Translation Of Open Reading Frame Research Articles

The complete sequence of hepatitis E virus genotype 4 reveals an alternative strategy for translation of open reading frames 2 and 3.

Isolates of hepatitis E virus (HEV) have recently been described from China that are distinct from Burmese, Mexican and US viruses and constitute a novel genotype (genotype 4). Here, the complete genomic sequence of a representative isolate of genotype 4 HEV, amplified directly from the stool of an acutely infected patient, is presented. Analysis of the entire sequence confirms our previous conclusion, based upon partial sequence data, that these Chinese isolates belong to a novel genotype. Typical of genetic variation in HEV, most nucleotide substitutions occur in the third base of the codon and do not affect the amino acid sequence. The genotype 4 virus is unusual in that a single nucleotide insertion in the ORF 3 region changes the initiation of ORF 3, and perhaps also ORF 2. The consequences of these changes are discussed.

Rubella virus nonstructural protein protease domains involved in trans- and cis-cleavage activities.

Rubella virus (RV) genomic RNA contains two large open reading frames (ORFs): a 5'-proximal ORF encoding nonstructural proteins (NSPs) that function primarily in viral RNA replication and a 3'-proximal ORF encoding the viral structural proteins. Proteolytic processing of the RV NSP ORF translation product p200 is essential for viral replication. Processing of p200 to two mature products (p150 and p90) in the order NH(2)-p150-p90-COOH is carried out by an RV-encoded protease residing in the C-terminal region of p150. The RV nonstructural protease (NS-pro) belongs to a viral papain-like protease family that cleaves the polyprotein both in trans and in cis. A conserved X domain of unknown function was found from previous sequence analysis to be associated with NS-pro. To define the domains responsible for cis- and trans-cleavage activities and the function of the X domain in terms of protease activity, an in vitro translation system was employed. We demonstrated that the NSP region from residue 920 to 1296 is necessary for trans-cleavage activity. The domain from residue 920 to 1020 is not required for cis-cleavage activity. The X domain located between residues 834 and 940, outside the regions responsible for both cis- and trans-cleavage activities of NS-pro, was found to be important for NS-pro trans-cleavage activity but not for cis-cleavage activity. Analysis of sequence homology and secondary structure of the RV NS-pro catalytic region reveals a folding structure similar to that of papain.

Identification and Phylogenetic Comparison of Salem Virus, a Novel Paramyxovirus of Horses

A virus that could not be identified as a previously known equine virus was isolated from the mononuclear cells of a horse. Electron microscopy revealed enveloped virions with nucleocapsid structures characteristic of viruses in the Paramyxoviridae family. The virus failed to hemadsorb chicken or guinea pig red blood cells and lacked neuraminidase activity. Two viral genes were isolated from a cDNA expression library. Multiple sequence alignments of one gene indicated an average identity of 45% as compared to Morbillivirus N protein sequences. A weaker relationship was found with Tupaia paramyxovirus (TPMV) and Hendra virus (HeV) N proteins. In the second gene, multiple open reading frames (ORFs) were identified, corresponding to the arrangement of the P, V, and C ORFs in the Morbillivirus and Respirovirus viruses. Short stretches in the C-terminal regions of the P and C proteins showed limited homologies to viruses in the Morbillivirus genus but no obvious relationship to viruses in other genera. The V ORF translation product contained a highly conserved, cysteine-rich domain that is common to most viruses in the Paramyxovirinae subfamily. Sequencing of P gene cDNA clones confirmed the use of a cotranscriptional editing mechanism for the regulation of P/V expression. Based on the location of its origin it has been named Salem virus (SalV).

Trypanosoma cruzi: Suppression of Tuzin Gene Expression by Its 5′-UTR and Spliced Leader Addition Site

Teixeira, S. M. R., Kirchhoff, L. V., and Donelson, J. E. 1999. Trypanosoma cruzi: Suppression of tuzin gene expression by its 5′-UTR and spliced leader addition site. Experimental Parasitology93, 143–151. The genome of the protozoan parasite Trypanosoma cruzi contains a tandemly repeated array of two alternating genes, one encoding amastin and the other encoding tuzin. Amastin is an abundant amastigote surface protein, whereas tuzin is thought to be a rare protein whose location and function are unknown. The 137-nucleotide 5′ untranslated region (5′-UTR) of the tuzin mRNA has a 22-codon open translation reading frame containing 3 methionine codons followed by a stop codon that overlaps the methionine start codon of the tuzin coding region. A fragment containing the tuzin 5′-UTR and upstream intergenic region was placed in front of a luciferase reporter gene in a plasmid for transient transfection assays of luciferase activity. By mutating the three upstream ATGs in the tuzin 5′-UTR and replacing the tuzin spliced leader (SL) acceptor site with that of the amastin gene, we found that the 22-codon reading frame and the tuzin SL acceptor site combine to substantially reduce expression of the luciferase gene. These results indicate that expression of the multicopy tuzin gene is posttranscriptionally suppressed by both inefficient RNA processing and poor translation initiation, resulting in a low level of tuzin.

Herpes simplex virus latency-associated transcript encodes a protein which greatly enhances virus growth, can compensate for deficiencies in immediate-early gene expression, and is likely to function during reactivation from virus latency.

Herpes simplex virus types 1 and 2 (HSV1 and HSV2) enter and reactivate from latency in sensory neurons, although the events governing these processes are little understood. During latency, only the latency-associated transcripts (LATs) are produced. However, although the LAT RNAs were described approximately 10 years ago, their function remains ambiguous. Mutations affecting the LATs have minimal effects other than a small reduction in establishment of and reactivation from latency in some cases. Mutations in putative LAT-contained open reading frames (ORFs) have so far shown no effect. The LATs consist of a large species from which smaller (approximately 2 kb), nuclear, nonlinear LATs which are abundant during latency are spliced. Thus, translation of ORFs in these smaller LATs would not usually be expected to be possible, and if expressed at all, their expression might be tightly regulated. Here we show that deregulated expression of the largest HSV1 2-kb LAT-contained ORF in various cells of neuronal and nonneuronal origin greatly enhances virus growth in a manner specific to HSV1-the HSV1 LAT ORF has no effect on the growth of HSV2. Similar results of enhanced growth were found when the HSV1 LAT ORF was constitutively expressed from within the HSV1 genome. The mechanism of LAT ORF action was strongly suggested to be by substituting for deficiencies in immediate-early (IE) gene expression (particularly ICP0), because deregulated LAT ORF expression, as well as enhancing wild-type virus growth, was also found to allow efficient growth of viruses with mutations in ICP0 or VMW65. Such viruses otherwise exhibit considerable growth defects. IE gene expression deficiencies are often the block to productive infection in nonpermissive cells and are also evident during latency. These results, which we show to be protein- rather than RNA-mediated effects, strongly suggest a function of the tightly regulated expression of a LAT ORF-encoded protein in the reactivation from HSV latency.

Adapt78, a Stress-Inducible mRNA, Is Related to the Glucose-Regulated Protein Family of Genes

We have recently reported a new oxidant- and calcium-inducible mRNA, adapt78, from hamster HA-1 cells. The adapt78 mRNA is induced in HA-1 cells under conditions where a protective adaptive response is observed and contains a translatable open reading frame whose protein product shows strong homology to a human sequence. Computer analysis of the predicted Adapt78 protein sequence also revealed a stretch of amino acids homologous to a portion of the glucose-regulated protein78 (Grp78). Based on this homology, we tested the hypothesis that adapt78 may be a new member of the grp gene family. Toward this, we assessed the modulation of adapt78 mRNA by stress agents known to induce grp78. In HA-1 cells, adapt78 mRNA was induced by the calcium ionophore A23187, 2-deoxyglucose, brefeldin A, tunicamycin, thapsigargin, and cyclopiazonic acid, with thapsigargin being the most potent inducer (7.3-fold). As expected, grp78 mRNA was also induced by these agents in our model system. In contrast, heat shock treatment produced little if any modulation of either grp78 or adapt78. Differences were also observed, as adapt78 mRNA but not grp78 mRNA was induced by 160 μM hydrogen peroxide, and adapt78 demonstrated earlier induction kinetics for certain agents compared with grp78. adapt78 mRNA was also found to be induced in several different human cell lines. A23187 had the strongest effect on adapt78 mRNA levels in human cells, inducing greater than 20-fold in all human cell cultures tested. Furthermore, in vitro transcription translation of human adapt78 cDNA produced an Adapt78 protein product. We conclude that adapt78 may be a new member of the grp family of genes and may represent an early response grp that complements the actions of grp78 and grp94.

Discovery of Three Novel Orphan G-Protein-Coupled Receptors

We have discovered three novel human genes, GPR34, GPR44, and GPR45, encoding family A G-protein-coupled receptors (GPCRs). The receptor encoded by GPR34 is most similar to the P2Y receptor subfamily, while the receptor encoded by GPR44 is most similar to chemoattractant receptors. The receptor encoded by GPR45 is the mammalian orthologue of a putative lysophosphatidic acid receptor fromXenopus laevis.Partial sequence of GPR34 was discovered during a search of the GenBank database of expressed sequence tags (ESTs). This sequence information was used both to isolate the full-length translational open reading frame from a human genomic library and to assemble a contig from additional GPR34 EST cDNAs. Northern blot andin situhybridization analyses revealed GPR34 mRNA transcripts in several human and rat brain regions. Also, we used polymerase chain reaction (PCR) to amplify human genomic DNA using degenerate oligonucleotides designed from sequences encoding transmembrane domains 3 and 7 of opioid and somatostatin receptors. Two PCR products partially encoding novel GPCRs, named GPR44 and GPR45, were discovered and used to isolate the full-length translational open reading frames from a human genomic library. Both GPR44 and GPR45 are expressed in the central nervous system and periphery. For chromosomal localization, fluorescencein situhybridization analysis was performed to assign GPR34 to chromosomes 4p12 and Xp11.3, GPR44 to chromosome 11q12–q13.3, and GPR45 to chromosome 2q11.1–q12.

Discovery of Three Novel G-Protein-Coupled Receptor Genes

We report here the molecular cloning, tissue distribution, and chromosomal localization of novel genes encoding G-protein-coupled receptors (GPCRs). A search of a mouse database of expressed sequence tags revealed an EST partially encoding a GPCR, which was used to screen a mouse genomic library to obtain the translational open reading frame (ORF). The resultant clone, GPR27, contained an intronless ORF, encoding a receptor of 379 amino acids. In an alternate strategy, human genomic DNA was subjected to polymerase chain reaction (PCR) amplification, using degenerate oligonucleotides based on GPR1. Two PCR products partially encoding GPCRs were isolated and used to screen a genomic library to obtain the translational ORF. One of the resultant clones, GPR30, contained an intronless ORF encoding a receptor of 375 amino acids. The other clone, GPR35, also contained an intronless ORF encoding a receptor of 309 amino acids. Transcripts corresponding to GPR27 and GPR30 were detected in several areas of human and rat CNS, while GPR35 expression was detected only in the rat intestine. Through fluorescencein situhybridization analysis the gene encoding GPR30 was localized to chromosome 7p22 and GPR35 to chromosome 2q37.3.

Enzymatic and control functions of reovirus structural proteins.

Viruses have evolved in many diverse ways in order to utilize efficiently their limited genetic information and successfully overcome the various defense mechanisms of different hosts. For the multisegmented dsRNA-containing reoviruses, this has apparently been accomplished at the level of the structural proteins rather than the mRNA. In reovirus infections, only full-length, unspliced viral mRNA are produced and, with one exception, each contains a single translational open reading frame. However, most, if not all, of the virion structural proteins also have enzymatic activities and/or other functions that are essential in the reovirus life cycle (Table 1). This structural protein pleiotropy is summarized in this chapter, which is based on the many studies that have correlated virion proteins with functional activities and assigned them to specific reovirus genome segments.

Bovine papillomavirus type 1 E1 and simian virus 40 large T antigen share regions of sequence similarity required for multiple functions.

The full-length product of the bovine papillomavirus type 1 (BPV-1) E1 translational open reading frame is required for viral DNA replication in vivo and in vitro. E1 is a multifunctional protein whose properties include ATP binding, acting as an ATPase-dependent DNA helicase, DNA binding to the BPV-1 origin of viral DNA replication, and association with the E2 transcriptional transactivator, E2TA, a second viral protein involved in DNA replication. All of these properties are thought to be important for E1's role in replicating the viral genome. In addition BPV-1 E1 can inhibit activation of the viral P89 promoter by the BPV-1 E2TA. E1 has amino acid homology with eight regions of SV40 large tumor antigen (T-ag), a DNA helicase that is essential for the replication of the SV40 DNA genome. These eight regions of similarity lie within the domain of T-ag that confers DNA helicase activity. We created a series of missense mutations in BPV-1 E1 at codons 295, 344-345, 446, 464, 466, 497-498, 523, and 542, which encode amino acids of identity in seven of the eight regions of similarity between E1 and T-ag, and at codon 370. The activities of these mutant E1 genes were compared to wild-type E1 in multiple assays that measured DNA replication, inhibition of E2TA-dependent transcription, DNA binding, ATP binding, and protein expression. Based upon these analyses, the following conclusions were made: (i) at least five of the eight regions in E1 that are similar to regions in T-ag are functionally important in viral DNA replication; (ii) specific E1 missense mutants, themselves defective for supporting DNA replication, could act in trans to suppress the replication function of wild-type E1; (iii) certain regions of similarity with T-ag that are important for E1's ability to support DNA replication are not necessary for its capacity to inhibit E2TA-dependent transcription; and (iv) efficient DNA binding by E1 is not essential for E1 to inhibit E2TA-dependent transcription.

Translation of an Uncapped mRNA Involves Scanning

tat, an essential gene of human immunodeficiency virus, when placed under the control of the RNA polymerase III promoter from the adenovirus VA RNA1 gene, is transcribed into an uncapped and nonpolyadenylated mRNA. This VA-Tat RNA is translated to produce functional Tat protein in transfected mammalian cells (Gunnery, S., and Mathews, M. B. (1995) Mol. Cell. Biol. 15, 3597-3607). The presence of an upstream open reading frame (ORF) in VA-Tat RNA is inhibitory to the translation of the Tat ORF, suggesting that the RNA is scanned during translation even though it is uncapped. Because the effect of the upstream ORF is relatively small (about 2-fold), we sought more definitive evidence of scanning by introducing secondary structures of varying stabilities into the 5'-untranslated region of VA-Tat RNA. The results of transfection experiments showed that highly stable secondary structure was inhibitory to Tat synthesis, whereas structures of lower stability were not inhibitory, confirming that uncapped mRNA is subject to scanning. Furthermore, translation of the downstream ORF was reduced but not eliminated by mutations that caused the upstream ORF to overlap the Tat ORF. Extending the overlap of the two ORFs further decreased the translation of the downstream ORF. This observation implies that ribosomes reinitiate after termination, possibly after migrating in a 3' to 5' direction through the overlap region of the mRNA. Similar results were obtained with a capped polymerase II transcript, indicating that the translation of polymerase II and polymerase III transcripts occurs through similar mechanisms.

ORF 3 of Lactate Dehydrogenase-Elevating Virus Encodes a Soluble, Nonstructural, Highly Glycosylated, and Antigenic Protein

Open reading frame (ORF) 3 of the genome of lactate dehydrogenase-elevating virus (LDV), strain P, was cloned into the plasmid pcDNAI/Amp andin vitrotranscribed and translated. Translation of ORF 3 yielded a soluble protein of the expected size (about 21 kDa). When synthesized in the presence of endoplasmic reticulum (ER) membranes the resulting glycoprotein of about 36 kDa became associated with the membranes. However, disruption of the ER vesicles by incubation in carbonate buffer, pH 11.5, resulted in the release of the protein from the membranes. Hydrophobic moment analysis of the ORF 3 protein indicated the absence of any potential transmembrane segments, except for a N-terminal signal peptide, but no cleavage of the signal peptide was observed during membrane-associatedin vitrosynthesis. The ORF 3 protein elicited a strong antibody response in infected mice. The antibodies from infected mice as well as a monoclonal antibody specifically precipitated thein vitro-synthesized ORF 3 protein, but no protein from LDV virions. The overall results suggest that the ORF 3 protein is a nonstructural, highly glycosylated, and antigenic glycoprotein that is probably soluble and secreted or at most only weakly associated with membranes via the signal peptide.

The gag coding region of the Drosophila telomeric retrotransposon, HeT-A, has an internal frame shift and a length polymorphic region.

A major component of Drosophila telomeres is the retrotransposon HeT-A, which is clearly related to other retrotransposons and retroviruses. This retrotransposon is distinguished by its exclusively telomeric location, and by the fact that, unlike other retrotransposons, it does not encode its own reverse transcriptase. HeT-A coding sequences diverge significantly, even between elements within the same genome. Such rapid divergence has been noted previously in studies of gag genes from other retroelements. Sequence comparisons indicate that the entire HeT-A coding region codes for gag protein, with regions of similarity to other insect retrotransposon gag proteins found throughout the open reading frame (ORF). Similarity is most striking in the zinc knuckle region, a region characteristic of gag genes of most replication-competent retroelements. We identify a subgroup of insect non-LTR retrotransposons with three zinc knuckles of the form: (1) CX2CX4HX4C, (2) CX2CX3HX4C, (3) CX2CX3HX6C. The first and third knuckles are invariant, but the second shows some differences between members of this subgroup. This subgroup includes HeT-A and a second Drosophila telomeric retrotransposon, TART. Unlike other gag regions, HeT-A requires a -1 frameshift for complete translation. Such frameshifts are common between the gag and pol sequences of retroviruses but have not before been seen within a gag sequence. The frameshift allows HeT-A to encode two polypeptides; this mechanism may substitute for the post-translational cleavage that creates multiple gag polypeptides in retroviruses. D. melanogaster HeT-A coding sequences have a polymorphic region with insertions/deletions of 1-31 codons and many nucleotide changes. None of these changes interrupt the open reading frame, arguing that only elements with translatable ORFs can be incorporated into the chromosomes. Perhaps HeT-A translation products act in cis to target the RNA to chromosome ends.

Bovine herpesvirus 4: genomic organization and relationship with two other gammaherpesviruses, Epstein-Barr virus and herpesvirus saimiri

Bovine herpesvirus 4 (BHV-4) belongs to the gammaherpesvirinae subfamily. Although the whole sequence of BHV-4 genome is not known it was possible, based on random sequencing, to assume that its genomic organization consists of genes clustered in blocks whose orientation and location in the genome are conserved within a herpesvirus subfamily. Between these blocks lie genes which are specific to either a particular virus or a virus subfamily. BHV-4 genome consists of 5 gene blocks conserved among the gammaherpesviruses and particularly within the Epstein-Barr virus (EBV) and the herpesvirus saimiri (HVS) genomes. Analysis of the regions located outside the gene blocks showed the presence of 12 open reading frames (ORFs). Protein database comparisons showed that no ORF translation products were similar to proteins encoded by alpha- or beta-herpesviruses. Nevertheless, 5 ORFs were homologous in amino acid sequences to proteins encoded by HVS and one was similar to a protein encoded by both HVS and EBV. On the basis of the molecular data BHV-4 is more closely related to HVS than to EBV. Genes homologous to cellular genes have been described in both HVS and EBV genomes. No genes homologous to presently sequenced cellular genes were found among those found in the BHV-4 genome to date.

Effects of mutations in the gene-start and gene-end sequence motifs on transcription of monocistronic and dicistronic minigenomes of respiratory syncytial virus.

Preceding and following each gene of respiratory syncytial virus (RSV) are two conserved sequences, the gene-start (GS) and gene-end (GE) motifs, respectively, which are thought to be transcription signals. The functions and boundaries of these signals and the process of sequential transcription were analyzed with cDNA-encoded RNA analogs (minigenomes) of nonsegmented negative-sense RSV genomic RNA. Two minigenomes were used. The monocistronic RSV-CAT minigenome consists of the chloramphenicol acetyltransferase (CAT) translational open reading frame (ORF) bordered by the GS and GE motifs and flanked by the 3' leader and 5' trailer extragenic regions of genomic RNA. The dicistronic RSV-CAT-LUC minigenome is a derivative of RSV-CAT into which the ORF for luciferase (LUC), bordered by GS and GE motifs, was inserted downstream of the CAT gene with an intergenic region positioned between the two genes. Each minigenome was synthesized in vitro and transfected into RSV-infected cells, where it was replicated and transcribed to yield the predicted polyadenylated subgenomic mRNA(s). The only RSV sequences required for efficient transcription and RNA replication were the 44-nucleotide 3' leader region, the last 40 nucleotides of the 5' trailer region, and the 9- to 10-nucleotide GS and 12- to 13-nucleotide GE motifs. The GS and GE motifs functioned as self-contained, transportable transcription signals which could be attached to foreign sequences to direct their transcription into subgenomic mRNAs. Removal of the GS motif greatly reduced transcription of its gene, and the requirement for this element was particularly strict for the gene in the downstream position. Ablation of the promoter-proximal GS signal was not associated with increased antigenome synthesis. Consistent with its proposed role in termination and polyadenylation, removal of the CAT GE signal in RSV-CAT resulted in the synthesis of a nonpolyadenylated CAT mRNA, and in RSV-CAT-LUC the same mutation resulted in readthrough transcription to yield a dicistronic CAT-LUC mRNA. The latter result showed that a downstream GS signal is not recognized for reinitiation by the polymerase if it is already engaged in mRNA synthesis; instead, it is recognized only if the polymerase first terminates transcription at an upstream termination signal. This result also showed that ongoing transcription did not open the downstream LUC gene for internal polymerase entry. Removal of both the GS and GE signals of the upstream CAT gene in RSV-CAT-LUC silenced expression of both genes, confirming that independent polymerase entry at an internal gene is insignificant. Remarkably, whereas both genes were silent when the CAT GS and GE signals were both absent, restoration of the CAT GE signal alone restored a significant level (approximately 10 to 12% of the wild-type level) of synthesis of both subgenomic mRNAs. This analysis identified a component of sequential transcription that was independent of the promoter-proximal GS signal and appeared to involve readthrough from the leader region.

The structurally diverse intergenic regions of respiratory syncytial virus do not modulate sequential transcription by a dicistronic minigenome

The first nine genes of respiratory syncytial virus (RSV), a nonsegmented negative-strand RNA virus, are separated by intergenic regions which range in size from 1 to 52 nucleotides for strain A2 and lack obvious consensus elements except that each ends in an A (genome sense). Their significance for gene expression was investigated by using RSV-CAT-LUC RNA, a helper-dependent cDNA-encoded dicistronic analog of RSV genomic RNA in which the viral genes were replaced by a negative-sense copy of the translational open reading frame (ORF) encoding chloramphenicol acetyltransferase (CAT) as the upstream, leader-proximal gene and that encoding luciferase (LUC) as the downstream gene. These foreign ORFs were flanked by the RSV gene-start (GS) and gene-end (GE) transcription signals and separated by the naturally occurring G/F intergenic region. The RSV-CAT-LUC minigenome was synthesized in vitro and transfected into RSV-infected cells, and synthesis of the CAT and LUC mRNAs was monitored by enzyme assay and Northern (RNA) blot hybridization. Surprisingly, substitution of each of the other naturally occurring RSV intergenic regions in turn did not significantly alter the absolute or relative amounts of the two mRNAs. Substitution of a nonnatural 10-nucleotide intergenic region, or elimination of the intergenic region altogether, also had little effect on the level of expression of the two genes. Four of the minigenome variants containing naturally occurring intergenic regions were modified further by replacing part of the LUC ORF with a second copy of the CAT ORF, so that each of the two mRNAs would hybridize equally with a CAT-specific probe and their relative molar amounts could be determined. The level of expression of the downstream gene was 0.30 to 0.36 that of the upstream one. This determined the magnitude of RSV transcriptional polarity across a gene pair and confirmed that this value was very similar among the various intergenic regions. Minigenome transcription also yielded a CAT-LUC readthrough mRNA at a level 0.10 to 0.13 that of the LUC mRNA. In summary, the structurally diverse RSV intergenic regions do not appear to play a role in modulating RSV gene expression.

Transcription elongation factor of respiratory syncytial virus, a nonsegmented negative-strand RNA virus.

RNA synthesis by the paramyxovirus respiratory syncytial virus, a ubiquitous human pathogen, was found to be more complex than previously appreciated for the nonsegmented negative-strand RNA viruses. Intracellular RNA replication of a plasmid-encoded "minigenome" analog of viral genomic RNA was directed by coexpression of the N, P, and L proteins. But, under these conditions, the greater part of mRNA synthesis terminated prematurely. This difference in processivity between the replicase and the transcriptase was unanticipated because the two enzymes ostensively shared the same protein subunits and template. Coexpression of the M2 gene at a low level of input plasmid resulted in the efficient production of full-length mRNA and, in the case of a dicistronic minigenome, sequential transcription. At a higher level, coexpression of the M2 gene inhibited transcription and RNA replication. The M2 mRNA contains two overlapping translational open reading frames (ORFs), which were segregated for further analysis. Expression of the upstream ORF1, which encoded the previously described 22-kDa M2 protein, was associated with transcription elongation. A model involving this protein in the balance between transcription and replication is proposed. ORF2, which lacks an assigned protein, was associated with inhibition of RNA synthesis. We propose that this activity renders nucleocapsids synthetically quiescent prior to incorporation into virions.

Bovine papillomavirus type 1 E2 transcriptional regulators directly bind two cellular transcription factors, TFIID and TFIIB.

The bovine papillomavirus type 1 (BPV-1) E2 translational open reading frame encodes three proteins that regulate viral transcription and DNA replication: the E2 transcriptional activator (E2TA), the E2 transcriptional repressor (E2TR) and the E8/E2 transcriptional repressor (E8/E2TR). E2TA is a strong activator of papillomaviral promoters and is required for viral DNA replication. E2TR and E8/E2TR inhibit the activities of E2TA but also possess weak transactivational properties of their own. Two components of the cellular transcription apparatus, TFIID and TFIIB, have previously been shown to associate with other viral and cellular transcriptional activators. We present evidence here that E2TA, the full-length E2 open reading frame gene product, directly binds both of these transcription factors in vitro. Glutathione S-transferase E2TA (GST-E2TA) fusion protein bound in vitro-synthesized TATA-box-binding protein (TBP), a component of TFIID, and in vitro-synthesized TFIIB. Likewise, GST-E2TA bound TFIID and TFIIB present in a nuclear extract from the human cervical cancer-derived cell line, HeLa. The binding of GST-E2TA to TBP and TFIIB required no additional mammalian factors, as shown by direct binding of GST-E2TA to bacterially synthesized recombinant TBP and recombinant TFIIB. The domain of E2TA required for its interaction with both TBP and TFIIB was localized to the C terminus of E2TA, a region also present in E2TR and E8/E2TR. This domain lies within the region of E2TA previously shown to confer cooperative DNA binding by E2TA and TBP and overlaps with the region of E2TA required for DNA binding and dimerization. Our findings, taken in context with previous studies, lead us to conclude that (i) cooperative DNA binding by E2 proteins and TBP is likely mediated by the direct binding of E2 proteins to TBP, (ii) the weak transcriptional transactivation by E2TR and E8/E2TR may result as a consequence of direct TBP and TFIIB binding by these proteins, and (iii) TBP and/or TFIIB binding may be required but is not sufficient for E2TA's strong transactivational activity.

Translation of the open reading frame encoded by comS, a gene of the srf operon, is necessary for the development of genetic competence, but not surfactin biosynthesis, in Bacillus subtilis.

A small open reading frame, comS of the srf operon, is the site of mutations that impair competence development in Bacillus subtilis. comS open reading frame translation was required for competence, as was confirmed by the suppression of a comS amber mutation [comS(Am)] by the nonsense suppressor sup-3. comS(Am), when introduced into the srf operon, eliminated late competence gene expression but had no significant effect on surfactin production.

Translation but not the encoded sequence is essential for the efficient propagation of the defective interfering RNAs of the coronavirus mouse hepatitis virus

The defective interfering (DI) RNA MIDI of mouse hepatitis virus strain A59 (MHV-A59) contains a large open reading frame (ORF) spanning almost its entire genome. This ORF consists of sequences derived from ORF1a, ORF1b, and the nucleocapsid gene. We have previously demonstrated that mutations that disrupt the ORF decrease the fitness of MIDI and its derivatives (R. J. de Groot, R. G. van der Most, and W. J. M. Spaan, J. Virol. 66:5898-5905, 1992). To determine whether translation of the ORF per se is required or whether the encoded polypeptide or a specific sequence is involved, we analyzed sets of related DI RNAs containing different ORFs. After partial deletion of ORF1b and nucleocapsid gene sequences, disruption of the remaining ORF is still lethal; translation of the entire ORF is not essential, however. When a large fragment of the MHV-A59 spike gene, which is not present in any of the MHV-A59 DI RNAs identified so far, was inserted in-frame into a MIDI derivative, translation across this sequence was vital to DI RNA survival. Thus, the translated sequence is irrelevant, indicating that translation per se plays a crucial role in DI virus propagation. Next, it was examined during which step of the viral life cycle translation plays its role. Since the requirement for translation also exists in DI RNA-transfected and MHV-infected cells, it follows that either the synthesis or degradation of DI RNAs is affected by translation.