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Flexural Rigidity of Individual Microtubules Measured by a Buckling Force with Optical Traps
Mahito Kikumoto, Masashi Kurachi, Valer Tosa, Hideo Tashiro Biophysical Journal Volume 90, Issue 5, Pages (March 2006) DOI: /biophysj Copyright © 2006 The Biophysical Society Terms and Conditions
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Figure 1 Four types of methods for a single microtubule rigidity measurement. F is the microtubule internal spring force caused by deformation and P is the synthetic external force working on a microtubule. Biophysical Journal , DOI: ( /biophysj ) Copyright © 2006 The Biophysical Society Terms and Conditions
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Figure 2 Schematic diagram of the video-enhanced DIC microscope with optical traps. The laser power was controlled by rotating the half-wave plate, HWP1, followed by a Glan-Laser polarizer. The ratio of the two beams was changed by rotating the half-wave plate, HWP2. Two laser beams were independently manipulated by changing the angles of the galvano mirrors X1, Y1 and X2, Y2. Biophysical Journal , DOI: ( /biophysj ) Copyright © 2006 The Biophysical Society Terms and Conditions
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Figure 3 Schematic representation of a buckled microtubule. The X axis is chosen to pass through two fulcrums that represent attachment points of beads to a microtubule. The origin, O, is located at one of the fulcrums. The two polystyrene beads of radius r illustrate the nonaxial buckling case. Biophysical Journal , DOI: ( /biophysj ) Copyright © 2006 The Biophysical Society Terms and Conditions
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Figure 4 A typical example of single-microtubule capturing, buckling, and release with micromanipulation of antibody-coated beads and optical traps. (A) Video-printed images of the procedure for a paclitaxel-stabilized microtubule. The single microtubule can be seen faintly (the dark shadow of bead images makes it difficult to observe the microtubule). DIC images were used to observe the single microtubule, and thus the beads appear larger than their actual size due to halation. The background darkness of each image is slightly altered because the light source fluctuated slightly and contrast was strongly enhanced. (B) The trace of the images in A. Circles and lines represent beads and microtubules, respectively. Row 1 shows the first bead being captured with the right (stronger) optical trap. Row 2 shows the second bead with a single microtubule being captured with the left (weaker) trap. The microtubule on the bead could be observed by relative flow upon moving the stage. Row 3 shows the dumbbell-shaped image resulting from a single microtubule and beads. Row 4 shows just the buckling state of the microtubule upon moving the right bead toward the left. The left bead also moved fractionally to the left due to the buckling force. An additional short microtubule, which was not relevant to the analysis, can be seen on the right bead. Row 5 shows the left bead escaping from the trap and the buckling microtubule relaxing back to its straight form. The microtubule cannot be observed. Row 6 shows the final state in which the right bead is held by the trap and the bent microtubule straightens by its own elasticity. The left bead is free from the optical trap but remained bound to the microtubule. The right bead moved slightly toward the left in response to the release from the buckling force. Biophysical Journal , DOI: ( /biophysj ) Copyright © 2006 The Biophysical Society Terms and Conditions
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Figure 5 The plot of flexural rigidity of a single microtubule against microtubule length. Paclitaxel-stabilized microtubules (open circles) were buckled 1–5 times and 48 measurements of 25 microtubules were performed in total. The average and standard deviations for individual microtubules measured repeatedly are shown as a marker and error bars, respectively. Note that there was no length dependency of the flexural rigidity. For paclitaxel-free microtubules (solid squares), only four measurements of four microtubules were done. The average rigidity of paclitaxel-free microtubules (7.9×10−24Nm2) was approximately four-times-higher than that of paclitaxel-stabilized microtubules (2.0×10−24Nm2). Biophysical Journal , DOI: ( /biophysj ) Copyright © 2006 The Biophysical Society Terms and Conditions
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