Exon definition may facilitate splice site selection in RNAs with multiple exons.

Interactions at the 3' end of the intron initiate spliceosome assembly and splice site selection in vertebrate pre-mRNAs. Multiple factors, including U1 small nuclear ribonucleoproteins (snRNPs), are involved in initial recognition at the 3' end of the intron. Experiments were designed to test the possibility that U1 snRNP interaction at the 3' end of the intron during early assembly functions to recognize and define the downstream exon and its resident 5' splice site. Splicing precursor RNAs constructed to have elongated second exons lacking 5' splice sites were deficient in spliceosome assembly and splicing activity in vitro. Similar substrates including a 5' splice site at the end of exon 2 assembled and spliced normally as long as the second exon was less than 300 nucleotides long. U2 snRNPs were required for protection of the 5' splice site terminating exon 2, suggesting direct communication during early assembly between factors binding the 3' and 5' splice sites bordering an exon. We suggest that exons are recognized and defined as units during early assembly by binding of factors to the 3' end of the intron, followed by a search for a downstream 5' splice site. In this view, only the presence of both a 3' and a 5' splice site in the correct orientation and within 300 nucleotides of one another will stable exon complexes be formed. Concerted recognition of exons may help explain the 300-nucleotide-length maximum of vertebrate internal exons, the mechanism whereby the splicing machinery ignores cryptic sites within introns, the mechanism whereby exon skipping is normally avoided, and the phenotypes of 5' splice site mutations that inhibit splicing of neighboring introns.     

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.     

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.     

Switch in 3' splice site recognition between exon definition and splicing catalysis is important for sex-lethal autoregulation

Maintenance of female sexual identity in Drosophila melanogaster involves an autoregulatory loop in which the protein Sex-lethal (SXL) promotes skipping of exon 3 from its own pre-mRNA. We have used transient transfection of Drosophila Schneider cells to analyze the role of exon 3 splice sites in regulation. Our results indicate that exon 3 repression requires competition between the 5' splice sites of exons 2 and 3 but is independent of their relative strength. Two 3' splice site AG's precede exon 3. We report here that, while the distal site plays a critical role in defining the exon, the proximal site is preferentially used for the actual splicing reaction, arguing for a switch in 3' splice site recognition between exon definition and splicing catalysis. Remarkably, the presence of the two 3' splice sites is important for the efficient regulation by SXL, suggesting that SXL interferes with molecular events occurring between initial splice site communication across the exon and the splice site pairing that leads to intron removal.     

Intron definition in splicing of small Drosophila introns.

Approximately half of the introns in Drosophila melanogaster are too small to function in a vertebrate and often lack the pyrimidine tract associated with vertebrate 3' splice sites. Here, we report the splicing and spliceosome assembly properties of two such introns: one with a pyrimidine-poor 3' splice site and one with a pyrimidine-rich 3' splice site. The pyrimidine-poor intron was absolutely dependent on its small size for in vivo and in vitro splicing and assembly. As such, it had properties reminiscent of those of yeast introns. The pyrimidine-rich intron had properties intermediate between those of yeasts and vertebrates. This 3' splice site directed assembly of ATP-dependent complexes when present as either an intron or exon and supported low levels of in vivo splicing of a moderate-length intron. We propose that splice sites can be recognized as pairs across either exons or introns, depending on which distance is shorter, and that a pyrimidine-rich region upstream of the 3' splice site facilitates the exon mode.     

Conserved quartets near 5' intron junctions in primate nuclear pre-mRNA

Analysis of a 1000 nucleotide span around 664 primate 5' exon/intron junctions revealed frequent recurrences of G-rich runs downstream of the 5' splice sites. In particular, AGGG, GGGA, GGGG, GGGT and TGGG are frequent at this site. Some C-rich quarters are frequent upstream of the 5' splice site. Similar behaviour of these G- and C-rich quartets is indicated for the 587 rodent introns and for a combined eukaryotic file containing 1688 introns. (A)GGG(A) is also frequent in the introns 60 nucleotides upstream of the 3' splice site, and (A)CCC(A) is frequently found in the exons downstream of the 3' site. The same consistent behaviour of the 3' splice sites is obtained as for the 5' sites, for the primates, rodents and combined eukaryotic file. These results suggest that in addition to the well-conserved 5' and 3' splice sequences, exon as well as intron sequences may play a role in nuclear pre-mRNA splicing.     

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.     

A 5' splice site-proximal enhancer binds SF1 and activates exon bridging of a microexon

Internal exon size in vertebrates occurs over a narrow size range. Experimentally, exons shorter than 50 nucleotides are poorly included in mRNA unless accompanied by strengthened splice sites or accessory sequences that act as splicing enhancers, suggesting steric interference between snRNPs and other splicing factors binding simultaneously to the 3' and 5' splice sites of microexons. Despite these problems, very small naturally occurring exons exist. Here we studied the factors and mechanism involved in recognizing a constitutively included six-nucleotide exon from the cardiac troponin T gene. Inclusion of this exon is dependent on an enhancer located downstream of the 5' splice site. This enhancer contains six copies of the simple sequence GGGGCUG. The enhancer activates heterologous microexons and will work when located either upstream or downstream of the target exon, suggesting an ability to bind factors that bridge splicing units. A single copy of this sequence is sufficient for in vivo exon inclusion and is the binding site for the known bridging mammalian splicing factor 1 (SF1). The enhancer and its bound SF1 act to increase recognition of the upstream exon during exon definition, such that competition of in vitro reactions with RNAs containing the GGGGCUG repeated sequence depress splicing of the upstream intron, assembly of the spliceosome on the 3' splice site of the exon, and cross-linking of SF1. These results suggest a model in which SF1 bridges the small exon during initial assembly, thereby effectively extending the domain of the exon.     

snRNA interactions at 5' and 3' splice sites monitored by photoactivated crosslinking in yeast spliceosomes.

Splice site recognition and catalysis of the transesterification reactions in the spliceosome are accompanied by a dynamic series of interactions involving conserved or invariant sequences in the spliceosomal snRNAs. We have used site-specific photoactivated crosslinking in yeast spliceosomes to monitor interactions between snRNAs and exon sequences near the 5' and 3' splice sites. The last nucleotide of the 5' exon can be crosslinked to an invariant loop sequence in U5 SnRNA before and after 5' splice site cleavage. The first nucleotide of the 3' exon can also be crosslinked to the same U5 loop sequence, but this contact is only detectable after the first transesterification. These results are in close agreement with earlier data from mammalian splicing extracts, and they are consistent with a model in which U5 snRNA aligns the 5' and 3' exons for the second transesterification. After the first catalytic step of splicing, the first nucleotide of the 3' exon can also crosslink to nt U23 in U2 snRNA. This is one of a cluster of residues in U2-U6 helix I implicated by mutational analysis in the second catalytic step of splicing. The crosslinking data suggest that these residues in U2-U6 helix I are in close proximity to the scissile phosphodiester bond at the 3' splice site prior to the second transesterification. These results constitute the first biochemical evidence for a direct interaction between the 3' splice site and U2 snRNA.     

Recognition of the 5' splice site by the spliceosome.

The splicing of nuclear pre-mRNAs is catalyzed by a large, multicomponent ribonucleoprotein complex termed the spliceosome. Elucidation of the molecular mechanism of splicing identified small nuclear RNAs (snRNAs) as important components of the spliceosome, which, by analogy to the self-splicing group II introns, are implicated in formation of the catalytic center. In particular, the 5' splice site (5'SS) and the branch site, which represent the two substrates for the first step of splicing, are first recognized by U1 and U2 snRNPs, respectively. This initial recognition of splice sites is responsible for the global definition of exons and introns, and represents the primary target for regulation of splicing. Subsequently, pairing interaction between the 5'SS and U1 snRNA is disrupted and replaced by a new interaction of the 5'SS with U6 snRNA. The 5'SS signal contains an invariant GU dinucleotide present at the 5' end of nearly all known introns, however, the mechanism by which the spliceosome recognizes this element is not known. We have identified and characterized a specific UV light-induced crosslink formed between the 5'SS RNA and hPrp8, a protein component of U5 snRNP in the spliceosome that is likely to reflect a specific recognition of the GU dinucleotide for splicing. Because recognition of the 5'SS must be linked to formation of the catalytic site, the identification of a specific and direct interaction between the 5'SS and Prp8 has significant implications for the role of this protein in the mechanism of mRNA splicing.     

Effect of 5'' splice site mutations on splicing of the preceding intron.

Three exon constructs containing identical intron and exon sequences were mutated at the 5' splice site beginning intron 2 and assayed for the effect of the mutation on splicing of the upstream intron in vitro. Alteration of two or six bases within the 5' splice site reduced removal of intron 1 at least 20-fold, as determined by quantitation of either spliced product or released lariat RNA. The prominent product was skip splicing of exon 1 to exon 3. Examination of complex formation indicated that mutation of the 5' splice site terminating exon 2 depressed the ability of precursor RNAs containing just the affected exon to direct assembly in vitro. These results suggest that mutation at the end of an internal exon inhibits the ability of the exon to be recognized by splicing factors. A comparison of the known vertebrate 5' splice site mutations in which the mutation resides at the end of an internal exon indicated that exon skipping is the preferred phenotype for this type of mutation, in agreement with the in vitro observation reported here. Inhibition of splicing by mutation at the distal and of the exon supports the suggestion that exons, rather than splice sites, are the recognition units for assembly of the spliceosome.     

In vivo recognition of a vertebrate mini-exon as an exon-intron-exon unit.

Very small vertebrate exons are problematic for RNA splicing because of the proximity of their 3' and 5' splice sites. In this study, we investigated the recognition of a constitutive 7-nucleotide mini-exon from the troponin I gene that resides quite close to the adjacent upstream exon. The mini-exon failed to be included in spliced RNA when placed in a heterologous gene unless accompanied by the upstream exon. The requirement for the upstream exon disappeared when the mini-exon was internally expanded, suggesting that the splice sites bordering the mini-exon are compatible with those of other constitutive vertebrate exons and that the small size of the exon impaired inclusion. Mutation of the 5' splice site of the natural upstream exon did not result in either exon skipping or activation of a cryptic 5' splice site, the normal vertebrate phenotypes for such mutants. Instead, a spliced RNA accumulated that still contained the upstream intron. In vitro, the mini-exon failed to assemble into spliceosome complexes unless either internally expanded or accompanied by the upstream exon. Thus, impaired usage of the mini-exon in vivo was accompanied by impaired recognition in vitro, and recognition of the mini-exon was facilitated by the presence of the upstream exon in vivo and in vitro. Cumulatively, the atypical in vivo and in vitro properties of the troponin exons suggest a mechanism for the recognition of this mini-exon in which initial recognition of an exon-intron-exon unit is followed by subsequent recognition of the intron.     

Proximity of the U12 snRNA with both the 5' splice site and the branch point during early stages of spliceosome assembly

U12 snRNA is required for branch point recognition in the U12-dependent spliceosome. Using site-specific cross-linking, we have captured an unexpected interaction between the 5' end of the U12 snRNA and the -2 position upstream of the 5' splice site of P120 and SCN4a splicing substrates. The U12 snRNA nucleotides that contact the 5' exon are the same ones that form the catalytically important helix Ib with U6atac snRNA in the spliceosome catalytic core. However, the U12/5' exon interaction is transient, occurring prior to the entry of the U4atac/U6atac.U5 tri-snRNP to the spliceosome. This suggests that the helix Ib region of U12 snRNA is positioned near the 5' splice site early during spliceosome assembly and only later interacts with U6atac to form helix Ib. We also provide evidence that U12 snRNA can simultaneously interact with 5' exon sequences near 5' splice site and the branch point sequence, suggesting that the 5' splice site and branch point sequences are separated by <40 to 50 A in the complex A of the U12-dependent spliceosome. Thus, no major rearrangements are subsequently needed to position these sites for the first step of catalysis.     

Extensive interactions of PRP8 protein with the 5'' and 3'' splice sites during splicing suggest a role in stabilization of exon alignment by U5 snRNA.

Precursor RNAs containing 4-thiouridine at specific sites were used with UV-crosslinking to map the binding sites of the yeast protein splicing factor PRP8. PRP8 protein interacts with a region of at least eight exon nucleotides at the 5' splice site and a minimum of 13 exon nucleotides and part of the polypyrimidine tract in the 3' splice site region. Crosslinking of PRP8 to mutant and duplicated 3' splice sites indicated that the interaction is not sequence specific, nor does it depend on the splice site being functional. Binding of PRP8 to the 5' exon was established before step 1 and to the 3' splice site region after step 1 of splicing. These interactions place PRP8 close to the proposed catalytic core of the spliceosome during both transesterification reactions. To date, this represents the most extensive mapping of the binding site(s) of a splicing factor on the substrate RNA. We propose that the large binding sites of PRP8 stabilize the intrinsically weaker interactions of U5 snRNA with both exons at the splice sites for exon alignment by the U5 snRNP.     

Atypical 5' splice sites cause CFTR exon 9 to be vulnerable to skipping

The molecular basis of the skipping of constitutive exons in many messenger RNAs is not fully understood. A well-studied example is exon 9 of the human cystic fibrosis transmembrane conductance regulator gene (CFTR), in which an abbreviated polypyrimidine tract between the branch point A and the 3' splice site is associated with increased exon skipping and disease. However, many exons, both in CFTR and in other genes and have short polypyrimidine tracts in their 3' splice sites, yet they are not skipped. Inspection of the 5' splice sites immediately up- and downstream of exon 9 revealed deviations from consensus sequence, so we hypothesized that this exon may be inherently vulnerable to skipping. To test this idea, we constructed a CFTR minigene and replicated exon 9 skipping associated with the length of the polypyrimidine tract upstream of exon 9. We then mutated the flanking 5' splice sites and determined the effect on exon skipping. Conversion of the upstream 5' splice site to consensus by replacing a pyrimidine at position +3 with a purine resulted in increased exon skipping. In contrast, conversion of the downstream 5' splice site to consensus by insertion of an adenine at position +4 resulted in a substantial reduction in exon 9 skipping, regardless of whether the upstream 5' splice site was consensus or not. These results suggested that the native downstream 5' splice site plays an important role in CFTR exon 9 skipping, a hypothesis that was supported by data from sheep and mouse genomes. Although CFTR exon 9 in sheep is preceded by a long polypyrimidine tract (Y(14)), it skips exon 9 in vivo and has a nonconsensus downstream 5' splice site identical to that in humans. On the other hand, CFTR exon 9 in mice is preceded by a short polypyrimidine tract (Y(5)) but is not skipped in vivo. Its downstream 5' splice site differs from that in humans by a 2-nt insertion, which, when introduced into the human CFTR minigene, abolished exon 9 skipping. Taken together, these observations place renewed emphasis on deviations at 5' splice sites in nucleotides other than the invariant GT, particularly when such changes are found in conjunction with other altered splicing sequences, such as a shortened polypyrimidine tract. Thus, careful inspection of entire 5' splice sites may identify constitutive exons that are vulnerable to skipping.     

Polypyrimidine tract binding protein blocks the 5' splice site-dependent assembly of U2AF and the prespliceosomal E complex

Polypyrimidine tract binding protein (PTB) represses some alternatively spliced exons by direct occlusion of splice sites. In repressing the splicing of the c-src N1 exon, we find that PTB acts by a different mechanism. PTB does not interfere with U1 snRNP binding to the N1 5' splice site. Instead, PTB prevents formation of the prespliceosomal early (E) complex across the intervening intron by preventing the assembly of the splicing factor U2AF on the 3' splice site of exon 4. When the unregulated 5' splice site of the upstream exon 3 is present, U2AF binding is restored and splicing between exons 3 and 4 proceeds in spite of the N1 exon bound PTB. Thus, rather than directly blocking the N1 splice sites, PTB prevents the 5' splice site-dependent assembly of U2AF into the E complex. This mechanism likely occurs in many other alternative exons.     

Identification of motifs that function in the splicing of non-canonical introns

Background  

While the current model of pre-mRNA splicing is based on the recognition of four canonical intronic motifs (5' splice site, branchpoint sequence, polypyrimidine (PY) tract and 3' splice site), it is becoming increasingly clear that splicing is regulated by both canonical and non-canonical splicing signals located in the RNA sequence of introns and exons that act to recruit the spliceosome and associated splicing factors. The diversity of human intronic sequences suggests the existence of novel recognition pathways for non-canonical introns. This study addresses the recognition and splicing of human introns that lack a canonical PY tract. The PY tract is a uridine-rich region at the 3' end of introns that acts as a binding site for U2AF65, a key factor in splicing machinery recruitment.     

Identification of proteins that interact with exon sequences, splice sites, and the branchpoint sequence during each stage of spliceosome assembly.

We have carried out a systematic analysis of the proteins that interact with specific intron and exon sequences during each stage of mammalian spliceosome assembly. This was achieved by site-specifically labeling individual nucleotides within the 5' and 3' splice sites, the branchpoint sequence (BPS), or the exons with 32P and identifying UV-cross-linked proteins in the E, A, B, or C spliceosomal complex. Significantly, two members of the SR family of splicing factors, which are known to promote E-complex assembly, cross-link within exon sequences to a region approximately 25 nucleotides upstream from the 5' splice site. At the 5' splice site, cross-linking of the U5 small nuclear ribonucleoprotein particle protein, U5(200), was detected in both the B and C complexes. As observed in yeast cells, U5(200), also cross-links to intron/exon sequences at the 3' splice site in the C complex and may play a role in aligning the 5' and 3' exons for ligation. With label at the branch site, we detected three distinct proteins, designated BPS72,BpS70, and BPS56, which replace one another in the E, A, and C complexes. Another dynamic exchange was detected with pre-mRNA labeled at the AG dinucleotide of the 3' splice site. In this case, a protein, AG100,cross-links in the A complex and is replaced by another protein, AG75, in the C complex. The observation that these proteins are specifically associated with critical pre-mRNA sequence elements in functional complexes at different stages of spliceosome assembly implicates roles for these factors in key recognition events during the splicing pathway.