Cleavage mediated by the catalytic domain of bacterial RNase P RNA.

Like other RNA molecules, RNase P RNA (RPR) is composed of domains, and these have different functions. Here, we provide data demonstrating that the catalytic (C) domain of Escherichia coli (Eco) RPR when separated from the specificity (S) domain mediates cleavage using various model RNA hairpin loop substrates. Compared to full-length Eco RPR, the rate constant, k(obs), of cleavage for the truncated RPR (CP RPR) was reduced 30- to 13,000-fold depending on substrate. Specifically, the structural architecture of the -1/+73 played a significant role where a C(-1)/G(+73) pair had the most dramatic effect on k(obs). Substitution of A(248) (E. coli numbering), positioned near the cleavage site in the RNase P-substrate complex, with G in the CP RPR resulted in 30-fold improvement in rate. In contrast, strengthening the interaction between the RPR and the 3' end of the substrate only had a modest effect. Interestingly, although deleting the S-domain gave a reduction in the rate, it resulted in a less erroneous RPR with respect to cleavage site selection. These data support and extend our understanding of the coupling between the distal interaction between the S-domain and events at the active site. Our findings will also be discussed with respect to the structure of RPR derived from different organisms.

Cleavage mediated by the P15 domain of bacterial RNase P RNA.

Independently folded domains in RNAs frequently adopt identical tertiary structures regardless of whether they are in isolation or are part of larger RNA molecules. This is exemplified by the P15 domain in the RNA subunit (RPR) of the universally conserved endoribonuclease P, which is involved in the processing of tRNA precursors. One of its domains, encompassing the P15 loop, binds to the 3'-end of tRNA precursors resulting in the formation of the RCCA-RNase P RNA interaction (interacting residues underlined) in the bacterial RPR-substrate complex. The function of this interaction was hypothesized to anchor the substrate, expose the cleavage site and result in re-coordination of Mg(2+) at the cleavage site. Here we show that small model-RNA molecules (~30 nt) carrying the P15-loop mediated cleavage at the canonical RNase P cleavage site with significantly reduced rates compared to cleavage with full-size RPR. These data provide further experimental evidence for our model that the P15 domain contributes to both substrate binding and catalysis. Our data raises intriguing evolutionary possibilities for 'RNA-mediated' cleavage of RNA.

Protein folding activity of ribosomal RNA is a selective target of two unrelated antiprion drugs.

BACKGROUND: 6-Aminophenanthridine (6AP) and Guanabenz (GA, a drug currently in use for the treatment of hypertension) were isolated as antiprion drugs using a yeast-based assay. These structurally unrelated molecules are also active against mammalian prion in several cell-based assays and in vivo in a mouse model for prion-based diseases. METHODOLOGY/PRINCIPAL FINDINGS: Here we report the identification of cellular targets of these drugs. Using affinity chromatography matrices for both drugs, we demonstrate an RNA-dependent interaction of 6AP and GA with the ribosome. These specific interactions have no effect on the peptidyl transferase activity of the ribosome or on global translation. In contrast, 6AP and GA specifically inhibit the ribosomal RNA-mediated protein folding activity of the ribosome. CONCLUSION/SIGNIFICANCE: 6AP and GA are therefore the first compounds to selectively inhibit the protein folding activity of the ribosome. They thus constitute precious tools to study the yet largely unexplored biological role of this protein folding activity.

Evidence for induced fit in bacterial RNase P RNA-mediated cleavage.

RNase P with its catalytic RNA subunit is involved in the processing of a number of RNA precursors with different structures. However, precursor tRNAs are the most abundant substrates for RNase P. Available data suggest that a tRNA is folded into its characteristic structure already at the precursor state and that RNase P recognizes this structure. The tRNA D-/T-loop domain (TSL-region) is suggested to interact with the specificity domain of RNase P RNA while residues in the catalytic domain interact with the cleavage site. Here, we have studied the consequences of a productive interaction between the TSL-region and its binding site (TBS) in the specificity domain using tRNA precursors and various hairpin-loop model substrates. The different substrates were analyzed with respect to cleavage site recognition, ground-state binding, cleavage as a function of the concentration of Mg(2+) and the rate of cleavage under conditions where chemistry is suggested to be rate limiting using wild-type Escherichia coli RNase P RNA, M1 RNA, and M1 RNA variants with structural changes in the TBS-region. On the basis of our data, we conclude that a productive TSL/TBS interaction results in a conformational change in the M1 RNA substrate complex that has an effect on catalysis. Moreover, it is likely that this conformational change comprises positioning of chemical groups (and Mg(2+)) at and in the vicinity of the cleavage site. Hence, our findings are consistent with an induced-fit mechanism in RNase P RNA-mediated cleavage.

Eukaryotic RNase P RNA mediates cleavage in the absence of protein.

The universally conserved ribonucleoprotein RNase P is involved in the processing of tRNA precursor transcripts. RNase P consists of one RNA and, depending on its origin, a variable number of protein subunits. Catalytic activity of the RNA moiety so far has been demonstrated only for bacterial and some archaeal RNase P RNAs but not for their eukaryotic counterparts. Here, we show that RNase P RNAs from humans and the lower eukaryote Giardia lamblia mediate cleavage of four tRNA precursors and a model RNA hairpin loop substrate in the absence of protein. Compared with bacterial RNase P RNA, the rate of cleavage (k(obs)) was five to six orders of magnitude lower, whereas the affinity for the substrate (appK(d)) was reduced approximately 20- to 50-fold. We conclude that the RNA-based catalytic activity of RNase P has been preserved during evolution. This finding opens previously undescribed ways to study the role of the different proteins subunits of eukaryotic RNase P.

The exocyclic amine at the RNase P cleavage site contributes to substrate binding and catalysis.

Most tRNAs carry a G at their 5' termini, i.e. at position +1. This position corresponds to the position immediately downstream of the site of cleavage in tRNA precursors. Here we studied RNase P RNA-mediated cleavage of substrates carrying substitutions/modifications at position +1 in the absence of the RNase P protein, C5, to investigate the role of G at the RNase P cleavage site. We present data suggesting that the exocyclic amine (2NH2) of G+1 contributes to cleavage site recognition, ground state binding and catalysis by affecting the rate of cleavage. This is in contrast to O6, N7 and 2'OH that are suggested to affect ground state binding and rate of cleavage to significantly lesser extent. We also provide evidence that the effects caused by the absence of 2NH2 at position +1 influenced the charge distribution and conceivably Mg2+ binding at the RNase P cleavage site. These findings are consistent with models where the 2NH2 at the cleavage site (when present) interacts with RNase P RNA and/or influences the positioning of Mg2+ in the vicinity of the cleavage site. Moreover, our data suggest that the presence of the base at +1 is not essential for cleavage but its presence suppresses miscleavage and dramatically increases the rate of cleavage. Together our findings provide reasons why most tRNAs carry a guanosine at their 5' end.

The naturally trans-acting ribozyme RNase P RNA has leadzyme properties.

Divalent metal ions promote hydrolysis of RNA backbones generating 5'OH and 2';3'P as cleavage products. In these reactions, the neighboring 2'OH act as the nucleophile. RNA catalyzed reactions also require divalent metal ions and a number of different metal ions function in RNA mediated cleavage of RNA. In one case, the LZV leadzyme, it was shown that this catalytic RNA requires lead for catalysis. So far, none of the naturally isolated ribozymes have been demonstrated to use lead to activate the nucleophile. Here we provide evidence that RNase P RNA, a naturally trans-acting ribozyme, has leadzyme properties. But, in contrast to LZV RNA, RNase P RNA mediated cleavage promoted by Pb2+ results in 5' phosphate and 3'OH as cleavage products. Based on our findings, we infer that Pb2+ activates H2O to act as the nucleophile and we identified residues both in the substrate and RNase P RNA that most likely influenced the positioning of Pb2+ at the cleavage site. Our data suggest that Pb2+ can promote cleavage of RNA by activating either an inner sphere H2O or a neighboring 2'OH to act as nucleophile.

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(Tyr)Su3) 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(Tyr)Su3. 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.

Cross talk between the +73/294 interaction and the cleavage site in RNase P RNA mediated cleavage.

To monitor functionally important metal ions and possible cross talk in RNase P RNA mediated cleavage we studied cleavage of substrates, where the 2'OH at the RNase P cleavage site (at -1) and/or at position +73 had been replaced with a 2' amino group (or 2'H). Our data showed that the presence of 2' modifications at these positions affected cleavage site recognition, ground state binding of substrate and/or rate of cleavage. Cleavage of 2' amino substituted substrates at different pH showed that substitution of Mg2+ by Mn2+ (or Ca2+), identity of residues at and near the cleavage site, and addition of C5 protein influenced the frequency of miscleavage at -1 (cleavage at the correct site is referred to as +1). From this we infer that these findings point at effects mediated by protonation/deprotonation of the 2' amino group, i.e. an altered charge distribution, at the site of cleavage. Moreover, our data suggested that the structural architecture of the interaction between the 3' end of the substrate and RNase P RNA influence the charge distribution at the cleavage site as well as the rate of cleavage under conditions where the chemistry is suggested to be rate limiting. Thus, these data provide evidence for cross talk between the +73/294 interaction and the cleavage site in RNase P RNA mediated cleavage. We discuss the role metal ions might play in this cross talk and the likelihood that at least one functionally important metal ion is positioned in the vicinity of, and use the 2'OH at the cleavage site as an inner or outer sphere ligand.