trans regulation of cap-independent translation by a viral subgenomic RNA

Many positive-strand RNA viruses generate 3'-coterminal subgenomic mRNAs to allow translation of 5'-distal open reading frames. It is unclear how viral genomic and subgenomic mRNAs compete with each other for the cellular translation machinery. Translation of the uncapped Barley yellow dwarf virus genomic RNA (gRNA) and subgenomic RNA1 (sgRNA1) is driven by the powerful cap-independent translation element (BTE) in their 3' untranslated regions (UTRs). The BTE forms a kissing stem-loop interaction with the 5' UTR to mediate translation initiation at the 5' end. Here, using reporter mRNAs that mimic gRNA and sgRNA1, we show that the abundant sgRNA2 inhibits translation of gRNA, but not sgRNA1, in vitro and in vivo. This trans inhibition requires the functional BTE in the 5' UTR of sgRNA2, but no translation of sgRNA2 itself is detectable. The efficiency of translation of the viral mRNAs in the presence of sgRNA2 is determined by proximity to the mRNA 5' end of the stem-loop that kisses the 3' BTE. Thus, the gRNA and sgRNA1 have "tuned" their expression efficiencies via the site in the 5' UTR to which the 3' BTE base pairs. We conclude that sgRNA2 is a riboregulator that switches off translation of replication genes from gRNA while permitting translation of structural genes from sgRNA1. These results reveal (i) a new level of control of subgenomic-RNA gene expression, (ii) a new role for a viral subgenomic RNA, and (iii) a new mechanism for RNA-mediated regulation of translation.     

A viral sequence in the 3''-untranslated region mimics a 5'' cap in facilitating translation of uncapped mRNA.

For recognition by the translational machinery, most eukaryotic cellular mRNAs have a 5' cap structure [e.g. m7G(5')ppp(5')N]. We describe a translation enhancer sequence (3'TE) located in the 3'-untranslated region (UTR) of the genome of the PAV barley yellow dwarf virus (BYDV-PAV) which stimulates translation from uncapped mRNA by 30- to 100-fold in vitro and in vivo to a level equal to that of efficient capped mRNAs. A four base duplication within the 3'TE destroyed the stimulatory activity. Efficient translation was recovered by addition of a 5' cap to this mRNA. Translation of both uncapped mRNA containing the 3'TE in cis and capped mRNA lacking any BYDV-PAV sequence was inhibited specifically by added 3'TE RNA in trans. This inhibition was reversed by adding initiation factor 4F (eIF4F), suggesting that the 3'TE, like the 5' cap, mediates eIF4F-dependent translation initiation. The BYDV-PAV 5'UTR was necessary for the 3'TE to function, except when the 3'TE itself was moved to the 5'UTR. Thus, the 3'TE is sufficient for recruiting the translation factors and ribosomes, while the viral 5'UTR may serve only for the long distance 3'-5' communication. Models are proposed to explain this novel mechanism of cap-independent translation initiation facilitated by the 3'UTR.     

Structure and function of a cap-independent translation element that functions in either the 3' or the 5' untranslated region

Barley yellow dwarf virus RNA lacks both a 5' cap and a poly(A) tail, yet it is translated efficiently. It contains a cap-independent translation element (TE), located in the 3' UTR, that confers efficient translation initiation at the AUG closest to the 5' end of the mRNA. We propose that the TE must both recruit ribosomes and facilitate 3'-5' communication. To dissect its function, we determined the secondary structure of the TE and roles of domains within it. Nuclease probing and structure-directed mutagenesis revealed that the 105-nt TE (TE105) forms a cruciform secondary structure containing four helices connected by single-stranded regions. TE105 can function in either UTR in wheat germ translation extracts. A longer viral sequence (at most 869 nt) is required for full cap-independent translation in plant cells. However, substantial translation of uncapped mRNAs can be obtained in plant cells with TE105 combined with a poly(A) tail. All secondary structural elements and most primary sequences that were mutated are required for cap-independent translation in the 3' and 5' UTR contexts. A seven-base loop sequence was needed only in the 3' UTR context. Thus, this loop sequence may be involved only in communication between the UTRs and not directly in recruiting translational machinery. This structural and functional analysis provides a framework for understanding an emerging class of cap-independent translation elements distinguished by their location in the 3' UTR.     

The 3' untranslated region of tobacco necrosis virus RNA contains a barley yellow dwarf virus-like cap-independent translation element

RNAs of many viruses are translated efficiently in the absence of a 5' cap structure. The tobacco necrosis virus (TNV) genome is an uncapped, nonpolyadenylated RNA whose translation mechanism has not been well investigated. Computational analysis predicted a cap-independent translation element (TE) within the 3' untranslated region (3' UTR) of TNV RNA that resembles the TE of barley yellow dwarf virus (BYDV), a luteovirus. Here we report that such a TE does indeed exist in the 3' UTR of TNV strain D. Like the BYDV TE, the TNV TE (i) functions both in vitro and in vivo, (ii) requires additional sequence for cap-independent translation in vivo, (iii) has a similar secondary structure and the conserved sequence CGGAUCCUGGGAAACAGG, (iv) is inactivated by a four-base duplication in this conserved sequence, (v) can function in the 5' UTR, and (vi) when located in its natural 3' location, may form long-distance base pairing with the viral 5' UTR that is conserved and probably required. The TNV TE differs from the BYDV TE by having only three helical domains instead of four. Similar structures were found in all members of the Necrovirus genus of the Tombusviridae family, except satellite tobacco necrosis virus, which harbors a different 3' cap-independent translation domain. The presence of the BYDV-like TE in select genera of different families indicates that phylogenetic distribution of TEs does not follow standard viral taxonomic relationships. We propose a new class of cap-independent TE called BYDV-like TE.     

A Six-Nucleotide Segment within the 3′ Untranslated Region of Hibiscus Chlorotic Ringspot Virus Plays an Essential Role in Translational Enhancement

RNA plant viruses use various translational regulatory mechanisms to control their gene expression. Translational enhancement of viral mRNAs that leads to higher levels of protein synthesis from specific genes may be essential for the virus to successfully compete for cellular translational machinery. The control elements have yet to be analyzed for members of the genus Carmovirus, a small group of plant viruses with positive-sense RNA genomes. In this study, we examined the 3' untranslated region (UTR) of hibiscus chlorotic ringspot virus (HCRSV) genomic RNA (gRNA) and subgenomic RNA (sgRNA) for its role in the translational regulation of viral gene expression. The results showed that the 3' UTR of HCRSV significantly enhanced the translation of several open reading frames on gRNA and sgRNA and a viral gene in a bicistronic construct with an inserted internal ribosome entry site. Through deletion and mutagenesis studies of both the bicistronic construct and full-length gRNA, we demonstrated that a six-nucleotide sequence, GGGCAG, that is complementary to the 3' region of the 18S rRNA and a minimal length of 180 nucleotides are required for the enhancement of translation induced by the 3' UTR.     

Poly(A)-binding protein facilitates translation of an uncapped/nonpolyadenylated viral RNA by binding to the 3' untranslated region

Viruses employ an alternative translation mechanism to exploit cellular resources at the expense of host mRNAs and to allow preferential translation. Plant RNA viruses often lack both a 5' cap and a 3' poly(A) tail in their genomic RNAs. Instead, cap-independent translation enhancer elements (CITEs) located in the 3' untranslated region (UTR) mediate their translation. Although eukaryotic translation initiation factors (eIFs) or ribosomes have been shown to bind to the 3'CITEs, our knowledge is still limited for the mechanism, especially for cellular factors. Here, we searched for cellular factors that stimulate the 3'CITE-mediated translation of Red clover necrotic mosaic virus (RCNMV) RNA1 using RNA aptamer-based one-step affinity chromatography, followed by mass spectrometry analysis. We identified the poly(A)-binding protein (PABP) as one of the key players in the 3'CITE-mediated translation of RCNMV RNA1. We found that PABP binds to an A-rich sequence (ARS) in the viral 3' UTR. The ARS is conserved among dianthoviruses. Mutagenesis and a tethering assay revealed that the PABP-ARS interaction stimulates 3'CITE-mediated translation of RCNMV RNA1. We also found that both the ARS and 3'CITE are important for the recruitment of the plant eIF4F and eIFiso4F factors to the 3' UTR and of the 40S ribosomal subunit to the viral mRNA. Our results suggest that dianthoviruses have evolved the ARS and 3'CITE as substitutes for the 3' poly(A) tail and the 5' cap of eukaryotic mRNAs for the efficient recruitment of eIFs, PABP, and ribosomes to the uncapped/nonpolyadenylated viral mRNA.     

A four-nucleotide translation enhancer in the 3'-terminal consensus sequence of the nonpolyadenylated mRNAs of rotavirus

The 5' cap and poly(A) tail of eukaryotic mRNAs work synergistically to enhance translation through a process that requires interaction of the cap-associated eukaryotic initiation factor, eIF-4G, and the poly(A)-binding protein, PABP. Because the mRNAs of rotavirus, and other members of the Reoviridae, contain caps but lack poly(A) tails, their translation may be enhanced through a unique mechanism. To identify translation-enhancement elements in the viral mRNAs that stimulate translation in vivo, chimeric RNAs were prepared that contained an open reading frame for luciferase and the 5' and 3' untranslated regions (UTRs) of a rotavirus mRNA or of a nonviral mRNA. Transfection of the chimeric RNAs into rotavirus-infected cells showed that the viral 3' UTR contained a translation-enhancement element that promoted gene expression. The element did not enhance gene expression in uninfected cells and did not affect the stability of the RNAs. Mutagenesis showed that the conserved sequence GACC located at the 3' end of rotavirus mRNAs operated as an enhancement element. The 3'-GACC element stimulated protein expression independently of the sequence of the 5' UTR, although efficient expression required the RNA to contain a cap. The results indicate that the expression of viral proteins in rotavirus-infected cells is specifically up-regulated by the activity of a novel 4-nt 3' translation enhancer (TE) common to the 11 nonpolyadenylated mRNAs of the virus. The 4-nt sequence of the rotavirus 3' TE represents by far the shortest of any of the sequence enhancers known to stimulate translation.     

Base-pairing between untranslated regions facilitates translation of uncapped, nonpolyadenylated viral RNA

Translationally competent mRNAs form a closed loop via interaction of initiation factors with the 5' cap and poly(A) tail. However, many viral mRNAs lack a cap and/or a poly(A) tail. We show that an uncapped, nonpolyadenylated plant viral mRNA forms a closed loop by direct base-pairing (kissing) of a stem loop in the 3' untranslated region (UTR) with a stem loop in the 5' UTR. This allows a sequence in the 3' UTR to confer translation initiation at the 5'-proximal AUG. This base-pairing is also required for replication. Unlike other cap-independent translation mechanisms, the ribosome enters at the 5' end of the mRNA. This remarkably long-distance base-pairing reveals a novel mechanism of cap-independent translation and means by which mRNA UTRs can communicate.     

Cap-independent translation mechanism of red clover necrotic mosaic virus RNA2 differs from that of RNA1 and is linked to RNA replication

The genome of Red clover necrotic mosaic virus (RCNMV) in the genus Dianthovirus is divided into two RNA molecules of RNA1 and RNA2, which have no cap structure at the 5' end and no poly(A) tail at the 3' end. The 3' untranslated region (3' UTR) of RCNMV RNA1 contains an essential RNA element (3'TE-DR1), which is required for cap-independent translation. In this study, we investigated a cap-independent translational mechanism of RNA2 using a firefly luciferase (Luc) gene expression assay system in cowpea protoplasts and a cell-free lysate (BYL) prepared from evacuolated tobacco BY2 protoplasts. We were unable to detect cis-acting RNA sequences in RNA2 that can replace the function of a cap structure, such as the 3'TE-DR1 of RNA1. However, the uncapped reporter RNA2, RNA2-Luc, in which the Luc open reading frame (ORF) was inserted between the 5' UTR and the movement protein ORF, was effectively translated in the presence of p27 and p88 in protoplasts in which RNA2-Luc was replicated. Time course experiments in protoplasts showed that the translational activity of RNA2-Luc did not reflect the amount of RNA2. Mutations in cis-acting RNA replication elements of RNA2 abolished the cap-independent translational activity of RNA2-Luc, suggesting that the translational activity of RNA2-Luc is coupled to RNA replication. Our results show that the translational mechanism differs between two segmented genomic RNAs of RCNMV. We present a model in which only RNA2 that is generated de novo through the viral RNA replication machinery functions as mRNA for translation.     

A translational enhancer element on the 3'-proximal end of the Panicum mosaic virus genome

Panicum mosaic virus (PMV) is a single-stranded positive-sense RNA virus in the family Tombusviridae. PMV genomic RNA (gRNA) and subgenomic RNA (sgRNA) are not capped or polyadenylated. We have determined that PMV uses a cap-independent mechanism of translation. A 116-nucleotide translational enhancer (TE) region on the 3'-untranslated region of both the gRNA and sgRNA has been identified. The TE is required for efficient translation of viral proteins in vitro. For mutants with a compromised TE, addition of cap analog, or transposition of the cis-active TE to another location, both restored translational competence of the 5'-proximal sgRNA genes in vitro.     

Cap-independent translational enhancement of turnip crinkle virus genomic and subgenomic RNAs

The presence of translational control elements and cap structures has not been carefully investigated for members of the Carmovirus genus, a group of small icosahedral plant viruses with positive-sense RNA genomes. In this study, we examined both the 5' and 3' untranslated regions (UTRs) of the turnip crinkle carmovirus (TCV) genomic RNA (4 kb) as well as the 5' UTR of the coat protein subgenomic RNA (1.45 kb) for their roles in translational regulation. All three UTRs enhanced translation of the firefly luciferase reporter gene to different extents. Optimal translational efficiency was achieved when mRNAs contained both 5' and 3' UTRs. The synergistic effect due to the 5'-3' cooperation was at least fourfold greater than the sum of the contributions of the individual UTRs. The observed translational enhancement of TCV mRNAs occurred in a cap-independent manner, a result consistent with the demonstration, using a cap-specific antibody, that the 5' end of the TCV genomic RNA was uncapped. Finally, the translational enhancement activity within the 5' UTR of 1.45-kb subgenomic RNA was shown to be important for the translation of coat protein in protoplasts and for virulent infection in Arabidopsis plants.     

Structure and function of the non-coding regions of hepatitis C viral RNA

At the 5' and 3' end of genomic HCV RNA there are two highly conserved, untranslated regions, 5'UTR and 3'UTR. These regions are organized into spatially ordered structures and they play key functions in regulation of processes of the viral life cycle. Most nucleotides of the region located at the 5' side of the coding sequence serve as an internal ribosomal entry site, IRES, which directs cap-independent translation. The RNA fragment present at the 3' end of the genome is required for virus replication and probably contributes to translation of viral proteins. During virus replication its genomic strand is transcribed into a strand of minus polarity, the replicative strand. Its 3' terminus is responsible for initiation of synthesis of descendant genomic strands. This article summarizes our current knowledge on the structure and function of the non-coding regions of hepatitis C genomic RNA, 5'UTR and 3'UTR, and the complementary sequences of the replicative viral strand.     

Conservation of RNA structures enables TNV and BYDV 5' and 3' elements to cooperate synergistically in cap-independent translation

The subgenomic RNA 2 of tobacco necrosis virus A (TNV sgRNA2) encodes the viral coat protein, is unpolyadenylated and presumably uncapped. Here, we show that TNV sgRNA2 is translated cap independently. This cap-independent translation requires the leader and a 140 nt element of the trailer both in wheat germ extract and in tobacco protoplasts. Similar to barley yellow dwarf virus (BYDV), the TNV 5′ and 3′ elements stimulate translation synergistically. Computer-aided phylogenetic analysis of the secondary structure of the TNV trailer revealed that the 3′ translation element is part of a major conserved stem–loop that contains similarities to structures in the BYDV 3′ translation element. These data suggest that the translation mechanisms of TNV sgRNA2 and BYDV RNA are related. To further characterize this relationship, we tested whether cooperativity exists between TNV sgRNA2 and BYDV 5′ and 3′ elements. We found that the TNV sgRNA2 5′ element stimulates translation synergistically with the BYDV 3′ element in vitro. This finding is the first evidence for conservation of structures that enable a 5′–3′ interaction stimulating cap-independent translation.     

Mechanism of plant eIF4E-mediated resistance against a Carmovirus (Tombusviridae): cap-independent translation of a viral RNA controlled in cis by an (a)virulence determinant

Translation initiation factors are universal determinants of plant susceptibility to RNA viruses, but the underlying mechanisms are poorly understood. Here, we show that a sequence in the 3' untranslated region (3'-UTR) of a viral genome that is responsible for overcoming plant eIF4E-mediated resistance (virulence determinant) functions as a 3' cap-independent translational enhancer (3'-CITE). The virus/plant pair studied here is Melon necrotic spot virus (MNSV) and melon, for which a recessive resistance controlled by melon eIF4E was previously described. Chimeric viruses between virulent and avirulent isolates enabled us to map the virulence and avirulence determinants to 49 and 26 nucleotides, respectively. The translational efficiency of a luc reporter gene flanked by 5'- and 3'-UTRs from virulent, avirulent and chimeric viruses was analysed in vitro, in wheatgerm extract, and in vivo, in melon protoplasts, showing that: (i) the virulence determinant mediates the efficient cap-independent translation in vitro and in vivo; (ii) the avirulence determinant was able to promote efficient cap-independent translation in vitro, but only when eIF4E from susceptible melon was added in trans, and, coherently, only in protoplasts of susceptible melon, but not in the protoplasts of resistant melon; (iii) these activities required the 5'-UTR of MNSV in cis. Thus, the virulence and avirulence determinants function as 3'-CITEs. The activity of these 3'-CITEs was host specific, suggesting that an inefficient interaction between the viral 3'-CITE of the avirulent isolate and eIF4E of resistant melon impedes the correct formation of the translation initiation complex at the viral RNA ends, thereby leading to resistance.     

Identification and Characterization of the Functional Elements within the Tobacco Etch Virus 5′ Leader Required for Cap-Independent Translation

Translation in plants is highly cap dependent, and the only plant mRNAs known to naturally lack a cap structure (m(7)GpppN) are viral in origin. The genomic RNA of tobacco etch virus (TEV), a potyvirus that belongs to the picornavirus superfamily, is a polyadenylated mRNA that is naturally uncapped and yet is a highly competitive mRNA during translation. The 143-nucleotide 5' leader is responsible for conferring cap-independent translation even on reporter mRNAs. We have carried out a deletion analysis of the TEV 5' leader to identify the elements responsible for its regulatory function and have identified two centrally located cap-independent regulatory elements (CIREs) that promote cap-independent translation. The introduction of a stable stem-loop structure upstream of each element demonstrated that CIRE-1 is less 5' end dependent in function than CIRE-2. In a dicistronic mRNA, the presence of the TEV 5' leader sequence in the intercistronic region increased expression of the second cistron, suggesting that the viral sequence can function in a 5'-distal position. Interestingly, the introduction of a stable stem-loop upstream of the TEV leader sequence or upstream of either CIRE in dicistronic constructs markedly increased their regulatory function. These data suggest that the TEV 5' leader contains two elements that together promote internal initiation but that the function of one element, in particular, is facilitated by proximity to the 5' end.     

A 3' UTR sequence stabilizes termination codons in the unspliced RNA of Rous sarcoma virus

Eukaryotic cells target mRNAs to the nonsense-mediated mRNA decay (NMD) pathway when translation terminates within the coding region. In mammalian cells, this is presumably due to a downstream signal deposited during pre-mRNA splicing. In contrast, unspliced retroviral RNA undergoes NMD in chicken cells when premature termination codons (PTCs) are present in the gag gene. Surprisingly, deletion of a 401-nt 3' UTR sequence immediately downstream of the normal gag termination codon caused this termination event to be recognized as premature. We termed this 3' UTR region the Rous sarcoma virus (RSV) stability element (RSE). The RSE also stabilized the viral RNA when placed immediately downstream of a PTC in the gag gene. Deletion analysis of the RSE indicated a smaller functional element. We conclude that this 3' UTR sequence stabilizes termination codons in the RSV RNA, and termination codons not associated with such an RSE sequence undergo NMD.