The ubiquitous endonuclease RNase P is responsible for the 5' maturation of tRNA precursors. Until the discovery of human mitochondrial RNase P, these enzymes had typically been found to be ribonucleoproteins, the catalytic activity of which is associated with the RNA component. Here we show that, in Arabidopsis thaliana mitochondria and plastids, a single protein called 'proteinaceous RNase P' (PRORP1) can perform the endonucleolytic maturation of tRNA precursors that defines RNase P activity. In addition, PRORP1 is able to cleave tRNA-like structures involved in the maturation of plant mitochondrial mRNAs. Finally, we show that Arabidopsis PRORP1 can replace the bacterial ribonucleoprotein RNase P in Escherichia coli cells. PRORP2 and PRORP3, two paralogs of PRORP1, are both localized in the nucleus.
Substrate recognition and cleavage-site selection by a single-subunit protein-only RNase P
RNase P is the enzyme that removes 5′ extensions from tRNA precursors. With its diversity of enzyme forms—either protein- or RNA-based, ranging from single polypeptides to multi-subunit ribonucleoproteins—the RNase P enzyme family represents a unique model system to compare the evolution of enzymatic mechanisms. Here we present a comprehensive study of substrate recognition and cleavage-site selection by the nuclear single-subunit proteinaceous RNase P PRORP3 from Arabidopsis thaliana. Compared to bacterial RNase P, the best-characterized RNA-based enzyme form, PRORP3 requires a larger part of intact tRNA structure, but little to no determinants at the cleavage site or interactions with the 5′ or 3′ extensions of the tRNA. The cleavage site depends on the combined dimensions of acceptor stem and T domain, but also requires the leader to be single-stranded. Overall, the single-subunit PRORP appears mechanistically more similar to the complex nuclear ribonucleoprotein enzymes than to the simpler bacterial RNase P. Mechanistic similarity or dissimilarity among different forms of RNase P thus apparently do not necessarily reflect molecular composition or evolutionary relationship.
RNase P is an essential tRNA-processing enzyme in all domains of life. We identified an unknown type of protein-only RNase P in the hyperthermophilic bacterium Aquifex aeolicus: Without an RNA subunit and the smallest of its kind, the 23-kDa polypeptide comprises a metallonuclease domain only. The protein has RNase P activity in vitro and rescued the growth of Escherichia coli and Saccharomyces cerevisiae strains with inactivations of their more complex and larger endogenous ribonucleoprotein RNase P. Homologs of Aquifex RNase P (HARP) were identified in many Archaea and some Bacteria, of which all Archaea and most Bacteria also encode an RNA-based RNase P; activity of both RNase P forms from the same bacterium or archaeon could be verified in two selected cases. Bioinformatic analyses suggest that A. aeolicus and related Aquificaceae likely acquired HARP by horizontal gene transfer from an archaeon.protein-only RNase P | Aquifex aeolicus | tRNA processing | HARP T he architectural diversity of RNase P enzymes is unique: In Bacteria, Archaea, and in the nuclei and organelles of many Eukarya, RNase P is a complex consisting of a catalytic RNA subunit and a varying number of proteins (one in Bacteria, at least four in Archaea, and up to 10 in Eukarya) (1, 2). A different type of RNase P was discovered more recently in human mitochondria (3) and, subsequently, in land plants and some protists (4, 5). This form, termed proteinaceous or protein-only RNase P (PRORP), lacks any RNA subunit and consists of one or three (animal mitochondria) protein subunit(s); it is found in most branches of the eukaryotic phylogenetic tree (6).Bacterial RNase P enzymes identified so far are composed of a ∼400-nt-long catalytic RNA subunit (encoded by rnpB) and a small protein subunit of ∼14 kDa (encoded by rnpA) (7). However, no rnpA and rnpB genes were identified in the genome of Aquifex aeolicus or other Aquificaceae (8-12). The genetic organization of A. aeolicus tRNAs in tandem clusters and as part of ribosomal operons and the detection of tRNAs with canonical mature 5′-ends in total RNA extracts from A. aeolicus implied the existence of a tRNA 5′-maturation activity (9) that was indeed subsequently detected in cell lysates of A. aeolicus (11, 13). However, to date, the identity and biochemical composition of RNase P in A. aeolicus has remained enigmatic. Results and DiscussionHere, we pursued a classical biochemical approach to identify the RNase P of A. aeolicus. The purification procedure consisted of three consecutive chromatographic steps: anion exchange, hydrophobic interaction, and size exclusion chromatography (AEC, HIC, and SEC, respectively; Fig. 1A and SI Appendix, Figs. S1-S8). RNase P activity was assayed at all purification steps. To identify putative protein components of the enzyme, fractions with low and high RNase P activity from different purification steps were comparatively analyzed by step-gradient SDS/PAGE, and protein bands correlating with activity (Fig. 1B) were subjected to mass spectrometry. An example i...
In Arabidopsis thaliana, RNase P function, that is, endonucleolytic tRNA 5'-end maturation, is carried out by three homologous polypeptides ("proteinaceous RNase P" (PRORP) 1, 2 and 3). Here we present the first kinetic analysis of these enzymes. For PRORP1, a specificity constant (k(react)/K(m(sto))) of 3×10(6) M(-1) min(-1) was determined under single-turnover conditions. We demonstrate a fundamentally different sensitivity of PRORP enzymes to an Rp-phosphorothioate modification at the canonical cleavage site in a 5'-precursor tRNA substrate; whereas processing by bacterial RNase P is inhibited by three orders of magnitude in the presence of this sulfur substitution and Mg(2+) as the metal-ion cofactor, the PRORP enzymes are affected by not more than a factor of five under the same conditions, without significantly increased miscleavage. These findings indicate that the catalytic mechanism utilized by proteinaceous RNase P is different from that of RNA-based bacterial RNase P, taking place without a direct metal-ion coordination to the (pro-)Rp substituent. As Rp-phosphorothioate and inosine modification at all 26 G residues of the tRNA body had only minor effects on processing by PRORP, we conclude that productive PRORP-substrate interaction is not critically dependent on any of the affected (pro-)Rp oxygens or guanosine 2-amino groups.
Bacterial RNase P is composed of an RNA subunit and a single protein subunit (encoded by the rnpB and rnpA genes, respectively). We constructed Bacillus subtilis mutant strains that conditionally express the RNase P protein under control of the xylose promoter (P xyl ). In one strain (d7), rnpA expression was efficiently repressed in the absence of the inducer xylose, leading to cell growth arrest. Growth could be restored by a second functional rnpA allele. This is the first RNase P protein knockdown strain, providing the first direct proof that the rnpA gene is essential in B. subtilis and, by inference, in other bacteria. We further show (i) that, in the wild-type context, rnpA expression is attenuated by transcriptional polarity and (ii) that translation of rnpA mRNA in B. subtilis can be initiated at two alternative start codons. His-tagged RNase P protein variants are functional in vivo and permit purification of in vivo-assembled holoenzymes by affinity chromatography. Simultaneous expression of plasmid-encoded RNase P RNA and His-tagged protein increased RNase P holoenzyme yields. Massive overproduction of RNase P protein in strain d7 is compatible with cell viability.Present knowledge about the in vivo function of the bacterial RNase P protein (termed P protein) originates from studies of the Escherichia coli system with a mutant strain (NHY322 [rnpA49]) encoding a P protein with a single amino acid mutation, which results in temperature-sensitive bacterial growth due to decreased affinity of the protein for its RNA subunit (1,7,11,13). Although the rnpA49 mutant's phenotype has indicated that the P protein is essential in E. coli, one caveat is that complementation studies were performed under stress conditions at 43°C. The heat shock response has a global effect on gene expression (14,19), and induced metabolic changes could exacerbate the mutant phenotype. Moreover, the mutant P protein is still expressed in the rnpA49 mutant strain under nonpermissive conditions and may interfere with the function of the P protein expressed from a plasmid in complementation studies.Here we describe the construction and biological properties of Bacillus subtilis mutant strains with suppressible rnpA expression. In one type of mutant strain, termed d7, chromosomal rnpA expression could essentially be abolished, resulting in cell growth arrest. Expression of plasmid-borne rnpA genes encoding either the wild-type (WT) P protein or variants carrying an N-or C-terminal His tag was able to rescue the conditionally lethal phenotype. In contrast, an rnpA gene with internal stop codons was unable to restore growth under restrictive conditions. Our results demonstrate directly that the bacterial P protein is essential for cell viability. We further demonstrate the utility of the d7 strain for RNase P overproduction and affinity purification via His-tagged protein variants. Finally, we show that rnpA expression in B. subtilis is attenuated by transcriptional polarity and that translation of rnpA mRNA in B. subtilis can be initi...
The RNase P family comprises structurally diverse endoribonucleases ranging from complex ribonucleoproteins to single polypeptides. We show that the organellar (AtPRORP1) and the two nuclear (AtPRORP2,3) single-polypeptide RNase P isoenzymes from Arabidopsis thaliana confer viability to Escherichia coli cells with a lethal knockdown of its endogenous RNA-based RNase P. RNA-Seq revealed that AtPRORP1, compared with bacterial RNase P or AtPRORP3, cleaves several precursor tRNAs (pre-tRNAs) aberrantly in E. coli. Aberrant cleavage by AtPRORP1 was mainly observed for pre-tRNAs that can form short acceptor-stem extensions involving G:C base pairs, including tRNAAsp(GUC), tRNASer(CGA) and tRNAHis. However, both AtPRORP1 and 3 were defective in processing of E. coli pre-tRNASec carrying an acceptor stem expanded by three G:C base pairs. Instead, pre-tRNASec was degraded, suggesting that tRNASec is dispensable for E. coli under laboratory conditions. AtPRORP1, 2 and 3 are also essentially unable to process the primary transcript of 4.5S RNA, a hairpin-like non-tRNA substrate processed by E. coli RNase P, indicating that PRORP enzymes have a narrower, more tRNA-centric substrate spectrum than bacterial RNA-based RNase P enzymes. The cells’ viability also suggests that the essential function of the signal recognition particle can be maintained with a 5΄-extended 4.5S RNA.
Immunolocalization of the exocytosis-sensitive phosphoprotein, PP63/parafusin, in Paramecium cells using antibodies against recombinant protein
We have localized a structure-bound fraction of the exocytosis-sensitive phosphoprotein, PP63/parafusin (PP63/pf), in Paramecium cells by widely different methods. We combined cell fractionation, western blots, as well as light and electron microscopy (pre-and postembedding immunolabeling), applying antibodies against the recombinant protein. PP63/pf is considerably enriched in certain cortical structures, notably the outlines of regular surface fields (kinetids), docking sites of secretory organelles (trichocysts) and the membranes of subplasmalemmal Ca 2+ -stores (alveolar sacs). From our localization studies we tentatively derive several potential functions for PP63/pf, including cell surface structuring, assembly of exocytosis sites, and/or Ca 2+ homeostasis.& b d y :
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