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. 2015 Feb 17;43(5):2767–2779. doi: 10.1093/nar/gkv087

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© The Author(s) 2015. Published by Oxford University Press on behalf of Nucleic Acids Research.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.

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Figure 5. — Off-rate kinetics of bis-intercalation. (a) DNA extension as a function of time in wash-off experiments starting at 100-nM Thiocoraline at four different forces, and fit to a double-exponential function (dotted gray). (b) Force dependence of the macroscopic kinetic rates: fast off-rate (blue), slow off-rate (purple). In red, k_tot from force-jump experiments is plotted as a reference. A fit to Equation (7) (solid lines) yields the macroscopic zero-force rates (k_{off, slow}(0) = 6.2(7) · 10⁻⁴s⁻¹, k_{off, fast}(0) = 3.4(4) · 10⁻³s⁻¹) and transition-state distances ( nm, nm) for each process. Values are reported as mean ± SD, N ≥ 3. (c) Wash-off experiment in which different forces (yellow) are sequentially tested within the same kinetic trace. The molecular extension (green) is initially followed at a constant force of 12 pN. The slope of the molecular extension is proportional to the number of bis-intercalators that unbind from DNA per unit time and hence it is indicative of how the off-rate (k_off) changes with force. Increasing the force from 12 pN (shadowed in gray) to a higher force value (40 pN, 25 pN) causes a decrease on the slope and hence in k_off, whereas decreasing the force to 5 pN causes the opposite effect. We also indicated the measured change in molecular extension (blue lines) when the force is set again at 12 pN after a few minutes at 40 pN, 25 pN and 5 pN, showing that ligands unbind faster as force is decreased.

Inline graphic — Off-rate kinetics of bis-intercalation. (a) DNA extension as a function of time in wash-off experiments starting at 100-nM Thiocoraline at four different forces, and fit to a double-exponential function (dotted gray). (b) Force dependence of the macroscopic kinetic rates: fast off-rate (blue), slow off-rate (purple). In red, k_tot from force-jump experiments is plotted as a reference. A fit to Equation (7) (solid lines) yields the macroscopic zero-force rates (k_{off, slow}(0) = 6.2(7) · 10⁻⁴s⁻¹, k_{off, fast}(0) = 3.4(4) · 10⁻³s⁻¹) and transition-state distances ( nm, nm) for each process. Values are reported as mean ± SD, N ≥ 3. (c) Wash-off experiment in which different forces (yellow) are sequentially tested within the same kinetic trace. The molecular extension (green) is initially followed at a constant force of 12 pN. The slope of the molecular extension is proportional to the number of bis-intercalators that unbind from DNA per unit time and hence it is indicative of how the off-rate (k_off) changes with force. Increasing the force from 12 pN (shadowed in gray) to a higher force value (40 pN, 25 pN) causes a decrease on the slope and hence in k_off, whereas decreasing the force to 5 pN causes the opposite effect. We also indicated the measured change in molecular extension (blue lines) when the force is set again at 12 pN after a few minutes at 40 pN, 25 pN and 5 pN, showing that ligands unbind faster as force is decreased.