In vivo dissection of cis-acting determinants for plastid RNA editing.

Abstract

Substitutional RNA editing changes single C nucleotides in higher plant chloroplast transcripts into U residues. To determine the cis-acting sequence elements involved in plastid RNA editing, we constructed a series of chloroplast transformation vectors harboring selected editing sites of the tobacco ndhB transcript in a chimeric context. The constructs were inserted into the tobacco plastid genome by biolistic transformation leading to the production of stable chimeric RNAs. Analysis of RNA editing revealed unexpected differences in the size of the essential cis elements or in their distance from the editing site. Flanking sequences of identical size direct virtually complete editing for one pair of editing sites, partial editing for a second and no editing at all for a third pair of sites. Serial 5′ and 3′ deletions allowed us to define the cis-acting elements more precisely and to identify a sequence element essential for editing site recognition. In addition, a single nucleotide substitution immediately upstream of an editing position was introduced. This mutation was found drastically and selectively to reduce the editing efficiency of the downstream editing site, demonstrating that position −1 is important for either site recognition or catalysis. Our results indicate that the editing of adjacent sites is likely to be mechanistically coupled. In no case did the presence in the plastome of the additional editing sites have any effect on the editing efficiency of the endogenous ndhB sites, indicating that the availability of site-specific trans-acting factors is not rate limiting.