1. Tension-dependent structural deformation alters single-molecule transition kinetics.
- Author
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Sudhanshu, B., Mihardja, S., Koslover, E. F., Mehraeen, S., Bustamante, C., and Spakowitz, A. J.
- Subjects
ANALYTICAL mechanics ,MOLECULES ,BIOMOLECULES ,POLYMERS ,QUANTUM theory - Abstract
We analyze the response of a single nucleosome to tension, which serves as a prototypical biophysical measurement where tension-dependent deformation alters transition kinetics. We develop a statistical-mechanics model of a nucleosome as a wormlike chain bound to a spool, incorporating fluctuations in the number of bases bound, the spool orientation, and the conformations of the unbound polymer segments. With the resulting free-energy surface, we perform dynamic simulations that permit a direct comparison with experiments. This simple approach demonstrates that the experimentally observed structural states at nonzero tension are a consequence of the tension and that these tension-induced states cease to exist at zero tension. The transitions between states exhibit substantial deformation of the unbound polymer segments. The associated deformation energy increases with tension; thus, the application of tension alters the kinetics due to tension-induced deformation of the transition states. This mechanism would arise in any system where the tether molecule is deformed in the transition state under the influence of tension. [ABSTRACT FROM AUTHOR]
- Published
- 2011
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