The nuclear gene MRS2 is essential for the excision of group II introns from yeast mitochondrial transcripts in vivo.

RNA splicing defects in mitochondrial intron mutants can be suppressed by a high dosage of several proteins encoded by nuclear genes. In this study we report on the isolation, nucleotide sequence, and possible functions of the nuclear MRS2 gene. When present on high copy number plasmids, the MRS2 gene acts as a suppressor of various mitochondrial intron mutations, suggesting that the MRS2 protein functions as a splicing factor. This notion is supported by the observations that disruption of the single chromosomal copy of the MRS2 gene causes (i) a pet- phenotype and (ii) a block in mitochondrial RNA splicing of all four mitochondrial group II introns, some of which are efficiently self-splicing in vitro. In contrast, the five group I introns monitored here are excised from pre-mRNA in a MRS2-disrupted background although at reduced rates. So far the MRS2 gene product is unique in that it is essential for splicing of all four group II introns, but relatively unimportant for splicing of group I introns. In strains devoid of any mitochondrial introns the MRS2 gene disruption still causes a pet- phenotype and cytochrome deficiency, although the standard pattern of mitochondrial translation products is produced. Therefore, apart from RNA splicing, the absence of the MRS2 protein may disturb the assembly of mitochondrial membrane complexes.     

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.     

Formation of lariats and circles in self-splicing of the precursor to the large ribosomal RNA of yeast mitochondria

Self-splicing of the precursor to large ribosomal RNA of yeast mitochondria leads not only to circles but also to lariats, structures that have not been observed before as products of self-splicing. Lariats were studied by electron microscopy after hybridization with an RNA complementary to the 3' half of the precursor. This leads to differentiation in at least two classes of lariats that vary in the position of the branch point. In all lariats the tail carries the 3' end, which suggests that a 5' end is used for branch formation with an internal nucleotide. The circles are formed from excised introns. They lack only three nucleotides encoded by mitochondrial DNA along with the 5'-terminal G added in the course of self-splicing. The diverse number of self-splicing products arising in vitro testifies to the considerable reactivity of this intron. The formation of lariats in an RNA catalyzed reaction may have implications for views on the mechanism of splicing of nuclear pre-mRNAs.     

Self-splicing of yeast mitochondrial ribosomal and messenger RNA precursors

We have previously shown linear and circular splicing intermediates resembling intermediates that result from self-splicing of ribosomal precursor RNA of Tetrahymena to be present in mitochondrial RNA. Here we show that splicing of yeast mitochondrial precursor RNA also occurs in vitro in the absence of mitochondrial proteins. The large ribosomal RNA gene, consisting of the intron and part of the flanking exon regions, was inserted behind the SP6 promoter in a recombinant plasmid and was transcribed in vitro. The resulting RNA shows self-catalyzed splicing via incorporation of GTP at the 5'-end of the excised intron, 5'- to 3'-exon ligation, and intron circularization. When purified mitochondrial RNA is incubated under similar conditions with alpha-32P-GTP, the excised ribosomal intron RNA is also labeled, as well as several other RNA species. Some of these RNAs are derived from excised introns from the multiply split gene coding for cytochrome oxidase subunit I.     

New RNA-mediated reactions by yeast mitochondrial group I introns.

The group I self-splicing reaction is initiated by attack of a guanosine nucleotide at the 5' splice site of intron-containing precursor RNA. When precursor RNA containing a yeast mitochondrial group I intron is incubated in vitro under conditions of self-splicing, guanosine nucleotide attack can also occur at other positions: (i) the 3' splice site, resulting in formation of a 3' exon carrying an extra added guanosine nucleotide at its 5' end; (ii) the first phosphodiester bond in precursor RNA synthesized from the SP6 bacteriophage promoter, leading to substitution of the first 5'-guanosine by a guanosine nucleotide from the reaction mixture; (iii) the first phosphodiester bond in already excised intron RNA, resulting in exchange of the 5' terminal guanosine nucleotide for a guanosine nucleotide from the reaction mixture. An identical sequence motif (5'-GAA-3') occurs at the 3' splice site, the 5' end of SP6 precursor RNA and at the 5' end of excised intron RNA. We propose that the aberrant reactions can be explained by base-pairing of the GAA sequence to the Internal Guide Sequence. We suggest that these reactions are mediated by the same catalytic centre of the intron RNA that governs the normal splicing reactions.     

Self-splicing of group II introns in vitro: mapping of the branch point and mutational inhibition of lariat formation

Group II intron bl1 from yeast mitochondria can undergo self-splicing in vitro. Exons become correctly ligated, and the excised intron has a lariat structure similar to that of introns from nuclear mRNA. The branch point of the bl1 lariat is located eight or nine nucleotides upstream of the 3' end of the intron and is part of a hairpin structure that is well conserved among group II introns. Several mutations next to the branch point and in other parts of the core structure of group II introns are shown to affect lariat formation. One of them, carried by strain M4873, abolishes splicing in vivo and in vitro, apparently by changing the architecture of the hairpin structure containing the branch point. Similarities between group II introns and nuclear pre-mRNA introns are discussed in terms of evolutionary relatedness.     

Group II intron domain 5 facilitates a trans-splicing reaction.

A self-splicing group II intron of yeast mitochondrial DNA (aI5g) was divided within intron domain 4 to yield two RNAs that trans-spliced in vitro with associated trans-branching of excised intron fragments. Reformation of the domain 4 secondary structure was not necessary for the trans reaction, since domain 4 sequences were shown to be dispensable. Instead, the trans reaction depended on a previously unpredicted interaction between intron domain 5, the most highly conserved region of group II introns, and another region of the RNA. Domain 5 was shown to be essential for cleavage at the 5' splice site. It stimulated that cleavage when supplied as a trans-acting RNA containing only 42 nucleotides of intron sequence. The relevance of our findings to in vivo trans-splicing mechanisms is discussed.     

Variation in sequence and RNA editing within core domains of mitochondrial group II introns among plants

The 3' regions of several group II introns within the mitochondrial genes nad1 and nad7 show unexpected sequence divergence among flowering plants, and the core domains 5 and 6 are predicted to have weaker helical structure than those in self-splicing group II introns. To assess whether RNA editing improves helical stability by the conversion of A-C mispairs to A-U pairs, we sequenced RT-PCR amplification products derived from excised intron RNAs or partially spliced precursors. Only in some cases was editing observed to strengthen the predicted helices. Moreover, the editing status within nad1 intron 1 and nad7 intron 4 was seen to differ among plant species, so that homologous intron sequences shared lower similarity at the RNA level than at the DNA level. Plant-specific variation was also seen in the length of the linker joining domains 5 and 6 of nad7 intron 3; it ranged from 4 nt in wheat to 11 nt in soybean, in contrast to the 2-4 nt length typical of classical group II introns. However, this intron is excised as a lariat structure with a domain 6 branchpoint adenosine. Our observations suggest that the core structures and sequences of these plant mitochondrial introns are subject to less stringent evolutionary constraints than conventional group II introns.     

A maturase-encoding group IIA intron of yeast mitochondria self-splices in vitro.

Intron 1 of the coxI gene of yeast mitochondrial DNA (aI1) is a group IIA intron that encodes a maturase function required for its splicing in vivo. It is shown here to self-splice in vitro under some reaction conditions reported earlier to yield efficient self-splicing of group IIB introns of yeast mtDNA that do not encode maturase functions. Unlike the group IIB introns, aI1 is inactive in 10 mM Mg2+ (including spermidine) and requires much higher levels of Mg2+ and added salts (1M NH4Cl or KCl or 2M (NH4)2SO4) for ready detection of splicing activity. In KCl-stimulated reactions, splicing occurs with little normal branch formation; a post-splicing reaction of linear excised intron RNA that forms shorter lariat RNAs with branches at cryptic sites was evident in those samples. At low levels of added NH4Cl or KCl, the precursor RNA carries out the first reaction step but appears blocked in the splicing step. AI1 RNA is most reactive at 37-42 degrees C, as compared with 45 degrees C for the group IIB introns; and it lacks the KCl- or NH4Cl-dependent spliced-exon reopening reaction that is evident for the self-splicing group IIB introns of yeast mitochondria. Like the group IIB intron aI5 gamma, the domain 4 of aI1 can be largely deleted in cis, without blocking splicing; also, trans-splicing of half molecules interrupted in domain 4 occurs. This is the first report of a maturase-encoding intron of either group I or group II that self-splices in vitro.     

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.     

Characterization of products derived from self-splicing of intron aI5 alpha which is located in the mitochondrial COX I gene of Saccharomyces cerevisiae.

We have characterized the in vitro self-splicing of intron aI5 alpha containing precursor RNA from the yeast mitochondrial gene coding for cytochrome oxidase subunit I. This intron follows the rules for group I self-splicing introns and all the characteristic products have been identified. In addition we have detected abnormal RNA products with features that indicate that the self-splicing behaviour of this intron is more complex. Two intron circles are formed by use of a major and minor intron-internal site for circle closure. A cryptic 5'-splice site located in the 3' exon results in guanosine nucleotide mediated opening at a position 30 nt downstream of the normal 3' splice site. The reactions can all be explained on the basis of the "splice guide" model proposed by Davies et al (1982 Nature 300 719-724). Although the sequence motifs at cyclization and splice sites occur more often in this intron, only some of them are allowed to interact with the internal guide sequence, suggesting that both primary structure and spatial folding of the RNA are involved in formation of productive reaction sites.     

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.     

Determination of functional domains in intron bI1 of yeast mitochondrial RNA by studies of mitochondrial mutations and a nuclear suppressor.

The sequence of intron 1 in the cob gene in mtDNA (bI1) of the yeast strain 777-3A has been determined. Furthermore, we have performed a systematic search for complementary sequence stretches within this intron RNA, and within the RNA of intron 5 gamma of the oxi3 gene (aI5 gamma) which shares distinctive sequences with bI1. Possible secondary structure models derived from this analysis show nearly identical core structures for bI1 and aI5 gamma RNA with conserved sequence stretches in prominent positions. These core structures are similar to those previously reported for RNAs of introns having very limited sequence homology with bI1 and aI5 gamma. In two mutants which are defective in bI1 excision from cob pre-mRNA, nucleotide sequence alterations in bI1 have been determined. One mutation (G5049) apparently affects the stability of a hybrid stretch in the proposed secondary structure of bI1 RNA whereas the other one (M1301), a deletion of one A in a run of five As, affects a sequence which is conserved in bI1 and aI5 gamma and is involved in the formation of a distinct secondary structure. Out of seven revertants of M1301, three were found to have restored the wild-type bI1 sequence AAAAA, three others had the related sequence AAAAG which is functionally indistinguishable from wild-type, whereas one revertant had a nuclear mutation which suppresses the splicing defect exerted by the mitochondrial mutation M1301. This nuclear suppressor (SUP-101) is allele specific and dominant. The possible role of the sequence affected by M1301 in terms of a recognition site for a nuclear gene product will be discussed.     

Group II intron self-splicing. Alternative reaction conditions yield novel products

Reaction parameters were modified to enhance the in vitro reaction rate and to reveal partial and novel reactions of the group II intron 5g of the mitochondrial gene from Saccharomyces cerevisiae encoding cytochrome c oxidase subunit I. One alteration yields separate 5'- and 3'-exons plus linear excised intron as the main products. A linear reaction intermediate, containing intron and 3'-exon, and products resulting from cleavages at two unexpected sites were identified. Spliced exon "reopening," a novel reaction between excised intron and spliced exons, appears responsible for separate 5'- and 3'-exon products.     

Synthesis of chimeric RNAs between U6 small nuclear RNA and (-)sTRSV and analysis of their cleavage activities against the substrate RNA.

U6 small nuclear RNA (U6 snRNA) is one of the spliceosomal RNAs essential for pre-mRNA splicing. Highly conserved region of U6 snRNA shows a structural similarity with the catalytic center of the negative strand of the satellite RNA of tobacco ring spot virus [(-)sTRSV], supporting the hypothesis that U6 snRNA has a catalytic role in pre-mRNA splicing. To test this hypothesis, we examined in vitro whether synthetic RNAs consisting of the sequence of the highly conserved region of U6 snRNA or various chimeric RNAs between the U6 region and the catalytic center of (-)sTRSV could cleave a substrate RNA that can partially base-pair with them and has a GU sequence between the pairing regions. Chimeric RNAs with 70 to 83% sequence identity with the conserved region of S. pombe U6 snRNA cleaved the substrate RNA at the 5' side of the GU sequence. In addition, we found that the highly conserved region of U6 snRNA is similar in structure to the catalytic core region of the group I self-splicing intron in cyanobacteria. These results support the hypothesis that U6 snRNA catalyzes the pre-mRNA splicing reaction and U6 snRNA may originate from the catalytic domain of an ancient self-splicing 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.     

Branched RNA

The only RNA molecules known to be branched are circular structures with tails known as lariats that arise during nuclear pre-mRNA splicing. Lariats accumulate within a large multicomponent particle called a spliceosome that forms upon the addition of unspliced mRNA to nuclear extracts. Recently an RNA molecule has been observed to catalyze branch formation. In this case a single intron of a yeast mitochondrial pre-mRNA participates in a self-splicing reaction that results in the accumulation of branched lariats that are processed to correctly spliced exons. An enzyme highly specific for branch removal found in the same extracts that form branches during pre-mRNA splicing can debranch RNA lariats to their linear forms without loss of nucleotides. The chemical synthesis of branched RNA has recently been achieved. High yields of sequence-specific oligonucleotides are now available for the analysis of RNA splicing by techniques dependent on branch-site recognition.     

Molecular genetics of group I introns: RNA structures and protein factors required for splicing--a review

In vivo and in vitro genetic techniques have been widely used to investigate the structure-function relationships and requirements for splicing of group-I introns. Analyses of group-I introns from extremely diverse genetic systems, including fungal mitochondria, protozoan nuclei, and bacteriophages, have yielded results which are complementary and highly consistent. In vivo genetic studies of fungal mitochondrial systems have served to identify cis-acting sequences within mitochondrial introns, and trans-acting protein products of mitochondrial and nuclear genes which are important for splicing, and to show that some mitochondrial introns are mobile genetic elements. In vitro genetic studies of the self-splicing intron within the Tetrahymena thermophila nuclear large ribosomal RNA precursor (Tetrahymena LSU intron) have been used to examine essential and nonessential RNA sequences and structures in RNA-catalyzed splicing. In vivo and in vitro genetic analysis of the intron within the bacteriophage T4 td gene has permitted the detailed examination of mutant phenotypes by analyzing splicing in vivo and self-splicing in vitro. The genetic studies combined with phylogenetic analysis of intron structure based on comparative nucleotide sequence data [Cech 73 (1988) 259-271] and with biochemical data obtained from in vitro splicing experiments have resulted in significant advances in understanding the biology and chemistry of group-I introns.     

Excised group II introns in yeast mitochondria are lariats and can be formed by self-splicing in vitro

Excised group II introns in yeast mitochondria appear as covalently closed circles under the electron microscope. We show that these circular molecules are branched and resemble the lariats arising through splicing of nuclear pre-mRNAs in yeast and higher eukaryotes. One member of this intron class (aI5c in the gene for cytochrome c oxidase subunit I) is capable of self-splicing in vitro, giving correct exon-exon ligation and resulting in the appearance of both linear and lariat forms of the excised intron. Nuclease digestion of the latter molecules reveals the presence of a complex oligonucleotide with the probable structure AGU, which thus resembles the branch point formed in the spliceosome-dependent reactions undergone by nuclear pre-mRNAs. Unlike group I introns, this group II intron is not demonstrably dependent on GTP for self-splicing and circularization of the isolated, linear intron is not observed. A model accounting for these observations is presented.