Processing of yeast mitochondrial RNA: involvement of intramolecular hybrids in splicing of cob intron 4 RNA by mutation and reversion

Revertants have been obtained from six mutants of the box9 cluster, which are supposed to be defective in RNA splicing as a result of alterations in a splice signal sequence. This sequence is in the 5' part of intron 4 of the cob gene, 330 to 340 bp downstream from the 5' splice site. Sequencing reveals that reversion to splicing competence is achieved by restoration of the wild-type box9 sequence; by creation of novel box9 sequences; and by introduction of a second site or suppressor mutation (sup-) compensating for the effect of the primary box9- mutation. The sup- mutation alters a sequence in intron 4,293 bp upstream from the box9- primary mutation. The box9 sequence and this upstream sequence can base pair to form an intramolecular hybrid in intron RNA in which box9- and sup- are compensatory base pair exchanges (G----A and C----U, respectively). Thus intramolecular hybrid structures of intron RNA are essential for RNA splicing.     

Impairment of yeast pre-mRNA splicing by potential secondary structure-forming sequences near the conserved branchpoint sequence.

The absolutely conserved TACTAAC box within introns of RNA polymerase II-transcribed genes of the yeast Saccharomyces cerevisiae serves an indispensable role in lariat formation. We show in this report that rather short palindromic sequences inserted into the yeast actin gene intron immediately 3' to the TACTAAC box block the second but not the first splicing step. In contrast, a palindromic sequence inserted some 23 bp 3' of the TACTAAC box did not affect correct and efficient splicing. The data suggest that hairpin structures that might form adjacent to the branchsite sequence interfere with some necessary alteration of the spliceosome required for 3' intron cleavage and exon ligation.     

An LKB1 AT-AC intron mutation causes Peutz-Jeghers syndrome via splicing at noncanonical cryptic splice sites

Peutz-Jeghers syndrome (PJS) is an autosomal dominant disorder associated with gastrointestinal polyposis and an increased cancer risk. PJS is caused by germline mutations in the tumor suppressor gene LKB1. One such mutation, IVS2+1A>G, alters the second intron 5' splice site, which has sequence features of a U12-type AT-AC intron. We report that in patients, LKB1 RNA splicing occurs from the mutated 5' splice site to several cryptic, noncanonical 3' splice sites immediately adjacent to the normal 3' splice site. In vitro splicing analysis demonstrates that this aberrant splicing is mediated by the U12-dependent spliceosome. The results indicate that the minor spliceosome can use a variety of 3' splice site sequences to pair to a given 5' splice site, albeit with tight constraints for maintaining the 3' splice site position. The unusual splicing defect associated with this PJS-causing mutation uncovers differences in splice-site recognition between the major and minor pre-mRNA splicing pathways.     

Multiple functions of Saccharomyces cerevisiae splicing protein Prp24 in U6 RNA structural rearrangements.

U6 spliceosomal RNA has a complex secondary structure that includes a highly conserved stemloop near the 3' end. The 3' stem is unwound when U6 RNA base-pairs with U4 RNA during spliceosome assembly, but likely reforms when U4 RNA leaves the spliceosome prior to the catalysis of splicing. A mutation in yeast U6 RNA that hyperstabilizes the 3' stem confers cold sensitivity and inhibits U4/U6 assembly as well as a later step in splicing. Here we show that extragenic suppressors of the 3' stem mutation map to the gene coding for splicing factor Prp24. The suppressor mutations are located in the second and third of three RNA-recognition motifs (RRMs) in Prp24 and are predicted to disrupt RNA binding. Mutations in U6 RNA predicted to destabilize a novel helix adjacent to the 3' stem also suppress the 3' stem mutation and enhance the growth defect of a suppressor mutation in RRM2 of Prp24. Both phenotypes are reverted by a compensatory mutation that restores pairing in the novel helix. These results are best explained by a model in which RRMs 2 and 3 of Prp24 stabilize an extended intramolecular structure in U6 RNA that competes with the U4/U6 RNA interaction, and thus influence both association and dissociation of U4 and U6 RNAs during the splicing cycle.     

Molecular consequences of specific intron mutations on yeast mRNA splicing in vivo and in vitro

We have altered the TACTAAC sequence in the yeast CYH2m gene intron to TACTACC. This mutation changes the nucleotide at the normal position of the branch in intron RNA lariats produced during pre-mRNA splicing, and it prevents splicing in vivo. In a yeast pre-mRNA splicing system, CYH2m pre-mRNA carrying the TACTACC mutation is not specifically cut or rearranged in any way. Substitution of an A for the first G of the CYH2m intron, converting the highly conserved GTATGT 5' splice site sequence to ATATGT, also blocks intron excision in vivo and in vitro: pre-mRNA carrying this mutation was still cut normally at the mutant 5' splice site in vitro, to give authentic exon 1 and an intron-exon 2 lariat RNA with an A-A 2'-5' phosphodiester linkage at the branch point. This lariat RNA is a dead-end product. The subsequent cleavage at the 3' splice site is therefore sensitive to the sequence of the 5' end of the intron attached at the branch point.     

Mapping of branchpoint nucleotides in mutant pre-mRNAs expressed in plant cells

Pre-mRNA encoding rubisco activase in the Arabidopsis thaliana mutant rca contains a GU to AU change at the 5' splice site of intron 3 and this mutation results in accumulation of splicing intermediates bearing an incompletely processed intron. It has been demonstrated that one of the intermediates contains intron 3 in the form of a lariat and the branchpoint nucleotide has been mapped to the A residue at position −32 forming part of the sequence UUG A U. Analysis of a similar GU to AU 5' splice site mutation, present in a synthetic pre-mRNA context expressed in transfected protoplasts of Nicotiana plumbaginifolia , also suggests formation of lariats with branching occurring at A₋₃₁. A small fraction (approximately 10%) of this mutant pre-mRNA also underwent the second step of splicing. In addition to the consensus AG, an AU dinucleotide was used as splicing acceptor.     

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.     

Mutations in yeast U5 snRNA alter the specificity of 5' splice-site cleavage

Recognition of 5' splice sites in pre-mRNA splicing is achieved in part by base pairing with U1 snRNA. We have used interactive suppression in the yeast Saccharomyces cerevisiae to look for other factors involved in 5' splice-site recognition. This approach identified an extragenic suppressor that activates a cryptic 5' splice site. The suppressor is a gene for U5 snRNA (snR7) with a single base mutation in a strictly conserved 9 base sequence. This suggests that U5 snRNA can play a part in determining the position of 5' splice-site cleavage. Consistent with this, we have been able to isolate other mutations in the 9 base element in U5 snRNA that specifically activate a second cryptic 5' splice site nearby.     

A spontaneous duplication in U6 spliceosomal RNA uncouples the early and late functions of the ACAGA element in vivo.

U6 RNA enters the spliceosome base paired with U4 RNA, but dissociates from U4 RNA before the catalytic steps of splicing. We have identified a cold-sensitive lethal mutation in U4 RNA (U4-cs1) that blocks the splicing pathway after U4/U6 complex formation, but before the first catalytic step of splicing. Remarkably, selection for suppressors of the cold-sensitive growth of the U4-cs1 strain yielded a tandem duplication of the highly conserved ACAGA sequence of U6 RNA (U6-Dup). The ACAGA sequence plays an essential role in spliceosome assembly and in the second catalytic step of pre-mRNA splicing; one or both of these roles involves direct base pairing to the pre-mRNA 5' splice site. In a U4-cs1/U6-Dup double-mutant strain grown at low temperature, the upstream ACAGA sequence of U6 RNA is required for suppression of the U4 mutation, whereas the downstream ACAGA sequence is required for other essential functions. Based on the sequence requirements for function of the upstream ACAGA element of U6-Dup, we propose that it pairs with the pre-mRNA 5' splice site during incorporation of the U4/U6 complex into the spliceosome and that the subsequent dissociation of U4 RNA exposes the downstream ACAGA sequence, which functions in the catalytic steps. The properties of this mutant U4/U6 complex provide compelling in vivo evidence that U6 RNA normally base pairs with the 5' splice site before disruption of its pairing with U4 RNA.     

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.     

Suppressor U1 Snrnas in Drosophila

Although the role of U1 small nuclear RNAs (snRNAs) in 5' splice site recognition is well established, suppressor U1 snRNAs active in intact multicellular animals have been lacking. Here we describe suppression of a 5' splice site mutation in the Drosophila melanogaster white gene (w(DR18)) by compensatory changes in U1 snRNA. Mutation of positions -1 and +6 of the 5' splice site of the second intron (ACG|GTGACT to ACC|GTGAGC) results in the accumulation of RNA retaining this 74-nucleotide intron in both transfected cells and transgenic flies. U1-3G, a suppressor U1 snRNA which restores basepairing at position +6 of the mutant intron, increases the ratio of spliced to unspliced w(DR18) RNA up to fivefold in transfected Schneider cells and increases eye pigmentation in w(DR18) flies. U1-9G, which targets position -1, suppresses w(DR18) in transfected cells less well. U1-3G,9G has the same effect as U1-3G although it accumulates to lower levels. Suppression of w(DR18) has revealed that the U1b embryonic variant (G134 to U) is active in Schneider cells and pupal eye discs. However, the combination of 9G with 134U leads to reduced accumulation of both U1b-9G and U1b-3G,9G, possibly because nucleotides 9 and 134 both participate in a potential long-range intramolecular base-pairing interaction. High levels of functional U1-3G suppressor reduce both viability and fertility in transformed flies. These results show that, despite the difficulties inherent in stably altering splice site selection in multicellular organisms, it is possible to obtain suppressor U1 snRNAs in flies.     

Synthesis of predominantly unspliced cytoplasmic RNAs by chimeric herpes simplex virus type 1 thymidine kinase-human beta-globin genes.

The herpes simplex virus type 1 thymidine kinase (tk) gene lacks introns and produces stable mRNA in the absence of splicing. We have prepared a hybrid gene by placing the first exon, first intron (first intervening sequence, designated IVS1), and most of the second exon of the normal human beta-globin gene into the 3' untranslated region of the tk gene. Although this hybrid gene contains all globin sequences presumed necessary for the splicing of IVS1, predominantly, unspliced stable cytoplasmic RNA is produced in both long- and short-term expression assays. Moreover, stable unspliced cytoplasmic RNA is detected whether the intron is situated in a sense or an antisense orientation. Efficient splicing of IVS1 is obtained either by deleting the majority of tk coding sequences or by relocating the globin sequences from the 3' to the 5' untranslated region of the tk gene.     

Interlocked circle formation by group I introns: structural requirements and mechanism.

Precursor RNA transcribed from the yeast mitochondrial gene coding for the large ribosomal RNA contains a group I intron that can excise itself in vitro. Apart from group I specific sequence elements the intron also contains a gene encoding a DNA endonuclease involved in intron dispersal. A precursor RNA derivative from which this gene has been removed self-splices efficiently, but due to activation of cryptic opening sites located in the 5' exon, the 3' part of this exon is sometimes co-excised with the intron. Upon further reaction, this enlarged intron molecules give rise to interlocked circles, comprising small circles derived from 5' exon parts and large circles of the intron. Sequence comparison between cryptic opening sites and authentic splice sites reveals in most cases homology with the 3' exon part that is capable of interacting with the Internal Guide Sequence. The role of the IGS was further substantiated by replacing the cryptic opening sites with well defined sequences of authentic splice sites: one corresponding to the 3' splice site and its mutant derivatives, the other to a fragment containing the natural 5'-3' exon junction. Precursor RNAs derived from these constructs give rise to interlocked circles, and mutation studies confirm that the 3' exon nucleotides flanking a 3' splice site are essential for their formation. The results underline the crucial role of the IGS in interlocked circle formation which behaves similarly as in the normal self-splicing reactions. It has been proposed that the two short helices formed by basepairing of the IGS with the 5' and 3' exon can co-axially stack on top of each other forming a quasi continuous RNA double helix or pseudoknot. We present a model explaining how transesterification reactions of a mutant precursor RNA in such a pseudoknot can lead to interlocked circles. The experiments support the notion that a similar structure is also operative in splicing of wild type precursor RNA.     

Requirements for mini-exon inclusion in potato invertase mRNAs provides evidence for exon-scanning interactions in plants

Invertases are responsible for the breakdown of sucrose to fructose and glucose. In all but one plant invertase gene, the second exon is only 9 nt in length and encodes three amino acids of a five-amino-acid sequence that is highly conserved in all invertases of plant origin. Sequences responsible for normal splicing (inclusion) of exon 2 have been investigated in vivo using the potato invertase, invGF gene. The upstream intron 1 is required for inclusion whereas the downstream intron 2 is not. Mutations within intron 1 have identified two sequence elements that are needed for inclusion: a putative branchpoint sequence and an adjacent U-rich region. Both are recognized plant intron splicing signals. The branchpoint sequence lies further upstream from the 3' splice site of intron 1 than is normally seen in plant introns. All dicotyledonous plant invertase genes contain this arrangement of sequence elements: a distal branchpoint sequence and adjacent, downstream U-rich region. Intron 1 sequences upstream of the branchpoint and sequences in exons 1, 2, or 3 do not determine inclusion, suggesting that intron or exon splicing enhancer elements seen in vertebrate mini-exon systems are absent. In addition, mutation of the 3' and 5' splice sites flanking the mini-exon cause skipping of the mini-exon, suggesting that both splice sites are required. The branchpoint/U-rich sequence is able to promote splicing of mini-exons of 6, 3, and 1 nt in length and of a chicken cTNT mini-exon of 6 nt. These sequence elements therefore act as a splicing enhancer and appear to function via interactions between factors bound at the branchpoint/U-rich region and at the 5' splice site of intron 2, activating removal of this intron followed by removal of intron 1. This first example of splicing of a plant mini-exon to be analyzed demonstrates that particular arrangement of standard plant intron splicing signals can drive constitutive splicing of a mini-exon.     

Multiple functional domains of human U2 small nuclear RNA: strengthening conserved stem I can block splicing.

We showed previously that a branch site mutation in simian virus 40 early pre-mRNA that prevented small t antigen mRNA splicing could be efficiently suppressed by a compensatory mutation in a coexpressed U2 small nuclear (sn) RNA gene. We have now generated second-site mutations in this suppressor gene to investigate regions of U2 RNA required for function. A number of mutations in a putative stem at the 5' end of the molecule inhibited splicing, indicating that bases in this region are important for activity. However, several lines of evidence suggested that formation of the entire stem is not essential for splicing. Indeed, mutations that strengthen the stem actually inhibited splicing, and evidence that this prevents a required base-pairing interaction with U6 snRNA is presented. These results suggest that the relative stabilities of competing intra- and intermolecular base-pairing interactions play an important role in the splicing reaction. Mutations in a conserved single-stranded region immediately 3' to the branch site recognition sequence all inhibited splicing, indicating that this region is required for U2 function, although its exact role remains unknown. Finally, two mutations in the loop of stem IV at the 3' end of the molecule, which destroy the binding site of U2 sn ribonucleoprotein B", prevented small t splicing; this finding contrasts with previous studies which utilized different assay systems. Analysis of the accumulation and subcellular localization of all of the mutant RNAs showed that they were similar to those of the parental suppressor U2 RNA, indicating that the effects observed indeed reflect defects in splicing.     

A comprehensive characterization of a group IB intron and its encoded maturase reveals that protein-assisted splicing requires an almost intact intron RNA

The group I intron (AnCOB) of the mitochondrial apocytochrome b gene from Aspergillus nidulans encodes a bi-functional maturase protein that is also a DNA endonuclease. Although the AnCOB intron self-splices, the encoded maturase protein greatly facilitates splicing, in part, by stabilizing RNA tertiary structure. To determine their role in self-splicing and in protein-assisted splicing, several peripheral RNA sub-domains in the 313 nucleotide intron were deleted (P2, P9, P9.1) or truncated (P5ab, P6a). The sequence in two helices (P2 and P9) was also inverted. Except for P9, the deleted regions are not highly conserved among group I introns and are often dispensable for catalytic activity. Nevertheless, despite the very tight binding of AnCOB RNA to the maturase and the high activity of the bimolecular complex (the rate of 5' splice-site cleavage was >20 min(-1) with guanosine as the cofactor), the intron was surprisingly sensitive to these modifications. Several mutations inactivated splicing completely and virtually all impaired splicing to varying degrees. Mutants containing comparatively small deletions in various regions of the intron significantly decreased binding affinity (generally >10(4)-fold), indicating that none of the domains that remained constitutes the primary recognition site of the maturase. The data argue that tight binding requires tertiary interactions that can be maintained by only a relatively intact intron RNA, and that the binding mechanism of the maturase differs from those of two other well-characterized group I intron splicing factors, CYT-18 and Cpb2. A model is proposed in which the protein promotes widespread cooperative folding of an RNA lacking extensive initial tertiary structure.     

The role of intron structures in trans-splicing and cap 4 formation for the Leishmania spliced leader RNA.

A 39-nucleotide leader is trans-spliced onto all trypanosome nuclear mRNAs. The precursor spliced leader RNA was tested for trans-splicing function in vivo by mutating the intron. We report that in Leishmania tarentolae spliced leader RNA 5' modification is influenced by the primary sequence of stem-loop II, the Sm-binding site, and the secondary structure of stem-loop III. The sequence of stem-loop II was found to be important for cap 4 formation and splicing. As in Ascaris, mutagenesis of the bulge nucleotide in stem-loop II was detrimental to trans-splicing. Because restoration of the L. tarentolae stem-loop II structure was not sufficient to restore splicing, this result contrasts the findings in the kinetoplastid Leptomonas, where mutations that restored stem-loop II structure supported splicing. Methylation of the cap 4 structure and splicing was also dependent on both the Sm-binding site and the structure of stem-loop III and was inhibited by incomplete 3' end processing. The critical nature of the L. tarentolae Sm-binding site is consistent with its essential role in the Ascaris spliced leader RNA, whereas in Leptomonas mutation of the Sm-binding site and deletion of stem-loop III did not affect trans-splicing. A pathway for Leishmania spliced leader RNA processing and maturation is proposed.