Plant dicistronic tRNA-snoRNA genes: a new mode of expression of the small nucleolar RNAs processed by RNase Z

Small nucleolar RNAs (snoRNAs) guiding modifications of ribosomal RNAs and other RNAs display diverse modes of gene organization and expression depending on the eukaryotic system: in animals most are intron encoded, in yeast many are monocistronic genes and in plants most are polycistronic (independent or intronic) genes. Here we report an unprecedented organization: plant dicistronic tRNA-snoRNA genes. In Arabidopsis thaliana we identified a gene family encoding 12 novel box C/D snoRNAs (snoR43) located just downstream from tRNA(Gly) genes. We confirmed that they are transcribed, probably from the tRNA gene promoter, producing dicistronic tRNA(Gly)-snoR43 precursors. Using transgenic lines expressing a tagged tRNA-snoR43.1 gene we show that the dicistronic precursor is accurately processed to both snoR43.1 and tRNA(Gly). In addition, we show that a recombinant RNase Z, the plant tRNA 3' processing enzyme, efficiently cleaves the dicistronic precursor in vitro releasing the snoR43.1 from the tRNA(Gly). Finally, we describe a similar case in rice implicating a tRNA(Met-e) expressed in fusion with a novel C/D snoRNA, showing that this mode of snoRNA expression is found in distant plant species.     

The evolution of the RNase P- and RNase MRP-associated RNAs: Phylogenetic analysis and nucleotide substitution rate

We report a detailed evolutionary study of the RNase P- and RNase MRP- associated RNAs. The analyses were performed on all the available complete sequences of RNase MRP (vertebrates, yeast, plant), nuclear RNase P (vertebrates, yeast), and mitochondrial RNase P (yeast) RNAs. For the first time the phylogenetic distance between these sequences and the nucleotide substitution rates have been quantitatively measured. The analyses were performed by considering the optimal multiple alignments obtained mostly by maximizing similarity between primary sequences. RNase P RNA and MRP RNA display evolutionary dynamics following the molecular clock. Both have similar rates and evolve about one order of magnitude faster than the corresponding small rRNA sequences which have been, so far, the most common gene markers used for phylogeny. However, small rRNAs evolve too slowly to solve close phylogenetic relationships such as those between mammals. The quicker rate of RNase P and MRP RNA allowed us to assess phylogenetic relationships between mammals and other vertebrate species and yeast strains. The phylogenetic data obtained with yeasts perfectly agree with those obtained by functional assays, thus demonstrating the potential offered by this approach for laboratory experiments. Correspondence to: E. Sbisà     

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.     

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.     

Type A and B RNase P RNAs are interchangeable in vivo despite substantial biophysical differences

We show that structural type A and B bacterial ribonuclease P (RNase P) RNAs can fully replace each other in vivo despite the many reported differences in their biogenesis, biochemical/biophysical properties and enzyme function in vitro. Our findings suggest that many of the reported idiosyncrasies of type A and B enzymes either do not reflect the in vivo situation or are not crucial for RNase P function in vivo, at least under standard growth conditions. The discrimination of mature tRNA by RNase P, so far thought to prevent product inhibition of the enzyme in the presence of a large cellular excess of mature tRNA relative to the precursor form, is apparently not crucial for RNase P function in vivo.     

Stimulation of bull seminal RNase by various basic proteins

The activity of purified bull seminal RNase was markedly stimulated by various basic proteins. At the half concentration of substrate RNA, basic proteins such as histones, high-mobility group chromosomal proteins and cytochrome c stimulated the enzyme activity 4-6 fold. Other non-basic proteins such as bovine serum albumin and human gamma-globulin were far less effective. In addition to enzyme-stimulating activity, basic proteins showed a marked enzyme-stabilizing activity, indicating the presence of a strong interaction between the enzyme and basic proteins.     

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 functional genomics approach to the mode of action of apratoxin A

The cyanobacterial metabolite apratoxin A (1) demonstrates potent cytotoxicity against tumor cell lines by a hitherto unknown mechanism. We have used functional genomics to elucidate the molecular basis for this activity. Gene expression profiling and DNA content analysis showed that apratoxin A induces G1-phase cell cycle arrest and apoptosis. Cell-based functional assays with a genome-wide collection of expression cDNAs showed that ectopic induction of fibroblast growth factor receptor (FGFR) signaling attenuates the apoptotic activity of apratoxin A. This natural product inhibited phosphorylation and activation of STAT3, a downstream effector of FGFR signaling. It also caused defects in FGF-dependent processes during zebrafish development, with concomitant reductions in expression levels of the FGF target gene mkp3. We conclude that apratoxin A mediates its antiproliferative activity through the induction of G1 cell cycle arrest and an apoptotic cascade, which is at least partially initiated through antagonism of FGF signaling via STAT3.     

A general approach to high-yield biosynthesis of chimeric RNAs bearing various types of functional small RNAs for broad applications

RNA research and therapy relies primarily on synthetic RNAs. We employed recombinant RNA technology toward large-scale production of pre-miRNA agents in bacteria, but found the majority of target RNAs were not or negligibly expressed. We thus developed a novel strategy to achieve consistent high-yield biosynthesis of chimeric RNAs carrying various small RNAs (e.g. miRNAs, siRNAs and RNA aptamers), which was based upon an optimal noncoding RNA scaffold (OnRS) derived from tRNA fusion pre-miR-34a (tRNA/mir-34a). Multi-milligrams of chimeric RNAs (e.g. OnRS/miR-124, OnRS/GFP-siRNA, OnRS/Neg (scrambled RNA) and OnRS/MGA (malachite green aptamer)) were readily obtained from 1 l bacterial culture. Deep sequencing analyses revealed that mature miR-124 and target GFP-siRNA were selectively released from chimeric RNAs in human cells. Consequently, OnRS/miR-124 was active in suppressing miR-124 target gene expression and controlling cellular processes, and OnRS/GFP-siRNA was effective in knocking down GFP mRNA levels and fluorescent intensity in ES-2/GFP cells and GFP-transgenic mice. Furthermore, the OnRS/MGA sensor offered a specific strong fluorescence upon binding MG, which was utilized as label-free substrate to accurately determine serum RNase activities in pancreatic cancer patients. These results demonstrate that OnRS-based bioengineering is a common, robust and versatile strategy to assemble various types of small RNAs for broad applications.     

A role for the intersubunit disulfides of seminal RNase in the mechanism of its antitumor action.

The dimeric structure of seminal ribonuclease (BS-RNase) is maintained by noncovalent interactions and by two intersubunit disulfide bridges. Another unusual feature of this enzyme is its antitumour action, consisting in a cytotoxic activity selective for malignant cells. This cytotoxic action is exerted when the protein reaches the cytosol of the affected cells, where it degrades ribosomal RNA, thus blocking protein synthesis and leading cells to death. The current model proposed for the mechanism of antitumour action of BS-RNase is based on the ability of the protein to resist the neutralizing action of the cytosolic RNase inhibitor, a resistance due to the dimeric structure of the enzyme. Monomeric RNases, and monomeric derivatives of BS-RNase, are strongly bound by the inhibitor and inactive as antitumor agents. Here we report on monomeric derivatives of BS-RNase that, although strongly inhibited by the cytosolic RNase inhibitor, are cytotoxic towards malignant cells. These monomers are produced by reductive cleavage of the intersubunit disulfides of the native, dimeric protein followed by linking the exposed sulfhydryls to small thiols through formation of mixed disulfides. We found that sulfhydryls from cell monolayers and cell membranes can attack these mixed disulfides in the monomeric derivatives, and reconstitute, through sulfhydryl-disulfide interchange reactions, the native dimeric protein, which is internalized as such, and displays its antitumour action.     

The mode of action of divalent cations on the RNase catalyzed hydrolysis of RNA and uridylyl (3'-5') uridine

Pseudo first order rate constants (k′) have been measured for the RNase A catalyzed hydrolysis of uridylyl (3′–5′) uridine at several ionic strengths and compositions. The k′ values are independent of Mg²⁺ concentration between 0 and 10 mM. This shows that for hydrolysis of RNA, in which Mg²⁺ concentration does change k′, the perturbation must be through binding of Mg²⁺ to the substrate RNA rather than to the enzyme RNase.     

Efficient reduction of target RNAs by small interfering RNA and RNase H-dependent antisense agents. A comparative analysis

RNA interference can be considered as an antisense mechanism of action that utilizes a double-stranded RNase to promote hydrolysis of the target RNA. We have performed a comparative study of optimized antisense oligonucleotides designed to work by an RNA interference mechanism to oligonucleotides designed to work by an RNase H-dependent mechanism in human cells. The potency, maximal effectiveness, duration of action, and sequence specificity of optimized RNase H-dependent oligonucleotides and small interfering RNA (siRNA) oligonucleotide duplexes were evaluated and found to be comparable. Effects of base mismatches on activity were determined to be position-dependent for both siRNA oligonucleotides and RNase H-dependent oligonucleotides. In addition, we determined that the activity of both siRNA oligonucleotides and RNase H-dependent oligonucleotides is affected by the secondary structure of the target mRNA. To determine whether positions on target RNA identified as being susceptible for RNase H-mediated degradation would be coincident with siRNA target sites, we evaluated the effectiveness of siRNAs designed to bind the same position on the target mRNA as RNase H-dependent oligonucleotides. Examination of 80 siRNA oligonucleotide duplexes designed to bind to RNA from four distinct human genes revealed that, in general, activity correlated with the activity to RNase H-dependent oligonucleotides designed to the same site, although some exceptions were noted. The one major difference between the two strategies is that RNase H-dependent oligonucleotides were determined to be active when directed against targets in the pre-mRNA, whereas siRNAs were not. These results demonstrate that siRNA oligonucleotide- and RNase H-dependent antisense strategies are both valid strategies for evaluating function of genes in cell-based assays.     

Structure of the UGAGAU hexaloop that braces Bacillus RNase P for action

Long-range interactions involving the P5.1 hairpin of Bacillus RNase P RNA are thought to form a structural truss to support RNA folding and activity. We determined the structure of this element by NMR and refined the structure using residual dipolar couplings from a sample weakly oriented in a dilute liquid crystalline mixture of polyethylene glycol and hexanol. Dipolar coupling refinement improved the global precision of the structure from 1.5 to 1.2 A (to the mean), revised the bend angle between segments of the P5.1 stem and corroborated the structure of the loop region. The UGAGAU hexaloop of P5.1 contains two stacks of bases on opposite sides of the loop, distinguishing it from GNRA tetraloops. The unusual conformation of the juxtaposed uracil residues within the hexaloop may explain their requirement in transactivation assays.     

Action of RNase II and polynucleotide phosphorylase against RNAs containing stem-loops of defined structure

The 3'-->5' exoribonucleases, RNase II and polynucleotide phosphorylase (PNPase), play an essential role in degrading fragments of mRNA generated by prior cleavages by endonucleases. We have assessed the ability of small RNA substrates containing defined stem-loop structures and variable 3' extensions to impede the exonucleolytic activity of these enzymes. We find that stem-loops containing five G-C base pairs do not block either enzyme; in contrast, more stable stem-loops of 7, 9, or 11 bp block the processive action of both enzymes. Under conditions where enzyme activity is limiting, both enzymes stall and dissociate from their substrates six to nine residues, on average, from the base of a stable stem-loop structure. Our data provide a clear mechanistic explanation for the previous observation that RNase II and PNPase behave as functionally redundant.     

Mechanism of action of RNase T. II. A structural and functional model of the enzyme

A detailed structural and functional model of E. coli RNase T was generated based on sequence analysis, homology modeling, and experimental observation. In the accompanying article, three short sequence segments (nucleic acid binding sequences (NBS)) important for RNase T substrate binding were identified. In the model, these segments cluster to form a positively charged surface patch. However, this patch is on the face of the RNase T monomer opposite the DEDD catalytic center. We propose that by dimerization, the NBS patch from one subunit is brought to the vicinity of the DEDD center of the second monomer to form a fully functional RNase T active site. In support of this model, mutagenetic studies show that one NBS1 residue, Arg(13), sits at the catalytic center despite being on the opposite side of the monomer. Second, the complementarity of the RNase T subunits through the formation of homodimers was demonstrated by reconstitution of partial RNase T activity from monomers derived from two inactive mutant proteins, one defective in catalysis and one in substrate binding. These data explain why RNase T must dimerize to function. The model provides a detailed framework on which to explain the mechanism of action of RNase T.