RNA pseudoknots play important roles in many biological processes. In the simian retrovirus type-1 (SRV-1) a pseudoknot together with a heptanucleotide slippery sequence are responsible for programmed ribosomal frameshifting, a translational recoding mechanism used to control expression of the Gag-Pol polyprotein from overlapping gag and pol open reading frames. Here we present the three-dimensional structure of the SRV-1 pseudoknot determined by NMR. The structure has a classical H-type fold and forms a triple helix by interactions between loop 2 and the minor groove of stem 1 involving base-base and base-sugar interactions and a ribose zipper motif, not identified in pseudoknots so far. Further stabilization is provided by a stack of five adenine bases and a uracil in loop 2, enforcing a cytidine to bulge. The two stems of the pseudoknot stack upon each other, demonstrating that a pseudoknot without an intercalated base at the junction can induce efficient frameshifting. Results of mutagenesis data are explained in context with the present three-dimensional structure. The two base-pairs at the junction of stem 1 and 2 have a helical twist of approximately 49 degrees, allowing proper alignment and close approach of the three different strands at the junction. In addition to the overwound junction the structure is somewhat kinked between stem 1 and 2, assisting the single adenosine in spanning the major groove of stem 2. Geometrical models are presented that reveal the importance of the magnitude of the helical twist at the junction in determining the overall architecture of classical pseudoknots, in particular related to the opening of the minor groove of stem 1 and the orientation of stem 2, which determines the number of loop 1 nucleotides that span its major groove.
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.
From mutational analysis of the 3′-terminal hairpin of turnip yellow mosaic virus (TYMV) RNA and use of nonstructured C-rich RNA templates, we conclude that the main determinant in the tRNA-like structure of TYMV RNA for initiation of minus-strand synthesis by the viral RNA-dependent RNA polymerase (RdRp) is the non-base-paired 3′ ACC(A) end. Base pairing of this 3′ end reduces the transcription efficiency drastically, and deletion of only the 3′-terminal A residue results in a fivefold drop in efficiency. The two C residues of the 3′ ACCA end are required for efficient transcription, as shown by substitution mutations. However, the 5′ A residue is not specifically involved in initiation of transcription, as shown by substitution mutations. Furthermore, the hairpin stem and loop upstream of the 3′ ACCA end also do not interact with the RdRp in a base-specific way. However, for efficient transcription, the hairpin stem should be at least five bp in length, while the calculated ΔG value should be less than −10.5 kcal/mol. Unexpectedly, the use of nonstructured C-rich RNA templates showed that the RdRp can start internally on an NCCN or NUCN sequence. Therefore, a possible function of the tRNA-like structure of TYMV RNA may be to prevent internal initiation of minus-strand synthesis.
In this paper we report on the thermal unfolding of the tRNA-like structure present at the 3' end of turnip yellow mosaic virus (TYMV) RNA. Diethyl pyrocarbonate (DEP), sodium bisulphite, nuclease S1 and ribonuclease T1 were used as structure probes at a broad range of temperatures. In this way most of the nucleotides present in the tRNA-like moiety were analysed. The melting behaviour of both secondary and tertiary interactions could be followed on the basis of the temperature dependent accessibility of the individual nucleotides or bases towards the various probes. The three-dimensional model of the tRNA-like domain (Dumas et al., J. Biomol. Struct. and Dyn. 4, 707 (1987] was supported by the results to a large extent. The interactions occurring between the T- and D-loop appear to be more complex than proposed in the latter model. Additional evidence for the presence of the RNA pseudoknot (Rietveld et al., Nucleic Acids Res. 10, 1929 (1982] was derived from the fact that the three coaxially stacked helical segments in the aminoacylacceptor arm displayed different melting transitions under certain experimental conditions. Aspects of melting behaviour and thermal stability of double helical regions within the tRNA-like structure are discussed, as well as the applicability of nucleases and modifying reagents at various temperatures in the analysis of RNA structure.
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