In the second step of the two consecutive transesterifications of the self-splicing reaction of the group I intron, the conserved guanosine at the 3′ terminus of the intron (ωG) binds to the guanosine-binding site (GBS) in the intron. In the present study, we designed a 22-nt model RNA (GBS/ωG) including the GBS and ωG from the Tetrahymena group I intron, and determined the solution structure by NMR methods. In this structure, ωG is recognized by the formation of a base triple with the G264[bull ]C311 base pair, and this recognition is stabilized by the stacking interaction between ωG and C262. The bulged structure at A263 causes a large helical twist angle (40 ± 8°) between the G264[bull ]C311 and C262[bull ]G312 base pairs. We named this type of binding pocket with a bulge and a large twist, formed on the major groove, a “Bulge-and-Twist” (BT) pocket. With another twist angle between the C262[bull ]G312 and G413[bull ]C313 base pairs (45 ± 10°), the axis of GBS/ωG is kinked at the GBS region. This kinked axis superimposes well on that of the corresponding region in the structure model built on a 5.0 Å resolution electron density map (Golden et al., Science, 1998, 282:345–358). This compact structure of the GBS is also consistent with previous biochemical studies on group I introns. The BT pockets are also found in the arginine-binding site of the HIV-TAR RNA, and within the 16S rRNA and the 23S rRNA.

Self-splicing of the Tetrahymena pre-rRNA is inhibited by a conserved rRNA hairpin P(−1) upstream of the 5′ splice site. P(−1) inhibits self-splicing by competing with formation of the P1 splice site helix. Here we show that the P(−1) hairpin also enhances dissociation of the spliced products, which was monitored by native gel electrophoresis. Mutations that stabilize the rRNA hairpin increase the rate of dissociation approximately 10-fold, from 0.5 min−1 for the wild-type RNA to ∼4 min−1 at 30 °C. Conversely, mutations or oligonucleotides that inhibit refolding of the exons and that stabilize the P1 helix decrease the rate of product release. The results suggest that refolding of products can be used to stimulate the turnover of ribozyme-catalyzed reactions. In the pre-rRNA, this conformational change helps shift the equilibrium of self-splicing toward the mature rRNA.

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 ScaI 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 [lhard ][rharu ] CCCUCU + NNGA5. UCG, predicted to form two base pairs in P9.0, reacts with a (kcat/KM) value ∼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 ∼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.

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 5γ (aI5γ) 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 aI5γ and from the group IIA intron, aI1. Trans-splicing experiments show that the crosslinked wild-type aI5γ 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 aI5γ 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.

Domain 6 (D6) of group II introns contains a bulged adenosine that serves as the branch-site during self-splicing. In addition to this adenosine, other structural features in D6 are likely to contribute to the efficiency of branching. To understand their role in promoting self-splicing, the branch-site and surrounding nucleotides were mutagenized. Detailed kinetic analysis on the self-splicing efficiency of the mutants revealed several interesting features. First, elimination of the branch-site does not preclude efficient splicing, which takes place instead through a hydrolytic first step. Second, pairing of the branch-site does not eliminate branching, particularly if the adenosine is involved in a mispair. Third, the G-U pairs that often surround group II intron branch-points contribute to the efficiency of branching. These results suggest that there is a strong driving force for promoting self-splicing by group II introns, which employ a versatile set of different mechanisms for ensuring that splicing is successful. In addition, the behavior of these mutants indicates that a bulged adenosine per se is not the important determinant for branch-site recognition in group II introns. Rather, the data suggest that the branch-site adenosine is recognized as a flipped base, a conformation that can be promoted by a variety of different substructures in RNA and DNA.

Self-splicing of the Tetrahymena group I intron is attenuated by an rRNA stem-loop in the 5′ exon, which competes with formation of the P1 splice site helix. The equilibrium between the P1 and P(−1) stem-loops is influenced by rRNA sequences upstream and downstream of the intron. To investigate the mechanism of this conformational switch, internal deletions and point mutations were introduced in the second rRNA stem-loop upstream of the 5′ splice site. Nuclease protection, native gel electrophoresis, and self-splicing results show that this helix is important for maintaining self-splicing activity. Co-axial base stacking of adjacent helices in the 5′ exon is proposed to enable exchange between inactive and active conformations of the pre-rRNA.

Substrate sequences surrounding catalytic RNAs but not involved in specific, conserved interactions can severely interfere with in vitro ribozyme activity. Using model group II intron precursor transcripts with truncated or randomized exon sequences, we show that unspecific sequences within the 5′ exon are particularly prone to inhibit both the forward and the reverse first splicing step (branching). Using in vitro selection, we selected efficient 5′ exons for the reverse branching reaction. Precursor RNAs carrying these selected 5′ exons reacted more homogeneously and faster than usual model precursor transcripts. This suggests that unfavorable structures induced by the 5′ exon can introduce a folding step that limits the rate of in vitro self-splicing. These results stress how critical is the choice of the sequences retained or discarded when isolating folding domains from their natural sequence environments. Moreover, they suggest that exon sequences not involved in specific interactions are more evolutionarily constrained with respect to splicing than previously envisioned.