Statistical mechanics of torque induced denaturation of DNA

Simona Cocco; Rémi Monasson

doi:10.1103/PhysRevLett.83.5178

Statistical mechanics of torque induced denaturation of DNA

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Abstract

A unifying theory of the denaturation transition of DNA, driven by temperature T or induced by an external mechanical torque Gamma is presented. Our model couples the hydrogen-bond opening and the untwisting of the helicoidal molecular structure. We show that denaturation corresponds to a first-order phase transition from B-DNA to d-DNA phases and that the coexistence region is naturally parametrized by the degree of supercoiling sigma. The denaturation free energy, the temperature dependence of the twist angle, the phase diagram in the T, Gamma plane and isotherms in the sigma, Gamma plane are calculated and show a good agreement with experimental data.

Original language	English
Pages (from-to)	5178-5181
Number of pages	4
Journal	Physical Review Letters
Volume	83
Issue number	24
DOIs	https://doi.org/10.1103/PhysRevLett.83.5178
Publication status	Published - 1 Jan 1999
Externally published	Yes

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10.1103/PhysRevLett.83.5178

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title = "Statistical mechanics of torque induced denaturation of DNA",

abstract = "A unifying theory of the denaturation transition of DNA, driven by temperature T or induced by an external mechanical torque Gamma is presented. Our model couples the hydrogen-bond opening and the untwisting of the helicoidal molecular structure. We show that denaturation corresponds to a first-order phase transition from B-DNA to d-DNA phases and that the coexistence region is naturally parametrized by the degree of supercoiling sigma. The denaturation free energy, the temperature dependence of the twist angle, the phase diagram in the T, Gamma plane and isotherms in the sigma, Gamma plane are calculated and show a good agreement with experimental data.",

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AB - A unifying theory of the denaturation transition of DNA, driven by temperature T or induced by an external mechanical torque Gamma is presented. Our model couples the hydrogen-bond opening and the untwisting of the helicoidal molecular structure. We show that denaturation corresponds to a first-order phase transition from B-DNA to d-DNA phases and that the coexistence region is naturally parametrized by the degree of supercoiling sigma. The denaturation free energy, the temperature dependence of the twist angle, the phase diagram in the T, Gamma plane and isotherms in the sigma, Gamma plane are calculated and show a good agreement with experimental data.

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Statistical mechanics of torque induced denaturation of DNA

Abstract

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