Partial characterization of an RNA component that copurifies with Saccharomyces cerevisiae RNase P.

Saccharomyces cerevisiae cellular RNase P is composed of both protein and RNA components that are essential for activity. The isolated holoenzyme contains a highly structured RNA of 369 nucleotides that has extensive sequence similarities to the 286-nucleotide RNA associated with Schizosaccharomyces pombe RNase P but bears little resemblance to the analogous RNA sequences in procaryotes or S. cerevisiae mitochondria. Even so, the predicted secondary structure of S. cerevisiae RNA is strikingly similar to the bacterial phylogenetic consensus rather than to previously predicted structures of other eucaryotic RNase P RNAs.     

micF RNA is a substrate for RNase E

Abstract The speA gene encoding streptococcal erythrogenic toxin A (SPE A) from Streptococcus pyogenes bacteriophage T12 was overexpressed in Escherichia coli under the control of the T7 promoter. Since most of the expressed protein was found in the periplasmic space, an osmotic shock extraction with 0.5 M sucrose resulted in a highly enriched preparation of SPE A. An additional two-step purification employing high pressure liquid chromatography resulted in a purified SPE A protein.     

Hypervariable noncoding sequences in Saccharomyces cerevisiae

Compared to protein-coding sequences, the evolution of noncoding sequences and the selective constraints placed on these sequences is not well characterized. To compare the evolution of coding and noncoding sequences, we have conducted a survey for DNA polymorphism at five randomly chosen loci among a diverse collection of 81 strains of Saccharomyces cerevisiae. Average rates of both polymorphism and divergence are 40% lower at noncoding sites and 90% lower at nonsynonymous sites in comparison to synonymous sites. Although noncoding and coding sequences show substantial variability in ratios of polymorphism to divergence, two of the loci, MLS1 and PDR10, show a higher rate of polymorphism at noncoding compared to synonymous sites. The high rate of polymorphism is not accompanied by a high rate of divergence and is limited to a few small regions. These hypervariable regions include sites with three segregating bases at a single site and adjacent polymorphic sites. We show that this clustering of polymorphic sites is significantly greater than one would expect on the basis of the spacing between polymorphic fourfold degenerate sites. Although hypervariable noncoding sequences could result from selection on regulatory mutations, they could also result from transient mutational hotspots.     

Transfer RNA is a substrate for RNase D in vivo

RNase D is a 3'-exonuclease whose in vitro specificity has suggested a role in tRNA processing. However, since mutant Escherichia coli strains devoid of RNase D display a normal phenotype, it has not been possible to ascertain the enzyme's function or even to determine which RNA is its substrate in vivo. Here we show that transformation of strains devoid of tRNA nucleotidyltransferase with a multicopy plasmid carrying the rnd+ gene leads to extremely slow growth due to elevated levels of RNase D activity. Analysis of such a slow-growing strain revealed that less tRNA is present in the cell and that the tRNA that could be recovered is substantially damaged. These studies demonstrate that RNase D can act at the 3' terminus of tRNA in vivo, and they support the conclusion that RNase D participates in tRNA metabolism.     

Evidence for helical unwinding of an RNA substrate by the RNA enzyme RNase P: use of an interstrand disulfide crosslink in substrate

To gain an understanding of structural changes induced in substrates by Escherichia coli ribonuclease P (RNase P), we have incorporated an interstrand disulfide crosslink proximal to the cleavage site in a model substrate. RNase P is able to process the reduced, non-crosslinked form of this substrate as well as a substrate in which the free thiol molecules have been alkylated with iodoacetamide. However, the oxidized, crosslinked form is cleaved at a significantly lower rate. Therefore, helical unwinding of the analog of the aminoacyl stem of the substrate near its site of cleavage may be necessary for efficient processing by E. coli RNase P.     

RNase P RNA mediated cleavage: substrate recognition and catalysis

The universally conserved endoribonuclease P consists of one RNA subunit and, depending on its origin, a variable number of protein subunits. RNase P is involved in the processing of a large variety of substrates in the cell, the preferred substrate being tRNA precursors. Cleavage activity does not require the presence of the protein subunit(s) in vitro. This is true for both prokaryotic and eukaryotic RNase P RNA suggesting that the RNA based catalytic activity has been preserved during evolution. Progress has been made in our understanding of the contribution of residues and chemical groups both in the substrate as well as in RNase P RNA to substrate binding and catalysis. Moreover, we have access to two crystal structures of bacterial RNase P RNA but we still lack the structure of RNase P RNA in complex with its substrate and/or the protein subunit. Nevertheless, these recent advancements put us in a new position to study the way and nature of interactions between in particular RNase P RNA and its substrate. In this review I will discuss various aspects of the RNA component of RNase P with an emphasis on our current understanding of the interaction between RNase P RNA and its substrate.     

Mutational analysis of Saccharomyces cerevisiae nuclear RNase P: randomization of universally conserved positions in the RNA subunit.

Three regions in the Saccharomyces cerevisiae RNase P RNA have been identified, at positions Sce 87-94, Sce 309-316, and Sce 339-349, that contain nucleotides that are invariant in identity and position among all the known RNase P RNAs. To study the importance of these conserved RPR1 RNA regions in enzyme function, three independent mutational libraries were created in which the positions of invariant nucleotides were randomized simultaneously. Screening in vivo was used to identify viable RPR1 variants when reconstituted into holoenzyme in cells. Despite the universal evolutionary conservation, most of these positions tolerate certain sequence changes without severely affecting function. Most changes, however, produced subtle defects in cell growth and RNase P function, supporting the importance of these conserved regions. Isolation of conditional growth mutants allowed the characterization of the effects of mutations on cell growth, RPR1 RNA maturation, and activity of the holoenzyme in vitro. Kinetic analysis showed that viable variants were usually more defective in catalytic rate (Kcat) than in substrate recognition (Km).     

The Saccharomyces cerevisiae RNase mitochondrial RNA processing is critical for cell cycle progression at the end of mitosis

We have identified a cell cycle delay in Saccharomyces cerevisiae RNase MRP mutants. Mutants delay with large budded cells, dumbbell-shaped nuclei, and extended spindles characteristic of "exit from mitosis" mutants. In accord with this, a RNase MRP mutation can be suppressed by overexpressing the polo-like kinase CDC5 or by deleting the B-type cyclin CLB1, without restoring the MRP-dependent rRNA-processing step. In addition, we identified a series of genetic interactions between RNase MRP mutations and mutations in CDC5, CDC14, CDC15, CLB2, and CLB5. As in most "exit from mitosis" mutants, levels of the Clb2 cyclin were increased. The buildup of Clb2 protein is not the result of a defect in the release of the Cdc14 phosphatase from the nucleolus, but rather the result of an increase in CLB2 mRNA levels. These results indicate a clear role of RNase MRP in cell cycle progression at the end of mitosis. Conservation of this function in humans may explain many of the pleiotropic phenotypes of cartilage hair hypoplasia.     

Interactions between subunits of Saccharomyces cerevisiae RNase MRP support a conserved eukaryotic RNase P/MRP architecture

Ribonuclease MRP is an endonuclease, related to RNase P, which functions in eukaryotic pre-rRNA processing. In Saccharomyces cerevisiae, RNase MRP comprises an RNA subunit and ten proteins. To improve our understanding of subunit roles and enzyme architecture, we have examined protein-protein and protein–RNA interactions in vitro, complementing existing yeast two-hybrid data. In total, 31 direct protein–protein interactions were identified, each protein interacting with at least three others. Furthermore, seven proteins self-interact, four strongly, pointing to subunit multiplicity in the holoenzyme. Six protein subunits interact directly with MRP RNA and four with pre-rRNA. A comparative analysis with existing data for the yeast and human RNase P/MRP systems enables confident identification of Pop1p, Pop4p and Rpp1p as subunits that lie at the enzyme core, with probable addition of Pop5p and Pop3p. Rmp1p is confirmed as an integral subunit, presumably associating preferentially with RNase MRP, rather than RNase P, via interactions with Snm1p and MRP RNA. Snm1p and Rmp1p may act together to assist enzyme specificity, though roles in substrate binding are also indicated for Pop4p and Pop6p. The results provide further evidence of a conserved eukaryotic RNase P/MRP architecture and provide a strong basis for studies of enzyme assembly and subunit function.     

The yeast,Saccharomyces cerevisiae,RNase P/MRP ribonucleoprotein endoribonuclease family

Ribonuclease P (RNase P) is a ribonucleoprotein responsible for the endonucleolytic cleavage of the 5-termini of tRNAs. Ribonuclease MRP (RNase MRP) is a ribonucleoprotein that has the ability to cleave both mitochondrial RNA primers presumed to be involved in mitochondrial DNA replication and rRNA precursors for the production of mature rRNAs. Several lines of evidence suggest that these two ribonucleoproteins are related to each other, both functionally and evolutionarily. Both of these enzymes have activity in the nucleus and mitochondria. Each cleave their RNA substrates in a divalent cation dependent manner to generate 5-phosphate and 3-OH termini. In addition, the RNA subunits of both complexes can be folded into a similar secondary structure. Each can be immunoprecipitated from mammalian cells with Th antibodies. In yeast, both have been found to share at least one common protein. This review will discuss some of the recent advances in our understanding of the structure, function and evolutionary relationship of these two enzymes in the yeast,Saccharomyces cerevisiae.Abbreviations LRI long range interaction - mt mitochondrial - MRP mitochondrial RNA processing - NME nuclear mitochondrial endonuclease - POP processing of precursor - RNase ribonuclease - SNM suppressor of NME - RNP ribonucleoprotein     

Base pairing between Escherichia coli RNase P RNA and its substrate.

Base pairing between the substrate and the ribozyme has previously been shown to be essential for catalytic activity of most ribozymes, but not for RNase P RNA. By using compensatory mutations we have demonstrated the importance of Watson-Crick complementarity between two well-conserved residues in Escherichia coli RNase P RNA (M1 RNA), G292 and G293, and two residues in the substrate, +74C and +75C (the first and second C residues in CCA). We suggest that these nucleotides base pair (G292/+75C and G293/+74C) in the ribozyme-substrate complex and as a consequence the amino acid acceptor stem of the precursor is partly unfolded. Thus, a function of M1 RNA is to anchor the substrate through this base pairing, thereby exposing the cleavage site such that cleavage is accomplished at the correct position. Our data also suggest possible base pairing between U294 in M1 RNA and the discriminator base at position +73 of the precursor. Our findings are also discussed in terms of evolution.     

A novel family of RNA tetraloop structure forms the recognition site for Saccharomyces cerevisiae RNase III.

RNases III are a family of double-stranded RNA (dsRNA) endoribonucleases involved in the processing and decay of a large number of cellular RNAs as well as in RNA interference. The dsRNA substrates of Saccharomyces cerevisiae RNase III (Rnt1p) are capped by tetraloops with the consensus sequence AGNN, which act as the primary docking site for the RNase. We have solved the solution structures of two RNA hairpins capped by AGNN tetraloops, AGAA and AGUU, using NMR spectroscopy. Both tetraloops have the same overall structure, in which the backbone turn occurs on the 3' side of the syn G residue in the loop, with the first A and G in a 5' stack and the last two residues in a 3' stack. A non-bridging phosphate oxygen and the universal G which are essential for Rnt1p binding are strongly exposed. The compared biochemical and structural analysis of various tetraloop sequences defines a novel family of RNA tetraloop fold with the consensus (U/A)GNN and implicates this conserved structure as the primary determinant for specific recognition of Rnt1p substrates.