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.     

Minimum secondary structure requirements for catalytic activity of a self-splicing group I intron

We have completed a comprehensive deletion analysis of the Tetrahymena ribozyme in order to define the minimum secondary structure requirements for phosphoester transfer activity of a self-splicing group I intron. A total of 299 nucleotides were removed in a piecewise fashion, leaving a catalytic core of 114 nucleotides that form 7 base-paired structural elements. Among the various deletion mutants are a 300-nucleotide single-deletion mutant and a 281-nucleotide double-deletion mutant whose activity exceeds that of the wild type when tested under physiologic conditions. Consideration of those structural elements that are essential for catalytic activity leads to a simplified secondary structure model of the catalytic core of a group I intron.     

One RNA plays three roles to provide catalytic activity to a group I intron lacking an endogenous internal guide sequence

Catalytic RNA molecules possess simultaneously a genotype and a phenotype. However, a single RNA genotype has the potential to adopt two or perhaps more distinct phenotypes as a result of differential folding and/or catalytic activity. Such multifunctionality would be particularly significant if the phenotypes were functionally inter-related in a common biochemical pathway. Here, this phenomenon is demonstrated by the ability of the Azoarcus group I ribozyme to function when its canonical internal guide sequence (GUG) has been removed from the 5′ end of the molecule, and added back exogenously in trans. The presence of GUG triplets in non-covalent fragments of the ribozyme allow trans-splicing to occur in both a reverse splicing assay and a covalent self-assembly assay in which the internal guide sequence (IGS)-less ribozyme can put itself together from two of its component pieces. Analysis of these reactions indicates that a single RNA fragment can perform up to three distinct roles in a reaction: behaving as a portion of a catalyst, behaving as a substrate, and providing an exogenous IGS. This property of RNA to be multifunctional in a single reaction pathway bolsters the probability that a system of self-replicating molecules could have existed in an RNA world during the origins of life on the Earth.     

Accommodation of Ca(II) ions for catalytic activity by a group I ribozyme

The wildtype Tetrahymena ribozyme cannot catalyze detectable levels of phosphotransfer activity in vitro on an exogenous RNA substrate oligonucleotide when calcium(II) is supplied as the only available divalent ion. Nevertheless, low-error mutants of this ribozyme have been acquired through directed evolution that do have activity in 10 mM CaCl₂. The mechanisms for such Ca(II) accommodation are not known. Here, we assayed the entire molecule in an effort to identify the roles of the mutations in allowing catalytic activity in Ca(II). We used four biochemical probing techniques - native-gel electrophoresis, hydroxyl radical footprinting, terbium(III) cleavage footprinting, and phosphorothioate interference mapping - to compare the solution structure of the wildtype ribozyme with that of a Ca(II)-active five-site mutant. We compared the gross folding patterns and specific metal-binding sites in both MgCl₂ and CaCl₂ solutions. We detected no large-scale folding differences between the two RNAs in either metal. However, we did discover a limited number of local folding differences, involving regions of the RNA affected by positions 42, 188, and 270. These data support the notion that Ca(II) is accommodated by the Tetrahymena ribozyme by a slight breathing at the active site, but that alterations at, near to, and distal from the active site can all contribute to Ca(II)-based activity.     

Inhibition of self-splicing group I intron RNA: high-throughput screening assays.

High-throughput screening assays have been developed to rapidly identify small molecule inhibitors targeting catalytic group I introns. Biochemical reactions catalyzed by a self-splicing group I intron derived from Pneumocystis carinii or from bacteriophage T4 have been investigated. In vitro biochemical assays amenable to high-throughput screening have been established. Small molecules that inhibit the functions of group I introns have been identified. These inhibitors should be useful in better understanding ribozyme catalysis or in therapeutic intervention of group I intron-containing microorganisms.     

A kinetic intermediate that regulates proper folding of a group II intron RNA

The D135 group II intron ribozyme follows a unique folding pathway that is direct and appears to be devoid of kinetic traps. During the earliest stages of folding, D135 collapses slowly to a compact intermediate, and all subsequent assembly events are rapid. Collapse of intron domain 1 (D1) has been shown to limit the rate constant for D135 folding, although the specific substructure of the D1 kinetic intermediate has not yet been identified. Employing time-resolved nucleotide analog interference mapping, we have identified a cluster of atoms within the D1 main stem that control the rate constant for D135 collapse. Functional groups within the κ-ζ element are particularly important for this earliest stage of folding, which is intriguing given that this same motif also serves later as the docking site for catalytic domain 5. More important, the κ-ζ element is shown to be a divalent ion binding pocket, indicating that this region is a Mg²⁺-dependent switch that initiates the cascade of D135 folding events. By measuring the Mg²⁺ dependence of the compaction rate constant, we conclude that the actual rate-limiting step in D1 compaction involves the formation of an unstable folding intermediate that is captured by the binding of Mg²⁺. This carefully orchestrated folding pathway, in which formation of an active-site docking region is early and rate limiting, ensures proper folding of the intron core and faithful splicing. It may represent an important paradigm for the folding of large, multidomain RNA molecules.     

Interlocked RNA circle formation by a self-splicing yeast mitochondrial group I intron

RNA containing the aI3 group I intron of the yeast mitochondrial gene encoding cytochrome oxidase subunit I shows self-splicing in vitro. The excised intron, comprising 1514 nucleotides, is partially split into an upstream portion, containing the intronic reading frame, and a downstream portion, containing the typical group I conserved sequence elements. Full-length intron RNA and intron parts occur in linear and circular form. In the transesterification reactions leading to circle formation, only the guanosine nucleotide added during splicing is removed. Reincubation of isolated, complete circular intron RNA under self-splicing conditions leads to formation of free subintronic RNA circles. Under similar conditions, purified linear intron RNA gives rise to a number of circular and linear products, one of which consists of interlocked subintronic RNA circles. These observations suggest that the intron RNA possesses a dynamic structure in which subtle alterations in folding result in the formation of RNA products with different topology.     

Monitoring intermediate folding states of the td group I intron in vivo

Group I introns consist of two major structural domains, the P4-P6 and P3-P9 domains, which assemble through interactions with peripheral extensions to fold into an active ribozyme. To assess group I intron folding in vivo, we probed the structure of td wild-type and mutant introns using dimethyl sulfate. The results suggest that the majority of the intron population is in the native state in accordance with the current structural model, which was refined to include two novel tertiary contacts. The importance of the loop E motif in the P7.1-P7.2 extension in assisting ribozyme folding was deduced from modeling and mutational analyses. Destabilization of stem P6 results in a deficiency in tertiary structure formation in both major domains, while weakening of stem P7 only interferes with folding of the P3-P9 domain. The different impact of mutations on the tertiary structure suggests that they interfere with folding at different stages. These results provide a first insight into the structure of folding intermediates and suggest a putative order of events in a hierarchical folding pathway in vivo.     

New pathways in folding of the Tetrahymena group I RNA enzyme.

Previous studies have shown that the earliest detectable step in folding of the Tetrahymena ribozyme is tertiary structure formation of the peripheral element P5abc. This, along with other results, has suggested that P5abc may serve as a scaffold upon which additional tertiary structure is built. Herein we use the onset of oligonucleotide cleavage activity as a readout for native state formation and investigate the effect of P5abc on the rate of folding to the native structure. Despite the early folding of P5abc, its removal to give the E delta P5abc variant decreases the rate of attainment of an active structure less than fivefold (20-100 mM Mg2+, 15-50 degrees C). Furthermore, P5abc added in trans is able to bind the folded E delta P5abc ribozyme and promote oligonucleotide cleavage at least tenfold more rapidly than folding of the wild-type ribozyme, indicating that E delta P5abc does not have to first unfold before productively binding P5abc to form the true native state. This suggests that a state with the overall tertiary structure formed but with P5abc unfolded represents a viable on-pathway intermediate for the wild-type ribozyme. These results provide strong evidence for the existence of two pathways to the native state: in one pathway P5abc forms tertiary structure first, and in another it forms late. The pathway in which P5abc forms first is favored because P5abc can fold quickly and because its tertiary structure is stable in the absence of additional structured elements, not because P5abc formation is required for subsequent folding steps. In the course of these experiments, we also found that most of the ribozyme population does not reach the native state directly under standard conditions in vitro, but instead forms an inactive structure that is stable for hours. Finally, the fraction that does fold to the native state folds with a single rate constant of 1 min-1, suggesting that there are no significantly populated "fast-track" pathways that reach the native state directly by avoiding slow folding steps.     

Productive folding to the native state by a group II intron ribozyme.

Group II introns are large catalytic RNA molecules that fold into compact structures essential for the catalysis of splicing and intron mobility reactions. Despite a growing body of information on the folded state of group II introns at equilibrium, there is currently no information on the folding pathway and little information on the ionic requirements for folding. Folding isotherms were determined by hydroxyl radical footprinting for the 32 individual protections that are distributed throughout a group II intron ribozyme derived from intron ai5gamma. The isotherms span a similar range of Mg(2+) concentrations and share a similar index of cooperativity. Time-resolved hydroxyl radical footprinting studies show that all regions of the ribozyme fold slowly and with remarkable synchrony into a single catalytically active structure at a rate comparable to those of other ribozymes studied thus far. The rate constants for the formation of tertiary contacts and recovery of catalytic activity are identical within experimental error. Catalytic activity analyses in the presence of urea provide no evidence that the slow folding of the ai5gamma intron is attributable to the presence of unproductive kinetic traps along the folding pathway. Taken together, the data suggest that the rate-limiting step for folding of group II intron ai5gamma occurs early along the reaction pathway. We propose that this behavior resembles protein folding that is limited in rate by high contact order, or the need to form key tertiary interactions from partners that are located far apart in the primary or secondary structure.     

In vitro self-splicing reactions of the chloroplast group I intron Cr.LSU from Chlamydomonas reinhardtii and in vivo manipulation via gene-replacement.

The group I intron from the chloroplast rRNA large subunit of Chlamydomonas reinhardtii (Cr.LSU) undergoes autocatalytic splicing in vitro. Cr.LSU displays a range of reactions typical of other group I introns. Under optimal conditions, the 5' cleavage step proceeds rapidly, but the exon-ligation step is relatively slow, and no pH dependent hydrolysis of the 3' splice site occurs. A requirement for high temperature and high [Mg2+] suggests involvement of additional splicing factors in vivo. The positions of three cyclization sites of the free intron have been mapped; two of these sites represent reactions analogous to 5'-splice site cleavage, whereas the third is an example of G-exchange. Cr.LSU contains an open reading frame (ORF) potentially encoding an 163 amino acid polypeptide. ORF function has been investigated by using chloroplast gene replacement via particle bombardment. We have shown that the ORF can be deleted from Cr.LSU without affecting splicing in vivo and it thus does not encode an essential splicing factor.     

In vivo facilitation of Tetrahymena group I intron splicing in Escherichia coli pre-ribosomal RNA.

The observation that the large ribosomal RNA intron of Tetrahymena is spliced 20-50-fold more rapidly in vivo than in vitro (Brehm SL, Cech TR, 1983, Biochemistry 22:2390-2397; Bass BL, Cech TR, 1984, Nature 308:820-826) suggests facilitation of RNA folding in vivo. To determine whether a specific group I splicing factor is required in Tetrahymena, the intron was inserted into the analogous position of the Escherichia coli 23S rRNA. We report that the intron is rapidly excised from pre-rRNA in bacteria and that the magnitude of the in vivo rate enhancement is similar to that in Tetrahymena. These results demonstrate that a species-specific protein is not required. Instead, a common mechanism of assisting RNA folding is sufficient to accelerate the removal of self-splicing introns from ribosomal RNA.