Unknown

Dataset Information

0

Hepatitis B Virus Capsid Completion Occurs through Error Correction.

ABSTRACT: Understanding capsid assembly is important because of its role in virus lifecycles and in applications to drug discovery and nanomaterial development. Many virus capsids are icosahedral, and assembly is thought to occur by the sequential addition of capsid protein subunits to a nucleus, with the final step completing the icosahedron. Almost nothing is known about the final (completion) step because the techniques usually used to study capsid assembly lack the resolution. In this work, charge detection mass spectrometry (CDMS) has been used to track the assembly of the T = 4 hepatitis B virus (HBV) capsid in real time. The initial assembly reaction occurs rapidly, on the time scale expected from low resolution measurements. However, CDMS shows that many of the particles generated in this process are defective and overgrown, containing more than the 120 capsid protein dimers needed to form a perfect T = 4 icosahedron. The defective and overgrown capsids self-correct over time to the mass expected for a perfect T = 4 capsid. Thus, completion is a distinct phase in the assembly reaction. Capsid completion does not necessarily occur by inserting the last building block into an incomplete, but otherwise perfect icosahedron. The initial assembly reaction can be predominently imperfect, and completion involves the slow correction of the accumulated errors.

SUBMITTER: Lutomski CA 

PROVIDER: S-EPMC6336459 | biostudies-literature | 2017 Nov

REPOSITORIES: biostudies-literature

Json Xml
altmetric image

Publications

Hepatitis B Virus Capsid Completion Occurs through Error Correction.

Lutomski Corinne A CA   Lyktey Nicholas A NA   Zhao Zhongchao Z   Pierson Elizabeth E EE   Zlotnick Adam A   Jarrold Martin F MF  

Journal of the American Chemical Society 20171110 46

Understanding capsid assembly is important because of its role in virus lifecycles and in applications to drug discovery and nanomaterial development. Many virus capsids are icosahedral, and assembly is thought to occur by the sequential addition of capsid protein subunits to a nucleus, with the final step completing the icosahedron. Almost nothing is known about the final (completion) step because the techniques usually used to study capsid assembly lack the resolution. In this work, charge det  ...[more]

Similar Datasets

Transcriptomics Expression data from the hepatitis E virus capsid protein
2012-12-01 | E-GEOD-29061 | biostudies-arrayexpress
Transcriptomics Expression data from the hepatitis E virus capsid protein
2012-12-01 | GSE29061 | GEO
Unknown Comparison of error correction algorithms for Ion Torrent PGM data: application to hepatitis B virus.
| S-EPMC5556038 | biostudies-literature
Unknown Dynamics of Hepatitis B Virus Capsid Protein Dimer Regulate Assembly through an Allosteric Network.
| S-EPMC8011827 | biostudies-literature
Unknown Polyvalent display of heme on hepatitis B virus capsid protein through coordination to hexahistidine tags.
| S-EPMC2715361 | biostudies-literature
Unknown Functional surfaces of the hepatitis B virus capsid.
| S-EPMC2772698 | biostudies-literature
Unknown Improving transcriptome assembly through error correction of high-throughput sequence reads.
| S-EPMC3728768 | biostudies-literature
Unknown Nucleolar localization of human hepatitis B virus capsid protein.
| S-EPMC533942 | biostudies-literature
Unknown A kinase chaperones hepatitis B virus capsid assembly and captures capsid dynamics in vitro.
| S-EPMC3219723 | biostudies-literature
Unknown Genome variability and capsid structural constraints of hepatitis a virus.
| S-EPMC140588 | biostudies-literature