Visualization of Intrinsically Disordered Regions of Proteins by High‐Speed Atomic Force Microscopy

Miyagi, Atsushi; Tsunaka, Yasuo; Uchihashi, Takayuki; Mayanagi, Kouta; Hirose, Susumu; Morikawa, Kosuke; Ando, Toshio

doi:10.1002/cphc.200800210

Cited by 93 publications

(98 citation statements)

References 39 publications

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“…The striation pattern has been observed previously and found to be due to the resonant vibration of the piezo tube scanner (e.g. [20][21][22][23][24]). Therefore, the dominant factor that limits the response speed of the system at 0.1 s per frame was the resonance of the piezo tube [14].…”

Section: (B)supporting

confidence: 64%

Imaging stability in force-feedback high-speed atomic force microscopy

Kim

Boehm

2013

Ultramicroscopy

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We studied the stability of force-feedback high-speed atomic force microscopy (HSAFM) by imaging soft, hard, and biological sample surfaces at various applied forces. The HSAFM images showed sudden topographic variations of streaky fringes with a negative applied force when collected on a soft hydrocarbon film grown on a grating sample, whereas they showed stable topographic features with positive applied forces. The instability of HSAFM images with the negative applied force was explained by the transition between contact and noncontact regimes in the force-distance curve. When the grating surface was cleaned, and thus hydrophilic by removing the hydrocarbon film, enhanced imaging stability was observed at both positive and negative applied forces. The higher adhesive interaction between the tip and the surface explains the improved imaging stability. The effects of imaging rate on the imaging stability were tested on an even softer adhesive Escherichia coli biofilm deposited onto the grating structure. The biofilm and planktonic cell structures in HSAFM images were reproducible within the force deviation less than ~0.5 nN at the imaging rate up to 0.2 s per frame, suggesting that the force-feedback HSAFM was stable for various imaging speeds in imaging softer adhesive biological samples.

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Section: (B)supporting

confidence: 64%

Imaging stability in force-feedback high-speed atomic force microscopy

Kim

Boehm

2013

Ultramicroscopy

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“…Imaging rate, 1.03 fps (×20 playback); scan size, 800 × 800 nm 2 [98]. ・Crystallization of a CaCO 3 thin film from supersaturated solution [72] ・Ultrafast imaging of collagen [58] ・Brownian motion & photo-degradation of π-conjugated polyrotaxane [73] ・DNA translocation and looping by type III restriction enzyme [74] ・Biotinylated DNA-streptavidin interaction [75] Miles Miles Shinohara Takeyasu Trimitsu 2008 5 ・Anisotropic diffusion of point defects in streptavidin 2D crystals [76] ・Identification of intrinsically disordered regions of proteins [77] ・Human chromosomes in liquid [78] ・DNA-nuclease interaction [ ・Dynamic equilibrium at the edge of bR 2D crystals [81] ・Structural change of CaM and actin polymerization on streptavidin 2D crystals [82] ・Unidirectional translocation of cellulase along cellulose fibers [83] ・Translocation of EcoRII restriction enzyme along DNA [84] ・Fabrication and imaging of hard material surface [85] ・Purple membrane in contact-mode HS-AFM [86] ・Thermal motion of π-conjugated polymer chain [87] ・Opening of 3D hollow structure of DNA Origami [88] ・Opening of 3D hollow structure of DNA Origami [89] ・ATP-induced conformational change in P2X 4 ・Walking myosin V along an actin filament [91] ・Photo-induced structural change in bR [92] ・2D crystal formation of annexin A-V and height change of p97 [93] ・Analysis of components covering magnesotome surface [94] ・Time course of cell death by antimicrobial peptide [95] ・Dissolution of extreme UV exposed resist films under developing [96] ・Dissolution of extreme UV exposed resist films under developing [97] ・Process of forming supported planar lipid bilayer [98] ・Self assembly of amyloid-like fibrils [99] ・Effect of ClpX on FtsZ polymerization ...…”

Section: Resultsmentioning

confidence: 99%

“…High-speed AFM has recently demonstrated its ability to visualize the thin and random structures of IDPs, using FACT protein as a test sample [77]. Displacement of histone H2A/H2B dimers from nucleosomes by FACT protein facilitates RNA polymerase II transcription [147] and chromatin remodeling [148].…”

Section: Intrinsically Disordered Fact Proteinmentioning

confidence: 99%

High-speed atomic force microscopy coming of age

Ando¹

2012

Nanotechnology

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309

243

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High-speed atomic force microscopy (HS-AFM) is now materialized. It allows direct visualization of dynamic structural changes and dynamic processes of functioning biological molecules in physiological solutions, at high spatiotemporal resolution. Dynamic molecular events unselectively appear in detail in an AFM movie, facilitating our understanding of how biological molecules operate to function. This review describes a historical overview of technical development towards HS-AFM, summarizes elementary devices and techniques used in the current HS-AFM, and then highlights recent imaging studies. Finally, future challenges of HS-AFM studies are briefly discussed.

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“…Since the oscillation amplitude of shorter cantilevers can be more precisely and sensitively detected than that of conventional long cantilevers, the vertical resolution of HS-AFM is higher than that of slow AFM, even at high bandwidth. The vertical resolution of~0.15 nm is high enough to visualize unstructured polypeptides (0.45-0.5 nm in diameter) on a solid support (Miyagi et al 2008).…”

Section: Current Performance Of Hs-afm Systemmentioning

confidence: 99%

High-speed atomic force microscopy and its future prospects

2017

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Various techniques have been developed and used to investigate how proteins produce complex biological architectures and phenomena. Among these techniques, high-speed atomic force microscopy (HS-AFM) holds a unique position. It is only HS-AFM that allows the simultaneous assessment of structure and dynamics of single protein molecules in action. This new microscopy tool has been successfully applied to a variety of proteins, from motor proteins to membrane proteins, antibodies, enzymes, and even to intrinsically disordered proteins. And yet there still remain many biomolecular phenomena that cannot be addressed by HS-AFM in its current form. Here, I present a brief history of HS-AFM development, describe the current state of HS-AFM, and then discuss which new biological scanning probe microscopy techniques will be coming up next.

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Visualization of Intrinsically Disordered Regions of Proteins by High‐Speed Atomic Force Microscopy

Cited by 93 publications

References 39 publications

Imaging stability in force-feedback high-speed atomic force microscopy

Imaging stability in force-feedback high-speed atomic force microscopy

High-speed atomic force microscopy coming of age

High-speed atomic force microscopy and its future prospects

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