Three-Dimensional Atomic Force Microscopy: Interaction Force Vector by Direct Observation of Tip Trajectory

Sigdel, Krishna P.; Grayer, Justin S.; King, Gavin M.

doi:10.1021/nl403423p

Cited by 11 publications

(7 citation statements)

References 33 publications

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“…Common applications range from high throughput drug discovery assays based on fluorescence polarization 5 to fundamental biophysical studies utilizing super-resolution methods that routinely break the diffraction limit 6 7 . Increasingly, optical microscopy techniques are being incorporated into AFM instruments to enhance functionality as well as precision 8 9 10 11 12 13 14 15 16 . Local probe techniques are not able to resolve small molecules in solution.…”

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confidence: 99%

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Glass is a Viable Substrate for Precision Force Microscopy of Membrane Proteins

Chada

Sigdel

Gari

et al. 2015

Sci Rep

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Though ubiquitous in optical microscopy, glass has long been overlooked as a specimen supporting surface for high resolution atomic force microscopy (AFM) investigations due to its roughness. Using bacteriorhodopsin from Halobacterium salinarum and the translocon SecYEG from Escherichia coli, we demonstrate that faithful images of 2D crystalline and non-crystalline membrane proteins in lipid bilayers can be obtained on microscope cover glass following a straight-forward cleaning procedure. Direct comparison between AFM data obtained on glass and on mica substrates show no major differences in image fidelity. Repeated association of the ATPase SecA with the cytoplasmic protrusion of SecYEG demonstrates that the translocon remains competent for binding after tens of minutes of continuous AFM imaging. This opens the door for precision long-timescale investigations of the active translocase in near-native conditions and, more generally, for integration of high resolution biological AFM with many powerful optical techniques that require non-birefringent substrates.

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confidence: 99%

“…Furthermore, AFM tips drift in space over time and experience forces in three dimensions. Inspired by techniques from the optical trapping microscopy community 17 18 19 we have recently demonstrated an ultra-stable AFM 10 that minimizes positional drift as well as a means to directly observe three-dimensional tip-sample interactions 15 .…”

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Glass is a Viable Substrate for Precision Force Microscopy of Membrane Proteins

Chada

Sigdel

Gari

et al. 2015

Sci Rep

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“…Since previous ultrastable techniques have focused on active stabilization of an AFM tip 18 , 19 , we directly benchmarked our method using an AFM tip as a fiducial for sample stabilization. An AFM cantilever (Oxford Instruments, TR400PSA) was glued to a coverslip and mounted on a custom confocal fluorescence microscope 24 , with the apex of the AFM tip pointed towards the objective (Fig.…”

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Method for high frequency tracking and sub-nm sample stabilization in single molecule fluorescence microscopy

Schmidt

Reichert

Lajoie

et al. 2018

Sci Rep

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While fluorescence microscopes and atomic force microscopes are widely used to visualize, track, and manipulate single biomolecules, the resolution of these methods is limited by sample drift. To minimize drift, active feedback methods have recently been used to stabilize single molecule microscopes on the sub-nanometer scale. However, these methods require high intensity lasers which limits their application in single molecule fluorescence measurements. Furthermore, these feedback methods do not track user-defined regions of the sample, but rather monitor the relative displacement of an unknown point on a fiducial marker, which limits their use in biological force measurements. To overcome these limitations, we have developed a novel method to image, track and stabilize a sample using low laser intensities. We demonstrate the capabilities of our approach by tracking a user-chosen point on a fiducial marker at 8.6 kHz and stabilizing it with sub-nanometer resolution. We further showcase the application of our method in single molecule fluorescence microscopy by imaging and stabilizing individual fluorescently-tagged streptavidin proteins under biologically relevant conditions. We anticipate that our method can be easily used to improve the resolution of a wide range of single molecule fluorescence microscopy and integrated force-fluorescence applications.

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“…The benefits of such an extension clamp have recently been described from a theoretical point of view [71]. Threedimensional detection of the tip also yields insight into the 3D forces acting on a cantilever during tapping-mode imaging [72].…”

Section: Achieving Positional Stability: Ultrastable Afmmentioning

confidence: 99%

Ultrastable atomic force microscopy: Improved force and positional stability

Churnside

Perkins

2014

FEBS Letters

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a b s t r a c tAtomic force microscopy (AFM) is an exciting technique for biophysical studies of single molecules, but its usefulness is limited by instrumental drift. We dramatically reduced positional drift by adding two lasers to track and thereby actively stabilize the tip and the surface. These lasers also enabled label-free optical images that were spatially aligned to the tip position. Finally, sub-pN force stability over 100 s was achieved by removing the gold coating from soft cantilevers. These enhancements to AFM instrumentation can immediately benefit research in biophysics and nanoscience.Published by Elsevier B.V. on behalf of the Federation of European Biochemical Societies.

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Three-Dimensional Atomic Force Microscopy: Interaction Force Vector by Direct Observation of Tip Trajectory

Cited by 11 publications

References 33 publications

Glass is a Viable Substrate for Precision Force Microscopy of Membrane Proteins

Glass is a Viable Substrate for Precision Force Microscopy of Membrane Proteins

Method for high frequency tracking and sub-nm sample stabilization in single molecule fluorescence microscopy

Ultrastable atomic force microscopy: Improved force and positional stability

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