Molecular motion of DNA as measured by triplet anisotropy decay.

Abstract: We have used triplet anisotropy decay techniques to measure the internal flexibility and overall rotational motion of DNA, covering a time range from 15 ns to 200 Is.Nearly monodisperse DNA fragments 65-600 base pairs long were studied by using the intercalating dye methylene blue as a triplet probe. We found that the slow end-over-end tumbling of short DNA fragments (s165 base pairs) is as predicted for a rigid rod.As expected, a longer DNA fragment (600 base pairs) experiences slow segmental motion of its he… Show more

“…Data about the collective motion of DNA/RNA helical domains arising from structural fluctuations of the duplex (bending and twisting) are almost non-existent in the literature, especially for short duplexes. However, it can be inferred that these motions mainly cover the range from tens of nanosecond to tens of microseconds (Hogan et al 1982;Naimushin et al 2000;Orden and Jung 2008;Porschke 2007;Schwieters and Clore 2007;Shajani and Varani 2007), although motions in the range 20-400 ls have been reported (Kojima et al 2001). Together, these considerations indicate that in most cases, energy transfer captures a transient ''static'' configuration of the duplex, whereas the slow acquisition rate allows the DNA/RNA duplex and associated fluorophores to adopt all possible configurations within the experimental period used for data acquisition.…”

Probing complexes with single fluorophores: factors contributing to dispersion of FRET in DNA/RNA duplexes

“…Data about the collective motion of DNA/RNA helical domains arising from structural fluctuations of the duplex (bending and twisting) are almost non-existent in the literature, especially for short duplexes. However, it can be inferred that these motions mainly cover the range from tens of nanosecond to tens of microseconds (Hogan et al 1982;Naimushin et al 2000;Orden and Jung 2008;Porschke 2007;Schwieters and Clore 2007;Shajani and Varani 2007), although motions in the range 20-400 ls have been reported (Kojima et al 2001). Together, these considerations indicate that in most cases, energy transfer captures a transient ''static'' configuration of the duplex, whereas the slow acquisition rate allows the DNA/RNA duplex and associated fluorophores to adopt all possible configurations within the experimental period used for data acquisition.…”

Probing complexes with single fluorophores: factors contributing to dispersion of FRET in DNA/RNA duplexes

“…In these measurements, the laser pulse has a finite width and therefore must be convoluted into the initial 20 ns of anisotropy decay simulation. When fitting our data to equations (1) and (2), we have included such a convolution (the pulse has been included as a. 20-ns gaussian excitation profile, using 100 points at 0.2-ns intervals).…”

“…4.0x 10-11 9.0X 10- 13 1.0 X 10-!2 2.0 X 10- 12 4.0x [10][11] l.Ox 10- 12 1.0 X 10-!2 2.0 X 10-12 4 Parameters are derived from a best fit of equations (1) and (2) to anisotropy decay data. 400±60, 260±40 and 800±200bp long DNA fragments were prepared as described in the legend to Fig.…”

“…1. C, Torsional spring constant calculated from equations (1) and (2); -r, exponential time constant for motion of the long helix axis estimated from a fit of the slowest part of the anisotropy decay data to a single exponential ; P, the apparent persistence length of the fragments ; E, Young's modulus, calculated from fits of data to equations (1) and (2). In these measurements, the laser pulse has a finite width and therefore must be convoluted into the initial 20 ns of anisotropy decay simulation.…”

Corrigendum

“…Parameters are derived from a best fit of equations (1) and (2) to anisotropy decay data. 400±60, 260±40 and 800±200bp long DNA fragments were prepared as described in the legend to Fig.…”

Errata