Three essential and conserved regions of the group II intron are proximal to the 5'-splice site

Despite the central role of group II introns in eukaryotic gene expression and their importance as biophysical and evolutionary model systems, group II intron tertiary structure is not well understood. In order to characterize the architectural organization of intron ai5gamma, we incorporated the photoreactive nucleotides s(4)U and s(6)dG at specific locations within the intron core and monitored the formation of cross-links in folded complexes. The resulting data reveal the locations for many of the most conserved, catalytically important regions of the intron (i.e., the J2/3 linker region, the IC1(i-ii) bulge in domain 1, the bulge of D5, and the 5'-splice site), showing that all of these elements are closely colocalized. In addition, we show by nucleotide analog interference mapping (NAIM) that a specific functional group in J2/3 plays a role in first-step catalysis, which is consistent with its apparent proximity to other first-step components. These results extend our understanding of active-site architecture during the first step of group II intron self-splicing and they provide a structural basis for spliceosomal comparison.     

Structure-function analysis from the outside in: long-range tertiary contacts in RNA exhibit distinct catalytic roles

The conserved catalytic core of the Tetrahymena group I ribozyme is encircled by peripheral elements. We have conducted a detailed structure-function study of the five long-range tertiary contacts that fasten these distal elements together. Mutational ablation of each of the tertiary contacts destabilizes the folded ribozyme, indicating a role of the peripheral elements in overall stability. Once folded, three of the five tertiary contact mutants exhibit defects in overall catalysis that range from 20- to 100-fold. These and the subsequent results indicate that the structural ring of peripheral elements does not act as a unitary element; rather, individual connections have distinct roles as further revealed by kinetic and thermodynamic dissection of the individual reaction steps. Ablation of P14 or the metal ion core/metal ion core receptor (MC/MCR) destabilizes docking of the substrate-containing P1 helix into tertiary interactions with the ribozyme's conserved core. In contrast, ablation of the L9/P5 contact weakens binding of the guanosine nucleophile by slowing its association, without affecting P1 docking. The P13 and tetraloop/tetraloop receptor (TL/TLR) mutations had little functional effect and small, local structural changes, as revealed by hydroxyl radical footprinting, whereas the P14, MC/MCR, and L9/P5 mutants show structural changes distal from the mutation site. These changes extended into regions of the catalytic core involved in docking or guanosine binding. Thus, distinct allosteric pathways couple the long-range tertiary contacts to functional sites within the conserved core. This modular functional specialization may represent a fundamental strategy in RNA structure-function interrelationships.     

Metal ion binding sites in a group II intron core

Group II introns are catalytic RNA molecules that require divalent metal ions for folding, substrate binding, and chemical catalysis. Metal ion binding sites in the group II core have now been elucidated by monitoring the site-specific RNA hydrolysis patterns of bound ions such as Tb(3+) and Mg(2+). Major sites are localized near active site elements such as domain 5 and its surrounding tertiary interaction partners. Numerous sites are also observed at intron substructures that are involved in binding and potentially activating the splice sites. These results highlight the locations of specific metal ions that are likely to play a role in ribozyme catalysis.     

Distinct sites of phosphorothioate substitution interfere with folding and splicing of the Anabaena group I intron

Although the active site of group I introns is phylogenetically conserved, subclasses of introns have evolved different mechanisms of stabilizing the catalytic core. Large introns contain weakly conserved 'peripheral' domains that buttress the core through predicted interhelical contacts, while smaller introns use loop-helix interactions for stability. In all cases, specific and non-specific magnesium ion binding accompanies folding into the active structure. Whether similar RNA-RNA and RNA-magnesium ion contacts play related functional roles in different introns is not clear, particularly since it can be difficult to distinguish interactions directly involved in catalysis from those important for RNA folding. Using phosphorothioate interference with RNA activity and structure in the small (249 nt) group I intron from Anabaena, we used two independent assays to detect backbone phosphates important for catalysis and those involved in intron folding. Comparison of the interference sites identified in each assay shows that positions affecting catalysis cluster primarily in the conserved core of the intron, consistent with conservation of functionally important phosphates, many of which are magnesium ion binding sites, in diverse group I introns, including those from Azoarcus and Tetrahymena. However, unique sites of folding interference located outside the catalytic core imply that different group I introns, even within the same subclass, use distinct sets of tertiary interactions to stabilize the structure of the catalytic core.     

Selection of the 3′-splice site in group I introns

A model for selection of 3′-splice sites in splicing of RNA precursors containing group I introns is presented. The key feature of this model is a newly identified tertiary interaction between the catalytic core of the intron and the 3′-splice site. This tertiary pairing would bring the 3′-splice site into the core of the intron, which is known to contain RNA sequences and structures essential for catalyzing the splicing reactions. The proposed tertiary interaction can coexist with P10, a pairing between 3′-exon sequences and the ‘internal guide sequence’ near the 5′-end of the intron. The model predicts that three RNA-RNA interactions are important in selection of 3′-splice sites: (i) binding of intron sequences with the core; (ii) pairing of exon sequences with the internal guide sequence; and (iii) binding of the terminal guanosine to an unknown site within the core.     

Assembly of an exceptionally stable RNA tertiary interface in a group I ribozyme

Group I intron RNAs contain a core of highly conserved helices flanked by peripheral domains that stabilize the core structure. In the Tetrahymena group I ribozyme, the P4, P5, and P6 helices of the core pack tightly against a three-helix subdomain called P5abc. Chemical footprinting and the crystal structure of the Tetrahymena intron P4-P6 domain revealed that tertiary interactions between these two parts of the domain create an extensive solvent-inaccessible interface. We have examined the formation and stability of this tertiary interface by providing the P5abc segment in trans to a Tetrahymena ribozyme construct that lacks P5abc (EDeltaP5abc). Equilibrium gel shift experiments show that the affinity of the P5abc and EDeltaP5abc RNAs is exceptionally strong, with a Kd of approximately 100 pM at 10 mM MgCl2 (at 37 degrees C). Chemical and enzymatic footprinting shows that the RNAs are substantially folded prior to assembly of the complex. Solvent accessibility mapping reveals that, in the absence of P5abc, the intron RNA maintains a nativelike fold but its active-site helices are not tightly packed. Upon binding of P5abc, the catalytic core becomes more tightly packed through indirect effects of the tertiary interface formation. This two-component system facilitates quantitative examination of individual tertiary contacts that stabilize the folded intron.     

Visualizing the solvent-inaccessible core of a group II intron ribozyme

Group II introns are well recognized for their remarkable catalytic capabilities, but little is known about their three-dimensional structures. In order to obtain a global view of an active enzyme, hydroxyl radical cleavage was used to define the solvent accessibility along the backbone of a ribozyme derived from group II intron ai5gamma. These studies show that a highly homogeneous ribozyme population folds into a catalytically compact structure with an extensively internalized catalytic core. In parallel, a model of the intron core was built based on known tertiary contacts. Although constructed independently of the footprinting data, the model implicates the same elements for involvement in the catalytic core of the intron.     

Recognition elements for 5' exon substrate binding to the Candida albicans group I intron

A group I intron precursor and ribozyme were cloned from the large subunit rRNA of the human pathogen Candida albicans. Both the precursor and ribozyme are functional as determined from in vitro assays. Comparisons of dissociation constants for oligonucleotide binding to the ribozyme and to a hexanucleotide mimic of its internal guide sequence lead to a model for recognition of the 5' exon substrate by this intron. In particular, tertiary contacts with the P1 helix that help align the splice site include three 2'-hydroxyl groups, a G.U pair that occurs at the intron's splice junction, and a G.A pair. The free energy contribution that each interaction contributes to tertiary binding is determined. When the G.A pair is replaced with a G-C pair, tertiary interactions to 5' exon mimic 2'-hydroxyl groups are significantly weakened. When the G.A pair is replaced with a G.U pair, tertiary interactions are retained and binding is 10-fold tighter. These results expand our knowledge of substrate recognition by group I introns, and also provide a basis for rational design of oligonucleotide-based therapeutics for targeting group I introns by binding enhancement by tertiary interactions and suicide inhibition strategies.     

A novel mechanism for protein-assisted group I intron splicing

Previously it was shown that the Aspergillus nidulans (A.n.) mitochondrial COB intron maturase, I-AniI, facilitates splicing of the COB intron in vitro. In this study, we apply kinetic analysis of binding and splicing along with RNA deletion analysis to gain insight into the mechanism of I-AniI facilitated splicing. Our results are consistent with I-AniI and A.n. COB pre-RNA forming a specific but labile encounter complex that is resolved into the native, splicing-competent complex. Significantly, kinetic analysis of splicing shows that the resolution step is rate limiting for splicing. RNA deletion studies show that I-AniI requires most of the A.n. COB intron for binding suggesting that the integrity of the I-AniI-binding site depends on overall RNA tertiary structure. These results, taken together with the observation that A.n. COB intron lacks significant stable tertiary structure in the absence of protein, support a model in which I-AniI preassociates with an unfolded COB intron via a "labile" interaction that facilitates correct folding of the intron catalytic core, perhaps by resolving misfolded RNAs or narrowing the number of conformations sampled by the intron during its search for native structure. The active intron conformation is then "locked in" by specific binding of I-Anil to its intron interaction site.     

A three-dimensional perspective on exon binding by a group II self-splicing intron

We have used chemical footprinting, kinetic dissection of reactions and comparative sequence analysis to show that in self-splicing introns belonging to subgroup IIB, the sites that bind the 5' and 3' exons are connected to one another by tertiary interactions. This unanticipated arrangement, which contrasts with the direct covalent linkage that prevails in the other major subdivision of group II (subgroup IIA), results in a unique three-dimensional architecture for the complex between the exons, their binding sites and intron domain V. A key feature of the modeled complex is the presence of several close contacts between domain V and one of the intron-exon pairings. These contacts, whose existence is supported by hydroxyl radical footprinting, provide a structural framework for the known role of domain V in catalysis and its recently demonstrated involvement in binding of the 5' exon.     

Uracil interference, a rapid and general method for defining protein-DNA interactions involving the 5-methyl group of thymines: the GCN4-DNA complex.

We describe a novel uracil interference method for examining protein contacts with the 5-methyl group of thymines. The protein of interest is incubated with target DNA containing randomly distributed deoxyuracil substitutions that is generated by carrying out the polymerase chain reaction in the presence of a mixture of TTP and dUTP. After separating DNA-protein complexes away from unbound DNA, the locations of deoxyuracil residues that either do or do not interfere with DNA-binding are determined by cleavage with uracil-N-glycosylase followed by piperidine. Using this uracil interference assay, we show that the methyl groups of the four core thymines, but not the two peripheral thymines, of the optimal binding site (ATG-ACTCAT) are important for high affinity binding of GCN4. Similar, but not identical, results are obtained using KMnO4 interference, another method used for studying protein-DNA interactions involving thymine residues. These observations strongly suggest that GCN4 directly contacts the 5-methyl groups of the four core thymines that lie in the major groove of the target DNA. Besides providing specific structural information about protein-DNA complexes, uracil interference should also be useful for identifying DNA-binding proteins and their target sites in eukaryotic promoter regions.     

Defining functional groups, core structural features and inter-domain tertiary contacts essential for group II intron self-splicing: a NAIM analysis.

Group II introns are self-splicing RNA molecules that are of considerable interest as ribozymes, mobile genetic elements and examples of folded RNA. Although these introns are among the most common ribozymes, little is known about the chemical and structural determinants for their reactivity. By using nucleotide analog interference mapping (NAIM), it has been possible to identify the nucleotide functional groups (Rp phosphoryls, 2'-hydroxyls, guanosine exocyclic amines, adenosine N7 and N6) that are most important for composing the catalytic core of the intron. The majority of interference effects occur in clusters located within the two catalytically essential Domains 1 and 5 (D1 and D5). Collectively, the NAIM results indicate that key tetraloop-receptor interactions display a specific chemical signature, that the epsilon-epsilon' interaction includes an elaborate array of additional features and that one of the most important core structures is an uncharacterized three-way junction in D1. By combining NAIM with site-directed mutagenesis, a new tertiary interaction, kappa-kappa', was identified between this region and the most catalytically important section of D5, adjacent to the AGC triad in stem 1. Together with the known zeta-zeta' interaction, kappa-kappa' anchors D5 firmly into the D1 scaffold, thereby presenting chemically essential D5 functionalities for participation in catalysis.     

An RNA binding motif in the Cbp2 protein required for protein-stimulated RNA catalysis.

The fifth and terminal intron of yeast cytochrome b pre-mRNA (a group I intron) requires a protein encoded by the nuclear gene CBP2 for splicing. Because catalysis is intrinsic to the RNA, the protein is believed to promote formation of secondary and tertiary structure of the RNA, resulting in a catalytically competent intron. In vitro, this mitochondrial intron can be made to self-splice or undergo protein-facilitated splicing by varying the Mg(2+) and monovalent salt concentrations. This two-component system, therefore, provides a good model for understanding the role of proteins in RNA folding. A UV cross-linking experiment was initiated to identify RNA binding sites on Cbp2 and gain insights into Cbp2-intron interactions. A 12-amino acid region containing a presumptive contact site near the amino terminus was targeted for mutagenesis, and mutant proteins were characterized for RNA binding and stimulation of splicing. Mutations in this region resulted in partial or complete loss of function, demonstrating the importance of this determinant for stimulation of RNA splicing. Several of the mutations that severely reduced splicing did not significantly shift the overall binding isotherm of Cbp2 for the precursor RNA, suggesting that contacts critical for activity are not necessarily reflected in the dissociation constant. This analysis has identified a unique RNA binding motif of alternating basic and aromatic residues that is essential for protein facilitated splicing.