Molecular dynamics simulations of biological membranes and membrane proteins using enhanced conformational sampling algorithms

Mori, Takaharu; Miyashita, Naoyuki; Im, Wonpil; Feig, Michael; Sugita, Yuji

doi:10.1016/j.bbamem.2015.12.032

Cited by 123 publications

(117 citation statements)

References 234 publications

(278 reference statements)

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“…To enhance conformational sampling, we combined replica exchange with molecular dynamics (REMD) simulations by running the CHARMM simulation program with the Multiscale Modeling Tools for Structural Biology . REMD simulations used 32 temperatures geometrically spaced over the range from 300 to 800 K. The exchange of the conformations in neighboring temperatures was attempted at every 500 time‐steps (1‐ps) according to the Metropolis criterion.…”

Section: Methodsmentioning

confidence: 99%

Membrane insertion of fusion peptides from Ebola and Marburg viruses studied by replica‐exchange molecular dynamics simulations

2017

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This work presents replica-exchange molecular dynamics simulations of inserting a 16-residue Ebola virus fusion peptide into a membrane bilayer. A computational approach is applied for modeling the peptide at the explicit all-atom level and the membrane-aqueous bilayer by a generalized Born continuum model with a smoothed switching function (GBSW). We provide an assessment of the model calculations in terms of three metrics: (1) the ability to reproduce the NMR structure of the peptide determined in the presence of SDS micelles and comparable structural data on other fusion peptides; (2) determination of the effects of the mutation Trp-8 to Ala and sequence discrimination of the homologous Marburg virus; and (3) calculation of potentials of mean force for estimating the partitioning free energy and their comparison to predictions from the Wimley-White interfacial hydrophobicity scale. We found the GBSW implicit membrane model to produce results of limited accuracy in conformational properties of the peptide when compared to the NMR structure, yet the model resolution is sufficient to determine the effect of sequence differentiation on peptide-membrane integration. © 2016 Wiley Periodicals, Inc.

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Section: Methodsmentioning

confidence: 99%

Membrane insertion of fusion peptides from Ebola and Marburg viruses studied by replica‐exchange molecular dynamics simulations

2017

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“…Computational studies and in particular molecular dynamics (MD) simulations are now a firmly established technique for the study of biological membranes. At the all‐atom or united‐atom level, molecular simulations have been successfully used to study various membrane properties, permeation of small molecules directly through model membranes, transport of ions and small molecules through specific channels, and dynamics of membrane protein structures solved in different environments …”

Section: Introductionmentioning

confidence: 99%

CHARMM‐GUI Martini Maker for modeling and simulation of complex bacterial membranes with lipopolysaccharides

et al. 2017

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A complex cell envelope, composed of a mixture of lipid types including complex lipopolysaccharides, protects bacteria from the external environment. Clearly, the proteins embedded within the various components of the cell envelope have an intricate relationship with their local environment. Therefore, to obtain meaningful results, molecular simulations need to mimic as far as possible this chemically heterogeneous system. However, setting up such systems for computational studies is far from trivial, and consequently the vast majority of simulations of outer membrane proteins still rely on oversimplified phospholipid membrane models. This work presents an update of CHARMM-GUI Martini Maker for coarse-grained modeling and simulation of complex bacterial membranes with lipopolysaccharides. The qualities of the outer membrane systems generated by Martini Maker are validated by simulating them in bilayer, vesicle, nanodisc, and micelle environments (with and without outer membrane proteins) using the Martini force field. We expect this new feature in Martini Maker to be a useful tool for modeling large, complicated bacterial outer membrane systems in a user-friendly manner.

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“…Reduction of these barriers will also enable at tighter integration between computational development and experimental testing, which is necessary, for example, to improve the energy functions and to foster the creation of more realistic lipid bilayer models, beyond the implicit solvent approximations commonly used today 28 . Indeed, recent technical advances in membrane protein structural biology (X-ray crystallography, NMR and cryo electron microscopy) 29–36 suggest that more systematic high-resolution characterization of designed-membrane proteins may be achieved in the near future.…”

Section: Beyond Minimalism: the Need For Better Experimental Methodsmentioning

confidence: 99%

Toward high-resolution computational design of the structure and function of helical membrane proteins

Barth

Senes

2016

Nat Struct Mol Biol

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The computational design of α-helical membrane proteins is still in its infancy but has made important progress. De novo design has produced stable, specific and active minimalistic oligomeric systems. Computational re-engineering can improve stability and modulate the function of natural membrane proteins. Currently, the major hurdle for the field is not computational, but the experimental characterization of the designs. The emergence of new structural methods for membrane proteins will accelerate progress

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Molecular dynamics simulations of biological membranes and membrane proteins using enhanced conformational sampling algorithms

Cited by 123 publications

References 234 publications

Membrane insertion of fusion peptides from Ebola and Marburg viruses studied by replica‐exchange molecular dynamics simulations

Membrane insertion of fusion peptides from Ebola and Marburg viruses studied by replica‐exchange molecular dynamics simulations

CHARMM‐GUI Martini Maker for modeling and simulation of complex bacterial membranes with lipopolysaccharides

Toward high-resolution computational design of the structure and function of helical membrane proteins

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