Collagenous Alzheimer amyloid plaque component assembles amyloid fibrils into protease resistant aggregates

Recently, a novel plaque-associated protein, collagenous Alzheimer amyloid plaque component (CLAC), was identified in brains from patients with Alzheimer's disease. CLAC is derived from a type II transmembrane collagen precursor protein, termed CLAC-P (collagen XXV). The biological function and the contribution of CLAC to the pathogenesis of Alzheimer's disease and plaque formation are unknown. In vitro studies indicate that CLAC binds to fibrillar, but not to monomeric, amyloid beta-peptide (Abeta). Here, we examined the effects of CLAC on Abeta fibrils using assays based on turbidity, thioflavin T binding, sedimentation analysis, and electron microscopy. The incubation of CLAC with preformed Abeta fibrils led to increased turbidity, indicating that larger aggregates were formed. In support of this contention, more Abeta was sedimented in the presence of CLAC, as determined by gel electrophoresis. Moreover, electron microscopy revealed an increased amount of Abeta fibril bundles in samples incubated with CLAC. Importantly, the frequently used thioflavin T-binding assay failed to reveal these effects of CLAC. Digestion with proteinase K or trypsin showed that Abeta fibrils, incubated together with CLAC, were more resistant to proteolytic degradation. Therefore, CLAC assembles Abeta fibrils into fibril bundles that have an increased resistance to proteases. We suggest that CLAC may act in a similar way in vivo.     

CLAC binds to amyloid beta peptides through the positively charged amino acid cluster within the collagenous domain 1 and inhibits formation of amyloid fibrils

CLAC (collagenous Alzheimer amyloid plaque component) is a proteolytic fragment derived from a novel membrane-bound collagen, CLAC-P/collagen type XXV, that deposits in senile plaques associated with amyloid beta peptides (Abeta) in the brains of patients with Alzheimer's disease. We previously showed that CLAC binds to the fibrillized form of Abeta in vitro, although the mechanism and the subdomains that mediate interaction of CLAC with Abeta as well as the effect of binding of CLAC on amyloid fibril formation remain unknown. Here we show that the collagenous domain 1 of CLAC, which is rich in positively charged amino acid residues, mediates its interaction with Abeta and that this binding is mediated by an electrostatic interaction and requires formation of the triple helix structure of CLAC. The soluble form of CLAC purified from the media of cells transfected with CLAC-P inhibited fibrillization of Abeta in vitro, especially in its elongation phase. These results suggest the anti-amyloidogenic roles of CLAC in the pathophysiology of Alzheimer's disease.     

Characterization of the Alzheimer's disease-associated CLAC protein and identification of an amyloid beta-peptide-binding site

Amyloid beta-peptide (Abeta) deposition into amyloid plaques is one of the invariant neuropathological features of Alzheimer's disease. Other proteins co-deposit with Abeta in plaques, and one recently identified amyloid-associated protein is the collagen-like Alzheimer amyloid plaque component CLAC. It is not known how CLAC deposition affects Abeta plaque genesis and the progress of the disease. Here, we studied the in vitro properties of CLAC purified from a mammalian expression system. CLAC displays features characteristic of a collagen protein, e.g. it forms a partly protease-resistant triple-helical structure, exhibits an intermediate affinity for heparin, and is glycosylated. Purified CLAC was also used to investigate the interaction between CLAC and Abeta. Using a solid-phase binding assay, we show that CLAC bound with a similar affinity to aggregates formed by Abeta-(1-40) and Abeta-(1-42) and that the interaction was impaired by increasing salt concentrations. An 8-residue-long sequence located in non-collagenous domain 2 of CLAC was found to be crucial for the interaction with Abeta. These findings may be useful for future therapeutic interventions aimed at finding compounds that modulate the binding of CLAC to Abeta deposits.     

The ratio of monomeric to aggregated forms of Abeta40 and Abeta42 is an important determinant of amyloid-beta aggregation, fibrillogenesis, and toxicity

Aggregation and fibril formation of amyloid-beta (Abeta) peptides Abeta40 and Abeta42 are central events in the pathogenesis of Alzheimer disease. Previous studies have established the ratio of Abeta40 to Abeta42 as an important factor in determining the fibrillogenesis, toxicity, and pathological distribution of Abeta. To better understand the molecular basis underlying the pathologic consequences associated with alterations in the ratio of Abeta40 to Abeta42, we probed the concentration- and ratio-dependent interactions between well defined states of the two peptides at different stages of aggregation along the amyloid formation pathway. We report that monomeric Abeta40 alters the kinetic stability, solubility, and morphological properties of Abeta42 aggregates and prevents their conversion into mature fibrils. Abeta40, at approximately equimolar ratios (Abeta40/Abeta42 approximately 0.5-1), inhibits (> 50%) fibril formation by monomeric Abeta42, whereas inhibition of protofibrillar Abeta42 fibrillogenesis is achieved at lower, substoichiometric ratios (Abeta40/Abeta42 approximately 0.1). The inhibitory effect of Abeta40 on Abeta42 fibrillogenesis is reversed by the introduction of excess Abeta42 monomer. Additionally, monomeric Abeta42 and Abeta40 are constantly recycled and compete for binding to the ends of protofibrillar and fibrillar Abeta aggregates. Whereas the fibrillogenesis of both monomeric species can be seeded by fibrils composed of either peptide, Abeta42 protofibrils selectively seed the fibrillogenesis of monomeric Abeta42 but not monomeric Abeta40. Finally, we also show that the amyloidogenic propensities of different individual and mixed Abeta species correlates with their relative neuronal toxicities. These findings, which highlight specific points in the amyloid peptide equilibrium that are highly sensitive to the ratio of Abeta40 to Abeta42, carry important implications for the pathogenesis and current therapeutic strategies of Alzheimer disease.     

Characterisation of the binding of amyloid imaging tracers to rodent Abeta fibrils and rodent-human Abeta co-polymers

Despite the application of amyloid imaging agents such as PIB, SB13, and FDDNP in Alzheimer's disease (AD) patients, the successful use of these agents in transgenic mice models of AD has not been reported to date. As a first step in understanding the behaviour of these ligands in transgenic models of AD, we have investigated in a series of in vitro ligand binding assays the interaction of selected agents, including PIB, FDDNP, SB13, and BSB, with amyloid fibrils produced from rodent Abeta(1-40) (roAbeta) peptide. The data indicate that the ligand binding affinities together with the pattern and number of binding sites on the roAbeta fibrils are broadly conserved with that reported previously for human Abeta(1-40) (huAbeta) fibrils. However, characterisation of huAbeta fibrils formed in the presence of increasing amounts of roAbeta (1, 5, 10% w/w) demonstrated a dose-dependent reduction in the number of high affinity [(3)H]Me-BTA-1 binding sites such that at the highest amount of roAbeta the specific signal was reduced by approximately 95%. These studies suggest that (i) the presence of small amounts of roAbeta in huAbeta fibrils has the potential to cause subtle ultrastructural alterations in the polymers and (ii) the weak binding signal observed in vivo in the transgenic mouse models of AD may in part be due to the decreased number of high affinity binding sites on the Abeta fibrils.     

High density lipoproteins bind Abeta and apolipoprotein C-II amyloid fibrils

Disease-associated amyloid deposits contain both fibrillar and nonfibrillar components. The majority of these amyloid components originate or coexist in the bloodstream. To understand the nature of the interaction between the nonfibrillar and fibrillar components, we have developed a centrifugation method to isolate fibril binding proteins from human serum. Amyloid fibrils composed of either Abeta peptide or apolipoprotein C-II (apoC-II) cosedimented with specific serum proteins. Gel electrophoresis, mass spectrometry peptide fingerprinting, and Western analysis identified the major binding species as proteins found in HDL particles, including apoA-I, apoA-II, apoE, clusterin, and serum amyloid A. Sedimentation analysis showed that purified human HDL and recombinant apoA-I lipid particles bound directly to Abeta and apoC-II amyloid fibrils. These studies reveal a novel function of HDL that may contribute to the well-established protective effect of this lipoprotein class in heart disease.     

An atomic model for the pleated beta-sheet structure of Abeta amyloid protofilaments.

Synchrotron x-ray studies on amyloid fibrils have suggested that the stacked pleated beta-sheets are twisted so that a repeating unit of 24 beta-strands forms a helical turn around the fibril axis (. J. Mol. Biol. 273:729-739). Based on this morphological study, we have constructed an atomic model for the twisted pleated beta-sheet of human Abeta amyloid protofilament. In the model, 48 monomers of Abeta 12-42 stack (four per layer) to form a helical turn of beta-sheet. Each monomer is in an antiparallel beta-sheet conformation with a turn located at residues 25-28. Residues 17-21 and 31-36 form a hydrophobic core along the fibril axis. The hydrophobic core should play a critical role in initializing Abeta aggregation and in stabilizing the aggregates. The model was tested using molecular dynamics simulations in explicit aqueous solution, with the particle mesh Ewald (PME) method employed to accommodate long-range electrostatic forces. Based on the molecular dynamics simulations, we hypothesize that an isolated protofilament, if it exists, may not be twisted, as it appears to be when in the fibril environment. The twisted nature of the protofilaments in amyloid fibrils is likely the result of stabilizing packing interactions of the protofilaments. The model also provides a binding mode for Congo red on Abeta amyloid fibrils. The model may be useful for the design of Abeta aggregation inhibitors.     

Abeta40 protects non-toxic Abeta42 monomer from aggregation

Abeta40 and Abeta42 are the predominant Abeta species in the human body. Toxic Abeta42 oligomers and fibrils are believed to play a key role in causing Alzheimer's disease (AD). However, the role of Abeta40 in AD pathogenesis is not well established. Emerging evidence indicates a protective role for Abeta40 in AD pathogenesis. Although Abeta40 is known to inhibit Abeta42 fibril formation, it is not clear whether the inhibition acts on the non-toxic monomer or acts on the toxic Abeta42 oligomers. In contrast to conventional methods that detect the appearance of fibrils, in our study Abeta42 aggregation was monitored by the decreasing NMR signals from Abeta42 monomers. In addition, differential NMR isotope labelling enabled the selective observation of Abeta42 aggregation in a mixture of Abeta42 and Abeta40. We found Abeta40 monomers inhibit the aggregation of non-toxic Abeta42 monomers, in an Abeta42/Abeta40 ratio-dependent manner. NMR titration revealed that Abeta40 monomers bind to Abeta42 aggregates with higher affinity than Abeta42 monomers. Abeta40 can also release Abeta42 monomers from Abeta42 aggregates. Thus, Abeta40 likely protects Abeta42 monomers by competing for the binding sites on pre-existing Abeta42 aggregates. Combining our data with growing evidence from transgenic mice and human genetics, we propose that Abeta40 plays a critical, protective role in Alzheimer's by inhibiting the aggregation of Abeta42 monomer. Abeta40 itself, a peptide already present in the human body, may therefore be useful for AD prevention and therapy.     

Early synergy between Abeta42 and oxidatively damaged membranes in promoting amyloid fibril formation by Abeta40

Oxidative lipid membrane damage is known to promote the misfolding of Abeta42 into pathological beta structure. In fully developed senile plaques of Alzheimer's disease, however, it is the shorter and more soluble amyloid beta protein, Abeta40, that predominates. To investigate the role of oxidative membrane damage in the misfolding of Abeta40, we have examined its interaction with supported lipid monolayer membranes using internal reflection infrared spectroscopy. Oxidatively damaged lipids modestly increased Abeta40 accumulation, with adsorption kinetics and a conformation that are distinct from that of Abeta42. In stark contrast, pretreatment of oxidatively damaged monolayer membranes with Abeta42 vigorously promoted Abeta40 accumulation and misfolding. Pretreatment of saturated or undamaged membranes with Abeta42 had no such effect. Parallel studies of lipid bilayer vesicles using a dye binding assay to detect fibril formation and electron microscopy to examine morphology demonstrated that Abeta42 pretreatment of oxidatively damaged membranes promoted the formation of mature Abeta40 amyloid fibrils. We conclude that oxidative membrane damage and Abeta42 act synergistically at an early stage to promote fibril formation by Abeta40. This synergy could be detected within minutes using internal reflection spectroscopy, whereas a dye-binding assay required several days and much higher protein concentrations to demonstrate this synergy.     

Structure and orientation of peptide inhibitors bound to beta-amyloid fibrils

Polymerization of the soluble beta-amyloid peptide into highly ordered fibrils is hypothesized to be a causative event in the development of Alzheimer's disease. Understanding the interactions of Abeta with inhibitors on an atomic level is fundamental for the development of diagnostics and therapeutic approaches, and can provide, in addition, important indirect information of the amyloid fibril structure. We have shown recently that trRDCs can be measured in solution state NMR for peptide ligands binding weakly to amyloid fibrils. We present here the structures for two inhibitor peptides, LPFFD and DPFFL, and their structural models bound to fibrillar Abeta(14-23) and Abeta(1-40) based on transferred nuclear Overhauser effect (trNOE) and transferred residual dipolar coupling (trRDC) data. In a first step, the inhibitor peptide structure is calculated on the basis of trNOE data; the trRDC data are then validated on the basis of the trNOE-derived structure using the program PALES. The orientation of the peptide inhibitors with respect to Abeta fibrils is obtained from trRDC data, assuming that Abeta fibrils orient such that the fibril axis is aligned in parallel with the magnetic field. The trRDC-derived alignment tensor of the peptide ligand is then used as a restraint for molecular dynamics docking studies. We find that the structure with the lowest rmsd value is in agreement with a model in which the inhibitor peptide binds to the long side of an amyloid fibril. Especially, we detect interactions involving the hydrophobic core, residues K16 and E22/D23 of the Abeta sequence. Structural differences are observed for binding of the inhibitor peptide to Abeta14-23 and Abeta1-40 fibrils, respectively, indicating different fibril structure. We expect this approach to be useful in the rational design of amyloid ligands with improved binding characteristics.     

Direct observation of Abeta amyloid fibril growth and inhibition

Amyloid fibril formation is a phenomenon common to many proteins and peptides, including amyloid beta (Abeta) peptide associated with Alzheimer's disease. To clarify the mechanism of fibril formation and to create inhibitors, real-time monitoring of fibril growth is essential. Here, seed-dependent amyloid fibril growth of Abeta(1-40) was visualized in real-time at the single fibril level using total internal reflection fluorescence microscopy (TIRFM) combined with the binding of thioflavin T, an amyloid-specific fluorescence dye. The clear image and remarkable length of the fibrils enabled an exact analysis of the rate of growth of individual fibrils, indicating that the fibril growth was a highly cooperative process extending the fibril ends at a constant rate. It has been known that Abeta amyloid formation is a stereospecific reaction and the stability is affected by l/d-amino acid replacement. Focusing on these aspects, we designed several analogues of Abeta(25-35), a cytotoxic fragment of Abeta(1-40), consisting of l and d-amino acid residues, and examined their inhibitory effects by TIRFM. Some chimeric Abeta(25-35) peptides inhibited the fibril growth of Abeta(25-35) strongly, although they could not inhibit the growth of Abeta(1-40). The results suggest that a more rational design of stereospecific inhibitors, combined with real-time monitoring of fibril growth, will be useful to invent a potent inhibitor preventing the amyloid fibril growth of Abeta(1-40) and other proteins.     

Human plasma contains cross-reactive Abeta conformer-specific IgG antibodies

Two conformers of aggregated Abeta, i.e., fibrils and oligomers, have been deemed important in the pathogenesis of Alzheimer's disease. We now report that intravenous immune globulin (IVIG) derived from pools of human plasma contains IgGs that recognize conformational epitopes present on fibrils and oligomers, but not their soluble monomeric precursor. We have used affinity chromatography to isolate these antibodies and have shown that they cross-reacted with comparable nanomolar avidity with both types of Abeta aggregates; notably, binding was not inhibited by soluble Abeta monomers. Our studies provide further support for investigating the therapeutic use of IVIG in Alzheimer's disease.     

Structural differences in Abeta amyloid protofibrils and fibrils mapped by hydrogen exchange--mass spectrometry with on-line proteolytic fragmentation

We report here structural differences between Abeta(1-40) protofibrils and mature amyloid fibrils associated with Alzheimer's disease as determined using hydrogen-deuterium exchange-mass spectrometry (HX-MS) coupled with on-line proteolysis. Specifically, we have identified regions of the Abeta(1-40) peptide containing backbone amide hydrogen atoms that are protected from HX or exposed when this peptide is incorporated into protofibrils or amyloid fibrils formed in phosphate-buffered saline without stirring at 37 degrees C. Study of protofibrils was facilitated by use of the protofibril-stabilizing agent calmidazolium chloride. Our data clearly show that both the C-terminal segment 35-40 and the N-terminal segment 1-19 are highly exposed to HX in both fibrils and protofibrils. In contrast, the internal fragment 20-34 is highly protected from exchange in fibrils but much less so in protofibrils. The data suggest that the beta-sheet elements comprising the amyloid fibril are already present in protofibrils, but that they are expanded into some adjacent residues upon the formation of mature amyloid. The N-terminal approximately ten residues appear to be unstructured in both protofibrils and fibrils. The 20-30 segment of Abeta(1-40) is more ordered in fibrils than in protofibrils, suggesting that, if protofibrils are a mechanistic precursor of fibrils, the transition from protofibril to fibril involves substantial ordering of this region of the Abeta peptide.     

Surface structure of amyloid-beta fibrils contributes to cytotoxicity

Amyloid beta (Abeta) toxicity has been hypothesized to initiate the pathogenesis of Alzheimer's disease (AD). The characteristic fibrillar morphology of Abeta-aggregates, that constitute the main components of senile plaque, has long been considered to account for the neurotoxicity. But recent reports argue against a primary role for mature fibrils in AD pathogenesis because of the lack of a robust correlation between the severity of neurological impairment and the extent of amyloid deposition. Toxicity from the soluble prefibrillar intermediate entity of aggregates often called oligomer has recently proposed a plausible explanation for this inconsistency. An alternative explanation is based on the observation that certain amyloid fibril morphologies are more toxic than others, indicating that not all amyloid fibrils are equally toxic. Here, we report that it is not only the beta-sheeted fibrillar structure but also the surface physicochemical composition that affects the toxicity of Abeta fibrils. For the first time, colloidal gold was used to visualize by electron microscopy positive-charge clusters on Abeta fibrils. Chemical modifications as well as point-mutated Abeta synthesis techniques were applied to change the surface structures of Abeta and to show how local structure affects surface properties that are responsible for electrostatic and hydrophobic interactions with cells. We also report that covering the surface of Abeta fibers with myelin basic protein, which has surface properties contrary to those of Abeta, suppresses Abeta toxicity. On the basis of these results, we propose that the surface structure of Abeta fibrils plays an important role in Abeta toxicity.     

Inhibitors of amyloid toxicity based on beta-sheet packing of Abeta40 and Abeta42

Amyloid fibrils associated with Alzheimer's disease and a wide range of other neurodegenerative diseases have a cross beta-sheet structure, where main chain hydrogen bonding occurs between beta-strands in the direction of the fibril axis. The surface of the beta-sheet has pronounced ridges and grooves when the individual beta-strands have a parallel orientation and the amino acids are in-register with one another. Here we show that in Abeta amyloid fibrils, Met35 packs against Gly33 in the C-terminus of Abeta40 and against Gly37 in the C-terminus of Abeta42. These packing interactions suggest that the protofilament subunits are displaced relative to one another in the Abeta40 and Abeta42 fibril structures. We take advantage of this corrugated structure to design a new class of inhibitors that prevent fibril formation by placing alternating glycine and aromatic residues on one face of a beta-strand. We show that peptide inhibitors based on a GxFxGxF framework disrupt sheet-to-sheet packing and inhibit the formation of mature Abeta fibrils as assayed by thioflavin T fluorescence, electron microscopy, and solid-state NMR spectroscopy. The alternating large and small amino acids in the GxFxGxF sequence are complementary to the corresponding amino acids in the IxGxMxG motif found in the C-terminal sequence of Abeta40 and Abeta42. Importantly, the designed peptide inhibitors significantly reduce the toxicity induced by Abeta42 on cultured rat cortical neurons.     

Abeta protofibrils possess a stable core structure resistant to hydrogen exchange

Protofibrils are transient structures observed during in vitro formation of mature amyloid fibrils and have been implicated as the toxic species responsible for cell dysfunction and neuronal loss in Alzheimer's disease (AD) and other protein aggregation diseases. To better understand the roles of protofibrils in amyloid assembly and Alzheimer's disease, we characterized secondary structural features of these heterogeneous and metastable assembly intermediates. We chromatographically isolated different size populations of protofibrils from amyloid assembly reactions of Abeta(1-40), both wild type and the Arctic variant associated with early onset familial AD, and exposed them to hydrogen-deuterium exchange analysis monitored by mass spectrometry (HX-MS). We show that HX-MS can distinguish among unstructured monomer, protofibrils, and fibrils by their different protection patterns. We find that about 40% of the backbone amide hydrogens of Abeta protofibrils are highly resistant to exchange with deuterium even after 2 days of incubation in aqueous deuterated buffer, implying a very stable, presumably H-bonded, core structure. This is in contrast to mature amyloid fibrils, whose equally stable structure protects about 60% of the backbone amide hydrogens over the same time frame. We also find a surprising degree of specificity in amyloid assembly, in that wild type Abeta is preferentially excluded from both protofibrils and fibrils grown from an equimolar mixture of wild type and Arctic mutant peptides. These and other data are interpreted and discussed in terms of the role of protofibrils in fibril assembly and in disease.     

Molecular modeling of the core of Abeta amyloid fibrils

Amyloid fibrils, a key pathological feature of Alzheimer's disease (AD) and other amyloidosis implicated in neurodegeneration, have a characteristic cross-beta structure. Here we present a structural model for the core of amyloid fibrils formed by the Abeta peptide using computational approaches and experimental data. Abeta(15-36) was threaded against the parallel beta-helical proteins. Our multi-layer model was constructed using the top scoring template 1lxa, a left-handed parallel beta-helical protein. This six-rung helical model has in-register repeats of the Abeta(15-36) sequence. Each rung has three beta-strands separated by two turns. The model was tested using molecular dynamics simulations in explicit water, and is in good agreement with a number of experimental observations. In addition, a model based on right-handed helical proteins is also described. The core structural model described here might serve as the building block of the Abeta(1-40) amyloid fibril as well as some other amyloid fibrils.     

Structural studies of Alzheimer's disease Abeta peptide oligomers

Amyloid beta peptide is recognized as the main constituent of the extracellular amyloid plaques, the major neuropathological hallmark of Alzheimer's disease. Abeta is a small peptide constitutively expressed in normal cells, not toxic in the monomeric form but aggregated Abeta is assumed to be the main if not the only factor causing Alzheimer's disease. Interestingly, the new reports suggest neurotoxicity of soluble Abeta oligomers rather than amyloid fibrils. Because of the fact that fibrils were thought to be the main toxic species in AD, early structural studies focused on fibrils themselves and Abeta monomers, as their building blocks while there is practically no data on oligomer structure and mechanism of neurotoxicity. Using a model peptide spanning residues 10–30 of Abeta, obtained by overexpression in bacteria, we have employed mass spectrometry of noncovalent complexes and disulfide rearrangement assay to gain new insight into structure and dynamics of a prenucleation step of Abeta peptide oligomerisation.     

CLAC: a novel Alzheimer amyloid plaque component derived from a transmembrane precursor, CLAC-P/collagen type XXV

We raised monoclonal antibodies against senile plaque (SP) amyloid and obtained a clone 9D2, which labeled amyloid fibrils in SPs and reacted with approximately 50/100 kDa polypeptides in Alzheimer's disease (AD) brains. We purified the 9D2 antigens and cloned a cDNA encoding its precursor, which was a novel type II transmembrane protein specifically expressed in neurons. This precursor harbored three collagen-like Gly-X-Y repeat motifs and was partially homologous to collagen type XIII. Thus, we named the 9D2 antigen as CLAC (collagen-like Alzheimer amyloid plaque component), and its precursor as CLAC-P/collagen type XXV. The extracellular domain of CLAC-P/collagen type XXV was secreted by furin convertase, and the N-terminus of CLAC deposited in AD brains was pyroglutamate modified. Both secreted and membrane-tethered forms of CLAC-P/collagen type XXV specifically bound to fibrillized Abeta, implicating these proteins in beta-amyloidogenesis and neuronal degeneration in AD.     

Distinct early folding and aggregation properties of Alzheimer amyloid-beta peptides Abeta40 and Abeta42: stable trimer or tetramer formation by Abeta42

The amyloid beta peptide (Abeta), composed of 40 or 42 amino acids, is a critical component in the etiology of the neurodegenerative Alzheimer disease. Abeta is prone to aggregate and forms amyloid fibrils progressively both in vitro and in vivo. To understand the process of amyloidogenesis, it is pivotal to examine the initial stages of the folding process. We examined the equilibrium folding properties, assembly states, and stabilities of the early folding stages of Abeta40 and Abeta42 prior to fibril formation. We found that Abeta40 and Abeta42 have different conformations and assembly states upon refolding from their unfolded ensembles. Abeta40 is predominantly an unstable and collapsed monomeric species, whereas Abeta42 populates a stable structured trimeric or tetrameric species at concentrations above approximately 12.5 microm. Thermodynamic analysis showed that the free energies of Abeta40 monomer and Abeta42 trimer/tetramer are approximately 1.1 and approximately 15/ approximately 22 kcal/mol, respectively. The early aggregation stages of Abeta40 and Abeta42 contain different solvent-exposed hydrophobic surfaces that are located at the sequences flanking its protease-resistant segment. The amyloidogenic folded structure of Abeta is important for the formation of spherical beta oligomeric species. However, beta oligomers are not an obligatory intermediate in the process of fibril formation because oligomerization is inhibited at concentrations of urea that have no effect on fibril formation. The distinct initial folding properties of Abeta40 and Abeta42 may play an important role in the higher aggregation potential and pathological significance of Abeta42.