Identification of in vivo processing intermediates and of splice junctions of tRNAs from maize chloroplasts by amplification with the polymerase chain reaction.

Total RNA from chloroplasts of maize seedlings was used for polymerase chain reaction (PCR) mediated amplification of tRNA precursors and of mature tRNAs encoded by the two split tRNA genes of the ribosomal spacer (tRNA(lle)GAU and tRNA(Ala)UGC) and the single intron-containing tRNA(Gly)UCC gene. Sequence analysis of DNAs amplified from the mature tRNAs by combinations of exon specific primers allows unambiguous identification of the respective splice junctions. Primer combinations in which 5'- or 3'-flanking precursor tRNA sequences are included, leads to the amplification of processing intermediates in which 5'-terminal extensions are still present, whereas no PCR products corresponding to 3'-terminal extensions could be detected. From this it is concluded that in chloroplasts the 5'-terminal endonucleolytic cleavage by RNase P occurs as one of the final steps in the tRNA processing pathway of which the endonucleolytic cleavage at the 3' side probably occurs prior to the splicing of the intron sequences.     

Identification of nuclear encoded precursor tRNAs within the mitochondrion of Trypanosoma brucei.

RNAs that function in mitochondria are typically encoded by the mitochondrial DNA. However, the mitochondrial tRNAs of Trypanosoma brucei are encoded by the nuclear DNA and therefore must be imported into the mitochondrion. It is becoming evident that RNA import into mitochondria is phylogenetically widespread and is essential for cellular processes, but virtually nothing is known about the mechanism of RNA import. We have identified and characterized mitochondrial precursor tRNAs in T. brucei. The identification of mitochondrially located precursor tRNAs clearly indicates that mitochondrial tRNAs are imported as precursors. The mitochondrial precursor tRNAs hybridize to cloned nuclear tRNA genes, label with [alpha-32P]CTP using yeast tRNA nucleotidyltransferase and in isolated mitochondria via an endogenous nucleotidyltransferase-like activity, and are processed to mature tRNAs by Escherichia coli and yeast mitochondrial RNase P. We show that T. brucei mitochondrial extract contains an RNase P activity capable of processing a prokaryotic tRNA precursor as well as the T. brucei tRNA precursors. Precursors for tRNA(Asn) and tRNA(Leu) were detected on Northern blots of mitochondrial RNA, and the 5' ends of these RNAs were characterized by primer extension analysis. The structure of the precursor tRNAs and the significance of nuclear encoded precursor tRNAs within the mitochondrion are discussed.     

Endonucleolytic processing of CCA-less tRNA precursors by RNase Z in Bacillus subtilis

In contrast to Escherichia coli, where the 3' ends of tRNAs are primarily generated by exoribonucleases, maturation of the 3' end of tRNAs is catalysed by an endoribonuclease, known as RNase Z (or 3' tRNase), in many eukaryotic and archaeal systems. RNase Z cleaves tRNA precursors 3' to the discriminator base. Here we show that this activity, previously unsuspected in bacteria, is encoded by the yqjK gene of Bacillus subtilis. Decreased yqjK expression leads to an accumulation of a population of B.subtilis tRNAs in vivo, none of which have a CCA motif encoded in their genes, and YqjK cleaves tRNA precursors with the same specificity as plant RNase Z in vitro. We have thus renamed the gene rnz. A CCA motif downstream of the discriminator base inhibits RNase Z activity in vitro, with most of the inhibition due to the first C residue. Lastly, tRNAs with long 5' extensions are poor substrates for cleavage, suggesting that for some tRNAs, processing of the 5' end by RNase P may have to precede RNase Z cleavage.     

tRNAs in Trypanosoma brucei: genomic organization, expression, and mitochondrial import

The mitochondrial genome of Trypanosoma brucei does not encode tRNAs. Consequently, all mitochondrial tRNAs are imported from the cytosol and originate from nucleus-encoded genes. Analysis of all currently available T. brucei sequences revealed that its genome carries 50 tRNA genes representing 40 different isoacceptors. The identified set is expected to be nearly complete since all but four codons are accounted for. The number of tRNA genes in T. brucei is very low for a eukaryote and lower than those of many prokaryotes. Using quantitative Northern analysis we have determined the absolute abundance in the cell and the mitochondrion of a group of 15 tRNAs specific for 12 amino acids. Except for the initiator type tRNA(Met), which is cytosol specific, the cytosolic and the mitochondrial sets of tRNAs were qualitatively identical. However, the extent of mitochondrial localization was variable for the different tRNAs, ranging from 1 to 7.5% per cell. Finally, by using transgenic cell lines in combination with quantitative Northern analysis it was shown that import of tRNA(Leu)(CAA) is independent of its 5'-genomic context, suggesting that the in vivo import substrate corresponds to the mature, fully processed tRNA.     

The T-stem determines the cytosolic or mitochondrial localization of trypanosomal tRNAsMet

The mitochondrion of Trypanosoma brucei lacks tRNA genes. Organellar translation therefore depends on import of cytosolic, nucleus-encoded tRNAs. Except for the cytosol-specific initiator tRNA(Met), all trypanosomal tRNAs function in both the cytosol and the mitochondrion. The initiator tRNA(Met) is closely related to the imported elongator tRNA(Met). Thus, the distinct localization of the two tRNAs(Met) must be specified by the 26 nucleotides, which differ between the two molecules. Using transgenic T. brucei cell lines and subsequent cell fractionation, we show that the T-stem is both required and sufficient to specify the localization of the tRNAs(Met). Furthermore, it was shown that the tRNA(Met) T-stem localization determinants are also functional in the context of two other tRNAs. In vivo analysis of the modified nucleotides found in the initiator tRNA(Met) indicates that the T-stem localization determinants do not require modified nucleotides. In contrast, import of native tRNAs(Met) into isolated mitochondria suggests that nucleotide modifications might be involved in regulating the extent of import of elongator tRNA(Met).     

Ribonuclease PH plays a major role in the exonucleolytic maturation of CCA-containing tRNA precursors in Bacillus subtilis

In contrast to Escherichia coli, where all tRNAs have the CCA motif encoded by their genes, two classes of tRNA precursors exist in the Gram-positive bacterium Bacillus subtilis. Previous evidence had shown that ribonuclease Z (RNase Z) was responsible for the endonucleolytic maturation of the 3' end of those tRNAs lacking an encoded CCA motif, accounting for about one-third of its tRNAs. This suggested that a second pathway of tRNA maturation must exist for those precursors with an encoded CCA motif. In this paper, we examine the potential role of the four known exoribonucleases of B.subtilis, PNPase, RNase R, RNase PH and YhaM, in this alternative pathway. In the absence of RNase PH, precursors of CCA-containing tRNAs accumulate that are a few nucleotides longer than the mature tRNA species observed in wild-type strains or in the other single exonuclease mutants. Thus, RNase PH plays an important role in removing the last few nucleotides of the tRNA precursor in vivo. The presence of three or four exonuclease mutations in a single strain results in CCA-containing tRNA precursors of increasing size, suggesting that, as in E.coli, the exonucleolytic pathway consists of multiple redundant enzymes. Assays of purified RNase PH using in vitro-synthesized tRNA precursor substrates suggest that RNase PH is sensitive to the presence of a CCA motif. The division of labor between the endonucleolytic and exonucleolytic pathways observed in vivo can be explained by the inhibition of RNase Z by the CCA motif in CCA-containing tRNA precursors and by the inhibition of exonucleases by stable secondary structure in the 3' extensions of the majority of CCA-less tRNAs.     

Effects of 5' leader and 3' trailer structures on pre-tRNA processing by nuclear RNase P

Eukaryotic transfer RNA precursors (pre-tRNAs) contain a 5' leader preceding the aminoacyl acceptor stem and a 3' trailer extending beyond this stem. An early step in pre-tRNA maturation is removal of the 5' leader by the endoribonuclease, RNase P. Extensive pairing between leader and trailer sequences has previously been demonstrated to block RNase P cleavage, suggesting that the 5' leader and 3' trailer sequences might need to be separated for the substrate to be recognized by the eukaryotic holoenzyme. To address whether the nuclear RNase P holoenzyme recognizes the 5' leader and 3' trailer sequences independently, interactions of RNase P with pre-tRNA(Tyr) containing either the 5' leader, the 3' trailer, or both were examined. Kinetic analysis revealed little effect of the 3' trailer or a long 5' leader on the catalytic rate (k(cat)) for cleavage using the various pre-tRNA derivatives. However, the presence of a 3' trailer that pairs with the 5' leader increases the K(m) of pre-tRNA slightly, in agreement with previous results. Similarly, competition studies demonstrate that removal of a complementary 3' trailer lowers the apparent K(I), consistent with the structure between these two sequences interfering with their interaction with the enzyme. Deletion of both the 5' and 3' extensions to give mature termini resulted in the least effective competitor. Further studies showed that the nuclear holoenzyme, but not the B. subtilis holoenzyme, had a high affinity for single-stranded RNA in the absence of attached tRNA structure. The data suggest that yeast nuclear RNase P contains a minimum of two binding sites involved in substrate recognition, one that interacts with tRNA and one that interacts with the 3' trailer. Furthermore, base pairing between the 5' leader and 3' trailer hinders recognition.     

O-ribosyl-phosphate purine as a constant modified nucleotide located at position 64 in cytoplasmic initiator tRNAs(Met) of yeasts.

The unknown modified nucleotide G*, isolated from both Schizosaccharomyces pombe and Torulopsis utilis initiator tRNAs(Met), has been identified as an O-ribosyl-(1"----2')-guanosine-5"-phosphate, called Gr(p), by means of HPLC, UV-absorption, mass spectrometry and periodate oxidation procedures. By comparison with the previously published structure of Ar(p) isolated from Saccharomyces cerevisiae initiator tRNA(Met), the (1"----2')-glycosidic bond in Gr(p) has been postulated to have a beta-spatial conformation. The modified nucleotide Gr(p) is located at position 64 in the tRNA(Met) molecules, i.e. at the same position as Ar(p). Since we have also characterized Gr(p) in Candida albicans initiator tRNA(Met), the phosphoribosylation of purine 64 can be considered as a constant nucleotide modification in the cytoplasmic initiator tRNAs(Met) of all yeast species so far sequenced. Precise evidence for the presence of Gr(p) in initiator tRNAs(Met) of several plants is also reported.     

Mitochondrial initiation factor 2 of Trypanosoma brucei binds imported formylated elongator-type tRNA(Met)

The mitochondrion of Trypanosoma brucei lacks tRNA genes. Its translation system therefore depends on the import of nucleus-encoded tRNAs. Thus, except for the cytosol-specific initiator tRNA(Met), all trypanosomal tRNAs function in both the cytosol and the mitochondrion. The only tRNA(Met) present in T. brucei mitochondria is therefore the one which, in the cytosol, is involved in translation elongation. Mitochondrial translation initiation depends on an initiator tRNA(Met) carrying a formylated methionine. This tRNA is then recognized by initiation factor 2, which brings it to the ribosome. To guarantee mitochondrial translation initiation, T. brucei has an unusual methionyl-tRNA formyltransferase that formylates elongator tRNA(Met). In the present study, we have identified initiation factor 2 of T. brucei and shown that its carboxyl-terminal domain specifically binds formylated trypanosomal elongator tRNA(Met). Furthermore, the protein also recognizes the structurally very different Escherichia coli initiator tRNA(Met), suggesting that the main determinant recognized is the formylated methionine. In vivo studies using stable RNA interference cell lines showed that knock-down of initiation factor 2, depending on which construct was used, causes slow growth or even growth arrest. Moreover, concomitantly with ablation of the protein, a loss of oxidative phosphorylation was observed. Finally, although ablation of the methionyl-tRNA formyltransferase on its own did not impair growth, a complete growth arrest was observed when it was combined with the initiation factor 2 RNA interference cell line showing the slow growth phenotype. Thus, these experiments illustrate the importance of mitochondrial translation initiation for growth of procyclic T. brucei.     

Co-evolution of tRNA 3' trailer sequences with 3' processing enzymes in bacteria

Maturation of the tRNA 3' terminus is a complicated process in bacteria. Usually, it is initiated by an endonucleolytic cleavage carried out by RNase E and Z in different bacteria. In Escherichia coli, RNase E cleaves AU-rich sequences downstream of tRNA, producing processing intermediates with a few extra residues at the 3' end; these are then removed by exoribonuclease trimming to generate the mature 3' end. Here we show that essentially all E. coli tRNA precursors contain a potential RNase E cleavage site, the AU-rich sequence element (AUE), in the 3' trailer. This suggests that RNase E cleavage and exonucleolytic trimming is a general pathway for tRNA maturation in this organism. Remarkably, the AUE immediately downstream of each tRNA is selectively conserved in bacteria having RNase E and tRNA-specific exoribonucleases, suggesting that this pathway for tRNA processing is also commonly used in these bacteria. Two types of RNase E-like proteins are identified in actinobacteria and the alpha-subdivision of proteobacteria. The tRNA 3' proximal AUE is conserved in bacteria with only one type of E-like protein. Selective conservation of the AUE is usually not observed in bacteria without RNase E. These results demonstrate a novel example of co-evolution of RNA sequences with processing activities.