In vitro processing of mitochondrial and plastid derived tRNA precursors in a plant mitochondrial extract

Fungal-Derived tRNAs Are Expressed and Aminoacylated in Orchid Mitochondria

Plant mitochondrial genomes (mitogenomes) experience remarkable levels of horizontal gene transfer, including the recent discovery that orchids anciently acquired DNA from fungal mitogenomes. Thus far, however, there is no evidence that any of the genes from this interkingdom horizontal gene transfer are functional in orchid mitogenomes. Here, we applied a specialized sequencing approach to the orchid Corallorhiza maculata and found that some fungal-derived tRNA genes in the transferred region are transcribed, post-transcriptionally modified, and aminoacylated. In contrast, all the transferred protein-coding sequences appear to be pseudogenes. These findings show that fungal horizontal gene transfer has altered the composition of the orchid mitochondrial tRNA pool and suggest that these foreign tRNAs function in translation. The exceptional capacity of tRNAs for horizontal gene transfer and functional replacement is further illustrated by the diversity of tRNA genes in the C. maculata mitogenome, which also include genes of plastid and bacterial origin in addition to their native mitochondrial counterparts.

Interchangeable parts: The evolutionarily dynamic tRNA population in plant mitochondria

Transfer RNAs (tRNAs) remain one of the very few classes of genes still encoded in the mitochondrial genome. These key components of the protein translation system must interact with a large enzymatic network of nuclear-encoded gene products to maintain mitochondrial function. Plants have an evolutionarily dynamic mitochondrial tRNA population, including ongoing tRNA gene loss and replacement by both horizontal gene transfer from diverse sources and import of nuclear-expressed tRNAs from the cytosol. Thus, plant mitochondria represent an excellent model for understanding how anciently divergent genes can act as "interchangeable parts" during the evolution of complex molecular systems. In particular, understanding the integration of the mitochondrial translation system with elements of the corresponding machinery used in cytosolic protein synthesis is a key area for eukaryotic cellular evolution. Here, we review the increasingly detailed phylogenetic data about the evolutionary history of mitochondrial tRNA gene loss, transfer, and functional replacement that has created extreme variation in mitochondrial tRNA populations across plant species. We describe emerging tRNA-seq methods with promise for refining our understanding of the expression and subcellular localization of tRNAs. Finally, we summarize current evidence and identify open questions related to coevolutionary changes in nuclear-encoded enzymes that have accompanied turnover in mitochondrial tRNA populations.

PPR proteins shed a new light on RNase P biology

A fast growing number of studies identify pentatricopeptide repeat (PPR) proteins as major players in gene expression processes. Among them, a subset of PPR proteins called PRORP possesses RNase P activity in several eukaryotes, both in nuclei and organelles. RNase P is the endonucleolytic activity that removes 5′ leader sequences from tRNA precursors and is thus essential for translation. Before the characterization of PRORP, RNase P enzymes were thought to occur universally as ribonucleoproteins, although some evidence implied that some eukaryotes or cellular compartments did not use RNA for RNase P activity. The characterization of PRORP reveals a two-domain enzyme, with an N-terminal domain containing multiple PPR motifs and assumed to achieve target specificity and a C-terminal domain holding catalytic activity. The nature of PRORP interactions with tRNAs suggests that ribonucleoprotein and protein-only RNase P enzymes share a similar substrate binding process.

tRNA-like elements in Haloferax volcanii

All functional RNAs are generated from precursor molecules by a plethora of processing steps. The generation of mature RNA molecules by processing is an important layer of gene expression regulation catalysed by ribonucleases. Here, we analysed 5S rRNA processing in the halophilic Archaeon Haloferax volcanii. Earlier experiments showed that the 5S rRNA is cleaved at its 5' end by the endonuclease tRNase Z. Interestingly, a tRNA-like structure was identified upstream of the 5S rRNA that might be used as a processing signal. Here, we show that this tRNA-like element is indeed recognised as a processing signal by tRNase Z. Substrates containing mutations in the tRNA-like sequence are no longer processed, whereas a substrate containing a deletion in the 5S rRNA sequence is still cleaved. Therefore, an intact 5S rRNA structure is not required for processing. Further, we used bioinformatics analyses to identify additional sequences in Haloferax containing tRNA-like structures. This search resulted in the identification of all tRNAs, the tRNA-like structure upstream of the 5S RNA and 47 new tRNA-like structural elements. However, the in vitro processing of selected examples showed no cleavage of these newly identified elements. Thus, tRNA-like elements are not a general processing signal in Haloferax.

Of P and Z: mitochondrial tRNA processing enzymes

Mitochondrial tRNAs are generally synthesized as part of polycistronic transcripts. Release of tRNAs from these precursors is thus not only required to produce functional adaptors for translation, but also responsible for the maturation of other mitochondrial RNA species. Cleavage of mitochondrial tRNAs appears to be exclusively accomplished by endonucleases. 5'-end maturation in the mitochondria of different Eukarya is achieved by various kinds of RNase P, representing the full range of diversity found in this enzyme family. While ribonucleoprotein enzymes with RNA components of bacterial-like appearance are found in a few unrelated protists, algae, and fungi, highly degenerate RNAs of dramatic size variability are found in the mitochondria of many fungi. The majority of mitochondrial RNase P enzymes, however, appear to be pure protein enzymes. Human mitochondrial RNase P, the first to be identified and possibly the prototype of all animal mitochondrial RNases P, is composed of three proteins. Homologs of its nuclease subunit MRPP3/PRORP, are also found in plants, algae and several protists, where they are apparently responsible for RNase P activity in mitochondria (and beyond) without the help of extra subunits. The diversity of RNase P enzymes is contrasted by the uniformity of mitochondrial RNases Z, which are responsible for 3'-end processing. Only the long form of RNase Z, which is restricted to eukarya, is found in mitochondria, even when an additional short form is present in the same organism. Mitochondrial tRNA processing thus appears dominated by new, eukaryal inventions rather than bacterial heritage. This article is part of a Special Issue entitled: Mitochondrial Gene Expression.

Arabidopsis encodes four tRNase Z enzymes

Functional transfer RNA (tRNA) molecules are a prerequisite for protein biosynthesis. Several processing steps are required to generate the mature functional tRNA from precursor molecules. Two of the early processing steps involve cleavage at the tRNA 5' end and the tRNA 3' end. While processing at the tRNA 5' end is performed by RNase P, cleavage at the 3' end is catalyzed by the endonuclease tRNase Z. In eukaryotes, tRNase Z enzymes are found in two versions: a short form of about 250 to 300 amino acids and a long form of about 700 to 900 amino acids. All eukaryotic genomes analyzed to date encode at least one long tRNase Z protein. Of those, Arabidopsis (Arabidopsis thaliana) is the only organism that encodes four tRNase Z proteins, two short forms and two long forms. We show here that the four proteins are distributed to different subcellular compartments in the plant cell: the nucleus, the cytoplasm, the mitochondrion, and the chloroplast. One tRNase Z is present only in the cytoplasm, one protein is found exclusively in mitochondria, while the third one has dual locations: nucleus and mitochondria. None of these three tRNase Z proteins is essential. The fourth tRNase Z protein is present in chloroplasts, and deletion of its gene results in an embryo-lethal phenotype. In vitro analysis with the recombinant proteins showed that all four tRNase Z enzymes have tRNA 3' processing activity. In addition, the mitochondrial tRNase Z proteins cleave tRNA-like elements that serve as processing signals in mitochondrial mRNA maturation.

tRNA recognition, processing, and disease: hypotheses around an unorthodox type of RNase P in human mitochondria

RNase P is the endonuclease responsible for the maturation of the 5' ends of tRNAs. A catalytic RNA component was long considered the premier attribute of the enzyme family. Ignoring this heritage, human mitochondria make their RNase P of three proteins only. While one of them appears to be the metallonuclease actually responsible for phosphodiester hydrolysis, the other two have been recruited from unrelated biochemical pathways and may be critical for substrate recognition. One of them is moreover identical to a previously identified amyloid-beta-binding protein, whereby it could link tRNA processing to mitochondrial dysfunction in Alzheimer's disease.

Maturation of the 5S rRNA 5' end is catalyzed in vitro by the endonuclease tRNase Z in the archaeon H. volcanii

Ribosomal RNA molecules are synthesized as precursors that have to undergo several processing steps to generate the functional rRNA. The 5S rRNA in the archaeon Haloferax volcanii is transcribed as part of a multicistronic transcript containing both large rRNAs and one or two tRNAs. Release of the 5S rRNA from the precursor requires two endonucleolytic cleavages by enzymes as yet not identified. Here we report the first identification of an archaeal 5S rRNA processing endonuclease. The enzyme tRNase Z, which was initially identified as tRNA processing enzyme, generates not only tRNA 3' ends but also mature 5S rRNA 5' ends in vitro. Interestingly, the sequence upstream of the 5S rRNA can be folded into a mini-tRNA, which might explain the processing of this RNA by tRNase Z. The endonuclease is active only at low salt concentrations in vitro, which is in contrast to the 2-4 M KCl concentration present inside the cell in vivo. Electron microscopy studies show that there are no compartments inside the Haloferax cell that could provide lower salt environments. Processing of the 5S rRNA 5' end is not restricted to the haloarchaeal tRNase Z since tRNase Z enzymes from a thermophilic archaeon, a lower and a higher eukaryote, are as well able to cleave the tRNA-like structure 5' of the 5S rRNA. Knock out of the tRNase Z gene in Haloferax volcanii is lethal, showing that the protein is essential for the cell.

Residues in two homology blocks on the amino side of the tRNase Z His domain contribute unexpectedly to pre-tRNA 3' end processing

tRNase Z, which can endonucleolytically remove pre-tRNA 3'-end trailers, possesses the signature His domain (HxHxDH; Motif II) of the beta-lactamase family of metal-dependent hydrolases. Motif II combines with Motifs III-V on its carboxy side to coordinate two divalent metal ions, constituting the catalytic core. The PxKxRN loop and Motif I on the amino side of Motif II have been suggested to modulate tRNase Z activity, including the anti-determinant effect of CCA in mature tRNA. Ala walks through these two homology blocks reveal residues in which the substitutions unexpectedly reduce catalytic efficiency. While substitutions in Motif II can drastically affect k(cat) without affecting k(M), five- to 15-fold increases in k(M) are observed with substitutions in several conserved residues in the PxKxRN loop and Motif I. These increases in k(M) suggest a model for substrate binding. Expressed tRNase Z processes mature tRNA with CCA at the 3' end approximately 80 times less efficiently than a pre-tRNA possessing natural sequence of the 3'-end trailer, due to reduced k(cat) with no effect on k(M), showing the CCA anti-determinant to be a characteristic of this enzyme.

Naturally occurring mutations in human mitochondrial pre-tRNASer(UCN) can affect the transfer ribonuclease Z cleavage site, processing kinetics, and substrate secondary structure

tRNAs are transcribed as precursors with a 5' end leader and a 3' end trailer. The 5' end leader is processed by RNase P, and in most organisms in all three kingdoms, transfer ribonuclease (tRNase) Z can endonucleolytically remove the 3' end trailer. Long ((L)) and short ((S)) forms of the tRNase Z gene are present in the human genome. tRNase Z(L) processes a nuclear-encoded pre-tRNA approximately 1600-fold more efficiently than tRNase Z(S) and is predicted to have a strong mitochondrial transport signal. tRNase Z(L) could, thus, process both nuclear- and mitochondrially encoded pre-tRNAs. More than 150 pathogenesis-associated mutations have been found in the mitochondrial genome, most of them in the 22 mitochondrially encoded tRNAs. All the mutations investigated in human mitochondrial tRNA(Ser(UCN)) affect processing efficiency, and some affect the cleavage site and secondary structure. These changes could affect tRNase Z processing of mutant pre-tRNAs, perhaps contributing to mitochondrial disease.

Gene expression in plant mitochondria: transcriptional and post-transcriptional control

The informational content of the mitochondrial genome in plants is, although small, essential for each cell. Gene expression in these organelles involves a number of distinct transcriptional and post-transcriptional steps. The complex post-transcriptional processes of plant mitochondria such as 5' and 3' RNA processing, intron splicing, RNA editing and controlled RNA stability extensively modify individual steady-state RNA levels and influence the mRNA quantities available for translation. In this overview of the processes in mitochondrial gene expression, we focus on confirmed and potential sites of regulatory interference and discuss the evolutionary origins of the transcriptional and post-transcriptional processes.

tRNA 3' end maturation in archaea has eukaryotic features: the RNase Z from Haloferax volcanii

Here, we report the first characterization and partial purification of an archaeal tRNA 3' processing activity, the RNase Z from Haloferax volcanii. The activity identified here is an endonuclease, which cleaves tRNA precursors 3' to the discriminator. Thus tRNA 3' processing in archaea resembles the eukaryotic 3' processing pathway. The archaeal RNase Z has a KCl optimum at 5mM, which is in contrast to the intracellular KCl concentration being as high as 4M KCl. The archaeal RNase Z does process 5' extended and intron-containing pretRNAs but with a much lower efficiency than 5' matured, intronless pretRNAs. At least in vitro there is thus no defined order for 5' and 3' processing and splicing. A heterologous precursor tRNA is cleaved efficiently by the archaeal RNase Z. Experiments with precursors containing mutated tRNAs revealed that removal of the anticodon arm reduces cleavage efficiency only slightly, while removal of D and T arm reduces processing effciency drastically, even down to complete inhibition. Comparison with its nuclear and mitochondrial homologs revealed that the substrate specificity of the archaeal RNase Z is narrower than that of the nuclear RNase Z but broader than that of the mitochondrial RNase Z.

The RNA world of plant mitochondria

Mitochondria are well known as the cellular power factory. Much less is known about these organelles as a genetic system. This is particularly true for mitochondria of plants, which subsist with respect to attention by the scientific community in the shadow of the chloroplasts. Nevertheless the mitochondrial genetic system is essential for the function of mitochondria and thus for the survival of the plant. In plant mitochondria the pathway from the genetic information encoded in the DNA to the functional protein leads through a very diverse RNA world. How the RNA is generated and what kinds of regulation and control mechanisms are operative in transcription are current topics in research. Furthermore, the modes of posttranscriptional alterations and their consequences for RNA stability and thus for gene expression in plant mitochondria are currently objects of intensive investigations. In this article current results obtained in the examination of plant mitochondrial transcription, RNA processing, and RNA stability are illustrated. Recent developments in the characterization of promoter structure and the respective transcription apparatus as well as new aspects of RNA processing steps including mRNA 3' processing and stability, mRNA polyadenylation, RNA editing, and tRNA maturation are presented. We also consider new suggestions concerning the endosymbiont hypothesis and evolution of mitochondria. These novel considerations may yield important clues for the further analysis of the plant mitochondrial genetic system. Conversely, an increasing knowledge about the mechanisms and components of the organellar genetic system might reveal new aspects of the evolutionary history of mitochondria.

The plant tRNA 3' processing enzyme has a broad substrate spectrum

To elucidate the minimal substrate for the plant nuclear tRNA 3' processing enzyme, we synthesized a set of tRNA variants, which were subsequently incubated with the nuclear tRNA 3' processing enzyme. Our experiments show that the minimal substrate for the nuclear RNase Z consists of the acceptor stem and T arm. The broad substrate spectrum of the nuclear RNase Z raises the possibility that this enzyme might have additional functions in the nucleus besides tRNA 3' processing. Incubation of tRNA variants with the plant mitochondrial enzyme revealed that the organellar counterpart of the nuclear enzyme has a much narrower substrate spectrum. The mitochondrial RNase Z only tolerates deletion of anticodon and variable arms and only with a drastic reduction in cleavage efficiency, indicating that the mitochondrial activity can only cleave bona fide tRNA substrates efficiently. Both enzymes prefer precursors containing short 3' trailers over extended 3' additional sequences. Determination of cleavage sites showed that the cleavage site is not shifted in any of the tRNA variant precursors.

tRNA 3' processing in plants: nuclear and mitochondrial activities differ

The nuclear tRNA 3' processing activity from wheat has been characterized and partially purified. Several characteristics of the wheat nuclear 3' processing enzyme now allow this activity to be distinguished from its mitochondrial counterpart. The nuclear enzyme is an endonuclease, which we termed nuclear RNase Z. The enzyme cleaves at the discriminator base and seems to consist only of protein subunits, since essential RNA subunits could not be detected. RNase Z leaves 5' terminal phosphoryl and 3' terminal hydroxyl groups at the processing products. It is a stable enzyme being active over broad temperature and pH ranges, with the highest activity at 35 degrees C and pH 8.4. The apparent molecular mass according to gel filtration chromatography is 122 kDa. The nuclear RNase Z does process 5' extended pretRNAs but with a much lower efficiency than 5' matured pretRNAs. Nuclear intron-containing precursor tRNAs as well as mitochondrial precursor tRNAs are efficiently cleaved by the nuclear RNase Z. Mitochondrial pretRNA(His) is processed by the nuclear RNase Z, generating a mature tRNA(His) containing an 8 base pair acceptor stem. The edited mitochondrial pretRNA(Phe) is cleaved easily, while the unedited version having a mismatch in the acceptor stem is not cleaved. Thus, an intact acceptor stem seems to be required for processing. Experiments with precursors containing mutated tRNAs showed that a completely intact anticodon arm is not necessary for processing by RNase Z. Comparison of the plant nuclear tRNA 3' processing enzyme with the plant mitochondrial one suggests that both activities are different enzymes.

Characterization of human mitochondrial RNase P: novel aspects in tRNA processing

Human mitochondrial RNase P does not distinguish itself from other RNase P enzymes by most of its basic properties. 5' phosphates on tRNA products, strict dependence on a divalent cation, independence of ATP or other cofactors, and sensitivity to puromycin are generally characteristic for RNase P. Slow sedimentation of human mitochondrial RNase P in glycerol gradients suggests a molecular weight considerably lower than that of bacterial or nuclear RNase P. In contrast to fungi, all putative components of mammalian mitochondrial RNase P are encoded by the nucleus. Intriguingly, no indication of the involvement of a trans-acting RNA was found in mammalian mitochondrial tRNA processing. Mitochondrial RNase P is resistant to rigorous treatments with nucleases and exhibits a protein-like density in Cs2SO4 gradients. Moreover, an analysis of copurifying RNAs revealed no putative RNase P RNA candidates. These data suggest that mammalian mitochondrial RNase P, unlike its nuclear counterpart or its bacterial relatives, is not a ribonucleoprotein but a protein enzyme.

5' end maturation and RNA editing have to precede tRNA 3' processing in plant mitochondria

We report the characterization and partial purification of potato mitochondrial RNase Z, an endonuclease that generates mature tRNA 3' ends. The enzyme consists of one (or more) protein(s) without RNA subunits. Products of the processing reaction are tRNA molecules with 3' terminal hydroxyl groups and 3' trailers with 5' terminal phosphates. The main processing sites are located immediately 3' to the discriminator and one nucleotide further downstream. This endonucleolytic processing at and close to the tRNA 3' end in potato mitochondria suggests a higher similarity to the eukaryotic than to the prokaryotic tRNA 3' processing pathway. Partial purification and separation of RNase Z from the 5' processing activity RNase P allowed us to determine biochemical characteristics of the enzyme. The activity is stable over broad pH and temperature ranges, with peak activity at pH 8 and 30 degrees C. Optimal concentrations for MgCl2 and KCl are 5 mM and 30 mM, respectively. The potato mitochondrial RNase Z accepts only tRNA precursors with mature 5' ends. The precursor for tRNAPhe requires RNA editing for efficient processing by RNase Z.

Transcription initiation sites for sorghum mitochondrial atp9 are positioned immediately 3' to trnfM

Sorghum mitochondrial atp9 is polymorphic among male-sterile cytoplasms, but each cytoplasm is characterized by a major 650 nt transcript, regardless of fertility status. The gene is positioned 323 bp 3' to trnfM. Primer extension revealed multiple atp9 5' transcript termini, distributed from +1 to +28 3' to trnfM; the termini could be labeled with polynucleotide kinase, suggesting that they result from the maturation of trnfM. Guanylyltransferase experiments, however, showed that four of the termini were capable. The juxtaposition of a putative promoter 3' to trnfM results in a unique atp9 transcript population consisting of primary and processed transcripts.

Regulation of gene expression in plant mitochondria

Many genes is plant mitochondria have been analyzed in the past 15 years and regulatory processes controlling gene expression can now be investigated. In vitro systems capable of initiating transcription faithfully at promoter sites have been developed for both monocot and dicot plants and will allow the identification of the interacting nucleic acid elements and proteins which specify and guide transcriptional activities. Mitochondrial activity, although required in all plant tissues, is capable of adapting to specific requirements by regulated gene expression. Investigation of the factors governing the quality and quantity of distinct RNAs will define the extent of interorganelle regulatory interference in mitochondrial gene expression.

RNA editing of larch mitochondrial tRNA(His) precursors is a prerequisite for processing

Larch mitochondria contain a'native'tRNAHis which is absent from angiosperms. Sequence comparisons of genomic DNA and cDNA obtained from unprocessed primary transcripts of the larch mitochondrial gene trnH encoding this tRNA revealed three nucleotide discrepancies. These three nucleotide alterations, in the acceptor stem, D stem and anticodon stem respectively, are conversions of genomic cytidines to thymidines in the cDNA (uridines in the tRNA) and thus resemble the RNA editing events observed in nearly all plant mitochondrial mRNAs. Two cases of editing affecting mitochondrial tRNAs from angiosperms have already been described, but we present here the first example of such events in a gymnosperm mitochondrial tRNA. All three editing events correct mismatched C x A base pairs which appear when folding the gene sequence into the standard cloverleaf structure, thereby improving the secondary structure of the tRNA. When incubated with a heterologous potato mitochondrial processing extract, only the edited form of the larch mitochondrial tRNAHis precursor was efficiently processed in vitro. These data strongly suggest that editing of larch mitochondrial tRNAHis is a prerequisite for its processing.

Characterization of the potato mitochondrial transcription unit containing 'native' trnS (GCU), trnF (GAA) and trnP (UGG)

In order to identify the sequences promoting the expression of plant mitochondrial tRNA genes, we have characterized the trnS (GCU), trnF (GAA) and trnP (UGG) transcription unit of the potato mitochondrial genome. These three tRNA genes were shown to be co-transcribed as a 1800 nt long primary transcript. The transcription initiation site located 305 to 312 nt upstream of trnS is surrounded by a purine-rich region but does not contain the consensus motif proposed as a promoter element in dicotyledonous plants. Differential labelling of potato mitochondrial RNA with either guanylyltransferase or T4 polynucleotide kinase suggests that this site corresponds to the unique functional region responsible for the transcription of the three tRNA genes. The initiation site recently found upstream of Oenothera mitochondrial trnF does not seem to be used in potato mitochondria, although a very similar sequence is present 317 nt upstream of the corresponding potato gene. Major processing sites were identified at the 3' end of each tRNA gene. Another processing site, surrounded by a double hairpin structure, is located 498 nt downstream of trnP in stretch of 10 A residues. As judged from northern experiments, this region is close to the determination site of this transcription unit.

RNA editing is required for efficient excision of tRNA(Phe) from precursors in plant mitochondria

RNA editing corrects a 4C-A69 mismatch to a conventional 4T-A69 Watson-Crick base pair in the acceptor stem of the mitochondrially encoded tRNAPhe in plants. In vitro processing of edited and unedited Oenothera tRNA Phe precursor RNAs with pea mitochondrial protein extracts shows a significant effect of this RNA-editing event on the efficiency of 5' and 3' processing. While mature tRNA molecules are rapidly generated by in vitro processing from edited precursors, the formation of mature tRNAs from unedited pre-tRNAs is considerably reduced. Primer extension analyses of in vitro processing products show that processing at both 5' and 3' termini is governed by the RNA-editing event. Investigation of edited and unedited precursor RNAs by lead cleavage experiments reveals differences in the higher order structures of the pre-tRNAs. The differing conformations are most likely responsible for the altered processing efficiencies of edited and unedited precursor molecules. RNA editing of the tRNAPhe precursors is thus a prerequisite for efficient excision of the mature tRNAPhe in vitro. Hence RNA editing might be involved in regulating the amount of mature tRNAPhe in the steady state RNA pool of mitochondria in higher plants.

Plant mitochondrial RNase P

Molecular investigations in mitochondria of higher plants have to take in account the complicated genomic structure of these organelles and their complex mode of gene expression. Recently tRNA processing activities and particularly RNase P-like activities have been described for mitochondria of mono- and dicot plants. The determined biochemical characteristics of these plant mitochondrial tRNA processing enzymes now allow a comparison to the bacterial prototype from which they evolved. The substrate specificity of the plant mitochondrial RNase P in particular has unique selection parameters distinct from the E. coli RNase P.

The processing of wild type and mutant forms of rat nuclear pre-tRNA(Lys) by the homologous RNase P

The 5' processing of rat pre-tRNA(Lys) and a series of mutant derivatives by rat cytosolic RNase P was examined. In standard, non-kinetic assays, mutant precursors synthesized in vitro with 5' leader sequences of 10, 17, 24, 25, and 46 nucleotides were processed to approximately equal levels and yielded precisely cleaved 5' processed intermediates with the normal 7-base pair aminoacyl stems. The construct containing the tRNA(Lys) with the 46-nucleotide leader was modified by PCR to give a series of pre-tRNA(Lys) mutants designed to measure the effect on processing by (1) substituting the nucleotide at the +1 position, (2) pairing and unpairing the +1 and +72 bases, (3) elongating the aminoacyl stem, and (4) disrupting the helix of the aminoacyl stem. Comparative kinetic analyses revealed that changing the wild type +1G to A, C, or U was well tolerated by the RNase P provided that compensatory changes at +72 created a base pair or a G.U noncanonical pair. Mutants with elongated aminoacyl stems that were produced either by inserting an additional base pair at +3:a + 69:a or by pairing the -1A with a +73U, were processed to yield 7-base pair aminoacyl stems, but with different efficiencies. The efficiency seen with the double insertion mutant was higher than even the wild type precursor, but the -1A-U + 73 mutant was a relatively poor substrate. Disrupting the aminoacyl stem helix by introducing a +7G G + 66 mispairing or by inserting a single G at the +3:a position dramatically reduced the processing efficiency, although the position of cleavage occurred precisely at the wild type cleavage site. However, the single insertion of a C at the +69:a position resulted in an efficiently cleaved precursor, but permitted a minor, secondary cleavage within the leader between the -6 and -5 nucleotides in addition to the dominant wild type scission.

Characterization and partial purification of tRNA processing activities from potato mitochondria

In plant mitochondria, as in most other genetic systems, several enzymatic processing and modification steps are required to yield mature tRNAs from primary transcripts. Three of the enzymes involved, RNase P, 3'-processing activity, and tRNA nucleotidyl transferase, were identified in potato (Solanum tuberosum) mitochondria and have been separated by several purification steps. RNase P was partially purified, with only a few proteins detectable in active fractions after a final glycerol gradient step. A small RNA molecule present in fractions with RNase P activity contains the heptanucleotide conserved in the other known RNase P RNA sequences and may be a fragment of the RNA moiety of the plant mitochondrial RNase P.

A tRNA gene transcription initiation site is similar to mRNA and rRNA promoters in plant mitochondria

The gene for tRNA(Phe) is located 292 nucleotides upstream of the tRNA(Pro) gene in the Oenothera mitochondrial genome. Hybridization with in vitro capped primary transcripts indicates a transcription initiation site in the 5' region of the gene for tRNA(Phe). Primer extension experiments show the presence of precursor transcripts covering tRNA(Phe) and adjacent sequences up to a transcription initiation site 181 or 180 nucleotides upstream of the tRNA gene. The genomic sequence at this transcription initiation site contains the consensus motif derived for putative promoters of mitochondrial protein and rRNA coding genes in dicotyledonous plants. This sequence similarity suggests that tRNAs, rRNAs and mRNAs can be transcribed from homologous promoters in plant mitochondria.

Sequence and transcript analysis of the Nco2.5 Ogura-specific fragment correlated with cytoplasmic male sterility in Brassica cybrids

Sequence analysis of the Ogura-specific mitochondrial DNA (mtDNA) fragment isolated previously from Brassica cybrids carrying Ogura cytoplasmic male sterility (cms) revealed a tRNA(fMet) sequence, a putative 138 amino acid open reading frame (orf138), and a 158 amino acid ORF (orf158) previously observed in mitochondrial genomes from several other plant species. Transcription mapping showed that both ORFs are present on a 1.4 kb cms-specific transcript. The orf158 sequence is also transcribed in fertile plants on a different mRNA, and thus is unlikely to be related to cms. On the other hand, fertile revertant plants lack transcripts of the orf138 sequence, whose possible role in the mechanism of Ogura cms is discussed.

Sugarbeet minicircular mitochondrial DNAs: high-resolution transcript mapping, transcript abundance and copy number determination

Three minicircular mitochondrial DNAs have been studied to address several aspects of transcription in sugarbeet mitochondria. High-resolution transcript mapping experiments have shown that sequences at the 5' termini of minicircle transcripts are highly homologous and resemble sequences at the 5' termini of sugarbeet mainband mitochondrial genes (atpA, atp6). In addition, they show homology to transcript termini of mitochondrial genes from other dicotyledonous plants, suggesting they may function as promoter sequences. Conserved sequences, which most probably act as RNA processing signals, were also identified at the 3' termini of minicircle transcripts. An oligonucleotide probe to a 14 base conserved sequence was used to determine the relative copy numbers of the three minicircle components in male-fertile mitochondria. Copy numbers were roughly equivalent, suggesting minicircles are replicated and/or transmitted with nearly equal efficiency, at least in sugarbeet taproots. Mc.a and Mc.c transcript levels are equivalent, consistent with their template copy number, however; Mc.d transcript levels were significantly lower than expected, implicating additional factors such as promoter strength and/or transcript stability in determining transcript levels in sugarbeet mitochondria, as recently demonstrated in maize.

Evaluation of the Extent of Homologous Chloroplast DNA Sequences in the Mitochondrial Genome of Cowpea (Vigna unguiculata L.)

Southern blot hybridization techniques were used to estimate the extent of chloroplast DNA sequences present in the mitochondrial genome of cowpea (Vigna unguiculata L.) The entire mitochondrial chromosome was homogeneously labeled and used to probe blotted DNA fragments obtained by extensive restriction of the tobacco chloroplast genome. The strongest cross-homologies were obtained with fragments derived from the inverted repeat and the atpBE cluster regions, although most of the clones tested (spanning 85% of the tobacco plastid genome) hybridized to mitochondrial DNA. Homologous chloroplast DNA restriction fragments represent a total of 30 to 68 kilobase pairs, depending upon the presence or absence of tRNA-encoding fragments. Plastid genes showing homology with mitochondrial DNA include those encoding ribosomal proteins, RNA polymerase, subunits of photosynthetic complexes, and the two major rRNAs.