Repair and polyadenylation of a naturally occurring hepatitis C virus 3' nontranslated region-shorter variant in selectable replicon cell lines

The 3' nontranslated region (NTR) of the hepatitis C virus (HCV) genome is highly conserved and contains specific cis-acting RNA motifs that are essential in directing the viral replication machinery to initiate at the correct 3' end of the viral genome. Since the ends of viral genomes may be damaged by cellular RNases, preventing the initiation of viral RNA replication, stable RNA hairpin structures in the 3' NTR may also be essential in host defense against exoribonucleases. During 3'-terminal sequence analysis of serum samples of a patient with chronic hepatitis related to an HCV1b infection, a number of clones were obtained that were several nucleotides shorter at the extreme 3' end of the genome. These shorter 3' ends were engineered in selectable HCV replicons in order to enable the study of RNA replication in cell culture. When in vitro-transcribed subgenomic RNAs, containing shorter 3' ends, were introduced into Huh-7 cells, a few selectable colonies were obtained, and the 3' terminus of these subgenomic RNAs was sequenced. Interestingly, most genomes recovered from these colonies had regained the wild-type 3' ends, showing that HCV, like several other positive-stranded RNA viruses, has developed a strategy to repair deleted 3' end nucleotides. Furthermore, we found several genomes in these replicon colonies that contained a poly(A) tail and a short linker sequence preceding the poly(A) tail. After recloning and subsequent passage in Huh-7 cells, these poly(A) tails persisted and varied in length. In addition, the connecting linker became highly diverse in sequence and length, suggesting that these tails are actively replicated. The possible terminal repair mechanisms, including roles for the poly(A) tail addition, are discussed.     

RNA-RNA recombination in Sindbis virus: roles of the 3' conserved motif, poly(A) tail, and nonviral sequences of template RNAs in polymerase recognition and template switching.

Sindbis virus (SIN), a mosquito-transmitted animal RNA virus, carries a 11.7-kb positive-sense RNA genome which is capped and polyadenylated. We recently reported that the SIN RNA-dependent RNA polymerase (RdRp) could initiate negative-strand RNA synthesis from a 0.3-kb 3'-coterminal SIN RNA fragment and undergo template switching in vivo (M. Hajjou, K. R. Hill, S. V. Subramaniam, J. Y. Hu, and R. Raju, J. Virol. 70:5153-5164, 1996). To identify and characterize the viral and nonviral sequences which regulate SIN RNA synthesis and recombination, a series of SIN RNAs carrying altered 3' ends were tested for the ability to produce infectious virus or to support recombination in BHK cells. The major findings of this report are as follows: (i) the 3'-terminal 20-nucleotides (nt) sequence along with the abutting poly(A) tail of the SIN genome fully supports negative-strand synthesis, genome replication, and template switching; (ii) a full-length SIN RNA carrying the 3'-terminal 24 nt but lacking the poly(A) tail is noninfectious; (iii) SIN RNAs which carry 3' 64 nt or more without the poly(A) tail are infectious and regain their poly(A) tail in vivo; (iv) donor templates lacking the poly(A) tail do not support template switching; (v) full-length SIN RNAs lacking the poly(A) tail but carrying 3' nonviral extensions, although debilitated to begin with, evolve into rapidly growing poly(A)-carrying mutants; (vi) poly(A) or poly(U) motifs positioned internally within the acceptor templates, in the absence of other promoter elements within the vicinity, do not induce the jumping polymerase to reinitiate at these sites; and (vii) the junction site selection on donor templates occurs independently of the sequences around the acceptor sites. In addition to furthering our understanding of RNA recombination, these studies give interesting clues as to how the alphavirus polymerase interacts with its 3' promoter elements of genomic RNA and nonreplicative RNAs. This is the first report that an in vitro-synthesized alphavirus RNA lacking a poly(A) tail can initiate infection and produce 3' polyadenylated viral genome in vivo.     

Host protein interactions with the 3' end of bovine coronavirus RNA and the requirement of the poly(A) tail for coronavirus defective genome replication

RNA viruses have 5' and 3' untranslated regions (UTRs) that contain specific signals for RNA synthesis. The coronavirus genome is capped at the 5' end and has a 3' UTR that consists of 300 to 500 nucleotides (nt) plus a poly(A) tail. To further our understanding of coronavirus replication, we have begun to examine the involvement of host factors in this process for two group II viruses, bovine coronavirus (BCV) and mouse hepatitis coronavirus (MHV). Specific host protein interactions with the BCV 3' UTR [287 nt plus poly(A) tail] were identified using gel mobility shift assays. Competition with the MHV 3' UTR [301 nt plus poly(A) tail] suggests that the interactions are conserved for the two viruses. Proteins with molecular masses of 99, 95, and 73 kDa were detected in UV cross-linking experiments. Less heavily labeled proteins were also detected in the ranges of 40 to 50 and 30 kDa. The poly(A) tail was required for binding of the 73-kDa protein. Immunoprecipitation of UV-cross-linked proteins identified the 73-kDa protein as the cytoplasmic poly(A)-binding protein (PABP). Replication of the defective genomes BCV Drep and MHV MIDI-C, along with several mutants, was used to determine the importance of the poly(A) tail. Defective genomes with shortened poly(A) tails consisting of 5 or 10 A residues were replicated after transfection into helper virus-infected cells. BCV Drep RNA that lacked a poly(A) tail did not replicate, whereas replication of MHV MIDI-C RNA with a deleted tail was detected after several virus passages. All mutants exhibited delayed kinetics of replication. Detectable extension or addition of the poly(A) tail to the mutants correlated with the appearance of these RNAs in the replication assay. RNAs with shortened poly(A) tails exhibited less in vitro PABP binding, suggesting that decreased interactions with the protein may affect RNA replication. The data strongly indicate that the poly(A) tail is an important cis-acting signal for coronavirus replication.     

Native replication intermediates of the yeast 20 S RNA virus have a single-stranded RNA backbone

20 S RNA virus is a positive strand RNA virus found in Saccharomyces cerevisiae. The viral genome (2.5 kb) only encodes its RNA polymerase (p91) and forms a ribonucleoprotein complex with p91 in vivo. A lysate prepared from 20 S RNA-induced cells showed an RNA polymerase activity that synthesized the positive strands of viral genome. When in vitro products, after phenol extraction, were analyzed in a time course, radioactive nucleotides were first incorporated into double-stranded RNA (dsRNA) intermediates and then chased out to the final single-stranded RNA products. The positive and negative strands in these dsRNA intermediates were non-covalently associated, and the release of the positive strand products from the intermediates required a net RNA synthesis. We found, however, that these dsRNA intermediates were an artifact caused by phenol extraction. Native replication intermediates had a single-stranded RNA backbone as judged by RNase sensitivity experiments, and they migrated distinctly from a dsRNA form in non-denaturing gels. Upon completion of RNA synthesis, positive strand RNA products as well as negative strand templates were released from replication intermediates. These results indicate that the native replication intermediates consist of a positive strand of less than unit length and a negative strand template loosely associated, probably through the RNA polymerase p91. Therefore, W, a dsRNA form of 20 S RNA that accumulates in yeast cells grown at 37 degrees C, is not an intermediate in the 20 S RNA replication cycle, but a by-product.     

Interactions of the RNA polymerase with the viral genome at the 5'- and 3'-ends contribute to 20S RNA narnavirus persistence in yeast

20S RNA narnavirus is a positive strand RNA virus found in the yeast Saccharomyces cerevisiae. The viral genome (2514 nucleotides) only encodes a single protein (p91), the RNA-dependent RNA polymerase and does not have capsid proteins to form intracellular virions. The genomic RNA has no 3' poly(A) tail and perhaps no cap structure at the 5'-end; thus resembling an intermediate of mRNA degradation. The virus, however, escapes the host surveillance and replicates in the yeast cytoplasm persistently. The viral genome is not naked but exists in the form of a ribonucleoprotein complex with p91 in a 1:1 stoichiometry. Here we investigated interactions between p91 and the viral genome. Our results indicate that p91 directly or indirectly interacts with the RNA at the 5'- and 3'-end regions and to a lesser extent at a central part. The 3'-end site is identical to or overlaps with the 3' cis signal for replication identified previously. The 5'-site is at the second stem loop structure from the 5'-end (nucleotides 72-104), and this structure also contains a cis signal for replication. Analysis of mutants in the structure revealed a tight correlation between replication and formation of complexes. These results highlight the importance of ribonucleoprotein complexes for the viral life cycle. We will discuss implications of these findings especially on how the virus escapes from mRNA degradation pathways and resides in the cytoplasm persistently despite the lack of a protective capsid.     

Requirements at the 3' end of the sindbis virus genome for efficient synthesis of minus-strand RNA

The 3'-untranslated region of the Sindbis virus genome is 0.3 kb in length with a 19-nucleotide conserved sequence element (3' CSE) immediately preceding the 3'-poly(A) tail. The 3' CSE and poly(A) tail have been assumed to constitute the core promoter for minus-strand RNA synthesis during genome replication; however, their involvement in this process has not been formally demonstrated. Utilizing both in vitro and in vivo analyses, we have examined the role of these elements in the initiation of minus-strand RNA synthesis. The major findings of this study with regard to efficient minus-strand RNA synthesis are the following: (i) the wild-type 3' CSE and the poly(A) tail are required, (ii) the poly(A) tail must be a minimum of 11 to 12 residues in length and immediately follow the 3' CSE, (iii) deletion or substitution of the 3' 13 nucleotides of the 3' CSE severely inhibits minus-strand RNA synthesis, (iv) templates possessing non-wild-type 3' sequences previously demonstrated to support virus replication do not program efficient RNA synthesis, and (v) insertion of uridylate residues between the poly(A) tail and a non-wild-type 3' sequence can restore promoter function to a limited extent. This study shows that the optimal structure of the 3' component of the minus-strand promoter is the wild-type 3' CSE followed a poly(A) tail of at least 11 residues. Our findings also show that insertion of nontemplated bases can restore function to an inactive promoter.     

Addition of poly(adenylic acid) to RNA using polynucleotide phosphorylase: an improved method for electron microscopic visualization of RNA-DNA hybrids.

We have observed that the enzyme polynucleotide phosphorylas from M. luteus or from E. coli will polymerize adenosine (A) from adenosine diphosphate onto 3' ends of RNA molecules. For gene mapping, the poly(A)-tailed RNA is hybridized to its complementary sequence on a longer DNA strand. The position of the poly(A)tail, and thus the position of the 3' end of the RNA on the DNA strand, can then be observed by electron microscopy. Our preferred mapping technique involves the synthesis of a poly(A)-specific label by polymerization of a poly(dBrU) tail onto one or both ends of a linear duplex DNA of defined length (a restriction fragment) and hybridization of this label to the poly(A) tail. In test experiments with a plasmid containing a Drosophila DNA sequence coding for 5S rRNA genes, overall labeling efficiencies of 70--80% were achieved.     

Influenza A virus RNA polymerase has the ability to stutter at the polyadenylation site of a viral RNA template during RNA replication

The viral polymerase of influenza virus, a negative-strand RNA virus, is believed to polyadenylate the mRNAs by stuttering at a stretch of five to seven uridine residues which are located close to the 5' ends of the viral RNA templates. However, a mechanism of polyadenylation based on a template-independent synthesis of the poly(A) tail has not been excluded. In this report, we present new evidence showing the inherent ability of the viral polymerase to stutter at the poly(U) stretch of a viral RNA template during RNA replication. Variants which possess 1- to 13-nucleotide-long insertions at the poly(U) stretch have been identified. These results support a stuttering mechanism for the polyadenylation of influenza virus mRNAs.     

Stimulation of picornavirus replication by the poly(A) tail in a cell-free extract is largely independent of the poly(A) binding protein (PABP)

Picornavirus infectivity is dependent on the RNA poly(A) tail, which binds the poly(A) binding protein (PABP). PABP was reported to stimulate viral translation and RNA synthesis. Here, we studied encephalomyocarditis virus (EMCV) and poliovirus (PV) genome expression in Krebs-2 and HeLa cell-free extracts that were drastically depleted of PABP (96%-99%). Although PABP depletion markedly diminished EMCV and PV internal ribosome entry site (IRES)-mediated translation of a polyadenylated luciferase mRNA, it displayed either no (EMCV) or slight (PV) deleterious effect on the translation of the full-length viral RNAs. Moreover, PABP-depleted extracts were fully competent in supporting EMCV and PV RNA replication and virus assembly. In contrast, removing the poly(A) tail from EMCV RNA dramatically reduced RNA synthesis and virus yields in cell-free reactions. The advantage conferred by the poly(A) tail to EMCV synthesis was more pronounced in untreated than in nuclease-treated extract, indicating that endogenous cellular mRNAs compete with the viral RNA for a component(s) of the RNA replication machinery. These results suggest that the poly(A) tail functions in picornavirus replication largely independent of PABP.     

Long-range RNA-RNA interactions circularize the dengue virus genome

Secondary and tertiary RNA structures present in viral RNA genomes play essential regulatory roles during translation, RNA replication, and assembly of new viral particles. In the case of flaviviruses, RNA-RNA interactions between the 5' and 3' ends of the genome have been proposed to be required for RNA replication. We found that two RNA elements present at the ends of the dengue virus genome interact in vitro with high affinity. Visualization of individual molecules by atomic force microscopy revealed that physical interaction between these RNA elements results in cyclization of the viral RNA. Using RNA binding assays, we found that the putative cyclization sequences, known as 5' and 3' CS, present in all mosquito-borne flaviviruses, were necessary but not sufficient for RNA-RNA interaction. Additional sequences present at the 5' and 3' untranslated regions of the viral RNA were also required for RNA-RNA complex formation. We named these sequences 5' and 3' UAR (upstream AUG region). In order to investigate the functional role of 5'-3' UAR complementarity, these sequences were mutated either separately, to destroy base pairing, or simultaneously, to restore complementarity in the context of full-length dengue virus RNA. Nonviable viruses were recovered after transfection of dengue virus RNA carrying mutations either at the 5' or 3' UAR, while the RNA containing the compensatory mutations was able to replicate. Since sequence complementarity between the ends of the genome is required for dengue virus viability, we propose that cyclization of the RNA is a required conformation for viral replication.     

Polyadenylate sequences of human rhinovirus and poliovirus RNA and cordycepin sensitivity of virus replication.

The polyadenylate [poly(A)] content of the genome RNA of human rhinovirus type 14 (HRV-14) is nearly twice as large as that of the genome RNA of poliovirus type 2. The poly(A) content of viral RNA was determined to be the RNase-resistant fraction of 32P-labeled viral RNA extracted from purified virions. Polyacrylamide gel electrophoresis indicated that the poly(A) sequences of HRV-14 are more heterogenous and on an average larger than those of poliovirus RNA. On the basis of susceptibility to micrococcal polynucleotide phosphorylase the rhinovirus genome terminates in poly(A). Replication of both viruses is almost totally inhibited by cordycepin at 50 mug/ml. At lower concentrations, rhinovirus replication is more sensitive to cordycepin than poliovirus replication. Addition of cordycepin (75 mug/ml) to infected culture prior to or during viral RNA replication results in more or less complete inhibition of virus-specific RNA synthesis. The results do not indicate that cordycepin sensitivity of either virus is due to preferential inhibition of viral poly(A) synthesis by this antibiotic.