In-Plant Persistence and Systemic Transport of Nicotiana benthamiana Retrozyme RNA.

Retrozymes are nonautonomous retrotransposons with hammerhead ribozymes in their long terminal repeats (LTRs). Retrozyme transcripts can be self-cleaved by the LTR ribozyme, circularized, and can undergo RNA-to-RNA replication. Here, we demonstrate that the Nicotiana benthamiana genome contains hundreds of retrozyme loci, of which nine represent full-length retrozymes. The LTR contains a promoter directing retrozyme transcription. Although retrozyme RNA is easily detected in plants, the LTR region is heavily methylated, pointing to its transcriptional silencing, which can be mediated by 24 nucleotide-long retrozyme-specific RNAs identified in N. benthamiana. A transcriptome analysis revealed that half of the retrozyme-specific RNAs in plant leaves have no exact matches to genomic retrozyme loci, containing up to 13% mismatches with the closest genomic sequences, and could arise as a result of many rounds of RNA-to-RNA replication leading to error accumulation. Using a cloned retrozyme copy, we show that retrozyme RNA is capable of replication and systemic transport in plants. The presented data suggest that retrozyme loci in the N. benthamiana genome are transcriptionally inactive, and that circular retrozyme RNA can persist in cells due to its RNA-to-RNA replication and be transported systemically, emphasizing functional and, possibly, evolutionary links of retrozymes to viroids-noncoding circular RNAs that infect plants.

RNA Binding by Plant Serpins in vitro.

Serpins constitute a large family of protease inhibitors with regulatory functions found in all living organisms. Most plant serpins have not been functionally characterized, with the exception of Arabidopsis thaliana AtSerpin1, an inhibitor of pro-apoptotic proteases, which is involved in the regulation of the programmed cell death induction, and Cucurbita maxima CmPS1, a phloem protein, which presumably inhibits insect digestive proteases and binds RNA. CmPS1 interacts most efficiently with highly structured RNA; in particular, it forms a specific complex with tRNA. Here, we demonstrated that AtSerpin1 also forms a complex with tRNA. Analysis of tRNA species bound by AtSerpin1 and CmPS1 in the presence of tRNA excess revealed that both proteins have no strict selectivity for individual tRNAs, suggesting specific interaction of AtSerpin1 and CmPS1 proteins with elements of the secondary/tertiary structure universal for all tRNAs. Analysis of CmPS1 binding of the microRNA precursor pre-miR390 and its mutants demonstrated that the pre-miR390 mutant with a perfect duplex in the hairpin stem lost the ability to form a discrete complex with CmPS1, whereas another variant of pre-miR390 with the native unpaired nucleotide residues in the stem retained this ability. These data indicate that specific interactions of plant serpins with structured RNA are based on the recognition of structurally unique spatial motifs formed with the participation of unpaired nucleotide residues in the RNA duplexes.