Association of thin filaments into thick filaments revealing the structural hierarchy of amyloid fibrils

Beta2-Microglobulin (beta2-m) is a major structural component of dialysis-related amyloid fibrils. Kozhukh et al. [J. Biol. Chem. 277 (2002) 1310] prepared a series of peptide fragments of beta2-m by the protease digestion and examined their ability to form amyloid fibrils in citrate buffer at pH 2.5. Among various peptides, a 22-residue K3 peptide corresponding to Ser20-Lys41 spontaneously formed amyloid fibrils in aqueous solution. This peptide also formed amyloid protofibrils in 20% (v/v) 2,2,2-trifluoroethanol (TFE). To investigate the influence of solvent conditions on fibril formation, we studied their structures by atomic force microscopy. In aqueous solution, fibrils had a diameter of 4 or 8 nm and tended to cluster each other. On the other hand, protofibrils in 20% (v/v) TFE had a diameter of 2 nm with no tendency of clustering. Intriguingly, when the K3 protofibrils were transferred from 20% (v/v) TFE to aqueous solution, some of them associated to form thicker fibrils with a diameter of 4-15 nm and a left-handed helical twist. TFE is a hydrophobic solvent, so that hydrophobic interactions between molecules may be weakened. The results suggest that the fibrils in aqueous conditions are formed by the cooperative association of protofibrils at the growing ends of the fibrils, in which hydrophobic interactions play a major role.     

Amyloid fibril formation of the mouse V(L) domain at acidic pH

The recombinant V(L) domain that represents the variable part of the light chain (type kappa) of mouse monoclonal antibody F11 directed against human spleen ferritin was found to form amyloid fibrils at acidic pH as evidenced by electron microscopy, thioflavin T binding, and apple-green birefringence after Congo red staining. This is the first demonstration of amyloid fibril formation of the mouse V(L) domain. To understand the mechanism of acidic pH-induced amyloid fibril formation, conformational changes of the V(L) domain were studied by one-dimensional NMR, differential scanning calorimetry, analytical ultracentrifugation, hydrophobic dye binding, far-UV circular dichroism, and tryptophan fluorescence. The results indicated accumulation of two intermediate states during acid unfolding, which might be responsible for amyloid fibril formation. The more structured intermediate that exhibited maximal accumulation at pH 3 retained the nativelike secondary structure and a hydrophobic core, but exposed hydrophobic surfaces that bind 8-anilino-1-naphthalenesulfonate. Below pH 2, a more disordered intermediate with dequenched tryptophan fluorescence but still retaining the beta-sheet structure accumulated. The optimal pH of amyloid fibril formation (i.e., pH 4) was close to the optimal pH of the accumulation of the nativelike intermediate, suggesting that the amyloid fibrils might be formed through this intermediate.     

Amyloidogenic potential of alpha-chymotrypsin in different conformational states

Amyloid fibril formation is widely believed to be a generic property of polypeptide chains. In the present study, alpha-chymotrypsin, a well-known serine protease has been driven toward these structures by the use of two different conditions involving (I) high temperature, pH 2.5, and (II) low concentration of trifluoroethanol (TFE), pH 2.5. A variety of experimental methods, including fluorescence emission, dynamic quenching, steady-state fluorescence anisotropy, far-UV circular dichroism, nuclear magnetic resonance spectroscopy, and dynamic light scattering were employed to characterize the conformational states of alpha-chymotrypsin that precede formation of amyloid fibrils. The structure formed under Condition I was an unfolded monomer, whereas an alpha-helical rich oligomer was induced in Condition II. Both the amyloid aggregation-prone species manifested a higher solvent exposure of hydrophobic and aromatic residues compared with the native state. Upon incubation of the protein in these conditions for 48 h, amyloid-like fibrils were formed with diameters of about 10-12 nm. In contrast, at neutral pH and low concentration of TFE, a significant degree of amorphous aggregation was observed, suggesting that charge neutralization of acidic residues in the amyloid core region has a positive influence on amyloid fibril formation. In summary, results presented in this communication suggest that amyloid fibrils of alpha-chymotrypsin may be obtained from a variety of structurally distinct conformational ensembles highlighting the critical importance of protein evolution mechanisms related to prevention of protein misfolding.     

Amyloid fibril formation by peptide LYS (11-36) in aqueous trifluoroethanol

Peptide LYS (11-36), derived from the beta-sheet region of T4 lysozyme, forms an amyloid fibril in aqueous trifluoroethanol (TFE) at elevated temperature. The peptide has a moderate alpha-helix content in 20 and 50% (v/v) TFE solution; large quantities of fibrils were formed after incubation at 55 degrees C for 2 weeks as monitored by a thioflavin T fluorescence assay. No fibrils were observed when the peptide initially existed predominantly as a random coil or as a complete alpha helix. Our results suggest that a moderate amount of alpha helix and random coil present in the peptide initially facilitates the fibril-formation process, but a high alpha-helix content inhibits fibril formation. Transmission electron microscopy revealed several types of fibril morphologies at different TFE concentrations. The fibrils were highly twisted and consisted of interleaved protofilaments in 50% TFE, while smooth and flat ribbonlike fibrils were found in 20% TFE. In 50% TFE, the fibril growth rate of LYS (11-36) was found to depend strongly on peptide concentration and seeding but was insensitive to solution pH and ionic strength.     

Amyloid-like fibril formation in an all beta-barrel protein. Partially structured intermediate state(s) is a precursor for fibril formation

Acidic fibroblast growth factor from newt (Notopthalmus viridescens) is a approximately 15-kDa, all beta-sheet protein devoid of disulfide bonds. In the present study, we investigate the effects of 2,2,2-trifluoroethanol (TFE) on the structure of newt acidic fibroblast growth factor (nFGF-1). The protein aggregates maximally in 10% (v/v) TFE. Congo red and thioflavin T binding experiments suggest that the aggregates induced by TFE have properties resembling the amyloid fibrils. Transmission electron microscopy and x-ray fiber diffraction data show that the fibrils (induced by TFE) are straight, unbranched, and have a cross-beta structure with an average diameter of 10-15 A. Preformed fibrils (induced by TFE) of nFGF-1 are observed to seed amyloid-like fibril formation in solutions containing the protein (nFGF-1) in the native beta-barrel conformation. Fluorescence, far-UV CD, anilino-8-napthalene sulfonate binding, multidimensional NMR, and Fourier transformed infrared spectroscopy data reveal that formation of a partially structured intermediate state(s) precedes the onset of the fibrillation process. The native beta-barrel structure of nFGF-1 appears to be disrupted in the partially structured intermediate state(s). The protein in the partially structured intermediate state(s) is found to be "sticky" with a solvent-exposed non-polar surface(s). Amyloid fibril formation appears to occur due to coalescence of the protein in the partially structured intermediate state(s) through solvent-exposed non-polar surfaces and intermolecular beta-sheet formation among the extended, linear beta-strands in the protein.     

Role of the helical structure of the N-terminal region of Plasmodium falciparum merozoite surface protein 2 in fibril formation and membrane interaction

Merozoite surface protein 2 (MSP2), an abundant glycosylphosphatidylinositol-anchored protein on the surface of Plasmodium falciparum merozoites, is a promising malaria vaccine candidate. MSP2 is intrinsically disordered and forms amyloid-like fibrils in solution under physiological conditions. The 25 N-terminal residues (MSP2(1-25)) play an important role in both fibril formation and membrane binding of the full-length protein. In this study, the fibril formation and solution structure of MSP2(1-25) in the membrane mimetic solvents sodium dodecyl sulfate (SDS), dodecylphosphocholine (DPC), and trifluoroethanol (TFE) have been investigated by transmission electronic microscopy, turbidity, thioflavin T fluorescence, circular dichroism (CD), and nuclear magnetic resonance (NMR) spectroscopy. Turbidity data showed that the aggregation of MSP2(1-25) was suppressed in the presence of membrane mimetic solvents. CD spectra indicated that helical structure in MSP2(1-25) was stabilized in SDS and DPC micelles and in high concentrations of TFE. The structure of MSP2(1-25) in 50% aqueous TFE, determined using NMR, showed that the peptide formed an amphipathic helix encompassing residues 10-24. Low concentrations of TFE favored partially folded helical conformations, as demonstrated by CD and NMR, and promoted MSP2(1-25) fibril formation. Our data suggest that partially folded helical conformations of the N-terminal region of MSP2 are on the pathway to amyloid fibril formation, while higher degrees of helical structure stabilized by high concentrations of TFE or membrane mimetics suppress self-association and thus inhibit fibril formation. The roles of the induced helical conformations in membrane interactions are also discussed.     

Conformational changes during amyloid fibril formation of pancreatic thiol proteinase inhibitor: effect of copper and zinc

Pancreatic thiol proteinase inhibitor (PTPI), a variant of cystatin superfamily of cysteine protease inhibitors, has been isolated from pancreas of Capra hircus. In the present study, we examined the effects of acid denaturation and a co-solvent on PTPI with a focus on protein conformational changes and amyloid fibril formation. The results demonstrate that PTPI can form amyloid like fibrils. Acid denaturation as studied by CD and fluorescence spectroscopy showed that PTPI populates three partly unfolded species, a native like state at pH 3.0, a structured molten globule at pH 1.0 and partly unfolded species at pH 2.0, from each of which amyloid like fibrils grow as assessed by Thioflavin T (ThT) spectroscopy. Effect of trifluoroethanol (TFE) on acid induced states of PTPI was analyzed. TFE stabilized each of the three acid-induced intermediates at predenaturational concentrations (10%) and accelerated fibril formation. Morphology of the protein species at the beginning and end of reactions was observed using transmission electron microscopy. Solvent conditions were decisive for final fibril morphology. Biometals, Cu²⁺ and Zn²⁺ produced a concentration dependent decline in ThT fluorescence suggesting deaggregation of the fibrils. When added prior to amyloid fibril initiation 50 μM Cu²⁺ or 10 μM Zn²⁺ prevented any amyloid aggregation. Implications for therapeutics in view of Cu²⁺ and Zn²⁺ as essential micronutrients are suggested.     

Partially folded intermediates as critical precursors of light chain amyloid fibrils and amorphous aggregates

Light chain, or AL, amyloidosis is a pathological condition arising from systemic extracellular deposition of monoclonal immunoglobulin light chain variable domains in the form of insoluble amyloid fibrils, especially in the kidneys. Substantial evidence suggests that amyloid fibril formation from native proteins occurs via a conformational change leading to a partially folded intermediate conformation, whose subsequent association is a key step in fibrillation. In the present investigation, we have examined the properties of a recombinant amyloidogenic light chain variable domain, SMA, to determine whether partially folded intermediates can be detected and correlated with aggregation. The results from spectroscopic and hydrodynamic measurements, including far- and near-UV circular dichroism, FTIR, NMR, and intrinsic tryptophan fluorescence and small-angle X-ray scattering, reveal the build-up of two partially folded intermediate conformational states as the pH is decreased (low pH destabilized the protein and accelerated the kinetics of aggregation). A relatively nativelike intermediate, I(N), was observed between pH 4 and 6, with little loss of secondary structure, but with significant tertiary structure changes and enhanced ANS binding, indicating exposed hydrophobic surfaces. At pH below 3, we observed a relatively unfolded, but compact, intermediate, I(U), which was characterized by decreased tertiary and secondary structure. The I(U) intermediate readily forms amyloid fibrils, whereas I(N) preferentially leads to amorphous aggregates. Except at pH 2, where negligible amorphous aggregate is formed, the amorphous aggregates formed significantly more rapidly than the fibrils. This is the first indication that different partially folded intermediates may be responsible for different aggregation pathways (amorphous and fibrillar). The data support the hypothesis that amyloid fibril formation involves the ordered self-assembly of partially folded species that are critical soluble precursors of fibrils.     

Theophylline-induced apoptosis is paralleled by protein kinase A-dependent tissue transglutaminase activation in cancer cells

beta(2)-Microglobulin (beta2M), the light chain of the type I major histocompatibility complex, is a major component of dialysis-related amyloid fibrils. beta2M in the native state has a typical immunoglobulin fold with a buried intrachain disulfide bond. The conformation and stability of recombinant beta2M in which the intrachain disulfide bond was reduced were studied by CD, tryptophan fluorescence, and one-dimensional NMR. The conformation of the reduced beta2M in the absence of denaturant at pH 8.5 was similar to that of the intact protein unless the thiol groups were modified. However, reduction of the disulfide bond decreased the stability as measured by denaturation in guanidine hydrochloride. Intact beta2M formed amyloid fibrils at pH 2.5 by extension reaction using sonicated amyloid fibrils as seeds. Under the same conditions, reduced beta2M did not form typical amyloid fibrils, although it inhibited fibril extension competitively, suggesting that the conformation defined by the disulfide bond is important for amyloid fibril formation of beta2M.     

Amphotericin B binds to amyloid fibrils and delays their formation: a therapeutic mechanism?

The membrane-active antifungal agent amphotericin B (AmB) is one of the few agents shown to slow the course of prion diseases in animals. Congo Red and other small molecules have been reported to directly inhibit amyloidogenesis in both prion and Alzheimer peptide model systems via specific binding. We propose that it is possible that AmB may act similarly to physically prevent conversion of the largely alpha-helical prion protein (PrP) to the pathological beta-sheet aggregate protease-resistant isoform (PrP(res)) in prion disease and by analogy prevent fibrillization in amyloid diseases. To assess whether AmB is capable of binding specifically to amyloid fibrils as does Congo Red, we have used the insulin fibril and Abeta 25-35 amyloid model fibril system. We find that AmB does bind strongly to both insulin (K(d) = 1.1 microM) and Abeta 25-35 amyloid (K(d) = 6.4 microM) fibrils but not to native insulin. Binding is characterized by a red-shifted AmB spectrum indicative of a more hydrophobic environment. Thus AmB seems to have a complementary face for amyloid fibrils but not the native protein. In addition, AmB interacts specifically with Congo Red, a known fibril-binding agent. In kinetic fibril formation studies, AmB was able to significantly kinetically delay the formation of Abeta 25-35 fibrils at pH 7.4 but not insulin fibrils at pH 2.     

Polymorphism of β2-microglobulin amyloid fibrils manifested by ultrasonication-enhanced fibril formation in trifluoroethanol

The polymorphic property of amyloid structures has been focused on as a molecular basis of the presence and propagation of different phenotypes of amyloid diseases, although little is known about the molecular mechanism for expressing diverse structures from only one protein sequence. Here, we have found that, in combination with an enhancing effect of ultrasonication on nucleation, β(2)-microglobulin, a protein responsible for dialysis-related amyloidosis, generates distinct fibril conformations in a concentration-dependent manner in the presence of 2,2,2-trifluoroethanol (TFE). Although the newly formed fibrils all exhibited a similar needle-like morphology with an extensive cross-β core, as suggested by Fourier transform infrared absorption spectra, they differed in thioflavin T intensity, extension kinetics, and tryptophan fluorescence spectra even in the same solvents, representing polymorphic structures. The hydrophobic residues seemed to be more exposed in the fibrils originating at higher concentrations of TFE, as indicated by the increased binding of 1-anilinonaphthalene-8-sulfonic acid, suggesting that the modulation of hydrophobic interactions is critical to the production of polymorphic amyloid structures. Interestingly, the fibrils formed at higher TFE concentrations showed significantly higher stability against guanidium hydrochloride, the perturbation of ionic strength, and, furthermore, pressurization. The cross-β structure inside the fibrils seems to have been more idealized, resulting in increased stability when nucleation occurred in the presence of the alcohol, indicating that a weaker contribution of hydrophobic interactions is intrinsically more amenable to the formation of a non-defective amyloid structure.     

Amyloid fibril formation by human stefin B: influence of the initial pH-induced intermediate state

The amyloid fibril field is briefly described, with some stress put on differences between various proteins and possible role for domain swapping. In the main body of the text, first, a short review is given of the folding properties of both human stefins, alpha/beta-type globular proteins of 53% identity with a known three-dimensional fold. Second, in vitro study of amyloid fibril formation by human stefin B (type I cystatin) is described. Solvents of pH 4.8 and pH 3.3 with and without 2,2,2-trifluoroethanol (TFE) were probed, as it has been shown previously that stefin B forms acid intermediates, a native-like and molten globule intermediate, respectively. The kinetics of fibrillation were measured by thioflavin T fluorescence and CD. At pH 3.3, the protein is initially in the molten globule state. The fibrillation is faster than at pH 4.8; however, there is more aggregation observed. On adding TFE at each pH, the fibril formation is further accelerated.     

Ultrasonication-induced amyloid fibril formation of beta2-microglobulin

To obtain insight into the mechanism of fibril formation, we examined the effects of ultrasonication, a strong agitator, on beta2-microglobulin (beta2-m), a protein responsible for dialysis-related amyloidosis. Upon sonication of an acid-unfolded beta2-m solution at pH 2.5, thioflavin T fluorescence increased markedly after a lag time of 1-2 h with a simultaneous increase of light scattering. Atomic force microscopy images showed the formation of a large number of short fibrils 3 nm in diameter. When the sonication-induced fibrils were used as seeds in the next seeding experiment at pH 2.5, a rapid and intense formation of long fibrils 3 nm in diameter was observed demonstrating seed-dependent fibril growth. We then examined the effects of sonication on the native beta2-m at neutral pH, conditions under which amyloid deposits occur in patients. In the presence of 0.5 mm sodium dodecyl sulfate, a model compound of potential trigger and stabilizer of amyloid fibrils in patients, a marked increase of thioflavin T fluorescence was observed after 1 day of sonication at pH 7.0. The products of sonication caused the accelerated fibril formation at pH 7.0. Atomic force microscopy images showed that the fibrils formed at pH 7.0 have a diameter of more than 7 nm, thicker than those prepared at pH 2.5. These results indicate that ultrasonication is one form of agitation triggering the formation of amyloid fibrils of beta2-m, producing fibrils adapted to the respective pH.     

Oligopeptide-mediated acceleration of amyloid fibril formation of amyloid beta(Abeta) and alpha-synuclein fragment peptide (NAC).

The effects of oligopeptides on the secondary structures of Abeta and NAC, a fragment of alpha-synuclein protein, were studied by circular dichroism (CD) spectra. The effects of oligopeptides on the amyloid fibril formation were also studied by fluorescence spectra due to thioflavine-T. The oligopeptides were composed of a fragment of Abeta or NAC and were interposed by acidic or basic amino acid residues. The peptide, Ac-ELVFFAKK-NH2, which involved a fragment Leu-Val-Phe-Phe-Ala at Abeta(17-21), had no effect on the secondary structures of Abeta(1-28) in 60% or 90% trifluoroethanol (TFE) solutions at both pH 3.2 and pH 7.2. However, it showed pronounced effects on the secondary structure of Abeta(1-28) at pH 5.4. The Ac-ELVFFAKK-NH2 reduced the alpha-helical content, while it increased the beta-sheet content of Abeta(1-28). In phosphate buffer solutions at pH 7.0, Ac-ELVFFAKK-NH2 had little effect on the secondary structures of Abeta(1-28). However, it accelerated amyloid fibril formation when monitored by fluorescence spectra due to thioflavine-T. On the other hand, LPFFD, a peptide known as a beta-sheet breaker, caused neither an appreciable extent of change in the secondary structure nor amyloid fibril formation in the same buffer solution. The peptide, Ac-ETVK-NH2, which involved a fragment Thr-Val at NAC(21-22), had no effect on the secondary structure of NAC in 90% TFE and in isotonic phosphate buffer. However, Ac-ETVK-NH2 in water with small amounts of NaN3 and hexafluoroisopropanol greatly increased the beta-sheet content of NAC after standing the solution for more than 1 week. Interestingly, in this solution. Ac-ETVK-NH2, accelerated the fibril formation of NAC. It was concluded that an oligopeptide that involves a fragment of amyloidogenic proteins could be a trigger for the formation of amyloid plaques of the proteins even when it had little effect on the secondary structures of the proteins as monitored by CD spectra for a short incubation time.     

Partial denaturation of transthyretin is sufficient for amyloid fibril formation in vitro.

Amyloid diseases are caused by the self-assembly of a given protein into an insoluble cross-beta-sheet quaternary structural form which is pathogenic. An understanding of the biochemical mechanism of amyloid fibril formation should prove useful in understanding amyloid disease. Toward this end, a procedure for the conversion of the amyloidogenic protein transthyretin into amyloid fibrils under conditions which mimic the acidic environment of a lysosome has been developed. Association of a structured transthyretin denaturation intermediate is sufficient for amyloid fibril formation in vitro. The rate of fibril formation is pH dependent with significant rates being observed at pHs accessible within the lysosome (3.6-4.8). Far-UV CD spectroscopic studies suggest that transthyretin retains its secondary structural features at pHs where fibrils are formed. Near-UV CD studies demonstrate that transthyretin has retained the majority of its tertiary structure during fibril formation as well. Near-UV CD analysis in combination with glutaraldehyde cross-linking studies suggests that a pH-mediated tetramer to monomer transition is operative in the pH range where fibril formation occurs. The rate of fibril formation decreases markedly at pHs below pH 3.6, consistent with denaturation to a monomeric TTR intermediate which has lost its native tertiary structure and capability to form fibrils. It is difficult to specify with certainty which quaternary structural form of transthyretin is the amyloidogenic intermediate at this time. These difficulties arise because the maximal rate of fibril formation occurs at pH 3.6 where tetramer, traces of dimer, and significant amounts of monomer are observed.(ABSTRACT TRUNCATED AT 250 WORDS)     

The amyloid fibrils of the constant domain of immunoglobulin light chain

Light chain-associated (AL) amyloidosis is characterized by dominant fibril deposition of the variable domain (VL) of an immunoglobulin light chain, and thus its constant domain (CL) has been considered not to be amyloidogenic. We examined the in vitro fibril formation of the isolated CL in comparison with β₂-microglobulin (β2-m), an immunoglobulin domain-like amyloidogenic protein responsible for dialysis-related amyloidosis. Two methods useful for β2-m at neutral pH also induced amyloid fibrils of CL, which were monitored by thioflavin-T binding and electron microscopy (EM). These results suggest that CL plays an important role, more than previously assumed, in the development of AL-amyloidosis.     

Molecular Dynamics Simulations to Gain Insights into the Stability and Morphologies of K3 Oligomers from β2-microglobulin

Abstract

β2-Microglobulin (β2-m) forms amyloid fibrils in patients undergoing long-term hemodialysis. K3 peptide, a Ser20-Lys41 fragment of β2-m, has been known to form fibrils over a wide range of pH and solvent conditions. Recent solid-state NMR has revealed that K3 oligomer adopts a parallel U-shaped β-strand-turn-β-strand motif. In order to investigate the stability and morphologies of K3 oligomers with different sizes (dimer, trimer, and tetrameri and organizations (single and double layers), several all-atom molecular dynamics simulations were conducted at 310 K and pH 2 in water and 2,2,2-trifluoroethanol (TFE). For single-layered organizations, our results show that TFE destabilizes the stacking of K3 peptides due to the fact that TFE weakens the intermolecular hydrophobic interactions of K3 oligomers. In addition, we also identified that the loop region is stabilized by the hydrophobic cluster involving resides Y7, Fll, and I16. Our results further suggest that K3 tetramer is a potential minimal nucleus seed for the formation of K3 protofibrils. For dou-ble-layered organizations in water, our data demonstrate that K3 peptides can form various stable assemblies through different interfacial arrangements, such as NN, NC, and CC, by different driving forces. We further propose that the stacking of different interfaces between two facing β-sheets of K3 peptides could be related to different fibril morphologies, which is in good agreement with the previous experimental results, showing that K3 protofibrils associated to formed mature fibrils with a wide range of diameters from 4 to 15 nm when they were transferred from 20% (v/v) TFE to aqueous solution.     

Identification of a novel human islet amyloid polypeptide beta-sheet domain and factors influencing fibrillogenesis

Human islet amyloid polypeptide (hIAPP) accumulates as pancreatic amyloid in type 2 diabetes and readily forms fibrils in vitro. Investigations into the mechanism of hIAPP fibril formation have focused largely on residues 20 to 29, which are considered to comprise a primary amyloidogenic domain. In rodents, proline substitutions within this region and the subsequent beta-sheet disruption, prevents fibril formation. An additional amyloidogenic fragment within the C-terminal sequence, residues 30 to 37, has been identified recently. We have extended these observations by examining a series of overlapping peptide fragments from the human and rodent sequences. Using protein spectroscopy (CD/FTIR), electron microscopy and X-ray diffraction, a previously unrecognised amyloidogenic domain was localised within residues 8 to 20. Synthetic peptides corresponding to this region exhibited a transition from random coil to beta-sheet conformation and assembled into fibrils having a typical amyloid-like morphology. The comparable rat 8-20 sequence, which contains a single His18Arg substitution, was also capable of assembling into amyloid-like fibrils. Examination of peptide fragments corresponding to residues 1 to 13 revealed that the immediate N-terminal region is likely to have only a modulating influence on fibril formation or conformational conversion. The contributions of charged residues as they relate to the amyloid-forming 8-20 sequence were also investigated using IAPP fragments and by assessing the effects of pH and counterions. The identification of these principal amyloidogenic sequences and the effects of associated factors provide details on the IAPP aggregation pathway and structure of the peptide in its fibrillar state.     

Human Immunoglobulin Light Chains λ Form Amyloid Fibrils and Granular Aggregates in Solution

Myeloma nephropathy is a disorder characterized by deposition of monoclonal immunoglobulin light chains in the kidneys. The chains deposited form either amyloid fibrils or granular (amorphous) aggregates. Distinct molecular mechanisms leading to the formation of different aggregate types in kidney of patients with multiple myeloma are poorly understood. Here we describe the self-association kinetics of human monoclonal immunoglobulin light chains lambda (GRY) isolated from urine of a patient with multiple myeloma. Under physiological conditions, the isolated light chain exists predominantly in a form of covalent dimer with apparent molecular mass of 50.1 kD. Spectral probe binding, analytical gel filtration, Western blot analysis, and electron microscopy indicate that GRY dimer aggregation occurs via two different pathways producing either amyloid fibrils or amorphous aggregates depending on microenvironment. Incubation of GRY (25 microM) for 4-14 days at 37 degrees C in phosphate buffered saline (PBS), pH 7.0, or in PBS containing urea (0.8 M), pH 6.5, leads to amyloid fibril formation. Under electron microscopy, the fibrils show unbranched thread-like structures, approximately 60-80 x 1000 A in size, which can bind thioflavin T and Congo Red. GRY maintained in acetate buffer, pH 3.5, forms granular aggregates. The structure of GRY oligomers formed during the early stage of amyloid fibril formation (1-4 days) has been examined by means of protein cross-linking with homobifunctional reagents. These oligomers are predominantly trimers and tetramers.     

Amyloid fibril formation in vitro from halophilic metal binding protein: Its high solubility and reversibility minimized formation of amorphous protein aggregations

Halophilic proteins are characterized by high net negative charges and relatively small fraction of hydrophobic amino acids, rendering them aggregation resistant. These properties are also shared by histidine‐rich metal binding protein (HP) from moderate halophile, Chromohalobacter salexigens, used in this study. Here, we examined how halophilic proteins form amyloid fibrils in vitro. His‐tagged HP, incubated at pH 2.0 and 58°C, readily formed amyloid fibrils, as observed by thioflavin fluorescence, CD spectra, and transmission or atomic force microscopies. Under these low‐pH harsh conditions, however, His‐HP was promptly hydrolyzed to smaller peptides most likely responsible for rapid formation of amyloid fibril. Three major acid‐hydrolyzed peptides were isolated from fibrils and turned out to readily form fibrils. The synthetic peptides predicted to form fibrils in these peptide sequences by Waltz software also formed fibrils. Amyloid fibril was also readily formed from full‐length His‐HP when incubated with 10–20% 2,2,2‐trifluoroethanol at pH 7.8 and 25°C without peptide bond cleavage.