Identification of the interfacial regions in misfolded transthyretin oligomers.

Misfolding and aggregation of transthyretin (TTR) is associated with numerous ATTR amyloidosis. TTR aggregates extracted from ATTR patients consist of not only full-length TTR, but also N-terminally truncated TTR fragments that can be produced by proteolytic cleavage, suggesting the presence of multiple misfolding pathways. Here, we report mechanistic studies of an early stage of TTR aggregation to probe the oligomerization process for the full-length as well as N-terminally truncated TTR. Our kinetic analyses using size exclusion chromatography revealed that amyloidogenic monomers dissociated from wild-type (WT) as well as pathogenic variants (V30M and L55P) form misfolded dimers, which self-assemble into oligomers, precursors of fibril formation. Dimeric interfaces in the full-length misfolded oligomers were investigated by examining the effect of single-point mutations on the two ß-strands (F and H). The single-point mutations on the two ß-strands (E92P on strand F and T119W on strand H) inhibited the dimerization of misfolded monomers, while the TTR variants can still form native dimers through the same F and H strands. These results suggest that the two strands are involved in intermolecular associations for both native and misfolded dimers, but detailed intermolecular interactions are different in the two forms of dimers. In the presence of a proteolytic enzyme, TTR aggregation is greatly accelerated. The two mutations on the two ß-strands, however, inhibited TTR aggregation even in the presence of a proteolytic enzyme, trypsin. These results suggest that the two ß-strands (F and H) play a critical role in aggregation of the N-terminally truncated TTR as well.

Characterization of α-synuclein oligomers formed in the presence of lipid vesicles.

Aggregation of α-synuclein into oligomers and fibrils is associated with numerous neurodegenerative diseases such as Parkinson's disease (PD). Although the identity of the pathogenic species formed during the aggregation process is still under active debate, mounting evidence suggests that small oligomeric species rather than fibrillar aggregates are real toxic species. Isolation and characterization of small oligomers is essential to developing therapeutic strategies to prevent oligomer formation. Preparation of misfolded oligomeric species for biophysical characterization is, however, a great challenge due to their heterogenous, transient nature. Here we report the preparation of toxic and non-toxic α-synuclein oligomeric species formed at different pH values in the presence of lipid vesicles that mimic mitochondria membranes containing cardiolipin. Biophysical characterization of the lipid-induced α-synuclein oligomeric assemblies revealed that α-synuclein oligomers formed at pH 7.4 have higher surface hydrophobicity than the aggregates formed at pH 6.0. In addition, the high-pH oligomers were shown to exhibit higher toxicity than the low-pH aggregates. Structural, dynamic properties of the oligomers were also investigated by using circular dichroism (CD) and NMR spectroscopy. Our CD analyses revealed that the two oligomeric species have distinct molecular conformations, and 2D 1H/15N HSQC NMR experiments suggested that the high-pH oligomers have more extended dynamic regions than the low-pH aggregates. The distinct structural and dynamic properties of the oligomers might be associated with their different cytotoxic properties.

CD and Solid-State NMR Studies of Low-Order Oligomers of Transthyretin.

Characterization of oligomeric intermediate states populated at an early stage of misfolding and aggregation is essential to understanding molecular mechanism of pathogenic protein aggregation. Growing evidence also suggests that oligomeric species are more toxic than mature fibrillar counterparts. Here, we describe procedures for isolating oligomeric species of an aggregation-prone protein, transthyretin, associated with protein misfolding disorders, including cardiomyopathy and polyneuropathy. We also describe methods for structural studies of the oligomeric species using circular dichroism and solid-state NMR spectroscopy. These methods can be applied to structural characterization of oligomeric intermediates of other aggregation-prone proteins.

Toxic Misfolded Transthyretin Oligomers with Different Molecular Conformations Formed through Distinct Oligomerization Pathways.

Protein aggregation is initiated by structural changes from native polypeptides to cytotoxic oligomers, which form cross-ß structured amyloid. Identification and characterization of oligomeric intermediates are critically important for understanding not only the molecular mechanism of aggregation but also the cytotoxic nature of amyloid oligomers. Preparation of misfolded oligomers for structural characterization is, however, challenging because of their transient, heterogeneous nature. Here, we report two distinct misfolded transthyretin (TTR) oligomers formed through different oligomerization pathways. A pathogenic TTR variant with a strong aggregation propensity (L55P) was used to prepare misfolded oligomers at physiological pH. Our mechanistic studies showed that the full-length TTR initially forms small oligomers, which self-assemble into short protofibrils at later stages. Enzymatic cleavage of the CD loop was also used to induce the formation of N-terminally truncated oligomers, which was detected in ex vivo cardiac TTR aggregates extracted from the tissues of patients. Structural characterization of the oligomers using solid-state nuclear magnetic resonance and circular dichroism revealed that the two TTR misfolded oligomers have distinct molecular conformations. In addition, the proteolytically cleaved TTR oligomers exhibit a higher surface hydrophobicity, suggesting the presence of distinct oligomerization pathways for TTR oligomer formation. Cytotoxicity assays also revealed that the cytotoxicity of cleaved oligomers is stronger than that of the full-length TTR oligomers, indicating that hydrophobicity might be an important property of toxic oligomers. These comparative biophysical analyses suggest that the toxic cleaved TTR oligomers formed through a different misfoling pathway may adopt distinct structural features that produce higher surface hydrophobicity, leading to the stronger cytotoxic activities.

Untwisted α-Synuclein Filaments Formed in the Presence of Lipid Vesicles.

Accumulation of filamentous aggregates of α-synuclein is a pathological hallmark of several neurodegenerative diseases, including Parkinson's disease (PD). The interaction between α-synuclein and phospholipids has been shown to play a critical role in the aggregation of α-synuclein. Most structural studies have, however, been focused on α-synuclein filaments formed in the absence of lipids. Here, we report the structural investigation of α-synuclein filaments assembled under the quiescent condition in the presence of anionic lipid vesicles using electron microscopy (EM), including cryogenic electron microscopy (cryo-EM). Our transmission electron microscopy (TEM) analyses reveal that α-synuclein forms curly protofilaments at an early stage of aggregation. The flexible protofilaments were then converted to long filaments after a longer incubation of 30 days. More detailed structural analyses using cryo-EM reveal that the long filaments adopt untwisted structures with different diameters, which have not been observed in previous α-synuclein fibrils formed in vitro. The untwisted filaments are rather similar to straight filaments with no observable twist that are extracted from patients with dementia with Lewy bodies. Our structural studies highlight the conformational diversity of α-synuclein filaments, requiring additional structural investigation of not only more ex vivo α-synuclein filaments but also in vitro α-synuclein filaments formed in the presence of diverse cofactors to better understand the molecular basis of diverse molecular conformations of α-synuclein filaments.

Tau induces formation of α-synuclein filaments with distinct molecular conformations.

Recent structural investigation of amyloid filaments extracted from human patients demonstrated that the ex vivo filaments associated with different disease phenotypes adopt diverse molecular conformations, which are different from those of in vitro amyloid filaments. A very recent cryo-EM structural study also revealed that ex vivo α-synuclein filaments extracted from multiple system atrophy patients adopt distinct molecular structures from those of in vitro α-synuclein filaments, suggesting the presence of co-factors for α-synuclein aggregation in vivo. Here, we report structural characterizations of α-synuclein filaments formed in the presence of a potential co-factor, tau, using cryo-EM and solid-state NMR. Our cryo-EM structure of the tau-promoted α-synuclein filaments reveals some similarities to one of the previously reported polymorphs of in vitro α-synuclein filaments in the core region, while illustrating distinct conformations in the N- and C-terminal regions. The structural study highlights the conformational plasticity of α-synuclein filaments and the importance of the co-factors, requiring additional structural investigation of not only more ex vivo α-synuclein filaments, but also in vitro α-synuclein filaments formed in the presence of diverse co-factors. The comparative structural analyses will help better understand molecular basis of diverse structures of α-synuclein filaments and possible relevance of each structure to the disease phenotype.

Covalent and non-covalent strategies for the immobilization of Tobacco Etch Virus protease (TEVp) on superparamagnetic nanoparticles.

Proteases with highly specific activities have numerous applications, including the cleavage of affinity tags (Flag; HA; His6X) and solubility promoting partners (GST; MBP) within the context of protein isolation and purification schemes. However, commercially sourced proteases such as Tobacco Etch Virus protease (TEVp) and Human Rhinovirus (HRV) 3C protease are typically applied as single use aliquots, which limits their cost-effectiveness. In addition, the presence of residual proteases in downstream applications can complicate analysis of the protein of interest. Thus, the creation of immobilized, reusable site-specific proteases would be of significant value to the life science community. In this work, we explore two strategies for the immobilization of TEV protease onto superparamagnetic iron oxide nanoparticles (SPIONs). In one strategy, a MBP-TEVp-Streptavidin fusion protein is immobilized on biotin-functionalized SPIONs. In a second strategy, TEV protease is covalently coupled onto SPIONs directly, via amine-mediated attachment, and indirectly, via HALO-tag mediated attachment. We demonstrate activity of our immobilized proteases in the presence of a MBP-GFP fusion protein containing the TEV protease target sequence (ENLYFQ|S). We then analyze time-dependent activity, longevity, and reuse of these immobilized protein preparations, comparing each approach. The protease immobilization strategies described in this work may be useful tools for simplifying challenging protein purification protocols, in addition to providing general methods for enzyme immobilization on SPIONs.

Disruption of the CD Loop by Enzymatic Cleavage Promotes the Formation of Toxic Transthyretin Oligomers through a Common Transthyretin Misfolding Pathway.

Amyloid formation of full-length TTR involves dissociation of the native tetramers into misfolded monomers that self-assemble into amyloid. In addition to the full-length TTR, C-terminal fragments including residues 49-127 were also observed in vivo, implying the presence of additional misfolding pathways. It was previously proposed that a proteolytic cleavage might lead to the formation of the C-terminal fragment TTR amyloid. Here, we report mechanistic studies of misfolding and aggregation of a TTR variant (G53A) in the absence and presence of a serine protease. A proteolytic cleavage of G53A in the CD loop (K48 and T49) with agitation promoted TTR misfolding and aggregation, suggesting that the proteolytic cleavage may lead to the aggregation of the C-terminal fragment (residues 49-127). To gain more detailed insights into TTR misfolding promoted by proteolytic cleavage, we investigated structural changes in G53A TTR in the presence and absence of trypsin. Our combined biophysical analyses revealed that the proteolytic cleavage accelerated the formation of spherical small oligomers, which exhibited cytotoxic activities. However, the truncated TTR appeared to maintain native-like structures, rather than the C-terminal fragment (residues 49-127) being released and unfolded from the native state. In addition, our solid-state nuclear magnetic resonance and Fourier transform infrared structural studies showed that the two aggregates derived from the full-length and cleaved TTR exhibited nearly identical molecular structural features, suggesting that the proteolytic cleavage in the CD loop destabilizes the native tetrameric structure and accelerates oligomer formation through a common TTR misfolding and aggregation mechanism rather than through a distinct molecular mechanism.

Structural Characterization of Cardiac Ex Vivo Transthyretin Amyloid: Insight into the Transthyretin Misfolding Pathway In Vivo.

Structural characterization of misfolded protein aggregates is essential to understanding the molecular mechanism of protein aggregation associated with various protein misfolding disorders. Here, we report structural analyses of ex vivo transthyretin aggregates extracted from human cardiac tissue. Comparative structural analyses of in vitro and ex vivo transthyretin aggregates using various biophysical techniques revealed that cardiac transthyretin amyloid has structural features similar to those of in vitro transthyretin amyloid. Our solid-state nuclear magnetic resonance studies showed that in vitro amyloid contains extensive nativelike ß-sheet structures, while other loop regions including helical structures are disrupted in the amyloid state. These results suggest that transthyretin undergoes a common misfolding and aggregation transition to nativelike aggregation-prone monomers that self-assemble into amyloid precipitates in vitro and in vivo.

Tau Interacts with the C-Terminal Region of α-Synuclein, Promoting Formation of Toxic Aggregates with Distinct Molecular Conformations.

An increasing body of evidence suggests that aggregation-prone proteins associated with various neurodegenerative diseases synergistically promote their mutual aggregation, leading to the co-occurrence of multiple neurodegenerative diseases in the same patient. Here we investigated teh molecular basis of synergistic interactions between the two pathological proteins, tau and α-synuclein, using various biophysical techniques including transmission electron microscopy (TEM), circular dichroism (CD), and solution and solid-state NMR. Our biophysical analyses of α-synuclein aggregation in the absence and presence of tau reveal that tau monomers promote the formation of α-synuclein oligomers and subsequently fibril formation. Solution NMR results also indicate that monomeric forms of tau selectively interact with the C-terminal region of the α-synuclein monomer, accelerating α-synuclein aggregation. In addition, a combined use of TEM and solid-state NMR spectroscopy reveals that the synergistic interactions lead to the formation of toxic α-synuclein aggregates with a distinct morphology and molecular conformation. The filamentous α-synuclein aggregates as well as α-synuclein monomers were also able to induce tau aggregation.

Transthyretin Aggregation Pathway toward the Formation of Distinct Cytotoxic Oligomers.

Characterization of small oligomers formed at an early stage of amyloid formation is critical to understanding molecular mechanism of pathogenic aggregation process. Here we identified and characterized cytotoxic oligomeric intermediates populated during transthyretin (TTR) aggregation process. Under the amyloid-forming conditions, TTR initially forms a dimer through interactions between outer strands. The dimers are then associated to form a hexamer with a spherical shape, which serves as a building block to self-assemble into cytotoxic oligomers. Notably, wild-type (WT) TTR tends to form linear oligomers, while a TTR variant (G53A) prefers forming annular oligomers with pore-like structures. Structural analyses of the amyloidogenic intermediates using circular dichroism (CD) and solid-state NMR reveal that the dimer and oligomers have a significant degree of native-like ß-sheet structures (35-38%), but with more disordered regions (~60%) than those of native TTR. The TTR variant oligomers are also less structured than WT oligomers. The partially folded nature of the oligomeric intermediates might be a common structural property of cytotoxic oligomers. The higher flexibility of the dimer and oligomers may also compensate for the entropic loss due to the oligomerization of the monomers.

Two distinct aggregation pathways in transthyretin misfolding and amyloid formation.

Misfolding and amyloid formation of transthyretin (TTR) is implicated in numerous degenerative diseases. TTR misfolding is greatly accelerated under acidic conditions, and thus most of the mechanistic studies of TTR amyloid formation have been conducted at various acidic pH values (2-5). In this study, we report the effect of pH on TTR misfolding pathways and amyloid structures. Our combined solution and solid-state NMR studies revealed that TTR amyloid formation can proceed via at least two distinct misfolding pathways depending on the acidic conditions. Under mildly acidic conditions (pH 4.4), tetrameric native TTR appears to dissociate to monomers that maintain most of the native-like ß-sheet structures. The amyloidogenic protein undergoes a conformational transition to largely unfolded states at more acidic conditions (pH 2.4), leading to amyloid with distinct molecular structures. Aggregation kinetics is also highly dependent upon the acidic conditions. TTR quickly forms moderately ordered amyloids at pH 4.4, while the aggregation kinetics is dramatically reduced at a lower pH of 2.4. The effect of the pathogenic mutations on aggregation kinetics is also markedly different under the two different acidic conditions. Pathogenic TTR variants (V30M and L55P) aggregate more aggressively than WT TTR at pH 4.4. In contrast, the single-point mutations do not affect the aggregation kinetics at the more acidic condition of pH 2.4. Given that the pathogenic mutations lead to more aggressive forms of TTR amyloidoses, the mildly acidic condition might be more suitable for mechanistic studies of TTR misfolding and aggregation.

Pathogenic Mutations Induce Partial Structural Changes in the Native ß-Sheet Structure of Transthyretin and Accelerate Aggregation.

Amyloid formation of natively folded proteins involves global and/or local unfolding of the native state to form aggregation-prone intermediates. Here we report solid-state nuclear magnetic resonance (NMR) structural studies of amyloid derived from wild-type (WT) and more aggressive mutant forms of transthyretin (TTR) to investigate the structural changes associated with effective TTR aggregation. We employed selective 13C labeling schemes to investigate structural features of ß-structured core regions in amyloid states of WT and two mutant forms (V30M and L55P) of TTR. Analyses of the 13C-13C correlation solid-state NMR spectra revealed that WT TTR aggregates contain an amyloid core consisting of nativelike CBEF and DAGH ß-sheet structures, and the mutant TTR amyloids adopt a similar amyloid core structure with nativelike CBEF and AGH ß-structures. However, the V30M mutant amyloid was shown to have a different DA ß-structure. In addition, strand D is more disordered even in the native state of L55P TTR, indicating that the pathogenic mutations affect the DA ß-structure, leading to more effective amyloid formation. The NMR results are consistent with our mass spectrometry-based thermodynamic analyses that showed the amyloidogenic precursor states of WT and mutant TTRs adopt folded structures but the mutant precursor states are less stable than that of WT TTR. Analyses of the oxidation rate of the methionine side chain also revealed that the side chain of residue Met-30 pointing between strands D and A is not protected from oxidation in the V30M mutant, while protected in the native state, supporting the possibility that the DA ß-structure might be disrupted in the V30M mutant amyloid.

Solid-State NMR Studies Reveal Native-like ß-Sheet Structures in Transthyretin Amyloid.

Structural characterization of amyloid rich in cross-ß structures is crucial for unraveling the molecular basis of protein misfolding and amyloid formation associated with a wide range of human disorders. Elucidation of the ß-sheet structure in noncrystalline amyloid has, however, remained an enormous challenge. Here we report structural analyses of the ß-sheet structure in a full-length transthyretin amyloid using solid-state NMR spectroscopy. Magic-angle-spinning (MAS) solid-state NMR was employed to investigate native-like ß-sheet structures in the amyloid state using selective labeling schemes for more efficient solid-state NMR studies. Analyses of extensive long-range (13)C-(13)C correlation MAS spectra obtained with selectively (13)CO- and (13)Cα-labeled TTR reveal that the two main ß-structures in the native state, the CBEF and DAGH ß-sheets, remain intact after amyloid formation. The tertiary structural information would be of great use for examining the quaternary structure of TTR amyloid.

Structural Changes Associated with Transthyretin Misfolding and Amyloid Formation Revealed by Solution and Solid-State NMR.

Elucidation of structural changes involved in protein misfolding and amyloid formation is crucial for unraveling the molecular basis of amyloid formation. Here we report structural analyses of the amyloidogenic intermediate and amyloid aggregates of transthyretin using solution and solid-state nuclear magnetic resonance (NMR) spectroscopy. Our solution NMR results show that one of the two main ß-sheet structures (CBEF ß-sheet) is maintained in the aggregation-competent intermediate, while the other DAGH ß-sheet is more flexible on millisecond time scales. Magic-angle-spinning solid-state NMR revealed that AB loop regions interacting with strand A in the DAGH ß-sheet undergo conformational changes, leading to the destabilized DAGH ß-sheet.