tau Exon 10 expression involves a bipartite intron 10 regulatory sequence and weak 5' and 3' splice sites

tau mutations that deregulate alternative exon 10 (E10) splicing cause frontotemporal dementia with parkinsonism chromosome 17-type by several mechanisms. Previously we showed that E10 splicing involved exon splicing enhancer sequences at the 5' and 3' ends of E10, an exon splicing silencer, a weak 5' splice site, and an intron splicing silencer (ISS) within intron 10 (I10). Here, we identify additional regulatory sequences in I10 using both non-neuronal and neuronal cells. The ISS sequence extends from I10 nucleotides 11-18, which is sufficient to inhibit use of a weakened 5' splice site of a heterologous exon. Furthermore, ISS function is location-independent but requires proximity to a weak 5' splice site. Thus, the ISS functions as a linear sequence. A new cis-acting element, the intron splicing modulator (ISM), was identified immediately downstream of the ISS at I10 positions 19-26. The ISM and ISS form a bipartite regulatory element, within which the ISM functions when the ISS is present, mitigating E10 repression by the ISS. Additionally, the 3' splice site of E10 is weak and requires exon splicing enhancer elements for efficient E10 inclusion. Thus far, tau FTDP-17 splicing mutations affect six predicted cis-regulatory sequences.     

Conservation of an open-reading frame as an element affecting 5' splice site selection

Splice site selection is a key element of pre-mRNA splicing and involves specific recognition of consensus sequences at the 5(') and 3(') splice sites. Evidently, the compliance of a given sequence with the consensus 5(') splice site sequence is not sufficient to define it as a functional 5(') splice site, because not all sequences that conform with the consensus are used for splicing. We have previously hypothesized that the necessity to avoid the inclusion of premature termination codons within mature mRNAs may serve as a criterion that differentiates normal 5(') splice sites from unused (latent) ones. We further provided experimental support to this idea, by analyzing the splicing of pre-mRNAs in which in-frame stop codons upstream of a latent 5(') splice site were mutated, and showing that splicing using the latent site is indeed activated by such mutations. Here we evaluate this hypothesis by a computerized survey for latent 5(') splice sites in 446 protein-coding human genes. This data set contains 2311 introns, in which we found 10490 latent 5(') splice sites. The utilization of 10045 (95.8%) of these sites for splicing would have led to the inclusion of an in-frame stop codon within the resultant mRNA. The validity of this finding is confirmed here by statistical analyses. This finding, together with our previous experimental results, invokes a nuclear scanning mechanism, as part of the splicing machine, which identifies in-frame stop codons within the pre-mRNA and prevents splicing that could lead to the formation of a prematurely terminated protein.     

Natural base-pairing interactions between 5' splice site and branch site sequences affect mammalian 5' splice site selection.

In the murine gene encoding the neuronal cell adhesion molecule (NCAM), the integrity of the 5' splice site of exon 18 (E18) is essential for regulation of alternative splicing. To further study the contribution of 5' splice site sequences, we used a simple NCAM pre-mRNA containing a portion of E18 fused to E19 and separated by a shortened intron. This RNA is spliced in vitro to produce five sets of lariat intermediates and products, the most abundant set displaying aberrant migration in acrylamide/urea gels. Base pairing interactions between positions +5 and +8 of the intron and positions -3 and -6 from the branch point were responsible for the faster migration of this set of lariat molecules. To test whether the duplex structure forms earlier and contributes to 5' splice site selection, we used NCAM substrates carrying the 5' splice sites of E17 and E18 in competition for the 3' splice site of E19. Mutations upstream of the major branch site improve E18/E19 splicing in NIH3T3 extracts, whereas compensatory mutations at positions +7 and +8 neutralize the effect of branch site mutations and curtail E18/E19 splicing. Our data suggest that duplex formation occurs early and interferes with the assembly of complexes initiated on the 5' splice site of NCAM E18. This novel type of intron interaction may exist in the introns of other mammalian pre-mRNAs.     

5' cleavage site in eukaryotic pre-mRNA splicing is determined by the overall 5' splice region, not by the conserved 5' GU

We have generated all possible single point mutations of the invariant 5' GT of the large beta-globin intron and determined their effect on splicing in vitro. None of the mutants prevented cleavage in the 5' splice region, but many reduced or abolished exon joining. The mutations GT----TT and GT----CT resulted in a shift of the 5' cleavage site on nucleotide upstream; in the case of the mutation GT----TT, this shift was reverted by a second site mutation within the 5' splice region. Our results suggest that the 5' cleavage site is determined not by the conserved GU sequence but by the 5' splice region as a whole, most probably via base-pairing to the 5' end of the U1 snRNA.     

Efficient internal exon recognition depends on near equal contributions from the 3' and 5' splice sites

Pre-mRNA splicing is carried out by the spliceosome, which identifies exons and removes intervening introns. In vertebrates, most splice sites are initially recognized by the spliceosome across the exon, because most exons are small and surrounded by large introns. This gene architecture predicts that efficient exon recognition depends largely on the strength of the flanking 3' and 5' splice sites. However, it is unknown if the 3' or the 5' splice site dominates the exon recognition process. Here, we test the 3' and 5' splice site contributions towards efficient exon recognition by systematically replacing the splice sites of an internal exon with sequences of different splice site strengths. We show that the presence of an optimal splice site does not guarantee exon inclusion and that the best predictor for exon recognition is the sum of both splice site scores. Using a genome-wide approach, we demonstrate that the combined 3' and 5' splice site strengths of internal exons provide a much more significant separator between constitutive and alternative exons than either the 3' or the 5' splice site strength alone.     

Antagonistic effects of the SRp30c protein and cryptic 5' splice sites on the alternative splicing of the apoptotic regulator Bcl-x

Alternative 5' splice site selection allows Bcl-x to produce two isoforms with opposite effects on apoptosis. The pro-apoptotic Bcl-x(S) variant is up-regulated by ceramide and down-regulated by protein kinase C through specific cis-acting exonic elements, one of which is bound by SAP155. Splicing to the Bcl-x(S) 5' splice site is also enforced by heterogeneous nuclear ribonucleoprotein (hnRNP) F/H proteins and by Sam68 in cooperation with hnRNP A1. Here, we have characterized exon elements that influence splicing to the 5' splice site of the anti-apoptotic Bcl-x(L) isoform. Within a 86-nucleotide region (B3) located immediately upstream of the Bcl-x(L) donor site we have identified two elements (ML2 and AM2) that stimulate splicing to the Bcl-x(L) 5' splice site. SRp30c binds to these elements and can shift splicing to the 5' splice site of Bcl-x(L) in an ML2/AM2-dependent manner in vitro and in vivo. The B3 region also contains an element that represses the use of Bcl-x(L). This element is bound by U1 small nuclear ribonucleoprotein and contains two 5' splice sites that can be used when the Bcl-x(L) 5' splice site is mutated or the ML2/AM2 elements are deleted. Conversely, mutating the cryptic 5' splice sites stimulates splicing to the Bcl-x(L) site. Thus, SRp30c stimulates splicing to the downstream 5' splice site of Bcl-x(L), thereby attenuating the repressive effect of upstream U1 snRNP binding sites.     

Cooperation of 5' and 3' processing sites as well as intron and exon sequences in calcitonin exon recognition.

We have previously shown that the calcitonin (CT)-encoding exon 4 of the human calcitonin/calcitonin gene-related peptide I (CGRP-I) gene (CALC-I gene) is surrounded by suboptimal processing sites. At the 5' end of exon 4 a weak 3' splice site is present because of an unusual branch acceptor nucleotide (U) and a weak poly(A) site is present at the 3' end of exon 4. For CT-specific RNA processing two different exon enhancer elements, A and B, located within exon 4 are required. In this study we have investigated the cooperation of these elements in CT exon recognition and inclusion by transient transfection into 293 cells of CALC-I minigene constructs. Improvement of the strength of the 3' splice site in front of exon 4 by the branchpoint mutation U-->A reduces the requirement for the presence of exon enhancer elements within exon 4 for CT-specific RNA processing, irrespective of the length of exon 4. Replacement of the exon 4 poly(A) site with a 5' splice site does not result in CT exon recognition, unless also one or more exon enhancer elements and/or the branchpoint mutation U-->A in front of exon 4 are present. This indicates that terminal and internal exons are recognised in a similar fashion. The number of additional enhancing elements that are required for CT exon recognition depends on the strength of the 5' splice site. Deletion of a large part of intron 4 also leads to partial exon 4 skipping. All these different elements contribute to CT exon recognition and inclusion. The CT exon is recognised as a whole entity and the sum of the strengths of the different elements determines recognition as an exon. Curiously, in one of our constructs a 5' splice site at the end of exon 4 is either ignored by the splicing machinery of the cell or recognised as a splice donor or as a splice acceptor site.     

Accurate selection of a 5' splice site requires sequences within fibronectin alternative exon B.

Inclusion of fibronectin alternative exon B in mRNA is developmentally regulated. Here we demonstrate that exon B contains two unique purine-rich sequence tracts, PRE1 and PRE2, that are important for proper 5' splice site selection both in vivo and in vitro. Targeted mutations of both PREs decreased the inclusion of exon B in the mRNA by 50% in vivo. Deletion or mutation of the PREs reduced removal of the downstream intron, but not the upstream intron, and induced the activation of cryptic 5' splice sites in vitro. PRE-mediated 5' splice selection activity appears sensitive to position and sequence context. A well characterized exon sequence enhancer that normally acts on the upstream 3' splice site can partially rescue proper exon B 5' splice site selection. In addition, we found that PRE 5' splice selection activity was preserved when exon B was inserted into a heterologous pre-mRNA substrate. Possible roles of these unique activities in modulating exon B splicing are considered.     

An intronic splicing enhancer binds U1 snRNPs to enhance splicing and select 5' splice sites

Intronic G triplets are frequently located adjacent to 5' splice sites in vertebrate pre-mRNAs and have been correlated with splicing efficiency and specificity via a mechanism that activates upstream 5' splice sites in exons containing duplicated sites (26). Using an intron dependent upon G triplets for maximal activity and 5' splice site specificity, we determined that these elements bind U1 snRNPs via base pairing with U1 RNA. This interaction is novel in that it uses nucleotides 8 to 10 of U1 RNA and is independent of nucleotides 1 to 7. In vivo functionality of base pairing was documented by restoring activity and specificity to mutated G triplets through compensating U1 RNA mutations. We suggest that the G-rich region near vertebrate 5' splice sites promotes accurate splice site recognition by recruiting the U1 snRNP.     

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.     

An element in the 5' common exon of the NCAM alternative splicing unit interacts with SR proteins and modulates 5' splice site selection.

The neural cell adhesion molecule (NCAM) gene contains an 801 nt exon that is included preferentially in neuronal cells. We have set up an in vitro splicing system that mimics the neuro-specific alternative splicing profile of NCAM exon 18. Splicing regulation is observed using model pre-mRNAs that contain competing 5' or 3' splice sites, suggesting that distinct pathways regulate NCAM 5' and 3' splice site selection. While inclusion of exon 18 is the predom-inant choice in neuronal cells, an element in the 5' common exon 17 improves exon 17/exon 19 splicing in a neuronal cell line. A similar behavior is observed in vitro as the element can stimulate the 5' splice site of exon 17 or a heterologous 5' splice site. The minimal 32 nt sequence of the exon 17 enhancer consists of purine stretches and A/C motifs. Mutations in the purine stretches compromise the binding of SR proteins and decreases splicing stimulation in vitro. Mutations in the A/C motifs do not affect SR protein binding but reduce enhancing activity. Our results suggest that the assembly of an enhancer complex containing SR proteins in a 5' common exon ensures that NCAM mRNAs lacking exon 18 are made in neuronal cells.     

Sensitivity of splice sites to antisense oligonucleotides in vivo

A series of HeLa cell lines which stably express beta-globin pre-mRNAs carrying point mutations at nt 654, 705, or 745 of intron 2 has been developed. The mutations generate aberrant 5' splice sites and activate a common 3' cryptic splice site upstream leading to aberrantly spliced beta-globin mRNA. Antisense oligonucleotides, which in vivo blocked aberrant splice sites and restored correct splicing of the pre-mRNA, revealed major differences in the sensitivity of these sites to antisense probes. Although the targeted pre-mRNAs differed only by single point mutations, the effective concentrations of the oligonucleotides required for correction of splicing varied up to 750-fold. The differences among the aberrant 5' splice sites affected sensitivity of both the 5' and 3' splice sites; in particular, sensitivity of both splice sites was severely reduced by modification of the aberrant 5' splice sites to the consensus sequence. These results suggest large differences in splicing of very similar pre-mRNAs in vivo. They also indicate that antisense oligonucleotides may provide useful tools for studying the interactions of splicing machinery with pre-mRNA.     

Exonic splicing enhancers contribute to the use of both 3' and 5' splice site usage of rat beta-tropomyosin pre-mRNA

The rat beta-tropomyosin gene encodes two tissue-specific isoforms that contain the internal, mutually exclusive exons 6 (nonmuscle/smooth muscle) and 7 (skeletal muscle). We previously demonstrated that the 3' splice site of exon 6 can be activated by introducing a 9-nt polyuridine tract at its 3' splice site, or by strengthening the 5' splice site to a U1 consensus binding site, or by joining exon 6 to the downstream common exon 8. Examination of sequences within exons 6 and 8 revealed the presence of two purine-rich motifs in exon 6 and three purine-rich motifs in exon 8 that could potentially represent exonic splicing enhancers (ESEs). In this report we carried out substitution mutagenesis of these elements and show that some of them play a critical role in the splice site usage of exon 6 in vitro and in vivo. Using UV crosslinking, we have identified SF2/ASF as one of the cellular factors that binds to these motifs. Furthermore, we show that substrates that have mutated ESEs are blocked prior to A-complex formation, supporting a role for SF2/ASF binding to the ESEs during the commitment step in splicing. Using pre-mRNA substrates containing exons 5 through 8, we show that the ESEs within exon 6 also play a role in cooperation between the 3' and 5' splice sites flanking this exon. The splicing of exon 6 to 8 (i.e., 5' splice site usage of exon 6) was enhanced with pre-mRNAs containing either the polyuridine tract in the 3' splice site or consensus sequence in the 5' splice site around exon 6. We show that the ESEs in exon 6 are required for this effect. However, the ESEs are not required when both the polyuridine and consensus splice site sequences around exon 6 were present in the same pre-mRNA. These results support and extend the exon-definition hypothesis and demonstrate that sequences at the 3' splice site can facilitate use of a downstream 5' splice site. In addition, the data support the hypothesis that ESEs can compensate for weak splice sites, such as those found in alternatively spliced exons, thereby providing a target for regulation.     

Identification of alternative 5'/3' splice sites based on the mechanism of splice site competition

Alternative splicing plays an important role in regulating gene expression. Currently, most efficient methods use expressed sequence tags or microarray analysis for large-scale detection of alternative splicing. However, it is difficult to detect all alternative splice events with them because of their inherent limitations. Previous computational methods for alternative splicing prediction could only predict particular kinds of alternative splice events. Thus, it would be highly desirable to predict alternative 5'/3' splice sites with various splicing levels using genomic sequences alone. Here, we introduce the competition mechanism of splice sites selection into alternative splice site prediction. This approach allows us to predict not only rarely used but also frequently used alternative splice sites. On a dataset extracted from the AltSplice database, our method correctly classified approximately 70% of the splice sites into alternative and constitutive, as well as approximately 80% of the locations of real competitors for alternative splice sites. It outperforms a method which only considers features extracted from the splice sites themselves. Furthermore, this approach can also predict the changes in activation level arising from mutations in flanking cryptic splice sites of a given splice site. Our approach might be useful for studying alternative splicing in both computational and molecular biology.     

A DNA damage signal activates and derepresses exon inclusion in Drosophila TAF1 alternative splicing

Signal-dependent alternative splicing is important for regulating gene expression in eukaryotes, yet our understanding of how signals impact splicing mechanisms is limited. A model to address this issue is alternative splicing of Drosophila TAF1 pre-mRNA in response to camptothecin (CPT)-induced DNA damage signals. CPT treatment of Drosophila S2 cells causes increased inclusion of TAF1 alternative cassette exons 12a and 13a through an ATR signaling pathway. To evaluate the role of TAF1 pre-mRNA sequences in the alternative splicing mechanism, we developed a TAF1 minigene (miniTAF1) and an S2 cell splicing assay that recapitulated key aspects of CPT-induced alternative splicing of endogenous TAF1. Analysis of miniTAF1 indicated that splice site strength underlies independent and distinct mechanisms that control exon 12a and 13a inclusion. Mutation of the exon 13a weak 5' splice site or weak 3' splice site to a consensus sequence was sufficient for constitutive exon 13a inclusion. In contrast, mutation of the exon 12a strong 5' splice site or moderate 3' splice site to a consensus sequence was only sufficient for constitutive exon 12a inclusion in the presence of CPT-induced signals. Analogous studies of the exon 13 3' splice site suggest that exon 12a inclusion involves signal-dependent pairing between constitutive and alternative splice sites. Finally, intronic elements identified by evolutionary conservation were necessary for full repression of exon 12a inclusion or full activation of exon 13a inclusion and may be targets of CPT-induced signals. In summary, this work defines the role of sequence elements in the regulation of TAF1 alternative splicing in response to a DNA damage signal.