Independent heterologous fibrillation of insulin and its B-chain peptide

Insulin is very prone to form amyloid fibrils under slightly destabilizing conditions, and the B-chain region plays a critical role in the fibrillation. We show here that the isolated B-chain peptide of bovine insulin also forms fibrils at both acidic and neutral pH. When a mixture of insulin and the B-chain peptide was incubated at either acidic or neutral pH, the formation of fibrils was clearly separated into two phases, with the faster phase corresponding to the formation of homogeneous fibrils from the B-chain and the slower phase corresponding to homogeneous fibrillation of insulin. To further investigate the interaction (or lack thereof) between the two polypeptides, we examined the effects of cross-seeding. The results indicate that seeds of B-chain fibrils accelerate the fibrillation of insulin at pH 1.6 and inhibit the fibrillation at pH 7.5, but seeds of insulin fibrils have little effect on the fibrillation of the B-chain. We conclude that at pH 7.5 simultaneous independent homologous fibrillation occurs, but at low pH, heterologous fibrillation takes place, and with B-chain seeding of insulin, a unique conformation of fibrils is formed. Our results demonstrate that in the co-aggregation of closely related peptides each peptide species may undergo concurrent homogeneous or heterologous polymerization and that fibrils of one species may or may not seed fibrillation of the other. The results demonstrate the significant "species" barrier in amyloid fibril formation between fibrillation induced by different fibrils. A model for the fibrillation of the heterogeneous system of insulin and B-chain insulin is proposed.     

Conformational prerequisites for alpha-lactalbumin fibrillation

Bovine alpha-lactalbumin, a small acidic Ca(2+)-binding milk protein, formed amyloid fibrils at low pH, where it adopted the classical molten globule-like conformation. Fibrillation was accompanied by a dramatic increase in the beta-structure content and a characteristic increase in the thioflavin T fluorescence intensity. S-(Carboxymethyl)-alpha-lactalbumin, a disordered form of the protein with three out of four disulfide bridges reduced, was even more susceptible to fibrillation. Other partially folded conformations induced in the intact protein at neutral pH, either by the removal of Ca(2+) or by the binding of Zn(2+) to the Ca(2+)-protein complex, did not fibrillate, although Zn(2+)-loaded alpha-lactalbumin precipitated out of solution as amorphous aggregates. Our data suggest that the transformation of a protein into an essentially unfolded (thus, highly flexible) conformation is required for successful fibril formation, whereas more rigid (but still flexible) species may form amorphous aggregates.     

Fibrillation of human insulin A and B chains

Human insulin, which consists of disulfide cross-linked A and B polypeptide chains, readily forms amyloid fibrils under slightly destabilizing conditions. We examined whether the isolated A and B chain peptides of human insulin would form fibrils at neutral and acidic pH. Although insulin exhibits a pH-dependent lag phase in fibrillation, the A chain formed fibrils without a lag at both pHs. In contrast, the B chain exhibited complex concentration-dependent fibrillation behavior at acidic pH. At higher concentrations, e.g., >0.2 mg/mL, the B chains preferentially and rapidly formed stable protofilaments rather than mature fibrils upon incubation at 37 degrees C. Surprisingly, these protofilaments did not convert into mature fibrils. At lower B chain concentrations, however, mature fibrils were formed. The explanation for the concentration dependence of B chain fibrillation is as follows. The B chains exist as soluble oligomers at acidic pH, have a beta-sheet rich conformation as determined by CD, and bind ANS strongly, and these oligomers rapidly form dead-end protofilaments. However, under conditions in which the B chain monomer is present, such as low B chain concentration (<0.2 mg/mL) or in the presence of low concentrations of GuHCl, which dissociates the soluble oligomers, mature fibrils were formed. Thus, both A and B chain peptides can form amyloid fibrils, and both are likely to be involved in the interactions leading to the fibrillation of intact insulin.     

Amyloid-forming peptides from beta2-microglobulin-Insights into the mechanism of fibril formation in vitro

Beta(2)-Microglobulin (beta(2)m) is one of over 20 proteins known to be involved in human amyloid disease. Peptides equivalent to each of the seven beta-strands of the native protein, together with an eighth peptide (corresponding to the most stable region in the amyloid precursor conformation formed at pH 3.6, that includes residues in the native strand E plus the eight succeeding residues (named peptide E')), were synthesised and their ability to form fibrils investigated. Surprisingly, only two sequences, both of which encompass the region that forms strand E in native beta(2)m, are capable of forming amyloid-like fibrils in vitro. These peptides correspond to residues 59-71 (peptide E) and 59-79 (peptide E') of intact beta(2)m. The peptides form fibrils under the acidic conditions shown previously to promote amyloid formation from the intact protein (pH <5 at low and high ionic strength), and also associate to form fibrils at neutral pH. Fibrils formed from these two peptides enhance fibrillogenesis of the intact protein. No correlation was found between secondary structure propensity, peptide length, pI or hydrophobicity and the ability of the peptides to associate into amyloid-like fibrils. However, the presence of a relatively high content of aromatic side-chains correlates with the ability of the peptides to form amyloid fibrils. On the basis of these results we propose that residues 59-71 may be important in the self-association of partially folded beta(2)m into amyloid fibrils and discuss the relevance of these results for the assembly mechanism of the intact protein in vitro.     

The mechanism of enhanced insulin amyloid fibril formation by NaCl is better explained by a conformational change model

The high propensity of insulin to fibrillate causes severe biomedical and biotechnological complications. Insulin fibrillation studies attain significant importance considering the prevalence of diabetes and the requirement of functional insulin in each dose. Although studied since the early years of the 20(th) century, elucidation of the mechanism of insulin fibrillation has not been understood completely. We have previously, through several studies, shown that insulin hexamer dissociates into monomer that undergoes partial unfolding before converting into mature fibrils. In this study we have established that NaCl enhances insulin fibrillation mainly due to subtle structural changes and is not a mere salt effect. We have carried out studies both in the presence and absence of urea and Gdn.HCl and compared the relationship between conformation of insulin induced by urea and Gdn.HCl with respect to NaCl at both pH 7.4 (hexamer) and pH 2 (monomer). Fibril formation was followed with a Thioflavin T assay and structural changes were monitored by circular dichroism and size-exclusion chromatography. The results show salt-insulin interactions are difficult to classify as commonly accepted Debye-Hückel or Hofmeister series interactions but instead a strong correlation between the association states and conformational states of insulin and their propensity to fibrillate is evident.     

Removal of intact β2-microglobulin at neutral ph by using seed-conjugated polymer beads prepared with β2-microglobulin-derived peptide (58-67)

Removal of β2-microglobulin (β2M) from the blood of patients suffering from kidney dysfunction is crucial to protect those individuals from getting the diseased state of dialysis-related amyloidosis. By harnessing the nucleation-dependent fibrillation process of amyloidogenesis, a β2M removal strategy has been proposed by preparing seed-conjugated polymer beads and assimilating soluble β2M to the fibrils on the surface at neutral pH. A novel peptide segment of β2M ranging from residue 58 to residue 67 (Lys-Asp-Trp-Ser-Phe-Tyr-Leu-Leu-Tyr-Tyr), which was capable of being fibrillated at neutral pH was isolated. Charge interaction between the positive N-terminal lysine and the negative C-terminal α-carboxylic group was demonstrated to be critical for the molecular self-assembly leading to the peptide fibril formation by favoring β-sheet conformation. Because the peptide fibrils were successful to seed intact β2M at neutral pH, the fibrils were immobilized on polymer beads of HiCore resins, and the resulting seed-conjugated beads were used to accrete intact β2M in the form of fibrils elongated on the bead surface. Its efficiency of the β2M removal was improved by placing the seed-immobilized beads in the middle of a continuous flow of the β2M-containing solution as practiced in the blood circulation during the hemodialysis. Therefore, this β2M removal system is suggested to exhibit high specificity, high binding capacity, and cost-effectiveness appropriate for eventual clinical application to remove β2M from the blood of renal failure patients.     

Cathepsin B1. A lysosomal enzyme that degrades native collagen

1. Experiments were made to determine whether the purified lysosomal proteinases, cathepsins B1 and D, degrade acid-soluble collagen in solution, reconstituted collagen fibrils, insoluble collagen or gelatin. 2. At acid pH values cathepsin B1 released (14)C-labelled peptides from collagen fibrils reconstituted at neutral pH from soluble collagen. The purified enzyme required activation by cysteine and EDTA and was inhibited by 4-chloromercuribenzoate, by the chloromethyl ketones derived from tosyl-lysine and acetyltetra-alanine and by human alpha(2)-macroglobulin. 3. Cathepsin B1 degraded collagen in solution, the pH optimum being pH4.5-5.0. The initial action was cleavage of the non-helical region containing the cross-link; this was seen as a decrease in viscosity with no change in optical rotation. The enzyme also attacked the helical region of collagen by a mechanism different from that of mammalian neutral collagenase. No discrete intermediate products of a specific size were observed in segment-long-spacing crystalloids (measured as native collagen molecules aligned with N-termini together along the long axis) or as separate peaks on gel filtration chromatography. This suggests that once an alpha-chain was attacked it was rapidly degraded to low-molecular-weight peptides. 4. Cathepsin B1 degraded insoluble collagen with a pH optimum below 4; this value is lower than that found for the soluble substrate, and a possible explanation is given. 5. The lysosomal carboxyl proteinase, cathepsin D, had no action on collagen or gelatin at pH3.0. Neither cathepsin B1 nor D cleaved Pz-Pro-Leu-Gly-Pro-d-Arg. 6. Cathepsin B1 activity was shown to be essential for the degradation of collagen by lysosomal extracts. 7. Cathepsin B1 may provide an alternative route for collagen breakdown in physiological and pathological situations.     

Investigation of a peptide responsible for amyloid fibril formation of beta 2-microglobulin by achromobacter protease I.

To obtain insight into the mechanism of amyloid fibril formation from beta(2)-microglobulin (beta2-m), we prepared a series of peptide fragments using a lysine-specific protease from Achromobacter lyticus and examined their ability to form amyloid fibrils at pH 2.5. Among the nine peptides prepared by the digestion, the peptide Ser(20)-Lys(41) (K3) spontaneously formed amyloid fibrils, confirmed by thioflavin T binding and electron microscopy. The fibrils composed of K3 peptide induced fibril formation of intact beta2-m with a lag phase, distinct from the extension reaction without a lag phase observed for intact beta2-m seeds. Fibril formation of K3 peptide with intact beta2-m seeds also exhibited a lag phase. On the other hand, the extension reaction of K3 peptide with the K3 seeds occurred without a lag phase. At neutral pH, the fibrils composed of either intact beta2-m or K3 peptide spontaneously depolymerized. Intriguingly, the depolymerization of K3 fibrils was faster than that of intact beta2-m fibrils. These results indicated that, although K3 peptide can form fibrils by itself more readily than intact beta2-m, the K3 fibrils are less stable than the intact beta2-m fibrils, suggesting a close relation between the free energy barrier of amyloid fibril formation and its stability.     

Certain metals trigger fibrillation of methionine-oxidized alpha-synuclein

The aggregation and fibrillation of alpha-synuclein has been implicated as a key step in the etiology of Parkinson's disease and several other neurodegenerative disorders. In addition, oxidative stress and certain environmental factors, including metals, are believed to play an important role in Parkinson's disease. Previously, we have shown that methionine-oxidized human alpha-synuclein does not fibrillate and also inhibits fibrillation of unmodified alpha-synuclein (Uversky, V. N., Yamin, G., Souillac, P. O., Goers, J., Glaser, C. B., and Fink, A. L. (2002) FEBS Lett. 517, 239-244). Using dynamic light scattering, we show that the inhibition results from stabilization of the monomeric form of Met-oxidized alpha-synuclein. We have now examined the effect of several metals on the structural properties of methionine-oxidized human alpha-synuclein and its propensity to fibrillate. The presence of metals induced partial folding of both oxidized and non-oxidized alpha-synucleins, which are intrinsically unstructured under conditions of neutral pH. Although the fibrillation of alpha-synuclein was completely inhibited by methionine oxidation, the presence of certain metals (Ti3+, Zn2+, Al3+, and Pb2+) overcame this inhibition. These findings indicate that a combination of oxidative stress and environmental metal pollution could play an important role in triggering the fibrillation of alpha-synuclein and thus possibly Parkinson's disease.     

Uridine diphosphate galactose 4-epimerase. pH dependence of the reduction of NAD+ by a substrate analog

Neutron activation analysis of UDP-galactose 4-epimerase from Escherichia coli for 53 metals shows that the enzyme does not contain any of these metals at significant levels. The substrate analog P1-5'-uridine-P2-glucose-6-yl pyrophosphate (UGP), a structural isomer of UDP-glucose with the sugar linked to UDP through the C-6 hydroxyl group, is an inactivator that irreversibly reduces epimerase.NAD+ to epimerase.NADH. The pH dependence of kobs reveals the essential involvement of an acidic group, kinetically measured pKa = 5.48 +/- 0.08, in unprotonated form and two weakly acidic or basic groups, apparent pKa values of 10.03 +/- 0.43, in protonated forms. Measurements of kobs as a function of [UGP] show that it is given by kobs = k[UGP]/(K + [UGP]) at a given pH, where K = 0.19 +/- 0.04 mM throughout the pH range 4.8-10.4. The pH-dependent first order rate constants range from 0.28 to 1.94 s-1, with the maximum value at pH 7.6 and decreasing at acidic and basic pH values. Reaction of [glucose-1-2H]UGP proceeds with kinetic isotope effects of 5.0, 2.1, 2.0, 1.9, and 3.5 at pH values 5.0, 6.2, 7.6, 9.0, and 10.0, respectively. Therefore, hydride transfer becomes rate-limiting at pH extremes but is not limiting at neutral pH, although deuteride transfer is significantly limiting at all pH values. The isotope effects facilitated correction of the kinetic pK values to the thermodynamic values 6.1-6.2 on the acid side and 9.0-9.6 on the alkaline side. We postulate that the group with pK1 = 5.5 (6.1-6.2 corrected) functions as an enzymic general base that abstracts the glucosyl C-1 hydroxyl proton in concert with transfer of the C-1 hydrogen and two electrons to NAD+. The pH dependence on the alkaline side may be related to the uridine nucleotide-dependent conformational transition that is an essential step in the reduction of epimerase.NAD+ to epimerase.NADH by sugars.     

Fibril formation of hsp10 homologue proteins and determination of fibril core regions: differences in fibril core regions dependent on subtle differences in amino acid sequence

Heat shock protein 10 (hsp10) is a member of the molecular chaperones and works with hsp60 in mediating various protein folding reactions. GroES is a representative protein of hsp10 from Escherichia coli. Recently, we found that GroES formed a typical amyloid fibril from a guanidine hydrochloride (Gdn-HCl) unfolded state at neutral pH. Here, we report that other hsp10 homologues, such as human hsp10 (Hhsp10), rat mitochondrial hsp10 (Rhsp10), Gp31 from T4 phage, and hsp10 from the hyperthermophilic bacteria Thermotoga maritima, also form amyloid fibrils from an unfolded state. Interestingly, whereas GroES formed fibrils from either the Gdn-HCl unfolded state (at neutral pH) or the acidic unfolded state (at pH 2.0-3.0), Hhsp10, Rhsp10, and Gp31 formed fibrils from only the acidic unfolded state. Core peptide regions of these protein fibrils were determined by proteolysis treatment followed by a combination of Edman degradation and mass spectroscopy analyses of the protease-resistant peptides. The core peptides of GroES fibrils were identical for fibrils formed from the Gdn-HCl unfolded state and those formed from the acidic unfolded state. However, a peptide with a different sequence was isolated from fibrils of Hhsp10 and Rhsp10. With the use of synthesized peptides of the determined core regions, it was also confirmed that the identified regions were capable of fibril formation. These findings suggested that GroES homologues formed typical amyloid fibrils under acidic unfolding conditions but that the fibril core structures were different, perhaps owing to differences in local amino acid sequences.     

Thiol compounds inhibit the formation of amyloid fibrils by beta 2-microglobulin at neutral pH

Dialysis-related amyloidosis frequently develops in patients undergoing long-term hemodialysis, in which the major component of fibrils is β₂-microglobulin (β2-m). To prevent the disease, it is important to stop the formation of fibrils. β2-m has one disulfide bond, which stabilizes the native structure, and amyloid fibrils. Here, the effects of reductants (i.e., dithiothreitol and cysteine) on the formation of β2-m amyloid fibrils were examined at neutral pH. Fibrils were generated by three methods: seed-dependent, ultrasonication-induced, and salt-and-heat-induced fibrillation. Thioflavin T fluorescence, electron microscopy, and far-UV circular dichroism revealed that the addition of reductants significantly inhibits seed-dependent and ultrasonication-induced fibrillation. For salt-and-heat-induced fibrillation, where the solution of β2-m was strongly agitated, formation of amyloid fibrils was markedly reduced in the presence of reductants, although a small number of fibrils formed even after the reduction of the disulfide bond. The results suggest that reductants such as cysteine and dithiothreitol would be useful for preventing the formation of β2-m amyloid fibrils under physiological conditions.     

Amyloidogenic properties of the artificial protein albebetin and its biologically active derivatives. The role of electrostatic interactions in fibril formation

The artificial protein albebetin (ABB) and its derivatives containing biologically active fragments of natural proteins form fibrils at physiological pH. The amyloid nature of the fibrils was confirmed by far UV circular dichroism spectra indicating for rich beta-structure, thioflavin T binding assays, and examination of the obtained polymers by atomic force microscopy. Fusing of short peptides--octapeptide of human alpha(2)-interferon (130-137) or hexapeptide HLDF-6 (41-46) of human leukemia differentiation factor--with the N-terminus of ABB led to increased amyloidogenicity of the protein: the rate of fibril formation increased and the morphology of fibrils became more complex. The presence of free hexapeptide HLDF-6 in the ABB solution had the same effect. Increasing ionic strength also activated the process of amyloid formation, but to less extent than did the peptides fused with ABB or added to the ABB solution. We suggest an important role of electrostatic interactions in formation of ABB fibrils. The foregoing ways (addition of salt or peptides) allow decrease in electrostatic repulsion between ABB molecules carrying large negative charge (-12) at neutral pH, thus promoting fibril formation.     

The Formation and Disaggregation of Soy Protein Isolate Fibril: Effects of pH

To identify the effects of charged states on the formation and disaggregation of soy protein isolate (SPI) fibril, we studied the thermal aggregation behaviors of the constituent peptides of SPI fibril (CPSF) at various pH values (2–10) and investigated the structural changes of SPI fibril with increasing pH (2–11). Results showed that CPSF would assemble into diverse shapes at different pH values, among which the aggregates contained multiple β-sheet structures at pH less than 6, but these β-sheets were stacked to form fibrils only at pH 2. The damages from the increased pH to SPI fibril structure could be roughly divided into two stages, as follows: when pH was less than or equal to 6, the morphology of fibrils changed markedly due to electrostatic neutralization; at pH larger than 6, the fibrils suffered great losses in β-sheet, causing its structure to disintegrate rapidly. This study could provide theoretical reference to improve the pH stability of SPI fibril from the aspects of preparation and structural protection of the fibril.

     

N- and C-terminal hydrophobic patches are involved in fibrillation of glucagon

Recent work suggests that the molecular structure of amyloid-like fibrils is determined by environmental conditions as well as amino acid sequence. To probe the involvement of side chains in fibrillation of the 29-residue hormone glucagon, we have measured fibrillation kinetics of 15 alanine mutants. At acidic pH, all of the mutants are able to form fibrils. However, substitution of hydrophobic residues in the N- and C-termini (in particular Phe6, Tyr10, Val23, and Met27) decelerates fibrillation dramatically. This indicates that the hydrophobicity and/or high beta-sheet propensity of these residues may be important for fibrillation. In contrast, substitution of Leu14 increases fibrillation propensity compared to that of the wild type. Nevertheless, despite identical fibrillation conditions, the thioflavin T and tryptophan fluorescence spectra of fibrils formed by mutants Tyr13, Leu14, and Asp15 are significantly different from those of other mutants, indicating that substitution of these residues may influence not only the fibrillation kinetics and fibril stability but also the preferred final structure of the fibrils that is formed, in line with the general structural polymorphism of glucagon fibrils. In contrast, under alkaline conditions, only a handful of the alanine mutants are capable of forming fibrils, suggesting that more side chains are involved in stabilizing interactions here. In addition, fibrils formed by wild-type glucagon at alkaline pH appear very stable, compared to fibrils formed at acidic pH. This suggests that the distribution of charges determines the number of different fibrillated states available to a peptide, since these can block formation of metastable fibrillated states.     

Effect of introducing a short amyloidogenic sequence from the Aβ peptide at the N‐terminus of 18‐residue amphipathic helical peptides

Fibril formation is the hallmark of pathogenesis in Alzheimer's disease and other amyloid disorders caused by conformational alterations leading to the aggregation of soluble monomers. Aβ40 self‐associates to form amyloid fibrils. Its central seven‐residue segment KLVFFAE (Aβ16–22), which is thought to be crucial for fibril formation of the full‐length peptide, forms fibrils even in isolation. Context‐dependent induction of amyloid formation by such sequences in peptides, which otherwise do not have that propensity, is of considerable interest. We have examined the effect of introducing the Aβ16–22 sequence at the N‐terminus of two amphipathic helical 18‐residue peptides Ac‐WYSEMKRNVQRLERAIEE‐am and Ac‐KQLIRFLKRLDRNLWGLA‐am, which have high average hydrophobic moment <μH> values but have net charges of 0 and +4, respectively, at neutral pH. Upon incubation in aqueous buffer, fibril‐like aggregates were discernible by transmission electron microscopy for the peptide with only 0 net charge, which also displayed ThT binding and β‐structure. Although both the sequences have been derived from amphipathic helical segments in globular proteins and possess high average hydrophobic moments, the +4 charge peptide lacks the ability to form fibrils, while the peptide with 0 charge has the tendency to form fibrillar structures. Variation in the net charge and the presence of several glutamic acids in the sequence of the peptide with net charge 0 appear to favor the formation of fibrils when the Aβ16–22 sequence is attached at the N‐terminus. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.     

Biochemical characterization of two novel β-glucosidase genes by metagenome expression cloning

Two novel β-glucosidase genes designated as bgl1D and bgl1E, which encode 172- and 151-aa peptides, respectively, were cloned by function-based screening of a metagenomic library from uncultured soil microorganisms. Sequence analyses indicated that Bgl1D and Bgl1E exhibited lower similarities with some putative β-glucosidases. Functional characterization through high-performance liquid chromatography demonstrated that purified recombinant Bgl1D and Bgl1E proteins hydrolyzed D-glucosyl-β-(1-4)-D-glucose to glucose. Using p-nitrophenyl-β-D-glucoside as substrate, K(m) was 0.54 and 2.11 mM, and k(cat)/K(m) was 1489 and 787 mM(-1) min(-1) for Bgl1D and Bgl1E, respectively. The optimum pH and temperature for Bgl1D was pH 10.0 and 30°C, while the optimum values for Bgl1E were pH 10.0 and 25°C. Bgl1D exhibited habitat-specific characteristics, including higher activity in lower temperature and at high concentrations of AlCl(3) and LiCl. Bgl1D also displayed remarkable activity across a broad pH range (5.5-10.5), making it a potential candidate for industrial applications.     

The role of protonation in protein fibrillation

Many proteins fibrillate at low pH despite a high population of charged side chains. Therefore exchange of protons between the fibrillating peptide and its surroundings may play an important role in fibrillation. Here, we use isothermal titration calorimetry to measure exchange of protons between buffer and the peptide hormone glucagon during fibrillation. Glucagon absorbs or releases protons to an extent which allows it to attain a net charge of zero in the fibrillar state, both at acidic and basic pH. Similar results are obtained for lysozyme. This suggests that side chain pK_a values change dramatically in the fibrillar state.     

Conformational transitions and fibrillation mechanism of human calcitonin as studied by high-resolution solid-state 13C NMR

Conformational transitions of human calcitonin (hCT) during fibril formation in the acidic and neutral conditions were investigated by high-resolution solid-state 13C NMR spectroscopy. In aqueous acetic acid solution (pH 3.3), a local alpha-helical form is present around Gly10 whereas a random coil form is dominant as viewed from Phe22, Ala26, and Ala31 in the monomer form on the basis of the 13C chemical shifts. On the other hand, a local beta-sheet form as viewed from Gly10 and Phe22, and both beta-sheet and random coil as viewed from Ala26 and Ala31 were detected in the fibril at pH 3.3. The results indicate that conformational transitions from alpha-helix to beta-sheet, and from random coil to beta-sheet forms occurred in the central and C-terminus regions, respectively, during the fibril formation. The increased 13C resonance intensities of fibrils after a certain delay time suggests that the fibrillation can be explained by a two-step reaction mechanism in which the first step is a homogeneous association to form a nucleus, and the second step is an autocatalytic heterogeneous fibrillation. In contrast to the fibril at pH 3.3, the fibril at pH 7.5 formed a local beta-sheet conformation at the central region and exhibited a random coil at the C-terminus region. Not only a hydrophobic interaction among the amphiphilic alpha-helices, but also an electrostatic interaction between charged side chains can play an important role for the fibril formation at pH 7.5 and 3.3 acting as electrostatically favorable and unfavorable interactions, respectively. These results suggest that hCT fibrils are formed by stacking antiparallel beta-sheets at pH 7.5 and a mixture of antiparallel and parallel beta-sheets at pH 3.3.     

Evidence for stepwise formation of amyloid fibrils by the mouse prion protein

The full-length mouse prion protein, moPrP, is shown to form worm-like amyloid fibrils at pH 2 in the presence of 0.15 M NaCl, in a slow process that is accelerated at higher temperatures. Upon reduction in pH to 2, native moPrP transforms into a mixture of soluble β-rich oligomers and α-rich monomers, which exist in a slow, concentration-dependent equilibrium with each other. It is shown that only the β-rich oligomers and not the α-rich monomers, can form worm-like amyloid fibrils. The mechanism of formation of the worm-like amyloid fibrils from the β-rich oligomers has been studied with four different physical probes over a range of temperatures and over a range of protein concentrations. The observed rate of fibrillation is the same, whether measured by changes in ellipticity at 216 nm, in thioflavin fluorescence upon binding, or in the mean hydrodynamic radius. The observed rate is significantly slower when monitored by total scattering intensity, suggesting that lateral association of the worm-like fibrils occurs after they form. The activation energy for worm-like fibril formation was determined to be 129 kJ/mol. The observed rate of fibrillation increases with an increase in protein concentration, but saturates at protein concentrations above 50 μM. The dependence of the observed rate of fibrillation on protein concentration suggests that aggregate growth is rate-limiting at low protein concentration and that conformational change, which is independent of protein concentration, becomes rate-limiting at higher protein concentrations. Hence, fibril formation by moPrP occurs in at least two separate steps. Longer but fewer worm-like fibrils are seen to form at low protein concentration, and shorter but more worm-like fibrils are seen to form at higher protein concentrations. This observation suggests that the β-rich oligomers grow progressively in size to form critical higher order-oligomers from which the worm-like amyloid fibrils then form.