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Literature DB >> 24507609

Mechanical stability and reversible fracture of vault particles.

Aida Llauró¹, Pablo Guerra², Nerea Irigoyen³, José F Rodríguez⁴, Núria Verdaguer², Pedro J de Pablo⁵.

Abstract

Vaults are the largest ribonucleoprotein particles found in eukaryotic cells, with an unclear cellular function and promising applications as vehicles for drug delivery. In this article, we examine the local stiffness of individual vaults and probe their structural stability with atomic force microscopy under physiological conditions. Our data show that the barrel, the central part of the vault, governs both the stiffness and mechanical strength of these particles. In addition, we induce single-protein fractures in the barrel shell and monitor their temporal evolution. Our high-resolution atomic force microscopy topographies show that these fractures occur along the contacts between two major vault proteins and disappear over time. This unprecedented systematic self-healing mechanism, which enables these particles to reversibly adapt to certain geometric constraints, might help vaults safely pass through the nuclear pore complex and potentiate their role as self-reparable nanocontainers.

Entities: Disease

Mesh：

Substances：

Year: 2014 PMID： 24507609 PMCID： PMC3945774 DOI： 10.1016/j.bpj.2013.12.035

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

40 in total

Review 1. Mechanical properties of viruses analyzed by atomic force microscopy: a virological perspective.

Authors: Mauricio G Mateu
Journal: Virus Res Date: 2012-06-15 Impact factor: 3.303

2. Measuring electrostatic, van der Waals, and hydration forces in electrolyte solutions with an atomic force microscope.

Authors: H J Butt
Journal: Biophys J Date: 1991-12 Impact factor: 4.033

Mechanical stability and reversible fracture of vault particles.

Review 1. Mechanical properties of viruses analyzed by atomic force microscopy: a virological perspective.

2. Measuring electrostatic, van der Waals, and hydration forces in electrolyte solutions with an atomic force microscope.

3. Mechanical elasticity as a physical signature of conformational dynamics in a virus particle.

4. Targeted vault nanoparticles engineered with an endosomolytic peptide deliver biomolecules to the cytoplasm.

5. Vaults and telomerase share a common subunit, TEP1.

6. Mechanical disassembly of single virus particles reveals kinetic intermediates predicted by theory.

7. Nanoindentation of virus capsids in a molecular model.

8. Elucidating the mechanism behind irreversible deformation of viral capsids.

9. The 193-kD vault protein, VPARP, is a novel poly(ADP-ribose) polymerase.

Review 10. Structural studies of large nucleoprotein particles, vaults.

1. Loading the dice: The orientation of virus-like particles adsorbed on titanate assisted organosilanized surfaces.

2. Mechanics of Virus-like Particles Labeled with Green Fluorescent Protein.

3. Direct visualization of single virus restoration after damage in real time.

4. Kinetics of Surface-Driven Self-Assembly and Fatigue-Induced Disassembly of a Virus-Based Nanocoating.

5. Calcium ions modulate the mechanics of tomato bushy stunt virus.

6. Monitoring SARS-CoV-2 Surrogate TGEV Individual Virions Structure Survival under Harsh Physicochemical Environments.

7. Cargo-shell and cargo-cargo couplings govern the mechanics of artificially loaded virus-derived cages.

8. Curating viscoelastic properties of icosahedral viruses, virus-based nanomaterials, and protein cages.

9. Decrease in pH destabilizes individual vault nanocages by weakening the inter-protein lateral interaction.

10. TensorCalculator: exploring the evolution of mechanical stress in the CCMV capsid.