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.     

Influenza A virus RNA polymerase has the ability to stutter at the polyadenylation site of a viral RNA template during RNA replication

The viral polymerase of influenza virus, a negative-strand RNA virus, is believed to polyadenylate the mRNAs by stuttering at a stretch of five to seven uridine residues which are located close to the 5' ends of the viral RNA templates. However, a mechanism of polyadenylation based on a template-independent synthesis of the poly(A) tail has not been excluded. In this report, we present new evidence showing the inherent ability of the viral polymerase to stutter at the poly(U) stretch of a viral RNA template during RNA replication. Variants which possess 1- to 13-nucleotide-long insertions at the poly(U) stretch have been identified. These results support a stuttering mechanism for the polyadenylation of influenza virus mRNAs.     

Characterization of the polyadenylation signal of influenza virus RNA.

It has been shown that a stretch of uridines (U's) near the 5' end of the virion RNA of influenza A virus is the polyadenylation site for viral mRNA synthesis. In addition, the RNA duplex made up the 3' and 5' terminal sequences adjacent to the U stretch is also involved in polyadenylation. We have further characterized the polyadenylation signal of influenza virus RNA with a ribonucleoprotein transfection system. We found that the optimal length of the U stretch is 5 to 7 uridine residues. We also showed that the upstream sequence at the 5' end is not involved in polyadenylation and that the optimal distance between the 5' end and the U stretch is 16 nucleotides. The combination of these features defines the polyadenylation site and differentiates this signal from other U stretches scattered throughout the genomes of influenza viruses.