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.     

Group II intron splicing in chloroplasts: identificationof mutations determining intron stability and fate of exon RNA.

In order to investigate in vivo splicing of group II introns in chloroplasts, we previously have integrated the mitochondrial intron rI1 from the green alga Scenedesmus obliquus into the Chlamydomonas chloroplast tscA gene. This construct allows a functional analysis of conserved intron sequences in vivo, since intron rI1 is correctly spliced in chloroplasts. Using site-directed mutagenesis, deletions of the conserved intron domains V and VI were performed. In another set of experiments, each possible substitution of the strictly conserved first intron nucleotide G1 was generated, as well as each possible single and double mutation of the tertiary base pairing gamma-gamma ' involved in the formation of the intron's tertiary RNA structure. In most cases, the intron mutations showed the same effect on in vivo intron splicing efficiency as they did on the in vitro self-splicing reaction, since catalytic activity is provided by the intron RNA itself. In vivo, all mutations have additional effects on the chimeric tscA -rI1 RNA, most probably due to the role played by trans -acting factors in intron processing. Substitutions of the gamma-gamma ' base pair lead to an accumulation of excised intron RNA, since intron stability is increased. In sharp contrast to autocatalytic splicing, all point mutations result in a complete loss of exon RNA, although the spliced intron accumulates to high levels. Intron degradation and exon ligation only occur in double mutants with restored base pairing between the gamma and gamma' sites. Therefore, we conclude that intron degradation, as well as the ligation of exon-exon molecules, depends on the tertiary intron structure. Furthermore, our data suggest that intron excision proceeds in vivo independent of ligation of exon-exon molecules.     

Restoration of the self-splicing activity of a defective group II intron by a small trans-acting RNA

The yeast mitochondrial group II intron bI1 is self-splicing in vitro. We have introduced a deletion of hairpin C1 within the structural domain 1 that abolishes catalytic activity of the intron in the normal splicing reaction in cis, but does less severely affect a reaction in trans, the reopening of ligated exons. Since exon reopening is supposed to correspond to a reverse 3' cleavage this suggests that the deletion specifically blocks the first reaction step. The intron regains its activity to self-splice in cis by intermolecular complementation with a small RNA harbouring sequences lacking in the mutant intron. These results demonstrate the feasibility to reconstitute a functionally active structure of the truncated intron by intermolecular complementation in vitro. Furthermore, the data support the hypothesis that group II introns are predecessors of nuclear pre-mRNA introns and that the small nuclear RNAs of the spliceosome arose by segregation from the original intron.     

Trans splicing integrates an exon of 22 nucleotides into the nad5 mRNA in higher plant mitochondria.

The genes coding for NADH dehydrogenase subunit 5 (nad5) in mitochondria of the higher plants Oenothera and Arabidopsis are split into five exons that are located in three distant genomic regions. These encode exons a + b, c and d + e, respectively. Maturation of the mRNAs requires two trans splicing events to integrate exon c of only 22 nucleotides. Both trans splicing reactions involve mitochondrial group II intron sequences that allow base pairings in the interrupted domain IV, demonstrating the flexibility of intron structures. The observation of fragmented intron sequences in plant mitochondria suggests that trans splicing is more widespread than previously assumed. RNA editing by C to U alterations in both Oenothera and Arabidopsis open reading frames improves the evolutionary conservation of the encoded polypeptides. Three C to U RNA editing events were observed in intron sequences.     

CRS1, a chloroplast group II intron splicing factor, promotes intron folding through specific interactions with two intron domains

Group II introns are ribozymes that catalyze a splicing reaction with the same chemical steps as spliceosome-mediated splicing. Many group II introns have lost the capacity to self-splice while acquiring compensatory interactions with host-derived protein cofactors. Degenerate group II introns are particularly abundant in the organellar genomes of plants, where their requirement for nuclear-encoded splicing factors provides a means for the integration of nuclear and organellar functions. We present a biochemical analysis of the interactions between a nuclear-encoded group II splicing factor and its chloroplast intron target. The maize (Zea mays) protein Chloroplast RNA Splicing 1 (CRS1) is required specifically for the splicing of the group II intron in the chloroplast atpF gene and belongs to a plant-specific protein family defined by a recently recognized RNA binding domain, the CRM domain. We show that CRS1's specificity for the atpF intron in vivo can be explained by CRS1's intrinsic RNA binding properties. CRS1 binds in vitro with high affinity and specificity to atpF intron RNA and does so through the recognition of elements in intron domains I and IV. These binding sites are not conserved in other group II introns, accounting for CRS1's intron specificity. In the absence of CRS1, the atpF intron has little uniform tertiary structure even at elevated [Mg2+]. CRS1 binding reorganizes the RNA, such that intron elements expected to be at the catalytic core become less accessible to solvent. We conclude that CRS1 promotes the folding of its group II intron target through tight and specific interactions with two peripheral intron segments.     

Mitochondrial introns: a critical view

Although group I and group II introns were discovered more than 25 years ago, they are still difficult to identify. Modeling their RNA structure also remains particularly challenging for organelle sequences, owing to their great diversity. In fact, accelerated evolution in organelles often results in a reduced RNA structure and a loss of autocatalytic splicing and intron mobility. We set out to identify all mitochondrial group I and II introns in published sequences, and, to this end, we developed and applied a new search approach: RNAweasel. On the basis of the results, we focus here on building a comprehensive picture of mitochondrial group I introns, including a modified (reduced) consensus RNA secondary structure and a concise phylogeny-based subclassification.     

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.     

Origin and evolution of the chloroplast trnK (matK) intron: a model for evolution of group II intron RNA structures

The trnK intron of plants encodes the matK open reading frame (ORF), which has been used extensively as a phylogenetic marker for classification of plants. Here we examined the evolution of the trnK intron itself as a model for group II intron evolution in plants. Representative trnK intron sequences were compiled from species spanning algae to angiosperms, and four introns were newly sequenced. Phylogenetic analyses showed that the matK ORFs belong to the ML (mitochondrial-like) subclass of group II intron ORFs, indicating that they were derived from a mobile group II intron of the class. RNA structures of the introns were folded and analyzed, which revealed progressive RNA structural deviations and degenerations throughout plant evolution. The data support a model in which plant organellar group II introns were derived from bacterial-like introns that had "standard" RNA structures and were competent for self-splicing and mobility and that subsequently the ribozyme structures degenerated to ultimately become dependent upon host-splicing factors. We propose that the patterns of RNA structure evolution seen for the trnK intron will apply to the other group II introns in plants.     

Integration of group II intron bI1 into a foreign RNA by reversal of the self-splicing reaction in vitro

Group II intron bI1, the first intron of the COB gene in the mitochondria of S. cerevisiae, is able to self-splice in vitro with the basic pathway similar to nuclear pre-mRNA splicing. We show that incubation of the intron lariat with ligated exons bE1 and bE2 leads to a complete reversal of the splicing reaction. The integration of the intron into the ligated exons is correct; the reconstituted preRNA of the reverse reaction can undergo a self-splicing reaction anew. When incubated with a foreign RNA species bearing a sequence motif that is complementary to exon binding site 1, the lariat can integrate into this RNA with the position of insertion immediately downstream of this sequence. This result implies that transposition of group II introns on the RNA level by reversal of the splicing reaction is, in principle, conceivable.     

The linear form of a group II intron catalyzes efficient autocatalytic reverse splicing, establishing a potential for mobility

Self-splicing group II introns catalyze their own excision from pre-RNAs, thereby joining the flanking exons. The introns can be released in a lariat or linear form. Lariat introns have been shown to reverse the splicing reaction; in contrast, linear introns are generally believed to perform no or only poor reverse splicing. Here, we show that a linear group II intron derived from ai5γ can reverse the second step of splicing with unexpectedly high efficiency and precision. Moreover, the linear intron generates dramatically more reverse-splicing product than its lariat equivalent. The finding that linear group II introns can readily undergo the critical first step of mobility by catalyzing efficient reverse splicing into complementary target molecules demonstrates their innate potential for mobility and transposition and raises the possibility that reverse splicing by linear group II introns may have played a significant role in certain forms of intron mobility and lateral gene transfer during evolution.     

Exon junction sequences as cryptic splice sites: implications for intron origin

Introns are flanked by a partially conserved coding sequence that forms the immediate exon junction sequence following intron removal from pre-mRNA. Phylogenetic evidence indicates that these sequences have been targeted by numerous intron insertions during evolution, but little is known about this process. Here, we test the prediction that exon junction sequences were functional splice sites that existed in the coding sequence of genes prior to the insertion of introns. To do this, we experimentally identified nine cryptic splice sites within the coding sequence of actin genes from humans, Arabidopsis, and Physarum by inactivating their normal intron splice sites. We found that seven of these cryptic splice sites correspond exactly to the positions of exon junctions in actin genes from other species. Because actin genes are highly conserved, we could conclude that at least seven actin introns are flanked by cryptic splice sites, and from the phylogenetic evidence, we could also conclude that actin introns were inserted into these cryptic splice sites during evolution. Furthermore, our results indicate that these insertion events were dependent upon the splicing machinery. Because most introns are flanked by similar sequences, our results are likely to be of general relevance.     

Trans splicing of mRNA precursors in vitro

Two exon segments from two separate RNA molecules can be joined in a trans splicing process. In trans splicing reactions, an RNA molecule containing an exon, a 5' splice site, and adjacent intron sequences was mixed with an RNA molecule containing an exon, a 3' splice site, and adjacent intron sequences. The efficiency of trans splicing of these two RNAs increased if the two termini of the intervening sequences were paired in a short RNA duplex. However, trans splicing of two RNA molecules with no significant complementarity was also observed. These results strongly suggest that significant secondary structures within intervening sequences could affect the splicing of flanking exons. Similarly, RNAs that are complementary to segments within the intervening sequences could potentially regulate the selection of splice sites. Finally, some organisms might use trans splicing to distribute a single exon to many different mRNAs.