Literature DB >> 20303864

Understanding the concentration dependence of viral capsid assembly kinetics--the origin of the lag time and identifying the critical nucleus size.

Michael F Hagan1, Oren M Elrad.   

Abstract

The kinetics for the assembly of viral proteins into a population of capsids can be measured in vitro with size exclusion chromatography or dynamic light scattering, but extracting mechanistic information from these studies is challenging. For example, it is not straightforward to determine the critical nucleus size or the elongation time (the time required for a nucleus to grow to completion). In this work, we study theoretical and computational models for capsid assembly to show that the critical nucleus size can be determined from the concentration dependence of the assembly half-life and that the elongation time is revealed by the length of the lag phase. Furthermore, we find that the system becomes kinetically trapped when nucleation becomes fast compared to elongation. Implications of this constraint for determining elongation mechanisms from experimental assembly data are discussed. Copyright 2010 Biophysical Society. Published by Elsevier Inc. All rights reserved.

Mesh:

Year:  2010        PMID: 20303864      PMCID: PMC2849049          DOI: 10.1016/j.bpj.2009.11.023

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


  40 in total

1.  In vitro papillomavirus capsid assembly analyzed by light scattering.

Authors:  Greg L Casini; David Graham; David Heine; Robert L Garcea; David T Wu
Journal:  Virology       Date:  2004-08-01       Impact factor: 3.616

2.  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
Journal:  Org Biomol Chem       Date:  2006-11-17       Impact factor: 3.876

3.  Distinguishing reversible from irreversible virus capsid assembly.

Authors:  Adam Zlotnick
Journal:  J Mol Biol       Date:  2006-11-11       Impact factor: 5.469

4.  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

5.  Nucleation and growth phases in the polymerization of coat and scaffolding subunits into icosahedral procapsid shells.

Authors:  P E Prevelige; D Thomas; J King
Journal:  Biophys J       Date:  1993-03       Impact factor: 4.033

6.  Quantitative analysis of multi-component spherical virus assembly: scaffolding protein contributes to the global stability of phage P22 procapsids.

Authors:  Kristin N Parent; Adam Zlotnick; Carolyn M Teschke
Journal:  J Mol Biol       Date:  2006-04-21       Impact factor: 5.469

7.  Mechanism of capsid assembly for an icosahedral plant virus.

Authors:  A Zlotnick; R Aldrich; J M Johnson; P Ceres; M J Young
Journal:  Virology       Date:  2000-11-25       Impact factor: 3.616

8.  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

9.  Hepatitis B virus capsid assembly is enhanced by naturally occurring mutation F97L.

Authors:  Pablo Ceres; Stephen J Stray; Adam Zlotnick
Journal:  J Virol       Date:  2004-09       Impact factor: 5.103

10.  Self-assembly of brome mosaic virus capsids: insights from shorter time-scale experiments.

Authors:  Chao Chen; C Cheng Kao; Bogdan Dragnea
Journal:  J Phys Chem A       Date:  2008-08-28       Impact factor: 2.781
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  44 in total

1.  Langevin dynamics simulation of polymer-assisted virus-like assembly.

Authors:  J P Mahalik; M Muthukumar
Journal:  J Chem Phys       Date:  2012-04-07       Impact factor: 3.488

2.  A kinetic Zipper model and the assembly of tobacco mosaic virus.

Authors:  Daniela J Kraft; Willem K Kegel; Paul van der Schoot
Journal:  Biophys J       Date:  2012-06-19       Impact factor: 4.033

3.  Mechanisms of capsid assembly around a polymer.

Authors:  Aleksandr Kivenson; Michael F Hagan
Journal:  Biophys J       Date:  2010-07-21       Impact factor: 4.033

4.  Modeling Viral Capsid Assembly.

Authors:  Michael F Hagan
Journal:  Adv Chem Phys       Date:  2014       Impact factor: 1.000

5.  Simulated self-assembly of the HIV-1 capsid: protein shape and native contacts are sufficient for two-dimensional lattice formation.

Authors:  Bo Chen; Robert Tycko
Journal:  Biophys J       Date:  2011-06-22       Impact factor: 4.033

6.  Mechanisms of kinetic trapping in self-assembly and phase transformation.

Authors:  Michael F Hagan; Oren M Elrad; Robert L Jack
Journal:  J Chem Phys       Date:  2011-09-14       Impact factor: 3.488

7.  Assembly Reactions of Hepatitis B Capsid Protein into Capsid Nanoparticles Follow a Narrow Path through a Complex Reaction Landscape.

Authors:  Roi Asor; Lisa Selzer; Christopher John Schlicksup; Zhongchao Zhao; Adam Zlotnick; Uri Raviv
Journal:  ACS Nano       Date:  2019-06-25       Impact factor: 15.881

8.  Probing the early temporal and spatial interaction of the Sindbis virus capsid and E2 proteins with reverse genetics.

Authors:  Jonathan E Snyder; Christian J Berrios; Thomas J Edwards; Joyce Jose; Rushika Perera; Richard J Kuhn
Journal:  J Virol       Date:  2012-09-05       Impact factor: 5.103

9.  Simulations of HIV capsid protein dimerization reveal the effect of chemistry and topography on the mechanism of hydrophobic protein association.

Authors:  Naiyin Yu; Michael F Hagan
Journal:  Biophys J       Date:  2012-09-19       Impact factor: 4.033

10.  Applying molecular crowding models to simulations of virus capsid assembly in vitro.

Authors:  Gregory R Smith; Lu Xie; Byoungkoo Lee; Russell Schwartz
Journal:  Biophys J       Date:  2014-01-07       Impact factor: 4.033
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