Eukaryotic elongation factor 1A interacts with the upstream pseudoknot domain in the 3' untranslated region of tobacco mosaic virus RNA

The genomic RNA of tobacco mosaic virus (TMV), like that of other positive-strand RNA viruses, acts as a template for both translation and replication. The highly structured 3' untranslated region (UTR) of TMV RNAs plays an important role in both processes; it is not polyadenylated but ends with a tRNA-like structure (TLS) preceded by a conserved upstream pseudoknot domain (UPD). The TLS of tobamoviral RNAs can be specifically aminoacylated and, in this state, can interact with eukaryotic elongation factor 1A (eEF1A)/GTP with high affinity. Using a UV cross-linking assay, we detected another specific binding site for eEF1A/GTP, within the UPDs of TMV and crucifer-infecting tobamovirus (crTMV), that does not require aminoacylation. A mutational analysis revealed that UPD pseudoknot conformation and some conserved primary sequence elements are required for this interaction. Its possible role in the regulation of tobamovirus gene expression and replication is discussed.     

The turnip yellow mosaic virus tRNA-like structure cannot be replaced by generic tRNA-like elements or by heterologous 3' untranslated regions known to enhance mRNA expression and stability.

The tRNA-like structure (TLS) at the 3' end of the turnip yellow mosaic virus genome was replaced with heterologous tRNA-like elements, and with a poly(A) tail, in order to assess its role. Replacement with the valylatable TLSs from two closely related tymoviruses resulted in infectious viruses. In contrast, no systemic symptoms on plants, and only low viral accumulations in protoplasts, were observed for three chimeric genomes with 3' sequences known to enhance mRNA stability and translatability. One of these chimeras had a poly(A) tail, and the others had the TLS with associated upstream pseudoknot tracts from the 3' ends of brome mosaic and tobacco mosaic viruses. The latter two chimeric RNAs were shown to be appropriately folded by demonstrating their aminoacylation in vitro with tyrosine and histidine, respectively. The results show that enhancement of genome stability or gene expression is not the major role of the turnip yellow mosaic virus TLS. The major role is likely to be replicational, dependent on features present in tymoviral TLSs but not in generic tRNA-like structures.     

tRNA-like properties of tobacco rattle virus RNA.

The 3' terminal forty nucleotides of tobraviral RNAs readily fold into a tertiary structure, resembling that of tymo- and tobamoviral RNAs. The latter RNAs possess a tRNA-like structure at their 3' end that is recognized by a number of tRNA-specific enzymes (Rietveld et al. (1984), EMBO J. 3, 2613-2619). Characteristic for their aminoacyl acceptor arm is the presence of a so-called pseudoknot which we now also find in a corresponding position at the 3' terminus of TRV RNA2 (PSG strain). The nucleotide sequences of all tobraviral RNAs analysed so far indicate that they all possess a similar 3' terminal structure. A domain resembling the anticodon arm of canonical tRNA is not readily recognizable. TRV RNA2 can be adenylated with CTP, ATP; tRNA nucleotidyl transferase and ATP. It is unable, however, to accept any of the twenty common amino acids when incubated with ATP and aminoacyl-tRNA synthetases from wheat germ or yeast. We conclude that TRV RNA contains a tRNA-like structure, which, in contrast to the tymo- and tobamoviral tRNA-like structures, cannot be aminoacylated. It is unlikely therefore, that aminoacylation of plant viral RNAs with a tRNA-like structure is a prerequisite for viral RNA replication.     

Interaction between the cellular protein eEF1A and the 3'-terminal stem-loop of West Nile virus genomic RNA facilitates viral minus-strand RNA synthesis

RNase footprinting and nitrocellulose filter binding assays were previously used to map one major and two minor binding sites for the cell protein eEF1A on the 3'(+) stem-loop (SL) RNA of West Nile virus (WNV) (3). Base substitutions in the major eEF1A binding site or adjacent areas of the 3'(+) SL were engineered into a WNV infectious clone. Mutations that decreased, as well as ones that increased, eEF1A binding in in vitro assays had a negative effect on viral growth. None of these mutations affected the efficiency of translation of the viral polyprotein from the genomic RNA, but all of the mutations that decreased in vitro eEF1A binding to the 3' SL RNA also decreased viral minus-strand RNA synthesis in transfected cells. Also, a mutation that increased the efficiency of eEF1A binding to the 3' SL RNA increased minus-strand RNA synthesis in transfected cells, which resulted in decreased synthesis of genomic RNA. These results strongly suggest that the interaction between eEF1A and the WNV 3' SL facilitates viral minus-strand synthesis. eEF1A colocalized with viral replication complexes (RC) in infected cells and antibody to eEF1A coimmunoprecipitated viral RC proteins, suggesting that eEF1A facilitates an interaction between the 3' end of the genome and the RC. eEF1A bound with similar efficiencies to the 3'-terminal SL RNAs of four divergent flaviviruses, including a tick-borne flavivirus, and colocalized with dengue virus RC in infected cells. These results suggest that eEF1A plays a similar role in RNA replication for all flaviviruses.     

Selection of viral RNA-derived tRNA-like structures with improved valylation activities

The tRNA-like structure (TLS) of turnip yellow mosaic virus (TYMV) RNA was previously shown to be efficiently charged by yeast valyl-tRNA synthetase (ValRS). This RNA has a noncanonical structure at its 3'-terminus but mimics a tRNA L-shaped fold, including an anticodon loop containing the major identity nucleotides for valylation, and a pseudoknotted amino acid accepting domain. Here we describe an in vitro selection experiment aimed (i) to verify the completeness of the valine identity set, (ii) to elucidate the impact of the pseudoknot on valylation, and (iii) to investigate whether functional communication exists between the two distal anticodon and amino acid accepting domains. Valylatable variants were selected from a pool of 2 x 10(13) RNA molecules derived from the TYMV TLS randomized in the anticodon loop nucleotides and in the length (1-6 nucleotides) and sequence of the pseudoknot loop L1. After nine rounds of selection by aminoacylation, 42 have been isolated. Among them, 17 RNAs could be efficiently charged by yeast ValRS. Their sequence revealed strong conservation of the second and the third anticodon triplet positions (A(56), C(55)) and the very 3'-end loop nucleotide C(53). A large variability of the other nucleotides of the loop was observed and no wild-type sequence was recovered. The selected molecules presented pseudoknot domains with loop L1 varying in size from 3-6 nucleotides and some sequence conservation, but did neither reveal the wild-type combination. All selected variants are 5-50 times more efficiently valylated than the wild-type TLS, suggesting that the natural viral sequence has emerged from a combination of evolutionary pressures among which aminoacylation was not predominant. This is in line with the role of the TLS in viral replication.     

The three-dimensional folding of the tRNA-like structure of tobacco mosaic virus RNA. A new building principle applied twice

The structure of the tRNA-like 3' terminus of tobacco mosaic virus (TMV) RNA has been studied. A 3' -terminal fragment possessing the tRNA-like properties was probed with chemical modification and enzymatic digestions. A model of the secondary structure is proposed for the last 105 nucleotides. The corresponding region of other tobamoviral RNAs can be folded in an identical secondary structure. A three-dimensional model for the tRNA-like structure is given which is compared with those proposed earlier for the tRNA-like 3' termini of turnip yellow mosaic virus (TYMV) RNA and brome mosaic virus (BMV) RNA. A new building principle which we discovered previously by studying the latter RNAs appears to be applied twice in the tRNA-like structure of TMV RNA. The determination of the minimal length requirement for recognition of CTP, ATP:tRNA nucleotidyl-transferase reveals a size of ˜100 nucleotides in agreement with the models proposed.     

Comparison and functional implications of the 3D architectures of viral tRNA-like structures

RNA viruses co-opt the host cell's biological machinery, and their infection strategies often depend on specific structures in the viral genomic RNA. Examples are tRNA-like structures (TLSs), found at the 3′ end of certain plant viral RNAs, which can use the cell's aminoacyl tRNA-synthetases (AARSs) to drive addition of an amino acid to the 3′ end of the viral RNA. TLSs are multifunctional RNAs involved in processes such as viral replication, translation, and viral RNA stability; these functions depend on their fold. Experimental result-based structural models of TLSs have been published. In this study, we further examine these structures using a combination of biophysical and biochemical approaches to explore the three-dimensional (3D) architectures of TLSs from the turnip yellow mosaic virus (TYMV), tobacco mosaic virus (TMV), and brome mosaic virus (BMV). We find that despite similar function, these RNAs are biophysically diverse: the TYMV TLS adopts a characteristic tRNA-like L shape, the BMV TLS has a large compact globular domain with several helical extensions, and the TMV TLS aggregates in solution. Both the TYMV and BMV TLS RNAs adopt structures with tight backbone packing and also with dynamic structural elements, suggesting complexities and subtleties that cannot be explained by simple tRNA mimicry. These results confirm some aspects of existing models and also indicate how these models can be improved. The biophysical characteristics of these TLSs show how these multifunctional RNAs might regulate various viral processes, including negative strand synthesis, and also allow comparison with other structured RNAs.     

Turnip yellow mosaic virus RNAs with anticodon loop substitutions that result in decreased valylation fail to replicate efficiently.

Single and multiple nucleotide substitutions have been introduced into the anticodon loop of the tRNA-like structure of turnip yellow mosaic virus (TYMV) genomic RNA. We studied the effects of these mutations on in vitro valylation and on replication in Chinese cabbage protoplasts and plants. Only those mutants capable of efficient and complete valylation showed efficient replication in protoplasts and gave rise to systemic symptoms in whole plants. Mutants that accepted valine inefficiently (in some cases Vmax/Km values were less than 10(-3) relative to wild-type values) replicated to levels 200- to 500-fold below wild-type levels in protoplasts (estimated on the basis of coat protein and genomic RNA levels). These mutants could not support systemic spread in plants. In one plant inoculated with TYMC-A55 RNA, which replicates poorly in protoplasts, systemic symptoms developed after a delay. The reversion in replication was accompanied by improved valine acceptance and the appearance of a U57 second-site mutation. Our results indicate a correlation between valine acceptance activity and viral yield. Possible roles for valylation are discussed, and the results are compared with those of similar studies with brome mosaic virus which suggested that tyrosylation is not crucial for brome mosaic virus replication (T. W. Dreher, A. L. N. Rao, and T. C. Hall, J. Mol. Biol. 206:425-438, 1989).     

The valine anticodon and valylatability of Peanut clump virus RNAs are not essential but provide a modest competitive advantage in plants

The role of valine aminoacylation of the two genomic RNAs of Peanut clump virus (PCV) was studied by comparing the amplification in vivo of RNAs with GAC, GDeltaC, or CCA anticodons in the tRNA-like structure (TLS) present at the 3' end of each viral RNA. The PCV RNA1 TLS of isolate PCV2 possesses a GAC anticodon and is capable of highly efficient valylation, whereas the RNA2 TLS has a GDeltaC anticodon that does not support valylation. The presence in RNA1 of GDeltaC or CCA anticodons that conferred nonvalylatability resulted in about 2- to 4-fold and a 14- to 24-fold reduction, respectively, in RNA accumulations in tobacco BY-2 protoplasts inoculated with the RNA1 variants together with wild-type RNA2(GDeltaC). No differences in RNA levels were observed among protoplasts inoculated with the three variant RNA2s in the presence of wild-type RNA1(GAC). All combinations of valylatable and nonvalylatable RNAs 1 and 2 were similarly infectious in Nicotiana benthamiana plants, and viral RNAs accumulated to similar levels; all input TLS sequences were present unchanged in apical leaves. In direct competition experiments in N. benthamiana plants, however, both RNA1 and RNA2 with GAC valylatable anticodons outcompeted the nonvalylatable variants. We conclude that valylation provides a small but significant replicational advantage to both PCV RNAs. Sequence analysis of the TLS from RNA2 of a second PCV isolate, PO2A, revealed the presence of an intact GAC valine anticodon, suggesting that the differential valylation of the genomic RNAs of isolate PCV2 is not a general characteristic of PCV.     

Modulation of replication, aminoacylation and adenylation in vitro and infectivity in vivo of BMV RNAs containing deletions within the multifunctional 3'' end.

The genome of brome mosaic virus (BMV) is comprised of three (+) strand RNAs, each containing a similar, highly structured, 200 base long sequence at its 3' end. A 134 base subset of this sequence contains signals directing interaction of the viral RNA with BMV RNA replicase, ATP,CTP:tRNA nucleotidyl transferase and aminoacyl tRNA synthetase. A series of mutants containing deletions within this region, previously constructed and tested in vitro for the effect on replication and aminoacylation activities, has now been assayed in vitro for adenylation function and in vivo for ability to replicate in isolated protoplasts and whole plants. These tests indicate that features of viral RNA recognized by BMV replicase overlap those directing adenylation, but are distinct from those directing aminoacylation. Consequently, the lethality of a deletion preferentially inhibiting aminoacylation suggests that this function may have an essential role contributing to viral replication in vivo. An RNA3 mutant bearing a 20-base deletion yielding normal levels of aminoacylation and enhanced levels of replicase template activity and adenylation in vitro was able to replicate in protoplasts and plants; however, its accumulation in protoplasts was reduced relative to wild-type. This suggests that additional functions affecting the replication and accumulation of viral RNA reside in the conserved 3' sequence.     

The tRNA-like structure at the 3' terminus of turnip yellow mosaic virus RNA. Differences and similarities with canonical tRNA.

The 3' terminus of TYMV RNA, which possesses tRNA-like properties, has been studied. A 3' terminal fragment of 112 nucleotides was obtained by cleavage with RNase H after hybridization of a synthetic oligodeoxynucleotide to the viral RNA. The accessibility of cytidine and adenosine residues was probed with chemical modification. Enzymatic digestion studies were performed with RNase T1, nuclease S1 and the double-strand specific RNase from the venom of the cobra Naja naja oxiana. A model is proposed for the secondary structure of the 3' terminal region of TYMV RNA comprising 86 nucleotides. The main feature of this secondary structure is the absence of a conventional acceptor stem as present in canonical tRNA. However, the terminal 42 nucleotides can be folded in a tertiary structure which bears strong resemblance with the acceptor arm of canonical tRNA. Comparison of this region of TYMV RNA with that of other RNAs from both the tymovirus group and the tobamovirus group gives support to our proposal for such a three-dimensional arrangement. The consequences for the recognition by TYMV RNA of tRNA-specific enzymes is discussed.     

Second-site suppressor mutations assist in studying the function of the 3'' noncoding region of turnip yellow mosaic virus RNA.

The 3' noncoding region of turnip yellow mosaic virus RNA includes an 82-nucleotide-long tRNA-like structure domain and a short upstream region that includes a potential pseudoknot overlapping the coat protein termination codon. Genomic RNAs with point mutations in the 3' noncoding region that result in poor replication in protoplasts and no systemic symptoms in planta were inoculated onto Chinese cabbage plants in an effort to obtain second-site suppressor mutations. Putative second-site suppressor mutations were identified by RNase protection and sequencing and were then introduced into genomic cDNA clones to permit their characterization. A C-57----U mutation in the tRNA-like structure was a strong suppressor of the C-55----A mutation which prevented both systemic infection and in vitro valylation of the viral RNA. Both of these phenotypes were rescued in the double mutant. An A-107----C mutation was a strong second-site suppressor of the U-96----G mutation, permitting the double mutant to establish systemic infection. The C-107 and G-96 mutations are located on opposite strands of one helix of a potential pseudoknot, and the results support a functional role for the pseudoknot structure. A mutation near the 5' end of the genome (G + 92----A), at position -3 relative to the initiation codon of the essential open reading frame 206, was found to be a general potentiator of viral replication, probably as a result of enhanced expression of open reading frame 206. The A + 92 mutation enhanced the replication of mutant TYMC-G96 in protoplasts but was not a sufficiently potent suppressor to permit systemic spread of the A + 92/G-96 double mutant in plants.     

Mutations in the 5' nontranslated region of bovine viral diarrhea virus result in altered growth characteristics

The 5' nontranslated region (NTR) of pestiviruses functions as an internal ribosome entry site (IRES) that mediates cap-independent translation of the viral polyprotein and probably contains additional cis-acting RNA signals involved in crucial processes of the viral life cycle. Computer modeling suggests that the 5'-terminal 75 nucleotides preceding the IRES element form two stable hairpins, Ia and Ib. Spontaneous and engineered mutations located in the genomic region comprising Ia and Ib were characterized by using infectious cDNA clones of bovine viral diarrhea virus. Spontaneous 5' NTR mutations carrying between 9 and 26 A residues within the loop region of Ib had no detectable influence on specific infectivity and virus growth properties. After tissue culture passages, multiple insertions and deletions of A residues occurred rapidly. In contrast, an engineered mutant carrying 5 A residues within the Ib loop was genetically stable during 10 tissue culture passages. This virus was used as starting material to generate a number of additional mutants. The analyses show that (i) deletion of the entire Ib loop region resulted in almost complete loss of infectivity that was rapidly restored during passages in cell culture by insertions of variable numbers of A residues; (ii) mutations within the 5'-terminal 4 nucleotides of the genomic RNA severely impaired virus replication; passaging of the supernatants obtained after transfection resulted in the emergence of efficiently replicating mutants that had regained the conserved 5'-terminal sequence; (iii) provided the conserved sequence motif 5'-GUAU was retained at the 5' end of the genomic RNA, substitutions and deletions of various parts of hairpin Ia or deletion of all of Ia and part of Ib were found to support replication, but to a lower degree than the parent virus. Restriction of specific infectivity and virus growth of the 5' NTR mutants correlated with reduced amounts of accumulated viral RNAs.     

A conformational switch at the 3' end of a plant virus RNA regulates viral replication.

3' untranslated regions of alfamo- and ilar-virus RNAs fold into a series of stem-loop structures to which the coat protein binds with high affinity. This binding plays a role in initiation of infection ('genome activation') and has been thought to substitute for a tRNA-like structure that is found at the 3' termini of related plant viruses. We propose the existence of an alternative conformation of the 3' ends of alfamo- and ilar-virus RNAs, including a pseudoknot. Based on (i) phylogenetic comparisons, (ii) in vivo and in vitro functional analyses of mutants in which the pseudoknot has been disrupted or restored by compensatory mutations, (iii) competition experiments between coat protein and viral replicase, and (iv) investigation of the effect of magnesium, we demonstrate that this pseudoknot is required for replication of alfalfa mosaic virus. This conformation resembles the tRNA-like structure of the related bromo- and cucumo-viruses. A low but specific interaction with yeast CCA-adding enzyme was found. The existence of two mutually exclusive conformations for the 3' termini of alfamo- and ilar-virus RNAs could enable the virus to switch from translation to replication and vice versa. The role of coat protein in this modulation and in genome activation is discussed.