Crystal structure of a self-splicing group I intron with both exons.

The discovery of the RNA self-splicing group I intron provided the first demonstration that not all enzymes are proteins. Here we report the X-ray crystal structure (3.1-A resolution) of a complete group I bacterial intron in complex with both the 5'- and the 3'-exons. This complex corresponds to the splicing intermediate before the exon ligation step. It reveals how the intron uses structurally unprecedented RNA motifs to select the 5'- and 3'-splice sites. The 5'-exon's 3'-OH is positioned for inline nucleophilic attack on the conformationally constrained scissile phosphate at the intron-3'-exon junction. Six phosphates from three disparate RNA strands converge to coordinate two metal ions that are asymmetrically positioned on opposing sides of the reactive phosphate. This structure represents the first splicing complex to include a complete intron, both exons and an organized active site occupied with metal ions.

Exploration of the conserved A+C wobble pair within the ribosomal peptidyl transferase center using affinity purified mutant ribosomes.

Protein synthesis in the ribosome's large subunit occurs within an active site comprised exclusively of RNA. Mutational studies of rRNA active site residues could provide valuable insight into the mechanism of peptide bond formation, but many of these mutations cause a dominant lethal phenotype, which prevents production of the homogeneous mutant ribosomes needed for analysis. We report a general method to affinity purify in vivo assembled 50S ribosomal subunits containing lethal active site mutations via a U1A protein-binding tag inserted onto the 23S rRNA. The expected pH-dependent formation of the A2450+C2063 wobble pair has made it a potential candidate for the pH-dependent conformational change that occurs within the ribosomal active site. Using this approach, the active site A2450+C2063 pair was mutated to the isosteric, but pH-independent, G2450*U2063 wobble pair, and 50S subunits containing the mutations were affinity purified. The G*U mutation caused the adjacent A2451 to become hyper-reactive to dimethylsulfate (DMS) modification in a pH-independent manner. Furthermore, the G*U mutation decreased both the rate of peptide bond formation and the affinity of the post-translocation complex for puromycin. The reaction rate (k(pep)) was reduced approximately 200-fold for both puromycin and the natural aminoacyl-tRNA A-site substrate. The mutations also substantially altered the pH dependence of the reaction. Mutation of this base pair has significant deleterious effects upon peptidyl transferase activity, but because G*U mutation disrupts several tertiary contacts with the wobble pair, the assignment of A2450 as the active site residue with the neutral pK(a) important for the peptidyl transferase reaction cannot be fully supported or excluded based upon these data.

Identification of an active site ligand for a group I ribozyme catalytic metal ion.

The transition state of the group I intron self-splicing reaction is stabilized by three metal ions. The functional groups within the intron substrates (guanosine and an oligoribonucleotide mimic of the 5'-exon) that coordinate these metal ions have been systematically defined through a series of metal ion specificity switch experiments. In contrast, the catalytic metal ligands within the ribozyme active site are unknown. In an effort to identify them, stereospecific (R(P) or S(P)) single-site phosphorothioate substitutions were introduced at five phosphates predicted to be in the vicinity of the catalytic center (A207, C208, A304, U305, and A306) within the Tetrahymena intron. Of the 10 ribozymes that were studied, four phosphorothioate substitutions (A207 S(P), C208 S(P), A306 R(P), and A306 S(P)) exhibited a significant reduction in the cleavage rate. Only the effect of the C208 S(P) phosphorothioate substitution could be significantly rescued by the addition of a thiophilic metal ion, either Mn(2+) or Zn(2+), when tested with an all-oxy substrate. The effect was not rescued with Cd(2+). To determine if one of the catalytic metal ions is coordinated to the C208 pro-S(P) oxygen, the phosphorothioate-substituted ribozymes were also assayed using oligonucleotide substrates with a 3'-phosphorothiolate or an S(P) phosphorothioate substitution at the scissile phosphate. This resulted in a second metal specificity switch, in that Mn(2+) or Zn(2+) no longer rescued the C208 S(P) ribozyme, but Cd(2+) provided efficient rescue in the context of either sulfur-containing substrate. The 3'-oxygen and the pro-S(P) oxygen of the scissile phosphate are both known to coordinate the same metal ion, M(A), which stabilizes the negative charge on the leaving group 3'-oxygen in the transition state. Taken together, these data suggest that metal M(A) is coordinated to the C208 pro-S(P) phosphate oxygen, which constitutes the first functional link between a specific catalytic metal ion and a particular functional group within the group I ribozyme active site.

Crystal structure of a group I intron splicing intermediate.

A recently reported crystal structure of an intact bacterial group I self-splicing intron in complex with both its exons provided the first molecular view into the mechanism of RNA splicing. This intron structure, which was trapped in the state prior to the exon ligation reaction, also reveals the architecture of a complex RNA fold. The majority of the intron is contained within three internally stacked, but sequence discontinuous, helical domains. Here the tertiary hydrogen bonding and stacking interactions between the domains, and the single-stranded joiner segments that bridge between them, are fully described. Features of the structure include: (1) A pseudoknot belt that circumscribes the molecule at its longitudinal midpoint; (2) two tetraloop-tetraloop receptor motifs at the peripheral edges of the structure; (3) an extensive minor groove triplex between the paired and joiner segments, P6-J6/6a and P3-J3/4, which provides the major interaction interface between the intron's two primary domains (P4-P6 and P3-P9.0); (4) a six-nucleotide J8/7 single stranded element that adopts a mu-shaped structure and twists through the active site, making critical contacts to all three helical domains; and (5) an extensive base stacking architecture that realizes 90% of all possible stacking interactions. The intron structure was validated by hydroxyl radical footprinting, where strong correlation was observed between experimental and predicted solvent accessibility. Models of the pre-first and pre-second steps of intron splicing are proposed with full-sized tRNA exons. They suggest that the tRNA undergoes substantial angular motion relative to the intron between the two steps of splicing.