A three-dimensional model of the histidylable 3'-terminal tRNA-like domain of tobacco mosaic virus RNA is proposed on the basis of a comparative structural analysis, chemical and enzymatic probing, combined with graphical modeling of three RNA constructs of increasing size (38, 108, and 182 nt) derived from the 3'-terminal viral RNA sequence. The comparison between the probing patterns of the three RNAs allowed the determination of the relative orientation of these structural domains in the full-length viral tRNA-like structure. Modeling data indicate that only one of the two possible isomers of the three-way junction located at a central position of the tRNA-like domain is in agreement with structural data. Interestingly, this isomer gives rise to a molecule bearing a structural mimicry with the L-shape of canonical tRNAs. A pseudoknotted acceptor branch containing a T-like loop is located perpendicularly to an anticodon-like branch. Moreover, a single-stranded RNA stretch belonging to the pseudoknotted central core mimics a D-like loop and it is proposed that it interacts via two conserved guanosines with nucleotides of the T-like loop as found in canonical tRNAs. This model is valid for the 3' noncoding regions of tobamoviral RNAs as well as for the tRNA-like domain of the satellite tobacco mosaic virus RNA. All three molecules are substrates for yeast HisRS; however, whereas the complete viral genome is required for optimal histidylation capacities, both charging levels and affinity constants are decreased for the three RNA transcripts, suggesting that additional contacts located outside the tRNA-like domain are needed for an optimal aminoacylation process.