Selection of cryptic 5'' splice sites by group II intron RNAs in vitro.

Recognition of 5' splice points by group I and group II self-splicing introns involves the interaction of exon sequences--directly preceding the 5' splice site--with intronic sequence elements. We show here that the exon binding sequences (EBS) of group II intron aI5c can accept various substitutes of the authentic intron binding sites (IBS) provided in cis or in trans. The efficiency of cleavages at these cryptic 5' splice sites was enhanced by deletion of the authentic IBS2 element. All cryptic 5' cleavage sites studied here were preceded by an IBS1 like sequence; indicating that the IBS1/EBS1 pairing alone is sufficient for proper 5' splice site selection by the intronic EBS element. The results are discussed in terms of minimal requirements for 5' cleavages and position effects of IBS sites relative to the intron.     

Sequence requirements for branch formation in a group II self-splicing intron.

Evidence is presented for the existence of a specific intron-intron interaction, necessary for the formation of the branched product in the self-splicing reaction of a group II yeast mitochondrial intron. Trans-splicing reactions involving two RNA molecules (5' exon with covalently linked regions of intron and intron with covalently linked 3' exon) show that the presence of portions of intron domain I on the 5' molecule is necessary for the formation of branched products which are not seen with shorter 5' molecules. Modification/interference reactions show regions necesary for branch-formation and support a major role for specific regions of intron domain I. Further experiments, utilizing a truncated 3' molecule that is missing the conserved branchpoint nucleotide, indicate that domain VI may be required for a successful domain I interaction. A model for the formation of a proper branched structure includes implications for both cis and trans configurations.     

Potential for alternative intron-exon pairings in group II intron RmInt1 from Sinorhizobium meliloti and its relatives

Ribozyme constructs derived from group II intron RmInt1 of Sinorhizobium meliloti self-splice in vitro when incubated under permissive conditions, but exon ligation is unusually inefficient when the 5' exon is truncated close to the IBS2 intron-binding site. One plausible explanation for this observation is the presence of an alternative intron-exon pairing between an intron segment that overlaps with the EBS2 exon-binding site and a 5' exon site located just distal of IBS2 relative to the splice junction. Strikingly, the existence of this pairing is supported by comparative sequence analysis of introns related to RmInt1.     

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.     

Group II intron RNA-catalyzed recombination of RNA in vitro.

We report the first evidence for a novel reaction mediated by the self-splicing yeast mitochondrial group II intron bl1; the site-specific recombination of RNA molecules in vitro. Upon incubation of the intron lariat with two different RNAs, each harbouring a short sequence complementary to exon binding site 1 (EBS1) of the intron, novel recombined RNAs are formed. As a result of this intron-mediated shuffling of gene segments, the 5' part of RNA1 is ligated to the 3' part of RNA2 and, reciprocally, the 5' part of RNA2 to the 3' part of RNA1. Sequence analysis of the recombinant junction shows that the site of recombination is precisely located 3' to intron binding site 1 (IBS1). The hypothesized mechanism of recombination involves exchange of RNA 5' parts after the first step of a reverse splicing reaction. The possible role of this mechanism in vivo and during prebiotic evolution is discussed.     

Relevance of the branch point adenosine, coordination loop, and 3' exon binding site for in vivo excision of the Sinorhizobium meliloti group II intron RmInt1

Excision of the bacterial group II intron RmInt1 has been demonstrated in vivo, resulting in the formation of both intron lariat and putative intron RNA circles. We show here that the bulged adenosine in domain VI of RmInt1 is required for splicing via the branching pathway, but branch site mutants produce small numbers of RNA molecules in which the first G residue of the intron is linked to the last C residue. Mutations in the coordination loop in domain I reduced splicing efficiency, but branched templates clearly predominated among splicing products. We also found that a single substitution at the EBS3 position (G329C), preventing EBS3-IBS3 pairing, resulted in the production of 50 to 100 times more RNA molecules in which the 5' and 3' extremities were joined. We provide evidence that these intron molecules may correspond to both, intron circles linked by a 2'-5' phosphodiester bond, and tandem, head-to-tail intron copies.     

NMR structure of the 5′ splice site in the group IIB intron Sc.ai5γ—conformational requirements for exon–intron recognition

A crucial step of the self-splicing reaction of group II intron ribozymes is the recognition of the 5′ exon by the intron. This recognition is achieved by two regions in domain 1 of the intron, the exon-binding sites EBS1 and EBS2 forming base pairs with the intron-binding sites IBS1 and IBS2 located at the end of the 5′ exon. The complementarity of the EBS1•IBS1 contact is most important for ensuring site-specific cleavage of the phosphodiester bond between the 5′ exon and the intron. Here, we present the NMR solution structures of the d3′ hairpin including EBS1 free in solution and bound to the IBS1 7-mer. In the unbound state, EBS1 is part of a flexible 11-nucleotide (nt) loop. Binding of IBS1 restructures and freezes the entire loop region. Mg²⁺ ions are bound near the termini of the EBS1•IBS1 helix, stabilizing the interaction. Formation of the 7-bp EBS1•IBS1 helix within a loop of only 11 nt forces the loop backbone to form a sharp turn opposite of the splice site, thereby presenting the scissile phosphate in a position that is structurally unique.     

An alternative intron-exon pairing scheme implied by unexpected in vitro activities of group II intron RmInt1 from Sinorhizobium meliloti

RmInt1 is a mobile group II intron which interrupts ISRm2011-2, another mobile element from the bacterium Sinorhizobium meliloti. Ribozyme constructs derived from intron RmInt1 self-splice in vitro when incubated under permissive conditions, but the excised intron and ligated exons are largely replaced by unconventional products. These include a slightly shorter, 5'-end truncated 3' exon, truncated variants of the linear and lariat forms of the intron-3' exon reaction intermediate, as well as presumably circular molecules derived from the latter. Two factors explain the abundance of these products: (i) nucleotides 5-11 of the 3' exon (IBS1*) provide a better match to the EBS1 5'-exon-binding site than the authentic IBS1 sequence in the 5' exon; (ii) exon ligation is unusually inefficient, and especially so when the 5' exon is truncated close to the second (IBS2) intron-binding site. We propose that reactions at the IBS1* site play a part in the regulation of the intron ISRm2011-2 host in vivo.     

Fate of the junction phosphate in alternating forward and reverse self-splicing reactions of group II intron RNA.

The RNA-catalysed self-splicing reaction of group II intron RNA is assumed to proceed by two consecutive transesterification steps, accompanied by lariat formation. This is effectively analogous to the small nuclear ribonucleoprotein (snRNP)-mediated nuclear pre-mRNA splicing process. Upon excision from pre-RNA, a group II lariat intervening sequence (IVS) has the capacity to re-integrate into its cognate exons, reconstituting the original pre-RNA. The process of reverse self-splicing is presumed to be a true reversion of both transesterification steps used in forward splicing. To investigate the fate of the esterified phosphate groups in splicing we assayed various exon substrates (5'E-*p3'E) containing a unique 32P-labelled phosphodiester at the ligation junction. In combined studies of alternating reverse and forward splicing we have demonstrated that the labelled phosphorus atom is displaced in conjunction with the 3' exon from the ligation junction to the 3' splice site and vice versa. Neither the nature of the 3' exon sequence nor its sequence composition acts as a prominent determinant for both substrate specificity and site-specific transesterification reactions catalysed by bI1 IVS. A cytosine ribonucleotide (pCp; pCOH) or even deoxyoligonucleotides could function as an efficient substitute for the authentic 3' exon in reverse and in forward splicing. Furthermore, the 3' exon can be single monophosphate group. Upon incubation of 3' phosphorylated 5' exon substrate (5'E-*p) with lariat IVS the 3'-terminal phosphate group is transferred in reverse and forward splicing like an authentic 3' exon, but with lower efficiency. In the absence of 3' exon nucleotides, it appears that substrate specificity is provided predominantly by the base-pairing interactions of the intronic exon binding site (EBS) sequences with the intron binding site (IBS) sequences in the 5' exon. These studies substantiate the predicted transesterification pathway in forward and reverse splicing and extend the catalytic repertoire of group II IVS in that they can act as a potential and sequence-specific transferase in vitro.     

Guiding ribozyme cleavage through motif recognition: the mechanism of cleavage site selection by a group ii intron ribozyme

The mechanism by which group II introns cleave the correct phosphodiester linkage was investigated by studying the reaction of mutant substrates with a ribozyme derived from intron ai5gamma. While fidelity was found to be quite high in most cases, a single mutation on the substrate (+1C) resulted in a dramatic loss of fidelity. When this mutation was combined with a second mutation that induces a bulge in the exon binding site 1/intron binding site 1 (EBS1/IBS1) duplex, the base-pairing register of the EBS1/IBS1 duplex was shifted and the cleavage site moved to a downstream position on the substrate. Conversely, when mismatches were incorporated at the EBS1/IBS1 terminus, the duplex was effectively truncated and cleavage occurred at an upstream site. Taken together, these data demonstrate that the cleavage site of a group II intron ribozyme can be tuned at will by manipulating the thermodynamic stability and structure of the EBS1/IBS1 pairing. The results are consistent with a model in which the cleavage site is not designated through recognition of specific nucleotides (such as the 5'-terminal residue of EBS1). Instead, the ribozyme detects a structure at the junction between single and double-stranded residues on the bound substrate. This finding explains the puzzling lack of phylogenetic conservation in ribozyme and substrate sequences near group II intron target sites.     

Exon sequence requirements for excision in vivo of the bacterial group II intron RmInt1

Background

Group II intron splicing proceeds through two sequential transesterification reactions in which the 5' and 3'-exons are joined together and the lariat intron is released. The intron-encoded protein (IEP) assists the splicing of the intron in vivo and remains bound to the excised intron lariat RNA in a ribonucleoprotein particle (RNP) that promotes intron mobility. Exon recognition occurs through base-pairing interactions between two guide sequences on the ribozyme domain dI known as EBS1 and EBS2 and two stretches of sequence known as IBS1 and IBS2 on the 5' exon, whereas the 3' exon is recognized through interaction with the sequence immediately upstream from EBS1 [(δ-δ' interaction (subgroup IIA)] or with a nucleotide [(EBS3-IBS3 interaction (subgroup IIB and IIC))] located in the coordination-loop of dI. The δ nucleotide is involved in base pairing with another intron residue (δ') in subgroup IIB introns and this interaction facilitates base pairing between the 5' exon and the intron.

Results

In this study, we investigated nucleotide requirements in the distal 5'- and 3' exon regions, EBS-IBS interactions and δ-δ' pairing for excision of the group IIB intron RmInt1 in vivo. We found that the EBS1-IBS1 interaction was required and sufficient for RmInt1 excision. In addition, we provide evidence for the occurrence of canonical δ-δ' pairing and its importance for the intron excision in vivo.

Conclusions

The excision in vivo of the RmInt1 intron is a favored process, with very few constraints for sequence recognition in both the 5' and 3'-exons. Our results contribute to understand how group II introns spread in nature, and might facilitate the use of RmInt1 in gene targeting.     

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.     

Splice site selection and role of the lariat in a group II intron.

The structural elements involved in 5' and 3' splice site (SS) selection in a group II intron were analyzed. While 5' SS selection appears to be defined by only one element, the EBS1-IBS1 pairing, four distinct structural components contribute to 3' SS selection, one of which being analogous to the "internal guide sequence" described for group I introns. Moreover, some of the mutants analyzed during this study induce efficient 5' SS hydrolysis and suggest how 5' SS transesterification is selected against hydrolysis. Finally, the lariat structure was found to accelerate both steps of splicing, suggesting that it "locks" the ribozyme in an active configuration.     

Self-splicing of a group II intron in yeast mitochondria: dependence on 5'' exon sequences.

It has been previously suggested that self-splicing of group II introns starts with a nucleophilic attack of the 2' OH group from the branchpoint adenosine on the 5' splice junction. To investigate the sequences governing the specificity of this attack, a series of Bal31 nuclease deletion mutants was constructed in which progressively larger amounts of 5' exon have been removed starting from its 5' end. The ability of mutant RNAs to carry out self-splicing in vitro was studied. Involvement of 5' exon sequences in self-splicing activity is indicated by the fact that a mutant in which as many as 18 nucleotides of 5' exon remain is seriously disturbed in splicing, while larger deletions eliminate splicing entirely. Mutants containing a truncated 5' exon form aberrant RNAs. One of these is a 425-nucleotide RNA containing the 5' exon as well as sequences of the 5' part of the intron. Its 3' end maps at position 374 of the 887-nucleotide intron. The other is a less abundant lariat RNA probably originating from the remainder of the intron linked to the 3' exon. We interpret this large dependence of reactivity of the intron on 5' exon and adjoining intron sequences as evidence for base-pairing interactions between the exon and parts of the intron, leading to an RNA folding necessary for splicing. Possible folding models are discussed.