Molecular Dynamics Simulation in Virus Research

Molecular Dynamics Simulation in Virus Research

Virus replication in the host proceeds by chains of interactions between viral and host proteins. The interactions are deeply influenced by host immune molecules and anti-viral compounds, as well as by mutations in viral proteins. To understand how these interactions proceed mechanically and how the...

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Main Authors: Hirotaka eOde, Masaaki eNakashima, Shingo eKitamura, Wataru eSugiura, Hironori eSato
Format: Article
Language:English
Published: Frontiers Media S.A. 2012-07-01
Series:Frontiers in Microbiology
Subjects:
protein dynamics
MD simulation
viral protein
three-dimensional structure
coarse-grained MD
Online Access:http://journal.frontiersin.org/Journal/10.3389/fmicb.2012.00258/full
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spelling doaj-a31cd471363945ac9b73502d7b9779fd2020-11-24T21:24:58ZengFrontiers Media S.A.Frontiers in Microbiology1664-302X2012-07-01310.3389/fmicb.2012.0025831245Molecular Dynamics Simulation in Virus ResearchHirotaka eOde0Hirotaka eOde1Masaaki eNakashima2Masaaki eNakashima3Shingo eKitamura4Shingo eKitamura5Wataru eSugiura6Wataru eSugiura7Hironori eSato8National Hospital Organization Nagoya Medical CenterNational Institute of Infectious DiseasesNational Hospital Organization Nagoya Medical CenterGraduate School of Engineering, Nagoya UniversityNational Hospital Organization Nagoya Medical CenterGraduate School of Engineering, Nagoya UniversityNational Hospital Organization Nagoya Medical CenterGraduate School of Medicine, Nagoya UniversityNational Institute of Infectious DiseasesVirus replication in the host proceeds by chains of interactions between viral and host proteins. The interactions are deeply influenced by host immune molecules and anti-viral compounds, as well as by mutations in viral proteins. To understand how these interactions proceed mechanically and how they are influenced by mutations, one needs to know the structures and dynamics of the proteins. Molecular dynamics (MD) simulation is a powerful computational method for delineating very motions of proteins at an atomic-scale via theoretical and empirical principles in physical chemistry. Recent advances in the hardware and software for biomolecular simulation have rapidly improved the precision and performance of this technique. Consequently, MD simulation is quickly extending the range of applications in biology, helping to reveal unique features of protein structures that would be hard to obtain by experimental methods alone. In this review, we summarize the recent advances in MD simulations in the study of virus-host interactions and evolution, and present future perspectives on this technique.http://journal.frontiersin.org/Journal/10.3389/fmicb.2012.00258/fullprotein dynamicsMD simulationviral proteinthree-dimensional structurecoarse-grained MD
collection DOAJ
language English
format Article
sources DOAJ
author Hirotaka eOde
Hirotaka eOde
Masaaki eNakashima
Masaaki eNakashima
Shingo eKitamura
Shingo eKitamura
Wataru eSugiura
Wataru eSugiura
Hironori eSato
spellingShingle Hirotaka eOde
Hirotaka eOde
Masaaki eNakashima
Masaaki eNakashima
Shingo eKitamura
Shingo eKitamura
Wataru eSugiura
Wataru eSugiura
Hironori eSato
Molecular Dynamics Simulation in Virus Research
Frontiers in Microbiology
protein dynamics
MD simulation
viral protein
three-dimensional structure
coarse-grained MD
author_facet Hirotaka eOde
Hirotaka eOde
Masaaki eNakashima
Masaaki eNakashima
Shingo eKitamura
Shingo eKitamura
Wataru eSugiura
Wataru eSugiura
Hironori eSato
author_sort Hirotaka eOde
title Molecular Dynamics Simulation in Virus Research
title_short Molecular Dynamics Simulation in Virus Research
title_full Molecular Dynamics Simulation in Virus Research
title_fullStr Molecular Dynamics Simulation in Virus Research
title_full_unstemmed Molecular Dynamics Simulation in Virus Research
title_sort molecular dynamics simulation in virus research
publisher Frontiers Media S.A.
series Frontiers in Microbiology
issn 1664-302X
publishDate 2012-07-01
description Virus replication in the host proceeds by chains of interactions between viral and host proteins. The interactions are deeply influenced by host immune molecules and anti-viral compounds, as well as by mutations in viral proteins. To understand how these interactions proceed mechanically and how they are influenced by mutations, one needs to know the structures and dynamics of the proteins. Molecular dynamics (MD) simulation is a powerful computational method for delineating very motions of proteins at an atomic-scale via theoretical and empirical principles in physical chemistry. Recent advances in the hardware and software for biomolecular simulation have rapidly improved the precision and performance of this technique. Consequently, MD simulation is quickly extending the range of applications in biology, helping to reveal unique features of protein structures that would be hard to obtain by experimental methods alone. In this review, we summarize the recent advances in MD simulations in the study of virus-host interactions and evolution, and present future perspectives on this technique.
topic protein dynamics
MD simulation
viral protein
three-dimensional structure
coarse-grained MD
url http://journal.frontiersin.org/Journal/10.3389/fmicb.2012.00258/full
work_keys_str_mv AT hirotakaeode moleculardynamicssimulationinvirusresearch
AT hirotakaeode moleculardynamicssimulationinvirusresearch
AT masaakienakashima moleculardynamicssimulationinvirusresearch
AT masaakienakashima moleculardynamicssimulationinvirusresearch
AT shingoekitamura moleculardynamicssimulationinvirusresearch
AT shingoekitamura moleculardynamicssimulationinvirusresearch
AT wataruesugiura moleculardynamicssimulationinvirusresearch
AT wataruesugiura moleculardynamicssimulationinvirusresearch
AT hironoriesato moleculardynamicssimulationinvirusresearch
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