Separation and characterization of 5'- and 3'-tRNA processing nucleases from rat liver mitochondria

Discovery, structure, mechanisms, and evolution of protein-only RNase P enzymes

The endoribonuclease RNase P is responsible for tRNA 5' maturation in all domains of life. A unique feature of RNase P is the variety of enzyme architectures, ranging from dual- to multi-subunit ribonucleoprotein forms with catalytic RNA subunits to protein-only enzymes, the latter occurring as single- or multi-subunit forms or homo-oligomeric assemblies. The protein-only enzymes evolved twice: a eukaryal protein-only RNase P termed PRORP and a bacterial/archaeal variant termed homolog of Aquifex RNase P (HARP); the latter replaced the RNA-based enzyme in a small group of thermophilic bacteria but otherwise coexists with the ribonucleoprotein enzyme in a few other bacteria as well as in those archaea that also encode a HARP. Here we summarize the history of the discovery of protein-only RNase P enzymes and review the state of knowledge on structure and function of bacterial HARPs and eukaryal PRORPs, including human mitochondrial RNase P as a paradigm of multi-subunit PRORPs. We also describe the phylogenetic distribution and evolution of PRORPs, as well as possible reasons for the spread of PRORPs in the eukaryal tree and for the recruitment of two additional protein subunits to metazoan mitochondrial PRORP. We outline potential applications of PRORPs in plant biotechnology and address diseases associated with mutations in human mitochondrial RNase P genes. Finally, we consider possible causes underlying the displacement of the ancient RNA enzyme by a protein-only enzyme in a small group of bacteria.

tRNA 3' processing in yeast involves tRNase Z, Rex1, and Rrp6

Mature tRNA 3' ends in the yeast Saccharomyces cerevisiae are generated by two pathways: endonucleolytic and exonucleolytic. Although two exonucleases, Rex1 and Rrp6, have been shown to be responsible for the exonucleolytic trimming, the identity of the endonuclease has been inferred from other systems but not confirmed in vivo. Here, we show that the yeast tRNA 3' endonuclease tRNase Z, Trz1, is catalyzing endonucleolytic tRNA 3' processing. The majority of analyzed tRNAs utilize both pathways, with a preference for the endonucleolytic one. However, 3'-end processing of precursors with long 3' trailers depends to a greater extent on Trz1. In addition to its function in the nucleus, Trz1 processes the 3' ends of mitochondrial tRNAs, contributing to the general RNA metabolism in this organelle.

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.

The role of mammalian PPR domain proteins in the regulation of mitochondrial gene expression

Pentatricopeptide repeat (PPR) domain proteins are a large family of RNA-binding proteins that are involved in the maturation and translation of organelle transcripts in eukaryotes. They were first identified in plant organelles and their important role in mammalian mitochondrial gene regulation is now emerging. Mammalian PPR proteins, like their plant counterparts, have diverse roles in mitochondrial transcription, RNA metabolism and translation and consequently are important for mitochondrial function and cell health. Here we discuss the current knowledge about the seven mammalian PPR proteins identified to date and their roles in the regulation of mitochondrial gene expression. Furthermore we discuss the mitochondrial RNA targets of the mammalian PPR proteins and methods to investigate the RNA targets of these mitochondrial RNA-binding proteins. This article is part of a Special Issue entitled: Mitochondrial Gene Expression.

LRP130, a pentatricopeptide motif protein with a noncanonical RNA-binding domain, is bound in vivo to mitochondrial and nuclear RNAs

LRP130 (also known as LRPPRC) is an RNA-binding protein that is a constituent of postsplicing nuclear RNP complexes associated with mature mRNA. It belongs to a growing family of pentatricopeptide repeat (PPR) motif-containing proteins, several of which have been implicated in organellar RNA metabolism. We show here that only a fraction of LRP130 proteins are in nuclei and are directly bound in vivo to at least some of the same RNA molecules as the nucleocytoplasmic shuttle protein hnRNP A1. The majority of LRP130 proteins are located within mitochondria, where they are directly bound to polyadenylated RNAs in vivo. In vitro, LRP130 binds preferentially to polypyrimidines. This RNA-binding activity maps to a domain in its C-terminal region that does not contain any previously described RNA-binding motifs and that contains only 2 of the 11 predicted PPR motifs. Therefore, LRP130 is a novel type of RNA-binding protein that associates with both nuclear and mitochondrial mRNAs and as such is a potential candidate for coordinating nuclear and mitochondrial gene expression. These findings provide the first identification of a mammalian protein directly bound to mitochondrial RNA in vivo and provide a possible molecular explanation for the recently described association of mutations in LRP130 with cytochrome c oxidase deficiency in humans.

Recombinant RNase Z does not recognize CCA as part of the tRNA and its cleavage efficieny is influenced by acceptor stem length

One of the essential maturation steps to yield functional tRNA molecules is the removal of 3'-trailer sequences by RNase Z. After RNase Z cleavage the tRNA nucleotidyl transferase adds the CCA sequence to the tRNA 3'-terminus, thereby generating the mature tRNA. Here we investigated whether a terminal CCA triplet as 3'-trailer or embedded in a longer 3'-trailer influences cleavage site selection by RNase Z using three activities: a recombinant plant RNase Z, a recombinant archaeal RNase Z and an RNase Z active wheat extract. A trailer of only the CCA trinucleotide is left intact by the wheat extract RNase Z but is removed by the recombinant plant and archaeal enzymes. Thus the CCA triplet is not recognized by the RNase Z enzyme itself, but rather requires cofactors still present in the extract. In addition, we investigated the influence of acceptor stem length on cleavage by RNase Z using variants of wild-type tRNATyr. While the wild type and the variant with 8 base pairs in the acceptor stem were processed efficiently by all three activities, variants with shorter and longer acceptor stems were poor substrates or were not cleaved at all.

3'-processing of yeast tRNATrp precedes 5'-processing

Previous analyses of eukaryotic pre-tRNAs processing have reported that 5'-cleavage by RNase P precedes 3'-maturation. Here we report that in contrast to all other yeast tRNAs analyzed to date, tRNA(Trp) undergoes 3'-maturation prior to 5'-cleavage. Despite its unusual processing pathway, pre-tRNA(Trp) resembles other pre-tRNAs, showing dependence on the essential Lsm proteins for normal processing and efficient association with the yeast La homolog, Lhp1p. tRNA(Trp) is also unusual in not requiring Lhp1p for 3' processing and stability. However, other Lhp1p-independent tRNAs, tRNA(2)(Lys) and tRNA(1)(Ile), follow the normal pathway of 5'-processing prior to 3-processing.

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.

This is the end: processing, editing and repair at the tRNA 3'-terminus

The generation of a mature tRNA 3'-end is an important step in the processing pathways leading to functional tRNA molecules. While 5'-end processing by RNase P is similar in all organisms, generation of the mature 3'-terminus seems to be more variable and complex. The first step in this reaction is the removal of 3'-trailer sequences. In bacteria, this is a multistep process performed by endo- and exonucleases. In contrast, the majority of eukaryotes generate the mature tRNA 3'-end in a single step reaction, which consists of an endonucleolytic cut at the tRNA terminus. After removal of the 3'-trailer, a terminal CCA triplet has to be added to allow charging of the tRNA with its cognate amino acid. The enzyme catalyzing this reaction is tRNA nucleotidyltransferase, homologs of which have been found in representatives of all three kingdoms. Furthermore, in metazoan mitochondria, some genes encode 3'-terminally truncated tRNAs, which are restored in an editing reaction in order to yield functional tRNAs. Interestingly, this reaction is not restricted to distinct tRNAs, but seems to act on a variety of tRNA molecules and represents therefore a more general tRNA repair mechanism than a specialized editing reaction. In this review, the current knowledge about these crucial reactions is summarized.

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.

The final cut. The importance of tRNA 3'-processing

To generate functional tRNA molecules, precursor RNAs must undergo several processing steps. While the enzyme that generates the mature tRNA 5'-end, RNase P, has been thoroughly investigated, the 3'-processing activity is, despite its importance, less understood. While nothing is known about tRNA 3'-processing in archaea, the phenomenon has been analysed in detail in bacteria and is known to be a multistep process involving several enzymes, including both exo- and endonucleases. tRNA 3'-end processing in the eukaryotic nucleus seems to be either exonucleolytic or endonucleolytic, depending on the organism analysed, whereas in organelles, 3'-end maturation occurs via a single endonucleolytic cut. An interesting feature of organellar tRNA 3'-processing is the occurrence of overlapping tRNA genes in metazoan mitochondria, which presents a unique challenge for the mitochondrial tRNA maturation enzymes, since it requires not only the removal but also the addition of nucleotides by an editing reaction.

The RNase P associated with HeLa cell mitochondria contains an essential RNA component identical in sequence to that of the nuclear RNase P

The mitochondrion-associated RNase P activity (mtRNase P) was extensively purified from HeLa cells and shown to reside in particles with a sedimentation constant ( approximately 17S) very similar to that of the nuclear enzyme (nuRNase P). Furthermore, mtRNase P, like nuRNase P, was found to process a mitochondrial tRNA(Ser(UCN)) precursor [ptRNA(Ser(UCN))] at the correct site. Treatment with micrococcal nuclease of highly purified mtRNase P confirmed earlier observations indicating the presence of an essential RNA component. Furthermore, electrophoretic analysis of 3'-end-labeled nucleic acids extracted from the peak of glycerol gradient-fractionated mtRNase P revealed the presence of a 340-nucleotide RNA component, and the full-length cDNA of this RNA was found to be identical in sequence to the H1 RNA of nuRNase P. The proportions of the cellular H1 RNA recovered in the mitochondrial fractions from HeLa cells purified by different treatments were quantified by Northern blots, corrected on the basis of the yield in the same fractions of four mitochondrial nucleic acid markers, and shown to be 2 orders of magnitude higher than the proportions of contaminating nuclear U2 and U3 RNAs. In particular, these experiments revealed that a small fraction of the cell H1 RNA (of the order of 0.1 to 0.5%), calculated to correspond to approximately 33 to approximately 175 intact molecules per cell, is intrinsically associated with mitochondria and can be removed only by treatments which destroy the integrity of the organelles. In the same experiments, the use of a probe specific for the RNA component of RNase MRP showed the presence in mitochondria of 6 to 15 molecules of this RNA per cell. The available evidence indicates that the levels of mtRNase P detected in HeLa cells should be fully adequate to satisfy the mitochondrial tRNA synthesis requirements of these cells.

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.

A novel RNA species from the turtle mitochondrial genome: induction and regulation of transcription and processing under anoxic and freezing stresses

The present study identifies a previously cloned cDNA, pBTaR914, as homologous to the mitochondrial WANCY (tryptophan, alanine, asparagine, cysteine, and tyrosine) tRNA gene cluster. This cDNA clone has a 304-bp sequence and its homologue, pBTaR09, has a 158-bp sequence with a long poly(A)+ tail (more than 60 adenosines). RNA blotting analysis using pBTaR914 probe against the total RNA from the tissues of adult and hatchling turtles revealed five bands: 540, 1800, 2200, 3200, and 3900 nucleotides (nt). The 540-nt transcript is considered to be an intact mtRNA unit from a novel mtDNA gene designated WANCYHP that overlaps the WANCY tRNA gene cluster region. This transcript was highly induced by both anoxic and freezing stresses in turtle heart. The other transcripts are considered to be the processed intermediates of mtRNA transcripts with WANCYHP sequence. All these transcripts were differentially regulated by anoxia and freezing in different organs. The data suggest that mtRNA processing is sensitive to regulation by external stresses, oxygen deprivation, and freezing. Furthermore, the fact that the WANCYHP transcript is highly induced during anoxic exposure suggests that it may play an important role in the regulation of mitochondrial activities to coordinate the physiological adaptation to anoxia.

Purification and characterization of the precursor tRNA 3'-end processing nuclease from Aspergillus nidulans

The precursor-tRNA 3'-end processing nuclease activity was purified homogeneously about 15,300 fold from the heat-treated fraction. The precursor-tRNA 3'-end processing nuclease was a single polypeptide of 160,000 Da. This nuclease generates a mature 3'-end of nuclear tRNA(Asp) of Aspergillus nidulans by the endonuclease activity and prefers the 5'-end processed tRNA(Asp) rather than primary precursor-tRNA(Asp) as a substrate. However, this enzyme did not process both primary mitochondrial precursor-tRNA(His) and 5'-end processed mitochondrial precursor-tRNA(His) of A. nidulans.

Molecular phenotype of a human lymphoblastoid cell-line homoplasmic for the np 7445 deafness-associated mitochondrial mutation

We have studied mitochondrial gene expression and metabolic function in a human lymphoblastoid cell-line homoplasmic for the np 7445, deafness-associated mitochondrial DNA mutation. The mutation maps to the 3' termini of the oppositely oriented genes encoding cytochrome oxidase subunit I (COI) and tRNA-ser(UCN). In comparison with control lymphoblastoid cells, we detected a marked depletion (> 60%) of tRNA-ser(UCN). There was, however, no significant impairment of respiratory function, no alteration to the structure or abundance of COI mRNA or its precursors, and no detectable abnormality of mitochondrial protein synthesis. We also found considerable tissue-variation in the abundance of tRNA-ser(UCN). We propose that the tissue-specific phenotype associated with this mutation results from an inherent deficiency in the processing of the mutant pre-tRNA, that becomes limiting for protein synthesis only in a restricted set of cells of the auditory system in which the tRNA is, for other reasons, already at a critically low level.

The evolution of the RNase P- and RNase MRP-associated RNAs: phylogenetic analysis and nucleotide substitution rate

We report a detailed evolutionary study of the RNase P- and RNase MRP- associated RNAs. The analyses were performed on all the available complete sequences of RNase MRP (vertebrates, yeast, plant), nuclear RNase P (vertebrates, yeast), and mitochondrial RNase P (yeast) RNAs. For the first time the phylogenetic distance between these sequences and the nucleotide substitution rates have been quantitatively measured.The analyses were performed by considering the optimal multiple alignments obtained mostly by maximizing similarity between primary sequences. RNase P RNA and MRP RNA display evolutionary dynamics following the molecular clock. Both have similar rates and evolve about one order of magnitude faster than the corresponding small rRNA sequences which have been, so far, the most common gene markers used for phylogeny. However, small rRNAs evolve too slowly to solve close phylogenetic relationships such as those between mammals. The quicker rate of RNase P and MRP RNA allowed us to assess phylogenetic relationships between mammals and other vertebrate species and yeast strains. The phylogenetic data obtained with yeasts perfectly agree with those obtained by functional assays, thus demonstrating the potential offered by this approach for laboratory experiments.

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.

Purification and characterization of mitochondrial ribonuclease P from Aspergillus nidulans

Mitochondrial ribonuclease (RNase) P from Aspergillus nidulans was purified to near homogeneity using whole-cell extract as the starting material. A 4400-fold purification with a yield of 5.2% was achieved by ammonium sulfate fractionation, heat treatment, and five types of column chromatography, including tRNA-affinity column chromatography. This enzyme, which has a molecular mass of 232 kDa determined by glycerol gradient sedimentation analysis, appears to be composed of seven polypeptides and an RNA moiety. These seven polypeptides consistently copurified with the RNase P activity through two ion-exchange chromatography columns and in a glycerol gradient. As judged by nuclease sensitivity, the enzyme requires an RNA component for its activity. The 3'-end-labeled RNAs that copurified with the enzyme displayed identical sequences but had variable lengths for the 5' end, indicating that they originated from a common RNA molecule, the putative RNA component of RNase P. The purified enzyme cleaved mitochondrial precursor tRNAHis, resulting in an 8-bp acceptor stem. This implies that the purified RNase P is a mitochondrial enzyme and that an additional guanylate residue (at position -1) of tRNAHis in A. nidulans mitochondria is generated by a mode that is analogous to the generation of their counterparts in prokaryotes and chloroplasts.

The RNA component of mitochondrial ribonuclease P from Aspergillus nidulans

Several RNA molecules that copurified with Aspergillus nidulans mitochondrial ribonuclease (RNase) P were identified [Lee, Y C., Lee, B. J., Hwang, D. S. & Kang, H. S. (1996) Eur J. Biochem. 235, 289-296], and their partial sequences were determined. Using an oligonucleotide probe, we cloned and mapped the gene encoding this putative RNA component of RNase P (RNase P-RNA), situated between URFA3 (unidentified reading frame A3) and cobA (apocytochrome b) genes in the mitochondrial genome of A. nidulans. The gene is extremely (A+T)-rich and contains two regions of sequence similarity conserved among the known mitochondrial RNase P-RNAs and the eubacterial RNase P-RNAs. The determination of 5' and 3' termini by primer extension and sequencing indicated that the length of the RNA transcript is 232 nucleotides. Northern-blot analysis revealed that its only subcellular location was the mitochondria. Two RNase P-RNA fragments of 110 nucleotides and 80 nucleotides, each containing one of the two conserved regions, could be recovered from the nuclease-treated enzyme without significant loss of activity. The sizes of these fragments appeared to be the minimum lengths required for the vitro activity of the enzyme.

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 RNase P of Dictyostelium discoideum

Ribonuclease P (RNase P) is a key enzyme involved in tRNA biosynthesis. It catalyses the endonucleolytic cleavage of nearly all tRNA precursors to produce 5'-end matured tRNA. RNase P activity has been found in all organisms examined, from bacteria to mammals. Eubacterial RNase RNA is the only known RNA enzyme which functions in trans in nature. Similar behaviour has not been demonstrated in RNase P enzymes examined from archaebacteria or eukaryotes. Characterisation of RNase P enzymes from more diverse eukaryotic species, including the slime mold Dictyostelium discoideum, is useful for comparative analysis of the structure and function of eukaryotic RNase P.

Human mitochondrial tRNA processing

tRNA processing is a central event in mammalian mitochondrial gene expression. We have identified key enzymatic activities (ribonuclease P, precursor tRNA 3'-endonuclease, and ATP(CTP)-tRNA-specific nucleotidyltransferase) that are involved in HeLa cell mitochondrial tRNA maturation. Different mitochondrial tRNA precursors are cleaved precisely at the tRNA 5'- and 3'-ends in a homologous mitochondrial in vitro processing system. The cleavage at the 5'-end precedes that at the 3'-end, and the tRNAs are substrates for the specific CCA addition in the same in vitro system. Using a comparative enzymatic approach as well as biochemical and immunological techniques, we furthermore demonstrate that human cells contain two distinct enzymes that remove 5'-extensions from tRNA precursors, the previously characterized nuclear and the newly identified mitochondrial ribonuclease P. These two cellular isoenzymes have different substrate specificities that seem to be well adapted to their structurally disparate mitochondrial and nuclear tRNA substrates. This kind of approach may also help to understand the structural diversities and commonalities of tRNAs.

Partial purification and characterization of RNase P from Dictyostelium discoideum

Ribonuclease P (RNase P) from Dictyostelium discoideum has been purified 470-fold. D. discoideum RNase P cleaves the precursor to Schizosaccharomyces pombe suppressor tRNA(Ser) at the same site as S. pombe RNase P, producing the mature 5' end of tRNA(Ser). pH and temperature optima for enzyme activity are 7.6 and 37 degrees C, respectively. The enzyme shows optimal activity in the presence of 5 mM MgCl2 and 10 mM NH4Cl or 5 mM KCl. The apparent Km for the S. pombe tRNA precursor derived from the supS1 tRNA(Ser) gene is 240 nM, and the apparent Vmax is 3.6 pmol/min. Inhibition of D. discoideum RNase P by proteinase K and micrococcal nuclease strongly indicates that the activity requires both protein and RNA components. In cesium sulfate density gradients, the enzyme has a buoyant density of 1.23 g/ml, indicating a low RNA/protein ratio for the holoenzyme.

Ordered processing of the polygenic transcripts from a mitochondrial tRNA gene cluster in K. lactis

In Saccharomyces cerevisiae, transcription of the mitochondrial genome starts at multiple initiation sites and is followed by the processing of multigenic transcripts at the 5' and 3' termini of tRNA sequences and in some intergenic regions. We have used a comparative approach to investigate the structure and function of the latter processing sites. We present here an analysis of the transcripts of a cluster of tRNA genes from the mitochondrial genome of Kluyveromyces lactis. The gene order of this cluster is the same as that of the cluster in S. cerevisiae but the sequence of the intergenic regions is different. A detailed analysis of transcripts has been performed using S1 mapping and primer extension techniques. The results can be summarized as follows: (1) transcription of the cluster very probably starts at initiation sites having the nonanucleotide sequence TTATAAGTA (which acts as a promoter in S. cerevisiae) and yields polygenic transcripts; (2) processing of these transcripts seems to occur through an ordered pathway of endonucleolytic events in which some tRNA sequences are preferentially excised and some endonucleolytic cuts occur more readily than others; (3) in two intergenic regions, strong signals indicate the existence of processing events. The sequences around these sites are similar in sequence and localization to S. cerevisiae intergenic processing sites, indicating a possible functional importance in maintaining a conserved order of tRNA genes in different species of yeasts.

Identification of a 100-kDa protein associated with nuclear ribonuclease P activity in Schizosaccharomyces pombe

Ribonuclease P from the fission yeast Schizosaccharomyces pombe has been purified to apparent homogeneity. A purification of 23,000-fold was achieved by four fractionation steps with DEAE-cellulose chromatography, phosphocellulose chromatography, glycerol-gradient fractionation and finally tRNA-affinity chromatography. A 100-kDa protein was present in the most pure preparations in amounts approximately stoichiometric with the previously identified RNA components of the enzyme, K1-RNA and K2-RNA [Krupp, G., Cherayil, B., Frendeway, D., Nishikawa, S. & Söll, D. (1986) EMBO J. 5, 1697-1703]. A cross-linking experiment utilizing a 4-thiouridine-substituted precursor tRNA demonstrated that the 100-kDa protein interacts with the ribonuclease P substrate in a specific fashion. We therefore conclude that the protein component of S. pombe ribonuclease P is a 100-kDa protein.

Characterization of ribonuclease P isolated from rat liver cytosol

Rat liver ribonuclease P was isolated from a cytosolic fraction and shown to have optimal activity in the presence of 1 mM MgCl2 and 150-200 mM KCl using Escherchia coli pre-tRNA(Tyr) as substrate. In cesium sulfate isopycnic density gradients, the enzyme had a buoyant density of 1.36 g/ml, indicating that it is a ribonucleoprotein complex. Analysis of the RNAs in the enzyme sample purified through two successive Cs2SO4 density gradient steps revealed the copurification of two major species of RNA (RRP1 and RRP2) along with several less abundant RNAs. Rat liver ribonuclease P activity was insensitive to micrococcal nuclease pretreatment. However, the nuclease-treated preparations contained several incompletely degraded RNA species that may have been sufficient to support the ribonuclease P activity. When RNase A was substituted for micrococcal nuclease, the ribonuclease P activity was diminished by greater than 90%, suggesting the requirement for an RNA subunit for activity.

Nuclear gadgets in mitochondrial DNA replication and transcription

In mammalian mitochondrial DNA, activation of the light-strand promoter mediates both priming of leading-strand replication and initiation of light-strand transcription. Accurate and efficient transcription requires at least two proteins: mitochondrial RNA polymerase and a separable transcription factor that can function across species boundaries. Subsequently, primer RNAs are cleaved by a site-specific ribonucleoprotein endoribonuclease that recognizes short, highly conserved sequence elements in the RNA substrate.

Nucleotide sequence of nine protein-coding genes and 22 tRNAs in the mitochondrial DNA of the sea star Pisaster ochraceus

We have cloned and sequenced over 9 kb of the mitochondrial genome from the sea star Pisaster ochraceus. Within a continuous 8.0-kb fragment are located the genes for NADH dehydrogenase subunits 1, 2, 3, and 4L (ND1, ND2, ND3, and ND4L), cytochrome oxidase subunits I, II, and III (COI, COII, and COIII), and adenosine triphosphatase subunits 6 and 8 (ATPase 6 and ATPase 8). This large fragment also contains a cluster of 13 tRNA genes between ND1 and COI as well as the genes for isoleucine tRNA between ND1 and ND2, arginine tRNA between COI and ND4L, lysine tRNA between COII and ATPase 8, and the serine (UCN) tRNA between COIII and ND3. The genes for the other five tRNAs lie outside this fragment. The gene for phenylalanine tRNA is located between cytochrome b and the 12S ribosomal genes. The genes for tRNA(glu) and tRNA(thr) are 3' to 12S ribosomal gene. The tRNAs for histidine and serine (AGN) are adjacent to each other and lie between ND4 and ND5. These data confirm the novel gene order in mitochondrial DNA (mtDNA) of sea stars and delineate additional distinctions between the sea star and other mtDNA molecules.