Vaccinia virus directs the synthesis of early mRNAs containing 5' poly(A) sequences

Emerging translation strategies during virus-host interaction

Translation control is crucial during virus-host interaction. On one hand, viruses completely rely on the protein synthesis machinery of host cells to propagate and have evolved various mechanisms to redirect the host's ribosomes toward their viral mRNAs. On the other hand, the host rewires its translation program in an attempt to contain and suppress the virus early on during infection; the antiviral program includes specific control on protein synthesis to translate several antiviral mRNAs involved in quenching the infection. As the infection progresses, host translation is in turn inhibited in order to limit viral propagation. We have learnt of very diverse strategies that both parties utilize to gain or retain control over the protein synthesis machinery. Yet novel strategies continue to be discovered, attesting for the importance of mRNA translation in virus-host interaction. This review focuses on recently described translation strategies employed by both hosts and viruses. These discoveries provide additional pieces in the understanding of the complex virus-host translation landscape. This article is categorized under: Translation > Translation Mechanisms Translation > Translation Regulation.

Transcription apparatus of the yeast virus-like elements: Architecture, function, and evolutionary origin

Extrachromosomal hereditary elements such as organelles, viruses, and plasmids are important for the cell fitness and survival. Their transcription is dependent on host cellular RNA polymerase (RNAP) or intrinsic RNAP encoded by these elements. The yeast Kluyveromyces lactis contains linear cytoplasmic DNA virus-like elements (VLEs, also known as linear plasmids) that bear genes encoding putative non-canonical two-subunit RNAP. Here, we describe the architecture and identify the evolutionary origin of this transcription machinery. We show that the two RNAP subunits interact in vivo, and this complex interacts with another two VLE-encoded proteins, namely the mRNA capping enzyme and a putative helicase. RNAP, mRNA capping enzyme and the helicase also interact with VLE-specific DNA in vivo. Further, we identify a promoter sequence element that causes 5' mRNA polyadenylation of VLE-specific transcripts via RNAP slippage at the transcription initiation site, and structural elements that precede the termination sites. As a result, we present a first model of the yeast virus-like element transcription initiation and intrinsic termination. Finally, we demonstrate that VLE RNAP and its promoters display high similarity to poxviral RNAP and promoters of early poxviral genes, respectively, thereby pointing to their evolutionary origin.

Bioinformatics and Translation Elongation

Codon usage depends on mutation bias, tRNA-mediated selection, and the need for high efficiency and accuracy in translation. One codon in a synonymous codon family is often strongly over-used, especially in highly expressed genes, which often leads to a high dN/dS ratio because dS is very small. Many different codon usage indices have been proposed to measure codon usage and codon adaptation. Sense codon could be misread by release factors and stop codons misread by tRNAs, which also contribute to codon usage in rare cases. This chapter outlines the conceptual framework on codon evolution, illustrates codon-specific and gene-specific codon usage indices, and presents their applications. A new index for codon adaptation that accounts for background mutation bias (Index of Translation Elongation) is presented and contrasted with codon adaptation index (CAI) which does not consider background mutation bias. They are used to re-analyze data from a recent paper claiming that translation elongation efficiency matters little in protein production. The reanalysis disproves the claim.

Opposing Roles of Double-Stranded RNA Effector Pathways and Viral Defense Proteins Revealed with CRISPR-Cas9 Knockout Cell Lines and Vaccinia Virus Mutants

Vaccinia virus (VACV) decapping enzymes and cellular exoribonuclease Xrn1 catalyze successive steps in mRNA degradation and prevent double-stranded RNA (dsRNA) accumulation, whereas the viral E3 protein can bind dsRNA. We showed that dsRNA and E3 colocalized within cytoplasmic viral factories in cells infected with a decapping enzyme mutant as well as with wild-type VACV and that they coprecipitated with antibody. An E3 deletion mutant induced protein kinase R (PKR) and eukaryotic translation initiation factor alpha (eIF2α) phosphorylation earlier and more strongly than a decapping enzyme mutant even though less dsRNA was made, leading to more profound effects on viral gene expression. Human HAP1 and A549 cells were genetically modified by clustered regularly interspaced short palindromic repeat-Cas9 (CRISPR-Cas9) to determine whether the same pathways restrict E3 and decapping mutants. The E3 mutant replicated in PKR knockout (KO) HAP1 cells in which RNase L is intrinsically inactive but only with a double knockout (DKO) of PKR and RNase L in A549 cells, indicating that both pathways decreased replication equivalently and that no additional dsRNA pathway was crucial. In contrast, replication of the decapping enzyme mutant increased significantly (though less than that of wild-type virus) in DKO A549 cells but not in DKO HAP1 cells where a smaller increase in viral protein synthesis occurred. Xrn1 KO A549 cells were viable but nonpermissive for VACV; however, wild-type and mutant viruses replicated in triple-KO cells in which RNase L and PKR were also inactivated. Since KO of PKR and RNase L was sufficient to enable VACV replication in the absence of E3 or Xrn1, the poor replication of the decapping mutant, particularly in HAP1 DKO, cells indicated additional translational defects.

IMPORTANCE

Viruses have evolved ways of preventing or counteracting the cascade of antiviral responses that double-stranded RNA (dsRNA) triggers in host cells. We showed that the dsRNA produced in excess in cells infected with a vaccinia virus (VACV) decapping enzyme mutant and by wild-type virus colocalized with the viral E3 protein in cytoplasmic viral factories. Novel human cell lines defective in either or both protein kinase R and RNase L dsRNA effector pathways and/or the cellular 5' exonuclease Xrn1 were prepared by CRISPR-Cas9 gene editing. Inactivation of both pathways was necessary and sufficient to allow full replication of the E3 mutant and reverse the defect cause by inactivation of Xrn1, whereas the decapping enzyme mutant still exhibited defects in gene expression. The study provided new insights into functions of the VACV proteins, and the well-characterized panel of CRISPR-Cas9-modified human cell lines should have broad applicability for studying innate dsRNA pathways.

Salmon Gill Poxvirus, the Deepest Representative of the Chordopoxvirinae

Poxviruses are large DNA viruses of vertebrates and insects causing disease in many animal species, including reptiles, birds, and mammals. Although poxvirus-like particles were detected in diseased farmed koi carp, ayu, and Atlantic salmon, their genetic relationships to poxviruses were not established. Here, we provide the first genome sequence of a fish poxvirus, which was isolated from farmed Atlantic salmon. In the present study, we used quantitative PCR and immunohistochemistry to determine aspects of salmon gill poxvirus disease, which are described here. The gill was the main target organ where immature and mature poxvirus particles were detected. The particles were detected in detaching, apoptotic respiratory epithelial cells preceding clinical disease in the form of lethargy, respiratory distress, and mortality. In moribund salmon, blocking of gas exchange would likely be caused by the adherence of respiratory lamellae and epithelial proliferation obstructing respiratory surfaces. The virus was not found in healthy salmon or in control fish with gill disease without apoptotic cells, although transmission remains to be demonstrated. PCR of archival tissue confirmed virus infection in 14 cases with gill apoptosis in Norway starting from 1995. Phylogenomic analyses showed that the fish poxvirus is the deepest available branch of chordopoxviruses. The virus genome encompasses most key chordopoxvirus genes that are required for genome replication and expression, although the gene order is substantially different from that in other chordopoxviruses. Nevertheless, many highly conserved chordopoxvirus genes involved in viral membrane biogenesis or virus-host interactions are missing. Instead, the salmon poxvirus carries numerous genes encoding unknown proteins, many of which have low sequence complexity and contain simple repeats suggestive of intrinsic disorder or distinct protein structures.

IMPORTANCE Aquaculture is an increasingly important global source of high-quality food. To sustain the growth in aquaculture, disease control in fish farming is essential. Moreover, the spread of disease from farmed fish to wildlife is a concern. Serious poxviral diseases are emerging in aquaculture, but very little is known about the viruses and the diseases that they cause. There is a possibility that viruses with enhanced virulence may spread to new species, as has occurred with the myxoma poxvirus in rabbits. Provision of the first fish poxvirus genome sequence and specific diagnostics for the salmon gill poxvirus in Atlantic salmon may help curb this disease and provide comparative knowledge. Furthermore, because salmon gill poxvirus represents the deepest branch of chordopoxvirus so far discovered, the genome analysis provided substantial insight into the evolution of different functional modules in this important group of viruses.

Pervasive initiation and 3'-end formation of poxvirus postreplicative RNAs

Poxviruses are large DNA viruses that replicate within the cytoplasm and encode a complete transcription system, including a multisubunit RNA polymerase, stage-specific transcription factors, capping and methylating enzymes, and a poly(A) polymerase. Expression of the more than 200 open reading frames by vaccinia virus, the prototype poxvirus, is temporally regulated: early mRNAs are synthesized immediately after infection, whereas intermediate and late mRNAs are synthesized following genome replication. The postreplicative transcripts are heterogeneous in length and overlap the entire genome, which pose obstacles for high resolution mapping. We used tag-based methods in conjunction with high throughput cDNA sequencing to determine the precise 5'-capped and 3'-polyadenylated ends of postreplicative RNAs. Polymerase slippage during initiation of intermediate and late RNA synthesis results in a 5'-poly(A) leader that allowed the unambiguous identification of true transcription start sites. Ninety RNA start sites were located just upstream of intermediate and late open reading frames, but many more appeared anomalous, occurring within coding and non-coding regions, indicating pervasive transcription initiation. We confirmed the presence of functional promoter sequences upstream of representative anomalous start sites and demonstrated that alternative start sites within open reading frames could generate truncated isoforms of proteins. In an analogous manner, poly(A) sequences allowed accurate mapping of the numerous 3'-ends of postreplicative RNAs, which were preceded by a pyrimidine-rich sequence in the DNA coding strand. The distribution of postreplicative promoter sequences throughout the genome provides enormous transcriptional complexity, and the large number of previously unmapped RNAs may have novel functions.

Translation initiation: a regulatory role for poly(A) tracts in front of the AUG codon in Saccharomyces cerevisiae

The 5'-UTR serves as the loading dock for ribosomes during translation initiation and is the key site for translation regulation. Many genes in the yeast Saccharomyces cerevisiae contain poly(A) tracts in their 5'-UTRs. We studied these pre-AUG poly(A) tracts in a set of 3274 recently identified 5'-UTRs in the yeast to characterize their effect on in vivo protein abundance, ribosomal density, and protein synthesis rate in the yeast. The protein abundance and the protein synthesis rate increase with the length of the poly(A), but exhibit a dramatic decrease when the poly(A) length is ≥12. The ribosomal density also reaches the lowest level when the poly(A) length is ≥12. This supports the hypothesis that a pre-AUG poly(A) tract can bind to translation initiation factors to enhance translation initiation, but a long (≥12) pre-AUG poly(A) tract will bind to Pab1p, whose binding size is 12 consecutive A residues in yeast, resulting in repression of translation. The hypothesis explains why a long pre-AUG poly(A) leads to more efficient translation initiation than a short one when PABP is absent, and why pre-AUG poly(A) is short in the early genes but long in the late genes of vaccinia virus.

Genome-wide analysis of the 5' and 3' ends of vaccinia virus early mRNAs delineates regulatory sequences of annotated and anomalous transcripts

Poxviruses are large DNA viruses that encode a multisubunit RNA polymerase, stage-specific transcription factors, and enzymes that cap and polyadenylate mRNAs within the cytoplasm of infected animal cells. Genome-wide microarray and RNA-seq technologies have been used to profile the transcriptome of vaccinia virus (VACV), the prototype member of the family. Here, we adapted tag-based methods in conjunction with SOLiD and Illumina deep sequencing platforms to determine the precise 5' and 3' ends of VACV early mRNAs and map the putative transcription start sites (TSSs) and polyadenylation sites (PASs). Individual and clustered TSSs were found preceding 104 annotated open reading frames (ORFs), excluding pseudogenes. In the majority of cases, a 15-nucleotide consensus core motif was present upstream of the ORF. This motif, however, was also present at numerous other locations, indicating that it was insufficient for transcription initiation. Further analysis revealed a 10-nucleotide AT-rich spacer following functional core motifs that may facilitate DNA unwinding. Additional putative TSSs occurred in anomalous locations that may expand the functional repertoire of the VACV genome. However, many of the anomalous TSSs lacked an upstream core motif, raising the possibility that they arose by a processing mechanism as has been proposed for eukaryotic systems. Discrete and clustered PASs occurred about 40 nucleotides after an UUUUUNU termination signal. However, a large number of PASs were not preceded by this motif, suggesting alternative polyadenylation mechanisms. Pyrimidine-rich coding strand sequences were found immediately upstream of both types of PASs, signifying an additional feature of VACV 3'-end formation and polyadenylation.

Poly(A) leader of eukaryotic mRNA bypasses the dependence of translation on initiation factors

Eukaryotic mRNAs in which a poly(A) sequence precedes the initiation codon are known to exhibit a significantly enhanced cap-independent translation, both in vivo and in cell-free translation systems. Consistent with high expression levels of poxviral mRNAs, they contain poly(A) sequences at their 5' ends, immediately before the initiation AUG codon. Here we show that poly(A) as a leader sequence in mRNA constructs promotes the recruitment of the 40S ribosomal subunits and the efficient formation of initiation complexes at cognate AUG initiation codons in the absence of two essential translation initiation factors, eIF3 and eIF4F. These factors are known to be indispensable for the cap-dependent (and ATP-dependent) mechanism of translation initiation but are shown here to be not required if an mRNA contains a 5'-proximal poly(A). Thus, the presence of a pre-AUG poly(A) sequence results in an alternative mechanism of translation initiation. It involves the binding of initiating 40S ribosomal subunits within the 5' UTR and their phaseless, ATP-independent, diffusional movement ("phaseless wandering") along the leader sequence, with subsequent recognition of the initiation (AUG) codon.

Eukaryotic translation initiation factor 4F architectural alterations accompany translation initiation factor redistribution in poxvirus-infected cells

Despite their self-sufficient ability to generate capped mRNAs from cytosolic DNA genomes, poxviruses must commandeer the critical eukaryotic translation initiation factor 4F (eIF4F) to recruit ribosomes. While eIF4F integrates signals to control translation, precisely how poxviruses manipulate the multisubunit eIF4F, composed of the cap-binding eIF4E and the RNA helicase eIF4A assembled onto an eIF4G platform, remains obscure. Here, we establish that the poxvirus infection of normal, primary human cells destroys the translational repressor eIF4E binding protein (4E-BP) and promotes eIF4E assembly into an active eIF4F complex bound to the cellular polyadenylate-binding protein (PABP). Stimulation of the eIF4G-associated kinase Mnk1 promotes eIF4E phosphorylation and enhances viral replication and protein synthesis. Remarkably, these eIF4F architectural alterations are accompanied by the concentration of eIF4E and eIF4G within cytosolic viral replication compartments surrounded by PABP. This demonstrates that poxvirus infection redistributes, assembles, and modifies core and associated components of eIF4F and concentrates them within discrete subcellular compartments. Furthermore, it suggests that the subcellular distribution of eIF4F components may potentiate the complex assembly.

Lsm proteins bind and stabilize RNAs containing 5' poly(A) tracts

Many orthopoxvirus messenger RNAs have an unusual nontemplated poly(A) tract of 5 to 40 residues at the 5' end. The precise function of this feature is unknown. Here we show that 5' poly(A) tracts are able to repress RNA decay by inhibiting 3'-to-5' exonucleases as well as decapping of RNA substrates. UV cross-linking analysis demonstrated that the Lsm complex associates with the 5' poly(A) tract. Furthermore, recombinant Lsm1-7 complex specifically binds 5' poly(A) tracts 10 to 21 nucleotides in length, consistent with the length of 5' poly(A) required for stabilization. Knockdown of Lsm1 abrogates RNA stabilization by the 5' poly(A) tract. We propose that the Lsm complex simultaneously binds the 3' and 5' ends of these unusual messenger RNAs and thereby prevents 3'-to-5' decay. The implications of this phenomenon for cellular mRNA decay are discussed.

Robust analysis of 5'-transcript ends (5'-RATE): a novel technique for transcriptome analysis and genome annotation

Complicated cloning procedures and the high cost of sequencing have inhibited the wide application of serial analysis of gene expression and massively parallel signature sequencing for genome-wide transcriptome profiling of complex genomes. Here we describe a new method called robust analysis of 5'-transcript ends (5'-RATE) for rapid and cost-effective isolation of long 5' transcript ends (approximately 80 bp). It consists of three major steps including 5'-oligocapping of mRNA, NlaIII tag and ditag generation, and pyrosequencing of NlaIII tags. Complicated steps, such as purification and cloning of concatemers, colony picking and plasmid DNA purification, are eliminated and the conventional Sanger sequencing method is replaced with the newly developed pyrosequencing method. Sequence analysis of a maize 5'-RATE library revealed complex alternative transcription start sites and a 5' poly(A) tail in maize transcripts. Our results demonstrate that 5'-RATE is a simple, fast and cost-effective method for transcriptome analysis and genome annotation of complex genomes.

Genetic manipulation of two fowlpox virus late transcriptional regulatory elements influences their ability to direct expression of foreign genes

Fowlpox virus (FWPV) is currently used as a vector to express foreign genes of various poultry and mammalian pathogens. However, due to limited information available about the primary structure of FWPV promoters required for an optimal transcriptional efficiency, the full potential of FWPV as an expression vector has not been completely realized. To dissect such transcriptional regulatory elements at the molecular level, we selected two FWPV promoters dictating contrasting levels of expression of acidic-type inclusion body protein gene (P190) and A15L vaccinia virus homolog of FWPV (P180) for site-directed mutagenesis studies. The transcriptional activity of mutated promoters was analyzed based on their ability to transcribe a reporter gene, lacZ, and translation of the resultant mRNA into functional protein. Replacement of the spacer sequences of P180 with those of P190 resulted in a five-fold increase in mRNA and a 17.6-fold increase in protein over those with its parental promoter, P180. Similarly, replacement of a thymidine after the start codon with guanosine resulted in a 2.3-fold increase in lacZ mRNA and a seven-fold increase in protein. Combining these substitutions in P180SG produced a maximum increase in mRNA and protein of 6.7- and 29.9-fold, respectively, over concentrations with its parental P180 promoter. The promoter activity of P180SG was comparable to that of the strongest natural promoter, P190. The amount of protein per transcript generated by the mutated promoters of P180 increased to at least three times that with the parental P180. In contrast, similar replacements in P190 resulted in a 40-50% reduction in mRNA and protein in all the mutated promoters. We discuss the significance of spacer sequence and the purine after the start codon in the context of a high level of expression.

A consideration of previously uncharacterized fowl poxvirus unidirectional and bidirectional late promoters for inclusion in homologous recombinant vaccines

Because of the limited analysis of fowl poxvirus (FPV) promoters, expression of foreign proteins by recombinant FPV has usually been directed by heterologous vaccinia virus or synthetic poxvirus promoters. Thus, the impact of completely homologous recombinant virus vaccines has yet to be realized by the poultry industry. In an effort to increase the availability of such transcriptional regulatory elements, the modulation of gene expression by six previously uncharacterized FPV late promoters was examined. To simplify this comparison, each promoter region was separately coupled to the same reporter gene (lacZ) in individual plasmid constructs, and their activities in transfected, virus-infected cells were monitored. In each of the four selected unidirectional transcriptional regulatory elements as well as a 30-base pair representative of the bidirectional promoter region, the predicted temporal specificity of expressing at late stages of virus replicative cycle was verified. Stable lacZ gene transcripts arising from each plasmid varied less than threefold in quantity, whereas the amounts of beta-galactosidase product ranged within a 130-fold interval. Only the promoter that naturally regulates expression of the A type inclusion body protein gene directed production of beta-galactosidase at a level comparable with that associated with the strong vaccinia virus P11 promoter. Because one of the remaining unidirectional transcriptional regulatory elements, P174, was only 2.4-fold less efficient, both of these promoters, P174 and P190, should be satisfactory for directing the expression of poultry pathogen genes inserted into the genomes of FPV recombinant vaccines.

Regulation of viral transcription elongation and termination during vaccinia virus infection

Vaccinia virus provides a useful genetic and biochemical tool for studies of the basic mechanisms of eukaryotic transcription. Vaccinia genes are transcribed in three successive gene classes during infection, early, intermediate, and late. Vaccinia transcription is regulated primarily by virus gene products not only during initiation, but also during elongation and termination. The factors and mechanisms regulating early elongation and termination differ from those regulating intermediate and late gene expression. Control of transcription elongation and termination in vaccinia virus bears some similarity to the same process in other prokaryotic and eukaryotic systems, yet features some novel mechanisms as well.

Characterization and temporal regulation of mRNAs encoded by vaccinia virus intermediate-stage genes

The steady-state levels of mRNAs encoded by three intermediate-stage genes of vaccinia virus, A1L, A2L, and G8R, were compared with those encoded by well-characterized early- and late-stage genes. After synchronous infection of HeLa cells, the early mRNA was detected within 20 min and peaked at about 100 min; all three intermediate mRNAs were detected at 100 min and peaked at about 120 min; and the late mRNA was detected at 140 min and increased thereafter. Upon reaching maximum levels, the early and intermediate mRNAs declined at rates consistent with half-lives of about 30 min, providing the basis for rapid changes in gene expression. Intermediate mRNA was not detected when viral DNA synthesis was prevented, whereas its accumulation was enhanced by blocking translation after removal of the replication inhibitor. The 5' ends of the mRNAs initiated within a TAAAT or TAAAAT sequence in the coding DNA strand but contained a poly(A) leader of up to 30 additional bases. Diffuse bands of A1L and G8R RNA, equal to and longer than the coding region, were resolved by agarose gel electrophoresis, suggesting preferred sites of 3'-end formation that did not correlate with early gene termination signals. The cis-regulatory sequences were investigated by constructing recombinant viruses containing mutated intermediate promoters preceding the beta-galactosidase reporter gene. The effects of mutations on expression were similar to those previously obtained by transfection studies (C.J. Baldick, Jr., J.G. Keck, and B. Moss, J. Virol. 66:4710-4719, 1992), providing further evidence for functional core, spacer, and initiator regions. In addition, an up-regulated bifunctional early/intermediate promoter was created by making four single-base substitutions in the G8R promoter.

Phosphorylation of ribosomal proteins by the vaccinia virus B1R protein kinase

Two proteins of the 40S ribosomal subunit were shown to be phosphorylated in vitro by a vaccinia virus-encoded serine/threonine protein kinase. These were identified by two-dimensional gel electrophoresis as ribosomal proteins Sa and S2 and were shown by phosphoamino acid analysis to both be phosphorylated on serine and threonine residues. The three phosphorylated forms of S2 produced by the B1R protein kinase in vitro matched the phosphorylated forms of S2 previously observed in cells infected with vaccinia virus. These data strongly suggest that this enzyme is responsible for the phosphorylation of S2 and Sa which occurs early during vaccinia virus infection.

Mutational analysis of the core, spacer, and initiator regions of vaccinia virus intermediate-class promoters

Activation of vaccinia virus late gene transcription is dependent on DNA replication and the expression of three genes: A1L, A2L, and G8R (J. G. Keck, C. J. Baldick, Jr., and B. Moss, Cell 61:801-809, 1990). To fully characterize the promoter elements of these trans-activator genes, we prepared more than 140 plasmid vectors containing natural and mutated DNA segments ligated to the Escherichia coli lacZ or chloramphenicol acetyltransferase reporter gene. Expression of the reporter genes occurred when the plasmids were transfected into vaccinia virus-infected cells and was enhanced when DNA replication was prevented, indicating that the A1L, A2L, and G8R promoters belong to the intermediate regulatory class. Deletional mutagenesis demonstrated that the regulatory elements of all three promoters extended between 20 and 30 nucleotides upstream of their RNA start sites. Single-base substitutions of the G8R promoter revealed two critical elements located from -26 to -13 (the core element) and -1 to +3 (the initiator element). Mutations in these regions drastically affected expression, as determined by beta-galactosidase and mRNA analyses. Additional mutations defined the TAAA sequence as the critical initiator element. The length, but not the nucleotide sequence, of the segment between the core and initiator regions was crucial. The requirement for the spacer to be 10 or 11 nucleotides was consistent with a single turn of a double helix. The A1L and A2L promoters resembled the G8R promoter, and mutations in the conserved bases had the predicted effects on expression. We concluded that the three intermediate promoters are composed of a 14-bp A+T-rich core sequence separated by one turn of the double helix from the TAAA initiator element.

Identification and expression of rpo19, a vaccinia virus gene encoding a 19-kilodalton DNA-dependent RNA polymerase subunit

The vaccinia virus DNA-dependent RNA polymerase subunit gene rpo19 was identified, and its expression was examined at RNA and protein levels. Antibody to the multisubunit RNA polymerase purified from virions reacted with a polypeptide with an apparent Mr of 21,000 that was synthesized in reticulocyte lysates programmed with (i) mRNA from infected cells that was isolated by hybridization to DNA subclones of the viral genomic HindIII A fragment and (ii) mRNA made in vitro by transcription of the viral open reading frame A6R. Polyclonal antiserum, raised to a recombinant protein product of the A6R open reading frame which could encode an 18,996-Da protein with an acidic N terminus, reacted with Mr-21,000 and -22,000 polypeptides that cosedimented with purified RNA polymerase. Internal sequencing of the two polypeptides confirmed that both were encoded by A6R, and the gene was named rpo19 to indicate the predicted molecular mass of the polypeptide in kilodaltons. Immunoblotting and metabolic labeling of infected cell proteins indicated that synthesis of the Mr-21,000 polypeptide started early and continued throughout virus infection, whereas the Mr-22,000 form appeared late following DNA replication. RNA analyses suggested that the rpo19 mRNA was expressed from a dual early/late promoter and that the protein-coding region of the mRNA was directly preceded by a short 5' poly(A) leader, apparently initiated within the TAAATG motif at the beginning of the open reading frame.

Mechanism of selective translation of vaccinia virus mRNAs: differential role of poly(A) and initiation factors in the translation of viral and cellular mRNAs

We have recently demonstrated that the poly(A) moieties of short RNAs obtained from both in vitro transcription and from vaccinia virus (VV)-infected cells exhibit dissimilar effects on the in vitro translation of cellular and VV mRNAs (R. Bablanian, G. Coppola, P. Masters, and A. K. Banerjee, Virology 148:375-380, 1986; M. J. Su and R. Bablanian, Virology 179:679-693, 1990). In the present study, we have investigated the roles of poly(A), m7GTP, and initiation factors in the mechanism of selective translation of VV mRNAs. The effects of unfractionated poly(A) [termed poly(A)un, with various chain lengths up to 3,000 nucleotides] and a 150- to 300-nucleotide fraction of synthetic poly(A) [termed poly(A)150-300] on the translation of HeLa cell mRNAs and early and late VV mRNAs were studied. Both the poly(A)un and the poly(A)150-300 completely inhibited the translation of HeLa cell mRNAs obtained from total cytoplasmic RNA in the nuclease-treated reticulocyte lysates. Viral mRNAs from total cytoplasmic RNA also were slightly inhibited (15 to 38%) by the poly(A)un, whereas the poly(A)150-300 had no significant effect on their translation. The translation of oligo(dT)-cellulose-selected HeLa mRNAs was as sensitive to inhibition by poly(A)150-300 as the mRNAs found in total cytoplasmic RNA. However, the translations of oligo(dT)-cellulose-selected viral mRNAs become more sensitive to the inhibitory effect of poly(A)150-300 than the translations of viral mRNAs found in the total cytoplasmic RNA. Both HeLa and VV mRNAs became more resistant to the poly(A)-mediated inhibition when these mRNAs were deadenylated, but the relative resistance to inhibition by poly(A)150-300 of deadenylated VV mRNAs was much greater than that of HeLa cell mRNAs. The translation of VV mRNAs was significantly less inhibited than the translation of HeLa mRNAs when the cap analog, m7GTP, was added to the cell-free system. The inhibition of HeLa cell mRNA translation by both poly(A)un and poly(A)150-300 was completely restored when poly(A)-binding protein (PAB) was added to the cell-free translational system. The addition of eukaryotic initiation factor 4A (eIF-4A) did not restore translation when poly(A)un was used to inhibit translation; however, inhibition by poly(A)150-300 was significantly reversed by this initiation factor. The reversal of poly (A)-mediated inhibition of HeLa cell mRNA translation was additive when PAB was used together with eIF-4A. Early VV mRNA translation was only slightly inhibited by poly(A)un (15%), and this inhibition was completely reversed by either PAB or eIF-4A.(ABSTRACT TRUNCATED AT 400 WORDS)

Structure and expression of the vaccinia virus gene which prevents virus-induced breakdown of RNA

Three noncomplementing vaccinia virus temperature-sensitive mutants, ts4, ts22, and ts23, exhibit an abortive late phenotype characterized by the simultaneous cessation of protein synthesis, the breakdown of rRNA and viral mRNA, and an increase in intracellular concentrations of 2'-5'-linked oligoadenylates late during infection at the nonpermissive temperature (R.F. Pacha and R.C. Condit, J. Virol. 56:395-403, 1985; R.J. Cohrs, R.C. Condit, R.F. Pacha, C.L. Thompson, and O.K. Sharma, J. Virol. 63:948-951, 1989). We have identified the virus gene affected by the abortive late mutants, determined its DNA sequence, and analyzed its transcription. The gene resides in the HindIII A DNA fragment, it has a predicted coding capacity of 57 kilodaltons, and it is transcribed both early and late during infection. The early transcript of the abortive late gene is unusual; it contains a 426-nucleotide 5' untranslated region, and it must be synthesized by transcription through an early transcription termination signal which is located in the middle of the gene in a hairpin loop structure. DNA sequence and transcription analysis of two flanking genes is also presented.

Identification of the vaccinia virus gene encoding an 18-kilodalton subunit of RNA polymerase and demonstration of a 5' poly(A) leader on its early transcript

The DNA-dependent RNA polymerase of vaccinia virus contains 8 to 10 virus-encoded polypeptides. We have mapped the gene encoding an 18-kilodalton RNA polymerase subunit to D7R, the seventh open reading frame of the HindIII D genomic subfragment. Localization of this gene was achieved by using antibody to the purified RNA polymerase for immunoprecipitation of the in vitro translation products of in vivo-synthesized early mRNA selected by hybridization to cloned DNA fragments. The identification was confirmed by translation of D7R transcripts made in vitro with bacteriophage T7 RNA polymerase. The phenotypes of two previously isolated conditionally lethal temperature-sensitive mutants that map to D7R (J. Seto, L. M. Celenza, R. C. Condit, and E. G. Niles, Virology 160:110-119, 1987) are consistent with an essential role of this subunit in late transcription. This polymerase gene, designated rpo18, predicts a polypeptide of 161 amino acids with a molecular mass of 17,892. The rpo18 gene is transcribed early in infection, even though the 5'-TAAATG-3' motif, which is conserved among many genes of the late class, is present near the RNA start site. Characterization of the 5' end of the early transcript by several different methods, including cDNA cloning, revealed a poly(A) leader with up to 14 adenylate residues, whereas only 3 are present in the corresponding location of the DNA template. Similar but somewhat longer poly(A) leaders have previously been observed in mRNAs of late genes. We noted a TAAATG motif near the initiation site of several other early genes, including the viral DNA polymerase, and carried out additional experiments to demonstrate that their early transcripts also have 5' poly(A) leaders. Thus, formation of the poly(A) leader is not exclusively a late function but apparently depends on sequences around the transcription initiation site.