Computational modeling suggests dimerization of equine infectious anemia virus Rev is required for RNA binding
Autor: | Jerald Rudy Chavez, Drena Dobbs, Chijioke N. Umunnakwe, Hyelee Loyd, Kinsey Cornick, Susan Carpenter |
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Jazyk: | angličtina |
Předmět: |
Models
Molecular Protein Conformation viruses Plasma protein binding Biology Coiled-coil motif EIAV Protein structure Virology Nuclear export signal Peptide sequence Genetics Research Lentivirus Arginine-rich motif RNA Bipartite RNA binding domain Protein tertiary structure Cell biology Gene Products rev Infectious Diseases RNA Viral Protein Multimerization Dimerization Alpha helix Rev Binding domain Infectious Anemia Virus Equine Protein Binding |
Zdroj: | Retrovirology |
ISSN: | 1742-4690 |
DOI: | 10.1186/s12977-014-0115-7 |
Popis: | Background The lentiviral Rev protein mediates nuclear export of intron-containing viral RNAs that encode structural proteins or serve as the viral genome. Following translation, HIV-1 Rev localizes to the nucleus and binds its cognate sequence, termed the Rev-responsive element (RRE), in incompletely spliced viral RNA. Rev subsequently multimerizes along the viral RNA and associates with the cellular Crm1 export machinery to translocate the RNA-protein complex to the cytoplasm. Equine infectious anemia virus (EIAV) Rev is functionally homologous to HIV-1 Rev, but shares very little sequence similarity and differs in domain organization. EIAV Rev also contains a bipartite RNA binding domain comprising two short arginine-rich motifs (designated ARM-1 and ARM-2) spaced 79 residues apart in the amino acid sequence. To gain insight into the topology of the bipartite RNA binding domain, a computational approach was used to model the tertiary structure of EIAV Rev. Results The tertiary structure of EIAV Rev was modeled using several protein structure prediction and model quality assessment servers. Two types of structures were predicted: an elongated structure with an extended central alpha helix, and a globular structure with a central bundle of helices. Assessment of models on the basis of biophysical properties indicated they were of average quality. In almost all models, ARM-1 and ARM-2 were spatially separated by >15 Å, suggesting that they do not form a single RNA binding interface on the monomer. A highly conserved canonical coiled-coil motif was identified in the central region of EIAV Rev, suggesting that an RNA binding interface could be formed through dimerization of Rev and juxtaposition of ARM-1 and ARM-2. In support of this, purified Rev protein migrated as a dimer in Blue native gels, and mutation of a residue predicted to form a key coiled-coil contact disrupted dimerization and abrogated RNA binding. In contrast, mutation of residues outside the predicted coiled-coil interface had no effect on dimerization or RNA binding. Conclusions Our results suggest that EIAV Rev binding to the RRE requires dimerization via a coiled-coil motif to juxtapose two RNA binding motifs, ARM-1 and ARM-2. Electronic supplementary material The online version of this article (doi:10.1186/s12977-014-0115-7) contains supplementary material, which is available to authorized users. |
Databáze: | OpenAIRE |
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