Ribonuclease P-mediated inhibition of human cytomegalovirus gene expression and replication induced by engineered external guide sequences

External guide sequences (EGSs) are RNA molecules that can bind to a target mRNA and direct ribonuclease P (RNase P), a tRNA processing enzyme, for specific cleavage of the target mRNA. Using an in vitro selection procedure, we have previously generated EGS variants that efficiently direct human RNase P to cleave a target mRNA in vitro. In this study, we constructed EGSs from a variant to target the overlapping region of the mRNAs coding for human cytomegalovirus (HCMV) capsid scaffolding protein (CSP) and assemblin, which are essential for viral capsid formation. The EGS variant was about 40-fold more active in directing human RNase P to cleave the mRNA in vitro than the EGS derived from a natural tRNA. Moreover, a reduction of about 98% and 75% in CSP/assemblin gene expression and a reduction of 7000- and 250-fold in viral growth were observed in HCMV-infected cells that expressed the variant and the tRNA-derived EGS, respectively. Our study shows that the EGS variant is more effective in blocking HCMV gene expression and growth than the tRNA-derived EGS. Moreover, these results demonstrate the utility of highly active EGS RNA variants in gene targeting applications including anti-HCMV therapy.

RNase P: at last, the key finds its lock

Apart from the ribosome, the crystal structure of the bacterial RNase P in complex with a tRNA, reported by Reiter and colleagues recently, constitutes the first example of a multiple turnover RNA enzyme. Except in rare exceptions, RNase P is ubiquitous and, like the ribosome, is older than the initial branch point of the phylogenetic tree. Importantly, the structure shows how the RNA and the protein moieties cooperate to process the pre-tRNA substrates. The catalytic site comprises some critical RNA residues spread over the secondary structure but gathered in a compact volume next to the protein, which helps recognize and orient the substrate. The discussion here outlines some important aspects of that crystal structure, some of which could apply to RNA molecules in general.

subtilis RNase P protein interacts with both PRNA and pre-tRNA to stabilize an active conformer

Ribonuclease P (RNase P) catalyzes the metal-dependent 5' end maturation of precursor tRNAs (pre-tRNAs). In Bacteria, RNase P is composed of a catalytic RNA (PRNA) and a protein subunit (P protein) necessary for function in vivo. The P protein enhances pre-tRNA affinity, selectivity, and cleavage efficiency, as well as modulates the cation requirement for RNase P function. Bacterial P proteins share little sequence conservation although the protein structures are homologous. Here we combine site-directed mutagenesis, affinity measurements, and single turnover kinetics to demonstrate that two residues (R60 and R62) in the most highly conserved region of the P protein, the RNR motif (R60-R68 in Bacillus subtilis), stabilize PRNA complexes with both P protein (PRNA•P protein) and pre-tRNA (PRNA•P protein•pre-tRNA). Additionally, these data indicate that the RNR motif enhances a metal-stabilized conformational change in RNase P that accompanies substrate binding and is essential for efficient catalysis. Stabilization of this conformational change contributes to both the decreased metal requirement and the enhanced substrate recognition of the RNase P holoenzyme, illuminating the role of the most highly conserved region of P protein in the RNase P reaction pathway.

Solution structure of RNase P RNA

The ribonucleoprotein enzyme ribonuclease P (RNase P) processes tRNAs by cleavage of precursor-tRNAs. RNase P is a ribozyme: The RNA component catalyzes tRNA maturation in vitro without proteins. Remarkable features of RNase P include multiple turnovers in vivo and ability to process diverse substrates. Structures of the bacterial RNase P, including full-length RNAs and a ternary complex with substrate, have been determined by X-ray crystallography. However, crystal structures of free RNA are significantly different from the ternary complex, and the solution structure of the RNA is unknown. Here, we report solution structures of three phylogenetically distinct bacterial RNase P RNAs from Escherichia coli, Agrobacterium tumefaciens, and Bacillus stearothermophilus, determined using small angle X-ray scattering (SAXS) and selective 2'-hydroxyl acylation analyzed by primer extension (SHAPE) analysis. A combination of homology modeling, normal mode analysis, and molecular dynamics was used to refine the structural models against the empirical data of these RNAs in solution under the high ionic strength required for catalytic activity.

Inactivation of expression of two genes in Saccharomyces cerevisiae with the external guide sequence methodology

The artificial inhibition of expression of genes in Saccharomyces cerevisiae is not a widespread, useful phenomenon. The external guide sequence (EGS) technology, which is well-proven in bacteria and mammalian cells in tissue culture and in mice, can also be utilized in yeast. The TOP2 and SRG1 genes can be inhibited by ∼30% with EGSs in vivo. Results in vitro also show convenient cleavage of the relevant transcripts by RNase P and appropriate EGSs. The feasible constructs shown to date have an EGS covalently linked to M1 RNA, the RNA subunit of RNase P from Escherichia coli. Greater efficiency in cleavage of transcripts can be fashioned using more than one EGS targeted to different sites in a transcript and stronger promoters controlling the EGS constructs.

Morpholino oligonucleotides do not participate perfectly in standard Watson-Crick complexes with RNA

RNase P from E. coli will cleave a RNA at a site designated in a complex with an external guide sequence (EGS). The location of the site is determined by the Watson-Crick complementary sequence that can be formed between the RNA and the EGS. Morpholino oligonucleotides (PMOs) that have the same base sequences as any particular EGS will not direct cleavage by RNase P of the target RNA at the expected site in three mRNAs. Instead, cleavage occurs at a secondary site that does not correspond exactly to the expected Watson-Crick sequence in the PMO. This cleavage in the mRNA for a drug resistance gene, CAT mRNA, is at least second order in the concentration of the PMOs, but the mechanism is not understood yet and might be more complicated than a simple second-order reaction. EGSs and PMOs inhibit the reactions of each other effectively in a competitive fashion. A basic peptide attached to the PMO (PPMO) is more effective because of its binding properties to the mRNA as a substrate. However, a PMO is just as efficient as a PPMO on a mRNA that is mutated so that the canonical W-C site has been altered. The altered mRNA is not recognizable by effective extensive W-C pairing to an EGS or PMO. The complex of a PMO on a mutated mRNA as a substrate shows that the dimensions of the modified oligonucleotide cannot be the same as a naked piece of single-stranded RNA.

Schizosaccharomyces cryophilus sp. nov., a new species of fission yeast

The genus Schizosaccharomyces is presently comprised of three species, namely Schizosaccharomyces pombe, Schizosaccharomyces octosporus and Schizosaccharomyces japonicus. Here, we describe a hitherto unknown species, Schizosaccharomyces cryophilus, named for its preference for growth at lower temperatures than the other fission yeast species. Although morphologically similar to S. octosporus, analysis of several rapidly evolving sequences, including the D1/D2 divergent domain of the large subunit (LSU) rRNA gene, the RNA subunit of RNAse P and the internal transcribed spacer elements, revealed significant divergence from any previously characterized Schizosaccharomyces strain. Based on phylogenetic analysis of the D1/D2 domain of the LSU rRNA gene, S. octosporus is the closest known relative of S. cryophilus, with the sequences of the two species differing by 25 nucleotide substitutions (>4%). Sequencing of the S. cryophilus genome and phylogenetic analysis of all 1 : 1 protein orthologs confirmed this observation, and together with morphological and physiological characterization, supports the assignment of S. cryophilus as a new species within the genus Schizosaccharomyces. The type strain of the new species is NRRL Y-48691(T) (=NBRC 106824(T)=CBS 11777(T)).

Of proteins and RNA: the RNase P/MRP family

Nuclear ribonuclease (RNase) P is a ubiquitous essential ribonucleoprotein complex, one of only two known RNA-based enzymes found in all three domains of life. The RNA component is the catalytic moiety of RNases P across all phylogenetic domains; it contains a well-conserved core, whereas peripheral structural elements are diverse. RNA components of eukaryotic RNases P tend to be less complex than their bacterial counterparts, a simplification that is accompanied by a dramatic reduction of their catalytic ability in the absence of protein. The size and complexity of the protein moieties increase dramatically from bacterial to archaeal to eukaryotic enzymes, apparently reflecting the delegation of some structural functions from RNA to proteins and, perhaps, in response to the increased complexity of the cellular environment in the more evolutionarily advanced organisms; the reasons for the increased dependence on proteins are not clear. We review current information on RNase P and the closely related universal eukaryotic enzyme RNase MRP, focusing on their functions and structural organization.

subtilis RNase P x pre-tRNA complex: a role for an inner-sphere metal ion in RNase P

Metal ions interact with RNA to enhance folding, stabilize structure, and, in some cases, facilitate catalysis. Assigning functional roles to specifically bound metal ions presents a major challenge in analyzing the catalytic mechanisms of ribozymes. Bacillus subtilis ribonuclease P (RNase P), composed of a catalytically active RNA subunit (PRNA) and a small protein subunit (P protein), catalyzes the 5'-end maturation of precursor tRNAs (pre-tRNAs). Inner-sphere coordination of divalent metal ions to PRNA is essential for catalytic activity but not for the formation of the RNase P x pre-tRNA (enzyme-substrate, ES) complex. Previous studies have demonstrated that this ES complex undergoes an essential conformational change (to the ES* conformer) before the cleavage step. Here, we show that the ES* conformer is stabilized by a high-affinity divalent cation capable of inner-sphere coordination, such as Ca(II) or Mg(II). Additionally, a second, lower-affinity Mg(II) activates cleavage catalyzed by RNase P. Structural changes that occur upon binding Ca(II) to the ES complex were determined by time-resolved Förster resonance energy transfer measurements of the distances between donor-acceptor fluorophores introduced at specific locations on the P protein and pre-tRNA 5' leader. These data demonstrate that the 5' leader of pre-tRNA moves 4 to 6 A closer to the PRNA x P protein interface during the ES-to-ES* transition and suggest that the metal-dependent conformational change reorganizes the bound substrate in the active site to form a catalytically competent ES* complex.

Protein-precursor tRNA contact leads to sequence-specific recognition of 5' leaders by bacterial ribonuclease P

Bacterial ribonuclease P (RNase P) catalyzes the cleavage of 5' leader sequences from precursor tRNAs (pre-tRNAs). Previously, all known substrate nucleotide specificities in this system are derived from RNA-RNA interactions with the RNase P RNA subunit. Here, we demonstrate that pre-tRNA binding affinities for Bacillus subtilis and Escherichia coli RNase P are enhanced by sequence-specific contacts between the fourth pre-tRNA nucleotide on the 5' side of the cleavage site (N(-4)) and the RNase P protein (P protein) subunit. B. subtilis RNase P has a higher affinity for pre-tRNA with adenosine at N(-4), and this binding preference is amplified at physiological divalent ion concentrations. Measurements of pre-tRNA-containing adenosine analogs at N(-4) indicate that specificity arises from a combination of hydrogen bonding to the N6 exocyclic amine of adenosine and steric exclusion of the N2 amine of guanosine. Mutagenesis of B. subtilis P protein indicates that F20 and Y34 contribute to selectivity at N(-4). The hydroxyl group of Y34 enhances selectivity, likely by forming a hydrogen bond with the N(-4) nucleotide. The sequence preference of E. coli RNase P is diminished, showing a weak preference for adenosine and cytosine at N(-4), consistent with the substitution of Leu for Y34 in the E. coli P protein. This is the first identification of a sequence-specific contact between P protein and pre-tRNA that contributes to molecular recognition of RNase P. Additionally, sequence analyses reveal that a greater-than-expected fraction of pre-tRNAs from both E. coli and B. subtilis contains a nucleotide at N(-4) that enhances RNase P affinity. This observation suggests that specificity at N(-4) contributes to substrate recognition in vivo. Furthermore, bioinformatic analyses suggest that sequence-specific contacts between the protein subunit and the leader sequences of pre-tRNAs may be common in bacterial RNase P and may lead to species-specific substrate recognition.

NMR and XAS reveal an inner-sphere metal binding site in the P4 helix of the metallo-ribozyme ribonuclease P

Functionally critical metals interact with RNA through complex coordination schemes that are currently difficult to visualize at the atomic level under solution conditions. Here, we report a new approach that combines NMR and XAS to resolve and characterize metal binding in the most highly conserved P4 helix of ribonuclease P (RNase P), the ribonucleoprotein that catalyzes the divalent metal ion-dependent maturation of the 5' end of precursor tRNA. Extended X-ray absorption fine structure (EXAFS) spectroscopy reveals that the Zn(2+) bound to a P4 helix mimic is six-coordinate, with an average Zn-O/N bond distance of 2.08 A. The EXAFS data also show intense outer-shell scattering indicating that the zinc ion has inner-shell interactions with one or more RNA ligands. NMR Mn(2+) paramagnetic line broadening experiments reveal strong metal localization at residues corresponding to G378 and G379 in B. subtilis RNase P. A new "metal cocktail" chemical shift perturbation strategy involving titrations with , Zn(2+), and confirm an inner-sphere metal interaction with residues G378 and G379. These studies present a unique picture of how metals coordinate to the putative RNase P active site in solution, and shed light on the environment of an essential metal ion in RNase P. Our experimental approach presents a general method for identifying and characterizing inner-sphere metal ion binding sites in RNA in solution.

Broadening the mission of an RNA enzyme

The "RNA World" hypothesis suggests that life developed from RNA enzymes termed ribozymes, which carry out reactions without assistance from proteins. Ribonuclease (RNase) P is one ribozyme that appears to have adapted these origins to modern cellular life by adding protein to the RNA core in order to broaden the potential functions. This RNA-protein complex plays diverse roles in processing RNA, but its best-understood reaction is pre-tRNA maturation, resulting in mature 5' ends of tRNAs. The core catalytic activity resides in the RNA subunit of almost all RNase P enzymes but broader substrate tolerance is required for recognizing not only the diverse sequences of tRNAs, but also additional cellular RNA substrates. This broader substrate tolerance is provided by the addition of protein to the RNA core and allows RNase P to selectively recognize different RNAs, and possibly ribonucleoprotein (RNP) substrates. Thus, increased protein content correlated with evolution from bacteria to eukaryotes has further enhanced substrate potential enabling the enzyme to function in a complex cellular environment.

Three-way RNA junctions with remote tertiary contacts: a recurrent and highly versatile fold

Three-way junction RNAs adopt a recurrent Y shape when two of the helices form a coaxial stack and the third helix establishes one or more tertiary contacts several base pairs away from the junction. In this review, the structure, distribution, and functional relevance of these motifs are examined. Structurally, the folds exhibit conserved junction topologies, and the distal tertiary interactions play a crucial role in determining the final shape of the structures. The junctions and remote tertiary contacts behave as flexible hinge motifs that respond to changes in the other region, providing these folds with switching mechanisms that have been shown to be functionally useful in a variety of contexts. In addition, the juxtaposition of RNA domains at the junction and at the distal tertiary complexes enables the RNA helices to adopt unusual conformations that are frequently used by proteins, RNA molecules, and antibiotics as platforms for specific binding. As a consequence of these properties, Y-shaped junctions are widely distributed in all kingdoms of life, having been observed in small naked RNAs such as riboswitches and ribozymes or embedded in complex ribonucleoprotein systems like ribosomal RNAs, RNase P, or the signal recognition particle. In all cases, the folds were found to play an essential role for the functioning or assembly of the RNA or ribonucleoprotein systems that contain them.

Inactivation of expression of several genes in a variety of bacterial species by EGS technology

The expression of gene products in bacteria can be inhibited by the use of RNA external guide sequences (EGSs) that hybridize to a target mRNA. Endogenous RNase P cleaves the mRNA in the complex, making it inactive. EGSs participate in this biochemical reaction as the data presented here show. They promote mRNA cleavage at the expected site and sometimes at other secondary sites. Higher-order structure must affect these reactions if the cleavage does not occur at the defined site, which has been determined by techniques based on their ability to find sites that are accessible to the EGS oligonucleotides. Sites defined by a random EGS technique occur as expected. Oligonucleotides made up primarily of defined or random nucleotides are extremely useful in inhibiting expression of the gyrA and rnpA genes from several different bacteria or the cat gene that determines resistance to chloramphenicol in Escherichia coli. An EGS made up of a peptide-phosphorodiamidate morpholino oligonucleotide (PPMO) does not cleave at the same site as an unmodified RNA EGS for reasons that are only partly understood. However, PPMO-EGSs are useful in inhibiting the expression of targeted genes from Gram-negative and Gram-positive organisms during ordinary growth in broth and may provide a basis for broad-spectrum antibiotics.

RNase P: increased versatility through protein complexity?

Ribonuclease P (RNase P) is an essential enzyme that catalyzes the 5' endonucleolytic cleavage of precursor transfer RNAs (pretRNAs). It is found in all phylogenetic domains: bacteria, archaea and eukaryotes. The bacterial enzyme consists of a single, catalytic RNA subunit and one small protein, while the archaeal and eukaryotic enzymes have 4-10 proteins in addition to a similar RNA subunit. The bacterial RNA acts as a ribozyme at high salt in vitro; however the added protein optimizes kinetics and makes specific contacts with the pre-tRNA substrate. The bacterial protein subunit also appears to be required for the processing of non-tRNA substrates by broadening recognition tolerance. In addition, the immense increase in protein content in the eukaryotic enzymes suggests substantially enlarged capacity for recognition of additional substrates. Recently intron-encoded box C/D snoRNAs were shown to be likely substrates for RNase P, with several lines of evidence suggesting that the nuclear holoenzyme binds tightly to, and can cleave single-stranded RNA in a sequence dependent fashion. The possible involvement of RNase P in additional RNA processing or turnover pathways would be consistent with previous findings that RNase MRP, a variant of RNase P that has evolved to participate in ribosomal RNA processing, is also involved in turnover of specific messenger RNAs. Here, involvement of RNase P in multiple RNA processing pathways is discussed.

Evidence that binding of C5 protein to P RNA enhances ribozyme catalysis by influencing active site metal ion affinity

The RNA subunit (P RNA) of the bacterial RNase P ribonucleoprotein is a ribozyme that catalyzes the Mg-dependent hydrolysis of pre-tRNA, but it requires an essential protein cofactor (P protein) in vivo that enhances substrate binding affinities and catalytic rates in a substrate dependent manner. Previous studies of Bacillus subtilis RNase P, containing a Type B RNA subunit, showed that its cognate protein subunit increases the affinity of metal ions important for catalysis, but the functional role of these ions is unknown. Here, we demonstrate that the Mg2+ dependence of the catalytic step for Escherichia coli RNase P, which contains a more common Type A RNA subunit, is also modulated by its cognate protein subunit (C5), indicating that this property is fundamental to P protein. To monitor specifically the binding of active site metal ions, we analyzed quantitatively the rescue by Cd2+ of an inhibitory Rp phosphorothioate modification at the pre-tRNA cleavage site. The results show that binding of C5 protein increases the apparent affinity of the rescuing Cd2+, providing evidence that C5 protein enhances metal ion affinity in the active site, and thus is likely to contribute significantly to rate enhancement at physiological metal ion concentrations.

subtilis RNase P holoenzyme active site by cross-linking and affinity cleavage

Bacterial ribonuclease P (RNase P) is a ribonucleoprotein complex composed of one catalytic RNA (PRNA) and one protein subunit (P protein) that together catalyze the 5' maturation of precursor tRNA. High-resolution X-ray crystal structures of the individual P protein and PRNA components from several species have been determined, and structural models of the RNase P holoenzyme have been proposed. However, holoenzyme models have been limited by a lack of distance constraints between P protein and PRNA in the holoenzyme-substrate complex. Here, we report the results of extensive cross-linking and affinity cleavage experiments using single-cysteine P protein variants derivatized with either azidophenacyl bromide or 5-iodoacetamido-1,10-o-phenanthroline to determine distance constraints and to model the Bacillus subtilis holoenzyme-substrate complex. These data indicate that the evolutionarily conserved RNR motif of P protein is located near (<15 Angstroms) the pre-tRNA cleavage site, the base of the pre-tRNA acceptor stem and helix P4 of PRNA, the putative active site of the enzyme. In addition, the metal binding loop and N-terminal region of the P protein are proximal to the P3 stem-loop of PRNA. Studies using heterologous holoenzymes composed of covalently modified B. subtilis P protein and Escherichia coli M1 RNA indicate that P protein binds similarly to both RNAs. Together, these data indicate that P protein is positioned close to the RNase P active site and may play a role in organizing the RNase P active site.

Heterodimerization regulates RNase MRP/RNase P association, localization, and expression of Rpp20 and Rpp25

Rpp20 and Rpp25 are subunits of the human RNase MRP and RNase P endoribonucleases belonging to the Alba superfamily of nucleic acid binding proteins. These proteins, which bind very strongly to each other, transiently associate with RNase MRP. Here, we show that the Rpp20-Rpp25 heterodimer is resistant to both high concentrations of salt and a nonionic detergent. The interaction of Rpp20 and Rpp25 with the P3 domain of the RNase MRP RNA appeared to be strongly enhanced by their heterodimerization. Coimmunoprecipitation experiments demonstrated that only a single copy of each of these proteins is associated with the RNase MRP and RNase P particles in HEp-2 cells. Both proteins accumulate in the nucleoli, which in case of Rpp20 is strongly dependent on its interaction with Rpp25. Finally, the results of overexpression and knock-down experiments indicate that their expression levels are codependent. Taken together, these data indicate that the Rpp20-Rpp25 heterodimerization regulates their RNA-binding activity, subcellular localization, and expression, which suggests that their interaction is also crucial for their role in RNase MRP/P function.

Thermostable RNase P RNAs lacking P18 identified in the Aquificales

The RNase P RNA (rnpB) and protein (rnpA) genes were identified in the two Aquificales Sulfurihydrogenibium azorense and Persephonella marina. In contrast, neither of the two genes has been found in the sequenced genome of their close relative, Aquifex aeolicus. As in most bacteria, the rnpA genes of S. azorense and P. marina are preceded by the rpmH gene coding for ribosomal protein L34. This genetic region, including several genes up- and downstream of rpmH, is uniquely conserved among all three Aquificales strains, except that rnpA is missing in A. aeolicus. The RNase P RNAs (P RNAs) of S. azorense and P. marina are active catalysts that can be activated by heterologous bacterial P proteins at low salt. Although the two P RNAs lack helix P18 and thus one of the three major interdomain tertiary contacts, they are more thermostable than Escherichia coli P RNA and require higher temperatures for proper folding. Related to their thermostability, both RNAs include a subset of structural idiosyncrasies in their S domains, which were recently demonstrated to determine the folding properties of the thermostable S domain of Thermus thermophilus P RNA. Unlike 16S rRNA phylogeny that has placed the Aquificales as the deepest lineage of the bacterial phylogenetic tree, RNase P RNA-based phylogeny groups S. azorense and P. marina with the green sulfur, cyanobacterial, and delta/epsilon proteobacterial branches.

Hybrid E. coli--Mitochondrial ribonuclease P RNAs are catalytically active

RNase P is a ribonucleoprotein that cleaves tRNA precursors at their 5'-end. Mitochondrion-encoded RNA subunits of mitochondrial RNase P (mtP-RNA) have been identified in jakobid flagellates such as Reclinomonas americana, in the prasinophyte alga Nephroselmis olivacea, and in several ascomycete and zygomycete fungi. While the structures of ascomycete mtP-RNAs are highly reduced, those of jakobids, prasinophytes, and zygomycetes retain most conserved features of their bacterial counterparts. Therefore, these mtP-RNAs might be active in vitro in the absence of a protein subunit, as are bacterial P-RNAs. Here we present a comparative structural analysis including seven newly characterized jakobid mtP-RNAs. We investigate ribozyme activities of mtP-RNAs and find that even the most bacteria-like molecules of jakobids are inactive in vitro. However, when certain domains of jakobid and N. olivacea mtP-RNAs are replaced with those from Escherichia coli, these hybrid RNAs show catalytic activity. In vitro mutagenesis of these hybrid mtP-RNAs shows that various structural elements play a critical role in ribozyme catalysis and provide further support for the presence of these elements in mtP-RNAs. These include GNRA tetraloops in helix P14 and P18 of Jakoba libera, and a remnant P3 pairing in Seculamonas ecuadoriensis. Finally, we will discuss reasons for the failure of mtP-RNAs to show catalytic activity in the absence of P-proteins based on our mutagenesis analysis.

The P4 metal binding site in RNase P RNA affects active site metal affinity through substrate positioning

Although helix P4 in the catalytic domain of the RNase P ribozyme is known to coordinate magnesium ions important for activity, distinguishing between direct and indirect roles in catalysis has been difficult. Here, we provide evidence for an indirect role in catalysis by showing that while the universally conserved bulge of helix P4 is positioned 5 nt downstream of the cleavage site, changes in its structure can still purturb active site metal binding. Because changes in helix P4 also appear to alter its position relative to the pre-tRNA cleavage site, these data suggest that P4 contributes to catalytic metal ion binding through substrate positioning.

Differential association of protein subunits with the human RNase MRP and RNase P complexes

RNase MRP is a eukaryotic endoribonuclease involved in nucleolar and mitochondrial RNA processing events. RNase MRP is a ribonucleoprotein particle, which is structurally related to RNase P, an endoribonuclease involved in pre-tRNA processing. Most of the protein components of RNase MRP have been reported to be associated with RNase P as well. In this study we determined the association of these protein subunits with the human RNase MRP and RNase P particles by glycerol gradient sedimentation and coimmunoprecipitation. In agreement with previous studies, RNase MRP sedimented at 12S and 60-80S. In contrast, only a single major peak was observed for RNase P at 12S. The analysis of individual protein subunits revealed that hPop4 (also known as Rpp29), Rpp21, Rpp20, and Rpp25 only sedimented in 12S fractions, whereas hPop1, Rpp40, Rpp38, and Rpp30 were also found in 60-80S fractions. In agreement with their cosedimentation with RNase P RNA in the 12S peak, coimmunoprecipitation with VSV-epitope-tagged protein subunits revealed that hPop4, Rpp21, and in addition Rpp14 preferentially associate with RNase P. These data show that hPop4, Rpp21, and Rpp14 may not be associated with RNase MRP. Furthermore, Rpp20 and Rpp25 appear to be associated with only a subset of RNase MRP particles, in contrast to hPop1, Rpp40, Rpp38, and Rpp30 (and possibly also hPop5), which are probably associated with all RNase MRP complexes. Our data are consistent with a transient association of Rpp20 and Rpp25 with RNase MRP, which may be inversely correlated to its involvement in pre-rRNA processing.

Effective inhibition of human cytomegalovirus gene expression and growth by intracellular expression of external guide sequence RNA

RNase P complexed with external guide sequence (EGS) represents a novel nucleic-acid-based gene interference approach to modulate gene expression. In this study, a functional EGS RNA was constructed to target the overlapping mRNA region of two human cytomegalovirus (HCMV) capsid proteins, the capsid scaffolding protein (CSP) and assemblin. The EGS RNA was shown to be able to direct human RNase P to cleave the target mRNA sequence efficiently in vitro. A reduction of approximately 75%-80% in the mRNA and protein expression levels of both CSP and assemblin and a reduction of 800-fold in viral growth were observed in human cells that expressed the functional EGS, but not in cells that either did not express the EGS or produced a "disabled" EGS that carried nucleotide mutations that precluded RNase P recognition. The action of the EGS is specific as the RNase P-mediated cleavage only reduces the expression of the CSP and assemblin but not other viral genes examined. Further studies of the antiviral effects of the EGS indicate that the expression of the functional EGS has no effect on HCMV genome replication but blocks viral capsid maturation, consistent with the notion that CSP and assemblin play essential roles in HCMV capsid formation. Our study provides the first direct evidence that EGS RNAs effectively inhibit HCMV gene expression and growth. Moreover, these results demonstrate the utility of EGS RNAs in gene therapy applications, including the treatment of HCMV infection by inhibiting the expression of virus-encoded essential proteins.

Regulated expression of functional external guide sequences in mammalian cells using a U6 RNA polymerase III promoter

A regulatable promoter has been stably integrated into a human embryonic kidney cell line. The promoter is a pol III mouse promoter and is under the control of ponasterone A, an ecdysone inducer. The promoter controls transcription of an external guide sequence (EGS) targeted against Rpp38, a protein subunit of human RNase P, or of lamin A/C, a gene product located in the nucleus. The amounts of protein of both gene products are severely reduced when the EGSs are made. Several other, but not all, of the protein subunits of RNase P are also inhibited in both mRNA and protein levels when Rpp38 mRNA is targeted.

3D models of yeast RNase P/MRP proteins Rpp1p and Pop3p

Sensitive profile searches and fold recognition were used to predict the structures of two yeast RNase P/MRP proteins. Rpp1p, which is one of the subunits common to eukaryotes and archaea, is predicted to adopt the seven-stranded TIM-barrel fold found in PHP phosphoesterases. Pop3p, initially thought to be one of the RNase P/MRP subunits unique to yeast, has been assigned the L7Ae/L30e fold. This RNA-binding fold is also present in human RNase P subunit Rpp38, raising the possibility that Pop3p and Rpp38 are functional homologs.

Crystal structure of archaeal ribonuclease P protein Ph1771p from Pyrococcus horikoshii OT3: an archaeal homolog of eukaryotic ribonuclease P protein Rpp29

Ribonuclease P (RNase P) is the endonuclease responsible for the removal of 5' leader sequences from tRNA precursors. The crystal structure of an archaeal RNase P protein, Ph1771p (residues 36-127) from hyperthermophilic archaeon Pyrococcus horikoshii OT3 was determined at 2.0 A resolution by X-ray crystallography. The structure is composed of four helices (alpha1-alpha4) and a six-stranded antiparallel beta-sheet (beta1-beta6) with a protruding beta-strand (beta7) at the C-terminal region. The strand beta7 forms an antiparallel beta-sheet by interacting with strand beta4 in a symmetry-related molecule, suggesting that strands beta4 and beta7 could be involved in protein-protein interactions with other RNase P proteins. Structural comparison showed that the beta-barrel structure of Ph1771p has a topological resemblance to those of Staphylococcus aureus translational regulator Hfq and Haloarcula marismortui ribosomal protein L21E, suggesting that these RNA binding proteins have a common ancestor and then diverged to specifically bind to their cognate RNAs. The structure analysis as well as structural comparison suggested two possible RNA binding sites in Ph1771p, one being a concave surface formed by terminal alpha-helices (alpha1-alpha4) and beta-strand beta6, where positively charged residues are clustered. A second possible RNA binding site is at a loop region connecting strands beta2 and beta3, where conserved hydrophilic residues are exposed to the solvent and interact specifically with sulfate ion. These two potential sites for RNA binding are located in close proximity. The crystal structure of Ph1771p provides insight into the structure and function relationships of archaeal and eukaryotic RNase P.

Interaction of the Bacillus subtilis RNase P with the 30S ribosomal subunit

Ribonuclease P (RNase P) is a ribozyme required for the 5' maturation of all tRNA. RNase P and the ribosome are the only known ribozymes conserved in all organisms. We set out to determine whether this ribonucleoprotein enzyme interacts with other cellular components, which may imply other functions for this conserved ribozyme. Incubation of the Bacillus subtilis RNase P holoenzyme with fractionated B. subtilis cellular extracts and purified ribosomal subunits results in the formation of a gel-shifted complex with the 30S ribosomal subunit at a binding affinity of approximately 40 nM in 0.1 M NH(4)Cl and 10 mM MgCl(2). The complex does not form with the RNase P RNA alone and is disrupted by a mRNA mimic polyuridine, but is stable in the presence of high concentrations of mature tRNA. Endogenous RNase P can also be detected in the 30S ribosomal fraction. Cleavage of a pre-tRNA substrate by the RNase P holoenzyme remains the same in the presence of the 30S ribosome, but the cleavage of an artificial non-tRNA substrate is inhibited eightfold. Hydroxyl radical protection and chemical modification identify several protected residues located in a highly conserved region in the RNase P RNA. A single mutation within this region significantly reduces binding, providing strong support on the specificity of the RNase P-30S ribosome complex. Our results also suggest that the dimeric form of the RNase P is primarily involved in 30S ribosome binding. We discuss several models on a potential function of the RNase P-30S ribosome complex.

Intracellular expression of engineered RNase P ribozymes effectively blocks gene expression and replication of human cytomegalovirus

A ribozyme (M1GS RNA) constructed from the catalytic RNA subunit of RNase P from Escherichia coli was used to target the overlapping region of two human cytomegalovirus (HCMV) mRNAs, which encode for the viral essential protease (PR) and capsid assembly proteins (AP), respectively. The results show a reduction of >80% in the expression levels of PR and AP and an inhibition of approximately 2000-fold of viral growth in cells that stably expressed the ribozyme. In comparison, <10% reduction in the expression of the targets and viral growth was found in cells that either did not express the ribozyme or produced a "disabled" ribozyme carrying mutations that abolished its catalytic activity. Examination of replication of the virus in the ribozyme-expressing cells indicates that packaging of the viral genomic DNA into capsids is blocked, and suggests that the antiviral effects are because the ribozyme specifically inhibits the AP and PR expression and, consequently, abolishes viral capsid formation and growth. Our results show that RNase P ribozymes are highly effective in blocking HCMV growth by targeting the PR and AP mRNAs and demonstrate the feasibility to use these ribozymes in gene therapy for antiviral applications.

Inhibition of Escherichia coli RNase P by oligonucleotide directed misfolding of RNA

Oligonucleotide directed misfolding of RNA (ODMiR) uses short oligonucleotides to inhibit RNA function by exploiting the ability of RNA to fold into different structures with similar free energies. It is shown that the 2'-O-methyl oligonucleotide, m(CAGCCUACCCGG), can trap Escherichia coli RNase P RNA (M1 RNA) in a nonfunctional structure in a transcription mixture containing RNase P protein (C5 protein). At about 200 nM, the 12-mer thus inhibits 50% of pre-tRNA processing by RNase P. Roughly 10-fold more 12-mer is required to inhibit RNase P containing full-length, renatured RNase P RNA. Diethyl pyrocarbonate modification in the presence of 12-mer reveals increased modification of sites in and interacting with P4, suggesting a structural rearrangement of a large pseudoknot important for catalytic activity. Thus, the ODMiR method can be applied to RNAs even when folding is facilitated by a cognate protein.

Recognition of the 5' leader of pre-tRNA substrates by the active site of ribonuclease P

The bacterial tRNA processing enzyme ribonuclease P (RNase P) is a ribonucleoprotein composed of a approximately 400 nucleotide RNA and a smaller protein subunit. It has been established that RNase P RNA contacts the mature tRNA portion of pre-tRNA substrates, whereas RNase P protein interacts with the 5' leader sequence. However, specific interactions with substrate nucleotides flanking the cleavage site have not previously been defined. Here we provide evidence for an interaction between a conserved adenosine, A248 in the Escherichia coli ribozyme, and N(-1), the substrate nucleotide immediately 5' of the cleavage site. Specifically, mutations at A248 result in miscleavage of substrates containing a 2' deoxy modification at N(-1). Compensatory mutations at N(-1) restore correct cleavage in both the RNA-alone and holoenzyme reactions, and also rescue defects in binding thermodynamics caused by A248 mutation. Analysis of pre-tRNA leader sequences in Bacteria and Archaea reveals a conserved preference for U at N(-1), suggesting that an interaction between A248 and N(-1) is common among RNase P enzymes. These results provide the first direct evidence for RNase P RNA interactions with the substrate cleavage site, and show that RNA and protein cooperate in leader sequence recognition.

The effect of a single, temperature-sensitive mutation on global gene expression in Escherichia coli

High-density DNA microarrays have been used to explore the genomic profiling of gene expression of a defective Escherichia coli strain with a temperature-sensitive mutation in the protein component of RNase P. A novel gene cluster was discovered in which two of the genes are known substrates of RNase P. The expression pattern of essential genes and gene discovery from intergenic regions, for which other new transcripts are found, are also discussed.

Initiation of tRNA maturation by RNase E is essential for cell viability in E. coli

RNase E, an essential endoribonuclease in Escherichia coli, is involved in 9S rRNA processing, the degradation of many mRNAs, and the processing of the M1 RNA subunit of RNase P. However, the reason that RNase E is required for cell viability is still not fully understood. In fact, recent experiments have suggested that defects in 9S rRNA processing and mRNA decay are not responsible for the lack of cell growth in RNase E mutants. By using several new rne alleles, we have confirmed these observations and have also ruled out that M1 processing by RNase E is required for cell viability. Rather, our data suggest that the critical in vivo role of RNase E is the initiation of tRNA maturation. Specifically, RNase E catalytic activity starts the processing of both polycistronic operons, such as glyW cysT leuZ, argX hisR leuT proM, and lysT valT lysW valZ lysY lysZ lysQ, as well as monocistronic transcripts like pheU, pheV, asnT, asnU, asnV, and asnW. Cleavage by RNase E within a few nucleotides of the mature 3' CCA terminus is required before RNase P and the various 3' --> 5' exonucleases can complete tRNA maturation. All 59 tRNAs tested involved RNase E processing, although some were cleaved more efficiently than others.

La protein and its associated small nuclear and nucleolar precursor RNAs

After transcription by RNA polymerase (pol) III, nascent Pol III transcripts pass through RNA processing, modification, and transport machineries as part of their posttranscriptional maturation process. The first factor to interact with Pol III transcripts is La protein, which binds principally via its conserved N-terminal domain (NTD), to the UUU-OH motif that results from transcription termination. This review includes a sequence Logo of the most conserved region of La and its refined modeling as an RNA recognition motif (RRM). La protects RNAs from 3' exonucleolytic digestion and also contributes to their nuclear retention. The variety of modifications found on La-associated RNAs is reviewed in detail and considered in the contexts of how La may bind the termini of structured RNAs without interfering with recognition by modification enzymes, and its ability to chaperone RNAs through multiple parts of their maturation pathways. The CTD of human La recognizes the 5' end region of nascent RNA in a manner that is sensitive to serine 366 phosphorylation. Although the CTD can control pre-tRNA cleavage by RNase P, a rate-limiting step in tRNASerUGA maturation, the extent to which it acts in the maturation pathway(s) of other transcripts is unknown but considered here. Evidence that a fraction of La resides in the nucleolus together with recent findings that several Pol III transcripts pass through the nucleolus is also reviewed. An imminent goal is to understand how the bipartite RNA binding, intracellular trafficking, and signal transduction activities of La are integrated with the maturation pathways of the various RNAs with which it associates.

Inhibition of Escherichia coli viability by external guide sequences complementary to two essential genes

Narrow spectrum antimicrobial activity has been designed to reduce the expression of two essential genes, one coding for the protein subunit of RNase P (C5 protein) and one for gyrase (gyrase A). In both cases, external guide sequences (EGS) have been designed to complex with either mRNA. Using the EGS technology, the level of microbial viability is reduced to less than 10% of the wild-type strain. The EGSs are additive when used together and depend on the number of nucleotides paired when attacking gyrase A mRNA. In the case of gyrase A, three nucleotides unpaired out of a 15-mer EGS still favor complete inhibition by the EGS but five unpaired nucleotides do not.

Verification of phylogenetic predictions in vivo and the importance of the tetraloop motif in a catalytic RNA

M1 RNA, the catalytic subunit of Escherichia coli RNase P, forms a secondary structure that includes five sequence variants of the tetraloop motif. Site-directed mutagenesis of the five tetraloops of M1 RNA, and subsequent steady-state kinetic analysis in vitro, with different substrates in the presence and absence of the protein cofactor, reveal that (i) certain mutants exhibit defects that vary in a substrate-dependent manner, and that (ii) the protein cofactor can correct the mutant phenotypes in vitro, a phenomenon that is also substrate dependent. Thermal denaturation curves of tetraloop mutants that exhibit kinetic defects differ from those of wild-type M1 RNA. Although the data collected in vitro underscore the importance of the tetraloop motif to M1 RNA function and structure, three of the five tetraloops we examined in vivo are essential for the function of E. coli RNase P. The kinetic data in vitro are not in total agreement with previous phylogenetic predictions but the data in vivo are, as only mutants in those tetraloops proposed to be involved in tertiary interactions fail to complement in vivo. Therefore, the tetraloop motif is critical for the stabilization of the structure of M1 RNA and essential to RNase P function in the cell.

Nucleolar localization of early tRNA processing

There is little information as to the location of early tRNA biosynthesis. Using fluorescent in situ hybridization in the budding yeast, Saccharomyces cerevisiae, examples of nuclear pre-tRNAs are shown to reside primarily in the nucleoli. We also probed the RNA subunit of RNase P. The majority of the signal from RNase P probes was nucleolar, with less intense signals in the nucleoplasm. These results demonstrate that a major portion of the tRNA processing pathway is compartmentalized in nucleoli with rRNA synthesis and ribosomal assembly. The spatial juxtaposition suggests the possibility of direct coordination between tRNA and ribosome biosynthesis.

Phenotypic conversion of drug-resistant bacteria to drug sensitivity

Plasmids that contain synthetic genes coding for small oligoribonucleotides called external guide sequences (EGSs) have been introduced into strains of Escherichia coli harboring antibiotic resistance genes. The EGSs direct RNase P to cleave the mRNAs transcribed from these genes thereby converting the phenotype of drug-resistant cells to drug sensitivity. Increasing the EGS-to-target mRNA ratio by changing gene copy number or the number of EGSs complementary to different target sites enhances the efficiency of the conversion process. We demonstrate a general method for the efficient phenotypic conversion of drug-resistant bacterial cultures.