Activation of Cellular Arf GTPases by Poliovirus Protein 3CD Correlates with Virus Replication

ABSTRACT We have previously shown that synthesis of poliovirus protein 3CD in uninfected HeLa cell extracts induces an increased association with membranes of the cellular Arf GTPases, which are key players in cellular membrane traffic. Arfs cycle between an inactive, cytoplasmic, GDP-bound form and an active, membrane-associated, GTP-bound form. 3CD promotes binding of Arf to membranes by initiating recruitment to membranes of guanine nucleotide exchange factors (GEFs), BIG1 and BIG2. GEFs activate Arf by replacing GDP with GTP. In poliovirus-infected cells, there is a dramatic redistribution of cellular Arf pools that coincides with the reorganization of membranes used to form viral RNA replication complexes. Here we demonstrate that Arf translocation in vitro can be induced by purified recombinant 3CD protein; thus, concurrent translation of viral RNA is not required. Coexpression of 3C and 3D proteins was not sufficient to target Arf to membranes. 3CD expressed in HeLa cells was retained after treatment of the cells with digitonin, indicating that it may interact with a membrane-bound host factor. A F441S mutant of 3CD was shown previously to have lost Arf translocation activity and was also defective in attracting the corresponding GEFs to membranes. A series of other mutations were introduced at 3CD residue F441. Mutations that retained Arf translocation activity of 3CD also supported efficient growth of virus, regardless of their effects on 3D polymerase elongation activity. Those that abrogated Arf activation by 3CD generated quasi-infectious RNAs that produced some plaques from which revertants that always restored the Arf activation property of 3CD were rescued.

Poliovirus Protein 3AB Displays Nucleic Acid Chaperone and Helix-Destabilizing Activities

ABSTRACT Poliovirus protein 3AB displayed nucleic acid chaperone activity in promoting the hybridization of complementary nucleic acids and destabilizing secondary structure. Hybridization reactions at 30°C between 20- and 40-nucleotide RNA oligonucleotides and 179- or 765-nucleotide RNAs that contained a complementary region were greatly enhanced in the presence of 3AB. The effect was nonspecific as reactions between DNA oligonucleotides and RNA or DNA templates were also enhanced. Reactions were optimal with 1 mM MgCl2 and 20 mM KCl. Analysis of the reactions with various 3AB and template concentrations indicated that enhancement required a critical amount of 3AB that increased as the concentration of nucleic acid increased. This was consistent with a requirement for 3AB to “coat” the nucleic acids for enhancement. The helix-destabilizing activity of 3AB was tested in an assay with two 42-nucleotide completely complementary DNAs. Each complement formed a strong stem-loop (ΔG = −7.2 kcal/mol) that required unwinding for hybridization to occur. DNAs were modified at the 3′ or 5′ end with fluorescent probes such that hybridization resulted in quenching of the fluorescent signal. Under optimal conditions at 30°C, 3AB stimulated hybridization in a concentration-dependent manner, as did human immunodeficiency virus nucleocapsid protein, an established chaperone. The results are discussed with respect to the role of 3AB in viral replication and recombination.

Echovirus-9 protein 2C binds single-stranded RNA unspecifically

Polypeptide 2C is essential for picornavirus replication. Although many data on multiple functions of this highly conserved protein are available, the mechanism of RNA binding is still obscure. In this work, protein 2C of echovirus-9 strain Barty was expressed as a histidine-tagged protein in E. coli followed by nondenaturing purification to homogeneity. After incubation of 2C protein with different kinds of RNA fragments, binding was shown in gel retardation assays. Competition experiments revealed that 2C targets linear RNA unspecifically; however, single-stranded linear DNA does not react with this protein. In contrast to poliovirus, protein 2C of echovirus-9 only recognizes RNA with a low content of secondary structures. This may be a first hint of a different binding specificity of 2C in echo- and polioviruses.