Reactions of the intervening sequence of the Tetrahymena ribosomal ribonucleic acid precursor: pH dependence of cyclization and site-specific hydrolysis

During self-splicing of the Tetrahymena rRNA precursor, the intervening sequence (IVS) is excised as a unique linear molecule and subsequently cyclized. Cyclization involves formation of a phosphodiester bond between the 3' end and nucleotide 16 of the linear RNA, with release of an oligonucleotide containing the first 15 nucleotides. We find that the rate of cyclization is independent of pH in the range 4.7-9.0. A minor site of cyclization at nucleotide 20 is characterized. Cyclization to this site becomes more prominent at higher pHs, although under all conditions examined it is minor compared to cyclization at nucleotide 16. The circular IVS RNAs are unstable, undergoing hydrolysis at the phosphodiester bond that was formed during cyclization. We find that the rate of site-specific hydrolysis is first order with respect to hydroxide ion concentration, with a rate constant 10(3)-10(4)-fold greater than that of hydrolysis of strained cyclic phosphate esters. On the basis of these results, we propose that circular IVS RNA hydrolysis involves direct attack of OH- on the phosphate at the ligation junction, that particular phosphate being made particularly reactive by the folding of the RNA molecule. Cyclization, on the other hand, appears to occur by direct attack of the 3'-terminal hydroxyl group of the linear IVS RNA without prior deprotonation.     

Self-catalyzed cyclization of the intervening sequence RNA of Tetrahymena: inhibition by intercalating dyes.

The intervening sequence (IVS) excised from the pre-rRNA of Tetrahymena undergoes a self-catalyzed cleavage-ligation reaction to form a covalently closed circular RNA. This cyclization reaction is kinetically inhibited by ethidium bromide (50% inhibition at 22 +/- 14 microM, greater than 99% inhibition at 53 +/- 16 microM for a 20 minute reaction). The dye does not alter the sites of the cyclization reaction, but it does increase the relative amount of reaction at a minor site 19 nucleotides from the 5' end of the IVS. The reversibility of the inhibition and the relative inhibitory strength of acridine orange, ethidium and proflavine suggest that inhibition is due to intercalation of the dye in functionally important secondary or tertiary structures of the IVS. The concentration of dye required to inhibit cyclization is much higher than expected from the known binding constants of such dyes to tRNA. At high Mg2+ to Na+ ratios, conditions which should stabilize RNA structure, a subpopulation of the IVS RNA molecules is resistant to ethidium inhibition, even at 200 microM ethidium. These data are interpreted as reflecting two conformational isomers of the IVS that differ in their reactivity and in their sensitivity to dye binding.     

Reactivity of modified ribose moieties of guanosine: new cleavage reactions mediated by the IVS of Tetrahymena precursor rRNA.

An RNA molecule consisting of the 5' exon and intervening sequence (IVS) of Tetrahymena precursor rRNA was oxidized with sodium periodate to convert the ribose moiety of the 3' terminal guanosine into a dialdehyde form. The modified RNA undergoes a specific cleavage reaction at the 5' splice site, but has no apparent cyclization activity. This novel reaction mediated by the IVS RNA is pH dependent over the range 6.5-8.5 and leaves a 5' phosphate and a 3'-OH at the newly created termini. The dialdehyde form of monomer guanosine is also capable of causing a specific cleavage reaction at the 5' splice site although the nucleotide is not covalently attached to the IVS RNA in the final product. These and other findings described in this report suggest that the cis diol of the intact ribose moiety of guanosine is not an absolute requirement for the IVS-mediated reactions.     

Sequence requirements for self-splicing of the Tetrahymena thermophila pre-ribosomal RNA.

The sequence requirements for splicing of the Tetrahymena pre-rRNA have been examined by altering the rRNA gene to produce versions that contain insertions and deletions within the intervening sequence (IVS). The altered genes were transcribed and the RNA tested for self-splicing in vitro. A number of insertions (8-54 nucleotides) at three locations had no effect on self-splicing activity. Two of these insertions, located at a site 5 nucleotides preceding the 3'-end of the IVS, did not alter the choice of the 3' splice site. Thus the 3' splice site is not chosen by its distance from a fixed point within the IVS. Analysis of deletions constructed at two sites revealed two structures, a hairpin loop and a stem-loop, that are entirely dispensable for IVS excision in vitro. Three other regions were found to be necessary. The regions that are important for self-splicing are not restricted to the conserved sequence elements that define this class of intervening sequences. The requirement for structures within the IVS for pre-rRNA splicing is in sharp contrast to the very limited role of IVS structure in nuclear pre-mRNA splicing.     

One binding site determines sequence specificity of Tetrahymena pre-rRNA self-splicing, trans-splicing, and RNA enzyme activity

The specificity of reactions catalyzed by the Tetrahymena pre-rRNA intervening sequence (IVS) was studied using site-specific mutagenesis. Two sequences required for 5' splice-site selection during self-splicing were defined. Single-base changes in either a 5' exon sequence or a 5' exon-binding site within the IVS disrupt their ability to pair and result in inefficient or inaccurate splicing. Combinations that restore complementarity suppress the effect of the single-base changes. Sequence alterations in the 5' exon-binding site also change the specificity of two other reactions: intermolecular exon ligation (trans-splicing) and the enzymatic nucleotidyltransferase activity of the IVS RNA. Thus the substrate specificity of an RNA enzyme can be changed in a manner predictable by the rules of Watson-Crick base-pairing.     

Guanosine binding required for cyclization of the self-splicing intervening sequence ribonucleic acid from Tetrahymena thermophila

We have converted the intramolecular cyclization reaction of the self-splicing intervening sequence (IVS) ribonucleic acid (RNA) from Tetrahymena thermophila into an intermolecular guanosine addition reaction. This was accomplished by selectively removing the 3'-terminal nucleotide by oxidation and beta-elimination; the beta-eliminated IVS thereby is no longer capable of reacting with itself. However, under cyclization conditions, a free guanosine molecule can make a nucleophilic attack at the normal cyclization site. We have used this guanosine addition reaction as a model system for a Michaelis-Menten kinetic analysis of the guanosine binding site involved in cyclization. The results indicate that functional groups on the guanine that are used in a G-C Watson-Crick base pair are important for the cyclization reaction. This is the same result that was obtained for the guanosine binding site involved in splicing [Bass, B. L., & Cech, T. R. (1984) Nature (London) 308, 820-826]. Unlike splicing, however, certain additional nucleotides 5' to the guanosine moiety make significant binding contributions. We conclude that the guanosine binding site in cyclization is similar to, but not identical with, the guanosine binding site in splicing. The same binding interactions used in cyclization could help align the 3' splice site of the rRNA precursor for exon ligation. We also report that the phosphodiester bond at the cyclization site is susceptible to a pH-dependent hydrolysis reaction; the phosphodiester bond is somehow activated toward attack by the 3'hydroxyl of a guanosine molecule or by a hydroxyl ion.     

Characterization of an authentic intermediate in the self-splicing process of ribosomal precursor RNA in macronuclei of Tetrahymena thermophila.

We have characterized a 1.5 kb RNA species in T. thermophila macronuclei previously found in vivo and including intron sequences linked to the 3' exon. This IVS-3' exon RNA could be detected in gels as a discrete molecule only after denaturation of nuclear RNA. After addition of 32P-GTP, as splicing cofactor in a nuclear in vitro system, the IVS-3' exon RNA was labeled at its 5' terminus, as was the by-product of splicing, the excised IVS RNA. The time course of labeling indicates that the IVS-3' exon RNA acts like a reaction intermediate and specifically a kinetic precursor to IVS RNA. Partial nuclease digestions showed that the IVS-3' exon RNA and the IVS RNA have the same 5' terminal sequence. In addition the IVS-3' exon RNA can release the 15-mer oligonucleotide cleaved off during circularization of IVS RNA under conditions of high temperature. Taken together, the structural, functional, and kinetic properties of the IVS-3' exon RNA strongly suggest that it represents a previously postulated in vivo intermediate in the splicing pathway.     

5' exon requirement for self-splicing of the Tetrahymena thermophila pre-ribosomal RNA and identification of a cryptic 5' splice site in the 3' exon

The intervening sequence (IVS) of the Tetrahymena thermophila ribosomal RNA precursor undergoes accurate self-splicing in vitro. The work presented here examines the requirement for Tetrahymena rRNA sequences in the 5' exon for the accuracy and efficiency of splicing. Three plasmids were constructed with nine, four and two nucleotides of the natural 5' exon sequence, followed by the IVS and 26 nucleotides of the Tetrahymena 3' exon. RNA was transcribed from these plasmids in vitro and tested for self-splicing activity. The efficiency of splicing, as measured by the production of ligated exons, is reduced as the natural 5' exon sequence is replaced with plasmid sequences. Accurate splicing persists even when only four nucleotides of the natural 5' exon sequence remain. When only two nucleotides of the natural exon remain, no ligated exons are observed. As the efficiency of the normal reaction diminishes, novel RNA species are produced in increasing amounts. The novel RNA species were examined and found to be products of aberrant reactions of the precursor RNA. Two of these aberrant reactions involve auto-addition of GTP to sites six nucleotides and 52 nucleotides downstream from the 3' splice site. The former site occurs just after the sequence GGU, and may indicate the existence of a GGU-binding site within the IVS RNA. The latter site follows the sequence CUCU, which is identical with the four nucleotides preceding the 5' splice site. This observation led to a model where where the CUCU sequence in the 3' exon acts as a cryptic 5' splice site. The model predicted the existence of a circular RNA containing the first 52 nucleotides of the 3' exon. A small circular RNA was isolated and partially sequenced and found to support the model. So, a cryptic 5' splice site can function even if it is located downstream from the 3' splice site. Precursor RNA labeled at its 5' end, presumably by a GTP exchange reaction mediated by the IVS, is also described.     

Mutational analysis of an essential binding site for the U3 snoRNA in the 5' external transcribed spacer of yeast pre-rRNA.

The small nucleolar RNA U3 is essential for viability in yeast. We have previously shown that U3 can be cross-linked in vivo to the pre-rRNA in the 5' external transcribed spacer (ETS), at +470. This ETS region contains 10 nucleotides of perfect complementarity to U3. In a genetic background where the mutated rDNA is the only transcribed rDNA repeat, the deletion of the 10 nt complementary to U3 is lethal. Cells lacking the U3 complementary sequence in pre-rRNA fail to accumulate 18S rRNA: pre-rRNA processing is inhibited at sites A0 in the 5' ETS, A1 at the 5' end of 18S rRNA and A2 in ITS1. We show here that effects on processing at site A0 are specific for U3 and its associated proteins and are not seen on depletion of other snoRNP components. The deletion of the sequence complementary to U3 in the ETS therefore mimics all the known effects of the depletion of U3 in trans. This indicates that we have identified an essential U3 binding site on pre-rRNA, required in cis for the maturation of 18S rRNA.     

Mutational analysis of an essential binding site for the U3 snoRNA in the 5' external transcribed spacer of yeast pre-rRNA.

The small nucleolar RNA U3 is essential for viability in yeast. We have previously shown that U3 can be cross-linked in vivo to the pre-rRNA in the 5' external transcribed spacer (ETS), at +470. This ETS region contains 10 nucleotides of perfect complementarity to U3. In a genetic background where the mutated rDNA is the only transcribed rDNA repeat, the deletion of the 10 nt complementary to U3 is lethal. Cells lacking the U3 complementary sequence in pre-rRNA fail to accumulate 18S rRNA: pre-rRNA processing is inhibited at sites A0 in the 5' ETS, A1 at the 5' end of 18S rRNA and A2 in ITS1. We show here that effects on processing at site A0 are specific for U3 and its associated proteins and are not seen on depletion of other snoRNP components. The deletion of the sequence complementary to U3 in the ETS therefore mimics all the known effects of the depletion of U3 in trans. This indicates that we have identified an essential U3 binding site on pre-rRNA, required in cis for the maturation of 18S rRNA.     

A new interaction between the mouse 5'' external transcribed spacer of pre-rRNA and U3 snRNA detected by psoralen crosslinking.

The first cleavage in mammalian pre-rRNA processing occurs within the 5' external transcribed spacer (ETS). We have recently shown that the U3 snRNP is required for this cleavage reaction, binds to the rRNA precursor, and remains complexed with the downstream processing product after the reaction has been completed (1). Using psoralen crosslinking in mouse cell extract we have detected a new interaction between U3 RNA and the mouse ETS processing substrate and its processed product. The crosslinked sites on both U3 and ETS RNAs have been mapped by RNase H cleavage and primer extension analyses. The crosslinked sites in U3 RNA map to C5, U6, and U8. U8 lies within and C5 and U6 are adjacent to an evolutionarily conserved U3 sequence termed box A'. In the ETS the crosslinked sites are U1012 and U1013, 362 nucleotides downstream from the processing site. Although the crosslinked site is dispensable for the primary processing reaction in vitro, a short conserved sequence just 3' to the cleavage site (nucleotides 650-668) is absolutely required for crosslink formation. We conclude that the interaction between U3 RNA and the 5' ETS detected by psoralen crosslinking may play a role in subsequent step(s) of pre-rRNA processing.     

Ribozyme inhibitors: deoxyguanosine and dideoxyguanosine are competitive inhibitors of self-splicing of the Tetrahymena ribosomal ribonucleic acid precursor

The intervening sequence (IVS) of the Tetrahymena rRNA precursor catalyzes its own splicing. During splicing the 3'-hydroxyl of guanosine is ligated to the 5' terminus of the IVS. One catalytic strategy of the IVS RNA is to specifically bind its guanosine substrate. Deoxyguanosine (dG) and dideoxyguanosine (ddG) are found to be competitive inhibitors of self-splicing. Comparison of the kinetic parameters (Ki = 1.1 mM for dG; Ki = 5.4 mM for ddG; Km = 0.032 mM for guanosine) indicates that the ribose hydroxyls are necessary for optimal binding of guanosine to the RNA. dG is not a substrate for the reaction even at very high concentrations. Thus, in addition to aiding in binding, the 2'-hydroxyl is necessary for reaction of the 3'-hydroxyl. A second catalytic strategy of the IVS RNA is to enhance the reactivity of specific bonds. For example, the phosphodiester bond at the 3' splice site is extremely labile to hydrolysis. We find that dG and ddG, as well as 2'-O-methylguanosine and 3'-O-methylguanosine, reduce hydrolysis at the 3' splice site. These data are consistent with an RNA structure that brings the 5' and 3' splice sites proximal to the guanosine binding site.     

Preribosomal RNA processing in Xenopus oocytes does not include cleavage within the external transcribed spacer as an early step.

Recently it has been reported that U3 snRNA is necessary for: (a) internal cleavage at +651/+657 within the external transcribed spacer (ETS) of mouse precursor ribosomal RNA (pre-rRNA); and (b) cleavage at the 5' end of 5.8S rRNA in Xenopus oocytes. To study if U3 snRNA plays a role at more than one processing site in the same system, we have investigated whether internal cleavage sites exist within the ETS of Xenopus oocyte pre-rRNA. The ETS of Xenopus pre-rRNA contains the consensus sequence for the mammalian early processing site (+651/+657 in mouse pre-rRNA), but freshly prepared RNA from Xenopus oocytes has no cuts in this region. The only putative cleavage sites we found in the ETS of Xenopus oocyte pre-rRNA are a cluster further downstream of the mouse early processing site consensus sequence. This cluster is not homologous to the mouse +651/+657 sites because unlike the latter it is (a) not abolished by disruption of U3 snRNA, (b) not cleaved during early steps of pre-rRNA processing, and (c) lacks sequence similarity to the +651/+657 consensus. Therefore, pre-rRNA of Xenopus oocytes does not cleave within the ETS as an early step in rRNA processing. We conclude that cleavage within the ETS is not an obligatory early step needed for the rest of rRNA maturation.     

Structure analysis of the 5' external transcribed spacer of the precursor ribosomal RNA from Saccharomyces cerevisiae.

Full-length precursor ribosomal RNA molecules were produced in vitro using as a template, a plasmid containing the yeast 35 S pre-rRNA gene under the control of the phage T3 promoter. The higher-order structure of the 5'-external transcribed spacer (5' ETS) sequence in the 35S pre-rRNA molecule was studied using dimethylsulfate, 1-cyclohexyl-3-(2-morpholinoethyl)-carbodiimide metho-p-toluenesulfonate, RNase T1 and RNase V1 as structure-sensitive probes. Modified residues were detected by primer extension. Data produced were used to evaluate several theoretical structure models predicted by minimum free-energy calculations. A model for the entire 5'ETS region is proposed that accommodates 82% of the residues experimentally shown to be in either base-paired or single-stranded structure in the correct configuration. The model contains a high degree of secondary structure with ten stable hairpins of varying lengths and stabilities. The hairpins are composed of the Watson-Crick A.T and G.C pairs plus the non-canonical G.U pairs. Based on a comparative analysis of the 5' ETS sequence from Saccharomyces cerevisiae and Schizosaccharomyces pombe, most of the base-paired regions in the proposed model appear to be phylogenetically supported. The two sites previously shown to be crosslinked to U3 snRNA as well as the previously proposed recognition site for processing and one of the early processing site (based on sequence homology to the vertebrate ETS cleavage site) are located in single-stranded regions in the model. The present folding model for the 5' ETS in the 35 S pre-rRNA molecule should be useful in the investigations of the structure, function and processing of pre-rRNA.     

RNA splicing in Neurospora mitochondria: nuclear mutants defective in both splicing and 3' end synthesis of the large rRNA

We have identified nuclear mutants of Neurospora that are defective in splicing the mitochondrial large rRNA and that accumulate unspliced pre-rRNA (35S RNA). In cyt-4 mutants, the unspliced pre-rRNA contains short 3' end extensions (110 nucleotides) that are not present in pre-rRNAs from the other mutants. This and other characteristics suggest that the cyt-4 mutants may be primarily defective in 3' end synthesis and the RNA splicing defect occurs secondarily as a result of impaired RNA folding. The cyt-4 mutants also accumulate a "short" intron RNA and small exon RNAs that may reflect aberrant RNA cleavages. The 5' end of the short intron is about 285 nucleotides downstream from the 5' splice site at or near the base of the "central hairpin", a putative intermediate in folding of the pre-rRNA. Furthermore, the aberrant cleavage sites are immediately after a six nucleotide sequence (GAUAAU) homologous to the final splice junction (GAU/AAC).     

An in vitro-selected RNA-binding site for the KH domain protein PSI acts as a splicing inhibitor element

P element somatic inhibitor (PSI) is a 97-kDa RNA-binding protein with four KH motifs that is involved in the inhibition of splicing of the Drosophila P element third intron (IVS3) in somatic cells. PSI interacts with a negative regulatory element in the IVS3 5' exon. This element contains two pseudo-5' splice sites, termed F1 and F2. To identify high affinity binding sites for the PSI protein, in vitro selection (SELEX) was performed using a random RNA oligonucleotide pool. Alignment of high affinity PSI-binding RNAs revealed a degenerate consensus sequence consisting of a short core motif of CUU flanked by alternative purines and pyrimidines. Interestingly, this sequence resembles the F2 pseudo-5' splice site in the P element negative regulatory element. Additionally, a negative in vitro selection of PCR-mutagenized P element 5' exon regulatory element RNAs identified two U residues in the F1 and F2 pseudo-5' splice sites as important nucleotides for PSI binding and the U residue in the F2 region is a nearly invariant nucleotide in the consensus SELEX motif. The high affinity PSI SELEX sequence acted as a splicing inhibitor when placed in the context of a P element splicing pre-mRNA in vitro. Data from in vitro splicing assays, UV crosslinking and RNA-binding competition experiments indicates a strong correlation between the binding affinities of PSI for the SELEX sequences and their ability to modulate splicing of P element IVS3 in vitro.     

Self-catalyzed cyclization of the intervening sequence RNA of Tetrahymena: inhibition by methidiumpropyl.EDTA and localization of the major dye binding sites.

The intervening sequence (IVS) excised from the rRNA precursor of Tetrahymena thermophila is converted to a covalently closed circular RNA in the absence of proteins in vitro. This self-catalyzed cyclization reaction is inhibited by the intercalating dye methidiumpropyl.EDTA (MPE; R.P. Hertzberg and P.B. Dervan (1982) J. Am. Chem. Soc. 104, 313-315). The MPE binding sites have been localized by mapping the sites of MPE.Fe(II) cleavage of the IVS RNA. There are three major binding sites within the 414 nucleotide IVS RNA. Two of these sites coincide with the A.B and 9L.2 pairings. These are structural elements that are conserved in all group I introns and are implicated as being functionally important for splicing. We propose that interaction of MPE with these sites is responsible for dye inhibition of cyclization. The reactions of MPE.Fe(II) with an RNA of known structure, tRNAPhe, and with the IVS RNA were studied as a function of temperature, ionic strength and ethidium concentration. Based on the comparison of the reaction with these two RNAs, we conclude that the dye is a very useful probe for structural regions of large RNAs, while it provides more limited structural information about the small, compact tRNA molecule.