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.     

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.     

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.     

Nuclear pre-mRNA decapping and 5' degradation in yeast require the Lsm2-8p complex

Previous analyses have identified related cytoplasmic Lsm1-7p and nuclear Lsm2-8p complexes. Here we report that mature heat shock and MET mRNAs that are trapped in the nucleus due to a block in mRNA export were strongly stabilized in strains lacking Lsm6p or the nucleus-specific Lsm8p protein but not by the absence of the cytoplasmic Lsm1p. These nucleus-restricted mRNAs remain polyadenylated until their degradation, indicating that nuclear mRNA degradation does not involve the incremental deadenylation that is a key feature of cytoplasmic turnover. Lsm8p can be UV cross-linked to nuclear poly(A)(+) RNA, indicating that an Lsm2-8p complex interacts directly with nucleus-restricted mRNA. Analysis of pre-mRNAs that contain intronic snoRNAs indicates that their 5' degradation is specifically inhibited in strains lacking any of the Lsm2-8p proteins but Lsm1p. Nucleus-restricted mRNAs and pre-mRNA degradation intermediates that accumulate in lsm mutants remain 5' capped. We conclude that the Lsm2-8p complex normally targets nuclear RNA substrates for decapping.     

Precursors to the U3 small nucleolar RNA lack small nucleolar RNP proteins but are stabilized by La binding

Almost all small eukaryotic RNAs are processed from transiently stabilized 3'-extended forms. A key question is how and why such intermediates are stabilized and how they can then be processed to the mature RNA. Here we report that yeast U3 is also processed from a 3'-extended precursor. The major 3'-extended forms of U3 (U3-3'I and -II) lack the cap trimethylation present in mature U3 and are not associated with small nucleolar RNP (snoRNP) proteins that bind mature U3, i.e., Nop1p, Nop56p, and Nop58p. Depletion of Nop58p leads to the loss of mature U3 but increases the level of U3-3'I and -II, indicating a requirement for the snoRNP proteins for final maturation. Pre-U3 is cleaved by the endonuclease Rnt1p, but U3-3'I and -II do not extend to the Rnt1p cleavage sites. Rather, they terminate at poly(U) tracts, suggesting that they might be bound by Lhp1p (the yeast homologue of La). Immunoprecipitation of Lhp1p fused to Staphylococcus aureus protein A resulted in coprecipitation of both U3-3'I and -II. Deletion of LHP1, which is nonessential, led to the loss of U3-3'I and -II. We conclude that pre-U3 is cleaved by Rnt1p, followed by exonuclease digestion to U3-3'I and -II. These species are stabilized against continued degradation by binding of Lhp1p. Displacement of Lhp1p by binding of the snoRNP proteins allows final maturation, which involves the exosome complex of 3'-->5' exonucleases.     

Yeast Rnt1p is required for cleavage of the pre-ribosomal RNA in the 3' ETS but not the 5' ETS.

We have reexamined the role of yeast RNase III (Rnt1p) in ribosome synthesis. Analysis of pre-rRNA processing in a strain carrying a complete deletion of the RNT1 gene demonstrated that the absence of Rnt1p does not block cleavage at site A0 in the 5' external transcribed spacers (ETS), although the early pre-rRNA cleavages at sites A0, A1, and A2 are kinetically delayed. In contrast, cleavage in the 3' ETS is completely inhibited in the absence of Rnt1p, leading to the synthesis of a reduced level of a 3' extended form of the 25S rRNA. The 3' extended forms of the pre-rRNAs are consistent with the major termination at site T2 (+210). We conclude that Rnt1p is required for cleavage in the 3' ETS but not for cleavage at site A0. The sites of in vivo cleavage in the 3' ETS were mapped by primer extension. Two sites of Rnt1p-dependent cleavage were identified that lie on opposite sides of a predicted stem loop structure, at +14 and +49. These are in good agreement with the consensus Rnt1p cleavage site. Processing of the 3' end of the mature 25S rRNA sequence in wild-type cells was found to occur concomitantly with processing of the 5' end of the 5.8S rRNA, supporting previous proposals that processing in ITS1 and the 3' ETS is coupled.     

Interaction between Escherichia coli RNase P RNA and the discriminator base results in slow product release.

We suggested previously that a purine at the discriminator base position in a tRNA precursor interacts with the well-conserved U294 in M1 RNA, the catalytic subunit of Escherichia coli RNase P. Here we investigated this interaction and its influence on the kinetics of cleavage as well as on cleavage site selection. The discriminator base in precursors to tRNA(Tyr)Su3 and tRNA(Phe) was changed from A to C and cleavage kinetics were studied by wild-type M1 RNA and a mutant M1 RNA carrying the compensatory substitution of a U to a G at position 294 in M1 RNA. Our data suggest that the discriminator base interacts with the residue at position 294 in M1 RNA. Although product release is a rate-limiting step both in the absence and in the presence of this interaction, its presence results in a significant reduction in the rate of product release. In addition, we studied cleavage site selection on various tRNA(His) precursor derivatives. These precursors carry a C at the discriminator base position. The results showed that the mutant M1 RNA harboring a G at position 294 miscleaved a wild-type tRNA(His) precursor and a tRNA(His) precursor carrying an inosine at the cleavage site. The combined data suggest a functional interaction between the discriminator base and the well-conserved U294 in M1 RNA. This interaction is suggested to play an important role in determining the rate of product release during multiple turnover cleavage of tRNA precursors by M1 RNA as well as in cleavage site selection.