Effect of single-base substitutions in the central domain of virus-associated RNA I on its function.

Adenoviruses use virus-associated RNA I (VAI RNA) to counteract the cellular antiviral response mediated by the interferon-induced, double-stranded-RNA-activated protein kinase PKR. VAI RNA is a highly structured small RNA which consists of two long duplex regions connected at the center by a complex, short stem-loop. This short stem-loop and the adjacent base-paired regions, referred to as the central domain, bind to PKR and inactivate it. Currently it is not known whether binding of VAI RNA to PKR is dependent solely on the secondary (and tertiary) structure of the central domain or whether nucleotide sequences in the central domain are also critical for this interaction. To address this question, 54 VAI mutants with single-base substitution mutations in the central domain of the RNA were constructed, and their capacities to inhibit the autophosphoryation of PKR in vitro were determined. It was found that although about half of the mutants inhibited PKR activity as efficiently as the wild type, a significant number of mutants lost the inhibitory activity substantially, without a perceptible change in their secondary structures. These results indicate that, in addition to secondary structure, at least some nucleotides in the central domain may be critical for the efficient function of VAI RNA.     

Structural requirements of adenovirus VAI RNA for its translation enhancement function.

Recently, by genetic and biochemical approaches, it has been shown that adenovirus VAI RNA is required for efficient translation of viral mRNAs at late times after infection. To understand the nucleotide sequences and the domains of the VAI RNA that are responsible for the role of VAI RNA in enhancement of translation, a mutational analysis of the VAI gene was undertaken. Deletion, substitution, and insertion mutations covering most of the nucleotide sequences of VAI RNA were introduced into the VAI gene at the plasmid level. These mutant genes were then reintroduced into the virus, and growth properties of the mutant viruses were studied. The majority of the mutants retained normal or nearly normal levels of biological function. Mutations in the region between +43 and +53 and between +107 and the 3' end of the gene resulted in a considerable loss of activity. These mutants, however, grew significantly better than did an adenovirus type 5 mutant lacking both functional VAI and VAII genes, indicating that they retain a portion of their activity. Because no one mutation was able to completely abolish the function, we suggest that the VAI RNA may have multiple functional sites for its translation modulation function. These multiple sites may be short oligonucleotide sequences that may interact with cellular or viral components or both during translation.     

Translational stimulation by reovirus polypeptide sigma 3: substitution for VAI RNA and inhibition of phosphorylation of the alpha subunit of eukaryotic initiation factor 2.

COS cells transfected with plasmids that activate DAI depend on expression of virus-associated I (VAI) RNA to prevent the inhibitory effects of the alpha subunit of eukaryotic initiation factor 2 (eIF-2 alpha) kinase (DAI) and restore the translation of vector-derived dihydrofolate reductase mRNA. This VAI RNA requirement could be completely replaced by reovirus polypeptide sigma 3, consistent with its double-stranded RNA (dsRNA)-binding activity. S4 gene transfection of 293 cells also partially restored adenovirus protein synthesis after infection with the VAI-negative dl331 mutant. In dl331-infected 293 cells, eIF-2 alpha was present mainly in the acidic, phosphorylated form, and trans complementation with polypeptide sigma 3 or VAI RNA decreased the proportion of eIF-2 alpha (P) from approximately 85 to approximately 30%. Activation of DAI by addition of dsRNA to extracts of S4 DNA-transfected COS cells required 10-fold-higher levels of dsRNA than extracts made from cells that were not producing polypeptide sigma 3. In extracts of reovirus-infected mouse L cells, the concentration of dsRNA needed to activate DAI was dependent on the viral serotype used for the infection. Although the proportion of eIF-2 alpha (P) was greater than that in uninfected cells, most of the factor remained in the unphosphorylated form, even at 16 h after infection, consistent with the partial inhibition of host protein synthesis observed with all three viral serotypes. The results indicate that reovirus polypeptide sigma 3 participates in the regulation of protein synthesis by modulating DAI and eIF-2 alpha phosphorylation.     

In vitro analysis of virus-associated RNA I (VAI RNA): inhibition of the double-stranded RNA-activated protein kinase PKR by VAI RNA mutants correlates with the in vivo phenotype and the structural integrity of the central domain.

Adenoviruses use the virus-encoded virus-associated RNA (VAI RNA) as a defense against cellular antiviral response by blocking the activation of the interferon-induced, double-stranded RNA-activated protein kinase PKR. The structure of VAI RNA consists of two long, imperfectly base-paired duplex regions connected by a complex short stem-loop at the center, referred to as the central domain. By using a series of adenovirus mutants with linker-scan mutations in the VAI RNA gene, we recently showed that the critical elements required for function in the VAI RNA molecule are in the central domain and that these same elements of the central domain are also involved in binding to PKR. In virus-infected cells, VAI RNA interacts with latent kinase, which is bound to ribosomes; this interaction takes place in a complex milieu. To more fully understand the relationship between structure and function and to determine whether the in vivo phenotype of these mutants can be reproduced in vitro, we have now analyzed these mutant VAI alleles for their ability to block the activation of a partially purified PKR from HeLa cells. We have also derived the structure of these mutants experimentally and correlated the structure with function. Without exception, when the structure of the short stem-loop of the central domain was perturbed, the mutants failed to inhibit PKR. Structural disruptions elsewhere in the central domain or in the long duplex regions of the molecule were not deleterious for in vitro function. Thus, these results support our previous findings and underscore the importance of the elements present in the central domain of the VAI RNA for its function. Our results also suggest that the interaction between PKR and VAI RNA involves a precise secondary (and tertiary) structure in the central domain. It has been suggested that VAI RNA does not activate PKR in virus-infected cells because of mismatches in the imperfectly base-paired long duplex regions. We constructed mutant VAI genes in which the imperfectly base-paired duplex regions were converted to perfectly base-paired regions and assayed in vitro for the activation of PKR. As with the wild-type VAI RNA, these mutants failed to activate PKR in vitro, while they were able to block the activation of PKR better than did the wild type. These results suggest that the failure of VAI RNA to activate PKR is not the result of mismatches in the long duplex regions.(ABSTRACT TRUNCATED AT 400 WORDS)