A base triple in the Tetrahymena group I core affects the reaction equilibrium via a threshold effect

Previous work on group I introns has suggested that a central base triple might be more important for the first rather than the second step of self-splicing, leading to a model in which the base triple undergoes a conformational change during self-splicing. Here, we use the well-characterized L-21 ScaI ribozyme derived from the Tetrahymena group I intron to probe the effects of base-triple disruption on individual reaction steps. Consistent with previous results, reaction of a ternary complex mimicking the first chemical step in self-splicing is slowed by mutations in this base triple, whereas reaction of a ternary complex mimicking the second step of self-splicing is not. Paradoxically, mechanistic dissection of the base-triple disruption mutants indicates that active site binding is weakened uniformly for the 5'-splice site and the 5'-exon analog, mimics for the species bound in the first and second step of self-splicing. Nevertheless, the 5'-exon analog remains bound at the active site, whereas the 5'-splice site analog does not. This differential effect arises despite the uniform destabilization, because the wild-type ribozyme binds the 5'-exon analog more strongly in the active site than in the 5'-splice site analog. Thus, binding into the active site constitutes an additional barrier to reaction of the 5'-splice site analog, but not the 5'-exon analog, resulting in a reduced reaction rate constant for the first step analog, but not the second step analog. This threshold model explains the self-splicing observations without the need to invoke a conformational change involving the base triple, and underscores the importance of quantitative dissection for the interpretation of effects from mutations.     

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.     

Divalent metal ion binding to a conserved wobble pair defining the upstream site of cleavage of group I self-splicing introns.

The upstream site of cleavage of all group I self-splicing introns is identified by an absolutely conserved U.G base pair. Although a wobble C.A pair can substitute the U.G pair, all other combinations of nucleotides at this position abolish splicing, suggesting that it is an unusual RNA structure, rather than sequence, that is recognized by the catalytic intron core. RNA enzymes are metalloenzymes, and divalent metal ion binding may be an important requirement for splice site recognition and catalysis. The paramagnetic broadening of NMR resonances upon manganese binding at specific sites was used to probe the interaction between divalent metal ions and an oligonucleotide model of a group I intron ribozyme substrate. Unlike previous studies in which only imino proton resonances were monitored, we have used isotopically labelled RNA and a set of complete spectral assignments to identify the location of the divalent metal binding site with much greater detail than previously possible. Two independent metal binding sites were identified for this oligonucleotide. A first metal binding site is located in the major groove of the three consecutive G.C base pairs at the end of double helical stem. A second site is found in the major groove of the RNA double helix in the vicinity of the U.G base pair. These results suggest that metal ion coordination (or a metal bridge) and tertiary interactions identified biochemically, may be used by group I intron ribozymes for substrate recognition.     

Probing the Tetrahymena group I ribozyme reaction in both directions

The Tetrahymena L-21 ScaI ribozyme derived from the self-splicing group I intron catalyzes a reversible reaction analogous to the first step of self-splicing: CCCUCUA (S) + [UC]G right harpoon over left harpoon CCCUCU (P) + [UC]GA. To relate our understanding of the ribozyme to the self-splicing reaction and to further the mechanistic dissection of the ribozyme reaction, we have established a quantitative kinetic and thermodynamic framework for the forward and reverse reaction of the L-21 ScaI ribozyme under identical conditions. Examination of the framework shows that binding of products is cooperative with binding enhanced 5-fold, as was observed previously for binding of the substrates. Further, binding of UCGA is 12-fold weaker than binding of the unphosphorylated UCG, analogous to the 20-fold weaker binding of phosphorylated S relative to P; the molecular interactions underlying the stronger binding of UCG were traced to the 3'-hydroxyl group of UCG. The symmetrical effects on binding of substrates and products result in the equilibrium between ribozyme-bound species, K(int), that is essentially unperturbed from the solution equilibrium, K(ext) (K(int) = [E.P.UCGA]/[E.S.UCG] = 4.6 and K(ext) = [P][UCGA]/[S][UCG] = 1.9). Last, we show that the pK(a) values of the nucleophiles in the forward and reverse reactions are >/=10. This observation suggests that metal ion activation of the nucleophile and stabilization of the leaving group can only account for a portion of the rate enhancement of this ribozyme. These and prior results suggest that the Tetrahymena group I ribozyme, analogous to protein enzymes, uses multiple catalytic strategies to achieve its large rate enhancement.     

A conserved base pair within helix P4 of the Tetrahymena ribozyme helps to form the tertiary structure required for self-splicing.

Site-specific mutagenesis of the self-splicing Tetrahymena intron has been used to investigate the function of C109-G212, a conserved base pair in the P4 stem of group I introns. Mutation of C109 to G affects splicing only slightly, whereas mutation of G212 to A or C reduces the rate of splicing substantially (500-fold reduction in kcat/Km under standard in vitro splicing conditions for the G212C mutant). Splicing activity of the compensatory double mutant (C109G:G212C) is intermediate between those of the two single mutants. Thus, the stability of the P4 stem as well as the identity of the base at position 212 are important for self-splicing. Single and double mutants containing the G212C substitution have a decreased temperature optimum for self-splicing and are partially Mg2+ suppressible, both indicative of structural destabilization. Chemical structure mapping indicates that the mutations do not redirect the global folding of the RNA, but affect the structure locally and at one other site (A183) that is distant in the secondary structure. We propose that, in addition to its pairing in P4, G212 is involved in a base triplet or an alternate base pair that contributes to the catalytically active tertiary structure of the ribozyme.     

The mechanism of group I self-splicing: an internal guide sequence can be provided in trans.

We have reconstituted a group I self-splicing reaction between two RNA molecules with different functional RNA parts: a substrate molecule containing the 5' splice site and a functional internal guide sequence (IGS), and a ribozyme molecule with core structure elements and splice sites but a mutated IGS. The 5' exon of the substrate molecule is ligated in trans to the 3' exon of the ribozyme molecule, suggesting that the deficient IGS in the ribozyme can be replaced by an externally added IGS present on the substrate molecule. This result is different from catalysis mediated by proteins where it is not possible to dissect the specificity of an enzyme from its catalytic activity.     

Molecular recognition in a trans excision-splicing ribozyme: non-Watson-Crick base pairs at the 5' splice site and omegaG at the 3' splice site can play a role in determining the binding register of reaction substrates

Trans excision-splicing (TES) ribozymes, derived from a Pneumocystis carinii group I intron, can catalyze the excision of targeted sequences from within RNAs. In this report, the sequence requirements of the splice sites are analyzed. These conserved sequences include a u-G wobble pair at the 5' splice site and a guanosine in the omega position at the 3' splice site (in the substrate). We report that 7 out of 16 base pair combinations at the 5' splice site produce appreciable TES product. This promiscuity is in contrast to results reported for analogous self-splicing reactions using a Tetrahymena ribozyme. At long reaction times TES products dissociate and rebind free ribozyme, at which point product degradation occurs via the 5' cleavage reaction. Unexpectedly, only in cases where Watson-Crick base pairs form at the 5'splice site do we see degradation of TES products at cryptic sites, suggesting that non-Watson-Crick base pairs at the 5' splice site are acting in concert with other factors to precisely determine the binding register of TES reaction substrates within the ribozyme. Moreover, cryptic site degradation does not occur with the corresponding reaction substrates, which additionally contain omegaG, suggesting that omegaG can play a similar role. We report that omegaG cannot be replaced by any other base, so TES substrates require a guanosine as the last (or only) base to be excised. Additionally, we demonstrate that P9.0 and P10 are expendable for TES reactions, suggesting that omegaG is sufficient as a 3' molecular recognition element.     

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.     

Characterization of the mode of binding of substrates to the active site of Tetrahymena self-splicing RNA using 5-fluorouracil-substituted mini-exons

Splice-site selection specificity in Tetrahymena self-splicing RNA is thought to be mediated by a base-paired complex between a CUCUCU sequence on the end of the 5' exon and a GGGAGG guide sequence in the intron. The substitution of uracil (U) in oligonucleotide mini-exons with 5-fluorouracil (UF), an analogue bearing a much more acidic N-3 proton, allowed us to test the role of hydrogen bonding between complementary bases in the splice-site selection process. The affinities of (U) and (UF) mini-exons for the ribozyme active site were similar and several orders of magnitude greater than expected from base pairing alone. In contrast to CUCU, the CUFCUF mini-exon lost substrate activity with increasing pH, presumably due to ionization of the UF residues. However, the apparent pK values of these residues were several pK units above that of free UF, indicating that the mini-exon is shielded from the solvent by an active site of low polarity. Loss of the pyrimidine N-3 hydrogen bond by selective ionization of the UF residues decreased the binding of CUFCUF to the ribozyme only 3-fold but did prevent its ligation to the 3' exon. Temperature dependence of substrate activity was identical for both (U) and (UF) mini-exons, whereas the UF-substituted ribozyme lost activity at a considerably lower temperature than did the natural (U) ribozyme. These observations indicate that hydrogen-bonded base pairs involving the U residues contribute little to the total binding energy of the 5' splice site with the active site of the ribozyme, but probably help to align the splice sites properly for ligation.     

A single metal ion plays structural and chemical roles in an aminoacyl-transferase ribozyme.

Catalytically active RNA molecules rely on metal ions for structural and/or catalytic functions. Our in vitro selected aminoacyl-transferase ribozyme is no exception, as it employs a single fully hydrated Mg2+ ion for catalysis [Suga, H., et al. (1998) Biochemistry 37, 10118-10125]. Here we report the essential catalytic residues of the ribozyme and their spatial arrangement in the relation to the metal binding site. Evidence obtained using a combination of Pb2+ and Tb3+ hydrolytic cleavage assays on wild type and mutant ribozymes revealed a cooperative metal binding site that consists of the tandem G:U wobble pairs in P1 and consecutive G:U and U:A pairs in P3. The formation of this concerted Mg2+ binding site positions the P1 and P3 helices in a parallel manner, placing the L3 tetraloop in close proximity to the internal guide sequence (IGS, substrate binding site), which is adjacent to P1. Certain monovalent metal ions inhibit catalysis at low concentrations but support catalysis at high concentrations. These analyses imply that the Mg2+ ion plays both structural and chemical roles and that it brings about the significant rate acceleration in aminoacyl-transfer in concert with the L3-IGS long-range interaction.     

Minimal catalytic domain of a group I self-splicing intron RNA

The self-splicing intron ribozymes have been regarded as primitive forms of the splicing machinery for eukaryotic pre-mRNAs. The splicing activity of group I self-splicing introns is dependent on an absolutely conserved and exceptionally densely packed core region composed of two helical domains, P3-P7 and P4-P6, that are connected rigidly via base triples. Here we show that a mutant group I intron ribozyme lacking both the P4-P6 domain and the base triples can perform the phosphoester transfer reactions required for splicing at both the 5' and 3' splice sites, demonstrating that the elements required for splicing are concentrated in the stacked helical P3-P7 domain. This finding establishes that the conserved core of the intron consists of two physically and functionally separable components, and we present a model showing the architecture of a prototype of this class of intron and the course of its molecular evolution.     

Thermodynamics and kinetics for base-pair opening in the P1 duplex of the Tetrahymena group I ribozyme

The thermodynamics and kinetics for base-pair opening of the P1 duplex of the Tetrahymena group I ribozyme were studied by NMR hydrogen exchange experiments. The apparent equilibrium constants for base pair opening were measured for most of the imino protons in the P1 duplex using the base catalysts NH3, HPO4(2-) or TRIS. These equilibrium constants were also measured for several modified P1 duplexes, and the C-2.G23 base pair was the most stable base pair in all the duplexes. The conserved U-1*G22 base pair is required for activity of the ribozyme and the data here show that this wobble base pair destabilizes neighboring base pairs on only one side of the wobble. A 2'-OMe modification on the U-3 residue stabilized its own base pair but had little effect on the neighboring base pairs. Three base pairs, U-1*G22, C-2*G23 and A2*U21 showed unusual equilibrium constants for opening and possible implications of the opening thermodynamics of these base pairs on the undocking rates of the P1 helix with catalytic core are discussed.     

RNA splicing: group I intron crystal structures reveal the basis of splice site selection and metal ion catalysis

The group I intron has served as a model for RNA catalysis since its discovery 25 years ago. Four recently determined high-resolution crystal structures complement extensive biochemical studies on this system. Structures of the Azoarcus, Tetrahymena and bacteriophage Twort group I introns mimic different states of the splicing or ribozyme reaction pathway and provide information on splice site selection and metal ion catalysis. The 5'-splice site is selected by formation of a conserved G.U wobble pair between the 5'-exon terminus and the intron. The 3'-splice site is identified through stacking of three base triples, in which the middle triple contains the conserved terminal nucleotide of the intron, OmegaG. The structures support a two-metal-ion mechanism for group I intron splicing that might have corollaries to group II intron and pre-mRNA splicing by the spliceosome.     

A peripheral element assembles the compact core structure essential for group I intron self-splicing

The presence of non-conserved peripheral elements in all naturally occurring group I introns underline their importance in ensuring the natural intron function. Recently, we reported that some peripheral elements are conserved in group I introns of IE subgroup. Using self-splicing activity as a readout, our initial screening revealed that one such conserved peripheral elements, P2.1, is mainly required to fold the catalytically active structure of the Candida ribozyme, an IE intron. Unexpectedly, the essential function of P2.1 resides in a sequence-conserved short stem of P2.1 but not in a long-range interaction associated with the loop of P2.1 that stabilizes the ribozyme structure. The P2.1 stem is indispensable in folding the compact ribozyme core, most probably by forming a triple helical interaction with two core helices, P3 and P6. Surprisingly, although the ribozyme lacking the P2.1 stem renders a loosely folded core and the loss of self-splicing activity requires two consecutive transesterifications, the mutant ribozyme efficiently catalyzes the first transesterification reaction. These results suggest that the intron self-splicing demands much more ordered structure than does one independent transesterification, highlighting that the universally present peripheral elements achieve their functional importance by enabling the highly ordered structure through diverse tertiary interactions.     

A catalytically active group II intron domain 5 can function in the U12-dependent spliceosome

Both spliceosomal and self-splicing group II introns require the function of similar small, metal binding RNA stem-loop elements located in U6 or U6atac snRNAs of the spliceosome or domain 5 (D5) of group II introns. Here we report that two different D5 elements can functionally replace the U6atac snRNA stem-loop in an in vivo splicing assay. For efficient function in vivo, a single base pair from the upper helical section of the D5 sequence had to be removed. Introducing the equivalent base pair deletion into the D5 element of a group II intron reduced but did not eliminate self-splicing activity. Our results strengthen the case that these RNA elements play similar roles in the catalytic centers of both the spliceosome and a self-splicing ribozyme.     

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.     

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.     

The structure of the L3 loop from the hepatitis delta virus ribozyme: a syn cytidine.

The structure of the L3 central hairpin loop isolated from the antigenomic sequence of the hepatitis delta virus ribozyme with the P2 and P3 stems from the ribozyme stacked on top of the loop has been determined by NMR spectroscopy. The 26 nt stem-loop structure contains nine base pairs and a 7 nt loop (5'-UCCUCGC-3'). This hairpin loop is critical for efficient catalysis in the intact ribozyme. The structure was determined using homonuclear and heteronuclear NMR techniques on non-labeled and15N-labeled RNA oligonucleotides. The overall root mean square deviation for the structure was 1.15 A (+/- 0.28 A) for the loop and the closing C.G base pair and 0.90 A (+/- 0.18 A) for the loop and the closing C.G base pair but without the lone purine in the loop, which is not well defined in the structure. The structure indicates a U.C base pair between the nucleotides on the 5'- and 3'-ends of the loop. This base pair is formed with a single hydrogen bond involving the cytosine exocyclic amino proton and the carbonyl O4 of the uracil. The most unexpected finding in the loop is a syn cytidine. While not unprecedented, syn pyrimidines are highly unusual. This one can be confidently established by intranucleotide distances between the ribose and the base determined by NMR spectroscopy. A similar study of the structure of this loop showed a somewhat different three-dimensional structure. A discussion of differences in the two structures, as well as possible sites of interaction with the cleavage site, will be presented.