Investigating the mechanism and machinery of RNA editing.

RNA editing in trypanosomes produces mature mRNAs by posttranscriptional guide RNA (gRNA)-directed uridylate insertion and deletion. This article describes methods for the study of RNA editing with an emphasis on an in vitro editing system that was used to explore the general mechanism of editing and that can be adapted for more in-depth studies of this intriguing and important process. Methods used to investigate the macromolecular complex that catalyzes RNA editing are also described. This complex is composed of multiple proteins and contains several catalytic activities. It is in the early stages of characterization. The methods described here are intended to assist in its further analysis.

RNA editing: getting U into RNA.

RNA editing in kinetoplastid protozoa remodels the sequences of mitochondrial pre-mRNAs by the precise insertion and deletion of uridylate residues. These sequence changes are directed by small trans-acting RNAs, termed guide RNAs. The basic mechanistic pathway by which edited RNA is generated has recently been elucidated using in vitro systems capable of a full round of guide-RNA-directed editing.

Kinetoplastid RNA editing: complexes and catalysts.

RNA editing in kinetoplastids involves post-transcriptional insertion and deletion of uridylates (Us) to produce mature mitochondrial mRNAs with sequences specified by trans acting small guide RNAs. In vitro studies indicate the reaction pathway involves endonucleolytic cleavage of the precursor mRNA at the editing site, uridylate addition or removal at the 3' end of the 5' cleavage product, followed by ligation to the 3' cleavage product. This editing is catalyzed by a macromolecular complex that is in the early stages of characterization. Recent studies have resolved the general mechanism of editing, and show that editing occurs in association with a macromolecular complex.

RNA editing: a mechanism for gRNA-specified uridylate insertion into precursor mRNA.

In the mitochondria of trypanosomatid protozoa the precursors of messenger RNAs (pre-mRNAs) have their coding information remodeled by the site-specific insertion and deletion of uridylate (U) residues. Small trans-acting guide RNAs (gRNAs) supply the genetic information for this RNA editing. An in vitro system was developed to study the mechanism of U insertion into pre-mRNA. U-insertion editing occurs through a series of enzymatic steps that begin with gRNA-directed pre-mRNA cleavage. Inserted U's are derived from free uridine triphosphate and are added to the 3' terminus of a 5' pre-mRNA cleavage product. gRNA specifies edited RNA sequence at the subsequent ligation step by base pairing-mediated juxtaposition of the 3' cleavage product and the processed 5' cleavage product. gRNA/pre-mRNA chimeras, purported intermediates, seem to be abortive end products of the same reaction.

Complexes from Trypanosoma brucei that exhibit deletion editing and other editing-associated properties.

Transcripts from many mitochondrial genes in kinetoplastids undergo RNA editing, a posttranscriptional process which inserts and deletes uridines. By assaying for deletion editing in vitro, we found that the editing activity from Trypanosoma brucei mitochondrial lysates (S.D. Seiwert and K.D. Stuart), Science 266:114-117,1994) sediments with a peak of approximately 20S. RNA helicase, terminal uridylyl transferase, RNA ligase, and adenylation activities, which may have a role in editing, cosediment in a broad distribution, with most of each activity at 35 to 40S. Most ATPase 6 (A6) guide RNA and unedited A6 mRNA sediments at 20 to 30S, with some sedimenting further into the gradient, while most edited A6 mRNA sediments at >35S. Several mitochondrial proteins which cross-link specifically with guide RNA upon UV treatment also sediment in glycerol gradients. Notably, a 65-kDa protein sediments primarily at approximately 20S, a 90-kDa protein sediments at 35 to 40S, and a 25-kDa protein is present at <10S. Most ribonucleoprotein complexes that form with gRNA in vitro sediment at 10 to 20S, except for one, which sediments at 30 to 45S. These results suggest that RNA editing takes place within a multicomponent complex. The potential functions of and relationships between the 20S and 35 to 40S complexes are discussed.

A Chlamydomonas protein that binds single-stranded G-strand telomere DNA.

We have identified a protein in Chlamydomonas reinhardtii cell extracts that specifically binds the single-stranded (ss) Chlamydomonas G-strand telomere sequence (TTTTAGGG)n. This protein, called G-strand binding protein (GBP), binds DNA with two or more ss TTTTAGGG repeats. A single polypeptide (M(r) 34 kDa) in Chlamydomonas extracts binds (TTTTAGGG)n, and a cDNA encoding this G-strand binding protein was identified by its expression of a G-strand binding activity. The cDNA (GBP1) sequence predicts a protein product (Gbp1p) that includes two domains with extensive homology to RNA recognition motifs (RRMs) and a region rich in glycine, alanine and arginine. Antibody raised against a peptide within Gbp1p reacted with both the 34 kDa polypeptide and bound G-strand DNA-protein complexes in gel retardation assays, indicating that GBP1 encodes GBP. Unlike vertebrate heteronuclear ribonucleoproteins, GBP does not bind the cognate telomere RNA sequence UUUUAGGG in gel retardation, North-Western or competition assays. Thus, GBP is a new type of candidate telomere binding protein that binds, in vitro, to ss G-strand telomere DNA, the primer for telomerase, and has domains that have homology to RNA binding domains in other proteins.