The power of coarse graining in biomolecular simulations

Helgi I. Ingolfsson; Cesar A. Lopez; Jaakko J. Uusitalo; Djurre H. de Jong; Srinivasa M. Gopal; Xavier Periole; Siewert J. Marrink

doi:10.1002/wcms.1169

The power of coarse graining in biomolecular simulations

Helgi I. Ingolfsson, Cesar A. Lopez, Jaakko J. Uusitalo, Djurre H. de Jong, Srinivasa M. Gopal, Xavier Periole, Siewert J. Marrink^*

^*Corresponding author voor dit werk

Moleculaire Dynamica

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Computational modeling of biological systems is challenging because of the multitude of spatial and temporal scales involved. Replacing atomistic detail with lower resolution, coarse grained (CG), beads has opened the way to simulate large-scale biomolecular processes on time scales inaccessible to all-atom models. We provide an overview of some of the more popular CG models used in biomolecular applications to date, focusing on models that retain chemical specificity. A few state-of-the-art examples of protein folding, membrane protein gating and self-assembly, DNA hybridization, and modeling of carbohydrate fibers are used to illustrate the power and diversity of current CG modeling.

Originele taal-2	English
Pagina's (van-tot)	225-248
Aantal pagina's	24
Tijdschrift	Wiley Interdisciplinary Reviews. Computational Molecular Science
Volume	4
Nummer van het tijdschrift	3
DOI's	https://doi.org/10.1002/wcms.1169
Status	Published - mei-2014

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10.1002/wcms.1169Licentie: CC BY-NC

The power of coarse graining inbiomolecular simulationsFinal publisher's version, 15,8 MBLicentie: CC BY-NC

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title = "The power of coarse graining in biomolecular simulations",

abstract = "Computational modeling of biological systems is challenging because of the multitude of spatial and temporal scales involved. Replacing atomistic detail with lower resolution, coarse grained (CG), beads has opened the way to simulate large-scale biomolecular processes on time scales inaccessible to all-atom models. We provide an overview of some of the more popular CG models used in biomolecular applications to date, focusing on models that retain chemical specificity. A few state-of-the-art examples of protein folding, membrane protein gating and self-assembly, DNA hybridization, and modeling of carbohydrate fibers are used to illustrate the power and diversity of current CG modeling.",

keywords = "MOLECULAR-DYNAMICS SIMULATIONS, RESIDUE FORCE-FIELD, PROTEIN-COUPLED RECEPTORS, MODEL LIPID-BILAYERS, STRUCTURE PREDICTION, COMPUTATIONAL MICROSCOPE, MECHANOSENSITIVE CHANNEL, STRUCTURAL DETERMINANTS, INTERACTION POTENTIALS, TRANSMEMBRANE HELICES",

author = "Ingolfsson, {Helgi I.} and Lopez, {Cesar A.} and Uusitalo, {Jaakko J.} and {de Jong}, {Djurre H.} and Gopal, {Srinivasa M.} and Xavier Periole and Marrink, {Siewert J.}",

year = "2014",

month = may,

doi = "10.1002/wcms.1169",

language = "English",

volume = "4",

pages = "225--248",

journal = "Wiley Interdisciplinary Reviews. Computational Molecular Science",

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TY - JOUR

T1 - The power of coarse graining in biomolecular simulations

AU - Ingolfsson, Helgi I.

AU - Lopez, Cesar A.

AU - Uusitalo, Jaakko J.

AU - de Jong, Djurre H.

AU - Gopal, Srinivasa M.

AU - Periole, Xavier

AU - Marrink, Siewert J.

PY - 2014/5

Y1 - 2014/5

N2 - Computational modeling of biological systems is challenging because of the multitude of spatial and temporal scales involved. Replacing atomistic detail with lower resolution, coarse grained (CG), beads has opened the way to simulate large-scale biomolecular processes on time scales inaccessible to all-atom models. We provide an overview of some of the more popular CG models used in biomolecular applications to date, focusing on models that retain chemical specificity. A few state-of-the-art examples of protein folding, membrane protein gating and self-assembly, DNA hybridization, and modeling of carbohydrate fibers are used to illustrate the power and diversity of current CG modeling.

AB - Computational modeling of biological systems is challenging because of the multitude of spatial and temporal scales involved. Replacing atomistic detail with lower resolution, coarse grained (CG), beads has opened the way to simulate large-scale biomolecular processes on time scales inaccessible to all-atom models. We provide an overview of some of the more popular CG models used in biomolecular applications to date, focusing on models that retain chemical specificity. A few state-of-the-art examples of protein folding, membrane protein gating and self-assembly, DNA hybridization, and modeling of carbohydrate fibers are used to illustrate the power and diversity of current CG modeling.

KW - MOLECULAR-DYNAMICS SIMULATIONS

KW - RESIDUE FORCE-FIELD

KW - PROTEIN-COUPLED RECEPTORS

KW - MODEL LIPID-BILAYERS

KW - STRUCTURE PREDICTION

KW - COMPUTATIONAL MICROSCOPE

KW - MECHANOSENSITIVE CHANNEL

KW - STRUCTURAL DETERMINANTS

KW - INTERACTION POTENTIALS

KW - TRANSMEMBRANE HELICES

U2 - 10.1002/wcms.1169

DO - 10.1002/wcms.1169

M3 - Review article

SN - 1759-0876

VL - 4

SP - 225

EP - 248

JO - Wiley Interdisciplinary Reviews. Computational Molecular Science

JF - Wiley Interdisciplinary Reviews. Computational Molecular Science

IS - 3

ER -

The power of coarse graining in biomolecular simulations

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