The residual structure of acid-denatured ß2 -microglobulin is relevant to an ordered fibril morphology.

ß2 -Microglobulin (ß2m) forms amyloid fibrils in vitro under acidic conditions. Under these conditions, the residual structure of acid-denatured ß2m is relevant to seeding and fibril extension processes. Disulfide (SS) bond-oxidized ß2m has been shown to form rigid, ordered fibrils, whereas SS bond-reduced ß2m forms curvy, less-ordered fibrils. These findings suggest that the presence of an SS bond affects the residual structure of the monomer, which subsequently influences the fibril morphology. To clarify this process, we herein performed NMR experiments. The results obtained revealed that oxidized ß2m contained a residual structure throughout the molecule, including the N- and C-termini, whereas the residual structure of the reduced form was localized and other regions had a random coil structure. The range of the residual structure in the oxidized form was wider than that of the fibril core. These results indicate that acid-denatured ß2m has variable conformations. Most conformations in the ensemble cannot participate in fibril formation because their core residues are hidden by residual structures. However, when hydrophobic residues are exposed, polypeptides competently form an ordered fibril. This conformational selection phase may be needed for the ordered assembly of amyloid fibrils.

Enhanced accessibility and hydrophobicity of amyloidogenic intermediates of the ß2-microglobulin D76N mutant revealed by high-pressure experiments.

ß2-Microglobulin (ß2m) is the causative protein of dialysis-related amyloidosis. Its unfolding mainly proceeds along the pathway of NC →UC ⇄ UT, whereas refolding follows the UT → IT (→NT) →NC pathway, in which N, I, and U are the native, intermediate, and unfolded states, respectively, with the Pro32 peptidyl-prolyl bond in cis or trans conformation as indicated by the subscript. It is noted that the IT state is a putative amyloidogenic precursor state. Several aggregation-prone variants of ß2m have been reported to date. One of these variants is D76N ß2m, which is a naturally occurring amyloidogenic mutant. To elucidate the molecular mechanisms contributing to the enhanced amyloidogenicity of the mutant, we investigated the equilibrium and kinetic transitions of pressure-induced folding/unfolding equilibria in the wild type and D76N mutant by monitoring intrinsic tryptophan and 1-anilino-8-naphthalene sulfonate fluorescence. An analysis of kinetic data revealed that the different folding/unfolding behaviors of the wild type and D76N mutant were due to differences in the activation energy between the unfolded and the intermediate states as well as stability of the native state, leading to more rapid accumulation of IT state for D76N in the refolding process. In addition, the IT state was found to assume more hydrophobic nature. These changes induced the enhanced amyloidogenicity of the D76N mutant and the distinct pathogenic symptoms of patients. Our results suggest that the stabilization of the native state will be an effective approach for suppressing amyloid fibril formation of this mutant.

Isoelectric point-amyloid formation of α-synuclein extends the generality of the solubility and supersaturation-limited mechanism.

Proteins in either a native or denatured conformation often aggregate at an isoelectric point (pI), a phenomenon known as pI precipitation. However, only a few studies have addressed the role of pI precipitation in amyloid formation, the crystal-like aggregation of denatured proteins. We found that α-synuclein, an intrinsically disordered protein of 140 amino acid residues associated with Parkinson's disease, formed amyloid fibrils at pI (= 4.7) under the low-sodium phosphate conditions. Although α-synuclein also formed amyloid fibrils at a wide pH range under high concentrations of sodium phosphate, the pI-amyloid formation was characterized by marked amyloid-specific thioflavin T fluorescence and clear fibrillar morphology, indicating highly ordered structures. Analysis by heteronuclear NMR in combination with principal component analysis suggested that amyloid formation under low and high phosphate conditions occurred by distinct mechanisms. The former was likely to be caused by the intermolecular attractive charge-charge interactions, where α-synuclein has +17 and -17 charges even with the zero net charge. On the other hand, the latter was caused by the phosphate-dependent salting-out effects. pI-amyloid formation may play a role in the membrane-dependent amyloid formation of α-synuclein, where the negatively charged membrane surface reduces the local pH to pI and the membrane hydrophobic environment enhances electrostatic interactions. The results extend the supersaturation-limited mechanism of amyloid formation: Amyloid fibrils are formed under a variety of conditions of decreased solubility of denatured proteins triggered by the breakdown of supersaturation.

Amyloid Formation under Complicated Conditions in Which ß2-Microglobulin Coexists with Its Proteolytic Fragments.

Amyloid formation in vivo occurs under complicated conditions in which various amyloidogenic and non-amyloidogenic components coexist, often under crowding. Controversy surrounds the role of additional components under complicated conditions. They have been suggested to accelerate amyloid formation because molecular crowding or interactions with additives increase effective concentrations and, thus, break the supersaturation of amyloidogenic proteins. On the other hand, cellular crowding conditions with various heterogeneous components may retard or prevent amyloid formation because they impede homologous amyloidogenic associations. To elucidate the roles of these additional components, we examined the amyloid formation of ß2-microglobulin (ß2m), a protein responsible for dialysis-related amyloidosis, with a simplified model system in which intact ß2m and its proteolytic peptides coexist. Among the nine proteolytic peptides of ß2m produced in vitro with lysyl endopeptidase, the 22-residue K3 peptide is highly amyloidogenic. The amyloid formation of the K3 peptide, which occurred with a lag time of 1 h at pH 2 and 37 °C, was significantly retarded by the coexistence of ß2m or a mixture of the proteolytic digests. To identify the sites of inhibitory interactions, we performed paramagnetic relaxation enhancement measurements using spin-labeled K3 and uniformly 15N-labeled ß2m with nuclear magnetic resonance detection. The results revealed that K3 interacted weakly with a broad cluster of the hydrophobic residues of ß2m, which accommodated the residues located in some distant sequence, leading to competitive inhibition. The results showed that relatively weak and broad interactions formed a nonproductive complex, implying a role for heterogeneous interactions under complicated conditions.

Heating during agitation of ß2-microglobulin reveals that supersaturation breakdown is required for amyloid fibril formation at neutral pH.

Amyloidosis-associated amyloid fibrils are formed by denatured proteins when supersaturation of denatured proteins is broken. ß2-Microglobulin (ß2m) forms amyloid fibrils and causes dialysis-related amyloidosis in patients receiving long-term hemodialysis. Although amyloid fibrils of ß2m in patients are observed at neutral pH, formation of ß2m amyloids in vitro has been difficult to discern at neutral pH because of the amyloid-resistant native structure. Here, to further understand the mechanism underlying in vivo amyloid formation, we investigated the relationship between protein folding/unfolding and misfolding leading to amyloid formation. Using thioflavin T assays, CD spectroscopy, and transmission EM analyses, we found that ß2m efficiently forms amyloid fibrils even at neutral pH by heating with agitation at high-salt conditions. We constructed temperature- and NaCl concentration-dependent conformational phase diagrams in the presence or absence of agitation, revealing how amyloid formation under neutral pH conditions is related to thermal unfolding and breakdown of supersaturation. Of note, after supersaturation breakdown and following the law of mass action, the ß2m monomer equilibrium shifted to the unfolded state, destabilizing the native state and thereby enabling amyloid formation even under physiological conditions with a low amount of unfolded precursor. The amyloid fibrils depolymerized at both lower and higher temperatures, resembling cold- or heat-induced denaturation of globular proteins. Our results suggest an important role for heating in the onset of dialysis-related amyloidosis and related amyloidoses.

Loosening of Side-Chain Packing Associated with Perturbations in Peripheral Dynamics Induced by the D76N Mutation of ß2-Microglobulin Revealed by Pressure-NMR and Molecular Dynamic Simulations.

ß2-Microglobulin (ß2m) is the causative protein of dialysis-related amyloidosis, and its D76N variant is less stable and more prone to aggregation. Since their crystal structures are indistinguishable from each other, enhanced amyloidogenicity induced by the mutation may be attributed to changes in the structural dynamics of the molecule. We examined pressure and mutation effects on the ß2m molecule by NMR and MD simulations, and found that the mutation induced the loosening of the inter-sheet packing of ß2m, which is relevant to destabilization and subsequent amyloidogenicity. On the other hand, this loosening was coupled with perturbed dynamics at some peripheral regions. The key result for this conclusion was that both the mutation and pressure induced similar reductions in the mobility of these residues, suggesting that there is a common mechanism underlying the suppression of inherent fluctuations in the ß2m molecule. Analyses of data obtained under high pressure conditions suggested that the network of dynamically correlated residues included not only the mutation site, but also distal residues, such as those of the C- and D-strands. Reductions in these local dynamics correlated with the loosening of inter-sheet packing.

Conformational Properties Relevant to the Amyloidogenicity of ß2-Microglobulin Analyzed Using Pressure- and Salt-Dependent Chemical Shift Data.

ß2-Microglobulin (ß2m) is associated with dialysis-related amyloidosis. In vitro experiments have shown that ß2m forms amyloid fibrils at acidic pHs in the presence of moderate concentrations of salt. Previous studies suggested that acid-denatured ß2m has a hydrophobic residual structure, and the exposure of the hydrophobic residues enhances the association with seeds or other ß2m monomers. However, the nature of the residual structure relevant to its amyloidogenicity remains to be investigated. To understand the structural properties of acid-denatured ß2m and the role of salt, we investigated pressure- and salt concentration-dependent conformational changes by nuclear magnetic resonance spectroscopy and other methods. Here, pressure was utilized to characterize the conformers existing in a conformational equilibrium at ambient pressure. The obtained pressure- and salt concentration-dependent chemical shift data were simultaneously subjected to principal component analysis to characterize individual conformational change events. Unexpectedly, the addition of salt induced an expansion of the ß2m molecule, which likely resulted from the exclusion of the N-terminal region from the hydrophobic cluster region. The dissected chemical shift patterns for the salt-induced conformational change and other experimental data indicated that this conformational change caused a rigidification in the intrinsic hydrophobic cluster, leading to the observed amyloidogenicity.

Heparin-dependent aggregation of hen egg white lysozyme reveals two distinct mechanisms of amyloid fibrillation.

Heparin, a biopolymer possessing high negative charge density, is known to accelerate amyloid fibrillation by various proteins. Using hen egg white lysozyme, we studied the effects of heparin on protein aggregation at low pH, raised temperature, and applied ultrasonic irradiation, conditions under which amyloid fibrillation was promoted. Heparin exhibited complex bimodal concentration-dependent effects, either accelerating or inhibiting fibrillation at pH 2.0 and 60 °C. At concentrations lower than 20 µg/ml, heparin accelerated fibrillation through transient formation of hetero-oligomeric aggregates. Between 0.1 and 10 mg/ml, heparin rapidly induced amorphous heteroaggregation with little to no accompanying fibril formation. Above 10 mg/ml, heparin again induced fibrillation after a long lag time preceded by oligomeric aggregate formation. Compared with studies performed using monovalent and divalent anions, the results suggest two distinct mechanisms of heparin-induced fibrillation. At low heparin concentrations, initial hen egg white lysozyme cluster formation and subsequent fibrillation is promoted by counter ion binding and screening of repulsive charges. At high heparin concentrations, fibrillation is caused by a combination of salting out and macromolecular crowding effects probably independent of protein net charge. Both fibrillation mechanisms compete against amorphous aggregation, producing a complex heparin concentration-dependent phase diagram. Moreover, the results suggest an active role for amorphous oligomeric aggregates in triggering fibrillation, whereby breakdown of supersaturation takes place through heterogeneous nucleation of amyloid on amorphous aggregates.

Non-Native α-Helices in the Initial Folding Intermediate Facilitate the Ordered Assembly of the ß-Barrel in ß-Lactoglobulin.

The roles of non-native α-helices frequently observed in the initial folding stage of ß-sheet proteins have been examined for many years. We herein investigated the residue-level structures of several mutants of bovine ß-lactoglobulin (ßLG) in quenched-flow pH-pulse labeling experiments. ßLG assumes a collapsed intermediate with a non-native α-helical structure (I0) in the early stage of folding, although its native form is predominantly composed of ß-structures. The protection profile in I0 of pseudo-wild type (WT*) ßLG was found to deviate from the pattern of the "average area buried upon folding" (AABUF). In particular, the level of protection at the region of strand A, at which non-native α-helices form in the I0 state, was significantly low compared to AABUF. G17E, the mutant with an increased helical propensity, showed a similar protection pattern. In contrast, the protection pattern for I0 of E44L, the mutant with an increased ß-sheet propensity, was distinct from that of WT* and resembled the AABUF pattern. Transverse relaxation measurements demonstrated that the positions of the residual structures in the unfolded states of these mutants were consistent with those of the protected residues in the respective I0 states. On the basis of the slower conversion of I0 to the native state for E44L to that for WT*, non-native α-helices facilitate the ordered assembly of the ß-barrel by preventing interactions that trap folding.

Functional conformer of c-Myb DNA-binding domain revealed by variable temperature studies.

The conformational fluctuation in the minimum DNA-binding domain of c-Myb, repeats 2 and 3 (R2R3), was studied under closely physiological conditions. A global unfolding transition, involving both the main chain and the side chains, was found to take place at the approximate temperature range 30-70 °C, with a transition temperature of approximately 50 °C. In addition, the observation of simultaneous shift change and broadening of NMR signals in both (1)H one-dimensional and (15)N/(1)H two-dimensional NMR spectra indicated the occurrence of locally fluctuating state at physiological temperature. In the wild-type protein containing a cavity in R2, the local fluctuation of R2 is more prominent than that of R3, whereas it is suppressed in the cavity-filled mutant, V103L. This indicates that the cavity in R2 contributes significantly to the conformational instability and the transition into the locally fluctuating state. For the wild-type R2R3 protein, the more dynamic conformer is estimated to be present to some extent at 37 °C and is likely beneficial for its biological function: DNA-binding. This result is in agreement with the concept of an excited-state conformer that exists in equilibrium with the dominant ground-state conformer and acts as the functional conformer of the protein. From the findings of the present study, it appears that the tandem repeats of two small domains with no disulfide bonds and with a destabilizing cavity function as the evolutionary strategy of the wide-type c-Myb DNA-binding domain to produce an appropriate fraction of the locally fluctuating state at 37 °C, which is more amenable to DNA-binding. Database: Chemical shifts and peak lists have been deposited in the Biological Magnetic Resonance Bank under entries 11584 and 11585.

Highly Collapsed Conformation of the Initial Folding Intermediates of ß-Lactoglobulin with Non-Native α-Helix.

In the folding of ß-lactoglobulin (ßLG), a predominantly ß-sheet protein, a transient intermediate possessing an excess amount of non-native α-helix is formed within a few milliseconds. To characterize the early folding dynamics of ßLG in terms of secondary structure content and compactness, we performed submillisecond-resolved circular dichroism (CD) and small-angle X-ray scattering (SAXS) measurements. Time-resolved CD after rapid dilution of urea showed non-native α-helix formation within 200µs. Time-resolved SAXS showed that the radius of gyration (R(g)) of the intermediate at 300 µs was 23.3±0.7 Å, indicating a considerable collapse from the unfolded state having R(g) of 35.1±7.1 Å. Further compaction to R(g) of 21.2±0.3 Å occurred with a time constant of 28±11 ms. Pair distribution functions showed that the intermediate at 300 µs comprises a single collapsed domain with a small fluctuating domain, which becomes more compact after the second collapse. Kinetic measurements in the presence of 2,2,2-trifluoroethanol showed that the intermediate at several milliseconds possessed an increased amount of α-helix but similar R(g) of 23.0±0.8 Å, suggesting similarity of the shape of the intermediate in different solvents. Consequently, the initial collapse occurs globally to a compact state with a small fluctuating domain irrespective of the non-native α-helical contents. The second collapse of the fluctuating domain occurs in accordance with the reported stabilization of the non-native helix around strand A. The non-native helix around strand A might facilitate the formation of long-range contacts required for the folding of ßLG.

Supersaturation-limited and Unlimited Phase Transitions Compete to Produce the Pathway Complexity in Amyloid Fibrillation.

Although amyloid fibrils and amorphous aggregates are two types of aggregates formed by denatured proteins, their relationship currently remains unclear. We used ß2-microglobulin (ß2m), a protein responsible for dialysis-related amyloidosis, to clarify the mechanism by which proteins form either amyloid fibrils or amorphous aggregates. When ultrasonication was used to accelerate the spontaneous fibrillation of ß2m at pH 2.0, the effects observed depended on ultrasonic power; although stronger ultrasonic power effectively accelerated fibrillation, excessively strong ultrasonic power decreased the amount of fibrils formed, as monitored by thioflavin T fluorescence. An analysis of the products formed indicated that excessively strong ultrasonic power generated fibrillar aggregates that retained ß-structures but without high efficiency as seeds. On the other hand, when the spontaneous fibrillation of ß2m was induced at higher concentrations of NaCl at pH 2.0 with stirring, amorphous aggregates became more dominant than amyloid fibrils. These apparent complexities in fibrillation were explained comprehensively by a competitive mechanism in which supersaturation-limited reactions competed with supersaturation-unlimited reactions. We link the kinetics of protein aggregation and a conformational phase diagram, in which supersaturation played important roles.

Effects of a reduced disulfide bond on aggregation properties of the human IgG1 CH3 domain.

Recombinant human monoclonal antibodies have become important protein-based therapeutics for the treatment of various diseases. An IgG1 molecule, which is now mainly used for antibody preparation, consists of a total of 12 immunoglobulin domains. Each domain has one disulfide bond. The CH3 domain is the C-terminal domain of the heavy chain of IgG1. The disulfide bonds of some of the CH3 domains are known to be reduced in recombinant human monoclonal antibodies. The lack of intramolecular disulfide bonds may decrease the stability and increase the aggregation propensity of an antibody molecule. To investigate the effects of a reduced disulfide bond in the CH3 domain on conformational stability and aggregation propensity, we performed several physicochemical measurements including circular dichroism, differential scanning calorimetry (DSC), and 2D NMR. DSC measurements showed that both the stability and reversibility of the reduced form were lower than those of the oxidized form. In addition, detailed analyses of the thermal denaturation data revealed that, although a dominant fraction of the reduced form retained a stable dimeric structure, some fractions assumed a less-specifically associated oligomeric state between monomers. The results of the present study revealed the characteristic aggregation properties of antibody molecules.

A common mechanism underlying amyloid fibrillation and protein crystallization revealed by the effects of ultrasonication.

Protein crystals form in supersaturated solutions via a nucleation and growth mechanism. The amyloid fibrils of denatured proteins also form via a nucleation and growth mechanism. This similarity suggests that, although protein crystals and amyloid fibrils are distinct in their morphologies, both processes can be controlled in a similar manner. It has been established that ultrasonication markedly accelerates the formation of amyloid fibrils and simultaneously breaks them down into fragmented fibrils. In this study, we investigated the effects of ultrasonication on the crystallization of hen egg white lysozyme and glucose isomerase from Streptomyces rubiginosus. Protein crystallization was monitored by light scattering, tryptophan fluorescence, and light transmittance. Repeated ultrasonic irradiations caused the crystallization of lysozyme and glucose isomerase after cycles of irradiations. The size of the ultrasonication-induced crystals was small and homogeneous, and their numbers were larger than those obtained under quiescent conditions. Switching off ultrasonic irradiation when light scattering or tryptophan fluorescence began to change resulted in the formation of larger crystals due to the suppression of the further nucleation and fractures in preformed crystals. The results indicate that protein crystallization and amyloid fibrillation are explained on the basis of a common phase diagram in which ultrasonication accelerates the formation of crystals or crystal-like amyloid fibrils as well as fragmentation of preformed crystals or fibrils.

GaInAsP/InP MZI waveguide optical isolator integrated with spot size converter.

We fabricated a waveguide optical isolator with a GaInAsP guiding layer integrated with spot size converters (SSCs) for efficient coupling to optical fibers. The isolator is constructed with a Mach-Zehnder interferometer (MZI), which is composed of multi-mode interference (MMI) couplers, as well as nonreciprocal and reciprocal phase shifters. The nonreciprocal phase shifter is constructed with a magneto-optical cladding layer directly bonded to a semiconductor guiding layer. The performance of the GaInAsP waveguide optical isolator was demonstrated with a maximum optical isolation of 28.3 dB at a wavelength of 1558 nm for the TM mode.

Principal component analysis of chemical shift perturbation data of a multiple-ligand-binding system for elucidation of respective binding mechanism.

Chemical shift perturbations (CSPs) in NMR spectra provide useful information about the interaction of a protein with its ligands. However, in a multiple-ligand-binding system, determining quantitative parameters such as a dissociation constant (K(d) ) is difficult. Here, we used a method we named CS-PCA, a principal component analysis (PCA) of chemical shift (CS) data, to analyze the interaction between bovine ß-lactoglobulin (ßLG) and 1-anilinonaphthalene-8-sulfonate (ANS), which is a multiple-ligand-binding system. The CSP on the binding of ANS involved contributions from two distinct binding sites. PCA of the titration data successfully separated the CSP pattern into contributions from each site. Docking simulations based on the separated CSP patterns provided the structures of ßLG-ANS complexes for each binding site. In addition, we determined the K(d) values as 3.42 × 10⁻4 M² and 2.51 × 10⁻³ M for Sites 1 and 2, respectively. In contrast, it was difficult to obtain reliable K(d) values for respective sites from the isothermal titration calorimetry experiments. Two ANS molecules were found to bind at Site 1 simultaneously, suggesting that the binding occurs cooperatively with a partial unfolding of the ßLG structure. On the other hand, the binding of ANS to Site 2 was a simple attachment without a significant conformational change. From the present results, CS-PCA was confirmed to provide not only the positions and the K(d) values of binding sites but also information about the binding mechanism. Thus, it is anticipated to be a general method to investigate protein-ligand interactions.

Distinguishing crystal-like amyloid fibrils and glass-like amorphous aggregates from their kinetics of formation.

Amyloid fibrils and amorphous aggregates are two types of aberrant aggregates associated with protein misfolding diseases. Although they differ in morphology, the two forms are often treated indiscriminately. ß(2)-microglobulin (ß2m), a protein responsible for dialysis-related amyloidosis, forms amyloid fibrils or amorphous aggregates depending on the NaCl concentration at pH 2.5. We compared the kinetics of their formation, which was monitored by measuring thioflavin T fluorescence, light scattering, and 8-anilino-1-naphthalenesulfonate fluorescence. Thioflavin T fluorescence specifically monitors amyloid fibrillation, whereas light scattering and 8-anilino-1-naphthalenesulfonate fluorescence monitor both amyloid fibrillation and amorphous aggregation. The amyloid fibrils formed via a nucleation-dependent mechanism in a supersaturated solution, analogous to crystallization. The lag phase of fibrillation was reduced upon agitation with stirring or ultrasonic irradiation, and disappeared by seeding with preformed fibrils. In contrast, the glass-like amorphous aggregates formed rapidly without a lag phase. Neither agitation nor seeding accelerated the amorphous aggregation. Thus, by monitoring the kinetics, we can distinguish between crystal-like amyloid fibrils and glass-like amorphous aggregates. Solubility and supersaturation will be key factors for further understanding the aberrant aggregation of proteins.

A back hydrogen exchange procedure via the acid-unfolded state for a large protein.

A deuterated protein sample is required for nuclear magnetic resonance (NMR) measurements of a large protein because severe signal broadenings occur because of the high molecular weight. The deuterated sample expressed in (2)H(2)O should subsequently be subjected to a back hydrogen exchange at amide groups. To perform the back exchange, the protein molecule is unfolded or destabilized so that internal residues become accessible to the solvent. However, the refolding yield from the destabilized or unfolded state of a large protein is usually low, leading to a dilemma in NMR measurements of large proteins. In our previous paper [Suzuki, M., et al. (2011) Biochemistry 50, 10390-10398], we suggested that an acid-denatured microbial transglutaminase (MTG) consisting of 331 amino acid residues can be recovered effectively under low-salt conditions, escaping from the aggregation-prone intermediate. Here, we demonstrate that proMTG, the pro form of MTG consisting of 376 amino acid residues, can be refolded perfectly from the acid-unfolded state under low-salt conditions, as confirmed by circular dichroism and NMR spectroscopies. By performing the same procedure with a deuterated proMTG expressed in (2)H(2)O, we observed complete back exchanges for internal residues by NMR spectroscopy. Our procedure has potential applications to the back hydrogen exchange of large proteins for NMR measurements.

The monomer-seed interaction mechanism in the formation of the ß2-microglobulin amyloid fibril clarified by solution NMR techniques.

Amyloid fibrils are proteinous aggregates associated with various diseases, including Alzheimer's disease, type II diabetes, and dialysis-related amyloidosis. It is generally thought that, during the progression of these diseases, a precursor peptide or protein assumes a partially denatured structure, which interacts with the fibril seed to change into the final amyloid form. ß2-Microglobulin (ß2m), associated with dialysis-related amyloidosis, is known to form amyloid fibrils at low pH via a partially structured state. However, the molecular mechanism by which the conformation of ß2m changes from the precursor to the final fibril structure is poorly understood. We performed various NMR experiments to characterize acid-denatured ß2m. The analysis of the transverse relaxation rates revealed that acid-denatured ß2m undergoes a structural exchange with an extensively unfolded form. The results of transferred cross-saturation experiments indicated that residues with a residual structure in the acid-denatured state are associated with the interaction with the fibril seed. Our experimental data suggest the partially structured state to be "activated" to become extensively unfolded, in which state the hydrophobic residues are exposed and associate with the seed. Our results provide general information about the extension of amyloid fibrils.

Ultrasonication-dependent acceleration of amyloid fibril formation.

Amyloid fibrils, similar to crystals, form through nucleation and growth. Because of the high free-energy barrier of nucleation, the spontaneous formation of amyloid fibrils occurs only after a long lag phase. Ultrasonication is useful for inducing amyloid nucleation and thus for forming fibrils, while the use of a microplate reader with thioflavin T fluorescence is suitable for detecting fibrils in many samples simultaneously. Combining the use of ultrasonication and microplate reader, we propose an efficient approach to studying the potential of proteins to form amyloid fibrils. With ß(2)-microglobulin, an amyloidogenic protein responsible for dialysis-related amyloidosis, fibrils formed within a few minutes at pH 2.5. Even under neutral pH conditions, fibrils formed after a lag time of 1.5 h. The results propose that fibril formation is a physical reaction that is largely limited by the high free-energy barrier, which can be effectively reduced by ultrasonication. This approach will be useful for developing a high-throughput assay of the amyloidogenicity of proteins.