Literature DB >> 26331253

The Robust Assembly of Small Symmetric Nanoshells.

Jef Wagner1, Roya Zandi2.   

Abstract

Highly symmetric nanoshells are found in many biological systems, such as clathrin cages and viral shells. Many studies have shown that symmetric shells appear in nature as a result of the free-energy minimization of a generic interaction between their constituent subunits. We examine the physical basis for the formation of symmetric shells, and by using a minimal model, demonstrate that these structures can readily grow from the irreversible addition of identical subunits. Our model of nanoshell assembly shows that the spontaneous curvature regulates the size of the shell while the mechanical properties of the subunit determine the symmetry of the assembled structure. Understanding the minimum requirements for the formation of closed nanoshells is a necessary step toward engineering of nanocontainers, which will have far-reaching impact in both material science and medicine.
Copyright © 2015 Biophysical Society. Published by Elsevier Inc. All rights reserved.

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Year:  2015        PMID: 26331253      PMCID: PMC4564843          DOI: 10.1016/j.bpj.2015.07.041

Source DB:  PubMed          Journal:  Biophys J        ISSN: 0006-3495            Impact factor:   4.033


  39 in total

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4.  Self-assembly of polyhedral shells: a molecular dynamics study.

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5.  Continuum theory of retroviral capsids.

Authors:  T T Nguyen; R F Bruinsma; W M Gelbart
Journal:  Phys Rev Lett       Date:  2006-02-21       Impact factor: 9.161

6.  Monodisperse polymer-virus hybrid nanoparticles.

Authors:  Friso D Sikkema; Marta Comellas-Aragonès; Remco G Fokkink; Benedictus J M Verduin; Jeroen J L M Cornelissen; Roeland J M Nolte
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7.  Irreversible growth model for virus capsid assembly.

Authors:  Stephen D Hicks; C L Henley
Journal:  Phys Rev E Stat Nonlin Soft Matter Phys       Date:  2006-09-25

8.  Self-assembly of viral capsid protein and RNA molecules of different sizes: requirement for a specific high protein/RNA mass ratio.

Authors:  Ruben D Cadena-Nava; Mauricio Comas-Garcia; Rees F Garmann; A L N Rao; Charles M Knobler; William M Gelbart
Journal:  J Virol       Date:  2011-12-28       Impact factor: 5.103

9.  Highly specific salt bridges govern bacteriophage P22 icosahedral capsid assembly: identification of the site in coat protein responsible for interaction with scaffolding protein.

Authors:  Juliana R Cortines; Tina Motwani; Aashay A Vyas; Carolyn M Teschke
Journal:  J Virol       Date:  2014-03-05       Impact factor: 5.103

10.  Mechanisms of size control and polymorphism in viral capsid assembly.

Authors:  Oren M Elrad; Michael F Hagan
Journal:  Nano Lett       Date:  2008-10-25       Impact factor: 11.189
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  19 in total

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Journal:  Biophys J       Date:  2017-07-12       Impact factor: 4.033

2.  Beyond icosahedral symmetry in packings of proteins in spherical shells.

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3.  Robust nonequilibrium pathways to microcompartment assembly.

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Review 4.  Physical Chemistry of Cellular Liquid-Phase Separation.

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Journal:  Chemistry       Date:  2019-02-07       Impact factor: 5.236

5.  Why Enveloped Viruses Need Cores-The Contribution of a Nucleocapsid Core to Viral Budding.

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Journal:  Biophys J       Date:  2018-02-06       Impact factor: 4.033

Review 6.  Recent advances in coarse-grained modeling of virus assembly.

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7.  Reentrant Phase Transitions and Non-Equilibrium Dynamics in Membraneless Organelles.

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Journal:  Biochemistry       Date:  2018-04-03       Impact factor: 3.162

Review 8.  Molecular dynamics of the viral life cycle: progress and prospects.

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Journal:  Curr Opin Virol       Date:  2021-08-28       Impact factor: 7.121

9.  Why large icosahedral viruses need scaffolding proteins.

Authors:  Siyu Li; Polly Roy; Alex Travesset; Roya Zandi
Journal:  Proc Natl Acad Sci U S A       Date:  2018-10-09       Impact factor: 11.205

10.  Mechanisms of Scaffold-Mediated Microcompartment Assembly and Size Control.

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Journal:  ACS Nano       Date:  2021-03-08       Impact factor: 15.881
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