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

Group II introns: mobile ribozymes that invade DNA

Group II introns are mobile ribozymes that self-splice from precursor RNAs to yield excised intron lariat RNAs, which then invade new genomic DNA sites by reverse splicing. The introns encode a reverse transcriptase that stabilizes the catalytically active RNA structure for forward and reverse splicing, and afterwards converts the integrated intron RNA back into DNA. The characteristics of group II introns suggest that they or their close relatives were evolutionary ancestors of spliceosomal introns, the spliceosome, and retrotransposons in eukaryotes. Further, their ribozyme-based DNA integration mechanism enabled the development of group II introns into gene targeting vectors ("targetrons"), which have the unique feature of readily programmable DNA target specificity.

Extensive mis-splicing of a bi-partite plant mitochondrial group II intron

Expression of the seed plant mitochondrial nad5 gene involves two trans-splicing events that remove fragmented group II introns and join the small, central exon c to exons b and d. We show that in both monocot and eudicot plants, extensive mis-splicing of the bi-partite intron 2 takes place, resulting in the formation of aberrantly spliced products in which exon c is joined to various sites within exon b. These mis-spliced products accumulate to levels comparable to or greater than that of the correctly spliced mRNA. We suggest that mis-splicing may result from folding constraints imposed on intron 2 by base-pairing between exon a and a portion of the bi-partite intron 3 downstream of exon c. Consistent with this hypothesis, we find that mis-splicing does not occur in Oenothera mitochondria, where intron 3 is further fragmented such that the predicted base-pairing region is not covalently linked to exon c. Our findings suggest that intron fragmentation may lead to mis-splicing, which may be corrected by further intron fragmentation.

DNA polymerization catalysed by a group II intron RNA in vitro

The excised group II intron bI1 from Saccharomyces cerevisiae can act as a ribozyme catalysing various chemical reactions with different substrate RNAs in vitro . Recently, we have described an editing-like RNA polymerization reaction catalysed by the bI1 intron lariat that proceeds in the 3'-->5'direction. Here we show that the bI1 lariat RNA can also catalyse successive deoxyribonucleotide polymerization reactions on exogenous substrate molecules. The basic mechanism of the reaction involved interacting cycles between an alternative version of partial reverse splicing (lariat charging) and canonical forward splicing (lariat discharging by exon ligation). With an overall chain growth in the 3'-->5' direction, the 5' exon RNAs (IBS1dN) were elongated by successive insertion of deoxyribonucleotides derived from single deoxyribonucleotide substitutions (dA, dG, dC or dT). All four deoxyribonucleotides were used as substrates, although with different efficiencies. Our findings extend the catalytic repertoire of group II intron RNAs not only by a novel DNA polymerization activity, but also by a DNA-DNA ligation capacity, supporting the idea that ribozymes might have been part of the first primordial polymerization machinery for both RNA and DNA.

Overexpression of DEAD box protein pMSS116 promotes ATP-dependent splicing of a yeast group II intron in vitro

The group II intron bI1, the first intron of the mitochondrial cytochrome b gene in yeast is self-splicing in vitro. Genetic evidence suggests that trans-acting factors are required for in vivo splicing of this intron. In accordance with these findings, we present in vitro data showing that splicing of bI1 under physiological conditions depends upon the presence of proteins of a mitochondrial lysate. ATP is an essential component is this reaction. Overexpression of the nuclear-encoded DEAD box protein pMSS-116 results in a marked increase in the ATP-dependent splicing activity of the extract, suggesting that pMSS116 may play an important role in splicing of bI1.

A tertiary interaction in the Tetrahymena intron contributes to selection of the 5' splice site

The utilization of cryptic splice sites has been observed in a number of RNA splicing reactions. In the self-splicing group I intron of Tetrahymena thermophila, point mutations of either A57 or A95 promote cleavage at two sites other than the normal 5' splice site, suggesting that these nucleotides are involved in a common tertiary interaction. These results are unusual since A57 and A95 are neither at nor near the 5' splice site in the sequence or secondary structure. Cleavage at the alternative sites appears to occur by intron cyclization, a reaction with well-established structural and mechanistic similarities to the first step of RNA self-splicing. Alternative docking of P1 (the helix containing the 5' splice site paired to the internal guide sequence of the intron) into the catalytic core accounts for cleavage at the cryptic reaction sites. We propose that the A57/A95 interaction, along with an element implicated previously (J1/2), provide structural connectivity from the reaction site in P1 to the catalytic core of the Tetrahymena intron. It seems likely that RNA splicing in general will require such tertiary interactions to position RNA helices.

A general two-metal-ion mechanism for catalytic RNA

A mechanism is proposed for the RNA-catalyzed reactions involved in RNA splicing and RNase P hydrolysis of precursor tRNA. The mechanism postulates that chemical catalysis is facilitated by two divalent metal ions 3.9 A apart, as in phosphoryl transfer reactions catalyzed by protein enzymes, such as the 3',5'-exonuclease of Escherichia coli DNA polymerase I. One metal ion activates the attacking water or sugar hydroxyl, while the other coordinates and stabilizes the oxyanion leaving group. Both ions act as Lewis acids and stabilize the expected pentacovalent transition state. The symmetry of a two-metal-ion catalytic site fits well with the known reaction pathway of group I self-splicing introns and can also be reconciled with emerging data on group II self-splicing introns, the spliceosome, and RNase P. The role of the RNA is to position the two catalytic metal ions and properly orient the substrates via three specific binding sites.

Splicing of group II introns in spinach chloroplasts (in vivo): analysis of lariat formation

To investigate the mechanism of chloroplast mRNA splicing in vivo, RNAs from four spinach chloroplast group II intron-containing genes were analyzed. For each of these genes, atpF, rpoC1, petD, and petB, Northern analysis of chloroplast RNAs detected putative lariat-intron/3' exon-splicing intermediates. Treatment of these RNAs with HeLa cell-debranching extract caused the putative splicing intermediates to disappear, thereby confirming their identities. The lariat-splicing intermediates were further examined by reverse transcriptase extension to determine the branch point location. The in vivo branch points of the atpF and petD introns were found to be eight bases upstream of their respective 3' intron/exon boundaries. In contrast, no splicing intermediates could be detected by primer-extension analysis of petB and rpoC1. This unexpected result served to demonstrate that the quantity of lariat-intron/3' exon-splicing intermediates present in the chloroplast RNA population is considerably less in the cases of rpoC1 and petB compared to atpF and petD. The steady-state level of any splicing intermediate is the result of a balance between the splicing kinetics of a particular RNA and the susceptibility of the splicing intermediate to degradation. We conclude that the balance between these two factors varies significantly for chloroplast introns, even for those, such as petB and petD, that are transcribed from the same promoter.

Group II introns deleted for multiple substructures retain self-splicing activity

Group II introns can be folded into highly conserved secondary structures with six major substructures or domains. Domains 1 and 5 are known to play key roles in self-splicing, while the roles of domains 2, 3, 4, and 6 are less clear. A trans assay for domain 5 function has been developed which indicates that domain 5 has a binding site on the precursor RNA that is not predicted from any secondary structure element. In this study, the self-splicing group II intron 5 gamma of the coxI gene of yeast mitochondrial DNA was deleted for various intron domains, singly and in combinations. Those mutant introns were characterized for self-splicing reactions in vitro as a means of locating the domain 5 binding site. A single deletion of domain 2, 3, 4, or 6 does not block in vitro reactions at either splice junction, though the deletion of domain 6 reduces the fidelity of 3' splice site selection somewhat. Even the triple deletion lacking domains 2, 4, and 6 retains some self-splicing activity. The deletion of domains 2, 3, 4, and 6 blocks the reaction at the 3' splice junction but not at the 5' junction. From these results, we conclude that the binding site for domain 5 is within domain 1 and that the complex of 5' exon, domain 1, and domain 5 (plus short connecting sequences) constitutes the essential catalytic core of this intron.

Group II introns deleted for multiple substructures retain self-splicing activity

Group II introns can be folded into highly conserved secondary structures with six major substructures or domains. Domains 1 and 5 are known to play key roles in self-splicing, while the roles of domains 2, 3, 4, and 6 are less clear. A trans assay for domain 5 function has been developed which indicates that domain 5 has a binding site on the precursor RNA that is not predicted from any secondary structure element. In this study, the self-splicing group II intron 5 gamma of the coxI gene of yeast mitochondrial DNA was deleted for various intron domains, singly and in combinations. Those mutant introns were characterized for self-splicing reactions in vitro as a means of locating the domain 5 binding site. A single deletion of domain 2, 3, 4, or 6 does not block in vitro reactions at either splice junction, though the deletion of domain 6 reduces the fidelity of 3' splice site selection somewhat. Even the triple deletion lacking domains 2, 4, and 6 retains some self-splicing activity. The deletion of domains 2, 3, 4, and 6 blocks the reaction at the 3' splice junction but not at the 5' junction. From these results, we conclude that the binding site for domain 5 is within domain 1 and that the complex of 5' exon, domain 1, and domain 5 (plus short connecting sequences) constitutes the essential catalytic core of this intron.

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.

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.

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.

Structural requirements for selection of 5'- and 3' splice sites of group II introns

The group II intron bl1 in the gene for apocytochrome b in yeast mitochondrial DNA (COB) is self-splicing in vitro. It could recently be shown that self-splicing of this intron is fully reversible in vitro. In addition, intron integration is not restricted to parental exons, since the intron can also integrate into a foreign RNA. The position of insertion seems to be immediately 3' to a cryptic intron binding site 1 (IBS1). We confirmed and extended these results by sequencing 26 individual RNAs with transposed introns after reverse transcription and PCR amplification. Results show that intron integration into authentic exons is generally correct, but that integration into a foreign RNA is often inaccurate, i.e. insertion is one nt downstream or upstream of the 3' end of IBS1. This leads to the generation of 5' splice junctions of the new intron-harbouring 'preRNAs' with addition (or deletion) of a single A residue at the 3' end of IBS1. To investigate which structures help to define the position of 5'- and 3' cleavage, preRNAs of i) these clones with aberrant 5' splice junctions and ii) preRNAs with artificial hairpins between domains 5 and 6 of the intron were spliced under different reaction conditions. Results obtained let us conclude that i) branchpoint dependent 5' cleavage is directed by the 5' terminal G residue of the intron and, ii) the first nucleotide(s) of the 3' exon play an important role in defining the 3' splice site.

Splicing of the Petunia cytochrome oxidase subunit II intron

A comparative analysis of the plant intron-containing mitochondrial cytochrome oxidase subunit II (coxII) genes provides an indication that four conserved sequence motifs, present in exon 1 (intron-binding sequences; IBS), and complementary motifs (exon-binding sequences; EBS), present in domain I of the group II intron, may be involved in splicing of the intron. Two of these potential IBS motifs (IBS1 and IBS2) have been previously discussed. Two further potential IBS motifs (IBSa and IBSb), which occur twice within exon 1, could be involved in specification of the 5' splice site and of a 5' cryptic splice site. Nuclease-protection experiments and DNA sequence analysis of a spliced coxII cDNA have confirmed the predicted positions of the petunia coxII 5' and 3' splice sites. Evidence for the occurrence of splicing in vivo at the putative 5' cryptic splice site in petunia is provided by the detection of a nuclease-protected fragment corresponding to the size which is predicted if splicing at the proposed cryptic splice site occurs. The existence and location of a cryptic splice site, upstream of the normal coxII 5' splice site, is consistent with the proposed derivation of the cytoplasmic male sterility (CMS)-associated pcf gene from an abnormally spliced coxII transcript (Pruitt and Hanson 1989).

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.

Evolutionary conservation of transcriptional machinery between yeast and plants as shown by the efficient expression from the CaMV 35S promoter and 35S terminator

Complementation of fission yeast mutants by plant genomic libraries could be a promising method for the isolation of novel plant genes. One important prerequisite is the functioning of plant promoters and terminators in Schizosaccharomyces pombe and Saccharomyces cerevisiae. Therefore, we studied the expression of the bacterial beta-glucuronidase (GUS) reporter gene under the control of the Cauliflower Mosaic Virus (CaMV) 35S promoter and 35S terminator. We show here that S. pombe initiates transcription at exactly the same start site as was reported for tobacco. The 35S CaMV terminator is appropriately recognized leading to a polyadenylated mRNA of the same size as obtained in plant cells transformed with the same construct. Furthermore, the GUS-mRNA is translated into fully functional GUS protein, as determined by an enzymatic assay. Interestingly, expression of the 35S promoter in the budding yeast S. cerevisiae was found to be only moderate and about hundredfold lower than in S. pombe. To investigate whether different transcript stabilities are responsible for this enormous expression difference in the two yeasts, the 35S promoter was substituted by the ADH (alcohol dehydrogenase) promoter from fission yeast. In contrast to the differential expression pattern of the 35S promoter, the ADH promoter resulted in equally high expression rates in both fission and budding yeast, comparable to the 35S promoter in S. pombe. Since the copy number of the 35S-GUS constructs differs only by a factor of two in the two yeasts, it appears that differential recognition of the 35S promoter is responsible for the different transcription rates.

A self-splicing group II intron in the mitochondrial large subunit rRNA (LSUrRNA) gene of the eukaryotic alga Scenedesmus obliquus

The DNA sequence has been determined of the 3' terminus from the mitochondrial large subunit ribosomal RNA (LSUrRNA) gene of the eukaryotic green alga Scenedesmus obliquus (strain KS3/2). The gene contains two intervening sequences with characteristic sequence motifs of group II and group I introns respectively. The exon/intron boundaries of the introns have been revealed by sequence determination of the mature rRNA. During RNA processing of the precursor RNA, several abundant RNA molecules are stably maintained in addition to the mature rRNA in vivo. In vitro transcripts of the LSUrRNA gene containing the group II intron (608 bp) display a strong 'self-splicing' activity under high salt conditions. The 608 bp intron is the first group II intron reported to be integrated into a LSUrRNA gene and represents the smallest self-splicing group II intron from eukaryotic organelles so far described.

Effect of deletions at structural domains of group II intron bI1 on self-splicing in vitro

Some group II introns can undergo a protein-independent splicing reaction with the basic reaction pathway similar to nuclear pre-mRNA splicing and the catalytic functions of some of the structural components have been determined. To identify further functional domains, we have generated an ensemble of partial and complete deletions of domains I, II, III and IV of the self-splicing group II intron bI1 from yeast mitochondria and studied their effects on the splicing reaction in vitro. Our results indicate that domains II and IV, which vary considerably in length and structure among group II introns, do not play a direct role in catalysis but mainly help to ensure the proper interaction between upstream and downstream catalytically active structural elements. Deletions of sub-domains of domain I and domain III indicate that these elements are involved in 5' cleavage by hydrolysis and in a reaction in trans (exon reopening), and that this function can be inhibited without affecting the normal 5' cleavage by transesterification. Yet, we infer that the helical structures affected by the mutational alterations might not contribute to this reaction mode per se but that changes within local secondary structures perturb the internal conformation of the ribozyme. Furthermore, we have designed an abbreviated version of intron bI1, with a length of 542 nucleotides, which is still catalytically active.

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.

Reverse self-splicing of group II intron RNAs in vitro

Group II introns, which are classed together on the basis of a conserved secondary structure, are found in organellar genes of lower eukaryotes and plants. Like introns in nuclear pre-messenger RNA, they are excised by a two-step splicing reaction to generate branched circular RNAs, the so-called lariats. A remarkable feature of group II introns is their self-splicing activity in vitro. In the absence of a nucleotide cofactor, the intron RNAs catalyse two successive transesterification reactions which lead to autocatalytic excision of the lariat IVS from pre-mRNA and concomitantly to exon ligation. By virtue of its ability to specifically bind the 5' exon, the intron can also catalyse such reactions on exogenous RNA substrates. This sequence-specific attachment could enable group II introns to integrate into unrelated RNAs by reverse splicing, in a process similar to that described for the self-splicing Tetrahymena group I intron. Here we report that group II lariat IVS can indeed reintegrate itself into an RNA composed of the ligated exons in vitro. This occurs by a process of self-splicing that completely reverses both transesterification steps of the forward reaction: it involves a transition of the 2'-5' phosphodiester bond of the lariat RNA into the 3'-5' bond of the reconstituted 5' splice junction.

Comparative and functional anatomy of group II catalytic introns--a review

The 70 published sequences of group II introns from fungal and plant mitochondria and plant chloroplasts are analyzed for conservation of primary sequence, secondary structure and three-dimensional base pairings. Emphasis is put on structural elements with known or suspected functional significance with respect to self-splicing: the exon-binding and intron-binding sites, the bulging A residue involved in lariat formation, structural domain V and two isolated base pairs, one of them involving the last intron nucleotide and the other one, the first nt of the 3' exon. Separate sections are devoted to the 29 group II-like introns from Euglena chloroplasts and to the possible relationship of catalytic group II introns to nuclear premessenger introns. Alignments of all available sequences of group II introns are provided in the APPENDIX.

Cytochrome oxidase subunit II sequences in Petunia mitochondria: two intron-containing genes and an intron-less pseudogene associated with cytoplasmic male sterility

The mitochondrial genome of Petunia hybrida contains two transcribed cytochrome oxidase subunit II (coxII) genes. The coding region of both genes is split by a 1.3 kb group II intron. Unlike coxII-1, which is similar to other sequenced plant coxII genes, the coxII-2 coding region is extended by 48 codons. The cytoplasmic male sterile (CMS) Petunia contains one coxII gene similar in structure and transcript pattern to the coxII-1 gene found in the fertile genome. Comparison of the sequenced coxII genes from the fertile mitochondrial genome with the coxII sequences present in the CMS-associated pcf gene from the CMS genome (Young and Hanson 1987) suggests that pcf is a processed pseudogene. A model for the generation of pcf is presented.