Methylphosphate cap structure increases the stability of 7SK, B2 and U6 small RNAs in Xenopus oocytes.

We studied the role of the methylphosphate cap structure in the stability and nucleocytoplasmic transport by microinjecting U6, 7SK and B2 RNAs into the Xenopus oocytes. In every case, the methylphosphate capped RNAs were 3 to 9 times more stable than the uncapped RNAs. When a methylphosphate cap structure was placed on human H1 RNA which is normally not capped, its stability was improved 2-7 fold. These data show that the methylphosphate cap enhances the stability of 7SK, B2, H1 and U6 RNAs. The methylphosphate-capped 7SK RNA was transported into the nucleus from cytoplasm, but remained in the nucleus when injected into the nucleus; in this respect, 7SK RNA exhibited properties previously shown for U6 RNA. Both U6 and 7SK RNAs with ppp on their 5' ends were transported from cytoplasm to the nucleus suggesting that the methylphosphate cap structure is not required for transport of these RNAs across the nuclear membrane.     

Regulation of small RNA stability: methylation and beyond

As central components of RNA silencing, small RNAs play diverse and important roles in many biological processes in eukaryotes. Aberrant reduction or elevation in the levels of small RNAs is associated with many developmental and physiological defects. The in vivo levels of small RNAs are precisely regulated through modulating the rates of their biogenesis and turnover. 2′-O-methylation on the 3′ terminal ribose is a major mechanism that increases the stability of small RNAs. The small RNA methyltransferase HUA ENHANCER1 (HEN1) and its homologs methylate microRNAs and small interfering RNAs (siRNAs) in plants, Piwi-interacting RNAs (piRNAs) in animals, and siRNAs in Drosophila. 3′ nucleotide addition, especially uridylation, and 3′-5′ exonucleolytic degradation are major mechanisms that turnover small RNAs. Other mechanisms impacting small RNA stability include complementary RNAs, cis-elements in small RNA sequences and RNA-binding proteins. Investigations are ongoing to further understand how small RNA stability impacts their accumulation in vivo in order to improve the utilization of RNA silencing in biotechnology and therapeutic applications.     

5' cloverleaf in poliovirus RNA is a cis-acting replication element required for negative-strand synthesis

A cloverleaf structure at the 5' terminus of poliovirus RNA binds viral and cellular proteins. To examine the role of the cloverleaf in poliovirus replication, we determined how cloverleaf mutations affected the stability, translation and replication of poliovirus RNA in HeLa S10 translation-replication reactions. Mutations within the cloverleaf destabilized viral RNA in these reactions. Adding a 5' 7-methyl guanosine cap fully restored the stability of the mutant RNAs and had no effect on their translation. These results indicate that the 5' cloverleaf normally protects uncapped poliovirus RNA from rapid degradation by cellular nucleases. Preinitiation RNA replication complexes formed with the capped mutant RNAs were used to measure negative-strand synthesis. Although the mutant RNAs were stable and functional mRNAs, they were not active templates for negative-strand RNA synthesis. Therefore, the 5' cloverleaf is a multifunctional cis-acting replication element required for the initiation of negative-strand RNA synthesis. We propose a replication model in which the 5' and 3' ends of viral RNA interact to form a circular ribonucleoprotein complex that regulates the stability, translation and replication of poliovirus RNA.     

Influence of RNA structural stability on the RNA chaperone activity of the Escherichia coli protein StpA

Proteins with RNA chaperone activity are able to promote folding of RNA molecules by loosening their structure. This RNA unfolding activity is beneficial when resolving misfolded RNA conformations, but could be detrimental to RNAs with low thermodynamic stability. In order to test this idea, we constructed various RNAs with different structural stabilities derived from the thymidylate synthase (td) group I intron and measured the effect of StpA, an Escherichia coli protein with RNA chaperone activity, on their splicing activity in vivo and in vitro. While StpA promotes splicing of the wild-type td intron and of mutants with wild-type-like stability, splicing of mutants with a lower structural stability is reduced in the presence of StpA. In contrast, splicing of an intron mutant, which is not destabilized but which displays a reduced population of correctly folded RNAs, is promoted by StpA. The sensitivity of an RNA towards StpA correlates with its structural stability. By lowering the temperature to 25°C, a temperature at which the structure of these mutants becomes more stable, StpA is again able to stimulate splicing. These observations clearly suggest that the structural stability of an RNA determines whether the RNA chaperone activity of StpA is beneficial to folding.     

Structure and function of eukaryotic Ribonuclease P RNA

Ribonuclease P (RNase P) is the ribonucleoprotein endonuclease that processes the 5' ends of precursor tRNAs. Bacterial and eukaryal RNase P RNAs had the same primordial ancestor; however, they were molded differently by evolution. RNase P RNAs of eukaryotes, in contrast to bacterial RNAs, are not catalytically active in vitro without proteins. By comparing the bacterial and eukaryal RNAs, we can begin to understand the transitions made between the RNA and protein-dominated worlds. We report, based on crosslinking studies, that eukaryal RNAs, although catalytically inactive alone, fold into functional forms and specifically bind tRNA even in the absence of proteins. Based on the crosslinking results and crystal structures of bacterial RNAs, we develop a tertiary structure model of the eukaryal RNase P RNA. The eukaryal RNA contains a core structure similar to the bacterial RNA but lacks specific features that in bacterial RNAs contribute to catalysis and global stability of tertiary structure.     

Biochemical research on oogenesis: Oocytes and liver cells of the teleost fish Tinca tinca contain different kinds of 5S RNA

Previtellogenic oocytes of Tinca tinca accumulate very large amounts of 5S RNA. We show here that 5S RNA stored in oocytes differs from liver 5S RNA in 3 out of 120 nucleotides. Liver and oocyte 5S RNAs, therefore, are produced by different genes. Both kinds of 5S genes are active in oocytes. However, only 5S RNA of the oocyte type accumulates in these cells. In Tinca tinca as in Xenopus laevis, oocyte-type and somatic-type 5S RNAs differ by three properties, ie., primary structure, conformation, and metabolic stability. Nucleotide substitutions occur in different positions in oocyte and somatic 5S RNAs of Tinca tinca and Xenopus laevis. We do not understand how different sets of nucleotide substitutions confer to 5S RNAs of both species similar properties in vivo, namely, increased metabolic stability.     

Effect of heat shock on the synthesis of low molecular weight RNAs in drosophila: Accumulation of a novel form of 5S RNA

The synthesis and stability of low molecular weight RNAs following heat shock in Drosophila melanogaster cell cultures have been examined. When cultures are raised from 25°C to 37°C, the synthesis of tRNA and at least two other low molecular weight RNAs continues at the 25°C rate. 5.8S ribosomal RNA and most of the low molecular weight nuclear RNAs are not synthesized. The synthesis of 5S ribosomal RNA is greatly reduced. A large amount of an RNA of about 135 nucleotides in length accumulates at 37°C. Nucleotide sequence analysis reveals that this RNA is a novel form of 5S RNA with approximately 15 additional nucleotides at its 3′ end.     

Synthesis, incorporation efficiency, and stability of disulfide bridged functional groups at RNA 5'-ends

Modified guanosine monophosphates have been employed to introduce various functional groups onto RNA 5'-ends. Applications of modified RNA 5'-ends include the generation of functionalized RNA libraries for in vitro selection of catalytic RNAs, the attachment of photoaffinity-tags for mapping RNA-protein interactions or active sites in catalytic RNAs, or the nonradioactive labeling of RNA molecules with fluorescent groups. While in these and in similar applications a stable linkage is desired, in selection experiments for generating novel catalytic RNAs it is often advantageous that a functional group is introduced reversibly. Here we give a quantitative comparison of the different strategies that can be applied to reversibly attach functional groups via disulfide bonds to RNA 5'-ends. We report the preparation of functional groups with disulfide linkages, their incorporation efficiency into an RNA library, and their stability under various conditions.     

ADAR-mediated RNA editing in non-coding RNA sequences

Adenosine to inosine (A-to-I) RNA editing is the most abundant editing event in animals. It converts adenosine to inosine in double-stranded RNA regions through the action of the adenosine deaminase acting on RNA (ADAR) proteins. Editing of pre-mRNA coding regions can alter the protein codon and increase functional diversity. However, most of the A-to-I editing sites occur in the non-coding regions of pre-mRNA or mRNA and non-coding RNAs. Untranslated regions (UTRs) and introns are located in pre-mRNA non-coding regions, thus A-to-I editing can influence gene expression by nuclear retention, degradation, alternative splicing, and translation regulation. Non-coding RNAs such as microRNA (miRNA), small interfering RNA (siRNA) and long non-coding RNA (lncRNA) are related to pre-mRNA splicing, translation, and gene regulation. A-to-I editing could therefore affect the stability, biogenesis, and target recognition of non-coding RNAs. Finally, it may influence the function of non-coding RNAs, resulting in regulation of gene expression. This review focuses on the function of ADAR-mediated RNA editing on mRNA non-coding regions (UTRs and introns) and non-coding RNAs (miRNA, siRNA, and lncRNA).     

Stepwise conversion of a mesophilic to a thermophilic ribozyme

A fundamental question in RNA folding is the mechanism of thermodynamic stability. We investigated the equilibrium folding of a series of sequence variants in which one to three motifs of a 255-nucleotide mesophilic ribozyme were substituted with the corresponding motifs from its thermophilic homologue. Substitution of three crucial motifs individually or in groups results in a continual increase in the stability and folding cooperativity in a stepwise fashion. We find an unexpected relationship between stability and folding cooperativity. Without changing the folding cooperativity, RNAs having a similar native structure can only achieve moderate change in stability and likewise, without changing stability, RNAs having a similar native structure can only achieve moderate change in folding cooperativity. This intricate relationship must be included in the predictions of tertiary RNA stability.