Electroporation of DNA into Physarum polycephalum Mitochondria: Effects on Transcription and RNA Editing in Isolated Organelles

RNA editing alters the identity of nucleotides in RNA molecules such that the information for a protein in the mRNA differs from the prediction of the genomic DNA. In chloroplasts and mitochondria of flowering plants, RNA editing changes C nucleotides to U nucleotides; in ferns and mosses, it also changes U to C. The approximately 500 editing sites in mitochondria and 40 editing sites in plastids of flowering plants are individually addressed by specific proteins, genes for which are amplified in plant species with organellar RNA editing. These proteins contain repeat elements that bind to cognate RNA sequence motifs just 5' to the edited nucleotide. In flowering plants, the site-specific proteins interact selectively with individual members of a different, smaller family of proteins. These latter proteins may be connectors between the site-specific proteins and the as yet unknown deaminating enzymatic activity.

RNA editing describes targeted sequence alterations in RNAs so that the transcript sequences differ from their DNA template. Since the original discovery of RNA editing in trypanosomes nearly 25 years ago more than a dozen such processes of nucleotide insertions, deletions, and exchanges have been identified in evolutionarily widely separated groups of the living world including plants, animals, fungi, protists, bacteria, and viruses. In many cases gene expression in mitochondria is affected, but RNA editing also takes place in chloroplasts and in nucleocytosolic genetic environments. While some RNA editing systems largely seem to repair defect genes (cryptogenes), others have obvious functions in modulating gene activities. The present review aims for an overview on the current states of research in the different systems of RNA editing by following a historic timeline along the respective original discoveries.

We report evidence of extensive substitutional editing of mitochondrial mRNAs in the dinoflagellate species Pfiesteria piscicida, Prorocentrum minimum and Crypthecodinium cohnii, based on a comparison of genomic and corresponding cDNA sequences determined for two mitochondrial DNA-encoded genes, cox1 (cytochrome oxidase subunit 1) and cob (apocytochrome b). In the cox1 mRNA, we identify 72 substitutions at 40 sites in 39 codons, whereas in cob mRNA, we infer 86 editing events at 51 sites in 48 codons. Editing, which takes place in distinct clusters, changes approximately 2% of the total sequence, occurs predominantly at first and second positions of codons, and involves mostly (but not exclusively) A-->G (47%), U-->C (23%) and C-->U (17%) substitutions. In all but four of the 158 cases, editing changes the identity of the specified amino acid. At 21 (cox1) and 26 (cob) sites, the same nucleotide change is observed at the same position in at least two of the species investigated. At about one-third of the sites, editing results in an amino acid change that increases similarity between the dinoflagellate Cox1 and Cob sequences and their homologs in other organisms; presumably editing at these sites is of particular functional significance. Overall, about half of the editing events either maintain or increase similarity between the dinoflagellate protein sequences and their non-dinoflagellate homologs, while a further one-third of the alterations are "dinoflagellate-specific" (i.e. they involve a change to an amino acid residue selectively conserved in at least two of the dinoflagellate species at a given position). The nature, pattern and phylogenetic distribution of the inferred edits implies either that more than one type of previously described editing process operates on a given transcript in dinoflagellate mitochondria, or that a mechanistically unique type of mitochondrial mRNA editing has evolved within the dinoflagellate lineage. (c) 2002 Elsevier Science Ltd.