The fitness of defective interfering murine coronavirus DI-a and its derivatives is decreased by nonsense and frameshift mutations.

The genome of the defective interfering (DI) mouse hepatitis virus DI-a carries a large open reading frame (ORF) consisting of ORF1a, ORF1b, and nucleocapsid sequences. To test whether this fusion ORF is important for DI virus replication, we constructed derivatives of the DI-a genome in which the reading frame was truncated by a nonsense codon or a frameshift mutation. In vitro-transcribed DI RNAs were transfected into mouse hepatitis virus-infected cells followed by undiluted passage of the resulting virus-DI virus stocks. The following observations were made. (i) Truncation of the fusion ORF was not lethal but led to reduced accumulation of DI RNA. (ii) When pairs of nearly identical in-frame and out-of-frame DI RNAs were directly compared by cotransfection, DI viruses containing in-frame genomic RNAs prevailed within three successive passage even when the out-of-frame RNAs were transfected in 10-fold molar excess. (iii) When DI viruses containing out-of-frame genomic RNAs were passaged, mutants emerged and were selected for that had restored the reading frame. We conclude that translation of the fusion ORF is indeed required for efficient propagation of DI-a and its derivatives.     

Asynchronous accumulation of lettuce infectious yellows virus RNAs 1 and 2 and identification of an RNA 1 trans enhancer of RNA 2 accumulation

Time course and mutational analyses were used to examine the accumulation in protoplasts of progeny RNAs of the bipartite Crinivirus, Lettuce infectious yellow virus (LIYV; family Closteroviridae). Hybridization analyses showed that simultaneous inoculation of LIYV RNAs 1 and 2 resulted in asynchronous accumulation of progeny LIYV RNAs. LIYV RNA 1 progeny genomic and subgenomic RNAs could be detected in protoplasts as early as 12 h postinoculation (p.i.) and accumulated to high levels by 24 h p.i. The LIYV RNA 1 open reading frame 2 (ORF 2) subgenomic RNA was the most abundant of all LIYV RNAs detected. In contrast, RNA 2 progeny were not readily detected until ca. 36 h p.i. Mutational analyses showed that in-frame stop codons introduced into five of seven RNA 2 ORFs did not affect accumulation of progeny LIYV RNA 1 or RNA 2, confirming that RNA 2 does not encode proteins necessary for LIYV RNA replication. Mutational analyses also supported that LIYV RNA 1 encodes proteins necessary for replication of LIYV RNAs 1 and 2. A mutation introduced into the LIYV RNA 1 region encoding the overlapping ORF 1B and ORF 2 was lethal. However, mutations introduced into only LIYV RNA 1 ORF 2 resulted in accumulation of progeny RNA 1 near or equal to wild-type RNA 1. In contrast, the RNA 1 ORF 2 mutants did not efficiently support the trans accumulation of LIYV RNA 2. Three distinct RNA 1 ORF 2 mutants were analyzed and all exhibited a similar phenotype for progeny LIYV RNA accumulation. These data suggest that the LIYV RNA 1 ORF 2 encodes a trans enhancer for RNA 2 accumulation.     

Evolutionary history of Cucumber mosaic virus deduced by phylogenetic analyses

Cucumber mosaic virus (CMV) is an RNA plant virus with a tripartite genome and an extremely broad host range. Previous evolutionary analyses with the coat protein (CP) and 5' nontranslated region (NTR) of RNA 3 suggested subdivision of the virus into three groups, subgroups IA, IB, and II. In this study 15 strains of CMV whose nucleotide sequences have been determined were used for a complete phylogenetic analysis of the virus. The trees estimated for open reading frames (ORFs) located on the different RNAs were not congruent and did not completely support the subgrouping indicated by the CP ORF, indicating that different RNAs had independent evolutionary histories. This is consistent with a reassortment mechanism playing an important role in the evolution of the virus. The evolutionary trees of the 1a and 3a ORFs were more compact and displayed more branching than did those of the 2a and CP ORFs. This may reflect more rigid host-interactive constraints exerted on the 1a and 3a ORFs. In addition, analysis of the 3' NTR that is conserved among all RNAs indicated that evolutionary constraints on this region are specific to the RNA component rather than the virus isolate. This indicates that functions other than replication are encoded in the 3' NTR. Reassortment may have led to the genetic diversity found among CMV strains and contributed to its enormous evolutionary success.     

Examination of potato virus X proteins synthesized in infected tobacco plants.

Nucleotide sequence analysis of potato virus X (PVX) genomic RNA predicts five open reading frames (ORFs). Previous analysis of total RNAs from PVX-infected leaf tissue suggested that six subgenomic RNAs are synthesized during infection. However, the proteins encoded by the genomic RNA, the subgenomic RNAs, or the predicted ORFs have not been identified in vivo. To characterize the coding properties of the viral RNA, particularly to determine whether the five predicted ORFs function in vivo, total protein extracts prepared from PVX-infected leaf tissue were analyzed by using antibodies raised against virus-specific synthetic peptides and against the virus capsid protein. Dot blot analyses showed that these antibodies reacted to PVX-infected extracts, indicating in vivo expression of the five predicted ORFs. In addition, Western blot (immunoblot) analysis of the extracts showed that ORF 1, 2, 3, and 4 peptide antisera and coat protein antiserum detect predominantly a single protein.     

The p23 Protein of Citrus Tristeza Virus Controls Asymmetrical RNA Accumulation

Citrus tristeza virus (CTV), a member of the Closteroviridae, has a 19.3-kb positive-stranded RNA genome that is organized into 12 open reading frames (ORFs) with the 10 3' genes expressed via a nested set of nine or ten 3'-coterminal subgenomic mRNAs (sgRNAs). Relatively large amounts of negative-stranded RNAs complementary to both genomic and sgRNAs accumulate in infected cells. As is characteristic of RNA viruses, wild-type CTV produced more positive than negative strands, with the plus-to-minus ratios of genomic and sgRNAs estimated at 10 to 20:1 and 40 to 50:1, respectively. However, a mutant with all of the 3' genes deleted replicated efficiently, but produced plus to minus strands at a markedly decreased ratio of 1 to 2:1. Deletion analysis of 3'-end genes revealed that the p23 ORF was involved in asymmetric RNA accumulation. A mutation which caused a frameshift after the fifth codon resulted in nearly symmetrical RNA accumulation, suggesting that the p23 protein, not a cis-acting element within the p23 ORF, controls asymmetric accumulation of CTV RNAs. Further in-frame deletion mutations in the p23 ORF suggested that amino acid residues 46 to 180, which contained RNA-binding and zinc finger domains, were indispensable for asymmetrical RNA accumulation, while the N-terminal 5 to 45 and C-terminal 181 to 209 amino acid residues were not absolutely required. Mutation of conserved cysteine residues to alanines in the zinc finger domain resulted in loss of activity of the p23 protein, suggesting involvement of the zinc finger in asymmetric RNA accumulation. The absence of p23 gene function was manifested by substantial increases in accumulation of negative-stranded RNAs and only modest decreases in positive-stranded RNAs. Moreover, the substantial decrease in the accumulation of negative-stranded coat protein (CP) sgRNA in the presence of the functional p23 gene resulted in a 12- to 15-fold increase in the expression of the CP gene. Apparently the excess negative-stranded sgRNA reduces the availability of the corresponding positive-stranded sgRNA as a messenger. Thus, the p23 protein controls asymmetric accumulation of CTV RNAs by downregulating negative-stranded RNA accumulation and indirectly increases expression of 3' genes.     

Serial passage of tobacco rattle virus under different selection conditions results in deletion of structural and nonstructural genes in RNA 2.

The RNA genome of tobacco rattle virus (TRV) is bipartite. RNA 2 of the nematode-transmissible TRV isolate PPK20 encodes the viral coat protein (cp) and proteins with molecular weights of 29,400 and 32,800 (29.4K and 32.8K proteins). When this isolate was serially passaged in tobacco by using phenol-extracted RNA as the inoculum in each transfer, defective interfering (DI) RNAs rapidly accumulated. A number of these DI RNAs were cloned. Six DI RNAs had single internal deletions in RNA 2 that removed most of the cp gene, the 29.4K gene, and the 5' half of the 32.8K gene. The borders of the deletions in these DI RNAs were found to be flanked in the genomic RNA 2 by short nucleotide repeats or sequences resembling the 5' end of TRV genomic and subgenomic RNAs. Two DI RNAs were found to be recombinants containing a 5' sequence derived from RNA 2 and a 3' sequence derived from RNA 1. When serial passage of TRV isolate PPK20 was carried out by using leaf homogenates as inocula in each transfer, accumulation of a DI RNA (designated D7) with a functional cp gene was observed. The deletion in D7 covered the 3' end of the cp gene, the 29.4K gene, and the 5' half of the 32.8K gene. An infectious cDNA clone of D7 RNA was made. In mixed infections, D7 RNA rapidly outcompeted RNA 2 but did not compete with RNA 1. The deletion in D7 RNA abolished the nematode transmissibility of the PPK20 isolate. These results may explain the observation that many laboratory isolates of tobraviruses have lost their nematode transmissibility and contain RNA 2 molecules of widely different lengths.     

Sequence and organization of barley yellow dwarf virus genomic RNA.

The nucleotide sequence of the genomic RNA of barley yellow dwarf virus, PAV serotype was determined, except for the 5'-terminal base, and its genome organization deduced. The 5,677 nucleotide genome contains five large open reading frames (ORFs). The genes for the coat protein (1) and the putative viral RNA-dependent RNA polymerase were identified. The latter shows a striking degree of similarity to that of carnation mottle virus (CarMV). By comparison with corona- and retrovirus RNAs, it is proposed that a translational frameshift is involved in expression of the polymerase. An ORF encoding an Mr 49,797 protein (50K ORF) may be translated by in-frame readthrough of the coat protein stop codon. The coat protein, an overlapping 17K ORF, and a 3'6.7K ORF are likely to be expressed via subgenomic mRNAs.     

Identification of polypeptides encoded in open reading frame 1b of the putative polymerase gene of the murine coronavirus mouse hepatitis virus A59.

The polypeptides encoded in open reading frame (ORF) 1b of the mouse hepatitis virus A59 putative polymerase gene of RNA 1 were identified in the products of in vitro translation of genome RNA. Two antisera directed against fusion proteins containing sequences encoded in portions of the 3'-terminal 2.0 kb of ORF 1b were used to immunoprecipitate p90, p74, p53, p44, and p32 polypeptides. These polypeptides were clearly different in electrophoretic mobility, antiserum reactivity, and partial protease digestion pattern from viral structural proteins and from polypeptides encoded in the 5' end of ORF 1a, previously identified by in vitro translation. The largest of these polypeptides had partial protease digestion patterns similar to those of polypeptides generated by in vitro translation of a synthetic mRNA derived from the 3' end of ORF 1b. The polypeptides encoded in ORF 1b accumulated more slowly during in vitro translation than polypeptides encoded in ORF 1a. This is consistent with the hypothesis that translation of gene A initiates at the 5' end of ORF 1a and that translation of ORF 1b occurs following a frameshift at the ORF 1a-ORF 1b junction. The use of in vitro translation of genome RNA and immunoprecipitation with antisera directed against various regions of the polypeptides encoded in gene A should make it possible to study synthesis and processing of the putative coronavirus polymerase.     

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.     

Complete genome sequence and analyses of the subgenomic RNAs of sweet potato chlorotic stunt virus reveal several new features for the genus Crinivirus

The complete nucleotide sequences of genomic RNA1 (9,407 nucleotides [nt]) and RNA2 (8,223 nt) of Sweet potato chlorotic stunt virus (SPCSV; genus Crinivirus, family Closteroviridae) were determined, revealing that SPCSV possesses the second largest identified positive-strand single-stranded RNA genome among plant viruses after Citrus tristeza virus. RNA1 contains two overlapping open reading frames (ORFs) that encode the replication module, consisting of the putative papain-like cysteine proteinase, methyltransferase, helicase, and polymerase domains. RNA2 contains the Closteroviridae hallmark gene array represented by a heat shock protein homologue (Hsp70h), a protein of 50 to 60 kDa depending on the virus, the major coat protein, and a divergent copy of the coat protein. This grouping resembles the genome organization of Lettuce infectious yellows virus (LIYV), the only other crinivirus for which the whole genomic sequence is available. However, in striking contrast to LIYV, the two genomic RNAs of SPCSV contained nearly identical 208-nt-long 3' terminal sequences, and the ORF for a putative small hydrophobic protein present in LIYV RNA2 was found at a novel position in SPCSV RNA1. Furthermore, unlike any other plant or animal virus, SPCSV carried an ORF for a putative RNase III-like protein (ORF2 on RNA1). Several subgenomic RNAs (sgRNAs) were detected in SPCSV-infected plants, indicating that the sgRNAs formed from RNA1 accumulated earlier in infection than those of RNA2. The 5' ends of seven sgRNAs were cloned and sequenced by an approach that provided compelling evidence that the sgRNAs are capped in infected plants, a novel finding for members of the Closteroviridae.     

Translation of a polycistronic mRNA in the presence of the cauliflower mosaic virus transactivator protein.

Polycistronic mRNAs containing an upstream beta-glucuronidase (GUS) and a downstream chloramphenicol acetyltransferase (CAT) reporter open reading frame (ORF) were expressed in transfected plant protoplasts. CAT expression could be strongly induced by coexpression of the cauliflower mosaic virus encoded translation transactivator. Transactivation was abolished when an upstream ORF overlapped the CAT ORF for a long distance. No specific sequence elements were required for transactivation but the presence of a short ORF upstream of the GUS ORF strongly enhanced the process. The inhibitory effect of additional presumed stem structures inserted into various regions of the reporter mRNAs indicates that both ORFs are translated by ribosomes that associate with the RNA at the 5' end and reach the ORFs by a linear migration mechanism.     

Repair of the tRNA-like CCA sequence in a multipartite positive-strand RNA virus

The 3' portions of plus-strand brome mosaic virus (BMV) RNAs mimic cellular tRNAs. Nucleotide substitutions or deletions in the 3'CCA of the tRNA-like sequence (TLS) affect minus-strand initiation unless repaired. We observed that 2-nucleotide deletions involving the CCA 3' sequence in one or all BMV RNAs still allowed RNA accumulation in barley protoplasts at significant levels. Alterations of CCA to GGA in only BMV RNA3 also allowed RNA accumulation at wild-type levels. However, substitutions in all three BMV RNAs severely reduced RNA accumulation, demonstrating that substitutions have different repair requirements than do small deletions. Furthermore, wild-type BMV RNA1 was required for the repair and replication of RNAs with nucleotide substitutions. Results from sequencing of progeny viral RNA from mutant input RNAs demonstrated that RNA1 did not contribute its sequence to the mutant RNAs. Instead, the repaired ends were heterogeneous, with one-third having a restored CCA and others having sequences with the only commonality being the restoration of one cytidylate. The role of BMV RNA1 in increased repair was examined.     

Accumulation of RNA homologous to human papillomavirus type 16 open reading frames in genital precancers.

The accumulation of human papillomavirus type 16 (HPV-16)-specific RNAs in tissue sections from biopsies of patients with genital precancers was studied by in situ hybridization with single-stranded 35S-labeled RNA. These analyses revealed that the most abundant early-region RNAs were derived from the E4 and E5 open reading frames (ORFs). RNAs homologous to the E6/E7 ORFs were also detected, whereas RNAs homologous to the intervening E1 ORF were not. This suggests that the E4 and E5 mRNAs are derived by splicing to the upstream E6/E7 ORFs, consistent with studies of HPV-11 in condylomata (L. T. Chow et al., Cancer Cells (Cold Spring Harbor) 5:55-72, 1987). Abundant RNAs homologous to the 5' portion of L1 were also detected. These RNAs were localized to the apical strata of the epithelium. HPV-16 RNAs accumulated in discrete regions of these lesions, and when present were most abundant in the upper cell layers of the precancerous epithelium. RNAs homologous to early ORFs were also detected in some germinal cells within the basal layer of the epithelium.