Reversible Mechanical Unzipping of Amyloid β-Fibrils

Kellermayer, Miklós; Grama, László; Karsai, Árpád; Nagy, Attila; Kahn, Amram; Datki, Zsolt; Penke, Botond

doi:10.1074/jbc.m411556200

Cited by 85 publications

(129 citation statements)

References 48 publications

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“…This method avoids indentation into the matrix, thus reduces the possibility of picking up multiple molecules in a single pull. Fitting the force curve with WLC model gave a persistence length of 0.35 ± 0.05 nm, which agrees pretty well with previous results on amyloid fibrils (Kellermayer, et al, 2005;. In addition, FT-IR spectroscopy and dye (Congo red and thioflavin T) staining confirmed the presence of -sheet and amyloid structures in the sample.…”

Section: Applicationssupporting

confidence: 77%

“…All of the force curves exhibited non-linear elastic mechanical response followed by one or several rupture events. The absence of force plateau, which is a characteristic pattern of the unzipping of -sheets from the fibril, implies that the high packing density in mature glucagon amyloid fibrils allows a stable confinement of the peptide molecules in the twisted fibrillar structure, in contrast to A amyloid fibrils (Karsai et al, 2006;Kellermayer, et al, 2005). The stable structure is further confirmed by repeatedly stretching a single fibril for 1000 times.…”

Section: Applicationsmentioning

confidence: 58%

“…This implies that the associated state of thesheets is highly favored and stabilized within the amyloid fibrils (Kellermayer, et al, 2005), which partly explains the high stability of amyloid fibrils. (Kellermayer, et al, 2005).…”

Section: Applicationsmentioning

confidence: 95%

“…In the AFM manipulation of the A 1-40 and A 25-35 fibrils (Kellermayer et al, 2005), the resulting force curves exhibited two distinct mechanical responses: (1) fully reversible, non-linear elasticity with WLC fitted contour length often exceeding 100 nm ( Figure 6A); (2) force platform characterized with long distance constant force stretching followed by abrupt force drop ( Figure 6B). In most cases, the two patterns are superposed onto each other ( Figure 6C, 6D).…”

Section: Applicationsmentioning

confidence: 99%

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Nanomechanics of Amyloid Materials Studied by Atomic Force Microscopy

Zeng¹,

Duan²,

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et al. 2012

Atomic Force Microscopy Investigations Into Biology - From Cell to Protein

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Section: Applicationssupporting

confidence: 77%

Section: Applicationsmentioning

confidence: 58%

Section: Applicationsmentioning

confidence: 95%

Section: Applicationsmentioning

confidence: 99%

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Nanomechanics of Amyloid Materials Studied by Atomic Force Microscopy

Zeng¹,

Duan²,

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“…More recently, Lim and coworkers showed that the elastic properties of blood clots are mainly determined by the coiled-coil helices of fibrinogen 142 . In another example, Kellermayer and coworkers described the structure and self assembly mechanism of amyloid β-fibrils 143 and myosin thick filaments 144 .…”

Section: Applications Of Afmmentioning

confidence: 99%

Single-molecule force spectroscopy: optical tweezers, magnetic tweezers and atomic force microscopy

2008

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“Nano‐Fishnet” Structure Making Silk Fibers Tougher

Liu

Deng

Zhou

et al. 2016

Adv Funct Materials

108

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wileyonlinelibrary.combiomedicines. [ 1 ] The mesoscale phenomena and architectures of soft materials are essential in generating the next generation of technology opportunities, societal benefi ts, and scientifi c advances. [ 2 ] The accumulating facts indicate that the functionality of soft materials that is critical to macroscopic performance begins to manifest itself not at the atomic or nanoscale but at the mesoscale. [ 3 ] Animal silks, including both spider and silkworm silks, show the hierarchical structures of amorphous chains and stacked β-sheets. [ 4 ] Due to the unique mechanical, optical, and biological behavior, [ 5 ] silk materials are found to have a broad range of applications in tissue engineering, bioelectronics, optics, and other areas. [ 6 ] In particular, the toughness of spider dragline silk fi bers overrides Kevlar, steel, and most man-made fi bers available today. [ 6c , 7 ] The most recent studies reveal that both spider dragline and silkworm silk fi bers consist of bundles of twisted nanofi brils, [ 2,8 ] which in turn consist of amorphous molecular chains and β-sheet nanocrystallites. [ 4a , 9 ] The great mechanical strength and substantial elasticity of silk fi bers are believed to be in connection with a special arrangement of amorphous molecular chains and β-sheet nanocrystallites in nanofi brils. [ 4a , 7c , 10 ] Unfortunately, although there are a number of speculations concerning such an arrangement, [ 4a,g , 7c , 10a , 11 ] none of them have been directly verifi ed experimentally.As a type of soft materials, the performance of silk fi bers should also be determined by four factors of hierarchical network structures ( Figure 1 ): [ 2,12 ] (1) Topology: The topology of nodes describes how the joints/ points are associated with each other. (2) Correlation length: The average of the distance between two adjacent building blocks in the same structural level. (3) Ordering/symmetry of building blocks: The symmetry or ordering of the nodes (or the representing blocks) of the network structure determine the performance of the materials. (4) Strength of linkage or interactions: It refers to the strength of linkage or interactions between the adjacent structural units at the same level. The linkage can be physical, chemical bonding, or virtual connection/association. [ 13 ] Based on the combined technologies of atomic force microscopy, X-ray diffraction/scattering, Fourier transform infrared spectra analysis, etc., it is demonstrated that the nano-fi shnet-like networks, one of the most fl exible but toughest structures, turn out to be the basic structure of silk fi laments. The force patterns of pulling individual fi brils allow the identifi cation of the pathways of unfolding protein segments in stacking β-crystallites, which reveal the fi shnetlike topology. The calculation shows that the β-crystallites in silk nanofi brils are the cross-linking points of the nano-fi shnets, which may enhance the toughness of silk fi laments up to 1000 times, compared with amyloid-like and unl...

show abstract

Reversible Mechanical Unzipping of Amyloid β-Fibrils

Cited by 85 publications

References 48 publications

Nanomechanics of Amyloid Materials Studied by Atomic Force Microscopy

Nanomechanics of Amyloid Materials Studied by Atomic Force Microscopy

Single-molecule force spectroscopy: optical tweezers, magnetic tweezers and atomic force microscopy

“Nano‐Fishnet” Structure Making Silk Fibers Tougher

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