Enhanced sampling method in molecular simulations using genetic algorithm for biomolecular systems

We propose a molecular simulation method using genetic algorithm (GA) for biomolecular systems to obtain ensemble averages efficiently. In this method, we incorporate the genetic crossover, which is one of the operations of GA, to any simulation method such as conventional molecular dynamics (MD), M...

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Veröffentlicht in:	Journal of computational chemistry 2019-01, Vol.40 (2), p.475-481
Hauptverfasser:	Sakae, Yoshitake, Straub, John E., Okamoto, Yuko
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Sprache:	eng
Schlagworte:	Backbone Computer simulation Crossovers Exchanging genetic algorithm Genetic algorithms Methods Molecular dynamics molecular simulation Monte Carlo simulation parallel computing Peptides protein folding Sampling sampling method Simulation
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creator	Sakae, Yoshitake Straub, John E. Okamoto, Yuko
description	We propose a molecular simulation method using genetic algorithm (GA) for biomolecular systems to obtain ensemble averages efficiently. In this method, we incorporate the genetic crossover, which is one of the operations of GA, to any simulation method such as conventional molecular dynamics (MD), Monte Carlo, and other simulation methods. The genetic crossover proposes candidate conformations by exchanging parts of conformations of a target molecule between a pair of conformations during the simulation. If the candidate conformations are accepted, the simulation resumes from the accepted ones. While conventional simulations are based on local update of conformations, the genetic crossover introduces global update of conformations. As an example of the present approach, we incorporated genetic crossover to MD simulations. We tested the validity of the method by calculating ensemble averages and the sampling efficiency by using two kinds of peptides, ALA3 and (AAQAA)3. The results show that for ALA3 system, the distribution probabilities of backbone dihedral angles are in good agreement with those of the conventional MD and replica‐exchange MD simulations. In the case of (AAQAA)3 system, our method showed lower structural correlation of α‐helix structures than the other two methods and more flexibility in the backbone ψ angles than the conventional MD simulation. These results suggest that our method gives more efficient conformational sampling than conventional simulation methods based on local update of conformations. © 2018 Wiley Periodicals, Inc. A sampling method for molecular simulations using genetic algorithm (GA) is presented. During the conventional molecular dynamics or Monte Carlo simulations, candidate conformations are regularly suggested by crossover and selection operation based on GA. If the conformations are accepted, new simulations using the accepted conformations start. The authors confirmed the validity for the statistics quantity and the sampling efficiency of this method by using two kinds of peptides, ALA3 and (AAQAA)3.
doi_str_mv	10.1002/jcc.25735
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In this method, we incorporate the genetic crossover, which is one of the operations of GA, to any simulation method such as conventional molecular dynamics (MD), Monte Carlo, and other simulation methods. The genetic crossover proposes candidate conformations by exchanging parts of conformations of a target molecule between a pair of conformations during the simulation. If the candidate conformations are accepted, the simulation resumes from the accepted ones. While conventional simulations are based on local update of conformations, the genetic crossover introduces global update of conformations. As an example of the present approach, we incorporated genetic crossover to MD simulations. We tested the validity of the method by calculating ensemble averages and the sampling efficiency by using two kinds of peptides, ALA3 and (AAQAA)3. The results show that for ALA3 system, the distribution probabilities of backbone dihedral angles are in good agreement with those of the conventional MD and replica‐exchange MD simulations. In the case of (AAQAA)3 system, our method showed lower structural correlation of α‐helix structures than the other two methods and more flexibility in the backbone ψ angles than the conventional MD simulation. These results suggest that our method gives more efficient conformational sampling than conventional simulation methods based on local update of conformations. © 2018 Wiley Periodicals, Inc. A sampling method for molecular simulations using genetic algorithm (GA) is presented. During the conventional molecular dynamics or Monte Carlo simulations, candidate conformations are regularly suggested by crossover and selection operation based on GA. If the conformations are accepted, new simulations using the accepted conformations start. 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In this method, we incorporate the genetic crossover, which is one of the operations of GA, to any simulation method such as conventional molecular dynamics (MD), Monte Carlo, and other simulation methods. The genetic crossover proposes candidate conformations by exchanging parts of conformations of a target molecule between a pair of conformations during the simulation. If the candidate conformations are accepted, the simulation resumes from the accepted ones. While conventional simulations are based on local update of conformations, the genetic crossover introduces global update of conformations. As an example of the present approach, we incorporated genetic crossover to MD simulations. We tested the validity of the method by calculating ensemble averages and the sampling efficiency by using two kinds of peptides, ALA3 and (AAQAA)3. The results show that for ALA3 system, the distribution probabilities of backbone dihedral angles are in good agreement with those of the conventional MD and replica‐exchange MD simulations. In the case of (AAQAA)3 system, our method showed lower structural correlation of α‐helix structures than the other two methods and more flexibility in the backbone ψ angles than the conventional MD simulation. These results suggest that our method gives more efficient conformational sampling than conventional simulation methods based on local update of conformations. © 2018 Wiley Periodicals, Inc. A sampling method for molecular simulations using genetic algorithm (GA) is presented. During the conventional molecular dynamics or Monte Carlo simulations, candidate conformations are regularly suggested by crossover and selection operation based on GA. If the conformations are accepted, new simulations using the accepted conformations start. 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In this method, we incorporate the genetic crossover, which is one of the operations of GA, to any simulation method such as conventional molecular dynamics (MD), Monte Carlo, and other simulation methods. The genetic crossover proposes candidate conformations by exchanging parts of conformations of a target molecule between a pair of conformations during the simulation. If the candidate conformations are accepted, the simulation resumes from the accepted ones. While conventional simulations are based on local update of conformations, the genetic crossover introduces global update of conformations. As an example of the present approach, we incorporated genetic crossover to MD simulations. We tested the validity of the method by calculating ensemble averages and the sampling efficiency by using two kinds of peptides, ALA3 and (AAQAA)3. The results show that for ALA3 system, the distribution probabilities of backbone dihedral angles are in good agreement with those of the conventional MD and replica‐exchange MD simulations. In the case of (AAQAA)3 system, our method showed lower structural correlation of α‐helix structures than the other two methods and more flexibility in the backbone ψ angles than the conventional MD simulation. These results suggest that our method gives more efficient conformational sampling than conventional simulation methods based on local update of conformations. © 2018 Wiley Periodicals, Inc. A sampling method for molecular simulations using genetic algorithm (GA) is presented. During the conventional molecular dynamics or Monte Carlo simulations, candidate conformations are regularly suggested by crossover and selection operation based on GA. If the conformations are accepted, new simulations using the accepted conformations start. The authors confirmed the validity for the statistics quantity and the sampling efficiency of this method by using two kinds of peptides, ALA3 and (AAQAA)3.</abstract><cop>Hoboken, USA</cop><pub>John Wiley & Sons, Inc</pub><pmid>30414195</pmid><doi>10.1002/jcc.25735</doi><tpages>7</tpages><orcidid>https://orcid.org/0000-0002-7083-2326</orcidid></addata></record>
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subjects	Backbone Computer simulation Crossovers Exchanging genetic algorithm Genetic algorithms Methods Molecular dynamics molecular simulation Monte Carlo simulation parallel computing Peptides protein folding Sampling sampling method Simulation
title	Enhanced sampling method in molecular simulations using genetic algorithm for biomolecular systems
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