Hairpins in the conformations of a confined polymer

E. Werner; A. Jain; A. Muralidhar; K. Frykholm; T. St Clere Smithe; J. Fritzsche; F. Westerlund; K. D. Dorfman; B. Mehlig

doi:10.1063/1.5018787

Hairpins in the conformations of a confined polymer

E. Werner, A. Jain, A. Muralidhar, K. Frykholm, T. St Clere Smithe, J. Fritzsche, F. Westerlund, K. D. Dorfman, B. Mehlig

Chemical Engineering and Materials Science

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Abstract

If a semiflexible polymer confined to a narrow channel bends around by 180°, the polymer is said to exhibit a hairpin. The equilibrium extension statistics of the confined polymer are well understood when hairpins are vanishingly rare or when they are plentiful. Here, we analyze the extension statistics in the intermediate situation via experiments with DNA coated by the protein RecA, which enhances the stiffness of the DNA molecule by approximately one order of magnitude. We find that the extension distribution is highly non-Gaussian, in good agreement with Monte-Carlo simulations of confined discrete wormlike chains. We develop a simple model that qualitatively explains the form of the extension distribution. The model shows that the tail of the distribution at short extensions is determined by conformations with one hairpin.

Original language	English (US)
Article number	024105
Journal	Biomicrofluidics
Volume	12
Issue number	2
DOIs	https://doi.org/10.1063/1.5018787
State	Published - Mar 1 2018

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abstract = "If a semiflexible polymer confined to a narrow channel bends around by 180°, the polymer is said to exhibit a hairpin. The equilibrium extension statistics of the confined polymer are well understood when hairpins are vanishingly rare or when they are plentiful. Here, we analyze the extension statistics in the intermediate situation via experiments with DNA coated by the protein RecA, which enhances the stiffness of the DNA molecule by approximately one order of magnitude. We find that the extension distribution is highly non-Gaussian, in good agreement with Monte-Carlo simulations of confined discrete wormlike chains. We develop a simple model that qualitatively explains the form of the extension distribution. The model shows that the tail of the distribution at short extensions is determined by conformations with one hairpin.",

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AU - Werner, E.

AU - Jain, A.

AU - Muralidhar, A.

AU - Frykholm, K.

AU - St Clere Smithe, T.

AU - Fritzsche, J.

AU - Westerlund, F.

AU - Dorfman, K. D.

AU - Mehlig, B.

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Hairpins in the conformations of a confined polymer

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