Structure of an early native‐like intermediate of β2‐microglobulin amyloidogenesis

To investigate early intermediates of β2‐microglobulin (β2m) amyloidogenesis, we solved the structure of β2m containing the amyloidogenic Pro32Gly mutation by X‐ray crystallography. One nanobody (Nb24) that efficiently blocks fibril elongation was used as a chaperone to co‐crystallize the Pro32Gly β2m monomer under physiological conditions. The complex of P32G β2m with Nb24 reveals a trans peptide bond at position 32 of this amyloidogenic variant, whereas Pro32 adopts the cis conformation in the wild‐type monomer, indicating that the cis to trans isomerization at Pro32 plays a critical role in the early onset of β2m amyloid formation.     

Nuclear magnetic resonance characterization of the refolding intermediate of beta2-microglobulin trapped by non-native prolyl peptide bond

beta(2)-Microglobulin (beta2-m), a light chain of the major histocompatibility complex type I, is also found as a major component of amyloid fibrils formed in dialysis-related amyloidosis. Denaturation of beta2-m is considered to initiate the formation of fibrils. To clarify the mechanism of fibril formation, it is important to characterize the intermediate conformational states at the atomic level. Here, we investigated the refolding of beta2-m from the acid-unfolded state by heteronuclear magnetic resonance and circular dichroism spectroscopies. At low temperature, beta2-m refolded slowly, accumulating a rate-limiting intermediate with non-native chemical shift dispersions for several residues, but with compactness and secondary structures similar to those of the native protein. beta2-m has a cis proline residue at Pro32, located on the turn connecting the betaB and betaC strands. The slow refolding phase disappeared upon mutation of Pro32 to Val, indicating that Pro32 is responsible for the accumulation of the intermediate. The distribution of the perturbed residues in the intermediate suggests that the non-native prolyl peptide bond of Pro32 affects large areas of the molecule. A cis proline residue is common to various immunoglobulin domains involved in amyloidosis, implying that a non-native prolyl peptide bond that might occur under physiological conditions is related to the amyloidogenicity of these immunoglobulin domains.     

Fibrillogenesis of human β2‐microglobulin in three‐dimensional silicon microstructures

The authors describe the interaction of biological nanostructures formed by β₂‐microglobulin amyloid fibrils with three‐dimensional silicon microstructures consisting in periodic arrays of vertical silicon walls (≈3 μm‐thick) separated by 50 μm‐deep air gaps (≈5 μm‐wide). These structures are of great interest from a biological point of view since they well mimic the interstitial environment typical of amyloid deposition in vivo. Moreover, they behave as hybrid photonic crystals, potentially applicable as optical transducers for label‐free detection of the kinetics of amyloid fibrils formation. Fluorescence and atomic force microscopy (AFM) show that a uniform distribution of amyloid fibrils is achieved when fibrillogenesis occurs directly on silicon. The high resolution AFM images also demonstrate that amyloid fibrils grown on silicon are characterized by the same fine structure typically ensured by fibrillogenesis in solution. (© 2012 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Oligomeric States along the Folding Pathways of β2-Microglobulin: Kinetics,Thermodynamics, and Structure

The transition of proteins from their soluble functional state to amyloid fibrils and aggregates is associated with the onset of several human diseases. Protein aggregation often requires some structural reshaping and the subsequent formation of intermolecular contacts. Therefore, the study of the conformation of excited protein states and their ability to form oligomers is of primary importance for understanding the molecular basis of amyloid fibril formation. Here, we investigated the oligomerization processes that occur along the folding of the amyloidogenic human protein β2-microglobulin. The combination of real-time two-dimensional NMR data with real-time small-angle X-ray scattering measurements allowed us to derive thermodynamic and kinetic information on protein oligomerization of different conformational states populated along the folding pathways. In particular, we could demonstrate that a long-lived folding intermediate (I-state) has a higher propensity to oligomerize compared to the native state. Our data agree well with a simple five-state kinetic model that involves only monomeric and dimeric species. The dimers have an elongated shape with the dimerization interface located at the apical side of β2-microglobulin close to Pro32, the residue that has a trans conformation in the I-state and a cis conformation in the native (N) state. Our experimental data suggest that partial unfolding in the apical half of the protein close to Pro32 leads to an excited state conformation with enhanced propensity for oligomerization. This excited state becomes more populated in the transient I-state due to the destabilization of the native conformation by the trans-Pro32 configuration.     

Nanoporous protein matrix made of amyloid fibrils of β2‐microglobulin

Amyloid fibrils are considered as novel nanomaterials because of their nanoscale width, a regular constituting structure of cross β‐sheet conformation, and considerable mechanical strength. By using an amyloidogenic protein of β₂‐microglobulin (β₂M) related to dialysis‐related amyloidosis, nanoporous protein matrix has been prepared. The β₂M granules made of around 15 monomers showed an average size of 23.1 nm. They formed worm‐like fibrils at pH 7.4 in 20 mM sodium phosphate containing 0.15 M NaCl following vigorous nondirectional shaking incubation, in which they became laterally associated and interwound to generate the porous amyloid fibrillar matrix with an average pore size of 30–50 nm. This nanoporous protein matrix was demonstrated to be selectively disintegrated by reducing agents, such as tris‐(2‐carboxyethyl) phosphine. High surface area with nanopores on the surface has been suggested to make the matrix of β₂M amyloid fibrils particularly suitable for applications in the area of nanobiotechnology including drug delivery and tissue engineering. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

Kinetic coupling of folding and prolyl isomerization of beta2-microglobulin studied by mutational analysis

β₂-Microglobulin (β2-m), a protein responsible for dialysis-related amyloidosis, adopts a typical immunoglobulin domain fold with the N-terminal peptide bond of Pro32 in a cis isomer. The refolding of β2-m is limited by the slow trans-to-cis isomerization of Pro32, implying that intermediates with a non-native trans-Pro32 isomer are precursors for the formation of amyloid fibrils. To obtain further insight into the Pro-limited folding of β2-m, we studied the Gdn-HCl-dependent unfolding/refolding kinetics using two mutants (W39 and P32V β2-ms) as well as the wild-type β2-m. W39 β2-m is a triple mutant in which both of the authentic Trp residues (Trp60 and Trp95) are replaced by Phe and a buried Trp common to other immunoglobulin domains is introduced at the position of Leu39 (i.e., L39W/W60F/W95F). W39 β2-m exhibits a dramatic quenching of fluorescence upon folding, enabling a detailed analysis of Pro-limited unfolding/refolding. On the other hand, P32V β2-m is a mutant in which Pro32 is replaced by Val, useful for probing the kinetic role of the trans-to-cis isomerization of Pro32. A comparative analysis of the unfolding/refolding kinetics of these mutants including three types of double-jump experiments revealed the prolyl isomerization to be coupled with the conformational transitions, leading to apparently unusual kinetics, particularly for the unfolding. We suggest that careful consideration of the kinetic coupling of unfolding/refolding and prolyl isomerization, which has tended to be neglected in recent studies, is essential for clarifying the mechanism of protein folding and, moreover, its biological significance.     

Kinetically trapped metastable intermediate of a disulfide‐deficient mutant of the starch‐binding domain of glucoamylase

Refolding of a thermally unfolded disulfide‐deficient mutant of the starch‐binding domain of glucoamylase was investigated using differential scanning calorimetry, isothermal titration calorimetry, CD, and ¹H NMR. When the protein solution was rapidly cooled from a higher temperature, a kinetic intermediate was formed during refolding. The intermediate was unexpectedly stable compared with typical folding intermediates that have short half‐lives. It was shown that this intermediate contained substantial secondary structure and tertiary packing and had the same binding ability with β‐cyclodextrin as the native state, suggesting that the intermediate is highly‐ordered and native‐like on the whole. These characteristics differ from those of partially folded intermediates such as molten globule states. Far‐UV CD spectra showed that the secondary structure was once disrupted during the transition from the intermediate to the native state. These results suggest that the intermediate could be an off‐pathway type, possibly a misfolded state, that has to undergo unfolding on its way to the native state.     

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.     

Heparin‐induced amyloid fibrillation of β2‐microglobulin explained by solubility and a supersaturation‐dependent conformational phase diagram

Amyloid fibrils are fibrillar deposits of denatured proteins associated with amyloidosis and are formed by a nucleation and growth mechanism. We revisited an alternative and classical view of amyloid fibrillation: amyloid fibrils are crystal‐like precipitates of denatured proteins formed above solubility upon breaking supersaturation. Various additives accelerate and then inhibit amyloid fibrillation in a concentration‐dependent manner, suggesting that the combined effects of stabilizing and destabilizing forces affect fibrillation. Heparin, a glycosaminoglycan and anticoagulant, is an accelerator of fibrillation for various amyloidogenic proteins. By using β₂‐microglobulin, a protein responsible for dialysis‐related amyloidosis, we herein examined the effects of various concentrations of heparin on fibrillation at pH 2. In contrast to previous studies that focused on accelerating effects, higher concentrations of heparin inhibited fibrillation, and this was accompanied by amorphous aggregation. The two‐step effects of acceleration and inhibition were similar to those observed for various salts. The results indicate that the anion effects caused by sulfate groups are one of the dominant factors influencing heparin‐dependent fibrillation, although the exact structures of fibrils and amorphous aggregates might differ between those formed by simple salts and matrix‐forming heparin. We propose that a conformational phase diagram, accommodating crystal‐like amyloid fibrils and glass‐like amorphous aggregates, is important for understanding the effects of various additives.     

Structural studies of the C‐terminal 19‐peptide of serum amyloid A and its Pro→Ala variants interacting with human cystatin C

Serum amyloid A (SAA) is a multifunctional acute‐phase protein whose concentration in serum increases markedly following a number of chronic inflammatory and neoplastic diseases. Prolonged high SAA level may give rise to reactive systemic amyloid A (AA) amyloidosis, where the N‐terminal segment of SAA is deposited as amyloid fibrils. Besides, recently, well‐documented association of SAA with high‐density lipoprotein or glycosaminoglycans, in particular heparin/heparin sulfate (HS), and specific interaction between SAA and human cystatin C (hCC), the ubiquitous inhibitor of cysteine proteases, was proved. Using a combination of selective proteolytic excision and high‐resolution mass spectrometry, a hCC binding site in the SAA sequence was determined as SAA(86–104). The role of this SAA C‐terminal fragment as a ligand‐binding locus is still not clear. It was postulated important in native SAA folding and in pathogenesis of AA amyloidosis. In the search of conformational details of this SAA fragment, we did its structure and affinity studies, including its selected double/triple Pro→Ala variants. Our results clearly show that the SAA(86–104) 19‐peptide has rather unordered structure with bends in its C‐terminal part, which is consistent with the previous results relating to the whole protein. The results of affinity chromatography, fluorescent ELISA‐like test, CD and NMR studies point to an importance of proline residues on structure of SAA(86–104). Conformational details of SAA fragment, responsible for hCC binding, may help to understand the objective of hCC–SAA complex formation and its importance for pathogenesis of reactive amyloid A amyloidosis. Copyright © 2015 John Wiley & Sons, Ltd.     

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.     

The residual structure of acid-denatured β2-microglobulin is relevant to an ordered fibril morphology

β₂-Microglobulin (β2m) forms amyloid fibrils in vitro under acidic conditions. Under these conditions, the residual structure of acid-denatured β2m is relevant to seeding and fibril extension processes. Disulfide (SS) bond-oxidized β2m has been shown to form rigid, ordered fibrils, whereas SS bond-reduced β2m 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 β2m 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 β2m 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.     

STITCHER: Dynamic assembly of likely amyloid and prion β‐structures from secondary structure predictions

The supersecondary structure of amyloids and prions, proteins of intense clinical and biological interest, are difficult to determine by standard experimental or computational means. In addition, significant conformational heterogeneity is known or suspected to exist in many amyloid fibrils. Previous work has demonstrated that probability‐based prediction of discrete β‐strand pairs can offer insight into these structures. Here, we devise a system of energetic rules that can be used to dynamically assemble these discrete β‐strand pairs into complete amyloid β‐structures. The STITCHER algorithm progressively ‘stitches’ strand‐pairs into full β‐sheets based on a novel free‐energy model, incorporating experimentally observed amino‐acid side‐chain stacking contributions, entropic estimates, and steric restrictions for amyloidal parallel β‐sheet construction. A dynamic program computes the top 50 structures and returns both the highest scoring structure and a consensus structure taken by polling this list for common discrete elements. Putative structural heterogeneity can be inferred from sequence regions that compose poorly. Predictions show agreement with experimental models of Alzheimer's amyloid beta peptide and the Podospora anserina Het‐s prion. Predictions of the HET‐s homolog HET‐S also reflect experimental observations of poor amyloid formation. We put forward predicted structures for the yeast prion Sup35, suggesting N‐terminal structural stability enabled by tyrosine ladders, and C‐terminal heterogeneity. Predictions for the Rnq1 prion and alpha‐synuclein are also given, identifying a similar mix of homogenous and heterogeneous secondary structure elements. STITCHER provides novel insight into the energetic basis of amyloid structure, provides accurate structure predictions, and can help guide future experimental studies. Proteins 2012. © 2011 Wiley Periodicals, Inc.     

Cooperativity of a protein folding reaction probed at multiple chain positions by real-time 2D NMR spectroscopy

The refolding reaction of S54G/P55N ribonuclease T1 is a two-step process, where fast formation of a partly folded intermediate is followed by the slow reaction to the native state, limited by a trans --> cis isomerization of Pro39. The hydrodynamic radius of this kinetic folding intermediate was determined by real-time diffusion NMR spectroscopy. Its folding to the native state was monitored by a series of 128 very fast 2D (15)N-HMQC spectra, to observe the kinetics of 66 individual backbone amide probes. We find that the intermediate is as compact as the native protein with many native chemical shifts. All 66 analyzed amide probes follow the rate-limiting prolyl isomerization, which indicates that this cooperative refolding reaction is fully synchronized. The stability of the folding intermediate was determined from the protection factors of 45 amide protons derived from a competition between refolding and H/D exchange. The intermediate has already gained 40% of the Gibbs free energy of refolding with many protected amides in not-yet-native regions.     

Understanding the contribution of disulfide bridges to the folding and misfolding of an anti‐Aβ scFv

ScFv‐h3D6 is a single chain variable fragment that precludes Aβ peptide‐induced cytotoxicity by withdrawing Aβ oligomers from the amyloid pathway to the worm‐like pathway. Production of scFv molecules is not a straightforward procedure because of the occurrence of disulfide scrambled conformations generated in the refolding process. Here, we separately removed the disulfide bond of each domain and solved the scrambling problem; and then, we intended to compensate the loss of thermodynamic stability by adding three C‐terminal elongation mutations, previously described to stabilize the native fold of scFv‐h3D6. Such stabilization occurred through stabilization of the intermediate state in the folding pathway and destabilization of a different, β‐rich, intermediate state driving to worm‐like fibrils. Elimination of the disulfide bridge of the less stable domain, V_L, deeply compromised the yield and increased the aggregation tendency, but elimination of the disulfide bridge of the more stable domain, V_H, solved the scrambling problem and doubled the production yield. Notably, it also changed the aggregation pathway from the protective worm‐like morphology to an amyloid one. This was so because a partially unfolded intermediate driving to amyloid aggregation was present, instead of the β‐rich intermediate driving to worm‐like fibrils. When combining with the elongation mutants, stabilization of the partially unfolded intermediate driving to amyloid fibrils was the only effect observed. Therefore, the same mutations drove to completely different scenarios depending on the presence of disulfide bridges and this illustrates the relevance of such linkages in the stability of different intermediate states for folding and misfolding.     

A β‐amino acid modified heptapeptide containing a designed recognition element disrupts fibrillization of the amyloid β‐peptide

We study the complex formation of a peptide βAβAKLVFF, previously developed by our group, with Aβ(1–42) in aqueous solution. Circular dichroism spectroscopy is used to probe the interactions between βAβAKLVFF and Aβ(1–42), and to study the secondary structure of the species in solution. Thioflavin T fluorescence spectroscopy shows that the population of fibers is higher in βAβAKLVFF/Aβ(1–42) mixtures compared to pure Aβ(1–42) solutions. TEM and cryo‐TEM demonstrate that co‐incubation of βAβAKLVFF with Aβ(1–42) causes the formation of extended dense networks of branched fibrils, very different from the straight fibrils observed for Aβ(1–42) alone. Neurotoxicity assays show that although βAβAKLVFF alters the fibrillization of Aβ(1–42), it does not decrease the neurotoxicity, which suggests that toxic oligomeric Aβ(1–42) species are still present in the βAβAKLVFF/Aβ(1–42) mixtures. Our results show that our designed peptide binds to Aβ(1–42) and changes the amyloid fibril morphology. This is shown to not necessarily translate into reduced toxicity. Copyright © 2010 European Peptide Society and John Wiley & Sons, Ltd.     

Relationship between stability of folding intermediates and amyloid formation for the yeast prion Ure2p: a quantitative analysis of the effects of pH and buffer system

The dimeric yeast protein Ure2 shows prion-like behaviour in vivo and forms amyloid fibrils in vitro. A dimeric intermediate is populated transiently during refolding and is apparently stabilized at lower pH, conditions suggested to favour Ure2 fibril formation. Here we present a quantitative analysis of the effect of pH on the thermodynamic stability of Ure2 in Tris and phosphate buffers over a 100-fold protein concentration range. We find that equilibrium denaturation is best described by a three-state model via a dimeric intermediate, even under conditions where the transition appears two-state by multiple structural probes. The free energy for complete unfolding and dissociation of Ure2 is up to 50 kcal mol(-1). Of this, at least 20 kcal mol(-1) is contributed by inter-subunit interactions. Hence the native dimer and dimeric intermediate are significantly more stable than either of their monomeric counterparts. The previously observed kinetic unfolding intermediate is suggested to represent the dissociated native-like monomer. The native state is stabilized with respect to the dimeric intermediate at higher pH and in Tris buffer, without significantly affecting the dissociation equilibrium. The effects of pH, buffer, protein concentration and temperature on the kinetics of amyloid formation were quantified by monitoring thioflavin T fluorescence. The lag time decreases with increasing protein concentration and fibril formation shows pseudo-first order kinetics, consistent with a nucleated assembly mechanism. In Tris buffer the lag time is increased, suggesting that stabilization of the native state disfavours amyloid nucleation.     

Slow formation of aggregation‐resistant β‐sheet folding intermediates

Protein folding has been studied extensively for decades, yet our ability to predict how proteins reach their native state from a mechanistic perspective is still rudimentary at best, limiting our understanding of folding‐related processes in vivo and our ability to manipulate proteins in vitro. Here, we investigate the in vitro refolding mechanism of a large β‐helix protein, pertactin, which has an extended, elongated shape. At 55 kDa, this single domain, all‐β‐sheet protein allows detailed analysis of the formation of β‐sheet structure in larger proteins. Using a combination of fluorescence and far‐UV circular dichroism spectroscopy, we show that the pertactin β‐helix refolds remarkably slowly, with multiexponential kinetics. Surprisingly, despite the slow refolding rates, large size, and β‐sheet‐rich topology, pertactin refolding is reversible and not complicated by off‐pathway aggregation. The slow pertactin refolding rate is not limited by proline isomerization, and 30% of secondary structure formation occurs within the rate‐limiting step. Furthermore, site‐specific labeling experiments indicate that the β‐helix refolds in a multistep but concerted process involving the entire protein, rather than via initial formation of the stable core substructure observed in equilibrium titrations. Hence pertactin provides a valuable system for studying the refolding properties of larger, β‐sheet‐rich proteins, and raises intriguing questions regarding the prevention of aggregation during the prolonged population of partially folded, β‐sheet‐rich refolding intermediates. Proteins 2010. © 2009 Wiley‐Liss, Inc.     

Solid-state NMR as a method to reveal structure and membrane-interaction of amyloidogenic proteins and peptides

It is important to understand the Amyloid fibril formation in view of numerous medical and biochemical aspects. Structural determination of amyloid fibril has been extensively studied using electron microscopy. Subsequently, solid state NMR spectroscopy has been realized to be the most important means to determine not only microscopic molecular structure but also macroscopic molecular packing. Molecular structure of amyloid fibril was first predicted to be parallel β-sheet structure, and subsequently, was further refined for Aβ(1-40) to be cross β-sheet with double layered in register parallel β-sheet structure by using solid state NMR spectroscopy. On the other hand, anti-parallel β-sheet structure has been reported to short fragments of Aβ-amyloid and other amyloid forming peptides. Kinetic study of amyloid fibril formation has been studied using a variety of methods, and two-step autocatalytic reaction mechanism used to explain fibril formation. Recently, stable intermediates or proto-fibrils have been observed by electron microscope (EM) images. Some of the intermediates have the same microscopic structure as the matured fibril and subsequently change to matured fibrils. Another important study on amyloid fibril formation is determination of the interaction with lipid membranes, since amyloid peptide are cleaved from amyloid precursor proteins in the membrane interface, and it is reported that amyloid lipid interaction is related to the cytotoxicity. Finally it is discussed how amyloid fibril formation can be inhibited. Firstly, properly designed compounds are reported to have inhibition ability of amyloid fibril formation by interacting with amyloid peptide. Secondly, it is revealed that site directed mutation can inhibit amyloid fibril formation. These inhibitors were developed by knowing the fibril structure determined by solid state NMR.     

β‐amyloid model core peptides: Effects of hydrophobes and disulfides

The mechanism by which a disordered peptide nucleates and forms amyloid is incompletely understood. A central domain of β‐amyloid (Aβ21–30) has been proposed to have intrinsic structural propensities that guide the limited formation of structure in the process of fibrillization. In order to test this hypothesis, we examine several internal fragments of Aβ, and variants of these either cyclized or with an N‐terminal Cys. While Aβ21–30 and variants were always monomeric and unstructured (circular dichroism (CD) and nuclear magnetic resonance spectroscopy (NMRS)), we found that the addition of flanking hydrophobic residues in Aβ16–34 led to formation of typical amyloid fibrils. NMR showed no long‐range nuclear overhauser effect (nOes) in Aβ21–30, Aβ16–34, or their variants, however. Serial ¹H‐¹⁵N‐heteronuclear single quantum coherence spectroscopy, ¹H‐¹H nuclear overhauser effect spectroscopy, and ¹H‐¹H total correlational spectroscopy spectra were used to follow aggregation of Aβ16–34 and Cys‐Aβ16–34 at a site‐specific level. The addition of an N‐terminal Cys residue (in Cys‐Aβ16–34) increased the rate of fibrillization which was attributable to disulfide bond formation. We propose a scheme comparing the aggregation pathways for Aβ16–34 and Cys‐Aβ16–34, according to which Cys‐Aβ16–34 dimerizes, which accelerates fibril formation. In this context, cysteine residues form a focal point that guides fibrillization, a role which, in native peptides, can be assumed by heterogeneous nucleators of aggregation.