Computing the Conformational Entropy for RNA Folds

Overview

Journal J Chem Phys

Publisher American Institute of Physics

Specialties Biophysics
Chemistry

Date 2010 Jun 25

PMID 20572741

Citations 16

Authors

Liang Liu

Shi-Jie Chen

Affiliations

Soon will be listed here.

Abstract

We develop a polymer physics-based method to compute the conformational entropy for RNA tertiary folds, namely, conformations consisting of multiple helices connected through (cross-linked) loops. The theory is based on a virtual bond conformational model for the nucleotide chain. A key issue in the calculation of the entropy is how to treat the excluded volume interactions. The weak excluded volume interference between the different loops leads to the decomposition of the whole structure into a number of three-body building blocks, each consisting of a loop and two helices connected to the two ends of the loop. The simple construct of the three-body system allows an accurate computation for the conformational entropy for each building block. The assembly of the building blocks gives the entropy of the whole structure. This approach enables treatment of molten globule-like folds (partially unfolded tertiary structures) for RNAs. Extensive tests against experiments and exact computer enumerations indicate that the method can give accurate results for the entropy. The method developed here provides a solid first step toward a systematic development of a theory for the entropy and free energy landscape for complex tertiary folds for RNAs and proteins.

Citing Articles

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Topological Constraints and Their Conformational Entropic Penalties on RNA Folds.

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Theory and Modeling of RNA Structure and Interactions with Metal Ions and Small Molecules.

Sun L, Zhang D, Chen S Annu Rev Biophys. 2017; 46:227-246.

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Structure Prediction of RNA Loops with a Probabilistic Approach.

Li J, Zhang J, Wang J, Li W, Wang W PLoS Comput Biol. 2016; 12(8):e1005032.

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