Crystal structure of the tRNA processing enzyme RNase PH from Aquifex aeolicus

RNase PH is one of the exoribonucleases that catalyze the 3' end processing of tRNA in bacteria. RNase PH removes nucleotides following the CCA sequence of tRNA precursors by phosphorolysis and generates mature tRNAs with amino acid acceptor activity. In this study, we determined the crystal structure of Aquifex aeolicus RNase PH bound with a phosphate, a co-substrate, in the active site at 2.3-A resolution. RNase PH has the typical alpha/beta fold, which forms a hexameric ring structure as a trimer of dimers. This ring structure resembles that of the polynucleotide phosphorylase core domain homotrimer, another phosphorolytic exoribonuclease. Four amino acid residues, Arg-86, Gly-124, Thr-125, and Arg-126, of RNase PH are involved in the phosphate-binding site. Mutational analyses of these residues showed their importance in the phosphorolysis reaction. A docking model with the tRNA acceptor stem suggests how RNase PH accommodates substrate RNAs.     

Ribonuclease PH plays a major role in the exonucleolytic maturation of CCA-containing tRNA precursors in Bacillus subtilis

In contrast to Escherichia coli, where all tRNAs have the CCA motif encoded by their genes, two classes of tRNA precursors exist in the Gram-positive bacterium Bacillus subtilis. Previous evidence had shown that ribonuclease Z (RNase Z) was responsible for the endonucleolytic maturation of the 3' end of those tRNAs lacking an encoded CCA motif, accounting for about one-third of its tRNAs. This suggested that a second pathway of tRNA maturation must exist for those precursors with an encoded CCA motif. In this paper, we examine the potential role of the four known exoribonucleases of B.subtilis, PNPase, RNase R, RNase PH and YhaM, in this alternative pathway. In the absence of RNase PH, precursors of CCA-containing tRNAs accumulate that are a few nucleotides longer than the mature tRNA species observed in wild-type strains or in the other single exonuclease mutants. Thus, RNase PH plays an important role in removing the last few nucleotides of the tRNA precursor in vivo. The presence of three or four exonuclease mutations in a single strain results in CCA-containing tRNA precursors of increasing size, suggesting that, as in E.coli, the exonucleolytic pathway consists of multiple redundant enzymes. Assays of purified RNase PH using in vitro-synthesized tRNA precursor substrates suggest that RNase PH is sensitive to the presence of a CCA motif. The division of labor between the endonucleolytic and exonucleolytic pathways observed in vivo can be explained by the inhibition of RNase Z by the CCA motif in CCA-containing tRNA precursors and by the inhibition of exonucleases by stable secondary structure in the 3' extensions of the majority of CCA-less tRNAs.     

The effects of matrices of paired substitutions in mid-acceptor stem on Drosophila tRNA(His) structure and end-processing

End-maturation reactions, in which the 5' end leader and 3' end trailer of precursor tRNA are removed by RNase P and 3'-tRNase, respectively, are early, essential steps in eukaryotic precursor tRNA processing. End-processing enzymes may be expected to contact the acceptor stem of tRNA due to its proximity to both cleavage sites. We constructed matrices of pair-wise substitutions in mid-acceptor stem at nt 3/70 and 4/69 of Drosophila tRNA(His) and analyzed their ability to be processed by Drosophila RNase P and 3'-tRNase. In accord with our earlier study of D/T loop processing matrices, we find that tRNA end processing enzymes respond to sequence changes differently. More processing defects were observed with 3'-tRNase than with RNase P, and substitutions at 4/69 reduced processing more than those at 3/70. We evaluated tRNA folding using structure probing nucleases and investigated the contribution of K(M) and V(Max) to the processing efficiency of selected variants. In one substitution (C3A), mis-folding correlates with processing defects. In another (C69A), a disruption of structure appears to be transmitted laterally to both ends of the acceptor stem. Poor processing of C69A by RNase P is due entirely to a reduction in V(Max), but for 3'-tRNase, it is due to an increase in K(M).     

Processing of a multimeric tRNA precursor from Bacillus subtilis by the RNA component of RNase P

Processing of multimeric precursor tRNAs from Bacillus subtilis by the catalytic RNA component of RNase P was studied in vitro. Previous studies on processing by either Escherichia coli or B. subtilis RNase P-RNA utilized monomeric or dimeric substrates. In the experiments described here, a multimeric precursor tRNA containing six complete tRNA sequences and the partial sequence of a seventh were used. One species did not encode the 3'-terminal CCA sequence and the partial tRNA lacked 3' nucleotides and could form only a 3-base pair instead of a 7-base paired aminoacyl stem. Two species had the potential for forming extended base-paired aminoacyl stems. Processing was studied under varied ionic conditions. Chemical sequencing of the products showed that the RNase P-RNA cleavage produced the proper mature 5' termini for all of the six complete tRNA species, but no 5'-cleavage of the partial species was observed. At suboptimal ionic concentrations, the two species capable of forming extended base-paired aminoacyl stems were not observed. Thus, encoding of the 3'-CCA in a tRNA species is not critical for processing, but the formation of an aminoacyl stem with more than 3 base pairs is necessary. Particularly noteworthy was the observation that all species of the multimeric precursor could be processed at significantly lower ionic conditions than monomeric precursors used previously by ourselves and others. However, a single precursor species produced from the multimeric precursor could also be processed at the same lower ionic conditions as the multimeric precursor. This demonstrates that precursor tRNA species can differ widely in their ionic requirements for processing and that, to a large extent, the optimal conditions of MgCl2 or NH4Cl are a function of the substrate which is used.     

Crystal structure of the phosphorolytic exoribonuclease RNase PH from Bacillus subtilis and implications for its quaternary structure and tRNA binding

RNase PH is a member of the family of phosphorolytic 3' --> 5' exoribonucleases that also includes polynucleotide phosphorylase (PNPase). RNase PH is involved in the maturation of tRNA precursors and especially important for removal of nucleotide residues near the CCA acceptor end of the mature tRNAs. Wild-type and triple mutant R68Q-R73Q-R76Q RNase PH from Bacillus subtilis have been crystallized and the structures determined by X-ray diffraction to medium resolution. Wild-type and triple mutant RNase PH crystallize as a hexamer and dimer, respectively. The structures contain a rare left-handed beta alpha beta-motif in the N-terminal portion of the protein. This motif has also been identified in other enzymes involved in RNA metabolism. The RNase PH structure and active site can, despite low sequence similarity, be overlayed with the N-terminal core of the structure and active site of Streptomyces antibioticus PNPase. The surface of the RNase PH dimer fit the shape of a tRNA molecule.     

RNase PH is essential for tRNA processing and viability in RNase-deficient Escherichia coli cells.

RNase PH is a Pi-dependent exoribonuclease that can act at the 3' terminus of tRNA precursors in vitro. To obtain information about the function of this enzyme in vivo, the Escherichia coli rph gene encoding RNase PH was interrupted with either a kanamycin resistance or a chloramphenicol resistance cassette and transferred to the chromosome of a variety of RNase-resistant strains. Inactivation of the chromosomal copy of rph eliminated RNase PH activity from extracts and also slowed the growth of many of the strains, particularly ones that already were deficient in RNase T or polynucleotide phosphorylase. Introduction of the rph mutation into a strain already lacking RNases I, II, D, BN, and T resulted in inviability. The rph mutation also had dramatic effects on tRNA metabolism. Using an in vivo suppressor assay we found that elimination of RNase PH greatly decreased the level of su3+ activity in cells deficient in certain of the other RNases. Moreover, in an in vitro tRNA processing system the defect caused by elimination of RNase PH was shown to be the accumulation of a precursor that contained 4-6 additional 3' nucleotides following the -CCA sequence. These data indicate that RNase PH can be an essential enzyme for the processing of tRNA precursors.     

The roles of intersubunit interactions in exosome stability

In eukaryotes, at least 10 proteins associate in a 3'-5' exonuclease complex, the exosome, which is involved in the processing of many RNA species. A recent model for the exosome placed six RNase PH-related components in a hexameric ring core structure, with three S1 domain proteins associated with the ring surface. So far, however, this model lacks experimental support. Using a combination of RNA interference, complex affinity purification, and yeast two-hybrid approaches, we show here that the RNase PH homologues are important for maintenance of complex integrity. In contrast, the S1 domain proteins are not required for complex stability, although they are required for exosome function. Our results are partially consistent with the proposed model of the exosome, but indicate a different arrangement of the RNase PH proteins.     

RNase PH catalyzes a synthetic reaction, the addition of nucleotides to the 3' end of RNA.

Escherichia coli RNase PH is a phosphate-dependent exoribonuclease that has been implicated in the 3' processing of tRNA precursors. It degrades RNA chains in a phosphorolytic manner releasing nucleoside diphosphates as products. Here we show that RNase PH also catalyzes a synthetic reaction, the addition of nucleotides to the 3' termini of RNA molecules. The synthetic activity co-purifies with RNase PH throughout an extensive enrichment indicating that it is due to the same enzyme. The synthetic activity can incorporate all nucleoside diphosphates, but not triphosphates, and is strongly inhibited by Pi, but not PPi. Various RNA molecules stimulate nucleotide incorporation, and with tRNA the 3' end of the molecule serves a primer function. RNA chains as long as 40 residues can be synthesized in this system. As with polynucleotide phosphorylase, the synthetic activity of RNase PH apparently represents the reversal of the degradative reaction.     

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.     

Analysis of the Saccharomyces cerevisiae exosome architecture and of the RNA binding activity of Rrp40p

The exosome is a complex of eleven subunits in yeast, involved in RNA processing and degradation. Despite the extensive in vivo functional studies of the exosome, little information is yet available on the structure of the complex and on the RNase and RNA binding activities of the individual subunits. The current model for the exosome structure predicts the formation of a heterohexameric RNase PH ring, bound on one side by RNA binding subunits, and on the opposite side by hydrolytic RNase subunits. Here, we report protein-protein interactions within the exosome, confirming the predictions of constituents of the RNase PH ring, and show some possible interaction interfaces between the other subunits. We also show evidence that Rrp40p can bind RNA in vitro, as predicted by sequence analysis.     

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.     

A novel function of RNase P from Escherichia coli: processing of a suppressor tRNA precursor.

The leuX gene of Escherichia coli codes for a suppressor tRNA and forms a single gene operon containing its own promoter and Q-independent terminator. An analysis of the in vitro processing of leuX precursor revealed that the processing of the 5' end took place in a single-step reaction catalysed by RNase P while the 3' processing involved two successive reactions. The endonucleolytic cleavage activity of the 3' precursor sequence was found to copurify with RNase P. Heat inactivation of thermosensitive RNase P from two independent E. coli mutants abolished the cleavage activity of both the 5' and 3' ends. These results altogether suggest that RNase P carries the activity of 3' end cleavage as well as that of 5' processing. In the presence of Mg2+ alone, the leuX precursor was found to be self-cleaved at a site approximately 13 nt inside from the 5' end of mature tRNA. The self-cleaved precursor tRNA was no longer processed by the 3' endonuclease, suggesting that the 3' endonuclease recognizes a specific conformation of the precursor tRNA for action.     

An in vitro evolved precursor tRNA with aminoacylation activity

A set of catalysts for aminoacyl-tRNA synthesis is an essential component for translation. The RNA world hypothesis postulates that RNA catalysts could have played this role. Here we show an in vitro evolved precursor tRNA consisting of two domains, a catalytic 5'-leader sequence and an aminoacyl-acceptor tRNA. The 5'-leader sequence domain selectively self-charges phenylalanine on the 3'-terminus of the tRNA domain. This cis-acting ribozyme is susceptible to RNase P RNA, generating the corresponding 5'-leader segment and the mature tRNA. Moreover, the 5'-leader segment is able to aminoacylate the mature tRNA in trans. Mutational studies have revealed that C(74) and C(75) at the tRNA aminoacyl-acceptor end form base pairs with G71 and G70 of the trans-acting ribozyme. Such Watson-Crick base pairing with tRNA has been observed in RNase P RNA and 23S rRNA, suggesting that all three ribozymes use a similar mechanism for the recognition of the aminoacyl-acceptor end. Our demonstrations indicate that catalytic precursor tRNAs could have provided the foundations for the genetic coding system in the proto-translation system.     

RNA channelling by the archaeal exosome

Exosomes are complexes containing 3' --> 5' exoribonucleases that have important roles in processing, decay and quality control of various RNA molecules. Archaeal exosomes consist of a hexameric core of three active RNase PH subunits (ribosomal RNA processing factor (Rrp)41) and three inactive RNase PH subunits (Rrp42). A trimeric ring of subunits with putative RNA-binding domains (Rrp4/cep1 synthetic lethality (Csl)4) is positioned on top of the hexamer on the opposite side to the RNA degrading sites. Here, we present the 1.6 A resolution crystal structure of the nine-subunit exosome of Sulfolobus solfataricus and the 2.3 A structure of this complex bound to an RNA substrate designed to be partly trimmed rather than completely degraded. The RNA binds both at the active site on one side of the molecule and on the opposite side in the narrowest constriction of the central channel. Multiple substrate-binding sites and the entrapment of the substrate in the central channel provide a rationale for the processive degradation of extended RNAs and the stalling of structured RNAs.     

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.     

Ion dependence of the Bacillus subtilis RNase P reaction

The properties of the Bacillus subtilis RNase P are characterized with regard to the types and concentrations of monovalent and divalent ions required to potentiate precursor tRNA cleavage by the protein-RNA holoenzyme and the catalytic RNA alone. The ionic dependence of the RNase P RNA-catalyzed reaction in part seems due to a requirement for ion shielding between substrate and catalytic RNAs. The RNase P protein, which binds to RNA nonspecifically and tightly, likely serves, in part, as a cation screen. However, the character of the ion dependence of the RNA catalysis, the inhibition by high SO2-4 concentration, and potentiation by solvents suggest that RNA conformational transition may be involved in the reaction. It is proposed that the reason for catalysis by RNA in the RNase P reaction may be a requirement for fluidity in the structure of the catalyst, so that it can accommodate many tRNA substrates, which vary in their structural details.     

The archaeal exosome core is a hexameric ring structure with three catalytic subunits

The exosome is a 3' --> 5' exoribonuclease complex involved in RNA processing. We report the crystal structure of the RNase PH core complex of the Sulfolobus solfataricus exosome determined at a resolution of 2.8 A. The structure reveals a hexameric ring-like arrangement of three Rrp41-Rrp42 heterodimers, where both subunits adopt the RNase PH fold common to phosphorolytic exoribonucleases. Structure-guided mutagenesis reveals that the activity of the complex resides within the active sites of the Rrp41 subunits, all three of which face the same side of the hexameric structure. The Rrp42 subunit is inactive but contributes to the structuring of the Rrp41 active site. The high sequence similarity of this archaeal exosome to eukaryotic exosomes and its high structural similarity to the bacterial mRNA-degrading PNPase support a common basis for RNA-degrading machineries in all three domains of life.