Probing the legitimate initiation of RNA synthesis by Qß replicase with oligonucleotide primers.

Oligoribonucleotides complementary to the template 3' terminus were tested for their ability to initiate RNA synthesis on legitimate templates capable of exponential amplification by Qß replicase. Oligonucleotides shorter than the distance to the nearest predicted template hairpin proved able to serve as primers, with the optimal length varying for different templates, suggesting that during initiation the template retains its native fold incorporating the 3' terminus. The priming activity of an oligonucleotide is greatly enhanced by its 5'-triphosphate group, the effect being strongly dependent on Mg2+ ions. This indicates that, unlike other studied RNA polymerases, Qß replicase binds the 5'-triphosphate of the initiating nucleotide GTP, and this binding is needed for the replication of legitimate templates.

Slippage at the initiation of RNA synthesis by Qß replicase results in a periodic polyG pattern.

The repetitive copying of template nucleotides due to transcriptional slippage has not been reported for RNA-directed RNA polymerases of positive-strand RNA phages. We unexpectedly observed that, with GTP as the only substrate, Qß replicase, the RNA-directed RNA polymerase of bacteriophage Qß, synthesizes by transcriptional slippage polyG strands, which on denaturing electrophoresis produce a ladder with at least three clusters of bolder bands. The ≈ 15-nt-long G15 , the major product of the shortest cluster, is tightly bound by the enzyme but can be released by the ribosomal protein S1, which, as a Qß replicase subunit, normally promotes the release of a completed transcript. 7-deaza-GTP suppresses the polyG synthesis and abolishes the periodic pattern, suggesting that the N7 atom is needed for the initiation of RNA synthesis and the formation of the structure recognized by protein S1. The results provide new insights into the mechanism of RNA synthesis by the RNA-directed RNA polymerase of a single-stranded RNA phage.