Macromolecular synthesis in cells infected by frog virus 3

The molecular biology of frog virus 3 and other iridoviruses infecting cold-blooded vertebrates

Frog virus 3 (FV3) is the best characterized member of the family Iridoviridae. FV3 study has provided insights into the replication of other family members, and has served as a model of viral transcription, genome replication, and virus-mediated host-shutoff. Although the broad outlines of FV3 replication have been elucidated, the precise roles of most viral proteins remain unknown. Current studies using knock down (KD) mediated by antisense morpholino oligonucleotides (asMO) and small, interfering RNAs (siRNA), knock out (KO) following replacement of the targeted gene with a selectable marker by homologous recombination, ectopic viral gene expression, and recombinant viral proteins have enabled researchers to systematically ascertain replicative- and virulence-related gene functions. In addition, the application of molecular tools to ecological studies is providing novel ways for field biologists to identify potential pathogens, quantify infections, and trace the evolution of ecologically important viral species. In this review, we summarize current studies using not only FV3, but also other iridoviruses infecting ectotherms. As described below, general principles ascertained using FV3 served as a model for the family, and studies utilizing other ranaviruses and megalocytiviruses have confirmed and extended our understanding of iridovirus replication. Collectively, these and future efforts will elucidate molecular events in viral replication, intrinsic and extrinsic factors that contribute to disease outbreaks, and the role of the host immune system in protection from disease.

Innate immune evasion mediated by the Ambystoma tigrinum virus eukaryotic translation initiation factor 2alpha homologue

Ranaviruses (family Iridoviridae, genus Ranavirus) are large, double-stranded DNA (dsDNA) viruses whose replication is restricted to ectothermic vertebrates. Many highly pathogenic members of the genus Ranavirus encode a homologue of the eukaryotic translation initiation factor 2α (eIF2α). Data in a heterologous vaccinia virus system suggest that the Ambystoma tigrinum virus (ATV) eIF2α homologue (vIF2αH; open reading frame [ORF] 57R) is involved in evading the host innate immune response by degrading the interferon-inducible, dsRNA-activated protein kinase, PKR. To test this hypothesis directly, the ATV vIF2αH gene (ORF 57R) was deleted by homologous recombination, and a selectable marker was inserted in its place. The ATVΔ57R virus has a small plaque phenotype and is 8-fold more sensitive to interferon than wild-type ATV (wtATV). Infection of fish cells with the ATVΔ57R virus leads to eIF2α phosphorylation, in contrast to infection with wtATV, which actively inhibits eIF2α phosphorylation. The inability of ATVΔ57R to prevent phosphorylation of eIF2α correlates with degradation of fish PKZ, an interferon-inducible enzyme that is closely related to mammalian PKR. In addition, salamanders infected with ATVΔ57R displayed an increased time to death compared to that of wtATV-infected salamanders. Therefore, in a biologically relevant system, the ATV vIF2αH gene acts as an innate immune evasion factor, thereby enhancing virus pathogenesis.

Transcriptome analysis of Frog virus 3, the type species of the genus Ranavirus, family Iridoviridae

Frog virus 3 is the best characterized species within the genus Ranavirus, family Iridoviridae. FV3's large ( approximately 105 kbp) dsDNA genome encodes 98 putative open reading frames (ORFs) that are expressed in a coordinated fashion leading to the sequential appearance of immediate early (IE), delayed early (DE) and late (L) viral transcripts. As a step toward elucidating molecular events in FV3 replication, we sought to identify the temporal class of viral messages. To accomplish this objective an oligonucleotide microarray containing 70-mer probes corresponding to each of the 98 FV3 ORFs was designed and used to examine viral gene expression. Viral transcription was initially monitored during the course of a productive replication cycle at 2, 4 and 9 h after infection. To confirm results of the time course assay, viral gene expression was also monitored in the presence of cycloheximide (CHX), which limits expression to only IE genes, and following infection with a temperature-sensitive (ts) mutant which at non-permissive temperatures is defective in viral DNA synthesis and blocked in late gene expression. Subsequently, microarray analyses were validated by RT-PCR and qRT-PCR. Using these approaches we identified 33 IE genes, 22 DE genes and 36 L viral genes. The temporal class of the 7 remaining genes could not be determined. Comparison of protein function with temporal class indicated that, in general, genes encoding putative regulatory factors, or proteins that played a part in nucleic acid metabolism and immune evasion, were classified as IE and DE genes, whereas those involved in DNA packaging and virion assembly were considered L genes. Information on temporal class will provide the basis for determining whether members of the same temporal class contain common upstream regulatory regions and perhaps allow us to identify virion-associated and virus-induced proteins that control viral gene expression.

Viruses of lower vertebrates

Viruses of lower vertebrates recently became a field of interest to the public due to increasing epizootics and economic losses of poikilothermic animals. These were reported worldwide from both wildlife and collections of aquatic poikilothermic animals. Several RNA and DNA viruses infecting fish, amphibians and reptiles have been studied intensively during the last 20 years. Many of these viruses induce diseases resulting in important economic losses of lower vertebrates, especially in fish aquaculture. In addition, some of the DNA viruses seem to be emerging pathogens involved in the worldwide decline in wildlife. Irido-, herpes- and polyomavirus infections may be involved in the reduction in the numbers of endangered amphibian and reptile species. In this context the knowledge of several important RNA viruses such as orthomyxo-, paramyxo-, rhabdo-, retro-, corona-, calici-, toga-, picorna-, noda-, reo- and birnaviruses, and DNA viruses such as parvo-, irido-, herpes-, adeno-, polyoma- and poxviruses, is described in this review.

Metabolism of host and viral mRNAs in frog virus 3-infected cells

Treatment of purified frog virus 3 (FV3) with nonionic detergent and high salt released an endoribonucleolytic activity and confirmed earlier findings of a virion-associated endonuclease. This observation, coupled with evidence implicating host and viral message destabilization in herpesvirus and poxvirus biogenesis, raised the question of what role, if any, mRNA degradation plays in FV3 replication. To answer this question, Northern analyses of mock- and virus-infected cells were performed using probes for representative host and viral messages. These studies demonstrated that the steady state level of host messages progressively declined during the course of productive FV3 infection, whereas the steady state level of viral messages was not affected. To determine whether the decline in the steady state level of host mRNA was due to virus-induced degradation or to normal turnover coupled to virus-mediated transcriptional shut-off, actin mRNA levels were examined in mock- and virus-infected cells in the presence and absence of actinomycin D. Under these conditions, actin mRNA levels declined more quickly in actinomycin D-treated, virus-infected cells, than in mock-infected cells incubated in the presence of actinomycin D suggesting that the decline in the steady state level of actin mRNA was due to degradation. However, although it appears as if host message degradation is responsible for virus-mediated translational shut-off, the ability of heat-inactivated FV3 to block cellular translation without destabilizing cellular messages indicates that message degradation is not required for translational inhibition. As noted above, the degradation of early FV3 messages was not involved in controlling the transition from early to late gene expression. Furthermore, the presence of abundant, but nontranslated, early messages late in infection, coupled with the inefficient translation of late messages in vitro supported earlier suggestions that FV3 gene expression is controlled, at least in part, at the translational level. Taken together, these results suggest that FV3 regulates gene expression in a unique manner and may be a good model to examine the mechanics of translational control.

A frog virus 3 gene codes for a protein containing the motif characteristic of the INT family of integrases

The integrase (INT) family of bacteriophage coded integrase-recombinase proteins are responsible for catalyzing strand exchange between DNA molecules and play an important role in the DNA replication of many bacteriophages. Within the frog virus 3 (FV3) genome we have identified an open reading frame (ORF) of which the deduced amino acid sequence contains a motif characteristic of the INT family of integrases-recombinases. The ORF consists of 825 bp which codes for a protein of 275 amino acids with a predicted Mr of 29,945. RNA transcribed from this ORF during virus infection was detected by Northern blot analysis and it is a delayed early message of approximately 1100 bases. The 5' and 3' ends of the putative FV3 integrase-recombinase transcript were mapped. The transcriptional start site is preceded by a presumptive TATA box, and a region of hyphenated dyad symmetry is present at the 3' end of the message. A protein with an Mr of approximately 30,500 was synthesized by a rabbit reticulocyte lysate programmed with capped runoff transcripts from the cloned gene, indicating that the ORF can be transcribed into a message coding for a viral protein. In the FV3 life cycle, DNA replication occurs in a large complex formed through the recombination of small viral DNA molecules. Thus, at this stage, DNA replication and recombination are interlinked. Resolution of concatameric DNA is required for the packaging of genomes into virus particles. The putative FV3 INT gene may be involved in one or more of these functions.

Structure and regulation of the immediate-early frog virus 3 gene that encodes ICR489

To test whether the promoters of two immediate-early genes from frog virus 3 were similar in nucleotide sequence, we have cloned and sequenced an immediate-early gene encoding an infected-cell mRNA of 489 kilodaltons (ICR489) and have shown that the protein product of this gene is approximately 46 kilodaltons. The 5' and 3' ends of the transcripts from this gene, as determined by mung bean nuclease analysis, were microheterogeneous. The promoter region was subcloned upstream from a promoterless chloramphenicol acetyltransferase gene, forming the recombinant plasmid pBS489CAT. As with the previously sequenced frog virus 3 immediate-early gene encoding ICR169, expression of chloramphenicol acetyltransferase in transfected cells required activation by a virion-associated protein. Although the promoter region of the gene encoding ICR489 contained TATA, CAAT, and GC motifs similar to those of typical eucaryotic promoters, it showed no significant homology to the ICR169 promoter, indicating that the concomitant temporal expression of these two genes is not due to similar promoter sequences.

Infection with frog virus 3 allows transcription of DNA methylated at cytosine but not adenine residues

The genome of the iridovirus, frog virus 3, is highly methylated at cytosine residues by a virus-encoded DNA methyltransferase. We have shown previously that an FV3-induced trans-acting protein alters either host RNA polymerase II or methylated template to allow transcription from promoters inactivated by methylation. We now present evidence that the ability of FV3-infected cells to transcribe methylated DNA is specific for DNA methylated at cytosine residues. Eukaryotic promoters were inactivated by methylation of either adenine or cytosine residues, and tested for transcriptional activity. Only promoters inactivated by cytosine methylation were transcribed in FV3-infected cells. We also show that the dinucleotide sequence in which the methylcytosine is found appears to have no effect on the ability of FV3 to trans-activate the methylated promoters.

Heat-inactivated frog virus 3 selectively inhibits equine herpesvirus type 1 translation in a temporal class-dependent manner

Superinfection of equine herpesvirus type 1 (EHV-1)-infected rabbit kidney cells with heat-inactivated frog virus 3 (delta FV3) differentially blocked EHV-1 protein synthesis. The extent of inhibition varied with the specific EHV-1 message, but in general late protein synthesis was inhibited more than early and immediate early translation. Since FV3 has been shown to block heterologous RNA and protein synthesis, it was necessary to determine whether the observed reduction in herpesvirus protein synthesis was primarily due to a block in translation or to an earlier inhibition of EHV-1 mRNA synthesis. To distinguish between these alternatives, replicate cultures of EHV-1 infected cells were either superinfected with delta FV3 or treated with 10 micrograms/ml actinomycin D at 6 hr after infection, and EHV-1 protein synthesis monitored 3 hr later. We found that addition of actinomycin D to EHV-1 infected cultures had only a slight effect on EHV-1 translation, whereas superinfection with delta FV3 markedly reduced EHV-1 protein synthesis. This result suggested that the observed decline in EHV-1 protein synthesis was not due to the inhibition of herpesvirus mRNA synthesis. In addition, we showed that RNA extracted from delta FV3-superinfected cells directed the synthesis of full-size EHV-1 proteins in vitro indicating that shut-off was not caused by the degradation of EHV-1 mRNAs. Taken together these results show that delta FV3 selectively inhibited EHV-1 protein synthesis and are consistent with earlier observations which suggest that translational shut-off occurs at initiation.

Regulation of protein synthesis in virus-infected animal cells

This chapter summarizes the structural features that govern the translation of viral mRNAs: where the synthesis of a protein starts and ends, how many proteins can be produced from one mRNA, and how efficiently. It focuses on the interplay between viral and cellular mRNAs and the translational machinery. That interplay, together with the intrinsic structure of viral mRNAs, determines the patterns of translation in infected cells. It also points out some possibilities for translational regulation that can only be glimpsed at present, but are likely to come into focus in the future. The mechanism of selecting the initiation site for protein synthesis appears to follow a single formula. The translational machinery displays a certain flexibility that is exploited more frequently by viral than by cellular mRNAs. Although some of the parameters that determine efficiency have been identified, how efficiently a given mRNA will be translated cannot be predicted by summing the known parameters.

trans activation of an immediate-early frog virus 3 promoter by a virion protein

We investigated the protein and DNA sequence requirements for the expression of an immediate-early frog virus 3 (FV3) gene, infected-cell RNA (ICR) 169. We used a plasmid containing the 78 nucleotides 5' to the transcription start site of ICR-169 placed upstream from the coding sequence for the bacterial enzyme chloramphenicol acetyltransferase (CAT). This construction, when introduced by CaPO4-mediated transfection into various eucaryotic cell lines, promoted CAT synthesis only if the transfected cells were subsequently infected with FV3. Dot-blot hybridization of RNA extracted from transfected, FV3-infected cells with a radioactive CAT probe showed that the induction of CAT synthesis by FV3 was at the level of transcription. When transfected cells were infected with FV3 in the presence of cycloheximide, induction of CAT-specific RNA still occurred, demonstrating that a virion protein was responsible for the trans activation. FV3-induced CAT synthesis was inhibited by alpha-amanitin in wild-type Chinese hamster ovary (CHO) cells but not in CHO cells with an alpha-amanitin-resistant RNA polymerase II. The results suggest that a virion protein alters either the DNA template or the host polymerase to allow transcription from immediate-early FV3 promoters.