The 5'-terminal region of the apocytochrome b transcript in Crithidia fasciculata is successively edited by two guide RNAs in the 3' to 5' direction

A cis-acting A-U sequence element induces kinetoplastid U-insertions

A 34-nucleotide A-U sequence located immediately upstream of the editing sites of the Leishmania tarentolae cytochrome b mRNA induces a mitochondrial extract to insert U nucleotides independent of guide RNA. Insertions are localized to positions immediately 5' and 3' of the A-U sequence. When placed within an unedited mammalian transcript, the A-U sequence is sufficient to induce U-insertions. The sequence has a high degree of similarity with the templating nucleotides of a cytochrome b guide RNA and with a sequence adjacent to the editing sites in ND7 mRNA, the other characterized kinetoplastid mRNA supporting guide RNA-independent U-insertions. At least one protein specifically interacts with the A-U sequence. The reaction is consistent with a mechanism proposed for guide RNA-directed editing.

The mitochondrial ND8 gene from Crithidia oncopelti is not pan-edited

RNA editing in trypanosomatid mitochondria is a process involving the insertion and deletion of uridine residues within the coding region of maxicircle messenger RNA transcripts. Twelve of the 17 known genes need editing to produce functional molecules. We have analyzed the predicted editing sites for the Crithidia oncopelti mitochondrial NADH-ubiquinone oxidoreductase subunit 8 (ND8) gene based on known mRNAs from other trypanosomatid species. All studied ND8 mRNAs undergo editing throughout the coding (and 3' noncoding) sequences (pan-editing). The 5' part of the C. oncopelti ND8 gene undergoes editing (like in Leishmania tarentolae and Trypanosoma brucei) while the 3' part of the pre-edited gene corresponds to the 3' part of edited ND8 mRNAs from other organisms. The organization of the ND8 gene in C. oncopelti mitochondrial DNA differs from all organisms investigated so far -- this gene is not pan-edited. We have also localized the guide RNA for cytochrome b between 9S rRNA and the ND8 gene. This RNA shows high homology to the gCYb-II gene of L. tarentolae and the gCyb gene of Crithidia fasciculata. A hypothetical editing pattern for the cytochrome b gene in C. oncopelti maxicircles is proposed.

Insertional editing of nascent mitochondrial RNAs in Physarum

Maturation of Physarum mitochondrial RNA involves the highly specific insertion of nonencoded nucleotides at multiple locations. To investigate the mechanism(s) by which this occurs, we previously developed an isolated mitochondrial system in which run-on transcripts are accurately and efficiently edited by nucleotide insertion. Here we show that under limiting concentrations of exogenous nucleotides the mitochondrial RNA polymerases stall, generating a population of nascent RNAs that can be extended upon addition of limiting nucleotide. Several of these RNA species have been characterized and were found to be fully edited, indicating that nascent RNA is a substrate for nucleotide insertion in isolated Physarum mitochondria. Remarkably, these RNAs are edited at positions located within 14-22 nucleotides of the polymerase active site, suggesting that insertional editing may be physically or functionally associated with transcription. The absence of unedited RNA in these experiments indicates that large tracts of RNA downstream of editing sites are not required for nucleotide addition, and argues that insertional editing in Physarum occurs with a 5' to 3' polarity. These data also provide strong evidence that insertional editing in Physarum is mechanistically distinct from editing in kinetoplastid systems.

Guide RNA-independent and guide RNA-dependent uridine insertion into cytochrome b mRNA in a mitochondrial lysate from Leishmania tarentolae. Role of RNA secondary structure

A primer extension assay was used for the detection of uridine insertions occurring in vitro in synthetic pre-edited cytochrome b mRNA during incubation with a Leishmania tarentolae mitochondrial extract. Two different activities were detected that inserted uridines within the first two editing sites: one that is dependent on the secondary structure of the mRNA but is independent of both exogenous and endogenous guide RNA, and a second that does not put the same structural constraints on the mRNA, but is dependent on the presence of a cognate guide RNA.

A possible role for the guide RNA U-tail as a specificity determinant in formation of guide RNA-messenger RNA chimeras in mitochondrial extracts of Crithidia fasciculata

Chimeric g(uide) RNA:pre-mRNA molecules are potential intermediates of the RNA editing process in kinetoplastid mitochondria. We have studied the characteristics of chimeric molecules formed in mitochondrial extracts of the insect trypanosomatid Crithidia fasciculata which had been supplied with synthetic NADH dehydrogenase (ND) subunit-7 gRNA and pre-mRNA variants. The ability of a gRNA to participate in chimera formation in this system depends on the possibility of base pairing with the pre-mRNA via the anchor sequence, but not on the presence of a U-tail or a full-length informational part. Chimeras formed with a specific gRNA:pre-mRNA pair displayed a large variation in length, due to variably sized 3' end truncations of the gRNA moieties and variation in the sites in the pre-mRNA to which the gRNAs were attached. Surprisingly, the presence of a U-tail in the gRNA for a large part determined the specificity of the linkage. In 60% of the cases gRNAs possessing a U-tail of at least one residue were attached to an editing site, whereas 75% of the gRNAs without Us were attached to non-editing sites. Furthermore, the chimera forming activity was greatly stimulated by the addition of ATP but not by AMP-CPP, an ATP-analogue with a non-hydrolyzable alpha-beta phosphate bond. This suggests the involvement in the chimera formation of an RNA ligase.

Ancient origin of RNA editing in kinetoplastid protozoa

A rooted phylogenetic tree of the kinetoplastid protozoa has been constructed that, together with a comparative analysis of editing of several genes, leads to the surprising conclusion that extensive or pan-editing with multiple overlapping guide RNAs is more ancient than 5'-editing. The mechanism of editing is still uncertain, but multiple ribonucleoprotein complexes have been identified that contain components of the enzymatic machinery.

RNA editing in trypanosomes

The nucleotide sequence of mitochondrial pre-mRNAs in trypanosomes is posttranscriptionally edited by the insertion and deletion of uridylate (U) residues. In some RNAs editing is limited to small sections but in African trypanosomes, such as Trypanosoma brucei, 9 of the 18 known mitochondrial mRNAs are created by massive editing which can produce more than 50% of the coding sequence. In all cases, however, RNA editing is a key event in gene expression during which translatable RNAs are generated. The information for the editing process and possibly also the inserted Us are provided by small guide RNAs, which are encoded in both the maxicircle and minicircle components of the trypanosome mitochondrial DNA. Current models of editing are largely based on the characteristics of partially edited RNAs and on the occurrence in vivo and the possibility of synthesis in vitro of chimeric molecules in which a guide RNA is covalently linked through its 3' oligo(U) tail to an editing site in pre-mRNA. In this paper, I will review the research in this rapidly growing field and illustrate how different interpretations of the available data can lead to different views of the mechanism and the biochemistry of the editing process.