Exploiting symmetry properties of the discretizable molecular distance geometry problem

Antonio Mucherino; Carlile Lavor; Leo Liberti

doi:10.1142/S0219720012420097

Exploiting symmetry properties of the discretizable molecular distance geometry problem

Antonio Mucherino
, Carlile Lavor
, Leo Liberti

University of Rennes
University of Campinas (UNICAMP)

Research output: Contribution to journal › Article › peer-review

Abstract

The Discretizable Molecular Distance Geometry Problem (DMDGP) involves a subset of instances of the distance geometry problem for which some assumptions allowing for discretization are satisfied. The search domain for the DMDGP is a binary tree that can be efficiently explored by employing a Branch & Prune (BP) algorithm. We showed in recent works that this binary tree may contain several symmetries, which are directly related to the total number of solutions of DMDGP instances. In this paper, we study the possibility of exploiting these symmetries for speeding up the solution of DMDGPs, and propose an extension of the BP algorithm that we named symmetry-driven BP (symBP). Computational experiments on artificial and protein instances are presented.

Original language	English
Article number	1242009
Journal	Journal of Bioinformatics and Computational Biology
Volume	10
Issue number	3
DOIs	https://doi.org/10.1142/S0219720012420097
Publication status	Published - 1 Jun 2012

Keywords

NMR
Protein conformation
branch-and-prune
discretization
distance geometry
symmetry

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10.1142/S0219720012420097

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abstract = "The Discretizable Molecular Distance Geometry Problem (DMDGP) involves a subset of instances of the distance geometry problem for which some assumptions allowing for discretization are satisfied. The search domain for the DMDGP is a binary tree that can be efficiently explored by employing a Branch \& Prune (BP) algorithm. We showed in recent works that this binary tree may contain several symmetries, which are directly related to the total number of solutions of DMDGP instances. In this paper, we study the possibility of exploiting these symmetries for speeding up the solution of DMDGPs, and propose an extension of the BP algorithm that we named symmetry-driven BP (symBP). Computational experiments on artificial and protein instances are presented.",

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N2 - The Discretizable Molecular Distance Geometry Problem (DMDGP) involves a subset of instances of the distance geometry problem for which some assumptions allowing for discretization are satisfied. The search domain for the DMDGP is a binary tree that can be efficiently explored by employing a Branch & Prune (BP) algorithm. We showed in recent works that this binary tree may contain several symmetries, which are directly related to the total number of solutions of DMDGP instances. In this paper, we study the possibility of exploiting these symmetries for speeding up the solution of DMDGPs, and propose an extension of the BP algorithm that we named symmetry-driven BP (symBP). Computational experiments on artificial and protein instances are presented.

AB - The Discretizable Molecular Distance Geometry Problem (DMDGP) involves a subset of instances of the distance geometry problem for which some assumptions allowing for discretization are satisfied. The search domain for the DMDGP is a binary tree that can be efficiently explored by employing a Branch & Prune (BP) algorithm. We showed in recent works that this binary tree may contain several symmetries, which are directly related to the total number of solutions of DMDGP instances. In this paper, we study the possibility of exploiting these symmetries for speeding up the solution of DMDGPs, and propose an extension of the BP algorithm that we named symmetry-driven BP (symBP). Computational experiments on artificial and protein instances are presented.

KW - NMR

KW - Protein conformation

KW - branch-and-prune

KW - discretization

KW - distance geometry

KW - symmetry

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JO - Journal of Bioinformatics and Computational Biology

JF - Journal of Bioinformatics and Computational Biology

IS - 3

M1 - 1242009

ER -

Exploiting symmetry properties of the discretizable molecular distance geometry problem

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