Domain swapping and amyloid fibril conformation

For several different proteins an apparent correlation has been observed between the propensity for dimerization by domain-swapping and the ability to aggregate into amyloid-like fibrils. Examples include the disease-related proteins β₂-microglobulin and transthyretin. This has led to proposals that the amyloid-formation pathway may feature extensive domain swapping. One possible consequence of such an aggregation pathway is that the resulting fibrils would incorporate structural elements that resemble the domain-swapped forms of the protein and, thus, reflect certain native-like structures or domain-interactions. In magic angle spinning solid-state NMR-based and other structural studies of such amyloid fibrils, it appears that many of these proteins form fibrils that are not native-like. Several fibrils, instead, have an in-register, parallel conformation, which is a common amyloid structural motif and is seen, for instance, in various prion fibrils. Such a lack of native structure in the fibrils suggests that the apparent connection between domain-swapping ability and amyloid-formation may be more subtle or complex than may be presumed at first glance.     

Amyloid-like fibrils from a domain-swapping protein feature a parallel, in-register conformation without native-like interactions

The formation of amyloid-like fibrils is characteristic of various diseases, but the underlying mechanism and the factors that determine whether, when, and how proteins form amyloid, remain uncertain. Certain mechanisms have been proposed based on the three-dimensional or runaway domain swapping, inspired by the fact that some proteins show an apparent correlation between the ability to form domain-swapped dimers and a tendency to form fibrillar aggregates. Intramolecular β-sheet contacts present in the monomeric state could constitute intermolecular β-sheets in the dimeric and fibrillar states. One example is an amyloid-forming mutant of the immunoglobulin binding domain B1 of streptococcal protein G, which in its native conformation consists of a four-stranded β-sheet and one α-helix. Under native conditions this mutant adopts a domain-swapped dimer, and it also forms amyloid-like fibrils, seemingly in correlation to its domain-swapping ability. We employ magic angle spinning solid-state NMR and other methods to examine key structural features of these fibrils. Our results reveal a highly rigid fibril structure that lacks mobile domains and indicate a parallel in-register β-sheet structure and a general loss of native conformation within the mature fibrils. This observation contrasts with predictions that native structure, and in particular intermolecular β-strand interactions seen in the dimeric state, may be preserved in "domain-swapping" fibrils. We discuss these observations in light of recent work on related amyloid-forming proteins that have been argued to follow similar mechanisms and how this may have implications for the role of domain-swapping propensities for amyloid formation.     

Folding and Fibrillogenesis: Clues from β2-Microglobulin

Renal failure impairs the clearance of β₂-microglobulin from the serum, with the result that this protein accumulates in joints under the form of amyloid fibrils. While the molecular mechanism leading to deposition of amyloid in vivo is not totally understood, some organic compounds, such as trifluoroethanol (TFE), are commonly used to promote the elongation of amyloid fibrils in vitro. This article gives some insights into the structural properties and the conformational states of β₂-microglobulin in the presence of TFE, using both the wild-type protein and the mutant Trp60Gly. The structure of the native state of the protein is rather insensitive to the presence of the alcohol, but the stability of this state is lowered in comparison to some other conformational states. In particular, a native-like folding intermediate is observed in the presence of moderate concentrations of TFE. Instead, at higher concentrations of the alcohol, the population of a disordered native-unlike state is dominant and correlates with the ability to elongate fibrils.     

Hsp104 targets multiple intermediates on the amyloid pathway and suppresses the seeding capacity of Abeta fibrils and protofibrils

The heat shock protein Hsp104 has been reported to possess the ability to modulate protein aggregation and toxicity and to “catalyze” the disaggregation and recovery of protein aggregates, including amyloid fibrils, in yeast, Escherichia coli, mammalian cell cultures, and animal models of Huntington's disease and Parkinson's disease. To provide mechanistic insight into the molecular mechanisms by which Hsp104 modulates aggregation and fibrillogenesis, the effect of Hsp104 on the fibrillogenesis of amyloid beta (Aβ) was investigated by characterizing its ability to interfere with oligomerization and fibrillogenesis of different species along the amyloid-formation pathway of Aβ. To probe the disaggregation activity of Hsp104, its ability to dissociate preformed protofibrillar and fibrillar aggregates of Aβ was assessed in the presence and in the absence of ATP. Our results show that Hsp104 inhibits the fibrillization of monomeric and protofibrillar forms of Aβ in a concentration-dependent but ATP-independent manner. Inhibition of Aβ fibrillization by Hsp104 is observable up to Hsp104/Aβ stoichiometric ratios of 1:1000, suggesting a preferential interaction of Hsp104 with aggregation intermediates (e.g., oligomers, protofibrils, small fibrils) on the pathway of Aβ amyloid formation. This hypothesis is consistent with our observations that Hsp104 (i) interacts with Aβ protofibrils, (ii) inhibits conversion of protofibrils into amyloid fibrils, (iii) arrests fibril elongation and reassembly, and (iv) abolishes the capacity of protofibrils and sonicated fibrils to seed the fibrillization of monomeric Aβ. Together, these findings suggest that the strong inhibition of Aβ fibrillization by Hsp104 is mediated by its ability to act at different stages and target multiple intermediates on the pathway to amyloid formation.     

Exclusion of the native alpha-helix from the amyloid fibrils of a mixed alpha/beta protein

Members of the cystatin superfamily are involved in an inherited form of cerebral amyloid angiopathy and readily form amyloid fibrils in vitro. We have determined the structured core of human stefin B (cystatin B) amyloid fibrils using quenched hydrogen exchange and NMR. The core contains residues from four of the five strands of the native β-sheet, delimited by unprotected loop regions analogous to those of the native monomeric structure. However, non-native features are also apparent, the most striking of which is the exclusion of the native α-helix. Before forming amyloid in vitro, cystatins dimerise via 3D domain swapping, and assemble into tetramers with trans to cis isomerism of a conserved proline. In the fibril, the hinge loop that forms an extended β-structure in the dimer remains protected, consistent with the domain-swapping interface being maintained. However, the fibril data are not compatible with a simple 3D domain-swapping model for amyloid formation, and the displacement of the helix points to alternative packing arrangements of native-like β-structure, in which proline isomerism is important in preventing steric clashing.     

The Folding Pathway of the Antibody VL Domain

Antibodies are modular proteins consisting of domains that exhibit a β-sandwich structure, the so-called immunoglobulin fold. Despite structural similarity, differences in folding and stability exist between different domains. In particular, the variable domain of the light chain V_L is unusual as it is associated with misfolding diseases, including the pathologic assembly of the protein into fibrillar structures. Here, we have analysed the folding pathway of a V_L domain with a view to determine features that may influence the relationship between productive folding and fibril formation. The V_L domain from MAK33 (murine monoclonal antibody of the subtype κ/IgG1) has not previously been associated with fibrillisation but is shown here to be capable of forming fibrils. The folding pathway of this V_L domain is complex, involving two intermediates in different pathways. An obligatory early molten globule-like intermediate with secondary structure but only loose tertiary interactions is inferred. The native state can then be formed directly from this intermediate in a phase that can be accelerated by the addition of prolyl isomerases. However, an alternative pathway involving a second, more native-like intermediate is also significantly populated. Thus, the protein can reach the native state via two distinct folding pathways. Comparisons to the folding pathways of other antibody domains reveal similarities in the folding pathways; however, in detail, the folding of the V_L domain is striking, with two intermediates populated on different branches of the folding pathway, one of which could provide an entry point for molecules diverted into the amyloid pathway.     

Strong acids induce amyloid fibril formation of β2-microglobulin via an anion-binding mechanism

Amyloid fibrils, crystal-like fibrillar aggregates of proteins associated with various amyloidoses, have the potential to propagate via a prion-like mechanism. Among known methodologies to dissolve preformed amyloid fibrils, acid treatment has been used with the expectation that the acids will degrade amyloid fibrils similar to acid inactivation of protein functions. Contrary to our expectation, treatment with strong acids, such as HCl or H₂SO₄, of β₂-microglobulin (β2m) or insulin actually promoted amyloid fibril formation, proportionally to the concentration of acid used. A similar promotion was observed at pH 2.0 upon the addition of salts, such as NaCl or Na₂SO₄. Although trichloroacetic acid, another strong acid, promoted amyloid fibril formation of β2m, formic acid, a weak acid, did not, suggesting the dominant role of anions in promoting fibril formation of this protein. Comparison of the effects of acids and salts confirmed the critical role of anions, indicating that strong acids likely induce amyloid fibril formation via an anion-binding mechanism. The results suggest that although the addition of strong acids decreases pH, it is not useful for degrading amyloid fibrils, but rather induces or stabilizes amyloid fibrils via an anion-binding mechanism.     

Structure,Folding Dynamics,and Amyloidogenesis of D76N β2-Microglobulin: ROLES OF SHEAR FLOW,HYDROPHOBIC SURFACES,AND α-CRYSTALLIN*

Systemic amyloidosis is a fatal disease caused by misfolding of native globular proteins, which then aggregate extracellularly as insoluble fibrils, damaging the structure and function of affected organs. The formation of amyloid fibrils in vivo is poorly understood. We recently identified the first naturally occurring structural variant, D76N, of human β₂-microglobulin (β₂m), the ubiquitous light chain of class I major histocompatibility antigens, as the amyloid fibril protein in a family with a new phenotype of late onset fatal hereditary systemic amyloidosis. Here we show that, uniquely, D76N β₂m readily forms amyloid fibrils in vitro under physiological extracellular conditions. The globular native fold transition to the fibrillar state is primed by exposure to a hydrophobic-hydrophilic interface under physiological intensity shear flow. Wild type β₂m is recruited by the variant into amyloid fibrils in vitro but is absent from amyloid deposited in vivo. This may be because, as we show here, such recruitment is inhibited by chaperone activity. Our results suggest general mechanistic principles of in vivo amyloid fibrillogenesis by globular proteins, a previously obscure process. Elucidation of this crucial causative event in clinical amyloidosis should also help to explain the hitherto mysterious timing and location of amyloid deposition.     

Thermal Response with Exothermic Effects of β2-Microglobulin Amyloid Fibrils and Fibrillation

Calorimetric measurements were carried out using a differential scanning calorimeter to characterize the thermal response of β₂-microglobulin amyloid fibrils, the deposition of which results in dialysis-related amyloidosis. The fibril solution showed a large decrease in heat capacity (exothermic effect) before the temperature-induced depolymerization of the fibrils, which was characterized by a definite dependence on heating rate. To understand the factors that determine the heating-rate-dependent thermal response, the concentration dependence of polyethylene glycol, which inhibits the association of amyloid fibrils with heating, on exothermic effect was examined in detail and showed a causal link between the exothermic effect and fibril association. The results suggest that the transient association driven by a spatial approach and the concomitant dehydration of hydrophobic areas of amyloid fibrils may be significant factors determining the thermal response with exothermic effect, which has not been observed in calorimetric studies of monomolecular globular proteins. The heating-rate-dependent thermal response with the exothermic effect was observed not only for other amyloid fibrils formed from amyloid β-peptides but also during the processes of the temperature-induced conversion of β₂-microglobulin protofibrils and hen egg-white lysozyme into amyloid fibrils. These results highlight the physics related to the heating-rate-dependent behaviors of heat capacity in terms of interactions between the specific structures of amyloid fibrils and water molecules.     

Expanding the Repertoire of Amyloid Polymorphs by Co-polymerization of Related Protein Precursors

Amyloid fibrils can be generated from proteins with diverse sequences and folds. Although amyloid fibrils assembled in vitro commonly involve a single protein precursor, fibrils formed in vivo can contain more than one protein sequence. How fibril structure and stability differ in fibrils composed of single proteins (homopolymeric fibrils) from those generated by co-polymerization of more than one protein sequence (heteropolymeric fibrils) is poorly understood. Here we compare the structure and stability of homo and heteropolymeric fibrils formed from human β₂-microglobulin and its truncated variant ΔN6. We use an array of approaches (limited proteolysis, magic angle spinning NMR, Fourier transform infrared spectroscopy, and fluorescence) combined with measurements of thermodynamic stability to characterize the different fibril types. The results reveal fibrils with different structural properties, different side-chain packing, and strikingly different stabilities. These findings demonstrate how co-polymerization of related precursor sequences can expand the repertoire of structural and thermodynamic polymorphism in amyloid fibrils to an extent that is greater than that obtained by polymerization of a single precursor alone.     

A Generic Mechanism of β2-Microglobulin Amyloid Assembly at Neutral pH Involving a Specific Proline Switch

Although numerous measurements of amyloid assembly of different proteins under distinct conditions in vitro have been performed, the molecular mechanisms underlying the specific self-association of proteins into amyloid fibrils remain obscure. Elucidating the nature of the events that initiate amyloid formation remains a particularly difficult challenge because of the heterogeneity and transient nature of the species involved. Here, we have used site-directed mutagenesis to create five proline to glycine variants in the naturally amyloidogenic protein β₂-microglobulin (β₂m). One of these variants, P5G, allowed us to isolate and characterise an intermediate containing a non-native trans Pro32 backbone conformation, a feature that is known to be required for amyloid elongation at neutral pH. By analysing oligomerisation and amyloid formation using analytical size-exclusion chromatography, multi-angle static light-scattering, analytical ultracentrifugation, circular dichroism and thioflavin T fluorescence we reveal a pathway for β₂m amyloid assembly at pH 7.5 that does not require the addition of metal ions, detergents, co-solvents or other co-factors that have been used to facilitate amyloid formation at physiological pH and temperature. Assembly is shown to involve the transient formation of a non-native monomer containing a trans P32 backbone conformation. This is followed by the formation of dimeric species and higher molecular mass oligomers that accumulate before the development of amyloid fibrils. On the basis of these results, we propose a generic mechanism for β₂m fibrillogenesis at neutral pH that is consistent with the wide range of published studies of this protein. In this mechanism, amyloid formation is initiated by a specific cis to trans proline switch, the rate of which we show to be controlled by the amino acid sequence proximal to P32 and to the applied solution conditions.     

Ultrasonication-dependent acceleration of amyloid fibril formation

Amyloid fibrils, similar to crystals, form through nucleation and growth. Because of the high free-energy barrier of nucleation, the spontaneous formation of amyloid fibrils occurs only after a long lag phase. Ultrasonication is useful for inducing amyloid nucleation and thus for forming fibrils, while the use of a microplate reader with thioflavin T fluorescence is suitable for detecting fibrils in many samples simultaneously. Combining the use of ultrasonication and microplate reader, we propose an efficient approach to studying the potential of proteins to form amyloid fibrils. With β₂-microglobulin, an amyloidogenic protein responsible for dialysis-related amyloidosis, fibrils formed within a few minutes at pH 2.5. Even under neutral pH conditions, fibrils formed after a lag time of 1.5 h. The results propose that fibril formation is a physical reaction that is largely limited by the high free-energy barrier, which can be effectively reduced by ultrasonication. This approach will be useful for developing a high-throughput assay of the amyloidogenicity of proteins.     

A β2-microglobulin cleavage variant fibrillates at near-physiological pH

β₂-microglobulin (β₂m) deposits as amyloid in dialysis-related amyloidosis (DRA), predominantly in joints. The molecular mechanisms underlying the amyloidogenicity of β₂m are still largely unknown. In vitro, acidic conditions, pH < 4.5, induce amyloid fibrillation of native β₂m within several days. Here, we show that amyloid fibrils are generated in less than an hour when a cleavage variant of β₂m—found in the circulation of many dialysis patients—is exposed to pH levels (pH 6.6) occurring in joints during inflammation. Aggregation and fibrillation, including seeding effects with intact, native β₂m were studied by Thioflavin T fluorescence spectroscopy, turbidimetry, capillary electrophoresis, and electron microscopy. We conclude that a biologically relevant variant of β₂m is amyloidogenic at slightly acidic pH. Also, only a very small amount of preformed fibrils of this variant is required to induce fibrillation of native β₂m. This may explain the apparent lack of detectable amounts of the variant β₂m in extracts of amyloid from DRA patients.     

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.     

Conformational stability of amyloid fibrils of beta2-microglobulin probed by guanidine-hydrochloride-induced unfolding

Although the stability of globular proteins has been studied extensively, that of amyloid fibrils is scarcely characterized. Beta2-microglobulin (beta2-m) is a major component of the amyloid fibrils observed in patients with dialysis-related amyloidosis. We studied the effects of guanidine hydrochloride on the amyloid fibrils of beta2-m, revealing a cooperative unfolding transition similar to that of the native state. The stability of amyloid fibrils increased on the addition of ammonium sulfate, consistent with a role of hydrophobic interactions. The results indicate that the analysis of unfolding transition is useful to obtain insight into the structural stability of amyloid fibrils.     

Amyloid fibrils formed by the programmed cell death regulator Bcl-xL

The accumulation of amyloid fibers due to protein misfolding is associated with numerous human diseases. For example, the formation of amyloid deposits in neurodegenerative pathologies is correlated with abnormal apoptosis. We report here the in vitro formation of various types of aggregates by Bcl-xL, a protein of the Bcl-2 family involved in the regulation of apoptosis. Bcl-xL forms aggregates in three states, micelles, native-like fibrils, and amyloid fibers, and their biophysical characterization has been performed in detail. Bcl-xL remains in its native state within micelles and native-like fibrils, and our results suggest that native-like fibrils are formed by the association of micelles. Formation of amyloid structures, that is, nonnative intermolecular β-sheets, is favored by the proximity of proteins within fibrils at the expense of the Bcl-xL native structure. Finally, we provide evidence of a direct relationship between the amyloid character of the fibers and the tertiary-structure stability of the native Bcl-xL. The potential causality between the accumulation of Bcl-xL into amyloid deposits and abnormal apoptosis during neurodegenerative diseases is discussed.     

Insights into the molecular mechanism of protein native-like aggregation upon glycation

Several human neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease and Familial Amyloidotic Polyneuropathy, have long been associated with, structural and functional changes in disease related proteins leading to aggregation into amyloid fibrils. Such changes can be triggered by post-translational modifications. Methylglyoxal modifications have been shown to induce the formation of small and stable native-like aggregates in the case of the amyloidogenic proteins insulin and α-synuclein. However, the fundamental biophysical mechanism underlying such methylglyoxal-induced protein aggregation is not yet fully understood. In this work cytochrome c (Cyt c) was used as a model protein for the characterization of specific glycation targets and to study their impact on protein structure, stability, and ability to form native-like aggregates. Our results show that methylglyoxal covalently modifies Cyt c at a single residue and induces early conformational changes that lead to the formation of native-like aggregates. Furthermore, partially unfolded species are formed, but do not seem to be implicated in the aggregation process. This shows a clear difference from the amyloid fibril mechanisms which involve partially or totally unfolded intermediates. Equilibrium-unfolding experiments show that glycation strongly decreases Cyt c conformational stability, which is balanced with an increase of conformational stability upon aggregation. Data collected from analytical and spectroscopic techniques, along with kinetic analysis based on least-squares parameter fitting and statistical model discrimination are used to help to understand the driving force underlying glycation-induced native-like aggregation, and enable the proposal of a comprehensive thermodynamic and kinetic model for native-like aggregation of methylglyoxal glycated Cyt c.     

Main-chain dominated amyloid structures demonstrated by the effect of high pressure

It has been suggested that, while the globular native forms of proteins are a side-chain-dominated compact structure evolved by pursuing a unique fold with optimal packing of amino acid residues, amyloid fibrils are a main-chain-dominated structure with an extensive hydrogen bond network. To address this issue, the effects of hydrostatic pressure on amyloid fibrils of beta2-microglobulin (beta2-m), involved in dialysis-related amyloidosis, were studied. A systematic analysis at various pressures and concentrations of guanidine hydrochloride conducted by monitoring thioflavin T fluorescence, light-scattering, and tryptophan fluorescence revealed contrasting conformational changes occurring consecutively: first, a pressure-induced reorganization of fibrils and then a pressure-induced unfolding. The changes in volume as well as the observed structural changes indicate that the beta2-m amyloid fibrils under ambient pressure are less tightly packed with a larger number of cavities, consistent with the main-chain-dominated amyloid structure. Moreover, the amyloid structure without optimal packing will enable various isoforms to form, suggesting the structural basis of multiple forms of amyloid fibrils in contrast to the unique native-fold.     

Amyloid formation under physiological conditions proceeds via a native-like folding intermediate

Although most proteins can assemble into amyloid-like fibrils in vitro under extreme conditions, how proteins form amyloid fibrils in vivo remains unresolved. Identifying rare aggregation-prone species under physiologically relevant conditions and defining their structural properties is therefore an important challenge. By solving the folding mechanism of the naturally amyloidogenic protein beta-2-microglobulin at pH 7.0 and 37 degrees C and correlating the concentrations of different species with the rate of fibril elongation, we identify a specific folding intermediate, containing a non-native trans-proline isomer, as the direct precursor of fibril elongation. Structural analysis using NMR shows that this species is highly native-like but contains perturbation of the edge strands that normally protect beta-sandwich proteins from self-association. The results demonstrate that aggregation pathways can involve self-assembly of highly native-like folding intermediates, and have implications for the prevention of this, and other, amyloid disorders.