Sequence of 1000 nucleotides at the 3'' end of tobacco mosaic virus RNA.

The sequence of 1000 nucleotides at the 3' end of tobacco mosaic virus RNA has been determined. The sequence contains the entire coat protein cistron as well as regions to its left and right. Sequence characterization was by conventional methods for use with uniformly 32P labeled RNA complemented by newer methods for in vitro 5' and 3' 32P end-labeling of RNA and its subsequent rapid analysis. The noncoding region separating the coat protein cistron from the 3' terminus is 204 residues long and may be folded into a clover-leaf-type secondary structure. The distribution of termination codons to the left of the coat protein cistron suggests that the end of the adjacent cistron is separated from the beginning of the coat protein cistron by only two nucleotides. The subgenomic viral coat protein mRNA was isolated from infected tissue and shown to be capped. The nontranslated sequence separating the cap from the AUG initiation codon is 9 residues long and thus overlaps a portion of the adjacent cistron on the genome RNA.     

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.     

Electron microscopy of double-stranded RNA induced by turnip yellow mosaic virus and tobacco mosaic virus

Summary Double-stranded RNA isolated by phenol extraction from turnip yellow mosaic virus-infected chinese cabbage leaves and from tobacco mosaic virus-9nfected tobacco leaves was rotary shadowed and examined in the electron microscope. The TYMV and TMV molecules are similar in appearance, having uniform width and a linear configuration similar to that previously described for double-stranded RNA and double-stranded DNA molecules. More than 99.5% of the molecules of each virus fall within the range 0.1 to 2.2 , there being a predominance of smaller molecules in both cases (TYMV mean=0.24 , TMV mean 0.42 ). The mode of the larger molecules of TYMV 1.92 and of TMV 1.8 . These values are close to the expected lengths of whole molecules, calculated from biophysical data. Apparently branched molecules were observed in preparations of both TYMV and TMV double-stranded RNA. It was found, however, that the number of such branches per unit length of RNA decreases with a decrease in density of the RNA in the fields examined.     

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.     

Ionic conditions for the cleavage of the tRNA-like structure of turnip yellow mosaic virus by the catalytic RNA of RNase P

The 3'-end of the RNA genome of turnip yellow mosaic virus can form a pseudoknotted tRNA-like structure that can be recognized by several tRNA-specific enzymes. We have found that the catalytic RNA component of Bacillus subtilis RNase P can cleave this structure in unusually low ionic strength buffers at a site analogous to the 5'-end of an aminoacyl stem of a tRNA. Most other precursors can only be processed under low ionic strength conditions if the RNase P holoenzyme is used; processing by the catalytic RNA component alone requires a higher ionic strength buffer. The cleavage of the turnip yellow mosaic virus tRNA-like structure demonstrates the importance of the substrate in determining the optimal buffer conditions for this reaction and also shows that high ionic strength buffers are not always necessary for cleavage by the catalytic RNA.     

Proteolytic origin of the 150-kilodalton protein encoded by turnip yellow mosaic virus genomic RNA.

Turnip yellow mosaic virus genomic RNA codes in vitro for two overlapping proteins, 150-kilodalton (150K protein) and 206-kilodalton (206K protein) proteins. The proteolytic maturation known to affect the 206K protein has been further characterized by in vitro translation assays in a reticulocyte lysate or wheat germ extract. Cleavage is inhibited at 37 degrees C and restored when the temperature is shifted to 30 or 25 degrees C. Temperature shift experiments are used here to demonstrate that the 150K protein and the previously characterized 78K protein are the two fragments resulting from a primary cleavage phenomenon that affects the 206K protein in a cotranslational manner under usual translation conditions. This processing is prevented by several cysteine and serine proteinase inhibitors.     

3-D graphics modelling of the tRNA-like 3'-end of turnip yellow mosaic virus RNA: structural and functional implications

The tRNA-like structure of the aminoacylatable 3'-end of turnip yellow mosaic virus (TYMV) RNA was submitted to 3-D graphics modelling. A model of this structure has been inferred previously from both biochemical results and sequence comparisons which presents a new RNA folding feature, the "pseudoknot". It has been verified that this structure can be constructed without compromising accepted RNA stereochemical rules, namely base stacking and preferential 3'-endo sugar pucker. The model has aided interpretation of previous structural mapping experiments using chemical and enzymatic probes, and new accessibilities of residues could be predicted and tested. Pseudoknots have been considered as potential splice sites because they form antiparallel helical segments in a single RNA molecule. We have examined this possibility with the constructed 3-D model and could verify the hypothesis on a structural basis. The model presents a striking similarity with canonical tRNA and allows a valuable comparison between the protection patterns of yeast tRNA(Val) and tRNA-like viral RNA by cognate yeast valyl-tRNA synthetase against structural probes.     

Aminoacyl RNA domain of turnip yellow mosaic virus Val-RNA interacting with elongation factor Tu

Turnip yellow mosaic virus (TYMV) Val-RNA forms a complex with the peptide elongation factor Tu (EF-Tu) in the presence of GTP: the Val-RNA is protected by EF-Tu·GTP from non-enzymatic deacylation and nuclease digestion. The determination of the length of the shortest TYMV Val-RNA fragment that binds EF-Tu·GTP leads us to conclude that the valylated aminoacyl RNA domain equivalent in tRNAs to the continuous helix formed by the acceptor stem and the T arm is sufficient for complex formation. Since the aminoacyl RNA domain is also sufficient for adenylation by the ATP(CTP):tRNA nucleotidyltransferase, an analogy can be drawn between these two tRNA-specific proteins.     

Mutational analysis of the pseudoknot in the tRNA-like structure of turnip yellow mosaic virus RNA. Aminoacylation efficiency and RNA pseudoknot stability.

Site-directed mutations were introduced in the connecting loops and one of the two stem regions of the RNA pseudoknot in the tRNA-like structure of turnip yellow mosaic virus RNA. The kinetic parameters of valylation for each mutated RNA were determined in a cell-free extract from wheat germ. Structure mapping was performed on most mutants with enzymic probes, like RNase T1, nuclease S1 and cobra venom ribonuclease. An insertion of four A residues in the four-membered connecting loop L1 that crosses the deep groove of the pseudoknot reduces aminoacylation efficiency. Deletions up to three nucleotides do not affect aminoacylation or RNA pseudoknot formation. Deletion of the entire loop abolishes aminoacylation. Although elimination of the pseudoknot is presumed, this could not be demonstrated. Unlike the mutations in loop L1, all mutations in the three-membered connecting loop L2 that crosses the shallow groove of the RNA pseudoknot decrease the aminoacylation efficiency considerably. Nonetheless, the RNA pseudoknot is still present in most mutated RNAs. These results indicate that a number of mutations can be introduced in both loops without abolishing aminoacylation. Results obtained with the introduction of mismatches and A.U base-pairs in stem S1 of the pseudoknot, containing three G.C base-pairs in wild-type RNA, indicate that the pseudoknot is only marginally stable. Our estimation of the gain of free energy due to the pseudoknot formation is at most 2.0 kcal/mol. The pseudoknot structure can, however, be stabilized upon binding the valyl-tRNA synthetase.     

The 5'' end group of tobacco mosaic virus RNA is m7G5'' ppp5'' Gp.

RNA extracted from CsC1-purified virions of tobacco mosaic virus is shown to give rise to an unusual nucleotide on digestion which RNAase T2, in addition to the four major nucleotides. This minor component has the electrophoretic characteristics of a phosphorylated end group, but is partially resistant to bacterial alkaline phosphatase. It is, however, a substrate for venom phosphodiesterase or nucleotide pyrophosphatase, yielding products which imply the structure m7G5'ppp5'Gp. TMV RNA, like many animal cellular and viral mRNAs recently examined, therefore has a 5' terminus blocked by a methylated nucleotide inverted with respect to the rest of the chain.