Characterization of chimeric turnip yellow mosaic virus genomes that are infectious in the absence of aminoacylation.

Previous experiments have characterized the chimeric genome TYMC-TMVPSK, in which the 3'-tRNA-like structure of turnip yellow mosaic virus (TYMV) was replaced by 3' sequences from tobacco mosaic virus. This genome accumulated in turnip protoplasts to a level about 3% of wild type, but was not infectious on plants. In the present study, TYMV sequences introduced into the anticodon loop and amino acid acceptor arm of the 3' region of this chimera led to three- to fourfold increases in viral accumulation. Two such modified chimeric genomes gave rise to stable infections in plants. After further passaging in plants and the accumulation of minor sequence changes in the 3' terminal region, the resultant viruses, TYMC-XX and TYMC-YY, were highly infectious. Viral accumulations in protoplasts were about 40% of wild type on the basis of coat protein levels, and virion yields in plants were about 0.1 mg/g leaf. Extensive assays failed to detect aminoacylation of these genomic RNAs in vitro, but they were active substrates for wheat germ. CCA nucleotidyltransferase. In separate experiments, the 3'-tRNA-like structure of TYMV RNA was replaced by the 3' terminal 96 nucleotides from erysimum latent tymovirus RNA, resulting in a genome that was infectious to plants (isolate TYMC-H). This chimeric virus produced similar symptoms and virion yield in plants as TYMC-XX and -YY, although accumulations of coat protein in protoplasts were 13% of wild type. The viral RNA was a poor substrate for CCA nucleotidyltransferase and could not be aminoacylated. TYMC-XX, -YY, and -H are the first TYMV replicons known to amplify efficiently and infect plants in the absence of aminoacylation. Their viability suggests that other properties can compensate for the absence of aminoacylation.

Aminoacylation identity switch of turnip yellow mosaic virus RNA from valine to methionine results in an infectious virus.

The turnip yellow mosaic virus genomic RNA terminates at its 3' end in a tRNA-like structure that is capable of specific valylation. By directed mutation, the aminoacylation specificity has been switched from valine to methionine, a novel specificity for viral tRNA-like structures. The switch to methionine specificity, assayed in vitro under physiological buffer conditions with wheat germ methionyl-tRNA synthetase, required mutation of the anticodon loop and the acceptor stem pseudoknot. The resultant methionylatable genomes are infectious and stable in plants, but genomes that lack strong methionine acceptance (as previously shown with regard to valine acceptance) replicate poorly. The results indicate that amplification of turnip yellow mosaic virus RNA requires aminoacylation, but that neither the natural (valine) specificity nor interaction specifically with valyl-tRNA synthetase is crucial.

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.

Immunodetection, expression strategy and complementation of turnip crinkle virus p28 and p88 replication components.

The plus-sense RNA genome of turnip crinkle virus (TCV) encodes at its 5' end a 28-kDa protein of unspecified function. Readthrough suppression of the p28 stop codon allows for the production of an 88-kDa product which is required for genome replication. Immunological analysis of the expression of p28 and p88 demonstrated that: (i) the genome directs the synthesis of polypeptides of approximately 28 and 88 kDa, (ii) the 88-kDa protein is immunologically related to p28, consistent with p88 being a readthrough product, and (iii) p28, but not p88, is detectable in vivo. An in vivo assay, in which readthrough is linked to the expression of a beta-glucuronidase reporter gene, showed that readthrough of the p28 amber stop codon occurs with an efficiency of approximately 1%. A similar efficiency of readthrough was observed when an altered context from the nonviable TCV mutant, mA2, containing a disrupted secondary structure (FfFa) spanning the p28 termination codon, was tested. This result suggests that the defective phenotype of mA2 is likely not linked to an alteration in readthrough efficiency. Additional studies demonstrated that complementation occurs in coinoculations with two nonviable TCV mutants, RT and APA, which are unable to express either p28 or p88, respectively. This result verifies that p28 is essential for TCV genome replication and provides the first definitive evidence for the role of a 5'-proximal open reading frame for any member of the family Tombusviridae.

Quantitative analysis of the binding of turnip crinkle virus coat protein to RNA fails to demonstrate binding specificity but reveals a highly cooperative assembly interaction.

An element(s) within a 386-nucleotide segment (TCV-386 RNA) of the turnip crinkle virus (TCV) genome was previously implicated in virus assembly nucleation. To localize the proposed high-affinity binding determinants, we analyzed the ability of the coat protein to bind the full-length and truncated derivatives of the TCV-386 RNA using gel retardation and nitrocellulose filter retention assays. Quantitation of the binding data indicated that the coat protein did not preferentially recognize a particular region of the RNA. Moreover, the affinity of the coat protein for the TCV-386 RNA [apparent dissociation constant (Kd) approximately 0.5 microM) did not appreciably differ from its affinity for other comparably sized RNAs tested, including nonviral RNAs. However, the quantitative studies also suggested that the coat protein binds RNA in a cooperative manner and this was supported by evidence that all of the RNAs examined were bound by multiple copies of the coat protein. Based on the number of binding intermediates which could be detected in titrations involving RNAs of different chain length, it appeared that each coat protein binding unit occupies 35-40 nucleotides. Our results demonstrate that encapsidation of TCV RNA results from highly cooperative binding of the coat protein on the large viral genome. However, we were not able to confirm that assembly is mediated by initiation at a high-affinity binding site on the viral RNA.

The signal for a leaky UAG stop codon in several plant viruses includes the two downstream codons.

Expression of the RNA replicase domain of tobacco mosaic virus (TMV) and certain protein-coding regions in other plant viruses, is mediated by translational readthrough of a leaky UAG stop codon. It has been proposed that normal tobacco tyrosine tRNAs are able to read the UAG codon of TMV by non-conventional base-pairing but recent findings that stop codons can also be bypassed as a result of extended translocational shifts (tRNA hopping) have encouraged a re-examination. In light of the alternatives, we investigated the sequences flanking the leaky UAG codon using an in vivo assay in which bypass of the stop codon is coupled to the transient expression of beta-glucuronidase (GUS) reporter genes in tobacco protoplasts. Analysis of GUS constructions in which codons flanking the stop were altered allowed definition of the minimal sequence required for read through as UAG-CAA-UUA. The effects of all possible single-base mutations in the codons flanking the stop indicated that 3' contexts of the form CAR-YYA confer leakiness and that the 3' context permits read through of UAA and UGA stop codons as well as UAG. Our studies demonstrate a major role for the 3' context in the read through process and do not support a model in which teh UAG is bypassed exclusively as a result of anticodon-codon interactions. No evidence for tRNA hopping was obtained. The 3' context apparently represents a unique sequence element that affects translation termination.

Analysis of leaky viral translation termination codons in vivo by transient expression of improved beta-glucuronidase vectors.

Plant RNA viruses commonly exploit leaky translation termination signals in order to express internal protein coding regions. As a first step to elucidate the mechanism(s) by which ribosomes bypass leaky stop codons in vivo, we have devised a system in which readthrough is coupled to the transient expression of beta-glucuronidase (GUS) in tobacco protoplasts. GUS vectors that contain the stop codons and surrounding nucleotides from the readthrough regions of several different RNA viruses were constructed and the plasmids were tested for the ability to direct transient GUS expression. These studies indicated that ribosomes bypass the leaky termination sites at efficiencies ranging from essentially 0 to ca. 5% depending upon the viral sequence. The results suggest that the efficiency of readthrough is determined by the sequence surrounding the stop codon. We describe improved GUS expression vectors and optimized transfection conditions which made it possible to assay low-level translational events.

A family of wheat embryo U2 snRNAs.

Evidence is presented for the existence of small nuclear RNAs in a higher plant species. Based on subcellular fractionation experiments, wheat embryos contain at least four putative snRNAs, one of which co-migrates on SDS-polyacrylamide gels with a relatively abundant cytoplasmic RNA, W1. We purified W1 from ribosome-free high speed supernatant fractions for characterization studies. Electrophoresis under partially denaturing conditions resolves this RNA into several components which bear m3 (2, 2, 7) G-5' caps and strongly resemble vertebrate U2 snRNA on the basis of modified nucleotide content. Preliminary sequence analyses indicate that wheat embryos contain at least three U2-like RNAs which possess slightly different sequences near their 3' ends.

Synthesis of human U1 RNA. II. Identification of two regions of the promoter essential for transcription initiation at position +1.

We have analyzed the requirements for human U1 RNA transcription catalyzed by RNA polymerase II. In Xenopus laevis oocytes, a human U1 RNA gene with only 231 and 35 nucleotides of the 5' and 3' flanking regions, respectively (Lund, E. and Dahlberg, J. E. (1984) J. Biol. Chem. 259, 2013-2021), is able to support accumulation of human U1 RNA. We show that the point in the template corresponding to the 5' end of U1 RNA is a site of transcription initiation. That result rules out the possibility that the 5' end of U1 RNA is generated by cleavage and capping of a precursor RNA. The accumulation of correctly initiated human U1 RNA transcripts requires at least two essential upstream elements. The region between positions -231 and -203 is indispensable for transcription both in oocytes and in vitro. The other region, between positions -105 and -6, fixes the location of the 5' ends of the U1 RNA transcripts in oocytes while not altering the overall level of transcription. This latter region contains a sequence located around position -50, which we propose serves as the analog of the T-A-T-A sequence in U1 and U2 RNA genes.