A Herpes Simplex Virus Scaffold Peptide That Binds the Portal Vertex Inhibits Early Steps in Viral Replication
Autor: | Elizabeth G. Wills, Joel D. Baines, Kui Yang |
---|---|
Rok vydání: | 2013 |
Předmět: |
DNA Replication
Scaffold protein viruses Molecular Sequence Data Immunology Peptide Peptide binding Herpesvirus 1 Human Biology Virus Replication medicine.disease_cause Antiviral Agents Microbiology Cell Line Capsid Virology Vaccines and Antiviral Agents medicine Animals Humans Amino Acid Sequence Peptide sequence chemistry.chemical_classification DNA replication Molecular biology Microscopy Electron Herpes simplex virus Microscopy Fluorescence chemistry Viral replication Cell culture Insect Science Mutation Insect Proteins Capsid Proteins Drosophila Peptides |
Zdroj: | Journal of Virology. 87:6876-6887 |
ISSN: | 1098-5514 0022-538X |
DOI: | 10.1128/jvi.00421-13 |
Popis: | Previous experiments identified a 12-amino-acid (aa) peptide that was sufficient to interact with the herpes simplex virus 1 (HSV-1) portal protein and was necessary to incorporate the portal into capsids. In the present study, cells were treated at various times postinfection with peptides consisting of a portion of the Drosophila antennapedia protein, previously shown to enter cells efficiently, fused to either wild-type HSV-1 scaffold peptide (YPYYPGEARGAP) or a control peptide that contained changes at positions 4 and 5. These 4-tyrosine and 5-proline residues are highly conserved in herpesvirus scaffold proteins and were previously shown to be critical for the portal interaction. Treatment early in infection with subtoxic levels of wild-type peptide reduced viral infectivity by over 1,000-fold, while the mutant peptide had little effect on viral yields. In cells infected for 3 h in the presence of wild-type peptide, capsids were observed to transit to the nuclear rim normally, as viewed by fluorescence microscopy. However, observation by electron microscopy in thin sections revealed an aberrant and significant increase of DNA-containing capsids compared to infected cells treated with the mutant peptide. Early treatment with peptide also prevented formation of viral DNA replication compartments. These data suggest that the antiviral peptide stabilizes capsids early in infection, causing retention of DNA within them, and that this activity correlates with peptide binding to the portal protein. The data are consistent with the hypothesis that the portal vertex is the conduit through which DNA is ejected to initiate infection. |
Databáze: | OpenAIRE |
Externí odkaz: |