Mechanistic analysis of RNA synthesis by RNA-dependent RNA polymerase from two promoters reveals similarities to DNA-dependent RNA polymerase.

The brome mosaic virus (BMV) RNA-dependent RNA polymerase (RdRp) directs template-specific synthesis of (-)-strand genomic and (+)-strand subgenomic RNAs in vitro. Although the requirements for (-)-strand RNA synthesis have been characterized previously, the mechanism of subgenomic RNA synthesis has not. Mutational analysis of the subgenomic promoter revealed that the +1 cytidylate and the +2 adenylate are important for RNA synthesis. Unlike (-)-strand RNA synthesis, which required only a high GTP concentration, subgenomic RNA synthesis required high concentrations of both GTP and UTP. Phylogenetic analysis of the sequences surrounding the initiation sites for subgenomic and genomic (+)-strand RNA synthesis in representative members of the alphavirus-like superfamily revealed that the +1 and +2 positions are highly conserved as a pyrimidine-adenylate. GDP and dinucleotide primers were able to more efficiently stimulate (-)-strand synthesis than subgenomic synthesis under conditions of limiting GTP. Oligonucleotide products of 6-, 7-, and 9-nt were synthesized and released by RdRp in 3-20-fold molar excess to full-length subgenomic RNA. Termination of RNA synthesis by RdRp was not induced by template sequence alone. Our characterization of the stepwise mechanism of subgenomic and (-)-strand RNA synthesis by RdRp permits comparisons to the mechanism of DNA-dependent RNA synthesis.

Initiation of (-)-strand RNA synthesis catalyzed by the BMV RNA-dependent RNA polymerase: synthesis of oligonucleotides.

RNA replication, a process of fundamental importance for pathogenesis by many viruses, remains poorly understood at the mechanistic level because relatively few of the responsible enzymes have been purified and characterized biochemically. Partially purified RNA-dependent RNA polymerase (RdRp) from brome mosaic virus (BMV)-infected barley leaves is able to synthesize (-)-strand RNAs from input (+)-strand templates. In resolving RdRp products generated during (-)-strand BMV RNA synthesis, we found that an RNA of eight nucleotides was generated at approximately 10-fold molar excess to the full-length (-)-strand RNA. Production of the 8-mer was dependent upon and specific to BMV RNA templates. Furthermore, inhibitors of full-length (-)-strand RNA synthesis by RdRp also affected the production of the 8-mer. Analysis of the sequence of the 8-mer suggests that it is initiated at the authentic initiation site on the BMV RNA template, consistent with the possibility that the 8-mer is an abortive initiation product of RNA synthesis by RdRp in vitro. Addition of heparin or Mn2+ differentially affected production of the 8-mer and full-length (-)-strand RNA, as did some nucleotide changes near the site of RNA initiation. These studies further define the initiation process of (-)-strand RNA synthesis.