlation functions of Abeta40 and Abeta42 were observed to decay at nano- and picosecond time scales, respectively. The significantly different time decays of these functions validate the factorization of the total correlation function (C(tot)(t)) of Abeta peptides into C(rot)(t) and C(int)(t). At both short and long time scales, the Clore-Szabo model that was used as C(int)(t) provided the best behavior of C(tot)(t) for both Abeta40 and Abeta42. In addition, an effective rotational correlation time of Abeta40 is also computed at 18 degrees C and the computed value (2.30 ns) is in close agreement with the experimental value of 2.45 ns. The computed S(2) parameters for the central hydrophobic core, the loop region, and C-terminal domains of Abeta40 and Abeta42 are in accord with the previous studies.

DHPC strongly affects the structure and oligomerization propensity of Alzheimer's Aβ(1-40) peptide

Alzheimer's disease (AD) is thought to depend on the deleterious action of amyloid fibrils or oligomers derived from β-amyloid (Aβ) peptide. Out of various known Aβ alloforms, the 40-residue peptide Aβ(1-40) occurs at highest concentrations inside the brains of AD patients. Its aggregation properties critically depend on lipids, and it was thus proposed that lipids could play a major role in AD. To better understand their possible effects on the structure of Aβ and on the ability of this peptide to form potentially detrimental amyloid structures, we here analyze the interactions between Aβ(1-40) and 1,2-dihexanoyl-sn-glycero-3-phosphocholine (DHPC). DHPC has served, due to its controlled properties, as a major model system for studying general lipid properties. Here, we show that DHPC concentrations of 8 mM or higher exert dramatic effects on the conformation of soluble Aβ(1-40) peptide and induce the formation of β-sheet structure at high levels. By contrast, we find that DHPC concentrations well below the critical micelle concentration present no discernible effect on the conformation of soluble Aβ, although they substantially affect the peptide's oligomerization and fibrillation kinetics. These data imply that subtle lipid-peptide interactions suffice in controlling the overall aggregation properties and drastically accelerate, or delay, the fibrillation kinetics of Aβ peptide in near-physiological buffer solutions.

The effect of curcumin on human islet amyloid polypeptide misfolding and toxicity

Type 2 diabetes involves aberrant misfolding of human islet amyloid polypeptide (h-IAPP) and resultant pancreatic amyloid deposits. Curcumin, a biphenolic small molecule, has offered potential benefits in other protein misfolding diseases, such as Alzheimer's disease. Our aim was to investigate whether curcumin alters h-IAPP misfolding and protects from cellular toxicity at physiologically relevant concentrations. The effect of curcumin on h-IAPP misfolding in vitro was investigated by electron paramagnetic resonance spectroscopy, ThT fluorescence and electron microscopy. Our in vitro studies revealed that curcumin significantly reduces h-IAPP fibril formation and aggregates formed in the presence of curcumin display alternative morphology and structure. We then tested a potential protective effect of curcumin against h-IAPP toxicity on β-cells. Micromolar concentrations of curcumin partially protect INS cells from exogenous IAPP toxicity. This protective effect, however, is limited to a narrow concentration range, as curcumin becomes cytotoxic at micromolar concentrations. In different models of endogenous over-expression of h-IAPP (INS cells and h-IAPP transgenic rat islets), curcumin failed to protect β-cells from h-IAPP-induced apoptosis. While curcumin has the ability to inhibit amyloid formation, the present data suggest that, without further modification, it is unlikely to be therapeutically useful in protection of β-cells in type 2 diabetes.

Two-photon and time-resolved fluorescence conformational studies of aggregation in amyloid peptides

The conformational changes associated with the aggregation of proteins are critical to the understanding of fundamental molecular events involved in early processes of neurodegenerative diseases. A detailed investigation of these processes requires the development of new approaches that allow for sensitive measurements of protein interactions. In this paper, we applied two-photon spectroscopy coupled with time-resolved fluorescence measurements to analyze amyloid peptide interactions through aggregation-dependent concentration effects. Labeled amyloid-beta peptide (TAMRA-Abeta1-42) was used in our investigation, and measurements of two-photon-excited fluorescence of the free and covalently conjugated peptide structure were carried out. The peptide secondary structure was correlated with a short fluorescence lifetime component, and this was associated with intramolecular interactions. Comparison of the fractional occupancy of the fluorescence lifetime measured at different excitation modes demonstrates the high sensitivity of the two-photon method in comparison to one-photon excitation (OPE). These results give strong justification for the development of fluorescence-lifetime-based multiphoton imaging and assays.

Structural variations in the cross-beta core of amyloid beta fibrils revealed by deep UV resonance Raman spectroscopy

Understanding fibrillogenesis at a molecular level requires detailed structural characterization of amyloid fibrils. The combination of deep UV resonance Raman (DUVRR) spectroscopy and post mortem hydrogen-deuterium exchange (HX) was utilized for probing parallel vs antiparallel beta-sheets in fibrils prepared from full-length Abeta(1-40) and Abeta(34-42) peptides, respectively. Using previously published structural data based on solid-state NMR analysis, we verified the applicability of Asher's approach for the quantitative characterization of peptide conformation in the Abeta(1-40) fibril core. We found that the conformation of the parallel beta-sheet in the Abeta(1-40) fibril core is atypical for globular proteins, while in contrast, the antiparallel beta-sheet in Abeta(32-42) fibrils is a common structure in globular proteins. In contrast to the case for globular proteins, the conformations of parallel and antiparallel beta-sheets in Abeta fibril cores are substantially different, and their differences can be distinguished by DUVRR spectroscopy.

The culprit behind amyloid beta peptide related neurotoxicity in Alzheimer's disease: oligomer size or conformation?

Since the reformulation of the amyloid cascade hypothesis to focus on oligomeric aggregates of amyloid beta as the prime toxic species causing Alzheimer's disease, many researchers refocused on detecting a specific molecular assembly of defined size thatis the main trigger of Alzheimer's disease. The result has been the identification of a host of molecular assemblies containing from two up to a hundred molecules of the amyloid beta peptide, which were all found to impair memory formation in mice. This clearly demonstrates that size is insufficient to define toxicity and peptide conformation has to be taken into account. In this review we discuss the interplay between oligomer size and peptide conformation as the key determinants of the neurotoxicity of the amyloid beta peptide.

A de novo designed 11 kDa polypeptide: model for amyloidogenic intrinsically disordered proteins

A de novo polypeptide GH(6)[(GA)(3)GY(GA)(3)GE](8)GAH(6) (YE8) has a significant number of identical weakly interacting beta-strands with the turns and termini functionalized by charged amino acids to control polypeptide folding and aggregation. YE8 exists in a soluble, disordered form at neutral pH but is responsive to changes in pH and ionic strength. The evolution of YE8 secondary structure has been successfully quantified during all stages of polypeptide fibrillation by deep UV resonance Raman (DUVRR) spectroscopy combined with other morphological, structural, spectral, and tinctorial characterization. The YE8 folding kinetics at pH 3.5 are strongly dependent on polypeptide concentration with a lag phase that can be eliminated by seeding with a solution of folded fibrillar YE8. The lag phase of polypeptide folding is concentration dependent leading to the conclusion that beta-sheet folding of the 11-kDa amyloidogenic polypeptide is completely aggregation driven.

Abeta(1-40) forms five distinct amyloid structures whose beta-sheet contents and fibril stabilities are correlated

The ability of a single polypeptide sequence to grow into multiple stable amyloid fibrils sets these aggregates apart from most native globular proteins. The existence of multiple amyloid forms is the basis for strain effects in yeast prion biology, and might contribute to variations in Alzheimer's disease pathology. However, the structural basis for amyloid polymorphism is poorly understood. We report here five structurally distinct fibrillar aggregates of the Alzheimer's plaque peptide Abeta(1-40), as well as a non-fibrillar aggregate induced by Zn(2+). Each of these conformational forms exhibits a unique profile of physical properties, and all the fibrillar forms breed true in elongation reactions under a common set of growth conditions. Consistent with their defining cross-beta structure, we find that in this series the amyloid fibrils containing more extensive beta-sheet exhibit greater stability. At the same time, side chain packing outside of the beta-sheet regions contributes to stability, and to differences of stability between polymorphic forms. Stability comparison is facilitated by the unique feature that the free energy of the monomer (equivalent to the unfolded state in a protein folding reaction) does not vary, and hence can be ignored, in the comparison of DeltaG degrees of elongation values for each polymorphic fibril obtained under a single set of conditions.

Resveratrol selectively remodels soluble oligomers and fibrils of amyloid Abeta into off-pathway conformers

Misfolded proteins associated with diverse aggregation disorders assemble not only into a single toxic conformer but rather into a suite of aggregated conformers with unique biochemical properties and toxicities. To what extent small molecules can target and neutralize specific aggregated conformers is poorly understood. Therefore, we have investigated the capacity of resveratrol to recognize and remodel five conformers (monomers, soluble oligomers, non-toxic oligomers, fibrillar intermediates, and amyloid fibrils) of the Abeta1-42 peptide associated with Alzheimer disease. We find that resveratrol selectively remodels three of these conformers (soluble oligomers, fibrillar intermediates, and amyloid fibrils) into an alternative aggregated species that is non-toxic, high molecular weight, and unstructured. Surprisingly, resveratrol does not remodel non-toxic oligomers or accelerate Abeta monomer aggregation despite that both conformers possess random coil secondary structures indistinguishable from soluble oligomers and significantly different from their beta-sheet rich, fibrillar counterparts. We expect that resveratrol and other small molecules with similar conformational specificity will aid in illuminating the conformational epitopes responsible for Abeta-mediated toxicity.

Structural conversion of neurotoxic amyloid-beta(1-42) oligomers to fibrils

The amyloid-beta(1-42) (Abeta42) peptide rapidly aggregates to form oligomers, protofibils and fibrils en route to the deposition of amyloid plaques associated with Alzheimer's disease. We show that low-temperature and low-salt conditions can stabilize disc-shaped oligomers (pentamers) that are substantially more toxic to mouse cortical neurons than protofibrils and fibrils. We find that these neurotoxic oligomers do not have the beta-sheet structure characteristic of fibrils. Rather, the oligomers are composed of loosely aggregated strands whose C termini are protected from solvent exchange and which have a turn conformation, placing Phe19 in contact with Leu34. On the basis of NMR spectroscopy, we show that the structural conversion of Abeta42 oligomers to fibrils involves the association of these loosely aggregated strands into beta-sheets whose individual beta-strands polymerize in a parallel, in-register orientation and are staggered at an intermonomer contact between Gln15 and Gly37.

Stacked sets of parallel, in-register beta-strands of beta2-microglobulin in amyloid fibrils revealed by site-directed spin labeling and chemical labeling

β₂-microglobulin (β₂m) is a 99-residue protein with an immunoglobulin fold that forms β-sheet-rich amyloid fibrils in dialysis-related amyloidosis. Here the environment and accessibility of side chains within amyloid fibrils formed in vitro from β₂m with a long straight morphology are probed by site-directed spin labeling and accessibility to modification with N-ethyl maleimide using 19 site-specific cysteine variants. Continuous wave electron paramagnetic resonance spectroscopy of these fibrils reveals a core predominantly organized in a parallel, in-register arrangement, by contrast with other β₂m aggregates. A continuous array of parallel, in-register β-strands involving most of the polypeptide sequence is inconsistent with the cryoelectron microscopy structure, which reveals an architecture based on subunit repeats. To reconcile these data, the number of spins in close proximity required to give rise to spin exchange was determined. Systematic studies of a model protein system indicated that juxtaposition of four spin labels is sufficient to generate exchange narrowing. Combined with information about side-chain mobility and accessibility, we propose that the amyloid fibrils of β₂m consist of about six β₂m monomers organized in stacks with a parallel, in-register array. The results suggest an organization more complex than the accordion-like β-sandwich structure commonly proposed for amyloid fibrils.

Exploration of the mechanism for LPFFD inhibiting the formation of beta-sheet conformation of A beta(1-42) in water

The main component of senile plaques found in AD brain is amyloid beta-peptide (A beta), and the neurotoxicity and aggregation of A beta are associated with the formation of beta-sheet structure. Experimentally, beta sheet breaker (BSB) peptide fragment Leu-Pro-Phe-Phe-Asp (LPFFD) can combine with A beta, which can inhibit the aggregation of A beta. In order to explore why LPFFD can inhibit the formation of beta-sheet conformation of A beta at atomic level, first, molecular docking is performed to obtain the binding sites of LPFFD on the A beta(1-42) (LPFFD/A beta(1-42)), which is taken as the initial conformation for MD simulations. Then, MD simulations on LPFFD/A beta(1-42) in water are carried out. The results demonstrate that LPFFD can inhibit the conformational transition from alpha-helix to beta-sheet structure for the C-terminus of A beta(1-42), which may be attributed to the hydrophobicity decreasing of C-terminus residues of A beta(1-42) and formation probability decreasing of the salt bridge Asp23-Lys28 in the presence of LPFFD.

Fibrillar oligomers nucleate the oligomerization of monomeric amyloid beta but do not seed fibril formation

Soluble amyloid oligomers are potent neurotoxins that are involved in a wide range of human degenerative diseases, including Alzheimer disease. In Alzheimer disease, amyloid beta (Abeta) oligomers bind to neuronal synapses, inhibit long term potentiation, and induce cell death. Recent evidence indicates that several immunologically distinct structural variants exist as follows: prefibrillar oligomers (PFOs), fibrillar oligomers (FOs), and annular protofibrils. Despite widespread interest, amyloid oligomers are poorly characterized in terms of structural differences and pathological significance. FOs are immunologically related to fibrils because they react with OC, a conformation-dependent, fibril-specific antibody and do not react with antibodies specific for other types of oligomers. However, fibrillar oligomers are much smaller than fibrils. FOs are soluble at 100,000 x g, rich in beta-sheet structures, but yet bind weakly to thioflavin T. EPR spectroscopy indicates that FOs display significantly more spin-spin interaction at multiple labeled sites than PFOs and are more structurally similar to fibrils. Atomic force microscopy indicates that FOs are approximately one-half to one-third the height of mature fibrils. We found that Abeta FOs do not seed the formation of thioflavin T-positive fibrils from Abeta monomers but instead seed the formation of FOs from Abeta monomers that are positive for the OC anti-fibril antibody. These results indicate that the lattice of FOs is distinct from the fibril lattice even though the polypeptide chains are organized in an immunologically identical conformation. The FOs resulting from seeded reactions have the same dimensions and morphology as the initial seeds, suggesting that the seeds replicate by growing to a limiting size and then splitting, indicating that their lattice is less stable than fibrils. We suggest that FOs may represent small pieces of single fibril protofilament and that the addition of monomers to the ends of FOs is kinetically more favorable than the assembly of the oligomers into fibrils via sheet stacking interaction. These studies provide novel structural insight into the relationship between fibrils and FOs and suggest that the increased toxicity of FOs may be due to their ability to replicate and the exposure of hydrophobic sheet surfaces that are otherwise obscured by sheet-sheet interactions between protofilaments in a fibril.

Monitoring Alzheimer Amyloid Peptide Aggregation by EPR

Plaques containing the aggregated beta-Amyloid (Abeta) peptide in the brain are the main indicators of Alzheimer's disease. Fibrils, the building blocks of plaques, can also be produced in vitro and consist of a regular arrangement of the peptide. The initial steps of fibril formation are not well understood and could involve smaller aggregates (oligomers) of Abeta. Such oligomers have even been implicated as the toxic agents. Here, a method to study oligomers on the time scale of aggregation is suggested. We have labeled the 40 residue Abeta peptide variant containing an N-terminal cysteine (cys-Abeta) with the MTSL [1-oxyl-2,2,5,5-tetramethyl-Delta-pyrroline-3-methyl] methanethiosulfonate spin label (SL-Abeta). Fibril formation in solutions of pure SL-Abeta and of SL-Abeta mixed with Abeta was shown by Congo-red binding and electron microscopy. Continuous-wave 9 GHz electron paramagnetic resonance reveals three fractions of different spin-label mobility: one attributed to monomeric Abeta, one to a multimer (8-15 monomers), and the last one to larger aggregates or fibrils. The approach, in principle, allows detection of oligomers on the time scale of aggregation.

Annexin A5 directly interacts with amyloidogenic proteins and reduces their toxicity

Protein misfolding is a central mechanism for the development of neurodegenerative diseases and type 2 diabetes mellitus. The accumulation of misfolded alpha-synuclein protein inclusions in the Lewy bodies of Parkinson's disease is thought to play a key role in pathogenesis and disease progression. Similarly, the misfolding of the beta-cell hormone human islet amyloid polypeptide (h-IAPP) into toxic oligomers plays a central role in the induction of beta-cell apoptosis in the context of type 2 diabetes. In this study, we show that annexin A5 plays a role in interacting with and reducing the toxicity of the amyloidogenic proteins, h-IAPP and alpha-synuclein. We find that annexin A5 is coexpressed in human beta-cells and that exogenous annexin A5 reduces the level of h-IAPP-induced apoptosis in human islets by approximately 50% and in rodent beta-cells by approximately 90%. Experiments with transgenic expression of alpha-synuclein in Caenorhabditis elegans show that annexin A5 reduces alpha-synuclein inclusions in vivo. Using thioflavin T fluorescence, electron microscopy, and electron paramagnetic resonance, we provide evidence that substoichiometric amounts of annexin A5 inhibit h-IAPP and alpha-synuclein misfolding and fibril formation. We conclude that annexin A5 might act as a molecular safeguard against the formation of toxic amyloid aggregates.

Comparison of Alzheimer Abeta(1-40) and Abeta(1-42) amyloid fibrils reveals similar protofilament structures

We performed mass-per-length (MPL) measurements and electron cryomicroscopy (cryo-EM) with 3D reconstruction on an Abeta(1-42) amyloid fibril morphology formed under physiological pH conditions. The data show that the examined Abeta(1-42) fibril morphology has only one protofilament, although two protofilaments were observed with a previously studied Abeta(1-40) fibril. The latter fibril was resolved at 8 A resolution showing pairs of beta-sheets at the cores of the two protofilaments making up a fibril. Detailed comparison of the Abeta(1-42) and Abeta(1-40) fibril structures reveals that they share an axial twofold symmetry and a similar protofilament structure. Furthermore, the MPL data indicate that the protofilaments of the examined Abeta(1-40) and Abeta(1-42) fibrils have the same number of Abeta molecules per cross-beta repeat. Based on this data and the previously studied Abeta(1-40) fibril structure, we describe a model for the arrangement of peptides within the Abeta(1-42) fibril.

Influence of residue 22 on the folding, aggregation profile, and toxicity of the Alzheimer's amyloid beta peptide

Several biophysical techniques have been used to determine differences in the aggregation profile (i.e., the secondary structure, aggregation propensity, dynamics, and morphology of amyloid structures) and the effects on cell viability of three variants of the amyloid beta peptide involved in Alzheimer's disease. We focused our study on the Glu22 residue, comparing the effects of freshly prepared samples and samples aged for at least 20 days. In the aged samples, a high propensity for aggregation and beta-sheet secondary structure appears when residue 22 is capable of establishing polar (Glu22 in wild-type) or hydrophobic (Val22 in E22V) interactions. The Arctic variant (E22G) presents a mixture of mostly disordered and alpha-helix structures (with low beta-sheet contribution). Analysis of transmission electron micrographs and atomic force microscopy images of the peptide variants after aging showed significant quantitative and qualitative differences in the morphology of the formed aggregates. The effect on human neuroblastoma cells of these Abeta(12-28) variants does not correlate with the amount of beta-sheet of the aggregates. In samples allowed to age, the native sequence was found to have an insignificant effect on cell viability, whereas the Arctic variant (E22G), the E22V variant, and the slightly-aggregating control (F19G-F20G) had more prominent effects.

Structural disorder in amyloid fibrils: its implication in dynamic interactions of proteins

Proteins are occasionally converted from their normal soluble state to highly ordered fibrillar aggregates (amyloids), which give rise to pathological conditions that range from neurodegenerative disorders to systemic amyloidoses. Recent methodological advances in solid-state NMR and EPR spectroscopy have enabled determination of the 3D structure of several amyloids at residue-level resolution. The general picture that emerges is that amyloids constitute parallel beta sheets, in which individual polypeptide chains run roughly perpendicular to the major axis of the fibril and are stacked in-register. Thus, the unifying theme of amyloid formation is the structural transition from an initial globular or intrinsically disordered state to a highly ordered regular form. In this minireview, we show that this description is somewhat oversimplified, because part of the polypeptide chain in the amyloid remains intrinsically disordered and does not become part of the ordered core. As demonstrated through examples such as the amyloids of alpha-synuclein and Abeta peptide and the yeast prions HET-s and Ure2p, these disordered segments are depleted in amino acids NQFYV and are enriched in DEKP. They are also significantly more charged and have a higher predicted disordered value than segments in the cross-beta core. We suggest that structural disorder in amyloid is a special case of 'fuzziness', i.e. disorder in the bound state that may serve different functions, such as the accommodation of destabilizing residues and the mediation of secondary interactions between protofibrils.

Probing the effect of amino-terminal truncation for Abeta1-40 peptides

We examine the effect of deletion of the amino-terminal (residues 1-9) on the structure and energetics of Abeta1-40 peptides. To this end, we use replica exchange molecular dynamics to compare the conformational ensembles of Abeta1-40 and amino-truncated Abeta10-40 monomers and dimers. Overall, the deletion of the amino-terminal appears to cause minor structural and energetic changes in Abeta monomers and dimers. More specifically, our findings are as follows: (1) there is a small but discernible conversion of beta-strand structure into helix upon amino-terminal deletion, (2) secondary structure changes due to truncation are caused by missing side chain interactions formed by the amino-terminal, and (3) the amino-terminal together with the central sequence region (residues 10-23) represents the primary aggregation interface in Abeta1-40 dimers. The amino-truncated Abeta10-40 retains this aggregation interface, which is reduced to the central sequence region. We argue that the analysis of available experimental data supports our conclusions. Our findings also suggest that amino-truncated Abeta10-40 peptide is an adequate model for studying Abeta1-40 aggregation.

Antiparallel beta-sheet: a signature structure of the oligomeric amyloid beta-peptide

AD (Alzheimer's disease) is linked to Abeta (amyloid beta-peptide) misfolding. Studies demonstrate that the level of soluble Abeta oligomeric forms correlates better with the progression of the disease than the level of fibrillar forms. Conformation-dependent antibodies have been developed to detect either Abeta oligomers or fibrils, suggesting that structural differences between these forms of Abeta exist. Using conditions which yield well-defined Abeta-(1-42) oligomers or fibrils, we studied the secondary structure of these species by ATR (attenuated total reflection)-FTIR (Fourier-transform infrared) spectroscopy. Whereas fibrillar Abeta was organized in a parallel beta-sheet conformation, oligomeric Abeta displayed distinct spectral features, which were attributed to an antiparallel beta-sheet structure. We also noted striking similarities between Abeta oligomers spectra and those of bacterial outer membrane porins. We discuss our results in terms of a possible organization of the antiparallel beta-sheets in Abeta oligomers, which may be related to reported effects of these highly toxic species in the amyloid pathogenesis associated with AD.

Evidence for novel beta-sheet structures in Iowa mutant beta-amyloid fibrils

Asp23-to-Asn mutation within the coding sequence of beta-amyloid, called the Iowa mutation, is associated with early onset, familial Alzheimer's disease and cerebral amyloid angiopathy, in which patients develop neuritic plaques and massive vascular deposition predominantly of the mutant peptide. We examined the mutant peptide, D23N-Abeta40, by electron microscopy, X-ray diffraction, and solid-state NMR spectroscopy. D23N-Abeta40 forms fibrils considerably faster than the wild-type peptide (k = 3.77 x 10(-3) min(-1) and 1.07 x 10(-4) min(-1) for D23N-Abeta40 and the wild-type peptide WT-Abeta40, respectively) and without a lag phase. Electron microscopy shows that D23N-Abeta40 forms fibrils with multiple morphologies. X-ray fiber diffraction shows a cross-beta pattern, with a sharp reflection at 4.7 A and a broad reflection at 9.4 A, which is notably smaller than the value for WT-Abeta40 fibrils (10.4 A). Solid-state NMR measurements indicate molecular level polymorphism of the fibrils, with only a minority of D23N-Abeta40 fibrils containing the in-register, parallel beta-sheet structure commonly found in WT-Abeta40 fibrils and most other amyloid fibrils. Antiparallel beta-sheet structures in the majority of fibrils are indicated by measurements of intermolecular distances through (13)C-(13)C and (15)N-(13)C dipole-dipole couplings. An intriguing possibility exists that there is a relationship between the aberrant structure of D23N-Abeta40 fibrils and the unusual vasculotropic clinical picture in these patients.

The role of prefibrillar structures in the assembly of a peptide amyloid

The self-assembly of proteins into stable, fibrillar aggregates is a general property of polypeptides most notably associated with degenerative diseases termed amyloidoses. These nano- to micrometer scale structures are formed predominantly of beta-sheets that self-assemble by a nucleation-dependent mechanism. The rate-limiting step of assembly involves stabilization of high-energy intermediates in a kinetic step termed nucleation. Determination of the structural characteristics of these high-energy intermediates has been elusive, as its members are the least populated states on the assembly pathway. Using a peptide derived from diabetes-related amyloid, we use electron paramagnetic resonance (EPR) spectroscopy and disulfide crosslinking to show that fibers are composed of parallel, in-register beta-sheets. Kinetic studies are then used to infer the structural elements of the pre-nucleation intermediates. Notably, stabilization of this ensemble is shown to depend on the number but not the position of amide side chains within the primary sequence. Additionally, fiber formation is accelerated by constructs that mimic the intra-sheet structure of the fiber. Our data suggest that pre-nucleation intermediates sample intra- beta-sheet structure and place bounds on the possible nucleation mechanisms for fiber assembly. Understanding the nucleation of fibrillogenesis is critical so that this process can be prevented in disease and productively controlled by design.

Mutational analysis of the aggregation-prone and disaggregation-prone regions of acylphosphatase

We have performed an extensive mutational analysis of aggregation and disaggregation of amyloid-like protofibrils of human muscle acylphosphatase. Our findings indicate that the regions that promote aggregation in 25% (v/v) 2,2,2 trifluoroethanol (TFE) are different from those that promote disaggregation under milder conditions (5% TFE). Significant changes in the rate of disaggregation of protofibrils in 5% TFE result not only from mutations situated in the regions of the sequence that play a key role in the mechanism of aggregation in 25% TFE, but also from mutations located in other regions. In order to rationalise these results, we have used a modified version of the Zyggregator aggregation propensity prediction algorithm to take into account structural rearrangements of the protofibrils that may be induced by changes in solution conditions. Our results suggest that a wider range of residues contributes to the stability of the aggregates in addition to those that play an important kinetic role in the aggregation process. The mutational approach described here is capable of providing residue-specific information on the structure and dynamics of amyloid protofibrils under conditions close to physiological and should be widely applicable to other systems.

Amyloid beta (1-42) folding multiplicity and single-molecule binding behavior studied with STM

The fine folding and assembling characteristics of amyloid beta (Abeta) peptides are important to pharmaceutical studies of drug molecules and to the pathological analysis of neurodegenerative disorders such as Alzheimer's disease at the molecular level. Here we present observations of the multiple folding characteristics of amyloid peptide Abeta(42) lamellae using scanning tunneling microscopy. Molecularly resolved core regions of Abeta(42) hairpins and unfolded peptide assembly structures are identified. The parallel assembling characteristics of Abeta(42) hairpins can be confirmed in the study. In addition, single-molecule binding characteristics of Congo red and thioflavin T have been shown to bind at the groove regions of peptide assemblies. This study demonstrates a complementary venue for studying molecular heterogeneity of peptide assemblies, as well as the binding characteristics of molecular modulators.

Fibrils with parallel in-register structure constitute a major class of amyloid fibrils: molecular insights from electron paramagnetic resonance spectroscopy

The deposition of amyloid- and amyloid-like fibrils is the main pathological hallmark of numerous protein misfolding diseases including Alzheimer's disease, transmissible spongiform encephalopathy, and type 2 diabetes. Besides the well-established role in disease, recent work on a variety of organisms ranging from bacteria to humans suggests that amyloid fibrils can also convey biological functions. To better understand the molecular mechanisms by which amyloidogenic proteins misfold in disease or perform biological functions, structural information is essential. Although high-resolution structural analysis of amyloid fibrils has been challenging, a combination of biophysical approaches is beginning to unravel the various structural features of amyloid fibrils. Here we review these recent developments with particular emphasis on amyloid fibrils that have been studied using site-directed spin labeling and electron paramagnetic resonance spectroscopy. This approach has been used to define the precise location of fibril-forming core regions and identify local secondary structures within such core regions. Perhaps one of the most remarkable findings arrived at by site-directed spin labeling was that most fibrils that contain an extensive core region of 20 amino acids or more share a common parallel in-register arrangement of beta strands. The preference for this arrangement can be explained on topological grounds and may be rationalized by the maximization of hydrophobic contact surface.

Molecular structural basis for polymorphism in Alzheimer's beta-amyloid fibrils

We describe a full structural model for amyloid fibrils formed by the 40-residue beta-amyloid peptide associated with Alzheimer's disease (Abeta(1-40)), based on numerous constraints from solid state NMR and electron microscopy. This model applies specifically to fibrils with a periodically twisted morphology, with twist period equal to 120 +/- 20 nm (defined as the distance between apparent minima in fibril width in negatively stained transmission electron microscope images). The structure has threefold symmetry about the fibril growth axis, implied by mass-per-length data and the observation of a single set of (13)C NMR signals. Comparison with a previously reported model for Abeta(1-40) fibrils with a qualitatively different, striated ribbon morphology reveals the molecular basis for polymorphism. At the molecular level, the 2 Abeta(1-40) fibril morphologies differ in overall symmetry (twofold vs. threefold), the conformation of non-beta-strand segments, and certain quaternary contacts. Both morphologies contain in-register parallel beta-sheets, constructed from nearly the same beta-strand segments. Because twisted and striated ribbon morphologies are also observed for amyloid fibrils formed by other polypeptides, such as the amylin peptide associated with type 2 diabetes, these structural variations may have general implications.

Prion protein amyloid formation under native-like conditions involves refolding of the C-terminal alpha-helical domain

Transmissible spongiform encephalopathies are associated with conformational conversion of the cellular prion protein, PrP(C), into a proteinase K-resistant, amyloid-like aggregate, PrP(Sc). Although the structure of PrP(Sc) remains enigmatic, recent studies have afforded increasingly detailed characterization of recombinant PrP amyloid. However, all previous studies were performed using amyloid fibrils formed in the presence of denaturing agents that significantly alter the folding state(s) of the precursor monomer. Here we report that PrP amyloid can also be generated under physiologically relevant conditions, where the monomeric protein is natively folded. Remarkably, site-directed spin labeling studies reveal that these fibrils possess a beta-core structure nearly indistinguishable from that of amyloid grown under denaturing conditions, where the C-terminal alpha-helical domain of the PrP monomer undergoes major refolding to a parallel and in-register beta-structure upon conversion. The structural similarity of fibrils formed under drastically different conditions strongly suggests that the common beta-sheet architecture within the approximately 160-220 core region represents a distinct global minimum in the PrP conversion free energy landscape. We also show that the N-terminal region of fibrillar PrP displays conformational plasticity, undergoing a reversible structural transition with an apparent pK(a) of approximately 5.3. The C-terminal region, on the other hand, retains its beta-structure over the pH range 1-11, whereas more alkaline buffer conditions denature the fibrils into constituent PrP monomers. This profile of pH-dependent stability is reminiscent of the behavior of brain-derived PrP(Sc), suggesting a substantial degree of structural similarity within the beta-core region of these PrP aggregates.

Describing the structure and assembly of protein filaments by EPR spectroscopy of spin-labeled side chains

In this review we summarize our approach to the study of Intermediate Filament (IF) structure and assembly by electron paramagnetic resonance (EPR) spectroscopy of site-directed spin labels. Using vimentin, a homopolymeric type III IF protein, we demonstrate that this approach serves as a general paradigm for studying protein filament structure and assembly. These strategies will be useful in exploring the structure and assembly properties of other filamentous or aggregation-prone systems.

Structural basis of infectious and non-infectious amyloids

Amyloid fibrils are elongated protein aggregates well known for their association with many human diseases. However, similar structures have also been found in other organisms and amyloid fibrils can also be formed in vitro by other proteins usually under non-physiological conditions. In all cases, these fibrils assemble in a nucleated polymerization reaction with a pronounced lag phase that can be eliminated by supplying pre-formed fibrils as seeds. Once formed, the fibrils are usually very stable, except for their tendency to break into smaller pieces forming more growing ends in the process. These properties give amyloid fibers a self-replicating character dependent only on a source of soluble protein. For some systems and under certain circumstances this can lead to infectious protein structures, so-called prions, that can be passed from one organism to another as in the transmissible spongiform encephalopathies and in fungal prion systems. Structural details about these processes have emerged only recently, mostly on account of the inability of traditional high-resolution methods to deal with insoluble, filamentous specimens. In consequence, current models for amyloid fibrils are based on fewer constraints than common atomic-resolution structures. This review gives an overview of the constraints used for the development of amyloid models and the methods used to derive them. The principally possible structures will be introduced by discussing current models of amyloid fibrils from Alzheimer's beta-peptide, amylin and several fungal systems. The infectivity of some amyloids under specific conditions might not be due to a principal structural difference between infectious and non-infectious amyloids, but could result from an interplay of the rates for filament nucleation, growth, fragmentation, and clearance.

Amyloid fibrils: abnormal protein assembly

Amyloid refers to the abnormal fibrous, extracellular, proteinaceous deposits found in organs and tissues. Amyloid is insoluble and is structurally dominated by beta-sheet structure. Unlike other fibrous proteins it does not commonly have a structural, supportive or motility role but is associated with the pathology seen in a range of diseases known as the amyloidoses. These diseases include Alzheimer's, the spongiform encephalopathies and type II diabetes, all of which are progressive disorders with associated high morbidity and mortality. Not surprisingly, research into the physicochemical properties of amyloid and its formation is currently intensely pursued. In this chapter we will highlight the key scientific findings and discuss how the stability of amyloid fibrils impacts on bionanotechnology.