Design and isolation of ribozyme-substrate pairs using RNase P-based ribozymes containing altered substrate binding sites.

Substrate recognition and cleavage by the bacterial RNase P RNA requires two domains, a specificity domain, or S-domain, and a catalytic domain, or C-domain. The S-domain binds the T stem-loop region in a pre-tRNA substrate to confer specificity for tRNA substrates. In this work, the entire S-domain of the Bacillus subtilis RNase P RNA is replaced with an artificial substrate binding module. New RNA substrates are isolated by in vitro selection using two libraries containing random regions of 60 nt. At the end of the selection, the cleavage rates of the substrate library are approximately 0.7 min(-1)in 10 mM MgCl(2)at 37 degrees C, approximately 4-fold better than the cleavage of a pre-tRNA substrate by the wild-type RNase P RNA under the same conditions. The contribution of the S-domain replacement to the catalytic efficiency is from 6- to 22 000-fold. Chemical and nuclease mapping of two ribozyme-product complexes shows that this contribution correlates with direct interactions between the S-domain replacement and the selected substrate. These results demonstrate the feasibility of design and isolation of RNase P-based, matching ribozyme-substrate pairs without prior knowledge of the sequence or structure of the interactive modules in the ribozyme or substrate.     

NAIM and site-specific functional group modification analysis of RNase P RNA: magnesium dependent structure within the conserved P1-P4 multihelix junction contributes to catalysis

The tRNA processing endonuclease ribonuclease P contains an essential and highly conserved RNA molecule (RNase P RNA) that is the catalytic subunit of the enzyme. To identify and characterize functional groups involved in RNase P RNA catalysis, we applied self-cleaving ribozyme-substrate conjugates, on the basis of the RNase P RNA from Escherichia coli, in nucleotide analogue interference mapping (NAIM) and site-specific modification experiments. At high monovalent ion concentrations (3 M) that facilitate protein-independent substrate binding, we find that the ribozyme is largely insensitive to analogue substitution and that concentrations of Mg2+ (1.25 mM) well below that necessary for optimal catalytic rate (>100 mM) are required to produce interference effects because of modification of nucleotide bases. An examination of the pH dependence of the reaction rate at 1.25 mM Mg2+ indicates that the increased sensitivity to analogue interference is not due to a change in the rate-limiting step. The nucleotide positions detected by NAIM under these conditions are located exclusively in the catalytic domain, consistent with the proposed global structure of the ribozyme, and predominantly occur within the highly conserved P1-P4 multihelix junction. Several sensitive positions in J3/4 and J2/4 are proximal to a previously identified site of divalent metal ion binding in the P1-P4 element. Kinetic analysis of ribozymes with site-specific N7-deazaadenosine and deazaguanosine modifications in J3/4 was, in general, consistent with the interference results and also permitted the analysis of sites not accessible by NAIM. These results show that, in this region only, modification of the N7 positions of A62, A65, and A66 resulted in measurable effects on reaction rate and modification at each position displayed distinct sensitivities to Mg2+ concentration. These results reveal a restricted subset of individual functional groups within the catalytic domain that are particularly important for substrate cleavage and demonstrate a close association between catalytic function and metal ion-dependent structure in the highly conserved P1-P4 multihelix junction.     

Recognition of the 5' leader of pre-tRNA substrates by the active site of ribonuclease P

The bacterial tRNA processing enzyme ribonuclease P (RNase P) is a ribonucleoprotein composed of a approximately 400 nucleotide RNA and a smaller protein subunit. It has been established that RNase P RNA contacts the mature tRNA portion of pre-tRNA substrates, whereas RNase P protein interacts with the 5' leader sequence. However, specific interactions with substrate nucleotides flanking the cleavage site have not previously been defined. Here we provide evidence for an interaction between a conserved adenosine, A248 in the Escherichia coli ribozyme, and N(-1), the substrate nucleotide immediately 5' of the cleavage site. Specifically, mutations at A248 result in miscleavage of substrates containing a 2' deoxy modification at N(-1). Compensatory mutations at N(-1) restore correct cleavage in both the RNA-alone and holoenzyme reactions, and also rescue defects in binding thermodynamics caused by A248 mutation. Analysis of pre-tRNA leader sequences in Bacteria and Archaea reveals a conserved preference for U at N(-1), suggesting that an interaction between A248 and N(-1) is common among RNase P enzymes. These results provide the first direct evidence for RNase P RNA interactions with the substrate cleavage site, and show that RNA and protein cooperate in leader sequence recognition.     

Interaction of the Bacillus subtilis RNase P with the 30S ribosomal subunit

Ribonuclease P (RNase P) is a ribozyme required for the 5' maturation of all tRNA. RNase P and the ribosome are the only known ribozymes conserved in all organisms. We set out to determine whether this ribonucleoprotein enzyme interacts with other cellular components, which may imply other functions for this conserved ribozyme. Incubation of the Bacillus subtilis RNase P holoenzyme with fractionated B. subtilis cellular extracts and purified ribosomal subunits results in the formation of a gel-shifted complex with the 30S ribosomal subunit at a binding affinity of approximately 40 nM in 0.1 M NH(4)Cl and 10 mM MgCl(2). The complex does not form with the RNase P RNA alone and is disrupted by a mRNA mimic polyuridine, but is stable in the presence of high concentrations of mature tRNA. Endogenous RNase P can also be detected in the 30S ribosomal fraction. Cleavage of a pre-tRNA substrate by the RNase P holoenzyme remains the same in the presence of the 30S ribosome, but the cleavage of an artificial non-tRNA substrate is inhibited eightfold. Hydroxyl radical protection and chemical modification identify several protected residues located in a highly conserved region in the RNase P RNA. A single mutation within this region significantly reduces binding, providing strong support on the specificity of the RNase P-30S ribosome complex. Our results also suggest that the dimeric form of the RNase P is primarily involved in 30S ribosome binding. We discuss several models on a potential function of the RNase P-30S ribosome complex.     

Helix P4 is a divalent metal ion binding site in the conserved core of the ribonuclease P ribozyme

The ribonuclease P ribozyme (RNase P RNA), like other large ribozymes, requires magnesium ions for folding and catalytic function; however, specific sites of metal ion coordination in RNase P RNA are not well defined. To identify and characterize individual nucleotide functional groups in the RNase P ribozyme that participate in catalytic function, we employed self-cleaving ribozyme-substrate conjugates that facilitate measurement of the effects of individual functional group modifications. The self-cleavage rates and pH dependence of two different ribozyme-substrate conjugates were determined and found to be similar to the single turnover kinetics of the native ribozyme. Using site-specific phosphorothioate substitutions, we provide evidence for metal ion coordination at the pro-Rp phosphate oxygen of A67, in the highly conserved helix P4, that was previously suggested by modification-interference experiments. In addition, we detect a new metal ion coordination site at the pro-Sp phosphate oxygen of A67. These findings, in combination with the proximity of A67 to the pre-tRNA cleavage site, support the conclusion that an important role of helix P4 in the RNase P ribozyme is to position divalent metal ions that are required for catalysis.     

Rp-phosphorothioate modifications in RNase P RNA that interfere with tRNA binding.

We have used Rp-phosphorothioate modifications and a binding interference assay to analyse the role of phosphate oxygens in tRNA recognition by Escherichia coli ribonuclease P (RNase P) RNA. Total (100%) Rp-phosphorothioate modification at A, C or G positions of RNase P RNA strongly impaired tRNA binding and pre-tRNA processing, while effects were less pronounced at U positions. Partially modified E. coli RNase P RNAs were separated into tRNA binding and non-binding fractions by gel retardation. Rp-phosphorothioate modifications that interfered with tRNA binding were found 5' of nucleotides A67, G68, U69, C70, C71, G72, A130, A132, A248, A249, G300, A317, A330, A352, C353 and C354. Manganese rescue at positions U69, C70, A130 and A132 identified, for the first time, sites of direct metal ion coordination in RNase P RNA. Most sites of interference are at strongly conserved nucleotides and nine reside within a long-range base-pairing interaction present in all known RNase P RNAs. In contrast to RNase P RNA, 100% Rp-phosphorothioate substitutions in tRNA showed only moderate effects on binding to RNase P RNAs from E. coli, Bacillus subtilis and Chromatium vinosum, suggesting that pro-Rp phosphate oxygens of mature tRNA contribute relatively little to the formation of the tRNA-RNase P RNA complex.     

Analysis of the tertiary structure of the ribonuclease P ribozyme-substrate complex by site-specific photoaffinity crosslinking.

Bacterial ribonuclease P (RNase P), an endonuclease involved in tRNA maturation, is a ribonucleoprotein containing a catalytic RNA. The secondary structure of this ribozyme is well-established, and a low-resolution model of the three-dimensional structure of the ribozyme-substrate complex has been proposed based on site-specific crosslinking and phylogenetic comparative data [Harris ME et al., 1994 EMBO J 13:3953-3963]. However, several substructures of that model were poorly constrained by the available data. In the present analysis, additional constraints between elements within the Escherichia coli RNase P RNA-pre-tRNA complex were determined by intra- and intermolecular crosslinking experiments. Circularly permuted RNase P RNAs were used to position an azidophenacyl photoactive crosslinking agent specifically at strategic sites within the ribozyme-substrate complex. Crosslink sites were mapped by primer extension and confirmed by analysis of the mobility of the crosslinked RNA lariats on denaturing acrylamide gels relative to circular and linear RNA standards. Crosslinked species generally retained significant catalytic activity, indicating that the results reflect the native ribozyme structure. The crosslinking results support the general configuration of the structure model and predicate new positions and orientations for helices that were previously poorly constrained by the data set. The expanded library of crosslinking constraints was used, together with secondary and tertiary structure identified by phylogenetic sequence comparisons, to refine significantly the model of RNase P RNA with bound substrate pre-tRNA. The crosslinking results and data from chemical-modification and mutational studies are discussed in the context of the current structural perspective on this ribozyme.     

Purine N7 groups that are crucial to the interaction of Escherichia coli rnase P RNA with tRNA.

We have detected by nucleotide analog interference mapping (NAIM) purine N7 functional groups in Escherichia coli RNase P RNA that are important for tRNA binding under moderate salt conditions (0.1 M Mg2+, 0.1 M NH4+). The majority of identified positions represent highly or universally conserved nucleotides. Our assay system allowed us, for the first time, to identify c7-deaza interference effects at two G residues (G292, G306). Several c7-deazaadenine interference effects (A62, A65, A136, A249, A334, A351) have also been identified in other studies performed at very different salt concentrations, either selecting for substrate binding in the presence of 0.025 M Ca2+ and 1 M NH4+ or self-cleavage of a ptRNA-RNase P RNA conjugate in the presence of 3 M NH4+ or Na+. This indicates that these N7 functional groups play a key role in the structural organization of ribozyme-substrate and -product complexes. We further observed that a c7-deaza modification at A76 of tRNA interferes with tRNA binding to and ptRNA processing by E. coli RNase P RNA. This finding combined with the strong c7-deaza interference at G292 of RNase P RNA supports a model in which substrate and product binding to E. coli RNase P RNA involves the formation of intermolecular base triples (A258-G292-C75 and G291-G259-A76).     

Identification of nucleotide residues essential for RNase P activity from the hyperthermophilic archaeon Pyrococcus horikoshii OT3

Ribonuclease P (RNase P) is involved in the processing of the 5' leader sequence of precursor tRNA (pre-tRNA). We have found that RNase P RNA (PhopRNA) and five proteins (PhoPop5, PhoRpp21, PhoRpp29, PhoRpp30, and PhoRpp38) reconstitute RNase P activity with enzymatic properties similar to those of the authentic ribozyme from the hyperthermophilic archaeon Pyrococcus horikoshii OT3. We report here that nucleotides A40, A41, and U44 at helix P4, and G269 and G270 located at L15/16 in PhopRNA, are, like the corresponding residues in Esherichia coli RNase P RNA (M1RNA), involved in hydrolysis by coordinating catalytic Mg(2+) ions, and in the recognition of the acceptor end (CCA) of pre-tRNA by base-pairing, respectively. The information reported here strongly suggests that PhopRNA catalyzes the hydrolysis of pre-tRNA in approximately the same manner as eubacterial RNase P RNAs, even though it has no enzymatic activity in the absence of the proteins.     

Evidence that binding of C5 protein to P RNA enhances ribozyme catalysis by influencing active site metal ion affinity

The RNA subunit (P RNA) of the bacterial RNase P ribonucleoprotein is a ribozyme that catalyzes the Mg-dependent hydrolysis of pre-tRNA, but it requires an essential protein cofactor (P protein) in vivo that enhances substrate binding affinities and catalytic rates in a substrate dependent manner. Previous studies of Bacillus subtilis RNase P, containing a Type B RNA subunit, showed that its cognate protein subunit increases the affinity of metal ions important for catalysis, but the functional role of these ions is unknown. Here, we demonstrate that the Mg2+ dependence of the catalytic step for Escherichia coli RNase P, which contains a more common Type A RNA subunit, is also modulated by its cognate protein subunit (C5), indicating that this property is fundamental to P protein. To monitor specifically the binding of active site metal ions, we analyzed quantitatively the rescue by Cd2+ of an inhibitory Rp phosphorothioate modification at the pre-tRNA cleavage site. The results show that binding of C5 protein increases the apparent affinity of the rescuing Cd2+, providing evidence that C5 protein enhances metal ion affinity in the active site, and thus is likely to contribute significantly to rate enhancement at physiological metal ion concentrations.     

The P3 domain of E. coli ribonuclease P RNA can be truncated and replaced

We prepared some truncated and replaced P3 mutants of Escherichia coli RNase P RNA, and used them to examine the RNase P ribozyme and holoenzyme reactions of a pre-tRNA substrate. The results indicated that mutations in the P3 domain did not affect the cleavage site selection of the pre-tRNA substrate, but did affect the efficiency of cleavage of the substrate. Results of stepwise truncation of the P3 domain and its replacement by the TAR sequence showed that the P3 domain of the E. coli RNase P was able to be truncated to certain length and was replaceable, but could not be deleted in the ribozyme.     

Activation of bacterial ribonuclease P by macrolides

The effect of macrolide antibiotic spiramycin on RNase P holoenzyme and M1 RNA from Escherichia coli was investigated. Ribonuclease P (RNase P) is a ribozyme that is responsible for the maturation of 5' termini of tRNA molecules. Spiramycin revealed a dose-dependent activation on pre-tRNA cleavage by E. coli RNase P holoenzyme and M1 RNA. The K s and V max, as well as the K s(app) and V max(app) values of RNase P holoenzyme and M1 RNA in the presence or absence of spiramycin, were calculated from primary and secondary kinetic plots. It was found that the activity status of RNase P holoenzyme and M1 RNA is improved by the presence of spiramycin 18- and 12-fold, respectively. Primer extension analysis revealed that spiramycin induces a conformational change of the P10/11 structural element of M1 RNA, which is involved in substrate recognition.     

The P4 metal binding site in RNase P RNA affects active site metal affinity through substrate positioning

Although helix P4 in the catalytic domain of the RNase P ribozyme is known to coordinate magnesium ions important for activity, distinguishing between direct and indirect roles in catalysis has been difficult. Here, we provide evidence for an indirect role in catalysis by showing that while the universally conserved bulge of helix P4 is positioned 5 nt downstream of the cleavage site, changes in its structure can still purturb active site metal binding. Because changes in helix P4 also appear to alter its position relative to the pre-tRNA cleavage site, these data suggest that P4 contributes to catalytic metal ion binding through substrate positioning.     

Concurrent molecular recognition of the amino acid and tRNA by a ribozyme.

We have recently reported an in vitro-evolved precursor tRNA (pre-tRNA) that is able to catalyze aminoacylation on its own 3'-hydroxyl group. This catalytic pre-tRNA is susceptible to RNase P RNA, generating the 5'-leader ribozyme and mature tRNA. The 5'-leader ribozyme is also capable of aminoacylating the tRNA in trans, thus acting as an aminoacyl-tRNA synthetase-like ribozyme (ARS-like ribozyme). Here we report its structural characterization that reveals the essential catalytic core. The ribozyme consists of three stem-loops connected by two junction regions. The chemical probing analyses show that a U-rich region (U59-U62 in J2a/3 and U67-U68 in L3) of the ribozyme is responsible for the recognition of the phenylalanine substrate. Moreover, a GGU-motif (G70-U72) of the ribozyme, adjacent to the U-rich region, forms base pairs with the tRNA 3' terminus. Our demonstration shows that simple RNA motifs can recognize both the amino acid and tRNA simultaneously, thus aminoacylating the 3' terminus of tRNA in trans.     

Modification interference approach to detect ribose moieties important for the optimal activity of a ribozyme.

A new approach for modification interference studies is presented. It involves the use of phosphorothioates as a handle to analyze any desired base or sugar modification. This method was applied to identify ribose and phosphate moieties which could be important in the pre-tRNA recognition of E. coli RNase P RNA (M1 RNA). The utility of this technique was confirmed by detecting the inhibitory effect of a deoxyribose in the 5'-flank (position-1). This site was already known to interfere with RNase P cleavage, if modified. We have analyzed pre-tRNA(Tyr) and pre-tRNA(Phe) and found different interference patterns for both tRNAs. Two unpaired regions were involved in both pre-tRNAs. Phosphorothioates interfered at the transition between acceptor- and D-arms. The results with deoxythymidines in the T-loop indicated that deoxyribose moieties or the extra methyl group in thymidine could interfere with RNAse P cleavage. These data suggest that even in complete pre-tRNAs, only a few intact ribonucleotides are important in the substrate recognition by RNase P. We have demonstrated the potential of this new approach which offers many future applications in all fields involving nucleic acids, for example RNA processing, action of ribozymes, tRNA charging and studies related to DNA promoter recognition.     

Comparative analyses of hairpin substrate recognition by Escherichia coli and Bacillus subtilis ribonuclease P ribozymes

Previously, we reported that the substrate shape recognition of the Escherichia coli ribonuclease (RNase) P ribozyme depends on the concentration of magnesium ion in vitro. We additionally examined the Bacillus subtilis RNase P ribozyme and found that the B. subtilis enzyme also required high magnesium ion, above 10 mM, for cleavage of a hairpin substrate. The results of kinetic studies showed that the metal ion concentration affected both the catalysis and the affinity of the ribozymes toward a hairpin RNA substrate.     

Identification of Nucleotide Residues Essential for RNase P Activity from the Hyperthermophilic Archaeon Pyrococcus horikoshii OT3

Ribonuclease P (RNase P) is involved in the processing of the 5′ leader sequence of precursor tRNA (pre-tRNA). We have found that RNase P RNA (PhopRNA) and five proteins (PhoPop5, PhoRpp21, PhoRpp29, PhoRpp30, and PhoRpp38) reconstitute RNase P activity with enzymatic properties similar to those of the authentic ribozyme from the hyperthermophilic archaeon Pyrococcus horikoshii OT3. We report here that nucleotides A40, A41, and U44 at helix P4, and G269 and G270 located at L15/16 in PhopRNA, are, like the corresponding residues in Esherichia coli RNase P RNA (M1RNA), involved in hydrolysis by coordinating catalytic Mg²⁺ ions, and in the recognition of the acceptor end (CCA) of pre-tRNA by base-pairing, respectively. The information reported here strongly suggests that PhopRNA catalyzes the hydrolysis of pre-tRNA in approximately the same manner as eubacterial RNase P RNAs, even though it has no enzymatic activity in the absence of the proteins.     

The RNR motif of B. subtilis RNase P protein interacts with both PRNA and pre-tRNA to stabilize an active conformer

Ribonuclease P (RNase P) catalyzes the metal-dependent 5′ end maturation of precursor tRNAs (pre-tRNAs). In Bacteria, RNase P is composed of a catalytic RNA (PRNA) and a protein subunit (P protein) necessary for function in vivo. The P protein enhances pre-tRNA affinity, selectivity, and cleavage efficiency, as well as modulates the cation requirement for RNase P function. Bacterial P proteins share little sequence conservation although the protein structures are homologous. Here we combine site-directed mutagenesis, affinity measurements, and single turnover kinetics to demonstrate that two residues (R60 and R62) in the most highly conserved region of the P protein, the RNR motif (R60–R68 in Bacillus subtilis), stabilize PRNA complexes with both P protein (PRNA•P protein) and pre-tRNA (PRNA•P protein•pre-tRNA). Additionally, these data indicate that the RNR motif enhances a metal-stabilized conformational change in RNase P that accompanies substrate binding and is essential for efficient catalysis. Stabilization of this conformational change contributes to both the decreased metal requirement and the enhanced substrate recognition of the RNase P holoenzyme, illuminating the role of the most highly conserved region of P protein in the RNase P reaction pathway.     

Conformational change in the Bacillus subtilis RNase P holoenzyme–pre-tRNA complex enhances substrate affinity and limits cleavage rate

Ribonuclease P (RNase P) is a ribonucleoprotein complex that catalyzes the 5′ maturation of precursor tRNAs. To investigate the mechanism of substrate recognition in this enzyme, we characterize the thermodynamics and kinetics of Bacillus subtilis pre-tRNA^Asp binding to B. subtilis RNase P holoenzyme using fluorescence techniques. Time courses for fluorescein-labeled pre-tRNA binding to RNase P are biphasic in the presence of both Ca(II) and Mg(II), requiring a minimal two-step association mechanism. In the first step, the apparent bimolecular rate constant for pre-tRNA associating with RNase P has a value that is near the diffusion limit and is independent of the length of the pre-tRNA leader. Following formation of the initial enzyme–substrate complex, a unimolecular step enhances the overall affinity of pre-tRNA by eight- to 300-fold as the length of the leader sequence increases from 2 to 5 nucleotides. This increase in affinity is due to a decrease in the reverse rate constant for the conformational change that correlates with the formation of an optimal leader–protein interaction in the RNase P holoenzyme–pre-tRNA complex. Furthermore, the forward rate constant for the conformational change becomes rate limiting for cleavage under single-turnover conditions at high pH, explaining the origin of the observed apparent pK_a in the RNase P-catalyzed cleavage reaction. These data suggest that a conformational change in the RNase P•pre-tRNA complex is coupled to the interactions between the 5′ leader and P protein and aligns essential functional groups at the cleavage active site to enhance efficient cleavage of pre-tRNA.