Substrate shape preference of Escherichia coli ribonuclease P ribozyme and holo enzyme using bottom-half part-shifting variants of pre-tRNA

We showed previously that the bacterial ribonuclease P (RNase P) ribozyme has substrate shape preference depending on the concentrations of catalytically important magnesium ions. The ribozyme discriminates a canonical cloverleaf precursor tRNA from a hairpin RNA with a CCA-tag sequence at low concentrations of magnesium ions. By detailed analysis of the shape preference using the bottom-half part-shifting variants of a tRNA precursor, we showed that the RNAs in a T-shape structure can be substrates for the ribozyme reactions even at low concentrations of magnesium ions, and that the RNA in a natural L-shape is the best substrate for both the ribozyme and the holo enzyme. The results also showed that the position of the bottom-half part did not affect the cleavage site selection of a substrate by the enzyme. Our results are the first kinetic evidence to show the importance of the bottom-half part of tRNA molecule, and our result also showed that the holo enzyme can discriminate substrate shape as well as the ribozyme at low concentrations of metal ions.     

Location of the RNA-processing enzymes RNase III, RNase E and RNase P in the Eschenchia coli cell

Cells overexpressing the RNA-processing enzymes RNase III, RNase E and RNase P were fractionated into membrane and cytoplasm. The RNA-processing enzymes were associated with the membrane fraction. The membrane was further separated to inner and outer membrane and the three RNA-processing enzymes were found in the inner membrane fraction. By assaying for these enzymatic activities we showed that even in a normal wild-type strain of Escherichia coli these enzymes fractionate primarily with the membrane. The RNA part of RNase P is found in the cytosolic fraction of cells overexpressing this RNA, while the overexpressed RNase P protein sediments with the membrane fraction; this suggests that the RNase P protein anchors the RNA catalytic moiety of the enzyme to a larger entity. The implications of these findings for the cellular organization of the RNA-processing enzymes in the cell are discussed.     

Dependence of M1 RNA substrate specificity on magnesium ion concentration.

We have constructed a plasmid expressing E. coli M1 RNA, the catalytic RNA subunit of ribonuclease P, under the control of a phage T7 promoter. The active M1 RNA species synthesized in vitro by T7 RNA polymerase from this vector was reacted with the tRNA(Gln) - tRNA(Leu) precursor RNA (Band K) encoded by phage T4. Only the tRNA(Leu) moiety of this dimeric precursor RNA contains the 3' terminal C-C-A sequence common to all tRNAs. We observed that protein-free M1 RNA was capable of processing the precursor RNA at the 5' ends of both tRNA tRNA sequences. The rate of cleavage of the tRNA(Gln) sequence was more strongly dependent on [Mg2+] than that of tRNA(Leu), increasing severalfold between 100 and 500 mM Mg2+, conditions under which the rate of cleavage at the tRNA(Leu) sequence was constant.     

The kinetics and specificity of cleavage by RNase P is mainly dependent on the structure of the amino acid acceptor stem.

Cleavage by RNase P of the tRNA(His precursor yields a mature tRNA with an 8 base pair amino acid acceptor stem instead of the usual 7 base pair stem. Here we show, both in vivo and in vitro, that this is mainly dependent on the primary structure and length of the acceptor stem in the precursor. Furthermore, the tRNA(His) precursor used in this study was processed with a change in both kinetic constants, Km and kcat, in comparison to the kinetics of cleavage of the precursor to tRNA(Tyr)Su3. Cleavage of a chimeric tRNA precursor showed that these altered kinetics were due to a difference in the primary structure and in the length of the acceptor stems of these two tRNA precursors. We also studied the cleavage reaction as a function of base substitutions at positions -1 and/or +73 in the precursor to tRNA(His). Our results suggest that the nucleotide at position +73 in tRNA(His) plays a significant role in the kinetics of cleavage of its precursor, possibly in product release. In addition, it appears that the C5 protein of RNase P is involved in the interaction between the enzyme and its substrate in a substrate-dependent manner, as previously suggested.     

Substrate specificity and reaction kinetics of an X-motif ribozyme

The X-motif is an in vitro-selected ribozyme that catalyzes RNA cleavage by an internal phosphoester transfer reaction. This ribozyme class is distinguished by the fact that it emerged as the dominant clone among at least 12 different classes of ribozymes when in vitro selection was conducted to favor the isolation of high-speed catalysts. We have examined the structural and kinetic properties of the X-motif in order to provide a framework for its application as an RNA-cleaving agent and to explore how this ribozyme catalyzes phosphoester transfer with a predicted rate constant that is similar to those exhibited by the four natural self-cleaving ribozymes. The secondary structure of the X-motif includes four stem elements that form a central unpaired junction. In a bimolecular format, two of these base-paired arms define the substrate specificity of the ribozyme and can be changed to target different RNAs for cleavage. The requirements for nucleotide identity at the cleavage site are GD, where D = G, A, or U and cleavage occurs between the two nucleotides. The ribozyme has an absolute requirement for a divalent cation cofactor and exhibits kinetic behavior that is consistent with the obligate binding of at least two metal ions.     

The P15-loop of Escherichia coli RNase P RNA is an autonomous divalent metal ion binding domain.

We have studied the structure and divalent metal ion binding of a domain of the ribozyme RNase P RNA that is involved in base pairing with its substrate. Our data suggest that the folding of this internal loop, the P15-loop, is similar irrespective of whether it is part of the full-length ribozyme or part of a model RNA molecule. We also conclude that this element constitutes an autonomous divalent metal ion binding domain of RNase P RNA and our data suggest that certain specific chemical groups within the P15-loop participate in coordination of divalent metal ions. Substitutions of the Sp- and Rp-oxygens with sulfur at a specific position in this loop result in a 2.5-5-fold less active ribozyme, suggesting that Mg2+ binding at this position contributes to function. Our findings strengthen the concept that small RNA building blocks remain basically unchanged when removed from their structural context and thus can be used as models for studies of their potential function and structure within native RNA molecules.     

Probing the substrate specificity of Escherichia coli RNase E using a novel oligonucleotide-based assay

Endoribonuclease RNase E has a central role in both processing and decay of RNA in Escherichia coli, and apparently in many other organisms, where RNase E homologs were identified or their existence has been predicted from genomic data. Although the biochemical properties of this enzyme have been already studied for many years, the substrate specificity of RNase E is still poorly characterized. Here, I have described a novel oligonucleotide-based assay to identify specific sequence determinants that either facilitate or impede the recognition and cleavage of RNA by the catalytic domain of the enzyme. The knowledge of these determinants is crucial for understanding the nature of RNA–protein interactions that control the specificity and efficiency of RNase E cleavage and opens new perspectives for further studies of this multi-domain protein. Moreover, the simplicity and efficiency of the proposed assay suggest that it can be a valuable tool not only for the characterization of RNase E homologs but also for the analysis of other site-specific nucleases.     

The RNase E of Escherichia coli is a membrane-binding protein

RNase E is an essential endoribonuclease involved in RNA processing and mRNA degradation. The N-terminal half of the protein encompasses the catalytic domain; the C-terminal half is the scaffold for the assembly of the multienzyme RNA degradosome. Here we identify and characterize 'segment-A', an element in the beginning of the non-catalytic region of RNase E that is required for membrane binding. We demonstrate in vitro that an oligopeptide corresponding to segment-A has the propensity to form an amphipathic alpha-helix and that it avidly binds to protein-free phospholipid vesicles. We demonstrate in vitro and in vivo that disruption of segment-A in full-length RNase E abolishes membrane binding. Taken together, our results show that segment-A is necessary and sufficient for RNase E binding to membranes. Strains in which segment-A has been disrupted grow slowly. Since in vitro experiments show that phospholipid binding does not affect the ribonuclease activity of RNase E, the slow-growth phenotype might arise from a defect involving processes such as accessibility to substrates or interactions with other membrane-bound machinery. This is the first report demonstrating that RNase E is a membrane-binding protein and that its localization to the inner cytoplasmic membrane is important for normal cell growth.     

RNase P of the Cyanophora paradoxa cyanelle: a plastid ribozyme

Ribonuclease P (RNase P) is a ribonucleoprotein enzyme that generates the mature 5' ends of tRNAs. Ubiquitous across all three kingdoms of life, the composition and functional contributions of the RNA and protein components of RNase P differ between the kingdoms. RNA-alone catalytic activity has been reported throughout bacteria, but only for some archaea, and only as trace activity for eukarya. Available information for RNase P from photosynthetic organelles points to large differences to bacterial as well as to eukaryotic RNase P: for spinach chloroplasts, protein-alone activity has been discussed; for RNase P from the cyanelle of the glaucophyte Cyanophora paradoxa, a type of organelle sharing properties of both cyanobacteria and chloroplasts, the proportion of protein was found to be around 80% rather than the usual 10% in bacteria. Furthermore, the latter RNase P was previously found catalytically inactive in the absence of protein under a variety of conditions; however, the RNA could be activated by a cyanobacterial protein, but not by the bacterial RNase P protein from Escherichia coli. Here we demonstrate that, under very high enzyme concentrations, the RNase P RNA from the cyanelle of C. paradoxa displays RNA-alone activity well above the detection level. Moreover, the RNA can be complemented to a functional holoenzyme by the E. coli RNase P protein, further supporting its overall bacterial-like architecture. Mutational analysis and domain swaps revealed that this A,U-rich cyanelle RNase P RNA is globally optimized but conformationally unstable, since changes as little as a single point mutation or a base pair identity switch at positions that are not part of the universally conserved catalytic core led to a complete loss of RNA-alone activity. Likely related to this low robustness, extensive structural changes towards an E. coli-type P5-7/P15-17 subdomain as a canonical interaction site for tRNA 3'-CCA termini could not be coaxed into increased ribozyme activity.     

Human tyrosine tRNA is also internally cleavable by E. coli ribonuclease P RNA ribozyme in vitro

Transfer RNA is an essential molecule for biological system, and each tRNA molecule commonly has a cloverleaf structure. Previously, we experimentally showed that some Drosophila tRNA (tRNA(Ala), tRNA(His), and tRNA(iMet)) molecules fit to form another, non-cloverleaf, structure in which the 3'-half of the tRNA molecules forms an alternative hairpin, and that the tRNA molecules are internally cleaved by the catalytic RNA of bacterial ribonuclease P (RNase P). Until now, the hyperprocessing reaction of tRNA has only been reported with Drosophila tRNAs. This time, we applied the hyperprocessing reaction to one of human tRNAs, human tyrosine tRNA, and we showed that this tRNA was also hyperprocessed by E. coli RNase P RNA. This tRNA is the first example for hyperprocessed non-Drosophila tRNAs. The results suggest that the hyperprocessing reaction can be a useful tool detect destablized tRNA molecules from any species.     

Escherichia coli tRNAs are resistant to the hyperprocessing reaction of homologous E. coli ribonuclease P ribozyme

Bacterial ribonuclease P RNA ribozyme can do the hyperprocessing reaction, the internal cleavage reaction of some floppy eukaryotic tRNAs. The hyperprocessing reaction can be used as a detection tool to examine the stability of the cloverleaf shape of tRNA. Until now, the hyperprocessing reaction has been observed in the heterologous combination of eukaryotic tRNAs and bacterial RNase P enzymes. In this paper, we examined the hyperprocessing reaction of Escherichia coli tRNAs by homologous E. coli RNase P, to find that these homologous tRNAs were resistant to the toxic hyperprocessing reaction. Our results display the evidence for molecular co-evolution between homologous tRNAs and RNase P in the bacterium E. coli.     

Substrate affinity and substrate specificity of proteasomes with RNase activity

We have partially reconstituted 20S proteasome/RNA complexes using oligonucleotides corresponding to ARE (adenosine- and uridine-rich element) (AUUUA)₄ and HIV-TAR (human immunodeficiency virus-Tat transactivation response element), a stem-loop structure in the 5 UTR (untranslated region) of HIV-mRNAs. We demonstrate that these RNAs which associate with proteasomes are degraded by proteasomal endonuclease activity. The formation of these 20S proteasome/RNA substrate complexes is rather specific since 20S proteasomes do not interfere with truncated TAR that is not cleaved by proteasomal endonuclease. In addition, affinity of proteasomes for (AUUUA)₄ is much stronger as it is for HIV-TAR. These results provide further arguments for our hypothesis that proteasomes could be involved in the destabilisation of cytokines mRNAs containing AUUUA sequences as well as viral mRNAs.     

Substrate structural requirements of Schizosaccharomyces pombe RNase P

RNase P from Schizosaccharomyces pombe has been purified over 2000-fold. The apparent Km for two S. pombe tRNA precursors derived from the supS1 and sup3-e tRNA(Ser) genes is 20 nM; the apparent Vmax is 2.5 nM/min (supS1) and 1.1 nM/min (sup3-e). Processing studies with precursors of other mutants show that the structures of the acceptor stem and anticodon/intron loop of tRNA are crucial for S. pombe RNase P action.     

Substrate discrimination in RNase P RNA-mediated cleavage: importance of the structural environment of the RNase P cleavage site

Like the translational elongation factor EF-Tu, RNase P interacts with a large number of substrates where RNase P with its RNA subunit generates tRNAs with matured 5′ termini by cleaving tRNA precursors immediately 5′ of the residue at +1, i.e. at the position that corresponds to the first residue in tRNA. Most tRNAs carry a G₊₁C₊₇₂ base pair at the end of the aminoacyl acceptor-stem whereas in tRNA^Gln G₊₁C₊₇₂ is replaced with U₊₁A₊₇₂. Here, we investigated RNase P RNA-mediated cleavage as a function of having G₊₁C₊₇₂ versus U₊₁A₊₇₂ in various substrate backgrounds, two full-size tRNA precursors (pre-tRNA^Gln and pre-tRNA^TyrSu3) and a model RNA hairpin substrate (pATSer). Our data showed that replacement of G₊₁C₊₇₂ with U₊₁A₊₇₂ influenced ground state binding, cleavage efficiency under multiple and single turnover conditions in a substrate-dependent manner. Interestingly, we observed differences both in ground state binding and rate of cleavage comparing two full-size tRNA precursors, pre-tRNA^Gln and pre-tRNA^TyrSu3. These findings provide evidence for substrate discrimination in RNase P RNA-mediated cleavage both at the level of binding, as previously observed for EF-Tu, as well as at the catalytic step. In our experiments where we used model substrate derivatives further indicated the importance of the +1/+72 base pair in substrate discrimination by RNase P RNA. Finally, we provide evidence that the structural architecture influences Mg²⁺ binding, most likely in its vicinity.     

Identification of phosphates involved in catalysis by the ribozyme RNase P RNA.

The RNA subunit of ribonuclease P (RNase P RNA) is a catalytic RNA that cleaves precursor tRNAs to generate mature tRNA 5' ends. Little is known concerning the identity and arrangement of functional groups that constitute the active site of this ribozyme. We have used an RNase P RNA-substrate conjugate that undergoes rapid, accurate, and efficient self-cleavage in vitro to probe, by phosphorothioate modification-interference, functional groups required for catalysis. We identify four phosphate oxygens where substitution by sulfur significantly reduces the catalytic rate (50-200-fold). Interference at one site was partially rescued in the presence of manganese, suggesting a direct involvement in binding divalent metal ion cofactors required for catalysis. All sites are located in conserved sequence and secondary structure, and positioned adjacent to the substrate phosphate in a tertiary structure model of the ribozyme-substrate complex. The spatial arrangement of phosphorothioate-sensitive sites in RNase P RNA was found to resemble the distribution of analogous positions in the secondary and potential tertiary structures of other large catalytic RNAs.