Optimization of an Elastic Network Augmented Coarse Grained Model to Study CCMV Capsid Deformation

Globisch, Christoph; Krishnamani, Venkatramanan; Deserno, Markus; Peter, Christine

doi:10.1371/journal.pone.0060582

Cited by 47 publications

(60 citation statements)

References 71 publications

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“…29 While this model handles a variety of secondary structure formation aspects very accurately, for instance, cooperativity in helix and helix-bundle folding transitions 30,31 and β-barrel formation, 32 it is not detailed enough to achieve folding of complex protein structures. However, nontrivial tertiary or quaternary folds can still be treated by adding stabilizing elastic networks, 33,34 but unstructured tails and flexible loops can now be left free to explore a meaningful phase space. The implicit-solvent CG lipid model used here 35,36 provides a similar resolution as the MARTINI force field (about three to four heavy atoms per bead).…”

Section: Individual Modelsmentioning

confidence: 99%

More than the sum of its parts: Coarse-grained peptide-lipid interactions from a simple cross-parametrization

Bereau

Wang

Deserno

2014

The Journal of Chemical Physics

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Interfacial systems are at the core of fascinating phenomena in many disciplines, such as biochemistry, soft-matter physics, and food science. However, the parametrization of accurate, reliable, and consistent coarse-grained (CG) models for systems at interfaces remains a challenging endeavor. In the present work, we explore to what extent two independently developed solvent-free CG models of peptides and lipids-of different mapping schemes, parametrization methods, target functions, and validation criteria-can be combined by only tuning the cross-interactions. Our results show that the cross-parametrization can reproduce a number of structural properties of membrane peptides (for example, tilt and hydrophobic mismatch), in agreement with existing peptide-lipid CG force fields. We find encouraging results for two challenging biophysical problems: (i) membrane pore formation mediated by the cooperative action of several antimicrobial peptides, and (ii) the insertion and folding of the helix-forming peptide WALP23 in the membrane. © 2014 AIP Publishing LLC.

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Section: Individual Modelsmentioning

confidence: 99%

More than the sum of its parts: Coarse-grained peptide-lipid interactions from a simple cross-parametrization

Bereau

Wang

Deserno

2014

The Journal of Chemical Physics

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“…As mentioned earlier, the mechanical response characterized through AFM nanoindentation experiments performed on the Cowpea Chlorotic Mottle Virus (CCMV) [5,22,23] have been computationally studied previously [11,12,24]. Given the amount of structural and physical information available, here we take the CCMV capsid as a test case to generate a CapsidMesh with our methodology which can then be used to study the mechanical properties of a macromolecular particle.…”

Section: Resultsmentioning

confidence: 99%

“…From a theoretical standpoint, it has also become possible to study whole viruses by molecular dynamics (MD) methods employing all-atom models [6][7][8][9]. In particular, the nanoindentation experiments performed on the Cowpea Chlorotic Mottle Virus (CCMV) [10] have been computationally studied to some depth using coarse-grain models [11], elastic network approximations [12], and topology-based self-organized polymer models [13].…”

Section: Introductionmentioning

confidence: 99%

CapsidMesh: atomic-detail structured mesh representation of icosahedral viral capsids and the study of their mechanical properties

Alonzo-Velázquez

Botello-Rionda

Herrera-Guzmán

et al. 2017

Preprint

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SUMMARYViruses are the most abundant pathogens affecting all forms of life. A major component of a virus is a protein shell, known as the viral capsid, that encapsulates the genomic material. The capsid has the fundamental functions to protect and transport the viral genome, and recognize the host cell. Descriptions of this macromolecular complex have been proposed at different scales of approximation, but little is known about the physical properties of the capsid. Here, we introduce a methodology to generate a structured volumetric mesh of icosahedral viral capsids, or CapsidMesh, based on their atomic information. The CapsidMesh models are suitable for numerical simulations and analysis, keeping control over all levels of protein structure (atoms, amino acids, chains, oligomers, capsid). Material properties of the capsid subunits can be set at every mesh element and then run a simulation of a physical process using a third-party package. Analysis can be made by extracting the information of interest. We validated our methodology by generating a CapsidMesh and simulating the nanoindentation through Finite Element analysis of several capsids previously characterized by Atomic Force Microscopy experiments. We estimated the elastic modulus consistently by reproducing the experimental linear elastic response. Our results show that the atomic detail of the CapsidMesh is sufficient to reproduce anisotropic properties of the particle. Supplementary Information available.

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“…Further applications of the model include the thermodynamics of helix-folding transitions (Bereau et al 2010 and the formation of b-barrels at the interface between virus capsid proteins (Bereau et al 2012). Though the model lacks chemical detail to fold more complex protein structures, the use of stabilizing elastic networks (e.g., Periole et al 2009;Globisch et al 2013) on parts of the protein can help explore the conformational variability of flexible segments.…”

Section: Cg Modelsmentioning

confidence: 99%

Enhanced Sampling of Coarse-Grained Transmembrane-Peptide Structure Formation from Hydrogen-Bond Replica Exchange

Bereau

Deserno

2014

J Membrane Biol

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Protein structure formation in the membrane highlights a grand challenge of sampling in computer simulations, because kinetic traps and slow dynamics make it difficult to find the native state. Exploiting increased fluctuations at higher temperatures can help overcome free-energy barriers, provided the membrane's structure remains stable. In this work, we apply Hamiltonian replica-exchange molecular dynamics, where we only tune the backbone hydrogen-bond strength to help reduce the propensity of long-lived misfolded states. Using a recently developed coarse-grained model, we illustrate the robustness of the method by folding different WALP transmembrane helical peptides starting from stretched, unstructured conformations. We show the efficiency of the method by comparing to simulations without enhanced sampling, achieving folding in one example after significantly longer simulation times. Analysis of the bilayer structure during folding provides insight into the local membrane deformation during helix formation as a function of chain length (from 16 to 23 residues). Finally, we apply our method to fold the 50-residue-long major pVIII coat protein (fd coat) of the filamentous fd bacteriophage. Our results agree well with experimental structures and atomistic simulations based on implicit membrane models, suggesting that our explicit CG folding protocol can serve as a starting point for better-refined atomistic simulations in a multiscale framework.

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Optimization of an Elastic Network Augmented Coarse Grained Model to Study CCMV Capsid Deformation

Cited by 47 publications

References 71 publications

More than the sum of its parts: Coarse-grained peptide-lipid interactions from a simple cross-parametrization

More than the sum of its parts: Coarse-grained peptide-lipid interactions from a simple cross-parametrization

CapsidMesh: atomic-detail structured mesh representation of icosahedral viral capsids and the study of their mechanical properties

Enhanced Sampling of Coarse-Grained Transmembrane-Peptide Structure Formation from Hydrogen-Bond Replica Exchange

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