Splice site selection by intron aI3 of the COX1 gene from Saccharomyces cerevisiae.

Interactions of the 5' and 3' splice sites with intron internal sequences of the yeast mitochondrial group I intron aI3 were studied using mutation analysis. The results can be fully explained by the splice guide model in which the splice sites are defined by the Internal Guide Sequence. No evidence was found for an alternative interaction between intron nucleotides preceding the 3' splice site and nucleotides in the vicinity of the core region as was found for the Tetrahymena intron. Our results also suggest that binding of the 5' and 3' splice site nucleotides to the IGS can not take place simultaneously. The intron must therefore undergo conformational changes as the reaction proceeds from the first step of self splicing, GTP attack at the 5' splice site, to exon ligation, the second step.     

Divalent metal ions promote the formation of the 5'-splice site recognition complex in a self-splicing group II intron

Group II introns are ribozymes occurring in genes of plants, fungi, lower eukaryotes, and bacteria. These large RNA molecular machines, ranging in length from 400 to 2500 nucleotides, are able to catalyze their own excision from pre-mRNA, as well as to reinsert themselves into RNA or sometimes even DNA. The intronic domain 1 contains two sequences (exon binding sites 1 and 2, EBS1 and EBS2) that pair with their complementary regions at the 3′-end of the 5′-exon (intron binding sites 1 and 2, IBS1 and IBS2) such defining the 5′-splice site. The correct recognition of the 5′-splice site stands at the beginning of the two steps of splicing and is thus crucial for catalysis. It is known that metal ions play an important role in folding and catalysis of ribozymes in general. Here, we characterize the specific metal ion requirements for the formation of the 5′-splice site recognition complex from the mitochondrial yeast group II intron Sc.ai5γ. Circular dichroism studies reveal that the formation of the EBS1 · IBS1 duplex does not necessarily require divalent metal ions, as large amounts of monovalent metal ions also promote the duplex, albeit at a 5000 times higher concentration. Nevertheless, micromolar amounts of divalent metal ions, e.g. Mg²⁺ or Cd²⁺, strongly promote the formation of the 5′-splice site. These observations illustrate that a high charge density independent of the nature of the ion is needed for binding EBS1 to IBS1, but divalent metal ions are presumably the better players.     

Assessment of a model for intron RNA secondary structure relevant to RNA self-splicing--a review

A widespread class of introns is characterized by a particular RNA secondary structure, based upon four conserved nucleotide sequences. Among such "class I" introns are found the majority of introns in fungal mitochondrial genes and the self-splicing intron of the large ribosomal RNA of several species of Tetrahymena. A model of the RNA secondary structure, which must underlie the self-splicing activity, is here evaluated in the light of data on 16 further introns. The main body or "core structure" of the intron always consists of the base-paired regions P3 to P9 with the associated single-stranded loops, with P2 present also in most cases. Two minority sub-classes of core structure occur, one of which is typical of introns in fungal ribosomal RNA. Introns in which the core structure is close to the 5' splice site all have an internal guide sequence (IGS) which can pair with exon sequences adjacent to the 5' and 3' splice sites to align them precisely, as proposed by Davies et al. [Nature 300 (1982) 719-724]. In these cases, the internal guide model allows us to predict correctly the exact location of splice sites. All other introns probably use other mechanisms of alignment. This analysis provides strong support for the RNA splicing model which we have developed.     

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.     

The Mrs1 Splicing Factor Binds the bI3 Group I Intron at Each of Two Tetraloop-Receptor Motifs

Most large ribozymes require protein cofactors in order to function efficiently. The yeast mitochondrial bI3 group I intron requires two proteins for efficient splicing, Mrs1 and the bI3 maturase. Mrs1 has evolved from DNA junction resolvases to function as an RNA cofactor for at least two group I introns; however, the RNA binding site and the mechanism by which Mrs1 facilitates splicing were unknown. Here we use high-throughput RNA structure analysis to show that Mrs1 binds a ubiquitous RNA tertiary structure motif, the GNRA tetraloop-receptor interaction, at two sites in the bI3 RNA. Mrs1 also interacts at similar tetraloop-receptor elements, as well as other structures, in the self-folding Azoarcus group I intron and in the RNase P enzyme. Thus, Mrs1 recognizes general features found in the tetraloop-receptor motif. Identification of the two Mrs1 binding sites now makes it possible to create a model of the complete six-component bI3 ribonucleoprotein. All protein cofactors bind at the periphery of the RNA such that every long-range RNA tertiary interaction is stabilized by protein binding, involving either Mrs1 or the bI3 maturase. This work emphasizes the strong evolutionary pressure to bolster RNA tertiary structure with RNA-binding interactions as seen in the ribosome, spliceosome, and other large RNA machines.     

Structural requirement for Mg2+ binding in the group I intron core

Divalent metal ions are required for splicing of group I introns, but their role in maintaining the structure of the active site is still under investigation. Ribonuclease and hydroxyl radical footprinting of a small group I intron from Azoarcus pre-tRNA(Ile) showed that tertiary interactions between helical domains are stable in a variety of cations. Only Mg(2+), however, induced a conformational change in the intron core that correlates with self-splicing activity. Three metal ion binding sites in the catalytic core were identified by Tb(III)-dependent cleavage. Two of these are near bound substrates in a three-dimensional model of the ribozyme. A third metal ion site is near an A minor motif in P3. In the pre-tRNA, Tb(3+) cleavage was redirected to the 5' and 3' splice sites, consistent with metal-dependent activation of splice site phosphodiesters. The results show that many counterions induce global folding, but organization of the group I active site is specifically linked to Mg(2+) binding at a few sites.     

Determination of an RNA structure involved in splicing inhibition of a muscle-specific exon

We have investigated the RNA structure of the region surrounding the muscle-specific exon 6B of the chicken beta-tropomyosin gene. We have used a variety of chemical and enzymatic probes: dimethylsulfate, N-cyclohexyl-N'-(2-(N-methylmorpholino)-ethyl)-carbodiimide-p-tolu enesulfonate) , RNase T1 and RNase V1. Lead acetate was also used to obtain some information on the tertiary structure of this region. Probing the wild-type sequence suggests a model involving one-stem and three-stem-loop structures in and around this exon. Two of these, hairpin I and stem III, have previously been implicated in repression of splicing of the intron following exon 6B in a HeLa nuclear extract. Stem I includes sequences at the beginning of exon 6B and stem III results from interaction of the intron upstream from exon 6B with sequences in the middle of the intron downstream from this exon (the intron whose splicing is repressed). Neither stem I nor stem III directly involves the consensus sequences (5' splice site, branch-point, 3' splice site) of the repressed intron. Probing RNAs that are derepressed for splicing of this intron show that there are structural changes around the 5' splice site and branch-point sequence that correlate with the derepression. This is true, despite the fact that the derepressed RNAs are altered in a region far from these consensus sequences. The most striking structural correlation with splicing capacity of the intron downstream from exon 6B is seen by probing with lead acetate. Lead ions cut RNA at specific residues; these sites are very sensitive to RNA tertiary structure. Repressed and derepressed RNAs show entirely different cleavage patterns after incubation with lead acetate. Remarkably, hybridizing a derepressed RNA with an RNA comprising the ascending arm of stem III not only re-establishes repression, but also converts the pattern of susceptibility to attack by lead ions over the whole molecule. We suggest that RNA conformation plays a role in keeping exon 6B from being spliced into non-muscle cell mRNA.     

A kinetic and thermodynamic framework for the Azoarcus group I ribozyme reaction

Determination of quantitative thermodynamic and kinetic frameworks for ribozymes derived from the Azoarcus group I intron and comparisons to their well-studied analogs from the Tetrahymena group I intron reveal similarities and differences between these RNAs. The guanosine (G) substrate binds to the Azoarcus and Tetrahymena ribozymes with similar equilibrium binding constants and similar very slow association rate constants. These and additional literature observations support a model in which the free ribozyme is not conformationally competent to bind G and in which the probability of assuming the binding-competent state is determined by tertiary interactions of peripheral elements. As proposed previously, the slow binding of guanosine may play a role in the specificity of group I intron self-splicing, and slow binding may be used analogously in other biological processes. The internal equilibrium between ribozyme-bound substrates and products is similar for these ribozymes, but the Azoarcus ribozyme does not display the coupling in the binding of substrates that is observed with the Tetrahymena ribozyme, suggesting that local preorganization of the active site and rearrangements within the active site upon substrate binding are different for these ribozymes. Our results also confirm the much greater tertiary binding energy of the 5′-splice site analog with the Azoarcus ribozyme, binding energy that presumably compensates for the fewer base-pairing interactions to allow the 5′-exon intermediate in self splicing to remain bound subsequent to 5′-exon cleavage and prior to exon ligation. Most generally, these frameworks provide a foundation for design and interpretation of experiments investigating fundamental properties of these and other structured RNAs.     

Sequence specificity of in vivo reverse splicing of the Tetrahymena group I intron.

Reverse splicing of group I introns is proposed to be a mechanism by which intron sequences are transferred to new genes. Integration of the Tetrahymena intron into the Escherichia coli 23S rRNA via reverse splicing depends on base pairing between the guide sequence of the intron and the target site. To investigate the substrate specificity of reverse splicing, the wild-type and 18 mutant introns with different guide sequences were expressed in E. coli. Amplification of intron-rRNA junctions by RT-PCR revealed partial reverse splicing at 69 sites and complete integration at one novel site in the 23S rRNA. Reverse splicing was not observed at some potential target sites, whereas other regions of the 23S rRNA were more reactive than expected. The results indicate that the frequency of reverse splicing is modulated by the structure of the rRNA. The intron is spliced 10-fold less efficiently in E. coli from a novel integration site (U2074) in domain V of the 23S rRNA than from a site homologous to the natural splice junction of the Tetrahymena 26S rRNA, suggesting that the forward reaction is less favored at this site.     

Alternative splicing attenuates transgenic expression directed by the apolipoprotein E promoter-enhancer based expression vector pLIV11

The plasmid vector pLIV11 is used commonly to achieve liver-specific expression of genes of interest in transgenic mice and rabbits. Expression is driven by the human apolipoprotein (apo)E 5′ proximal promoter, which includes 5 kb of upstream sequence, exon 1, intron 1, and 5 bp of exon 2. A 3.8 kb 3′ hepatic control region, derived from a region ∼18 kb downstream of the apoE gene, enhances liver-specific expression. Here, we report that cDNA sequences inserted into the multiple cloning site (MCS) of pLIV11, which is positioned just downstream of truncated exon 2, can cause exon 2 skipping. Hence, splicing is displaced to downstream cryptic 3′ splice acceptor sites causing deletion of cloned 5′ untranslated mRNA sequences and, in some cases, deletion of the 5′ end of an open reading frame. To prevent use of cryptic splice sites, the pLIV11 vector was modified with an engineered 3′ splice acceptor site inserted immediately downstream of truncated apoE exon 2. Presence of this sequence fully shifted splicing of exon 1 from the native intron 1–exon 2 splice acceptor site to the engineered site. This finding confirmed that sequences inserted into the MCS of the vector pLIV11 can affect exon 2 recognition and provides a strategy to protect cloned sequences from alternative splicing and possible attenuation of transgenic expression.     

Mutational analysis of the U12-dependent branch site consensus sequence

Highly conserved sequences at the 5′ splice site and branch site of U12-dependent introns are important determinants for splicing by U12-dependent spliceosomes. This study investigates the in vivo splicing phenotypes of mutations in the branch site consensus sequence of the U12-dependent intron F from a human NOL1 (P120) minigene. Intron F contains a fully consensus branch site sequence (UUCCUUAAC). Mutations at each position were analyzed for their effects on U12-dependent splicing in vivo. Mutations at most positions resulted in a significant reduction of correct U12-dependent splicing. Defects observed included increased unspliced RNA levels, the activation of cryptic U2-dependent 5′ and 3′ splice sites, and the activation of cryptic U12-dependent branch/3′ splice sites. A strong correlation was observed between the predicted thermodynamic stability of the branch site: U12 snRNA interaction and correct U12-dependent splicing. The lack of a polypyrimidine tract between the branch site and 3′ splice site of U12-dependent introns and the observed reliance on base-pairing interactions for correct U12-dependent splicing emphasize the importance of RNA/RNA interactions during U12-dependent intron recognition and proper splice site selection.     

Novel system for analysis of group I 3' splice site reactions based on functional trans-interaction of the P1/P10 reaction helix with the ribozyme's catalytic core.

A group I intron from a bacterial tRNA precursor has been converted into an RNA enzyme that catalyzes the efficient polymerization of oligoribonucleotide analogs of tRNA exons using a reaction scheme consisting of multiple cycles of reverse and forward exon ligation reactions. Here, we present results showing that this system represents a novel and useful tool for the analysis of 3' splice site reactions of group I ribozymes. First, analysis of variant substrates containing base substitutions in group I secondary structure elements P1, P9.0 and P10 confirms that exon polymerization is dependent on these structures, and therefore constitutes an appropriate and relevant model system for studying the exon ligation step of splicing. Second, to probe interactions between the intron's catalytic core and the bases and backbone of the P1/P10 reaction helix, two successful strategies for separating the internal guide sequence from the intron core were devised. One such strategy uses a construct in which the reaction helix interacts functionally with the catalytic core using only tertiary contacts. Further stabilization of this interaction through the inclusion of a 7 bp intermolecular P2 helix generates increased reaction efficiency. Third, when provided with two reaction helices, the ribozyme synthesizes mixed polymers through a mechanism that involves sequential binding and release of the duplexes. Fourth, in these reactions, turnover of the external guide sequence requires unwinding and annealing of the P2 helix, suggesting that P2 unwinding may occur during group I splicing. These results provide novel experimental tools to probe the relatively poorly understood 3' splice site reactions of group I introns, and may be relevant to ribozyme-catalyzed assembly and recombination of oligomers in prebiotic scenarios.     

Base pairing at the 5' splice site with U1 small nuclear RNA promotes splicing of the upstream intron but may be dispensable for slicing of the downstream intron.

We previously reported that exon skipping in vivo due to point mutations in the 5' splice site (5'ss) signal of an internal mammalian exon can be prevented by coexpression of U1 small nuclear RNAs, termed shift-U1s, with complementarity to sequence upstream or downstream of the mutated site. We now show by S1 nuclease protection experiments that a typical shift-U1 restores splicing of the upstream intron, but not necessarily of the down stream intron. This indicates that the normal 5'ss sequence acts as an enhancer for splicing of the upstream intron, that it owes this activity to base pairing with U1, and that the enhancer activity is reproduced by base pairing of U1 with other sequences in the area. Shift-U1s are dispensable when the 3'ss sequence of the upstream intron is improved, which suggests that base pairing of U1 with sequences at or near the downstream end of the exon normally functions by compensating for a weakness in the upstream 3'ss. Accordingly, U1 appears to be involved in communication across the exon, but our data indicate at the same time that extensive base pairing between U1 and the 5'ss sequence is not necessary for accurate splicing of the downstream intron. These findings are discussed in relation to the coordinate selection exon termini proposed by the exon definition model.     

Mutation of putative branchpoint consensus sequences in plant introns reduces splicing efficiency

Intron lariat formation between the 5' end of an intron and a branchpoint adenosine is a fundamental aspect of the first step in animal and yeast nuclear pre-mRNA splicing. Despite similarities in intron sequence requirements and the components of splicing, differences exist between the splicing of plant and vertebrate introns. The identification of AU-rich sequences as major functional elements in plant introns and the demonstration that a branchpoint consensus sequence was not required for splicing have led to the suggestion that the transition from AU-rich intron to GC-rich exon is a major potential signal by which plant pre-mRNA splice sites are recognized. The role of putative branchpoint sequences as an internal signal in plant intron recognition/definition has been re-examined. Single nucleotide mutations in putative branchpoint adenosines contained within CUNAN sequences in four different plant introns all significantly reduced splicing efficiency. These results provide the most direct evidence to date for preferred branchpoint sequences being required for the efficient splicing of at least some plant introns in addition to the important role played by AU sequences in dicot intron recognition. The observed patterns of 3' splice site selection in the introns studied are consistent with the scanning model described for animal intron 3' splice site selection. It is suggested that, despite the clear importance of AU sequences for plant intron splicing, the fundamental processes of splice site selection and splicing in plants are similar to those in animals.     

Functionally distinct nucleic acid binding sites for a group I intron encoded RNA maturase/DNA homing endonuclease

A large number of group I introns encode a family of homologous proteins that either promote intron splicing (maturases) or are site-specific DNA endonucleases that function in intron mobility (a process called "homing"). Genetic studies have shown that some of these proteins have both activities, yet how a single protein carries out both functions remains obscure. The similarity between respective DNA-binding sites and the RNA structure near the 5' and 3' splice sites has fueled speculation that such proteins may use analogous interactions to perform both functions. The Aspergillus nidulans mitochondrial COB group I intron encodes a bi-functional protein, I-AniI, that has both RNA maturase and site-specific DNA endonuclease activities in vitro. Here, we show that I-AniI shows distinctive features of the endonuclease family to which it belongs, including highly specific, tight binding and sequential DNA strand cleavage. Competition experiments demonstrate that I-AniI binds the COB intron RNA even in saturating concentrations of its DNA target site substrate, suggesting that the protein has a separate binding site for RNA. In addition, we provide evidence that two different DNA-binding site mutants of I-AniI have little effect on the protein's RNA maturation activity. Since RNA splicing is likely a secondary adaptation of the protein, these observations support a model in which homing endonucleases may have developed maturase function by utilizing a hitherto "non-functional" protein surface.