An upstream AG determines whether a downstream AG is selected during catalytic step II of splicing

Specific mechanisms must exist to ensure fidelity in selecting the AG dinucleotide that functions as the 3' splice site during the second transesterification step of splicing. Here we show that the optimal location for this AG is within a narrow distance (19 to 23 nucleotides [nt]) downstream from the branch point sequence (BPS). Contrary to previous expectations, AGs located less than 23 nt from the BPS are always recognized, even when a second AG located more optimally downstream is used in the transesterification reaction. Indeed, the AG closest to the BPS actually dictates the precise location of the AG that engages in the reaction. This mechanism, in which the AG is identified by a general localization step followed by a precise localization step, may be used to achieve fidelity while allowing flexibility in the location of 3' splice sites.     

Mutational analysis of 3' splice site selection during trans-splicing

trans-Splicing is essential for mRNA maturation in trypanosomatids. A conserved AG dinucleotide serves as the 3' splice acceptor site, and analysis of native processing sites suggests that selection of this site is determined according to a 5'-3' scanning model. A series of stable gene replacement lines were generated that carried point mutations at or near the 3' splice site within the intergenic region separating CUB2.65, the calmodulin-ubiquitin associated gene, and FUS1, the ubiquitin fusion gene of Trypanosoma cruzi. In one stable line, the elimination of the native 3' splice acceptor site led to the accumulation of Y-branched splicing intermediates, which served as templates for mapping the first trans-splicing branch points in T. cruzi. In other lines, point mutations shifted the position of the first consensus AG dinucleotide either upstream or downstream of the wild-type 3' splice acceptor site in this intergenic region. Consistent with the scanning model, the first AG dinucleotide downstream of the branch points was used as the predominant 3' splice acceptor site. In all of the stable lines, the point mutations affected splicing efficiency in this region.     

Wobble splicing reveals the role of the branch point sequence-to-NAGNAG region in 3' tandem splice site selection

Alternative splicing involving the 3' tandem splice site NAGNAG sequence may play a role in the structure-function diversity of proteins. However, how 3' tandem splice site utilization is determined is not well understood. We previously demonstrated that 3' NAGNAG-based wobble splicing occurs mostly in a tissue- and developmental stage-independent manner. Bioinformatic analysis reveals that the nucleotide preceding the AG dinucleotide may influence 3' splice site utilization; this is also supported by an in vivo splicing assay. Moreover, we found that the intron sequence plays an important role in 3' splice site selection for NAGNAG wobble splicing. Mutations of the region between the branch site and the NAGNAG 3' splice site, indeed, affected the ratio of the distal/proximal AG selection. Finally, we found that single nucleotide polymorphisms around the NAGNAG motif could affect the splice site choice, which may lead to a change in mRNA patterns and influence protein function. We conclude that the NAGNAG motif and its upstream region to the branch point sequence are required for 3' tandem splice site selection.     

U-rich tracts enhance 3' splice site recognition in plant nuclei

The process of 5' and 3' splice site definition in plant pre-mRNA splicing differs from that in mammals and yeast. In mammals, splice sites are chosen by their complementarity to U1 snRNA surrounding the /GU at the 5' splice site and by the strength of the pyrimidine tract preceding the AG/ at the 3' splice site; in plants, the 3' intron boundary is defined in a position-dependent manner relative to AU-rich elements within the intron. To determine if uridines are utilized to any extent in plant 3' splice site recognition, uridines in the region preceding the normal (−1) 3' splice site of pea rbcS3A intron 1 were replaced with adenosines. This mutant activates two cryptic 3' splice sites (+62, +95) in the downstream exon, indicating that the uridines in the region immediately preceding the normal (−1) site are essential for recognition. Placement of different length uridine tracts upstream from the cryptic +62 site indicated that a cryptic exonic 3' splice site containing 14 or 10 uridine tracts with a G at −4 can effectively outcompete the normal 3' splice site containing an eight uridine tract with a U at −4. Substitutions at the −4 position demonstrated that the identity of the nucleotide at this position greatly affects 3' splice site selection. It has been concluded that several factors affect competition between these 3' splice sites. These factors include the position of the AU transition point, the strength of the uridine tract immediately preceding the 3' terminal CAG/ and the identity of nucleotide −4.     

A U-rich tract enhances usage of an alternative 3' splice site in yeast.

There has been a long-standing belief that the mechanisms of mammalian and yeast splicing differ fundamentally in their requirement for a pyrimidine-rich motif preceding the 3' splice site. Using an in vivo assay, we have tested the influence of uridine content on competition between alternative 3' splice sites in yeast. We find that a uridine-rich tract preceding a PyAG greatly enhances its ability to compete as a splice acceptor. Moreover, a proximal PyAG is often overlooked if a more distal PyAG occurs in a superior sequence context; this observation cannot be accounted for by simple scanning models. Finally, we show that a distal (greater than 30 nucleotide) 3' splice site that is not preceded by uridines is a poor substrate for the second step of splicing; this argues that recognition of a uridine-rich motif is required for effective identification and utilization of distant splice sites.     

The conserved dinucleotide AG of the 3′ splice site may be recognized twice during in vitro splicing of mammalian mRNA precursors

We have previously used site-directed mutagenesis to introduce an additional branch site into the first intron of the human β-globin gene at nt −24 between the natural branch site (nt−37) and the normal 3′ splice site (nt−1). We found that either the upstream or downstream branch site could be used during in vitro splicing, depending on which site best matched the mammalian branch site consensus YURAC (R = purine; Y = pyrimidine). Here we show that introduction of an additional AG dinucleotide at nt −20 between the downstream branch site and the normal 3′ splice site results in alternative 3′ splicing. Splicing to the new AG uses the upstream branch site exclusively, presumably because the downstream branch site is only 4 nt from this 3′ splice site. We were surprised, however, to find that the presence of the new AG also prevents the use of the upstream branch site for splicing to the normal 3′ splice site. Analysis of additional mutants confirmed earlier work [Krainer et al.: Mechanisms of human β-globin pre-mRNA splicing. In Berg, P. (Ed.), The Robert A. Welch Foundation Conferences on Chemical Research XXIX. Genetic Chemistry: The Molecular Basis of Heredity. Welch Foundation, Houston, TX, 1985, pp. 353–382] that the new AG cannot function by itself as a complete 3′ splice site; rather, it appears that alternative 3′ splicing initiates at the normal 3′ splices site but then searches, once the reaction is underway, for the first AG downstream from the chosen branch site. Taken together, our data suggest that the conserved AG dinucleotide at the 3′ splice site may be recognized twice during mammalian mRNA splicing in vitro.     

The role of branchpoint-3'' splice site spacing and interaction between intron terminal nucleotides in 3'' splice site selection in Saccharomyces cerevisiae.

A conserved 3' splice site YAG is essential for the second step of pre-mRNA splicing but no trans-acting factor recognizing this sequence has been found. A direct, non-Watson-Crick interaction between the intron terminal nucleotides was suggested to affect YAG selection. The mechanism of YAG recognition was proposed to involve 5' to 3' scanning originating from the branchpoint or the polypyrimidine tract. We have constructed a yeast intron harbouring two closely spaced 3' splice sites. Preferential selection of a wild-type site over mutant ones indicated that the two sites are competing. For two identical sequences, the proximal site is selected. As previously observed, an A at the first intron nucleotide spliced most efficiently with a 3' splice site UAC. In this context, UAA or UAU were also more efficient 3' splice sites than UAG and competed more efficiently than the wild-type sequence with a 3' splice site UAC. We observed that a U at the first intron nucleotide is used for splicing in combination with 3' splice sites UAG, UAA or UAU. Our data indicate that the 3' splice site is not primarily selected through an interaction with the first intron nucleotide. Selection of the 3' splice site depends critically on its distance from the branchpoint but does not occur by a simple leaky scanning mechanism.     

Both the polypyrimidine tract and the 3' splice site function prior to the first step of splicing in fission yeast.

While it is known that several trans -acting splicing factors are highly conserved between Schizosaccharomyces pombe and mammals, the roles of cis -acting signals have received comparatively little attention. In Saccharomyces cerevisiae, sequences downstream from the branch point are not required prior to the first transesterification reaction, whereas in mammals the polypyrimidine tract and, in some introns, the 3' AG dinucleotide are critical for initial recognition of an intron. We have investigated the contribution of these two sequence elements to splicing in S.pombe. To determine the stage at which the polypyrimidine tract functions, we analyzed the second intron of the cdc2 gene (cdc 2-Int2), in which pyrimidines span the entire interval between the branch point and 3' splice site. Our data indicate that substitution of a polypurine tract results in accumulation of linear pre-mRNA, while expanding the polypyrimidine tract enhances splicing efficiency, as in mammals. To examine the role of the AG dinucleotide in cdc 2-Int2 splicing, we mutated the 3' splice junction in both the wild-type and pyrimidine tract variant RNAs. These changes block the first transesterification reaction, as in a subset of mammalian introns. However, in contrast to the situation in mammals, we were unable to rescue the first step of splicing in a 3' splice site mutant by expanding the polypyrimidine tract. Mutating the terminal G in the third intron of the nda 3 gene (nda 3-Int3) also blocks the first transesterification reaction, suggesting that early recognition of the 3' splice site is a general property of fission yeast introns. Counter to earlier work with an artificial intron, it is not possible to restore the first step of splicing in cdc 2-Int2 and nda 3-Int3 3' splice site mutants by introducing compensatory changes in U1 snRNA. These results highlight the diversity and probable redundancy of mechanisms for identifying the 3' ends of introns.     

Strict 3' splice site sequence requirements for U2 snRNP recruitment after U2AF binding underlie a genetic defect leading to autoimmune disease

We report that the 3' splice site associated with the alternatively spliced exon 6 of the Fas receptor CD95 displays strict sequence requirements and that a mutation that disrupts this particular sequence arrangement leads to constitutive exon 6 skipping in a patient suffering from autoimmune lymphoproliferative syndrome (ALPS). Specifically, we find an absolute requirement for RCAG/G at the 3' splice site (where R represents purine, and / indicates the intron/exon boundary) and the balance between exon inclusion and skipping is exquisitely sensitive to single nucleotide variations in the uridine content of the upstream polypyrimidine (Py)-tract. Biochemical experiments revealed that the ALPS patient mutation reduces U2 snRNP recruitment to the 3' splice site region and that this effect cannot be explained by decreased interaction with the U2 snRNP Auxiliary Factor U2AF, whose 65- and 35-kDa subunits recognize the Py-tract and 3' splice site AG, respectively. The effect of the mutation, which generates a tandem of two consecutive AG dinucleotides at the 3' splice site, can be suppressed by increasing the distance between the AGs, mutating the natural 3' splice site AG or increasing the uridine content of the Py-tract at a position distal from the 3' splice site. The suppressive effects of these additional mutations correlate with increased recruitment of U2 snRNP but not with U2AF binding, again suggesting that the strict architecture of Fas intron 5 3' splice site region is tuned to regulate alternative exon inclusion through modulation of U2 snRNP assembly after U2AF binding.     

Bimolecular exon ligation by the human spliceosome bypasses early 3' splice site AG recognition and requires NTP hydrolysis

Here we report further characterization of an in vitro assay system for exon ligation by the human spliceosome in which the 3' splice site AG is supplied by a different RNA molecule than that containing the 5' splice and branch sites. By varying the time during splicing reactions when the 3' splice site AG is made available to the splicing machinery, we show that AG recognition need not occur until after lariat formation. Thus an early AG recognition event required for spliceosome formation and lariat formation on some mammalian introns is not required for exon ligation. Depletion/add-back studies and cold competitor challenge experiments reveal that commitment of a 3' splice site AG to exon ligation requires NTP hydrolysis. Because it both physically and kinetically uncouples exon ligation from spliceosome assembly and lariat formation, the bimolecular system will be a valuable tool for further mechanistic analysis of the second step of splicing.     

Sequences involved in the control of adenovirus L1 alternative RNA splicing.

During an adenovirus infection the expression of mRNA from late region L1 is temporally regulated at the level of alternative 3' splice site selection to produce two major mRNAs encoding the 52,55K and IIIa polypeptides. The proximal 3' splice site (52,55K) is used at all times of the infectious cycle whereas the distal site (IIIa) is used exclusively late after infection. We show that a single A branch nucleotide located at position -23 is used in 52,55K splicing and that two A's located at positions -21 and -22 are used in IIIa splicing. Both 3' splice sites were active in vitro in nuclear extracts prepared from uninfected HeLa cells. However, the efficiency of IIIa splicing was only approximately 10% of 52,55K splicing. This difference in splice site activity correlated with a reduced affinity of the IIIa, relative to the 52,55K, 3' splice site for polypyrimidine tract binding proteins. Reversing the order of 3' splice sites on a tandem pre-mRNA resulted in an almost exclusive IIIa splicing indicating that the order of 3' splice site presentation is important for the outcome of alternative L1 splicing. Based on our results we suggest a cis competition model where the two 3' splice sites compete for a common RNA splicing factor(s). This may represent an important mechanism by which L1 alternative splicing is regulated.     

Conserved putative signals in 3' intron junctions in rodents

Several 3' splice signals are known todate. At the 3' splice site an AG doublet is frequently found. Just upstream of the splice site there is a string of 6-11 pyrimidines. More recently it has been found that one of the stages in the splicing process involves formation of a lariat, in which the 5' end of the intron forms a 2'-5' branch with an A residue located 18-37 nucleotides upstream of the 3' splice site. The branching-point consensus is weakly defined and consists of the sequence YNYTRAY, where Y is a pyrimidine, R a purine and N any base. The A in the sixth position is the one with which branching occurs. Here we present the results of extensive searches for additional putative signals around the branching-point consensus and the 3' splice site in rodent nuclear precursor mRNAs. The signals obtained for the over 370 rodent introns are compared with those found in a larger eukaryotic sample containing over 900 nuclear pre-mRNA introns. Of particular interest are GGGA and CCCA. In both analyses GGGA occurs about 60 nucleotides upstream and CCCA is found 3-40 nucleotides downstream from the 3' splice site. A model explaining some of the putative signals discussed here is also proposed. This model involves formation of alternate stem-loop structures around the branching point and 3' splice site. Such signals and structures can possibly aid in protein or nucleoprotein branching point and splice site recognition.     

Specific and stable intron-factor interactions are established early during in vitro pre-mRNA splicing

Biochemical components (splicing factors) interact with specific intron regions during pre-mRNA splicing in vitro. The pre-mRNA specifically associates with factors at both the branch point and the 5' splice site and these RNA-factor interactions are maintained in the intron-containing RNA processing products. The first detectable event, the ATP-dependent association of a factor (or factors) with the branch point, is mediated by at least one factor containing an essential nucleic acid component. Mutant RNA substrates that lack either the 5' splice site or the vast majority of exon sequences can still associate with the branch point binding factor(s). However, this branch point-factor interaction does not occur with a mutant RNA substrate that contains the branch point but that lacks the 3' splice site consensus sequence. These results suggest that selection of the 3' splice site accompanied by the association of a factor with the branch point may be the initial step in mammalian pre-mRNA splicing.     

Interactions between the terminal bases of mammalian introns are retained in inosine-containing pre-mRNAs.

Nuclear pre-mRNA splicing has a fundamentally similar two-step mechanism to that employed by group II self-splicing introns. It is believed that nuclear pre-mRNA splicing involves a network of RNA-RNA interactions which form the catalytic core of the active spliceosome. We show here a non-Watson-Crick interaction between the first and last guanosine residues of a mammalian intron. As in Saccharomyces cerevisiae, substitution of the conserved guanosines at the 5' and 3' splice sites by A and C respectively, specifically suppresses step 2 splicing defects resulting from the individual mutations. No other combination of terminal nucleotides was able to restore splicing. We additionally provide independent evidence for an indirect interaction between other nucleotides of the consensus splice sites during step 2 of splicing. Substitution of the nucleotide in the +3 position of the 5' splice site affects competition between closely spaced AG dinucleotides at the 3' splice site, although the interaction is not via direct differential base pairing. Finally, we show that complete substitution of guanosine residues by inosine in a pre-mRNA has only a modest effect upon step 2 of splicing, although earlier spliceosome assembly steps are impaired. Predictions can thus be made about the precise configuration of the non-Watson-Crick interaction between the terminal residues.     

Cryptic branch point activation allows accurate in vitro splicing of human beta-globin intron mutants

The excised introns of pre-mRNAs and intron-containing splicing intermediates are in a lariat configuration in which the 5' end of the intron is linked by a 2'-5' phosphodiester bond (RNA branch) to a single adenosine residue near the 3' end of the intron. To determine the role of the specific sequence surrounding the RNA branch, we have mutated the branch point sequence of the human beta-globin IVS1. Pre-mRNAs lacking the authentic branch point sequence are accurately spliced in vitro; processing of the mutant pre-mRNAs generates RNA lariats due to the activation of cryptic branch points within IVS1. The cryptic branch points always occur at adenosine residues, but the sequences surrounding the branched nucleotide vary. Regardless of the type of mutation or the sequences remaining within IVS1, the cryptic branch points are 22 to 37 nucleotides upstream of the 3' splice site. These results suggest that RNA branch point selection is primarily based on a mechanism that measures the distance from the 3' splice site.     

Self-splicing of group II introns in vitro: lariat formation and 3' splice site selection in mutant RNAs

Deletion or substitution of the branch A residue in group II intron bl1 significantly reduces splicing activity; yet, residual exon ligation is correct, and lariats have their branch points at the normal distance from the 3' end of the intron. Mutations in the sequence facing the branch point also allow residual lariat formation; however, free 3' exons are generated with false 5' termini, all of which are within a UCACA consensus sequence located upstream or downstream of the normal 3' splice site. These results indicate that both the conserved 3' splice site APy and the spatial arrangements in stem 6 are crucial for correct 3' splice site selection.     

mRNA processing in Dictyostelium: sequence requirements for termination and splicing

Criteria for the identification of termination regions in Dictyostelium discoideum genes have been established and the sequence requirements for termination in 33 genes have been analyzed. A canonical hexamer signal AATAAA was present 15-30 nucleotides upstream of the cleavage site, usually a TA, and was embedded in a particularly A-rich environment. T- or GT-rich downstream elements characteristic of animal cells could not be identified. In a sample of 102 introns we have established the consensus AG/GTAAGT and ATAG/ for the 5' and 3' splice sites, respectively. Most introns are 75-150 nucleotides long and the A+T content is high (90%). A putative branch point was identified in half of the introns 20-60 nucleotides upstream of the 3' splice site and the consensus TACTAAY was derived. A polypyrimidine tract required for branching in vertebrates was not identified, but weak preference for pyrimidine was found 10-45 nucleotides upstream of the 3' splice site.     

Branch point identification and sequence requirements for intron splicing in Plasmodium falciparum

Splicing of mRNA is an ancient and evolutionarily conserved process in eukaryotic organisms, but intron-exon structures vary. Plasmodium falciparum has an extreme AT nucleotide bias (>80%), providing a unique opportunity to investigate how evolutionary forces have acted on intron structures. In this study, we developed an in vivo luciferase reporter splicing assay and employed it in combination with lariat isolation and sequencing to characterize 5' and 3' splicing requirements and experimentally determine the intron branch point in P. falciparum. This analysis indicates that P. falciparum mRNAs have canonical 5' and 3' splice sites. However, the 5' consensus motif is weakly conserved and tolerates nucleotide substitution, including the fifth nucleotide in the intron, which is more typically a G nucleotide in most eukaryotes. In comparison, the 3' splice site has a strong eukaryotic consensus sequence and adjacent polypyrimidine tract. In four different P. falciparum pre-mRNAs, multiple branch points per intron were detected, with some at U instead of the typical A residue. A weak branch point consensus was detected among 18 identified branch points. This analysis indicates that P. falciparum retains many consensus eukaryotic splice site features, despite having an extreme codon bias, and possesses flexibility in branch point nucleophilic attack.