The role of subunit hinges and molecular “switches” in the control of viral capsid polymorphism
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Periodic table of virus capsids: implications for natural selection and designAtomic structure reveals the unique capsid organization of a dsRNA virusGeometric considerations in virus capsid size specificity, auxiliary requirements, and bucklingStructural Convergence between Cryo-EM and NMR Reveals Intersubunit Interactions Critical for HIV-1 Capsid FunctionAssembly-Directed Antivirals Differentially Bind Quasiequivalent Pockets to Modify Hepatitis B Virus Capsid Tertiary and Quaternary StructureMonodisperse polymer-virus hybrid nanoparticlesMechanisms of size control and polymorphism in viral capsid assemblyThe thermodynamics of virus capsid assembly.Optimization of an elastic network augmented coarse grained model to study CCMV capsid deformationModeling Viral Capsid Assembly.Crystal Structures of a Piscine Betanodavirus: Mechanisms of Capsid Assembly and Viral Infection.Self-assembly of viral capsid protein and RNA molecules of different sizes: requirement for a specific high protein/RNA mass ratio.Engineered mutations change the structure and stability of a virus-like particlePackaging of a polymer by a viral capsid: the interplay between polymer length and capsid sizeDesigning two self-assembly mechanisms into one viral capsid proteinPartitivirus structure reveals a 120-subunit, helix-rich capsid with distinctive surface arches formed by quasisymmetric coat-protein dimers.A theory for viral capsid assembly around electrostatic cores.Synergistic effects of mutations and nanoparticle templating in the self-assembly of cowpea chlorotic mottle virus capsids.Natural supramolecular building blocks: from virus coat proteins to viral nanoparticles.Exploiting plant virus-derived components to achieve in planta expression and for templates for synthetic biology applications.Nodavirus-based biological container for targeted delivery system.The Effect of RNA Secondary Structure on the Self-Assembly of Viral Capsids.Structure and assembly of scalable porous protein cages.Induction of particle polymorphism by cucumber necrosis virus coat protein mutants in vivo.The N-terminal region containing the zinc finger domain of tobacco streak virus coat protein is essential for the formation of virus-like particles.Atomistic modeling of the low-frequency mechanical modes and Raman spectra of icosahedral virus capsids.Assembly of viral capsids, buckling, and the Asaro-Grinfeld-Tiller instability.Templated Formation of Luminescent Virus-like Particles by Tailor-made Pt(II)-Amphiphiles.Quantum dot encapsulation in virus-like particles with tuneable structural properties and low toxicitySelf-assembly and characterization of small and monodisperse dye nanospheres in a protein cageCapsid Structure of dsRNA Fungal Viruses
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P2860
The role of subunit hinges and molecular “switches” in the control of viral capsid polymorphism
description
article
@en
im April 2006 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована у квітні 2006
@uk
name
The role of subunit hinges and ...... l of viral capsid polymorphism
@en
The role of subunit hinges and ...... l of viral capsid polymorphism
@nl
type
label
The role of subunit hinges and ...... l of viral capsid polymorphism
@en
The role of subunit hinges and ...... l of viral capsid polymorphism
@nl
prefLabel
The role of subunit hinges and ...... l of viral capsid polymorphism
@en
The role of subunit hinges and ...... l of viral capsid polymorphism
@nl
P2093
P1476
The role of subunit hinges and ...... l of viral capsid polymorphism
@en
P2093
Jennifer M. Johnson
Jinghua Tang
John E. Johnson
Kelly A. Dryden
Mark J. Young
P356
10.1016/J.JSB.2005.10.013
P577
2006-04-01T00:00:00Z