Length changes in the joining segment between domains 5 and 6 of a group II intron inhibit self-splicing and alter 3' splice site selection.

Domain 5 (D5) and domain 6 (D6) are adjacent folded hairpin substructures of self-splicing group II introns that appear to interact within the active ribozyme. Here we describe the effects of changing the length of the 3-nucleotide segment joining D5 to D6 [called J(56)3] on the splicing reactions of intron 5 gamma of the COXI gene of yeast mitochondrial DNA. Shortened variants J(56)0 and J(56)1 were defective in vitro for branching, and the second splicing step was performed inefficiently and inaccurately. The lengthened variant J(56)5 had a milder defect-splicing occurred at a reduced rate but with correct branching and a mostly accurate 3' splice junction choice. Yeast mitochondria were transformed with the J(56)5 allele, and the resulting yeast strain was respiration deficient because of ineffective aI5 gamma splicing. Respiration-competent revertants were recovered, and in one type a single joiner nucleotide was deleted while in the other type a nucleotide of D6 was deleted. Although these revertants still showed partial splicing blocks in vivo and in vitro, including a substantial defect in the second step of splicing, both spliced accurately in vivo. These results establish that a 3-nucleotide J(56) is optimal for this intron, especially for the accuracy of 3' splice junction selection, and indicate that D5 and D6 are probably not coaxially stacked.     

Photocrosslinking of 4-thio uracil-containing RNAs supports a side-by-side arrangement of domains 5 and 6 of a group II intron

Previous studies suggested that domains 5 and 6 (D5 and D6) of group II introns act together in splicing and that the two helical structures probably do not interact by helix stacking. Here, we characterized the major Mg2+ ion- and salt-dependent, long-wave UV light-induced, intramolecular crosslinks formed in 4-thiouridine-containing D56 RNA from intron 5gamma (aI5gamma) of the COXI gene of yeast mtDNA. Four major crosslinks were mapped and found to result from covalent bonds between nucleotides separating D5 from D6 [called J(56)] and residues of D6 near and including the branch nucleotide. These findings are extended by results of similar experiments using 4-thioU containing D56 RNAs from a mutant allele of aI5gamma and from the group IIA intron, aI1. Trans-splicing experiments show that the crosslinked wild-type aI5gamma D56 RNAs are active for both splicing reactions, including some first-step branching. An RNA containing the 3-nt J(56) sequence and D6 of aI5gamma yields one main crosslink that is identical to the most minor of the crosslinks obtained with D56 RNA, but in this case in a cation-independent fashion. We conclude that the interaction between J(56) and D6 is influenced by charge repulsion between the D5 and D6 helix backbones and that high concentrations of cations allow the helices to approach closely under self-splicing conditions. The interaction between J(56) and D6 appears to be a significant factor establishing a side-by-side (i.e., not stacked) orientation of the helices of the two domains.     

Probing the role of a secondary structure element at the 5'- and 3'-splice sites in group I intron self-splicing: the tetrahymena L-16 ScaI ribozyme reveals a new role of the G.U pair in self-splicing

Several ribozyme constructs have been used to dissect aspects of the group I self-splicing reaction. The Tetrahymena L-21 ScaI ribozyme, the best studied of these intron analogues, catalyzes a reaction analogous to the first step of self-splicing, in which a 5'-splice site analogue (S) and guanosine (G) are converted into a 5'-exon analogue (P) and GA. This ribozyme preserves the active site but lacks a short 5'-terminal segment (called the IGS extension herein) that forms dynamic helices, called the P1 extension and P10 helix. The P1 extension forms at the 5'-splice site in the first step of self-splicing, and P10 forms at the 3'-splice site in the second step of self-splicing. To dissect the contributions from the IGS extension and the helices it forms, we have investigated the effects of each of these elements at each reaction step. These experiments were performed with the L-16 ScaI ribozyme, which retains the IGS extension, and with 5'- and 3'-splice site analogues that differ in their ability to form the helices. The presence of the IGS extension strengthens binding of P by 40-fold, even when no new base pairs are formed. This large effect was especially surprising, as binding of S is essentially unaffected for S analogues that do not form additional base pairs with the IGS extension. Analysis of a U.U pair immediately 3' to the cleavage site suggests that a previously identified deleterious effect from a dangling U residue on the L-21 ScaI ribozyme arises from a fortuitous active site interaction and has implications for RNA tertiary structure specificity. Comparisons of the affinities of 5'-splice site analogues that form only a subset of base pairs reveal that inclusion of the conserved G.U base pair at the cleavage site of group I introns destabilizes the P1 extension >100-fold relative to the stability of a helix with all Watson-Crick base pairs. Previous structural data with model duplexes and the recent intron structures suggest that this effect can be attributed to partial unstacking of the P1 extension at the G.U step. These results suggest a previously unrecognized role of the G.U wobble pair in self-splicing: breaking cooperativity in base pair formation between P1 and the P1 extensions. This effect may facilitate replacement of the P1 extension with P10 after the first chemical step of self-splicing and release of the ligated exons after the second step of self-splicing.     

The conserved U.G pair in the 5'' splice site duplex of a group I intron is required in the first but not the second step of self-splicing.

Group I self-splicing introns have a 5' splice site duplex (P1) that contains a single conserved base pair (U.G). The U is the last nucleotide of the 5' exon, and the G is part of the internal guide sequence within the intron. Using site-specific mutagenesis and analysis of the rate and accuracy of splicing of the Tetrahymena thermophila group I intron, we found that both the U and the G of the U.G pair are important for the first step of self-splicing (attack of GTP at the 5' splice site). Mutation of the U to a purine activated cryptic 5' splice sites in which a U.G pair was restored; this result emphasizes the preference for a U.G at the splice site. Nevertheless, some splicing persisted at the normal site after introduction of a purine, suggesting that position within the P1 helix is another determinant of 5' splice site choice. When the U was changed to a C, the accuracy of splicing was not affected, but the Km for GTP was increased by a factor of 15 and the catalytic rate constant was decreased by a factor of 7. Substitution of U.A, U.U, G.G, or A.G for the conserved U.G decreased the rate of splicing by an even greater amount. In contrast, mutation of the conserved G enhanced the second step of splicing, as evidenced by a trans-splicing assay. Furthermore, a free 5' exon ending in A or C instead of the conserved U underwent efficient ligation. Thus, unlike the remainder of the P1 helix, which functions in both the first and second steps of self-splicing, the conserved U.G appears to be important only for the first step.     

A ribozyme selected from variants of U6 snRNA promotes 2',5'-branch formation

In vitro selection was used to sample SnRNA-related sequences for ribozyme activities, and several 2',5'-branch-forming ribozymes were isolated. One such ribozyme is highly dependent upon an 11-nt motif that contains a conserved U6 snRNA sequence (ACAGAGA-box) known to be important for pre-mRNA splicing. The ribozyme reaction is similar to the first step of splicing in that an internal 2'-hydroxyl of an unpaired adenosine attacks at the 5'-phosphate of a guanosine. It differs in that the leaving group is diphosphate rather than a 5' exon. The finding that lariat formation can be accomplished by a small RNA with sequences related to U6 snRNA indicates that the RNA available in the spliceosome may be involved in RNA-catalyzed branch formation.     

New tertiary constraints between the RNA components of active yeast spliceosomes: a photo-crosslinking study

Elucidation of the three-dimensional (3D) structures of the two sequential active sites in spliceosomes is essential for understanding the mechanism of premessenger RNA splicing. The mechanism is predicted to be catalyzed by the small nuclear RNA (snRNA) components of spliceosomes. To obtain new tertiary constraints between the RNA components, we produced and mapped crosslinks between U6 snRNA and the proximal RNAs of active yeast spliceosomes ("yeast" in this report is Saccharomyces cerevisiae). Thus, specific sites in U6, when substituted with a photoreactive 4-thiouridine or 5-iodouridine, produced spliceosome-dependent crosslinks to U2 snRNA, or in one case, to the pre-mRNA substrate. One set of U2-U6 crosslinks formed before the Prp2p-dependent step of spliceosome assembly, whereas another set formed during or after this step but before the first chemical step of splicing. This latter set of crosslinks formed across U2-U6 helix I. Importantly, this set provides new tertiary constraints for developing 3D models of fully assembled yeast spliceosomes, which are poised for the first chemical step of splicing.     

Evidence that U2/U6 helix I promotes both catalytic steps of pre-mRNA splicing and rearranges in between these steps

During pre-mRNA splicing, the spliceosome must configure the substrate, catalyze 5′ splice site cleavage, reposition the substrate, and catalyze exon ligation. The highly conserved U2/U6 helix I, which adjoins sequences that define the reactive sites, has been proposed to configure the substrate for 5′ splice site cleavage and promote catalysis. However, a role for this helix at either catalytic step has not been tested rigorously and previous observations question its role at the catalytic steps. Through a comprehensive molecular genetic study of U2/U6 helix I, we found that weakening U2/U6 helix I, but not mutually exclusive structures, compromised splicing of a substrate limited at the catalytic step of 5′ splice site cleavage, providing the first compelling evidence that this helix indeed configures the substrate during 5′ splice site cleavage. Further, mutations that we proved weaken only U2/U6 helix I suppressed a mutation in PRP16, a DEAH-box ATPase required after 5′ splice site cleavage, providing persuasive evidence that helix I is destabilized by Prp16p and suggesting that this structure is unwound between the catalytic steps. Lastly, weakening U2/U6 helix I also compromised splicing of a substrate limited at the catalytic step of exon ligation, providing evidence that U2/U6 helix I reforms and functions during exon ligation. Thus, our data provide evidence for a fundamental and apparently dynamic role for U2/U6 helix I during the catalytic stages of splicing.     

Studies of point mutants define three essential paired nucleotides in the domain 5 substructure of a group II intron.

Domain 5 (D5) is a highly conserved, largely helical substructure of group II introns that is essential for self-splicing. Only three of the 14 base pairs present in most D5 structures (A2.U33, G3.U32, and C4.G31) are nearly invariant. We have studied effects of point mutations of those six nucleotides on self-splicing and in vivo splicing of aI5 gamma, an intron of the COXI gene of Saccharomyces cerevisiae mitochondria. Though none of the point mutations blocked self-splicing under one commonly used in vitro reaction condition, the most debilitating mutations were at G3 and G4. Following mitochondrial Biolistic transformation, it was found that mutations at A2, G3, and C4 blocked respiratory growth and splicing while mutations at the other sites had little effect on either phenotype. Intra-D5 second-site suppressors showed that pairing between nucleotides at positions 2 and 33 and 4 and 31 is especially important for D5 function. At the G3.U32 wobble pair, the mutant A.U pair blocks splicing, but a revertant of that mutant that can form an A+.C base pair regains some splicing. A dominant nuclear suppressor restores some splicing to the G3A mutant but not the G3U mutant, suggesting that a purine is required at position 3. These findings are discussed in terms of the hypothesis of Madhani and Guthrie (H. D. Madhani and C. Guthrie, Cell 71:803-817, 1992) that helix 1 formed between yeast U2 and U6 small nuclear RNAs may be the spliceosomal cognate of D5.     

Identification of a U2/U6 helix la mutant that influences 3' splice site selection during nuclear pre-mRNA splicing

Base substitutions in U2/U6 helix I, a conserved base-pairing interaction between the U6 and U2 snRNAs, have previously been found to specifically block the second catalytic step of nuclear pre-mRNA splicing. To further assess the role of U2/U6 helix I in the second catalytic step, we have screened mutations in U2/U6 helix I to identify those that influence 3' splice site selection using a derivative of the yeast actin pre-mRNA. In these derivatives, the spacing between the branch site adenosine and 3' splice site has been reduced from 43 to 12 nt and this results in enhanced splicing of mutants in the conserved 3' terminal intron residue. In this context, mutation of the conserved 3' intron terminal G to a C also results in the partial activation of a nearby cryptic 3' splice site with U as the 3' terminal intron nucleotide. Using this highly sensitive mutant substrate, we have identified a mutation in the U6 snRNA (U57A) that significantly increases the selection of the cryptic 3' splice site over the normal 3' splice site and augments its utilization relative to that observed with the wild-type U2 or U6 snRNAs. In a previous study, we found that the same U6 mutation suppressed the effects of an A-to-G branch site mutation in an allele-specific fashion. The ability of U6-U57 mutants to influence the fidelity of both branch site and 3' splice site recognition suggests that this nucleotide may participate in the formation of the active site(s) of the spliceosome.     

Solution structure of domain 5 of a group II intron ribozyme reveals a new RNA motif

Domain 5 (D5) is the central core of group II intron ribozymes. Many base and backbone substituents of this highly conserved hairpin participate in catalysis and are crucial for binding to other intron domains. We report the solution structures of the 34-nucleotide D5 hairpin from the group II intron ai5 gamma in the absence and presence of divalent metal ions. The bulge region of D5 adopts a novel fold, where G26 adopts a syn conformation and flips down into the major groove of helix 1, close to the major groove face of the catalytic AGC triad. The backbone near G26 is kinked, exposing the base plane of the adjacent A-U pair to the solvent and causing bases of the bulge to stack intercalatively. Metal ion titrations reveal strong Mg(2+) binding to a minor groove shelf in the D5 bulge. Another distinct metal ion-binding site is observed along the minor groove side of the catalytic triad, in a manner consistent with metal ion binding in the ribozyme active site.     

New features of 23S ribosomal RNA folding: the long helix 41-42 makes a "U-turn" inside the ribosome.

23S rRNA from Escherichia coli was cleaved at single internucleotide bonds using ribonuclease H in the presence of appropriate chimeric oligonucleotides; the individual cleavage sites were between residues 384 and 385, 867 and 868, 1045 and 1046, and 2510 and 2511, with an additional fortuitous cleavage at positions 1117 and 1118. In each case, the 3'' terminus of the 5'' fragment was ligated to radioactively labeled 4-thiouridine 5''-,3''-biphosphate ("psUp"), and the cleaved 23S rRNA carrying this label was reconstituted into 50S subunits. The 50S subunits were able to associate normally with 30S subunits to form 70S ribosomes. Intra-RNA crosslinks from the 4-thiouridine residues were induced by irradiation at 350 nm, and the crosslink sites within the 23S rRNA were analyzed. The rRNA molecules carrying psUp at positions 867 and 1117 showed crosslinks to nearby positions on the opposite strand of the same double helix where the cleavage was located, and no crosslinking was detected from position 2510. In contrast, the rRNA carrying psUp at position 384 showed crosslinking to nt 420 (and sometimes also to 416 and 425) in the neighboring helix in 23S rRNA, and the rRNA with psUp at position 1045 gave a crosslink to residue 993. The latter crosslink demonstrates that the long helix 41-42 of the 23S rRNA (which carries the region associated with GTPase activity) must double back on itself, forming a "U-turn" in the ribosome. This result is discussed in terms of the topography of the GTPase region in the 50S subunit, and its relation to the locations of the 5S rRNA and the peptidyl transferase center.     

U11 snRNA interacts in vivo with the 5' splice site of U12-dependent (AU-AC) pre-mRNA introns.

A notable feature of the newly described U12 snRNA-dependent class of eukaryotic nuclear pre-mRNA introns is the highly conserved 8-nt 5'' splice site sequence. This sequence is virtually invariant in all known members of this class from plants to mammals. Based on sequence complementarity between this sequence and the 5'' end of the U11 snRNA, we proposed that U11 snRNP may play a role in identifying and/or activating the 5'' splice site for splicing. Here we show that mutations of the conserved 5'' splice site sequence of a U12-dependent intron severely reduce correct splicing in vivo and that compensatory mutations in U11 snRNA can suppress the effects of the 5'' splice site mutations to varying extents. This provides evidence for a required interaction between U11 snRNA and the 5'' splice site sequence involving Watson-Crick base pairing. This data, in addition to a report that U11 snRNP is bound transiently to the U12-dependent spliceosome, suggests that U11 snRNP is the analogue of U1 snRNP in splicing this rare class of introns.     

snRNA interactions at 5' and 3' splice sites monitored by photoactivated crosslinking in yeast spliceosomes.

Splice site recognition and catalysis of the transesterification reactions in the spliceosome are accompanied by a dynamic series of interactions involving conserved or invariant sequences in the spliceosomal snRNAs. We have used site-specific photoactivated crosslinking in yeast spliceosomes to monitor interactions between snRNAs and exon sequences near the 5' and 3' splice sites. The last nucleotide of the 5' exon can be crosslinked to an invariant loop sequence in U5 SnRNA before and after 5' splice site cleavage. The first nucleotide of the 3' exon can also be crosslinked to the same U5 loop sequence, but this contact is only detectable after the first transesterification. These results are in close agreement with earlier data from mammalian splicing extracts, and they are consistent with a model in which U5 snRNA aligns the 5' and 3' exons for the second transesterification. After the first catalytic step of splicing, the first nucleotide of the 3' exon can also crosslink to nt U23 in U2 snRNA. This is one of a cluster of residues in U2-U6 helix I implicated by mutational analysis in the second catalytic step of splicing. The crosslinking data suggest that these residues in U2-U6 helix I are in close proximity to the scissile phosphodiester bond at the 3' splice site prior to the second transesterification. These results constitute the first biochemical evidence for a direct interaction between the 3' splice site and U2 snRNA.     

Synthesis of chimeric RNAs between U6 small nuclear RNA and (-)sTRSV and analysis of their cleavage activities against the substrate RNA.

U6 small nuclear RNA (U6 snRNA) is one of the spliceosomal RNAs essential for pre-mRNA splicing. Highly conserved region of U6 snRNA shows a structural similarity with the catalytic center of the negative strand of the satellite RNA of tobacco ring spot virus [(-)sTRSV], supporting the hypothesis that U6 snRNA has a catalytic role in pre-mRNA splicing. To test this hypothesis, we examined in vitro whether synthetic RNAs consisting of the sequence of the highly conserved region of U6 snRNA or various chimeric RNAs between the U6 region and the catalytic center of (-)sTRSV could cleave a substrate RNA that can partially base-pair with them and has a GU sequence between the pairing regions. Chimeric RNAs with 70 to 83% sequence identity with the conserved region of S. pombe U6 snRNA cleaved the substrate RNA at the 5' side of the GU sequence. In addition, we found that the highly conserved region of U6 snRNA is similar in structure to the catalytic core region of the group I self-splicing intron in cyanobacteria. These results support the hypothesis that U6 snRNA catalyzes the pre-mRNA splicing reaction and U6 snRNA may originate from the catalytic domain of an ancient self-splicing intron.     

Activity of chimeric RNAs of U6 snRNA and (-)sTRSV in the cleavage of a substrate RNA.

U6 small nuclear RNA is one of the spliceosomal RNAs essential for pre-mRNA splicing. Discovery of mRNA-type introns in the highly conserved region of the U6 snRNA genes led to the hypothesis that U6 snRNA functions as a catalytic element during pre-mRNA splicing. The highly conserved region of U6 snRNA has a structural similarity with the catalytic domain of the negative strand of the satellite RNA of tobacco ring spot virus [(-)sTRSV], suggesting that the highly conserved region of U6 snRNA forms the catalytic center. We examined whether synthetic RNAs consisting of the sequence of the highly conserved region of U6 snRNA or various chimeric RNAs between the U6 region and the catalytic RNA of (-)sTRSV could cleave a substrate RNA that can partially base-pair with them and have a GU sequence. Chimeric RNAs with 70 to 83% sequence identity with the conserved region of S. pombe U6 snRNA cleaved the substrate RNA at the 5' side of the GU sequence, which is shared by the 5' end of an intron in a pre-mRNA. We found that the highly conserved region of U6 snRNA and the catalytic domain of (-)sTRSV are strikingly similar in structure to the catalytic core region of the group I self-splicing intron in cyanobacteria. These results suggest that U6 snRNA, (-)sTRSV and the group I self-splicing intron originated from a common ancestral RNA, and support the hypothesis that U6 snRNA catalyzes pre-mRNA splicing reaction.     

Invariant U2 RNA sequences bordering the branchpoint recognition region are essential for interaction with yeast SF3a and SF3b subunits.

U2 small nuclear RNA (snRNA) contains a sequence (GUAGUA) that pairs with the intron branchpoint during splicing. This sequence is contained within a longer invariant sequence of unknown secondary structure and function that extends between U2 and I and stem IIa. A part of this region has been proposed to pair with U6 in a structure called helix III. We made mutations to test the function of these nucleotides in yeast U2 snRNA. Most single base changes cause no obvious growth defects; however, several single and double mutations are lethal or conditional lethal and cause a block before the first step of splicing. We used U6 compensatory mutations to assess the contribution of helix III and found that if it forms, helix III is dispensable for splicing in Saccharomyces cerevisiae. On the other hand, mutations in known protein components of the splicing apparatus suppress or enhance the phenotypes of mutations within the invariant sequence that connect the branchpoint recognition sequence to stem IIa. Lethal mutations in the region are suppressed by Cus1-54p, a mutant yeast splicing factor homologous to a mammalian SF3b subunit. Synthetic lethal interactions show that this region collaborates with the DEAD-box protein Prp5p and the yeast SF3a subunits Prp9p, Prp11p, and Prp21p. Together, the data show that the highly conserved RNA element downstream of the branchpoint recognition sequence of U2 snRNA in yeast cells functions primarily with the proteins that make up SF3 rather than with U6 snRNA.     

Fluorescence and solution NMR study of the active site of a 160-kDa group II intron ribozyme

We have reconstructed the group II intron from Pylaiella littoralis (PL) into a hydrolytic ribozyme, comprising domains 1-3 (D123) connected in cis plus domain 5 (D5) supplied in trans that efficiently cleaves spliced exon substrates. Using a novel gel-based fluorescence assay and nuclear magnetic resonance (NMR) spectroscopy, we monitored the direct binding of D5 to D123, characterized the kinetics of the spliced exon hydrolysis reaction (which is mechanistically analogous to the reverse of the second catalytic step of splicing), and identified the binding surface of D123 on D5. This PL ribozyme acts as an RNA endonuclease even at low monovalent (100 mM KCl) and divalent ion concentrations (1-10 mM MgCl(2)). This is in contrast to other group II intron ribozyme systems that require high levels of salt, making NMR analysis problematic. D5 binds tightly to D123 with a K(d) of 650 +/- 250 nM, a K(m) of approximately 300 nM, and a K(cat) of 0.02 min(-1) under single turnover conditions. Within the approximately 160-kDa D123-D5 binary complex, site-specific binding to D123 leads to dramatic chemical shift perturbation of residues localized to the tetraloop and internal bulge within D5, suggesting a structural switch model for D5-assisted splicing. This minimal ribozyme thus recapitulates the essential features of the reverse of the second catalytic step and represents a well-behaved system for ongoing high-resolution structural work to complement folding and catalytic functional studies.     

The conserved central domain of yeast U6 snRNA: importance of U2-U6 helix Ia in spliceosome assembly

In the pre-mRNA processing machinery of eukaryotic cells, U6 snRNA is located at or near the active site for pre-mRNA splicing catalysis, and U6 is involved in catalyzing the first chemical step of splicing. We have further defined the roles of key features of yeast U6 snRNA in the splicing process. By assaying spliceosome assembly and splicing in yeast extracts, we found that mutations of yeast U6 nt 56 and 57 are similar to previously reported deletions of U2 nt 27 or 28, all within yeast U2-U6 helix Ia. These mutations lead to the accumulation of yeast A1 spliceosomes, which form just prior to the Prp2 ATPase step and the first chemical step of splicing. These results strongly suggest that, at a late stage of spliceosome assembly, the presence of U2-U6 helix Ia is important for promoting the first chemical step of splicing, presumably by bringing together the 5' splice site region of pre-mRNA, which is base paired to U6 snRNA, and the branchsite region of the intron, which is base paired to U2 snRNA, for activation of the first chemical step of splicing, as previously proposed by Madhani and Guthrie [Cell, 1992, 71: 803-817]. In the 3' intramolecular stem-loop of U6, mutation G81C causes an allele-specific accumulation of U6 snRNP. Base pairing of the U6 3' stem-loop in yeast spliceosomes does not extend as far as to include the U6 sequence of U2-U6 helix Ib, in contrast to the human U6 3' stem-loop structure.