Specific site selection in RNA resulting from a combination of nonspecific secondary structure and -CCR- boxes: initiation of minus strand synthesis by turnip yellow mosaic virus RNA-dependent RNA polymerase

A turnip yellow mosaic virus RNA-dependent RNA polymerase activity was used to study the template requirements for in vitro minus strand synthesis, which is initiated specifically opposite the 3'-CCA that terminates the 3'-tRNA-like structure. A deletion survey confirmed earlier results suggesting the absence of minus strand promoter elements upstream of the pseudoknotted acceptor stem and 3'-terminus. Reiteration of this 27-nt domain provided two competing initiation sites. By varying the added downstream element, it was shown that the pseudoknotted domain could be functionally replaced by various simple stem/loops, although with some decrease in activity. The addition of varying numbers of consecutive -CCA- triplets to the 3' end of the tRNA-like structure resulted in accurate initiation from each added triplet. A similar spectrum of initiations occurred with an unstructured RNA consisting of 12 consecutive -CCA- triplets and no additional viral sequence. Substitution mutations revealed no influence on minus strand synthesis of the identity of the nucleotide immediately upstream of a -CC- initiation site, but a preference for a purine immediately downstream. The introduction of secondary structure into the linear template showed that the usage of potential -CCR- initiation sites is influenced by nonspecific secondary structure. We conclude that specificity arises from the requirement that a -CCR- sequence be sterically accessible. This mechanism is only applicable to interactions that do not involve RNA unwinding during site selection, but may be used commonly in positive strand RNA virus replication and be applicable to other RNA-protein interactions.     

cis-Acting signals involved in termination of vesicular stomatitis virus mRNA synthesis include the conserved AUAC and the U7 signal for polyadenylation

We investigated the cis-acting sequences involved in termination of vesicular stomatis virus mRNA synthesis by using bicistronic genomic analogs. All of the cis-acting signals necessary for termination reside within the first 13 nucleotides of the 23-nucleotide conserved gene junction. This 13-nucleotide termination sequence at the end of the upstream gene comprises the tetranucleotide AUAC, the tract containing seven uridines (U7 tract), and the intergenic dinucleotide (GA), but it does not include the downstream gene start sequence. Data presented here show that upstream mRNA termination is independent of downstream mRNA initiation. Alteration of any nucleotide in the 13-nucleotide sequence decreased the termination activity of the gene junction and resulted in increased synthesis of a bicistronic readthrough RNA. This finding indicated that the wild-type gene junction has evolved to achieve the maximum termination efficiency. The most critical position of the AUAC sequence was the C, which could not be altered without complete loss of mRNA termination. Reducing the length of the wild-type U7 tract to zero, five, or six U residues also totally abolished mRNA termination, resulting in exclusive synthesis of the bicistronic readthrough mRNA. Shortening the wild-type U7 tract to either five or six U residues abolished VSV polymerase slippage during readthrough RNA synthesis. Since neither the U5 nor U6 template was able to direct mRNA termination, these data imply that polymerase slippage is a prerequisite for termination. Evidence is also presented to show that in addition to causing polymerase slippage, the U7 tract itself or its poly(A) product constitutes an essential signal for mRNA termination.     

Interdependence between DNA template secondary structure and priming efficiencies of short primers

Here we analyze the effect of DNA folding on the performance of short primers and describe a simple technique for assessing hitherto uncertain values of thermodynamic parameters that determine the folding of single-stranded DNA into secondary structure. An 8mer with two degenerate positions is extended simultaneously at several complementary sites on a known template (M13mp18) using one, two or three (but never all four) of the possible dNTPs. The length of the extension is site specific because it is limited by the first occurrence in the downstream template sequence of a base whose complementary dNTP is not present. The relative priming efficiencies of different sites are then ranked by comparing their band brightnesses on a gel. The priming efficiency of a short primer (unlike conventional long primers) depends dramatically on the secondary structure of the template at and around the priming site. We calculated the secondary structure and its effect on priming using a simple model with relatively few parameters which were then optimized to achieve the best match between the predictions and the actual rankings of the sites in terms of priming efficiency. This work introduces an efficient and conceptually novel approach that in the future can make use of more data to optimize a larger set of DNA folding parameters in a more refined model. The model we used, however crude it may be, significantly improved the prediction of priming efficiencies of 8mer primers and appreciably raised the success rate of our DNA sequencing technique (from 67 to 91% with a significance of P < 7 x 10(-5)), which uses such primers.     

Peak height pattern in dichloro-rhodamine and energy transfer dye terminator sequencing

Establishing the pattern in peak heights within local sequence contexts improves the accuracy of base calling and the identification of DNA sequence variations in dye-terminator cycle sequencing. We have systematically examined pairs of sequence-tagged sites (STSs) that vary at only a single nucleotide to determine how base changes influence the peak heights of neighboring bases in sequencing traces generated by two recently commercialized dye-terminator chemistries, the dichloro-rhodamine (dRhodamine) and the energy transfer (BigDye) terminators. For sequencing traces generated with the dRhodamine terminators, the peak height of a particular base in 28 of 64 possible 3-base windows (44%) can be predicted by knowing just one or two bases 5' to the base in question. For those generated with the BigDye terminators, the peak height of a particular base in 23 of 64 possible 3-base windows (36%) can be predicted by knowing the local sequence context. When the peak heights are binned slightly differently, 75% (48 out of 64 cases) of the base peaks generated by both dRhodamine and BigDye terminators fall in the middle half, confirming that the peak patterns of these two new dye terminator chemistries are much more even than those found in the original rhodamine dye terminator sequences.