Abstract
In positive-strand RNA viruses, 5' untranslated regions (5' UTRs) mediate many essential viral processes, including genome replication. Previously, we proposed that the 5'-terminal portion of the genomic leader sequence of Tomato bushy stunt virus (TBSV) forms an RNA structure containing a 3-helix junction, termed the T-shaped domain (TSD). In the present study, we have carried out structure-function analysis of the proposed TSD and have confirmed an important role for this domain in mediating efficient viral RNA amplification. Using a model TBSV defective interfering RNA replicon and a protoplast system, we demonstrated that various TSD subelements contribute to the efficiency of viral RNA replication. In particular, the stabilities of all three stems (S1, S2, and S4) forming the 3-helix junction are important, while stem-loop 3-a terminal extension of S2-is largely dispensable. Additionally, some of the sequences forming the 3-helix junction are required in an identity-dependent manner. Thus, both secondary structure and nucleotide identity are important for TSD-mediated viral RNA replication. Importantly, these results are fully consistent with the dual functions we defined previously for the sequences corresponding to loops 3 and 4, respectively, in facilitating 5' cap- and 3' poly(A) tail-independent translation of the genome by forming a loop-loop interaction with the 3'-proximal translational enhancer and in mediating viral RNA replication through formation of a pseudoknot with the adjacent downstream RNA domain. Also, since comparable TSDs and associated interactions are predicted in the 5' UTRs of all sequenced Aureusvirus genomes, members of at least one other genus in the family Tombusviridae appear to utilize this type of multifunctional RNA domain.