A New Structural Model of Aβ<sub>40</sub> Fibrils

Bertini, Ivano; Gonnelli, Leonardo; Luchinat, Claudio; Mao, Jiafei; Nesi, Antonella

doi:10.1021/ja2035859

Cited by 294 publications

(456 citation statements)

References 91 publications

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“…This is in large part due to the spontaneous formation, inertness, and insolubility of bactofilin polymers, which makes them difficult substrates for crystallography studies as well as conventional liquid-state NMR methods. We therefore resorted to the use of solid-state NMR (ssNMR) spectroscopy, a technique that has recently been adapted to obtain high-resolution structural information on insoluble and noncrystalline protein assemblies, including functional oligomeric assemblies (15)(16)(17), disease-related amyloid fibrils (18)(19)(20)(21), and membrane proteins in a lipid bilayer environment (22)(23)(24)(25)(26). In this study, we have applied state-of-theart magic-angle spinning ssNMR spectroscopy in combination with a range of other biophysical methods to filaments of the C. crescentus bactofilin BacA (161 residues).…”

Section: Significancementioning

confidence: 99%

β-Helical architecture of cytoskeletal bactofilin filaments revealed by solid-state NMR

Vasa¹,

Lin

Shi

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Bactofilins are a widespread class of bacterial filament-forming proteins, which serve as cytoskeletal scaffolds in various cellular pathways. They are characterized by a conserved architecture, featuring a central conserved domain (DUF583) that is flanked by variable terminal regions. Here, we present a detailed investigation of bactofilin filaments from Caulobacter crescentus by highresolution solid-state NMR spectroscopy. De novo sequential resonance assignments were obtained for residues Ala39 to Phe137, spanning the conserved DUF583 domain. Analysis of the secondary chemical shifts shows that this core region adopts predominantly β-sheet secondary structure. Mutational studies of conserved hydrophobic residues located in the identified β-strand segments suggest that bactofilin folding and polymerization is mediated by an extensive and redundant network of hydrophobic interactions, consistent with the high intrinsic stability of bactofilin polymers. Transmission electron microscopy revealed a propensity of bactofilin to form filament bundles as well as sheet-like, 2D crystalline assemblies, which may represent the supramolecular arrangement of bactofilin in the native context. Based on the diffraction pattern of these 2D crystalline assemblies, scanning transmission electron microscopy measurements of the mass per length of BacA filaments, and the distribution of β-strand segments identified by solid-state NMR, we propose that the DUF583 domain adopts a β-helical architecture, in which 18 β-strand segments are arranged in six consecutive windings of a β-helix.solid-state NMR | cytoskeleton | protein structure | filaments

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Section: Significancementioning

confidence: 99%

β-Helical architecture of cytoskeletal bactofilin filaments revealed by solid-state NMR

Vasa¹,

Lin

Shi

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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“…High-resolution solidstate NMR structures of hIAPP 20-29 fibrils have provided detailed insight into the antiparallel hetero zipper with a twist along the fibril axis (21-23). However, no uniform detailed theory of the self-assembly behavior is available (11) and, in particular, the transitions between different intermediates during fibrillation remain to be elucidated.Here, we apply high-resolution AFM and the recently developed microsecond force spectroscopy (μFS) for quantitative nanomechanical maps (24, 25) to explore the nanostructures and nanomechanical properties of species formed during the self-assembly of the decapeptide hIAPP [20][21][22][23][24][25][26][27][28][29] . By following the temporal evolution of the amyloid peptide self-assembly process, we calculate the average thickening speed of ribbon structures, which is considered a key intermediate in the ribbon-like packing scheme (26,27).…”

mentioning

confidence: 99%

“…hIAPP is a 37-amino-acid peptide hormone, and the decapeptide SNNFGAILSS comprising hIAPP [20][21][22][23][24][25][26][27][28][29] , considered to be the core fibrillating element of hIAPP relating to T2D (18, 19), is critical for the fibrillation of hIAPP and shows cytotoxicity (19). The analysis of hIAPP 20-29 fibrils revealed two distinct fibril types, comprising either parallel β-strands or antiparallel β-strands (20).…”

mentioning

confidence: 99%

“…Transitions among the various intermediate stages are the subject of many studies but are not yet fully elucidated. Here, we combine high-resolution atomic force microscopy and quantitative nanomechanical mapping to determine the self-assembled structures of the decapeptide hIAPP [20][21][22][23][24][25][26][27][28][29] , which is considered to be the fibrillating core fragment of the human islet amyloid polypeptide (hIAPP) involved in type-2 diabetes. We successfully follow the evolution of hIAPP [20][21][22][23][24][25][26][27][28][29] nanostructures over time, calculate the average thickening speed of small ribbon-like structures, and provide evidence of the coexistence of ribbon and helical fibrils, highlighting a key step within the self-assembly model.…”

mentioning

confidence: 99%

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Coexistence of ribbon and helical fibrils originating from hIAPP _20–29 revealed by quantitative nanomechanical atomic force microscopy

Zhang

Andreasen

Nielsen

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

107

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Uncontrolled misfolding of proteins leading to the formation of amyloid deposits is associated with more than 40 types of diseases, such as neurodegenerative diseases and type-2 diabetes. These irreversible amyloid fibrils typically assemble in distinct stages. Transitions among the various intermediate stages are the subject of many studies but are not yet fully elucidated. Here, we combine high-resolution atomic force microscopy and quantitative nanomechanical mapping to determine the self-assembled structures of the decapeptide hIAPP [20][21][22][23][24][25][26][27][28][29] , which is considered to be the fibrillating core fragment of the human islet amyloid polypeptide (hIAPP) involved in type-2 diabetes. We successfully follow the evolution of hIAPP 20-29 nanostructures over time, calculate the average thickening speed of small ribbon-like structures, and provide evidence of the coexistence of ribbon and helical fibrils, highlighting a key step within the self-assembly model. In addition, the mutations of individual side chains of wide-type hIAPP 20-29 shift this balance and destabilize the helical fibrils sufficiently relative to the twisted ribbons to lead to their complete elimination. We combine atomic force microscopy structures, mechanical properties, and solid-state NMR structural information to build a molecular model containing β sheets in cross-β motifs as the basis of selfassembled amyloids.μFS | mutants | nanomechanical map | self-assembly nanostructure P rotein aggregation and amyloid deposits (1, 2) are associated with more than 40 different diseases (3) ranging from neurodegenerative diseases such as Alzheimer's disease (4) and Parkinson disease (5) to systemic amyloidosis, such as type-2 diabetes mellitus (T2D) (6). Over the last few decades, amyloid structures and amyloid assembly have been extensively studied using a variety of diffraction techniques such as X-ray scattering and electron diffraction. However, these methods only provide average structures (7). Many structures have also been resolved in great detail by solid-state NMR spectroscopy (8, 9), which mainly represents end-point structures and, unless specifically trapping intermediates, typically does not provide a clear picture of the transient structures formed during the fibrillation process. However, it is very important to resolve the dynamics of the nanostructures of amyloids at various steps during self-assembly to understand the mechanics behind amyloid initialization, formation, growth, and maturation as well as for the design of potential drugs. Atomic force microscopy (AFM) is capable of obtaining nanoscale resolution of individual molecules or supermolecular structures. This method also allows for the analysis of the selfassembly mechanism and the driving force of aggregation (10-14). Importantly, AFM, furthermore, provides the possibility to follow the dynamics to obtain a detailed picture of the amyloid assembly process (15).In the case of T2D, amyloid deposits, composed mainly of human islet amyloid polypeptide (hIA...

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“…4 In the past, several Ab fibril structure models have been suggested. These are based on MAS solidstate NMR experiments, [5][6][7][8][9][10][11] and cryo-electron microscopic image reconstructions. 12 Even though there is some controversy concerning the conformational space that Ab fibrils can adopt, all published models, including the 2-fold 7,10 and 3-fold 9 symmetric Ab 1-40 fibril structure suggested by Tycko, and Bertini and co-workers, agree on the basic building block which involves a b-sheet (b1, residues 12-24), a turn, and a second b-sheet (b2, residues [28][29][30][31][32][33][34][35][36][37][38][39][40].…”

mentioning

confidence: 99%

Hydrogen bonding involving side chain exchangeable groups stabilizes amyloid quarternary structure

Agarwal

Linser

Dasari

et al. 2013

Phys. Chem. Chem. Phys.

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The amyloid b-peptide (Ab) is the major structural component of amyloid fibrils in the plaques of brains of Alzheimer's disease patients. Numerous studies have addressed important aspects of secondary and tertiary structure of fibrils. In electron microscopic images, fibrils often bundle together. The mechanisms which drive the association of protofilaments into bundles of fibrils are not known. We show here that amino acid side chain exchangeable groups like e.g. histidines can provide useful restraints to determine the quarternary assembly of an amyloid fibril. Exchangeable protons are only observable if a side chain hydrogen bond is formed and the respective protons are protected from exchange. The method relies on deuteration of the Ab peptide. Exchangeable deuterons are substituted with protons, before fibril formation is initiated.Alzheimer's disease (AD) is a slowly progressive neurological disorder which is associated with memory loss, cognitive impairment and finally dementia and death. The amyloid b-peptide (Ab) is the major structural component of amyloid fibrils in the plaques of brains of Alzheimer's disease patients. Ab is a cleavage product resulting from Alzheimer Precursor Protein (APP) processing. 1 The g-secretase cut yields Ab fragments of different lengths of which Ab40 and Ab42 are most abundant. 2,3 In vitro, the Ab peptide aggregates over time into oligomers and fibrillar structures. 4 In the past, several Ab fibril structure models have been suggested. These are based on MAS solidstate NMR experiments, 5-11 and cryo-electron microscopic image reconstructions. 12 Even though there is some controversy concerning the conformational space that Ab fibrils can adopt, all published models, including the 2-fold 7,10 and 3-fold 9 symmetric Ab 1-40 fibril structure suggested by Tycko, and Bertini and co-workers, agree on the basic building block which involves a b-sheet (b1, residues 12-24), a turn, and a second b-sheet (b2, residues 28-40). Biophysical studies indicate a certain degree of conformational plasticity for the N-terminal b-sheet. 13,14 Whereas b2 is present in all the studies, b1 can be truncated or does not adopt a regular b-sheet structure. Depending on the preparation conditions, amide protons in the region of the peptide where the first b-strand is expected show differential H/D protection factors. 13 Similarly, a certain degree of conformational variability in the N-terminus is suggested using cryo-electron microscopy. 14 In all structural models, Ab peptides are arranged in a parallel fashion. An antiparallel arrangement is only observed for the Iowa mutant Ab-D23N, 15 and for truncated forms of the peptide such as Ab [11][12][13][14][15][16][17][18][19][20][21][22][23][24][25] . 16 The fibril structure is stabilized in particular by hydrogen bonding interactions. Therefore, observation of exchangeable and titratable groups is of particular interest to identify hydrogen bonding patterns. We and others could show in the past that high resolution proton spectra can be obtained for...

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A New Structural Model of Aβ₄₀ Fibrils

Cited by 294 publications

References 91 publications

β-Helical architecture of cytoskeletal bactofilin filaments revealed by solid-state NMR

β-Helical architecture of cytoskeletal bactofilin filaments revealed by solid-state NMR

Coexistence of ribbon and helical fibrils originating from hIAPP _20–29 revealed by quantitative nanomechanical atomic force microscopy

Hydrogen bonding involving side chain exchangeable groups stabilizes amyloid quarternary structure

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A New Structural Model of Aβ40 Fibrils

Cited by 294 publications

References 91 publications

β-Helical architecture of cytoskeletal bactofilin filaments revealed by solid-state NMR

β-Helical architecture of cytoskeletal bactofilin filaments revealed by solid-state NMR

Coexistence of ribbon and helical fibrils originating from hIAPP 20–29 revealed by quantitative nanomechanical atomic force microscopy

Hydrogen bonding involving side chain exchangeable groups stabilizes amyloid quarternary structure

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A New Structural Model of Aβ₄₀ Fibrils

Coexistence of ribbon and helical fibrils originating from hIAPP _20–29 revealed by quantitative nanomechanical atomic force microscopy