An essential protein-binding domain of nuclear RNase P RNA

Eukaryotic RNase P and RNase MRP are endoribonucleases composed of RNA and protein subunits. The RNA subunits of each enzyme share substantial secondary structural features, and most of the protein subunits are shared between the two. One of the conserved RNA subdomains, designated P3, has previously been shown to be required for nucleolar localization. Phylogenetic sequence analysis suggests that the P3 domain interacts with one of the proteins common to RNase P and RNase MRP, a conclusion strengthened by an earlier observation that the essential domain can be interchanged between the two enzymes. To examine possible functions of the P3 domain, four conserved nucleotides in the P3 domain of Saccharomyces cerevisiae RNase P RNA (RPR1) were randomized to create a library of all possible sequence combinations at those positions. Selection of functional genes in vivo identified permissible variations, and viable clones that caused yeast to exhibit conditional growth phenotypes were tested for defects in RNase P RNA and tRNA biosynthesis. Under nonpermissive conditions, the mutants had reduced maturation of the RPR1 RNA precursor, an expected phenotype in cases where RNase P holoenzyme assembly is defective. This loss of RPR1 RNA maturation coincided, as expected, with a loss of pre-tRNA maturation characteristic of RNase P defects. To test whether mutations at the conserved positions inhibited interactions with a particular protein, specific binding of the individual protein subunits to the RNA subunit was tested in yeast using the three-hybrid system. Pop1p, the largest subunit shared by RNases P and MRP, bound specifically to RPR1 RNA and the isolated P3 domain, and this binding was eliminated by mutations at the conserved P3 residues. These results indicate that Pop1p interacts with the P3 domain common to RNases P and MRP, and that this interaction is critical in the maturation of RNase P holoenzyme.     

A conserved RNA motif involved in divalent cation utilization by nuclear RNase P.

Catalytic RNAs are metalloenzymes that require precise coordination of divalent cation cofactors. In RNase P RNA, a conserved structural subdomain that has been implicated in magnesium coordination contains the consensus sequence acAGaRA. Randomization mutagenesis of the analogous sequence in the Saccharomyces cerevisiae nuclear RNase P RNA gene, RPR1, gave viable sequence variants that confer magnesium-correctable growth defects and are defective in magnesium cofactor utilization by the RNase P holoenzyme in vitro. Kinetic analysis of the defective holoenzymes suggests that the primary effects were on catalytic rate, rather than substrate recognition. The possible involvement of this RNA subdomain in catalysis is discussed.     

Characterization of conserved sequence elements in eukaryotic RNase P RNA reveals roles in holoenzyme assembly and tRNA processing

RNase P is a ubiquitous endoribonuclease responsible for cleavage of the 5' leader of precursor tRNAs (pre-tRNAs). Although the protein composition of RNase P holoenzymes varies significantly among Bacteria, Archaea, and Eukarya, the holoenzymes have essential RNA subunits with several sequences and structural features that are common to all three kingdoms of life. Additional structural elements of the RNA subunits have been found that are conserved in eukaryotes, but not in bacteria, and might have functions specifically required by the more complex eukaryotic holoenzymes. In this study, we have mutated four eukaryotic-specific conserved regions in Saccharomyces cerevisiae nuclear RNase P RNA and characterized the effects of the mutations on cell growth, enzyme function, and biogenesis of RNase P. RNase P with mutations in each of the four regions tested is sufficiently functional to support life although growth of the resulting yeast strains was compromised to varying extents. Further analysis revealed that mutations in three different regions cause differential defects in holoenzyme assembly, localization, and pre-tRNA processing in vivo and in vitro. These data suggest that most, but not all, eukaryotic-specific conserved regions of RNase P RNA are important for the maturation and function of the holoenzyme.     

Processing of histidine transfer RNA precursors. Abnormal cleavage site for RNase P

The 5'-terminal guanylate residue (G-1) of mature Escherichia coli tRNA(His) is generated as a result of an unusual cleavage by RNase P (Orellana, O., Cooley, L., and S?ll, D. (1986) Mol. Cell. Biol. 6, 525-529). We have examined the importance of the unique acceptor stem structure of E. coli tRNA(His) in determining the specificity of RNase P cleavage. Mutant tRNA(His) precursors bearing substitutions of the normal base G-1 or the opposing, potentially paired base, C73, can be cleaved at the +1 position, in contrast to wild-type precursors which are cut exclusively at the -1 position. These data indicate that the nature of the base at position -1 is of greater importance in determining the site of RNase P cleavage than potential base pairing between nucleotides -1 and 73. In addition, processing of the mutant precursors by M1-RNA or P RNA under conditions of ribozyme catalysis yields a higher proportion of +1-cleaved products in comparison to the reaction catalyzed by the RNase P holoenzyme. This lower sensitivity of the holoenzyme to alterations in acceptor stem structure suggests that the protein moiety of RNase P may play a role in determining the specificity of the reaction and implies that recognition of the substrate involves additional regions of the tRNA. We have also shown that the RNase P holoenzyme and tRNA(His) precursor of Saccharomyces cerevisiae, unlike their prokaryotic counterparts, do not possess these abilities to carry out this unusual reaction.     

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.     

A novel tertiary interaction in M1 RNA, the catalytic subunit of Escherichia coli RNase P.

Phylogenetic covariation of the nucleotides corresponding to the bases at positions 121 and 236 in Escherichia coli RNase P RNA (M1 RNA) has been demonstrated in eubacterial RNase P RNAs. To investigate whether the nucleotides at these positions interact in M1 RNA we introduced base substitutions at either or at both of these positions. Single base substitutions at 121 or at 236 resulted in M1 RNA molecules which did not complement the temperature-sensitive phenotype associated with rnpA49 in vivo whereas wild-type M1 RNA or the double mutant M1 RNA, with restored base-pairing between 121 and 236, did. In addition, wild-type and the double mutant M1 RNA were efficiently cleaved by Pb++ between positions 122 and 123 whereas the rate of this cleavage was significantly reduced for the singly mutated M1 RNA variants. From these data we conclude that the nucleotides at positions 121 and 236 in M1 RNA establish a novel long-range tertiary interaction in M1 RNA. Our results also demonstrated that this interaction is not absolutely required for cleavage in vitro, however, a disruption resulted in a reduction in cleavage efficiency (kcat/Km), both in the absence and presence of C5.     

Several regions of a tRNA precursor determine the Escherichia coli RNase P cleavage site.

The RNase P cleavage reaction was studied as a function of the number of base-pairs in the acceptor-stem and/or T-stem of a natural tRNA precursor, the tRNA(Tyr)Su3 precursor. Our data suggest that the location of the Escherichia coli RNase P cleavage site does not depend merely on the lengths of the acceptor-stem and T-stem as previously suggested. Surprisingly, we find that precursors with only four base-pairs in the acceptor-stem are cleaved by M1 RNA and by holoenzyme. Furthermore, we show that both disruption of base-pairing, and alteration of the nucleotide sequence (without disruption of base-pairing) proximal to the cleavage site result in aberrant cleavage. Thus, the identity of the nucleotides near the cleavage site is important for recognition of the cleavage site rather than base-pairing. The important nucleotides are those at positions -2, -1, +1, +72, +73 and +74. We propose that the nucleotide at position +1 functions as a guiding nucleotide. These results raise the possibility that Mg2+ binding near the cleavage site is dependent on the identity of the nucleotides at these positions. In addition, we show that disruption of base-pairing in the acceptor-stem affects both Michaelis-Menten constants, Km and kcat.     

Elucidation of structure–function relationships in Methanocaldococcus jannaschii RNase P,a multi-subunit catalytic ribonucleoprotein

RNase P is a ribonucleoprotein (RNP) that catalyzes removal of the 5′ leader from precursor tRNAs in all domains of life. A recent cryo-EM study of Methanocaldococcus jannaschii (Mja) RNase P produced a model at 4.6-Å resolution in a dimeric configuration, with each holoenzyme monomer containing one RNase P RNA (RPR) and one copy each of five RNase P proteins (RPPs; POP5, RPP30, RPP21, RPP29, L7Ae). Here, we used native mass spectrometry (MS), mass photometry (MP), and biochemical experiments that (i) validate the oligomeric state of the Mja RNase P holoenzyme in vitro, (ii) find a different stoichiometry for each holoenzyme monomer with up to two copies of L7Ae, and (iii) assess whether both L7Ae copies are necessary for optimal cleavage activity. By mutating all kink-turns in the RPR, we made the discovery that abolishing the canonical L7Ae–RPR interactions was not detrimental for RNase P assembly and function due to the redundancy provided by protein–protein interactions between L7Ae and other RPPs. Our results provide new insights into the architecture and evolution of RNase P, and highlight the utility of native MS and MP in integrated structural biology approaches that seek to augment the information obtained from low/medium-resolution cryo-EM models.     

Phylogenetic comparative mutational analysis of the base-pairing between RNase P RNA and its substrate.

We have studied the base-pairing between the 3'-terminal CCA motif of a tRNA precursor and RNase P RNA by a phylogenetic mutational comparative approach. Thus, various derivatives of the Escherichia coli tRNA(Ser)Su1 precursor harboring all possible substitutions at either the first or the second C of the 3'-terminal CCA motif were generated. Cleavage site selection on these precursors was studied using mutant variants of M1 RNA, the catalytic subunit of E. coli RNase P, carrying changes at positions 292 or 293, which are involved in the interaction with the 3'-terminal CCA motif. From our data we conclude that these two C's in the substrate interact with the well-conserved G292 and G293 through canonical Watson-Crick base-pairing. Cleavage performed using reconstituted holoenzyme complexes suggests that this interaction also occurs in the presence of the C5 protein. Furthermore, we studied the interaction using various derivatives of RNase P RNAs from Mycoplasma hyopneumoniae and Mycobacterium tuberculosis. Our results suggest that the base-pairing between the 3'-terminal CCA motif and RNase P is present also in other bacterial RNase P-substrate complexes and is not limited to a particular bacterial species.     

Functional characterization of the conserved amino acids in Pop1p, the largest common protein subunit of yeast RNases P and MRP

RNase P and RNase MRP are ribonucleoprotein enzymes required for 5'-end maturation of precursor tRNAs (pre-tRNAs) and processing of precursor ribosomal RNAs, respectively. In yeast, RNase P and MRP holoenzymes have eight protein subunits in common, with Pop1p being the largest at >100 kDa. Little is known about the functions of Pop1p, beyond the fact that it binds specifically to the RNase P RNA subunit, RPR1 RNA. In this study, we refined the previous Pop1 phylogenetic sequence alignment and found four conserved regions. Highly conserved amino acids in yeast Pop1p were mutagenized by randomization and conditionally defective mutations were obtained. Effects of the Pop1p mutations on pre-tRNA processing, pre-rRNA processing, and stability of the RNA subunits of RNase P and MRP were examined. In most cases, functional defects in RNase P and RNase MRP in vivo were consistent with assembly defects of the holoenzymes, although moderate kinetic defects in RNase P were also observed. Most mutations affected both pre-tRNA and pre-rRNA processing, but a few mutations preferentially interfered with only RNase P or only RNase MRP. In addition, one temperature-sensitive mutation had no effect on either tRNA or rRNA processing, consistent with an additional role for RNase P, RNase MRP, or Pop1p in some other form. This study shows that the Pop1p subunit plays multiple roles in the assembly and function of of RNases P and MRP, and that the functions can be differentiated through the mutations in conserved residues.     

Bacterial ribonuclease P holoenzyme crosslinking analysis reveals protein interaction sites on the RNA subunit

The structure of the Escherichia coli ribonuclease P (RNase P) holoenzyme was investigated by site-directed attachment of an aryl azide crosslink reagent to specific sites in the protein subunit of the enzyme. The sites of crosslinking to the RNase P RNA subunit were mapped by primer extension to several conserved residues and structural features throughout the RNA. The results suggest rearrangement of current tertiary models of the RNA subunit, particularly in regions poorly constrained by earlier data. Crosslinks to the substrate precursor-tRNA were also detected, consistent with previous crosslinking results in the Bacillus subtilis RNase P holoenzyme.     

Protein cofactors and substrate influence Mg2+-dependent structural changes in the catalytic RNA of archaeal RNase P

The ribonucleoprotein (RNP) form of archaeal RNase P comprises one catalytic RNA and five protein cofactors. To catalyze Mg²⁺-dependent cleavage of the 5′ leader from pre-tRNAs, the catalytic (C) and specificity (S) domains of the RNase P RNA (RPR) cooperate to recognize different parts of the pre-tRNA. While ∼250–500 mM Mg²⁺ renders the archaeal RPR active without RNase P proteins (RPPs), addition of all RPPs lowers the Mg²⁺ requirement to ∼10–20 mM and improves the rate and fidelity of cleavage. To understand the Mg²⁺- and RPP-dependent structural changes that increase activity, we used pre-tRNA cleavage and ensemble FRET assays to characterize inter-domain interactions in Pyrococcus furiosus (Pfu) RPR, either alone or with RPPs ± pre-tRNA. Following splint ligation to doubly label the RPR (Cy3-RPR_{C domain} and Cy5-RPR_{S domain}), we used native mass spectrometry to verify the final product. We found that FRET correlates closely with activity, the Pfu RPR and RNase P holoenzyme (RPR + 5 RPPs) traverse different Mg²⁺-dependent paths to converge on similar functional states, and binding of the pre-tRNA by the holoenzyme influences Mg²⁺ cooperativity. Our findings highlight how Mg²⁺ and proteins in multi-subunit RNPs together favor RNA conformations in a dynamic ensemble for functional gains.     

Cooperative RNP assembly: complementary rescue of structural defects by protein and RNA subunits of archaeal RNase P

Ribonuclease P (RNase P) is a ribonucleoprotein complex that utilizes a Mg(2+)-dependent RNA catalyst to cleave the 5' leader of precursor tRNAs (pre-tRNAs) and generate mature tRNAs. The bacterial RNase P protein (RPP) aids RNase P RNA (RPR) catalysis by promoting substrate binding, Mg(2+) coordination and product release. Archaeal RNase P comprises an RPR and at least four RPPs, which have eukaryal homologs and function as two binary complexes (POP5·RPP30 and RPP21·RPP29). Here, we employed a previously characterized substrate-enzyme conjugate [pre-tRNA(Tyr)-Methanocaldococcus jannaschii (Mja) RPR] to investigate the functional role of a universally conserved uridine in a bulge-helix structure in archaeal RPRs. Deletion of this bulged uridine resulted in an 80-fold decrease in the self-cleavage rate of pre-tRNA(Tyr)-MjaΔU RPR compared to the wild type, and this defect was partially ameliorated upon addition of either RPP pair. The catalytic defect in the archaeal mutant RPR mirrors that reported in a bacterial RPR and highlights a parallel in their active sites. Furthermore, an N-terminal deletion mutant of Pyrococcus furiosus (Pfu) RPP29 that is defective in assembling with its binary partner RPP21, as assessed by isothermal titration calorimetry and NMR spectroscopy, is functional when reconstituted with the cognate Pfu RPR. Collectively, these results indicate that archaeal RPPs are able to compensate for structural defects in their cognate RPR and vice-versa, and provide striking examples of the cooperative subunit interactions critical for driving archaeal RNase P toward its functional conformation.     

In vitro selection of RNase P RNA reveals optimized catalytic activity in a highly conserved structural domain.

In vitro selection techniques are useful means of dissecting the functions of both natural and artificial ribozymes. Using a self-cleaving conjugate containing the Escherichia coli ribonuclease P RNA and its substrate, pre-tRNA (Frank DN, Harris ME, Pace NR, 1994, Biochemistry 33:10800-10808), we have devised a method to select for catalytically active variants of the RNase P ribozyme. A selection experiment was performed to probe the structural and sequence constraints that operate on a highly conserved region of RNase P: the J3/4-P4-J2/4 region, which lies within the core of RNase P and is thought to bind catalytically essential magnesium ions (Harris ME et al., 1994, EMBO J 13:3953-3963; Hardt WD et al., 1995, EMBO J 14:2935-2944; Harris ME, Pace NR, 1995, RNA 1:210-218). We sought to determine which, if any, of the nearly invariant nucleotides within J3/4-P4-J2/4 are required for ribozyme-mediated catalysis. Twenty-two residues in the J3/4-P4-J2/4 component of RNase P RNA were randomized and, surprisingly, after only 10 generations, each of the randomized positions returned to the wild-type sequence. This indicates that every position in J3/4-P4-J2/4 contributes to optimal catalytic activity. These results contrast sharply with selections involving other large ribozymes, which evolve improved catalytic function readily in vitro (Chapman KB, Szostak JW, 1994, Curr Opin Struct Biol 4:618-622; Joyce GF, 1994, Curr Opin Struct Biol 4:331-336; Kumar PKR, Ellington AE, 1995, FASEB J 9:1183-1195). The phylogenetic conservation of J3/4-P4-J2/4, coupled with the results reported here, suggests that the contribution of this structure to RNA-mediated catalysis was optimized very early in evolution, before the last common ancestor of all life.     

Mapping RNA-protein interactions in ribonuclease P from Escherichia coli using disulfide-linked EDTA-Fe

The protein subunit of Escherichia coli ribonuclease P (which has a cysteine residue at position 113) and its single cysteine-substituted mutant derivatives (S16C/C113S, K54C/C113S and K66C/C113S) have been modified using a sulfhydryl-specific iron complex of EDTA-2- aminoethyl 2-pyridyl disulfide (EPD-Fe). This reaction converts C5 protein, or its single cysteine-substituted mutant derivatives, into chemical nucleases which are capable of cleaving the cognate RNA ligand, M1 RNA, the catalytic RNA subunit of E. coli RNase P, in the presence of ascorbate and hydrogen peroxide. Cleavages in M1 RNA are expected to occur at positions proximal to the site of contact between the modified residue (in C5 protein) and the ribose units in M1 RNA. When EPD-Fe was used to modify residue Cys16 in C5 protein, hydroxyl radical-mediated cleavages occurred predominantly in the P3 helix of M1 RNA present in the reconstituted holoenzyme. C5 Cys54-EDTA-Fe produced cleavages on the 5' strand of the P4 pseudoknot of M1 RNA, while the cleavages promoted by C5 Cys66-EDTA-Fe were in the loop connecting helices P18 and P2 (J18/2) and the loop (J2/4) preceding the 3' strand of the P4 pseudoknot. However, hydroxyl radical-mediated cleavages in M1 RNA were not evident with Cys113-EDTA-Fe, perhaps indicative of Cys113 being distal from the RNA-protein interface in the RNase P holoenzyme. Our directed hydroxyl radical-mediated footprinting experiments indicate that conserved residues in the RNA and protein subunit of the RNase-P holoenzyme are adjacent to each other and provide structural information essential for understanding the assembly of RNase P.     

Contribution of structural elements to Thermus thermophilus ribonuclease P RNA function.

We have performed a deletion and mutational analysis of the catalytic ribonuclease (RNase) P RNA subunit from the extreme thermophilic eubacterium Thermus thermophilus HB8. Catalytic activity was reduced 600-fold when the terminal helix, connecting the 5' and 3' ends of the molecule, was destroyed by deleting 15 nucleotides from the 3' end. In comparison, the removal of a large portion (94 nucleotides, about one quarter of the RNA) of the upper loop region impaired function only to a relatively moderate extent (400-fold reduction in activity). The terminal helix appears to be crucial for the proper folding of RNase P RNA, possibly by orientating the adjacent universally conserved pseudoknot structure. The region containing the lower half of the pseudoknot structure was shown to be a key element for enzyme function, as was the region of nucleotides 328-335. Deleting a conserved hairpin (nucleotides 304-327) adjacent to this region and replacing the hairpin by a tetranucleotide sequence or a single cytidine reduced catalytic activity only 6-fold, whereas a simultaneous mutation of the five highly conserved nucleotides in the region of nucleotides 328-335 reduced catalytic activity by > 10(5)-fold. The two strictly conserved adenines 244 and 245 (nucleotides 248/249 in Escherichia coli RNase P RNA) were not as essential for enzyme function as suggested by previous data. However, additional disruption of two helical segments (nucleotides 235-242) adjacent to nucleotides 244 and 245 reduced activity by > 10(4)-fold, supporting the notion that nucleotides in this region are also part of the active core structure.(ABSTRACT TRUNCATED AT 250 WORDS)