Structure of the Tetrahymena ribozyme: base triple sandwich and metal ion at the active site

The Tetrahymena intron is an RNA catalyst, or ribozyme. As part of its self-splicing reaction, this ribozyme catalyzes phosphoryl transfer between guanosine and a substrate RNA strand. Here we report the refined crystal structure of an active Tetrahymena ribozyme in the absence of its RNA substrate at 3.8 A resolution. The 3'-terminal guanosine (omegaG), which serves as the attacking group for RNA cleavage, forms a coplanar base triple with the G264-C311 base pair, and this base triple is sandwiched by three other base triples. In addition, a metal ion is present in the active site, contacting or positioned close to the ribose of the omegaG and five phosphates. All of these phosphates have been shown to be important for catalysis. Therefore, we provide a picture of how the ribozyme active site positions both a catalytic metal ion and the nucleophilic guanosine for catalysis prior to binding its RNA substrate.     

Activation of a cryptic 5' splice site by U1 snRNA

In the course of analyzing 5' splice site mutations in the second intron of Schizosaccharomyces pombe cdc2, we identified a cryptic 5' junction containing a nonconsensus nucleotide at position +2. An even more unusual feature of this cryptic 5' junction was its pattern of activation. By analyzing the profile of splicing products for an extensive series of cdc2 mutants in the presence and absence of compensatory U1 alleles, we have obtained evidence that the natural 5' splice site participates in activation of the cryptic 5' splice site, and that it does so via base pairing to U1 snRNA. Furthermore, the results of follow-up experiments strongly suggest that base pairing between U1 snRNA and the cryptic 5' junction itself plays a dominant role in its activation. Most remarkably, a mutant U1 can activate the cryptic 5' splice site even in the presence of a wild-type sequence at the natural 5' junction, providing unambiguous evidence that this snRNA redirects splicing via base pairing. Although previous work has demonstrated that U5 and U6 snRNAs can activate cryptic 5' splice sites through base pairing interactions, this is the first example in which U1 snRNA has been implicated in the final selection of a cryptic 5' junction.     

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.     

Circle reopening in the Tetrahymena ribozyme resembles site-specific hydrolysis at the 3' splice site.

The Tetrahymena intron, after splicing from its flanking exons, can mediate its own circularization. This is followed by site-specific hydrolysis of the phosphodiester bond formed during the circularization reaction. The structural components involved in recognition of this bond for hydrolysis have not been established. We have made base substitutions to the P9.0 pairing and at the 3'-terminal guanosine residue (G414) of the intron to investigate their effects on circle formation and reopening. We have found that disruption of either P9.0 pairing or binding of the terminal nucleotide result in the formation of a large circle, C-413:5E23 from precursor RNA molecules that have undergone hydrolysis at the 3' splice site. This circle is formed at the phosphodiester bond of the 5'-terminal guanosine residue of the upstream exon via nucleophilic attack by the 3'-terminal nucleotide of the intron. The large circle is novel since it can reopen eight bases downstream from the original circularization junction at a site resembling the normal 3' splice site, restoring a guanosine to the 3' terminus and re-establishing P9.0 pairing. The new 3' terminus of the intron is capable of recircularization at any of the three normal wild-type sites. We conclude that both P9.0 and the 3'-terminal guanosine residue are required for the selection of the phosphodiester bond hydrolysed during circle reopening.     

U-rich tracts enhance 3' splice site recognition in plant nuclei

The process of 5' and 3' splice site definition in plant pre-mRNA splicing differs from that in mammals and yeast. In mammals, splice sites are chosen by their complementarity to U1 snRNA surrounding the /GU at the 5' splice site and by the strength of the pyrimidine tract preceding the AG/ at the 3' splice site; in plants, the 3' intron boundary is defined in a position-dependent manner relative to AU-rich elements within the intron. To determine if uridines are utilized to any extent in plant 3' splice site recognition, uridines in the region preceding the normal (−1) 3' splice site of pea rbcS3A intron 1 were replaced with adenosines. This mutant activates two cryptic 3' splice sites (+62, +95) in the downstream exon, indicating that the uridines in the region immediately preceding the normal (−1) site are essential for recognition. Placement of different length uridine tracts upstream from the cryptic +62 site indicated that a cryptic exonic 3' splice site containing 14 or 10 uridine tracts with a G at −4 can effectively outcompete the normal 3' splice site containing an eight uridine tract with a U at −4. Substitutions at the −4 position demonstrated that the identity of the nucleotide at this position greatly affects 3' splice site selection. It has been concluded that several factors affect competition between these 3' splice sites. These factors include the position of the AU transition point, the strength of the uridine tract immediately preceding the 3' terminal CAG/ and the identity of nucleotide −4.     

Defining a 5' splice site by functional selection in the presence and absence of U1 snRNA 5' end

Pre-mRNA splicing in metazoans is mainly specified by sequences at the termini of introns. We have selected functional 5' splice sites from randomized intron sequences through repetitive rounds of in vitro splicing in HeLa cell nuclear extract. The consensus sequence obtained after one round of selection in normal extract closely resembled the consensus of natural occurring 5' splice sites, suggesting that the selection pressures in vitro and in vivo are similar. After three rounds of selection under competitive splicing conditions, the base pairing potential to the U1 snRNA increased, yielding a G100%U100%R94%A67%G89%U76%R83% intronic consensus sequence. Surprisingly, a nearly identical consensus sequence was obtained when the selection was performed in nuclear extract containing U1 snRNA with a deleted 5' end, suggesting that other factors than the U1 snRNA are involved in 5' splice site recognition. The importance of a consecutive complementarity between the 5' splice site and the U1 snRNA was analyzed systematically in the natural range for in vitro splicing efficiency and complex formation. Extended complementarity was inhibitory to splicing at a late step in spliceosome assembly when pre-mRNA substrates were incubated in normal extract, but favorable for splicing under competitive splicing conditions or in the presence of truncated U1 snRNA where transition from complex A to complex B occurred more rapidly. This suggests that stable U1 snRNA binding is advantageous for assembly of commitment complexes, but inhibitory for the entry of the U4/U6.U5 tri-snRNP, probably due to a delayed release of the U1 snRNP.     

Exonic splicing enhancers contribute to the use of both 3' and 5' splice site usage of rat beta-tropomyosin pre-mRNA

The rat beta-tropomyosin gene encodes two tissue-specific isoforms that contain the internal, mutually exclusive exons 6 (nonmuscle/smooth muscle) and 7 (skeletal muscle). We previously demonstrated that the 3' splice site of exon 6 can be activated by introducing a 9-nt polyuridine tract at its 3' splice site, or by strengthening the 5' splice site to a U1 consensus binding site, or by joining exon 6 to the downstream common exon 8. Examination of sequences within exons 6 and 8 revealed the presence of two purine-rich motifs in exon 6 and three purine-rich motifs in exon 8 that could potentially represent exonic splicing enhancers (ESEs). In this report we carried out substitution mutagenesis of these elements and show that some of them play a critical role in the splice site usage of exon 6 in vitro and in vivo. Using UV crosslinking, we have identified SF2/ASF as one of the cellular factors that binds to these motifs. Furthermore, we show that substrates that have mutated ESEs are blocked prior to A-complex formation, supporting a role for SF2/ASF binding to the ESEs during the commitment step in splicing. Using pre-mRNA substrates containing exons 5 through 8, we show that the ESEs within exon 6 also play a role in cooperation between the 3' and 5' splice sites flanking this exon. The splicing of exon 6 to 8 (i.e., 5' splice site usage of exon 6) was enhanced with pre-mRNAs containing either the polyuridine tract in the 3' splice site or consensus sequence in the 5' splice site around exon 6. We show that the ESEs in exon 6 are required for this effect. However, the ESEs are not required when both the polyuridine and consensus splice site sequences around exon 6 were present in the same pre-mRNA. These results support and extend the exon-definition hypothesis and demonstrate that sequences at the 3' splice site can facilitate use of a downstream 5' splice site. In addition, the data support the hypothesis that ESEs can compensate for weak splice sites, such as those found in alternatively spliced exons, thereby providing a target for regulation.     

Natural base-pairing interactions between 5' splice site and branch site sequences affect mammalian 5' splice site selection.

In the murine gene encoding the neuronal cell adhesion molecule (NCAM), the integrity of the 5' splice site of exon 18 (E18) is essential for regulation of alternative splicing. To further study the contribution of 5' splice site sequences, we used a simple NCAM pre-mRNA containing a portion of E18 fused to E19 and separated by a shortened intron. This RNA is spliced in vitro to produce five sets of lariat intermediates and products, the most abundant set displaying aberrant migration in acrylamide/urea gels. Base pairing interactions between positions +5 and +8 of the intron and positions -3 and -6 from the branch point were responsible for the faster migration of this set of lariat molecules. To test whether the duplex structure forms earlier and contributes to 5' splice site selection, we used NCAM substrates carrying the 5' splice sites of E17 and E18 in competition for the 3' splice site of E19. Mutations upstream of the major branch site improve E18/E19 splicing in NIH3T3 extracts, whereas compensatory mutations at positions +7 and +8 neutralize the effect of branch site mutations and curtail E18/E19 splicing. Our data suggest that duplex formation occurs early and interferes with the assembly of complexes initiated on the 5' splice site of NCAM E18. This novel type of intron interaction may exist in the introns of other mammalian pre-mRNAs.     

Mutations at the guanosine-binding site of the Tetrahymena ribozyme also affect site-specific hydrolysis.

Self-splicing group I introns use guanosine as a nucleophile to cleave the 5' splice site. The guanosine-binding site has been localized to the G264-C311 base pair of the Tetrahymena intron on the basis of analysis of mutations that change the specificity of the nucleophile from G (guanosine) to 2AP (2-aminopurine ribonucleoside) (F. Michel et al. (1989) Nature 342, 391-395). We studied the effect of these mutations (G-U, A-C and A-U replacing G264-C311) in the L-21 ScaI version of the Tetrahymena ribozyme. In this enzymatic system (kcat/Km)G monitors the cleavage step. This kinetic parameter decreased by at least 5 x 10(3) when the G264-C311 base pair was mutated to an A-U pair, while (kcat/Km)2AP increased at least 40-fold. This amounted to an overall switch in specificity of at least 2 x 10(5). The nucleophile specificity (G > 2AP for the G-C and G-U pairs, 2AP > G for the A-U and A-C pairs) was consistent with the proposed hydrogen bond between the nucleotide at position 264 and N1 of the nucleophile. Unexpectedly, the A-U and A-C mutants showed a decrease of an order of magnitude in the rate of ribozyme-catalyzed hydrolysis of RNA, in which H2O or OH- replaces G as the nucleophile, whereas the G-U mutant showed a decrease of only 2-fold. The low hydrolysis rates were not restored by raising the Mg2+ concentration or lowering the temperature. In addition, the mutant ribozymes exhibited a pattern of cleavage by Fe(II)-EDTA indistinguishable from that of the wild type, and the [Mg2+]1/2 for folding of the A-U mutant ribozyme was the same as that of the wild type. Therefore the guanosine-binding site mutations do not appear to have a major effect on RNA folding or stability. Because changing G264 affects the hydrolysis reaction without perturbing the global folding of the RNA, we conclude that the catalytic role of this conserved nucleotide is not limited to guanosine binding.     

Oriented scanning is the leading mechanism underlying 5' splice site selection in mammals

Splice site selection is a key element of pre-mRNA splicing. Although it is known to involve specific recognition of short consensus sequences by the splicing machinery, the mechanisms by which 5' splice sites are accurately identified remain controversial and incompletely resolved. The human F7 gene contains in its seventh intron (IVS7) a 37-bp VNTR minisatellite whose first element spans the exon7-IVS7 boundary. As a consequence, the IVS7 authentic donor splice site is followed by several cryptic splice sites identical in sequence, referred to as 5' pseudo-sites, which normally remain silent. This region, therefore, provides a remarkable model to decipher the mechanism underlying 5' splice site selection in mammals. We previously suggested a model for splice site selection that, in the presence of consecutive splice consensus sequences, would stimulate exclusively the selection of the most upstream 5' splice site, rather than repressing the 3' following pseudo-sites. In the present study, we provide experimental support to this hypothesis by using a mutational approach involving a panel of 50 mutant and wild-type F7 constructs expressed in various cell types. We demonstrate that the F7 IVS7 5' pseudo-sites are functional, but do not compete with the authentic donor splice site. Moreover, we show that the selection of the 5' splice site follows a scanning-type mechanism, precluding competition with other functional 5' pseudo-sites available on immediate sequence context downstream of the activated one. In addition, 5' pseudo-sites with an increased complementarity to U1snRNA up to 91% do not compete with the identified scanning mechanism. Altogether, these findings, which unveil a cell type-independent 5'-3'-oriented scanning process for accurate recognition of the authentic 5' splice site, reconciliate apparently contradictory observations by establishing a hierarchy of competitiveness among the determinants involved in 5' splice site selection.     

The U1 snRNP base pairs with the 5' splice site within a penta-snRNP complex

Recognition of the 5' splice site is an important step in mRNA splicing. To examine whether U1 approaches the 5' splice site as a solitary snRNP or as part of a multi-snRNP complex, we used a simplified in vitro system in which a short RNA containing the 5' splice site sequence served as a substrate in a binding reaction. This system allowed us to study the interactions of the snRNPs with the 5' splice site without the effect of other cis-regulatory elements of precursor mRNA. We found that in HeLa cell nuclear extracts, five spliceosomal snRNPs form a complex that specifically binds the 5' splice site through base pairing with the 5' end of U1. This system can accommodate RNA-RNA rearrangements in which U5 replaces U1 binding to the 5' splice site, a process that occurs naturally during the splicing reaction. The complex in which U1 and the 5' splice site are base paired sediments in the 200S fraction of a glycerol gradient together with all five spliceosomal snRNPs. This fraction is functional in mRNA spliceosome assembly when supplemented with soluble nuclear proteins. The results argue that U1 can bind the 5' splice site in a mammalian preassembled penta-snRNP complex.     

A novel exon mutation in the human beta-hexosaminidase beta subunit gene affects 3' splice site selection.

The molecular basis of a dramatically decreased steady state level of beta-hexosaminidase beta subunit mRNA in a patient with juvenile Sandhoff disease was investigated. Nucleotide sequence analysis of the HEXB gene coding for the beta subunit revealed two single base substitutions, one in exon 2 (A to G, a known polymorphism) and the other in exon 11 (C to T). Analysis of the beta subunit mRNA species demonstrated activation of a cryptic splice site in exon 11 as well as skipping of the exon. A transfection assay using a chimeric gene containing intron 10 flanked by cDNA sequences carrying the mutation confirmed that the single base substitution located at position 8 of exon 11 inhibits the selection of the normal 3' splice site. The results demonstrate a new type of exon mutation affecting 3' splice site selection.     

Specificity from steric restrictions in the guanosine binding pocket of a group I ribozyme

The 3' splice site of group I introns is defined, in part, by base pairs between the intron core and residues just upstream of the splice site, referred to as P9.0. We have studied the specificity imparted by P9.0 using the well-characterized L-21 Scal ribozyme from Tetrahymena by adding residues to the 5' end of the guanosine (G) that functions as a nucleophile in the oligonucleotide cleavage reaction: CCCUCUA5 (S) + NNG <--> CCCUCU + NNGA5. UCG, predicted to form two base pairs in P9.0, reacts with a (kcat/KM) value approximately 10-fold greater than G, consistent with previous results. Altering the bases that form P9.0 in both the trinucleotide G analog and the ribozyme affects the specificity in the manner predicted for base-pairing. Strikingly, oligonucleotides incapable of forming P9.0 react approximately 10-fold more slowly than G, for which the mispaired residues are simply absent. The observed specificity is consistent with a model in which the P9.0 site is sterically restricted such that an energetic penalty, not present for G, must be overcome by G analogs with 5' extensions. Shortening S to include only one residue 3' of the cleavage site (CCCUCUA) eliminates this penalty and uniformly enhances the reactions of matched and mismatched oligonucleotides relative to guanosine. These results suggest that the 3' portion of S occupies the P9.0 site, sterically interfering with binding of G analogs with 5' extensions. Similar steric effects may more generally allow structured RNAs to avoid formation of incorrect contacts, thereby helping to avoid kinetic traps during folding and enhancing cooperative formation of the correct structure.     

Sequestering of the 3' splice site in a theophylline-responsive riboswitch allows ligand-dependent control of alternative splicing

Despite the important role of alternative splicing in various aspects of biological processes, our ability to regulate this process at will remains a challenge. In this report, we asked whether a theophylline-responsive riboswitch could be adapted to manipulate alternative splicing. We constructed a pre-mRNA containing a single upstream 5' splice site and two 3' splice sites, of which the proximal 3' splice site is embedded in theophylline-responsive riboswitch. We show that this pre-mRNA spliced with preferential utilization of proximal 3' splice site in vitro. However, addition of theophylline to the splicing reaction promoted splicing at distal 3' splice site thereby changing the ratio of distal-to-proximal 3' splice site usage by more than twofold. Our data suggest that theophylline influenced 3' splice site choice without affecting the kinetics of the splicing reaction. We conclude that an in vitro selected riboswitch can be adapted to control alternative splicing, which may find many applications in basic, biotechnological, and biomedical research.     

An LKB1 AT-AC intron mutation causes Peutz-Jeghers syndrome via splicing at noncanonical cryptic splice sites

Peutz-Jeghers syndrome (PJS) is an autosomal dominant disorder associated with gastrointestinal polyposis and an increased cancer risk. PJS is caused by germline mutations in the tumor suppressor gene LKB1. One such mutation, IVS2+1A>G, alters the second intron 5' splice site, which has sequence features of a U12-type AT-AC intron. We report that in patients, LKB1 RNA splicing occurs from the mutated 5' splice site to several cryptic, noncanonical 3' splice sites immediately adjacent to the normal 3' splice site. In vitro splicing analysis demonstrates that this aberrant splicing is mediated by the U12-dependent spliceosome. The results indicate that the minor spliceosome can use a variety of 3' splice site sequences to pair to a given 5' splice site, albeit with tight constraints for maintaining the 3' splice site position. The unusual splicing defect associated with this PJS-causing mutation uncovers differences in splice-site recognition between the major and minor pre-mRNA splicing pathways.     

Exon definition may facilitate splice site selection in RNAs with multiple exons.

Interactions at the 3' end of the intron initiate spliceosome assembly and splice site selection in vertebrate pre-mRNAs. Multiple factors, including U1 small nuclear ribonucleoproteins (snRNPs), are involved in initial recognition at the 3' end of the intron. Experiments were designed to test the possibility that U1 snRNP interaction at the 3' end of the intron during early assembly functions to recognize and define the downstream exon and its resident 5' splice site. Splicing precursor RNAs constructed to have elongated second exons lacking 5' splice sites were deficient in spliceosome assembly and splicing activity in vitro. Similar substrates including a 5' splice site at the end of exon 2 assembled and spliced normally as long as the second exon was less than 300 nucleotides long. U2 snRNPs were required for protection of the 5' splice site terminating exon 2, suggesting direct communication during early assembly between factors binding the 3' and 5' splice sites bordering an exon. We suggest that exons are recognized and defined as units during early assembly by binding of factors to the 3' end of the intron, followed by a search for a downstream 5' splice site. In this view, only the presence of both a 3' and a 5' splice site in the correct orientation and within 300 nucleotides of one another will stable exon complexes be formed. Concerted recognition of exons may help explain the 300-nucleotide-length maximum of vertebrate internal exons, the mechanism whereby the splicing machinery ignores cryptic sites within introns, the mechanism whereby exon skipping is normally avoided, and the phenotypes of 5' splice site mutations that inhibit splicing of neighboring introns.     

Cryptic intron activation within the large exon of the mouse polymeric immunoglobulin receptor gene: cryptic splice sites correspond to protein domain boundaries.

The fourth exon of the mouse polymeric immuno-globulin receptor (pIgR) is 654 nt long and, despite being surrounded by large introns, is constitutively spliced into the mRNA. Deletion of an 84 nt sequence from this exon strongly activated both cryptic 5' and 3' splice sites surrounding a 78 nt cryptic intron. The 84 nt deletion is just upstream of the cryptic 3' splice site; the cryptic 3' splice site was likely activated because the deletion created a better 3' splice site. However, the cryptic 5' splice site was also required to activate the cryptic splice reaction; point mutations in either of the cryptic splice sites that decreased their match to the consensus splice site sequence inactivated the cryptic splice reaction. The activation and inactivation of these cryptic splice sites as a pair suggests that they are being co-recognized by the splicing machinery. Interestingly, the large fourth exon of the pIgR gene encodes two immunoglobulin-like extracellular protein domains; the cryptic 3' splice site coincides with the junction between these protein domains. The cryptic 5' splice site is located between protein subdomains where an intron is found in another gene of the immunoglobulin superfamily.     

Folding problems of the 5' splice site containing the P1 stem of the group I thymidylate synthase intron: substrate binding inhibition in vitro and mis-splicing in vivo

We developed an in vitro cleaving assay for the thymidylate synthase (td) group I intron and observed that the off-rate of the substrate is faster than cleavage. From the sequence stems P1 and P2 can vary from 4 to 8 and from 6 to 10 base pairs, respectively, with folding of a long P1 stem being in competition with folding of a long P2 stem. Shorter substrates, which cannot compete with the formation of an extended P2, result in faster cleavage, suggesting that binding of the substrate indeed interferes with folding of stem P2. In vivo splicing analyses of mutants containing alterations in stems P1 and P2 indicate that the wild-type exon sequence of P1 is suboptimal for splicing. Furthermore, folding of P1 in vivo is in competition with an alternative cryptic P1 stem resulting in mis-splicing. Translation promotes splicing at the correct 5' splice site, whereas in the absence of translation, mis-splicing is favored. The combination of the in vitro and in vivo assays clearly displays the folding problems for correct splice site selection in this group I intron.