Statistical Thermodynamics for Chain Molecules with Simple RNA Tertiary Contacts

Overview

Journal J Chem Phys

Publisher American Institute of Physics

Specialties Biophysics
Chemistry

Date 2005 Apr 20

PMID 15836183

Citations 7

Authors

Zoia Kopeikin

Shi-Jie Chen

Affiliations

Soon will be listed here.

Abstract

A statistical thermodynamic model is developed for chain molecules with simple RNA tertiary contacts. The model, which accounts for the excluded volume effect and the nonadditivity in the free energy, enables reliable predictions for the conformational entropy and partition function for simple tertiary folds. Illustrative applications are made to conformational transitions involving simple tertiary contacts. The model can predict the interplay between the secondary and the tertiary interactions in the conformational changes. Though the present form of the theory is tested and validated in a two-dimensional lattice model, the methodology, which is developed based on a general graphical representation for chain conformations, is applicable to any off-lattice chain representations. Moreover, the analytical formulation of the method makes possible the systematic development of the theory for more complex tertiary structures.

Citing Articles

Computing the conformational entropy for RNA folds.

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RNA folding on the 3D triangular lattice.

Gillespie J, Mayne M, Jiang M BMC Bioinformatics. 2009; 10:369.

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Prediction of geometrically feasible three-dimensional structures of pseudoknotted RNA through free energy estimation.

Zhang J, Dundas J, Lin M, Chen R, Wang W, Liang J RNA. 2009; 15(12):2248-63.

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RNA folding: conformational statistics, folding kinetics, and ion electrostatics.

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