hPop1: an autoantigenic protein subunit shared by the human RNase P and RNase MRP ribonucleoproteins.

The eukaryotic endonucleases RNase P and RNase MRP require both RNA and protein subunits for function. Even though the human RNase P and MRP RNAs were previously characterized, the protein composition of the particles remains unknown. We have identified a human a Caenorhabditis elegans sequence showing homology to yPop1, a protein subunit of the yeast RNase P and MRP particles. A cDNA containing the complete coding sequence for the human protein, hPop1, was cloned. Sequence analysis identifies three novel sequence motifs, conserved between the human, C. elegans and yeast proteins. Affinity-purified anti-hPop1 antibodies recognize a single 115 kDa protein in HeLa cell nuclear extracts. Immunoprecipitations with different anti-hPop1 antibodies demonstrate an association of hPop1 with the vast majority of the RNase P and MRP RNAs in HeLa cell nuclear extracts. Additionally, anti-hPop1 immunoprecipitates possess RNase P enzymatic activity. These results establish hPop1 as the first identified RNase P and MRP protein subunit from humans. Anti-hPop1 antibodies generate a strong nucleolar and a weaker homogeneous nuclear staining in HeLa cells. A certain class of autoimmune patient serum precipitates in vitro-translated hPop1. hPop1 is therefore an autoantigen in patients suffering from connective tissue diseases.     

Molecular modeling of the three-dimensional architecture of the RNA component of yeast RNase MRP.

RNase mitochondrial RNA processing (MRP) is a ribonucleoprotein endoribonuclease that is involved in RNA processing events in both the nucleus and the mitochondria. The MRP RNA is both structurally and evolutionarily related to RNase P, the ribonucleoprotein endoribonuclease that processes the 5'-end of tRNAs. Previous analysis of the RNase MRP RNA by phylogenetic analysis and chemical modification has revealed strikingly conserved secondary structural elements in all characterized RNase MRP RNAs. Utilizing successive constraint modeling and energy minimization I derived a three-dimensional model of the yeast RNase MRP RNA. The final model predicts several notable features. First, the enzyme appears to contain two separate structural domains, one that is highly conserved among all MRP and P RNAs and a second that is only conserved in MRP RNAs. Second, nearly all of the highly conserved nucleotides cluster in the first domain around a long-range interaction (LRI-I). This LRI-I is characterized by a ubiquitous uridine base, which points into a cleft between these two structural domains generating a potential active site for RNA cleavage. Third, helices III and IV (the yeast equivalent of the To-binding site) model as a long extended helix. This region is believed to be the binding site of shared proteins between RNase P and RNase MRP and would provide a necessary platform for binding these seven proteins. Indeed, several residues conserved between the yeast MRP and P RNAs cluster in the central region of these helixes. Lastly, characterized mutations in the MRP RNA localize in the model based on their severity. Those mutations with little or no effect on the activity of the enzyme localize to the periphery of the model, while the most severe mutations localize to the central portion of the molecule where they would be predicted to cause large structural defects. Press.     

Efficient site-specific cleavage by RNase MRP requires interaction with two evolutionarily conserved mitochondrial RNA sequences.

RNase MRP is a site-specific endonuclease that processes primer mitochondrial RNA from the leading-strand origin of mitochondrial DNA replication. Using deletional analysis and saturation mutagenesis, we have determined the substrate requirements for cleavage by mouse mitochondrial RNase MRP. Two regions of sequence homology among vertebrate mitochondrial RNA primers, conserved sequence blocks II and III, were found to be critical for both efficient and accurate cleavage; a third region of sequence homology, conserved sequence block I, was dispensable. Analysis of insertion and deletion mutations within conserved sequence block II demonstrated that the specificity of RNase MRP accommodates the natural sequence heterogeneity of conserved sequence block II in vivo. Heterologous assays with human RNase MRP and mutated mouse mitochondrial RNA substrates indicated that sequences essential for substrate recognition are conserved between mammalian species.     

A functional dominant mutation in Schizosaccharomyces pombe RNase MRP RNA affects nuclear RNA processing and requires the mitochondrial-associated nuclear mutation ptp1-1 for viability.

The essential gene for RNase MRP RNA, mrp1, was identified previously in Schizosaccharomyces pombe by homology to mammalian RNase MRP RNAs. Here we describe distinct site-specific mutations in RNase MRP RNA that support a conserved role for this ribonucleoprotein in nucleolar 5.8S rRNA processing. One characterized mutation, mrp1-ND90, displays dominance and results in accumulation of unspliced precursor RNAs of dimeric tRNA(Ser)-tRNA(Met)i, suggesting a novel nuclear role for RNase MRP in tRNA processing. Cells carrying the mrp1-ND90 mutation, in the absence of a wild-type copy of mrp1, additionally require the mitochondrially associated nuclear mutation ptp1-1 for viability. Analysis of this mrp1 mutation reinforces previous biochemical evidence suggesting a role for RNase MRP in mitochondrial DNA replication. Several mutations in mrp1 result in unusual cellular morphology, including alterated nuclear organization, and are consistent with a broader nuclear role for RNase MRP in regulating a nuclear signal for septation; these results are a further indication of the multifunctional nature of this ribonucleoprotein.     

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.     

Functional characterization of the conserved amino acids in Pop1p, the largest common protein subunit of yeast RNases P and MRP

RNase P and RNase MRP are ribonucleoprotein enzymes required for 5'-end maturation of precursor tRNAs (pre-tRNAs) and processing of precursor ribosomal RNAs, respectively. In yeast, RNase P and MRP holoenzymes have eight protein subunits in common, with Pop1p being the largest at >100 kDa. Little is known about the functions of Pop1p, beyond the fact that it binds specifically to the RNase P RNA subunit, RPR1 RNA. In this study, we refined the previous Pop1 phylogenetic sequence alignment and found four conserved regions. Highly conserved amino acids in yeast Pop1p were mutagenized by randomization and conditionally defective mutations were obtained. Effects of the Pop1p mutations on pre-tRNA processing, pre-rRNA processing, and stability of the RNA subunits of RNase P and MRP were examined. In most cases, functional defects in RNase P and RNase MRP in vivo were consistent with assembly defects of the holoenzymes, although moderate kinetic defects in RNase P were also observed. Most mutations affected both pre-tRNA and pre-rRNA processing, but a few mutations preferentially interfered with only RNase P or only RNase MRP. In addition, one temperature-sensitive mutation had no effect on either tRNA or rRNA processing, consistent with an additional role for RNase P, RNase MRP, or Pop1p in some other form. This study shows that the Pop1p subunit plays multiple roles in the assembly and function of of RNases P and MRP, and that the functions can be differentiated through the mutations in conserved residues.     

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.     

Crystal structure of human RPP20-RPP25 proteins in complex with the P3 domain of lncRNA RMRP

Human RNase MRP ribonucleoprotein complex is an essential endoribonuclease involved in the processing of ribosomal RNAs, mitochondrial RNAs and certain messenger RNAs. Its RNA subunit RMRP catalyzes the cleavage of substrate RNAs, and the protein components of RNase MRP are required for activity. RMRP mutations are associated with several types of inherited developmental disorders, but the pathogenic mechanism is largely unknown. Recent structural studies shed lights on the catalytic mechanism of yeast RNase MRP and the closely related RNase P; however, the structural and catalytic mechanism of RMRP in human RNase MRP complex remains unclear. Here we report the crystal structure of the P3 domain of RMRP in complex with the RPP20 and RPP25 proteins of human RNase MRP, which shows that the P3 RNA binds to a conserved positively-charged surface of the RPP20-RPP25 heterodimer through its distal stem and internal loop regions. The disease-related mutations of RMRP^P3 are mostly located at the protein-RNA interface and are likely to weaken the binding of P3 to RPP20-RPP25. Moreover, the structure reveals a homodimeric organization of the entire RPP20-RPP25-RMRP^P3 complex, which might mediate the dimerization of human RNase MRP complex in cells. These findings provide structural clues to the assembly and pathogenesis of human RNase MRP complex and also reveal a tetrameric feature of RPP20-RPP25 evolutionarily conserved with that of the archaeal Alba proteins.     

Interactions of a Pop5/Rpp1 heterodimer with the catalytic domain of RNase MRP

Ribonuclease (RNase) MRP is a multicomponent ribonucleoprotein complex closely related to RNase P. RNase MRP and eukaryotic RNase P share most of their protein components, as well as multiple features of their catalytic RNA moieties, but have distinct substrate specificities. While RNase P is practically universally found in all three domains of life, RNase MRP is essential in eukaryotes. The structural organizations of eukaryotic RNase P and RNase MRP are poorly understood. Here, we show that Pop5 and Rpp1, protein components found in both RNase P and RNase MRP, form a heterodimer that binds directly to the conserved area of the putative catalytic domain of RNase MRP RNA. The Pop5/Rpp1 binding site corresponds to the protein binding site in bacterial RNase P RNA. Structural and evolutionary roles of the Pop5/Rpp1 heterodimer in RNases P and MRP are discussed.     

Dynamic localization of RNase MRP RNA in the nucleolus observed by fluorescent RNA cytochemistry in living cells

The dynamic intra-nuclear localization of MRP RNA, the RNA component of the ribonucleoprotein enzyme RNase MRP, was examined in living cells by the method of fluorescent RNA cytochemistry (Wang, J., L.-G. Cao, Y.-L. Wang, and T. Pederson. 1991. Proc. Natl. Acad. Sci. USA. 88:7391-7395). MRP RNA very rapidly accumulated in nucleoli after nuclear microinjection of normal rat kidney (NRK) epithelial cells. Localization was specifically in the dense fibrillar component of the nucleolus, as revealed by immunocytochemistry with a monoclonal antibody against fibrillarin, a known dense fibrillar component protein, as well as by digital optical sectioning microscopy and 3-D stereo reconstruction. When MRP RNA was injected into the cytoplasm it was not imported into the nucleus. Nuclear microinjection of mutant MRP RNAs revealed that nucleolar localization requires a sequence element (nucleotides 23-62) previously implicated as a binding site for a nucleolar protein, the To antigen. These results demonstrate the dynamic localization of MRP RNA in the nucleus and provide important insights into the nucleolar targeting of MRP RNA.     

Bovine RNase MRP cleaves the divergent bovine mitochondrial RNA sequence at the displacement-loop region

RNase MRP is a site-specific ribonucleoprotein endoribonuclease that cleaves mitochondrial RNA from the origin of leading-strand DNA synthesis contained within the displacement-loop region. Bovine mitochondrial DNA maintains the typical gene content and order of mammalian mitochondrial DNAs but differs in the nature of sequence conservation within this displacement-loop regulatory region. This markedly different sequence arrangement raises the issue of the degree to which a bovine RNase MRP would reflect the physical and functional properties ascribed to the enzymes previously characterized from mouse and human. We find that bovine RNase MRP exists as a ribonucleoprotein, with an RNA component of 279 nucleotides that is homologous to that of mouse or human RNase MRP RNA. Characterization of the nuclear gene for bovine RNase MRP RNA showed conservation of sequence extending 5 of the RNase MRP RNA coding sequence, including the presence of a cis-acting element known to be important for the expression of some mitochondrial protein-coding nuclear genes. Bovine or mouse RNase MRP cleaves a standard mouse mitochondrial RNA substrate in the same manner; each also cleaves a bovine mitochondrial RNA substrate identically. Since bovine and mouse RNase MRPs process both bovine and mouse substrates, we conclude that the structural features of the mitochondrial RNA substrate required for enzymatic cleavage have been well conserved despite significant overall primary sequence divergence. Inspection of the bovine RNA substrate reveals conservation of only the most critical portion of the primary sequence as indicated by earlier studies with mouse and human RNase MRPs. Interestingly, a principal cleavage site in the bovine mitochondrial RNA substrate is downstream of the promoter located at the leading-strand mitochondrial DNA replication origin. Correspondence to: D.J. Dairaghi     

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.     

RNase MRP RNA and RNase P activity in plants are associated with a Pop1p containing complex

RNase P processes the 5'-end of tRNAs. An essential catalytic RNA has been demonstrated in Bacteria, Archaea and the nuclei of most eukaryotes; an organism-specific number of proteins complement the holoenzyme. Nuclear RNase P from yeast and humans is well understood and contains an RNA, similar to the sister enzyme RNase MRP. In contrast, no protein subunits have yet been identified in the plant enzymes, and the presence of a nucleic acid in RNase P is still enigmatic. We have thus set out to identify and characterize the subunits of these enzymes in two plant model systems. Expression of the two known Arabidopsis MRP RNA genes in vivo was verified. The first wheat MRP RNA sequences are presented, leading to improved structure models for plant MRP RNAs. A novel mRNA encoding the central RNase P/MRP protein Pop1p was identified in Arabidopsis, suggesting the expression of distinct protein variants from this gene in vivo. Pop1p-specific antibodies precipitate RNase P activity and MRP RNAs from wheat extracts. Our results provide evidence that in plants, Pop1p is associated with MRP RNAs and with the catalytic subunit of RNase P, either separately or in a single large complex.     

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.     

Role of RNase MRP in viral RNA degradation and RNA recombination

RNA degradation, together with RNA synthesis, controls the steady-state level of viral RNAs in infected cells. The endoribonucleolytic cleavage of viral RNA is important not only for viral RNA degradation but for RNA recombination as well, due to the participation of some RNA degradation products in the RNA recombination process. To identify host endoribonucleases involved in degradation of Tomato bushy stunt virus (TBSV) in a Saccharomyces cerevisiae model host, we tested eight known endoribonucleases. Here we report that downregulation of SNM1, encoding a component of the RNase MRP, and a temperature-sensitive mutation in the NME1 gene, coding for the RNA component of RNase MRP, lead to reduced production of the endoribonucleolytically cleaved TBSV RNA in yeast. We also show that the highly purified yeast RNase MRP cleaves the TBSV RNA in vitro, resulting in TBSV RNA degradation products similar in size to those observed in yeast cells. Knocking down the NME1 homolog in Nicotiana benthamiana also led to decreased production of the cleaved TBSV RNA, suggesting that in plants, RNase MRP is involved in TBSV RNA degradation. Altogether, this work suggests a role for the host endoribonuclease RNase MRP in viral RNA degradation and recombination.     

Secondary structure probing of the human RNase MRP RNA reveals the potential for MRP RNA subsets

RNase MRP is a ribonucleoprotein endoribonuclease involved in eukaryotic pre-rRNA processing. The enzyme possesses an RNA subunit, structurally related to that of RNase P RNA, that is thought to be catalytic. RNase MRP RNA sequences from Saccharomycetaceae species are structurally well defined through detailed phylogenetic and structural analysis. In contrast, higher eukaryote MRP RNA structure models are based on comparative sequence analysis of only five sequences and limited probing data. Detailed structural analysis of the Homo sapiens MRP RNA, entailing enzymatic and chemical probing, is reported. The data are consistent with the phylogenetic secondary structure model and demonstrate unequivocally that higher eukaryote MRP RNA structure differs significantly from that reported for Saccharomycetaceae species. Neither model can account for all of the known MRP RNAs and we thus propose the evolution of at least two subsets of RNase MRP secondary structure, differing predominantly in the predicted specificity domain.