A gene required for RNase P activity in Candida (Torulopsis) glabrata mitochondria codes for a 227-nucleotide RNA with homology to bacterial RNase P RNA.

We have mapped a gene in the mitochondrial DNA of Candida (Torulopsis) glabrata and shown that it is required for 5' end maturation of mitochondrial tRNAs. It is located between the tRNAfMet and tRNAPro genes, the same tRNA genes that flank the mitochondrial RNase P RNA gene in the yeast Saccharomyces cerevisiae. The gene is extremely AT rich and codes for AU-rich RNAs that display some sequence homology with the mitochondrial RNase P RNA from S. cerevisiae, including two regions of striking sequence homology between the mitochondrial RNAs and the bacterial RNase P RNAs. RNase P activity that is sensitive to micrococcal nuclease has been detected in mitochondrial extracts of C. glabrata. An RNA of 227 nucleotides that is one of the RNAs encoded by the gene that we mapped cofractionated with this mitochondrial RNase P activity on glycerol gradients. The nuclease sensitivity of the activity, the cofractionation of the RNA with activity, and the homology of the RNA with known RNase P RNAs lead us to propose that the 227-nucleotide RNA is the RNA subunit of the C. glabrata mitochondrial RNase P enzyme.     

A noncoding RNA in Saccharomyces cerevisiae is an RNase P substrate

Ribonuclease P (RNase P) is involved in regulation of noncoding RNA (ncRNA) expression in Saccharomyces cerevisiae. A hidden-in-reading-frame antisense-1 (HRA1) RNA in S. cerevisiae, which belongs to a class of ncRNAs located in the antisense strand to verified protein coding regions, was cloned for further use in RNase P assays. Escherichia coli RNase P assays in vitro of HRA1 RNA show two cleavage sites, one major and one minor in terms of rates. The same result was observed with a partially purified S. cerevisiae RNase P activity, both at 30 degrees C and 37 degrees C. These latter cells are normally grown at 30 degrees C. Predictions of the secondary structure of HRA1 RNA in silico show the cleavage sites are canonical RNase P recognition sites. A relatively small amount of endogenous HRA1 RNA was identified by RT-PCR in yeast cells. The endogenous HRA1 RNA is increased in amount in strains that are deficient in RNase P activity. A deletion of 10 nucleotides in the HRA1 gene that does not overlap with the gene coding for a protein (DRS2) in the sense strand shows no defective growth in galactose or glucose. These data indicate that HRA1 RNA is a substrate for RNase P and does not appear as a direct consequence of separate regulatory effects of the enzyme on ncRNAs.     

Binding and cleavage of unstructured RNA by nuclear RNase P

Ribonuclease P (RNase P) is an essential endoribonuclease for which the best-characterized function is processing the 5' leader of pre-tRNAs. Compared to bacterial RNase P, which contains a single small protein subunit and a large catalytic RNA subunit, eukaryotic nuclear RNase P is more complex, containing nine proteins and an RNA subunit in Saccharomyces cerevisiae. Consistent with this, nuclear RNase P has been shown to possess unique RNA binding capabilities. To understand the unique molecular recognition of nuclear RNase P, the interaction of S. cerevisiae RNase P with single-stranded RNA was characterized. Unstructured, single-stranded RNA inhibits RNase P in a size-dependent manner, suggesting that multiple interactions are required for high affinity binding. Mixed-sequence RNAs from protein-coding regions also bind strongly to the RNase P holoenzyme. However, in contrast to poly(U) homopolymer RNA that is not cleaved, a variety of mixed-sequence RNAs have multiple preferential cleavage sites that do not correspond to identifiable consensus structures or sequences. In addition, pre-tRNA(Tyr), poly(U)(50) RNA, and mixed-sequence RNA cross-link with purified RNase P in the RNA subunit Rpr1 near the active site in "Conserved Region I," although the exact positions vary. Additional contacts between poly(U)(50) and the RNase P proteins Rpr2p and Pop4p were identified. We conclude that unstructured RNAs interact with multiple protein and RNA contacts near the RNase P RNA active site, but that cleavage depends on the nature of interaction with the active site.     

Archaeal RNase P has multiple protein subunits homologous to eukaryotic nuclear RNase P proteins

Although archaeal RNase P RNAs are similar in both sequence and structure to those of Bacteria rather than eukaryotes, and heterologous reconstitution between the Bacillus subtilis RNase P protein and some archaeal RNase P RNAs has been demonstrated, no archaeal protein sequences with similarity to any known bacterial RNase P protein subunit have been identified, and the density of Methanothermobacter thermoautotrophicus RNase P in Cs2SO4 (1.42 g/mL) is inconsistent with a single small bacterial-like protein subunit. Four hypothetical open reading frames (MTH11, MTH687, MTH688, and MTH1618) were identified in the genome of M. thermoautotrophicus that have sequence similarity to four of the nine Saccharomyces cerevisiae RNase P protein subunits: Pop4p, Pop5p, Rpp1p, and Rpr2p, respectively. Polyclonal antisera generated to recombinant Mth11p, Mth687p, Mth688p, and Mth1618p each recognized a protein of the predicted molecular weight in western blots of partially purified M. thermoautotrophicus RNase P, and immunoprecipitated RNase P activity from the same partially purified preparation. RNase P in Archaea is therefore composed of an RNA subunit similar to bacterial RNase P RNA and multiple protein subunits similar to those in the eukaryotic nucleus.     

Dramatic size variation of yeast mitochondrial RNAs suggests that RNase P RNAs can be quite small

The gene coding for the AU-rich RNA required for mitochondrial RNase P activity in Saccharomyces cerevisiae codes for a 490-base RNA while that in Candida glabrata codes for a 227-base RNA. We have detected a 140-nucleotide RNA coded by the mitochondrial DNA from Saccharomycopsis fibuligera by hybridization with an oligonucleotide complementary to a conserved sequence found in mitochondrial and prokaryotic RNase P RNAs. DNA sequence analysis of the mitochondrial DNA from the region coding for this RNA revealed a second conserved sequence block characteristic of RNase P RNA genes and the presence of a downstream tRNA(Pro) gene. Like previously characterized mitochondrial RNase P RNAs, this small RNA is extremely AU-rich. The discovery of this 140-base RNA suggests that naturally occurring RNase P RNAs may be quite small.     

Expression of double-stranded-RNA-specific RNase III of Escherichia coli is lethal to Saccharomyces cerevisiae.

The gene for the double-stranded RNA (dsRNA)-specific RNase III of Escherichia coli was expressed in Saccharomyces cerevisiae to examine the effects of this RNase activity on the yeast. Induction of the RNase III gene was found to cause abnormal cell morphology and cell death. Whereas double-stranded killer RNA is degraded by RNase III in vitro, killer RNA, rRNA, and some mRNAs were found to be stable in vivo after induction of RNase III. Variants selected for resistance to RNase III induction were isolated at a frequency of 4 X 10(-5) to 5 X 10(-5). Ten percent of these resistant strains had concomitantly lost the capacity to produce killer toxin and M dsRNA while retaining L dsRNA. The genetic alteration leading to RNase resistance was localized within the RNase III-coding region but not in the yeast chromosome. These results indicate that S. cerevisiae contains some essential RNA which is susceptible to E. coli RNase III.     

Structural organizations of yeast RNase P and RNase MRP holoenzymes as revealed by UV-crosslinking studies of RNA-protein interactions

Eukaryotic ribonuclease (RNase) P and RNase MRP are closely related ribonucleoprotein complexes involved in the metabolism of various RNA molecules including tRNA, rRNA, and some mRNAs. While evolutionarily related to bacterial RNase P, eukaryotic enzymes of the RNase P/MRP family are much more complex. Saccharomyces cerevisiae RNase P consists of a catalytic RNA component and nine essential proteins; yeast RNase MRP has an RNA component resembling that in RNase P and 10 essential proteins, most of which are shared with RNase P. The structural organizations of eukaryotic RNases P/MRP are not clear. Here we present the results of RNA-protein UV crosslinking studies performed on RNase P and RNase MRP holoenzymes isolated from yeast. The results indicate locations of specific protein-binding sites in the RNA components of RNase P and RNase MRP and shed light on the structural organizations of these large ribonucleoprotein complexes.     

Footprinting analysis demonstrates extensive similarity between eukaryotic RNase P and RNase MRP holoenzymes

Eukaryotic ribonuclease (RNase) P and RNase MRP are evolutionary related RNA-based enzymes involved in metabolism of various RNA molecules, including tRNA and rRNA. In contrast to the closely related eubacterial RNase P, which is comprised of an RNA component and a single small protein, these enzymes contain multiple protein components. Here we report the results of footprinting studies performed on purified Saccharomyces cerevisiae RNase MRP and RNase P holoenzymes. The results identify regions of the RNA components affected by the protein moiety, suggest a role of the proteins in stabilization of the RNA fold, and point to substantial similarities between the two evolutionary related RNA-based enzymes.     

Specific binding of a Pop6/Pop7 heterodimer to the P3 stem of the yeast RNase MRP and RNase P RNAs

Pop6 and Pop7 are protein subunits of Saccharomyces cerevisiae RNase MRP and RNase P. Here we show that bacterially expressed Pop6 and Pop7 form a soluble heterodimer that binds the RNA components of both RNase MRP and RNase P. Footprint analysis of the interaction between the Pop6/7 heterodimer and the RNase MRP RNA, combined with gel mobility assays, demonstrates that the Pop6/7 complex binds to a conserved region of the P3 domain. Binding of these proteins to the MRP RNA leads to local rearrangement in the structure of the P3 loop and suggests that direct interaction of the Pop6/7 complex with the P3 domain of the RNA components of RNases MRP and P may mediate binding of other protein components. These results suggest a role for a key element in the RNase MRP and RNase P RNAs in protein binding, and demonstrate the feasibility of directly studying RNA-protein interactions in the eukaryotic RNases MRP and P complexes.     

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.     

Saccharomyces cerevisiae RNase H(35) functions in RNA primer removal during lagging-strand DNA synthesis, most efficiently in cooperation with Rad27 nuclease

Correct removal of RNA primers of Okazaki fragments during lagging-strand DNA synthesis is a critical process for the maintenance of genome integrity. Disturbance of this process has severe mutagenic consequences and could contribute to the development of cancer. The role of the mammalian nucleases RNase HI and FEN-1 in RNA primer removal has been substantiated by several studies. Recently, RNase H(35), the Saccharomyces cerevisiae homologue of mammalian RNase HI, was identified and its possible role in DNA replication was proposed (P. Frank, C. Braunshofer-Reiter, and U. Wintersberger, FEBS Lett. 421:23-26, 1998). This led to the possibility of moving to the genetically powerful yeast system for studying the homologues of RNase HI and FEN-1, i.e., RNase H(35) and Rad27p, respectively. In this study, we have biochemically defined the substrate specificities and the cooperative as well as independent cleavage mechanisms of S. cerevisiae RNase H(35) and Rad27 nuclease by using Okazaki fragment model substrates. We have also determined the additive and compensatory pathological effects of gene deletion and overexpression of these two enzymes. Furthermore, the mutagenic consequences of the nuclease deficiencies have been analyzed. Based on our findings, we suggest that three alternative RNA primer removal pathways of different efficiencies involve RNase H(35) and Rad27 nucleases in yeast.     

Identification and assignment of base pairs in three helical stems of Torulopsis utilis ribosomal 5S RNA and its RNase T1 and RNase T2 cleaved fragments via 500-MHz proton homonuclear overhauser enhancements

Imino proton resonances in the downfield region (10-14 ppm) of the 500-MHz 1H NMR spectrum of Torulopsis utilis 5S RNA are identified (A X U, G X C, or G X U) and assigned to base pairs in helices I, IV, and V via analysis of homonuclear Overhauser enhancements (NOE) from intact T. utilis 5S RNA, its RNase T1 and RNase T2 digested fragments, and a second yeast (Saccharomyces cerevisiae) 5S RNA whose nucleotide sequence differs at only six residues from that of T. utilis 5S RNA. The near-identical chemical shifts and NOE behavior of most of the common peaks from these four RNAs strongly suggest that helices I, IV, and V retain the same conformation after RNase digestion and that both T. utilis and S. cerevisiae 5S RNAs share a common secondary and tertiary structure. Of the four G X U base pairs identified in the intact 5S RNA, two are assigned to the terminal stem (helix I) and the other two to helices IV and V. Seven of the nine base pairs of the terminal stem have been assigned. Our experimental demonstration of a G X U base pair in helix V supports the 5S RNA secondary structural model of Luehrsen and Fox [Luehrsen, K. R., & Fox, G.E. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 2150-2154]. Finally, the base-pair proton peak assigned to the terminal G X U in helix V of the RNase T2 cleaved fragment is shifted downfield from that in the intact 5S RNA, suggesting that helices I and V may be coaxial in intact T. utilis 5S RNA.     

A novel protein shared by RNase MRP and RNase P.

We have isolated suppressors of the temperature-sensitive rRNA processing mutation rrp2-2 in Saccharomyces cerevisiae. A class of extragenic suppressors was mapped to the YBR257w reading frame in the right arm of Chromosome II. Characterization of this gene, renamed POP4, shows that the gene product is necessary both for normal 5.8S rRNA processing and for processing of tRNA. Immunoprecipitation studies indicate that Pop4p is associated with both RNase MRP and RNase P. The protein is also required for accumulation of RNA from each of the two ribonucleoprotein particles.     

Phylogenetic analysis of the structure of RNase MRP RNA in yeasts

RNase MRP is a ribonucleoprotein enzyme involved in processing precursor rRNA in eukaryotes. To facilitate our structure-function analysis of RNase MRP from Saccharomyces cerevisiae, we have determined the likely secondary structure of the RNA component by a phylogenetic approach in which we sequenced all or part of the RNase MRP RNAs from 17 additional species of the Saccharomycetaceae family. The structure deduced from these sequences contains the helices previously suggested to be common to the RNA subunit of RNase MRP and the related RNA subunit of RNase P, an enzyme cleaving tRNA precursors. However, outside this common region, the structure of RNase MRP RNA determined here differs from a previously proposed universal structure for RNase MRPs. Chemical and enzymatic structure probing analyses were consistent with our revised secondary structure. Comparison of all known RNase MRP RNA sequences revealed three regions with highly conserved nucleotides. Two of these regions are part of a helix implicated in RNA catalysis in RNase P, suggesting that RNase MRP may cleave rRNA using a similar catalytic mechanism.     

A conserved element in the yeast RNase MRP RNA subunit can participate in a long-range base-pairing interaction

RNase MRP is a ribonucleoprotein endoribonuclease involved in eukaryotic pre-rRNA processing. The enzyme possesses a putatively catalytic RNA subunit, structurally related to that of RNase P. A thorough structure analysis of Saccharomyces cerevisiae MRP RNA, entailing enzymatic and chemical probing, mutagenesis and thermal melting, identifies a previously unrecognised stem that occupies a position equivalent to the P7 stem of RNase P. Inclusion of this P7-like stem confers on yeast MRP RNA a greater degree of similarity to the core RNase P RNA structure than that described previously and better delimits domain 2, the proposed specificity domain. The additional stem is created by participation of a conserved sequence element (ymCR-II) in a long-range base-pairing interaction. There is potential for this base-pairing throughout the known yeast MRP RNA sequences. Formation of a P7-like stem is not required, however, for the pre-rRNA processing or essential function of RNase MRP. Mutants that can base-pair are nonetheless detrimental to RNase MRP function, indicating that the stem will form in vivo but that only the wild-type pairing is accommodated. Although the alternative MRP RNA structure described is clearly not part of the active RNase MRP enzyme, it would be the more stable structure in the absence of protein subunits and the probability that it represents a valid intermediate species in the process of yeast RNase MRP assembly is discussed.     

Mutational analysis of the RNA component of Saccharomyces cerevisiae RNase MRP reveals distinct nuclear phenotypes

The 340-nucleotide RNA component of Saccharomyces cerevisiae RNase MRP is encoded by the single-copy essential gene, NME1. To gain additional insight into the proposed structure and functions of this endoribonuclease, we have extensively mutagenized the NME1 gene and characterized yeast strains expressing mutated forms of the RNA using a gene shuffle technique. Strains expressing each of 26 independent mutations in the RNase MRP RNA gene were characterized for their ability to grow at various temperatures and on various carbon sources, stability of the RNase MRP RNA and processing of the 5.8S rRNA (a nuclear function of RNase MRP). 11 of the mutations resulted in a lethal phenotype, six displayed temperature-conditional lethality, and several preferred a non-fermentable carbon source for growth. In those mutants that exhibited altered growth phenotypes, the severity of the growth defect was directly proportional to the severity of the 5.8S rRNA processing defect in the nucleus. Together this analysis has defined essential regions of the RNase MRP RNA and provides evidence that is consistent with the proposed function of the RNase MRP enzyme.     

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.