Partial duplication of the large ribosomal RNA sequence in an inverted repeat in circular mitochondrial DNA from Kloeckera africana: Implications for mechanisms of the petite mutation

The 27,100 base-pair circular mitochondrial DNA from the yeast Kloeckera africana has been found to contain an inverted duplication spanning 8600 base-pairs. Sequences hybridizing to transfer RNAs and the large ribosomal RNA are present in the duplication; however, one end of this segment terminates in the large mitochondrial ribosomal RNA sequence so that at least 1000 base-pairs of the gene are not repeated. The large and small mitochondrial ribosomal RNAs have been shown to have lengths of 2700 and 1450 bases, respectively, and genes for these sequences are separated by a minimum of 1300 base-pairs and a maximum of 1750 base-pairs. Consequences of the large inverted duplication to mechanisms of the petite mutation are discussed in terms of previous hypotheses centred on intramolecular recombination in yeast mitochondrial DNA at sequences of homology or partial homology. Despite the long inverted duplication in K. africana mitochondrial DNA, this yeast has one of the lowest frequencies of spontaneous petite mutants amongst petite positive yeasts. One implication of these findings is that in this yeast intra-molecular mitochondrial DNA sequence homology may not be an important factor in the excision process leading to petite formation.     

Induced tRNA Import into Human Mitochondria: Implication of a Host Aminoacyl-tRNA-Synthetase

In human cell, a subset of small non-coding RNAs is imported into mitochondria from the cytosol. Analysis of the tRNA import pathway allowing targeting of the yeast tRNA^Lys _CUU into human mitochondria demonstrates a similarity between the RNA import mechanisms in yeast and human cells. We show that the cytosolic precursor of human mitochondrial lysyl-tRNA synthetase (preKARS2) interacts with the yeast tRNA^Lys _CUU and small artificial RNAs which contain the structural elements determining the tRNA mitochondrial import, and facilitates their internalization by isolated human mitochondria. The tRNA import efficiency increased upon addition of the glycolytic enzyme enolase, previously found to be an actor of the yeast RNA import machinery. Finally, the role of preKARS2 in the RNA mitochondrial import has been directly demonstrated in vivo, in cultured human cells transfected with the yeast tRNA and artificial importable RNA molecules, in combination with preKARS2 overexpression or downregulation by RNA interference. These findings suggest that the requirement of protein factors for the RNA mitochondrial targeting might be a conserved feature of the RNA import pathway in different organisms.     

Prediction of signal recognition particle RNA genes

We describe a method for prediction of genes that encode the RNA component of the signal recognition particle (SRP). A heuristic search for the strongly conserved helix 8 motif of SRP RNA is combined with covariance models that are based on previously known SRP RNA sequences. By screening available genomic sequences we have identified a large number of novel SRP RNA genes and we can account for at least one gene in every genome that has been completely sequenced. Novel bacterial RNAs include that of Thermotoga maritima, which, unlike all other non-gram-positive eubacteria, is predicted to have an Alu domain. We have also found the RNAs of Lactococcus lactis and Staphylococcus to have an unusual UGAC tetraloop in helix 8 instead of the normal GNRA sequence. An investigation of yeast RNAs reveals conserved sequence elements of the Alu domain that aid in the analysis of these RNAs. Analysis of the human genome reveals only two likely genes, both on chromosome 14. Our method for SRP RNA gene prediction is the first convenient tool for this task and should be useful in genome annotation.     

Yeast and human mitochondrial helicases

Mitochondria are semiautonomous organelles which contain their own genome. Both maintenance and expression of mitochondrial DNA require activity of RNA and DNA helicases. In Saccharomyces cerevisiae the nuclear genome encodes four DExH/D superfamily members (MSS116, SUV3, MRH4, IRC3) that act as helicases and/or RNA chaperones. Their activity is necessary for mitochondrial RNA splicing, degradation, translation and genome maintenance. In humans the ortholog of SUV3 (hSUV3, SUPV3L1) so far is the best described mitochondrial RNA helicase. The enzyme, together with the matrix-localized pool of PNPase (PNPT1), forms an RNA-degrading complex called the mitochondrial degradosome, which localizes to distinct structures (D-foci). Global regulation of mitochondrially encoded genes can be achieved by changing mitochondrial DNA copy number. This way the proteins involved in its replication, like the Twinkle helicase (c10orf2), can indirectly regulate gene expression. Here, we describe yeast and human mitochondrial helicases that are directly involved in mitochondrial RNA metabolism, and present other helicases that participate in mitochondrial DNA replication and maintenance. This article is part of a Special Issue entitled: The Biology of RNA helicases — Modulation for life.     

Discovery of new genes and deletion editing in Physarum mitochondria enabled by a novel algorithm for finding edited mRNAs

Gene finding is complicated in organisms that exhibit insertional RNA editing. Here, we demonstrate how our new algorithm Predictor of Insertional Editing (PIE) can be used to locate genes whose mRNAs are subjected to multiple frameshifting events, and extend the algorithm to include probabilistic predictions for sites of nucleotide insertion; this feature is particularly useful when designing primers for sequencing edited RNAs. Applying this algorithm, we successfully identified the nad2, nad4L, nad6 and atp8 genes within the mitochondrial genome of Physarum polycephalum, which had gone undetected by existing programs. Characterization of their mRNA products led to the unanticipated discovery of nucleotide deletion editing in Physarum. The deletion event, which results in the removal of three adjacent A residues, was confirmed by primer extension sequencing of total RNA. This finding is remarkable in that it comprises the first known instance of nucleotide deletion in this organelle, to be contrasted with nearly 500 sites of single and dinucleotide addition in characterized mitochondrial RNAs. Statistical analysis of this larger pool of editing sites indicates that there are significant biases in the 2 nt immediately upstream of editing sites, including a reduced incidence of nucleotide repeats, in addition to the previously identified purine-U bias.     

A Flexible peptide tether controls accessibility of a unique C-terminal RNA-binding domain in leucyl-tRNA synthetases

A unique C-terminal domain extension is required by most leucyl-tRNA synthetases (LeuRS) for aminoacylation. In one exception, the enzymatic activity of yeast mitochondrial LeuRS is actually impeded by its own C-terminal domain. It was proposed that the yeast mitochondrial LeuRS has compromised its aminoacylation activity to some extent and adapted its C terminus for a second role in RNA splicing, which is also essential. X-ray crystal structures of the LeuRS-tRNA complex show that the 60 residue C-terminal domain is tethered to the main body of the enzyme via a flexible peptide linker and allows interactions with the tRNA^Leu elbow. We hypothesized that this short peptide linker would facilitate rigid body movement of the C-terminal domain as LeuRS transitions between an aminoacylation and editing complex or, in the case of yeast mitochondrial LeuRS, an RNA splicing complex. The roles of the C-terminal linker peptide for Escherichia coli and yeast mitochondrial LeuRS were investigated via deletion mutagenesis as well as by introducing chimeric swaps. Deletions within the C-terminal linker of E. coli LeuRS determined that its length, rather than its sequence, was critical to aminoacylation and editing activities. Although deletions in the yeast mitochondrial LeuRS peptide linker destabilized the protein in general, more stable chimeric enzymes that contained an E. coli LeuRS C-terminal domain showed that shortening its tether stimulated aminoacylation activity. This suggested that limiting C-terminal domain accessibility to tRNA^Leu facilitates its role in protein synthesis and may be a unique adaptation of yeast mitochondrial LeuRS that accommodates its second function in RNA splicing.     

Coordinated Function of Cellular DEAD-Box Helicases in Suppression of Viral RNA Recombination and Maintenance of Viral Genome Integrity

The intricate interactions between viruses and hosts include an evolutionary arms race and adaptation that is facilitated by the ability of RNA viruses to evolve rapidly due to high frequency mutations and genetic RNA recombination. In this paper, we show evidence that the co-opted cellular DDX3-like Ded1 DEAD-box helicase suppresses tombusviral RNA recombination in yeast model host, and the orthologous RH20 helicase functions in a similar way in plants. In vitro replication and recombination assays confirm the direct role of the ATPase function of Ded1p in suppression of viral recombination. We also present data supporting a role for Ded1 in facilitating the switch from minus- to plus-strand synthesis. Interestingly, another co-opted cellular helicase, the eIF4AIII-like AtRH2, enhances TBSV recombination in the absence of Ded1/RH20, suggesting that the coordinated actions of these helicases control viral RNA recombination events. Altogether, these helicases are the first co-opted cellular factors in the viral replicase complex that directly affect viral RNA recombination. Ded1 helicase seems to be a key factor maintaining viral genome integrity by promoting the replication of viral RNAs with correct termini, but inhibiting the replication of defective RNAs lacking correct 5’ end sequences. Altogether, a co-opted cellular DEAD-box helicase facilitates the maintenance of full-length viral genome and suppresses viral recombination, thus limiting the appearance of defective viral RNAs during replication.