Purification and some properties of a specific nuclease which cleaves transfer RNA precursors from the posterior silk gland of Bombyx mori.

A specific endonuclease involved in the processing of tRNA precursors was isolated and partially purified from the posterior silk gland of Bombyx mori, and designated as RNase P.Bmo. This enzyme was shown to catalyze the conversion of 4.5 S precursor RNA to 4.1 S RNA by trimming the 5'-additional segment from the precursor RNA. RNase P.Bmo required divalent cations, Mg2+ or Mn2+. In the presence of these divalent cations, K+ or NH4+ activated the RNase P.Bmo reaction. Optimum pH was observed around 8.0. Ribosomal RNA's and mature tRNA from the silk gland were not cleaved by RNase P.Bmo. A 4.5 S precursor RNA fraction containing formycin, an adenosine analog, was less susceptible to RNase P.Bmo than the normal one. These results indicate that RNase P.Bmo has a high substrate specificity. An additional nuclease(s) was isolated. This activity was assumed to remove the extra 3'-segment of the 4.5 S precursor RNA.     

A site in a tRNA precursor that can be processed by the whole RNase P enzyme but not by the RNA alone

A precursor molecule for 10 Sb RNA, the RNA moiety of the RNA processing enzyme RNase P, was purified, characterized for enzymatic activity, and compared to 10 Sb RNA and to RNase P. In these studies the K RNA, a dimeric precursor of tRNAGln-tRNALeu, coded by bacteriophage T4, was used as a substrate. This precursor contains two RNase P cleavage sites, one at each 5' end of the two tRNAs. The precursor 10 Sb and 10 Sb RNAs have the capacity to cleave the precursor tRNA molecule but only at the 5' end of tRNALeu, not at the 5' end of tRNAGln. Even when a substrate was prepared that contained only one site for RNase P (the one next to tRNAGln), this substrate was not cleaved by the RNA alone while the whole enzyme was effective in processing this substrate. The possible function of the protein of RNase P in the enzymatic reaction is discussed.     

RNase P activity in the mitochondria of Saccharomyces cerevisiae depends on both mitochondrion and nucleus-encoded components.

A requisite step in the biosynthesis of tRNA is the removal of 5' leader sequences from tRNA precursors. We have detected an RNase P activity in yeast mitochondrial extracts that can carry out this reaction on a homologous precursor tRNA. This mitochondrial RNase P was sensitive to both micrococcal nuclease and protease, demonstrating that it requires both a nucleic acid and protein for activity. The presence of RNase P activity in vitro directly correlated with the presence of a locus on yeast mitochondrial DNA previously shown by genetic and biochemical studies to be required for tRNA maturation. The product of the locus, the 9S RNA, and this newly described mitochondrial RNase P activity cofractionated, providing further evidence that the 9S RNA is the RNA component of yeast mitochondrial RNase P.     

Interplay among processing and degradative enzymes and a precursor ribonucleic acid in the selective maturation and maintenance of ribonucleic acid molecules

In order to understand why the first tRNA (tRNAGln) in the T4 tRNA gene cluster is not produced when T4 infects an RNase III- mutant of Escherichia coli, RNA metabolism was analyzed in RNase III- RNase P- (rnc, rnp) cells infected with bacteriophage T4. After such an infection a new dimeric precursor RNA molecule of tRNAGln and tRNALeu has been identified and analyzed. This molecule is structurally very similar to K band RNA that accumulates in rnc+ rnp strains. It is four nucleotides shorter than K RNA at the 5' end. This molecule like K RNA contains two RNase P processing sites at the 5' ends of each tRNA. Both sites are accessible to RNase P. However, while in the K RNA the site at the 5' end of tRNALeu (the site in the middle of the substrate) is more efficiently cleaved than the other site, this differential is even increased in the Ks (K like) molecule. This difference is sufficiently large that in vivo in the RNase III- strain the smaller precursor of tRNAGln is degraded rather than being matured to tRNAGln by RNase P. This information contributes to the elucidation of the key role of RNase III in the processing of T4 tRNA. It shows the dependence of RNase P activity at the 5' end of tRNAGln on a correct and specific cleavage by RNase III at a position six nucleotides proximal to the RNase P site, and it explains why in the absence of RNase III the first tRNA in the T4 tRNA cluster, tRNAGln, does not accumulate.     

The nucleotide sequence of a precursor to the glycine- and threonine-specific transfer ribonucleic acids of Escherichia coli.

The primary nucleotide sequence of an Escherichia coli tRNA precursor molecule has been determined. This precursor RNA, specified by the transducing phage lambdah80dglyTsuA36 thrT tyrT, accumulates in a mutant strain temperature-sensitive for RNase P activity. The 170-nucleotide precursor RNA is processed by E. coli extracts to form mature tRNA Gly 2 suA36 and tRNA Thr ACU/C. The sequence of the precursor is pG-U-U-C-C-A-G-G-A-U-G-C-G-G-G-C-A-U-C-G-U-A-U-A-A-U-G-G-C-U-A-U-U-A-C-C-U-C-A-G-C-C-U-N-C-U-A-A-G-C-U-G-A-U-G-A-U-G-C-G-G-G-T-psi-C-G-A-U-U-C-C-C-G-C-U-G-C-C-C-G-C-U-C-C-A-A-G-A-U-G-U-G-C-U-G-A-U-A-U-A-G-C-U-C-A-G-D-D-G-G-D-A-G-A-G-C-G-C-A-C-C-C-U-U-G-G-U-mt6A-A-G-G-G-U-G-A-G-m7G-U-C-G-G-C-A-G-T-psi-C-G-A-A-U-C-U-G-C-C-U-A-U-C-A-G-C-A-C-C-A-C-U-UOH(tRNA sequences are italicized). It contains the entire primary nucleotide sequences of tRNA Gly2 suA36 and tRNA Thr ACU/C, including the common 3'-terminal sequence, CCA. Nineteen additional nucleotides are present, with 10 at the 5' end, 3 at the 3' end, and the remaining 6 in the inter-tRNA spacer region. RNase P cleaves the precursor specifically at the 5' ends of the mature tRNA sequences.     

Eukaryotic RNase P: role of RNA and protein subunits of a primordial catalytic ribonucleoprotein in RNA-based catalysis

Ribonuclease P (RNase P) is an essential enzyme that processes the 5' leader sequence of precursor tRNA. Eubacterial RNase P is an RNA enzyme, while its eukaryotic counterpart acts as catalytic ribonucleoprotein, consisting of RNA and numerous protein subunits. To study the latter form, we reconstitute human RNase P activity, demonstrating that the subunits H1 RNA, Rpp21, and Rpp29 are sufficient for 5' cleavage of precursor tRNA. The reconstituted RNase P precisely delineates its cleavage sites in various substrates and hydrolyzes the phosphodiester bond. Rpp21 and Rpp29 facilitate catalysis by H1 RNA, which seems to require a phylogenetically conserved pseudoknot structure for function. Unexpectedly, Rpp29 forms a catalytic complex with M1 RNA of E. coli RNase P. The results uncover the core components of eukaryotic RNase P, reveal its evolutionary origin in translation, and provide a paradigm for studying RNA-based catalysis by other nuclear and nucleolar ribonucleoprotein enzymes.     

Alterations in the intracellular level of a protein subunit of human RNase P affect processing of tRNA precursors

The human ribonucleoprotein ribonuclease P (RNase P), processing tRNA, has at least 10 distinct protein subunits. Many of these subunits, including the autoimmune antigen Rpp38, are shared by RNase MRP, a ribonucleoprotein enzyme required for processing of rRNA. We here show that constitutive expression of exogenous, tagged Rpp38 protein in HeLa cells affects processing of tRNA precursors. Alterations in the site-specific cleavage and in the steady-state level of 3′ sequences of the internal transcribed spacer 1 of rRNA are also observed. These processing defects are accompanied by selective shut-off of expression of Rpp38 and by low expression of the tagged protein. RNase P purified from these cells exhibits impaired activity in vitro. Moreover, inhibition of Rpp38 by the use of small interfering RNA causes accumulation of the initiator methionine tRNA precursor. Expression of other protein components, but not of the H1 RNA subunit, is coordinately inhibited. Our results reveal that normal expression of Rpp38 is required for the biosynthesis of intact RNase P and for the normal processing of stable RNA in human cells.     

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.     

Phylogenetic comparative chemical footprint analysis of the interaction between ribonuclease P RNA and tRNA.

Ribonuclease P RNA is the catalytic moiety of the ribonucleoprotein enzyme that endonucleolytically cleaves precursor sequences from the 5' ends of pre-tRNAs. The bacterial RNase P RNA-tRNA complex was examined with a footprinting approach, utilizing chemical modification to determine RNase P RNA nucleotides that potentially contact tRNA. RNase P RNA was modified with dimethylsulfate or kethoxal in the presence or absence of tRNA, and sites of modification were detected by primer extension. Comparison of the results reveals RNase P bases that are protected from modification upon binding tRNA. Analyses were carried out with RNase P RNAs from three different bacteria: Escherichia coli, Chromatium vinosum and Bacillus subtilis. Discrete bases of these RNAs that lie within conserved, homologous portions of the secondary structures are similarly protected. One protection among all three RNAs was attributed to the precursor segment of pre-tRNA. Experiments using pre-tRNAs containing precursor segments of variable length demonstrate that a precursor segment of only 2-4 nucleotides is sufficient to confer this protection. Deletion of the 3'-terminal CCA sequence of tRNA correlates with loss of protection of a particular loop in the RNase P RNA secondary structure. Analysis of mutant tRNAs containing sequential 3'-terminal deletions suggests a relative orientation of the bound tRNA CCA to that loop.     

RNase P from bacteria. Substrate recognition and function of the protein subunit

RNase P recognizes many different precursor tRNAs as well as other substrates and cleaves all of them accurately at the expected position. RNase P recognizes the tRNA structure of the precursor tRNA by a set of interactions between the catalytic RNA subunit and the T- and acceptor-stems mainly, although residues in the 5-leader sequence as well as the 3-terminal CCA are important. These conclusions have been reached by several studies on mutant precursor tRNAs as well as cross-linking studies between RNase P RNA and precursor tRNAs. The protein subunit of RNase P seems also to affect the way that the substrate is recognized as well as the range of substrates that can be used by RNase P, although the protein does not seem to interact directly with the substrates. The interaction between the protein and RNA subunits of RNase P has been extensively studiedin vitro. The protein subunit sequence is not highly conserved among bacteria, however different proteins are functionally equivalent as heterologous reconstitution of the RNase P holoenzyme can be achieved in many cases.Abbreviations C5 protein protein subunit fromE. coli RNase P - EGS external guide sequence - M1 RNA RNA subunit formE. coli RNase P - ptRNA precursor tRNA - RNase P ribonuclease P     

The road to RNase P

In 1989, Sidney Altman and Thomas R. Cech shared the Nobel Prize in Chemistry for their discovery of catalytic properties of RNA. Cech was studying the splicing of RNA in a unicellular organism called Tetrahymena thermophila. He found that the precursor RNA could splice in vitro in the absence of proteins. Altman studied ribonuclease P (RNase P), a ribonucleoprotein that is a key enzyme in the biosynthesis of tRNA. RNase P is an RNA processing endonuclease that specifically cleaves precursors of tRNA, releasing 5' precursor sequences and mature tRNAs. RNase P is involved in processing all species of tRNA and is present in all cells and organelles that carry out tRNA synthesis. What follows is a personal recollection by Altman of how he came to study this remarkable enzyme.     

Chloroplast ribonuclease P does not utilize the ribozyme-type pre-tRNA cleavage mechanism

The transfer RNA 5' maturation enzyme RNase P has been characterized in Bacteria, Archaea, and Eukarya. The purified enzyme from all three kingdoms is a ribonucleoprotein containing an essential RNA subunit; indeed, the RNA subunit of bacterial RNase P RNA is the sole catalytic component. In contrast, the RNase P activity isolated from spinach chloroplasts lacks an RNA component and appears to function as a catalytic protein. Nonetheless, the chloroplast enzyme recognizes a pre-tRNA substrate for E. coli RNase P and cleaves it as efficiently and precisely as does the bacterial enzyme. To ascertain whether there are differences in catalytic mechanism between an all-RNA and an all-protein RNase P, we took advantage of the fact that phosphodiester bond selection and hydrolysis by the E. coli RNase P ribozyme is directed by a Mg2+ ion coordinated to the nonbridging pro-Rp oxygen of the scissile bond, and is blocked by sulfur replacement of this oxygen. We therefore tested the ability of the chloroplast enzyme to process a precursor tRNA containing this sulfur substitution. Partially purified RNase P from spinach chloroplasts can accurately and efficiently process phosphorothioate-substituted pre-tRNAs; cleavage occurs exclusively at the thio-containing scissile bond. The enzymatic throughput is fivefold slower, consistent with a general chemical effect of the phosphorothioate substitution rather than with a metal coordination deficiency. The chloroplast RNase P reaction mechanism therefore does not involve a catalytic Mg2+ bonded to the pro-Rp phosphate oxygen, and hence is distinct from the mechanism of the bacterial ribozyme RNase P.     

RNase P: role of distinct protein cofactors in tRNA substrate recognition and RNA-based catalysis

The Escherichia coli ribonuclease P (RNase P) has a protein component, termed C5, which acts as a cofactor for the catalytic M1 RNA subunit that processes the 5′ leader sequence of precursor tRNA. Rpp29, a conserved protein subunit of human RNase P, can substitute for C5 protein in reconstitution assays of M1 RNA activity. To better understand the role of the former protein, we compare the mode of action of Rpp29 to that of the C5 protein in activation of M1 RNA. Enzyme kinetic analyses reveal that complexes of M1 RNA–Rpp29 and M1 RNA–C5 exhibit comparable binding affinities to precursor tRNA but different catalytic efficiencies. High concentrations of substrate impede the activity of the former complex. Rpp29 itself exhibits high affinity in substrate binding, which seems to reduce the catalytic efficiency of the reconstituted ribonucleoprotein. Rpp29 has a conserved C-terminal domain with an Sm-like fold that mediates interaction with M1 RNA and precursor tRNA and can activate M1 RNA. The results suggest that distinct protein folds in two unrelated protein cofactors can facilitate transition from RNA- to ribonucleoprotein-based catalysis by RNase P.     

Novel mechanisms for maturation of chloroplast transfer RNA precursors

Despite the prokaryotic origins of chloroplasts, a plant chloroplast tRNA precursor is processed in a homologous in vitro system by a pathway distinct from that observed in Escherichia coli, but identical to that utilized for maturation of nuclear pre-tRNAs. The mature tRNA 5' terminus is generated by the site-specific endonucleolytic cleavage of an RNase P (or P-type) activity. The 3' end is likewise produced by a single precise endonucleolytic cut at the 3' terminus of the encoded tRNA domain. This is the first complete structural characterization of an organellar tRNA processing system using a homologous substrate. In contrast to eubacterial RNase P, chloroplast RNase P does not appear to contain an RNA subunit. The chloroplast activity bands with bulk protein at 1.28 g/ml in CsCI density gradients, whereas E.coli RNase P bands as ribonucleoprotein at 1.73 g/ml. Chloroplast RNase P activity survives treatment with micrococcal nuclease (MN) at levels 10- to 100-fold higher than those required to totally inactivate the E.coli enzyme. The chloroplast system is sensitive to a suppression of tRNA processing, caused by binding of inactive MN to pre-tRNA substrate, which is readily overcome by addition of carrier RNA to the assay.     

Transfer RNA precursors are accumulated in Escherichia coli in the absence of RNase E

A temperature-sensitive Escherichia coli mutant, which contains a heat-labile RNase E, fails to produce 5-S rRNA at a non-permissive temperature. It accumulates a number of RNA molecules in the 4-12-S range. One of these molecules, a 9-S RNA, is a precursor to 5-S rRNA [Ghora, B. K. and Apirion, D. (1978) Cell, 15, 1055-1056]. These molecules were purified and processed in a cell-free system. Some of these RNA molecules, after processing, give rise to products the size of transfer RNA, but not to 5-S-rRNA. Further characterization of the processed products of one such precursor molecule shows that it contains tRNA1Leu and tRNA1His. RNase E is necessary but not sufficient for the processing of this molecule to mature tRNAs in vitro. The accumulation of such tRNA precursors in an RNase E mutant cell and the obligatory participation of RNase E in its processing indicate that RNase E functions in the maturation of transfer RNAs as well as of 5-S rRNA.